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D 1269
OULU 2014
UNIV ER S IT Y OF OULU P. O. BR[ 00 FI-90014 UNIVERSITY OF OULU FINLAND
U N I V E R S I TAT I S
S E R I E S
SCIENTIAE RERUM NATURALIUM
Professor Esa Hohtola
HUMANIORA
University Lecturer Santeri Palviainen
TECHNICA
Postdoctoral research fellow Sanna Taskila
ACTA
IMMUNE CELL INFILTRATION
AND INFLAMMATORY
BIOMARKERS IN
COLORECTAL CANCER
MEDICA
Professor Olli Vuolteenaho
SCIENTIAE RERUM SOCIALIUM
University Lecturer Veli-Matti Ulvinen
SCRIPTA ACADEMICA
Director Sinikka Eskelinen
OECONOMICA
Professor Jari Juga
EDITOR IN CHIEF
Professor Olli Vuolteenaho
PUBLICATIONS EDITOR
Publications Editor Kirsti Nurkkala
ISBN 978-952-62-0640-0 (Paperback)
ISBN 978-952-62-0641-7 (PDF)
ISSN 0355-3221 (Print)
ISSN 1796-2234 (Online)
U N I V E R S I T AT I S O U L U E N S I S
Juha Väyrynen
E D I T O R S
Juha Väyrynen
A
B
C
D
E
F
G
O U L U E N S I S
ACTA
A C TA
D 1269
UNIVERSITY OF OULU GRADUATE SCHOOL;
UNIVERSITY OF OULU,
FACULTY OF MEDICINE,
INSTITUTE OF DIAGNOSTICS,
DEPARTMENT OF PATHOLOGY;
MEDICAL RESEARCH CENTER OULU;
OULU UNIVERSITY HOSPITAL
D
MEDICA
ACTA UNIVERSITATIS OULUENSIS
D Medica 1269
JUHA VÄYRYNEN
IMMUNE CELL INFILTRATION AND
INFLAMMATORY BIOMARKERS IN
COLORECTAL CANCER
Academic dissertation to be presented with the assent
of the Doctoral Training Committee of Health and
Biosciences of the University of Oulu for public defence
in Auditorium 4 of Oulu University Hospital, on 12
December 2014, at 12 noon
U N I VE R S I T Y O F O U L U , O U L U 2 0 1 4
Copyright © 2014
Acta Univ. Oul. D 1269, 2014
Supervised by
Professor Markus Mäkinen
Reviewed by
Professor Timo Paavonen
Docent Jari Sundström
Opponent
Professor Ilmo Leivo
ISBN 978-952-62-0640-0 (Paperback)
ISBN 978-952-62-0641-7 (PDF)
ISSN 0355-3221 (Printed)
ISSN 1796-2234 (Online)
Cover Design
Raimo Ahonen
JUVENES PRINT
TAMPERE 2014
Väyrynen, Juha, Immune cell infiltration and inflammatory biomarkers in
colorectal cancer.
University of Oulu Graduate School; University of Oulu, Faculty of Medicine, Institute of
Diagnostics, Department of Pathology; Medical Research Center Oulu; Oulu University
Hospital
Acta Univ. Oul. D 1269, 2014
University of Oulu, P.O. Box 8000, FI-90014 University of Oulu, Finland
Abstract
Colorectal cancer (CRC) is one of the most common malignancies and causes of cancer deaths in
Finland. Increased number of tumor-infiltrating immune cells has been associated with improved
survival in CRC. However, accurate, reproducible analysis methods, as well as better
understanding of the interrelationships between different inflammatory markers would be
important in order to establish a valuable prognostic and potentially predictive tool.
In these studies, a computer-assisted method for the analysis of the densities of tumorinfiltrating immune cells and a quantitative method for the evaluation of CRC-associated
lymphoid reaction (CLR) were adopted and validated. Utilizing the new methods, the
inflammatory cell infiltration was characterized in independent groups of 418 (Cohort 1) and 149
(Cohort 2) CRC patients. Serum matrix metalloproteinase-8 (MMP-8) levels were measured in
Cohort 2 and in a control group of 83 healthy age- and gender-matched controls.
The automated cell counting method was found accurate and reproducible. In the tumor
samples, there were high positive correlations between different types of immune cells, with the
exception of mast cells and CD1a+ immature dendritic cells. High numbers of T cells predicted
improved disease-free survival. High CLR density correlated with low tumor stage, but also with
better survival regardless of stage. The median serum MMP-8 level of the patients was more than
three times higher than that of the healthy controls.
In conclusion, the present studies provide insight into the significance of various immune cell
types and inflammatory markers in CRC and validate new methods for the analysis of immune cell
infiltration in CRC. The results suggest that, especially, the densities of tumor-infiltrating T cells
and CLR represent relevant prognostic indicators in CRC. Further studies are needed to evaluate
the potential value of serum MMP-8 as an aid for CRC diagnostics, surveillance, or
prognostication.
Keywords: colorectal cancer, computer-assisted image analysis, immunohistochemistry,
inflammation, prognosis, tumor immunology
Väyrynen, Juha, Paikallinen tulehdussolukko ja tulehdusmerkkiaineet kolorektaalisyövässä.
Oulun yliopiston tutkijakoulu; Oulun yliopisto, Lääketieteellinen tiedekunta, Diagnostiikan
laitos, Patologia; Medical Research Center Oulu; Oulun yliopistollinen sairaala
Acta Univ. Oul. D 1269, 2014
Oulun yliopisto, PL 8000, 90014 Oulun yliopisto
Tiivistelmä
Kolorektaalisyöpä on yksi yleisimmistä pahanlaatuisista kasvaintaudeista ja syöpäkuolemien
aiheuttajista Suomessa. Tulehdussolujen korkean määrän kasvainnäytteissä on havaittu olevan
yhteydessä potilaiden parempaan ennusteeseen. Tarkat ja luotettavat analyysimenetelmät sekä
tieto eri tulehdusmerkkiaineiden keskinäisistä yhteyksistä olisivat tärkeitä, jotta tulehdussolukon määritystä voitaisiin luotettavasti käyttää potilaiden ennusteen arviointiin.
Tutkimuksessa otettiin käyttöön ja validoitiin uusi tietokonepohjainen menetelmä kasvaimen
tulehdussolukon arviointiin sekä uusi menetelmä kolorektaalisyövän imukeräsreaktion arviointiin. Kasvainnäytteiden tulehdussolukon määrää ja laatua analysoitiin itsenäisissä 418 (Kohortti
1) ja 149 (Kohortti 2) kolorektaalisyöpäpotilaan aineistoissa uusia menetelmiä hyödyntäen.
Lisäksi kohortilta 2 sekä 83 terveeltä ikä- ja sukupuolivalikoidulta verrokilta määritettiin seerumin matriksin metalloproteinaasi-8 (MMP-8) -taso.
Tietokonepohjaisen kuva-analyysin tarkkuus ja toistettavuus todettiin erinomaiseksi. Kasvainnäytteistä analysoitujen tulehdussolutyyppien määrät olivat riippuvaisia toisistaan mastsoluja ja CD1a+ epäkypsiä dendriittisoluja lukuun ottamatta. T-solujen runsas määrä oli yhteydessä taudin vähäisempään uusiutumisriskiin. Korkea imukerästiheys kasvainnäytteissä oli yhteydessä matalaan levinneisyysasteeseen sekä potilaiden parempaan ennusteeseen levinneisyysasteesta riippumatta. Seerumin MMP-8-tason mediaani oli potilailla yli kolme kertaa korkeampi
kuin terveillä verrokeilla.
Tutkimus tuo lisätietoa eri tulehdussolutyyppien ja tulehdusmerkkiaineiden merkityksestä
kolorektaalisyövässä, ja sen tuloksena validoitiin uusia tulehdussolukon analysointimenetelmiä.
Tulosten perusteella erityisesti kasvaimen alueen T-solujen ja imukerästen tiheys tuovat hyödyllistä tietoa potilaiden ennusteesta. Lisätutkimuksia tarvitaan seerumin MMP-8:n mahdollisesta
soveltuvuudesta kolorektaalisyövän diagnostiikan, seurannan tai ennusteen määrittämisen apuvälineeksi.
Asiasanat: ennuste, immunohistokemia, kasvainimmunologia, kolorektaalisyöpä,
tietokoneavusteinen kuva-analyysi, tulehdus
To Sara
8
Acknowledgements
This study was carried out at the Department of Pathology, Institute of
Diagnostics, University of Oulu from 2010 to 2014.
I wish to thank the Head of the Department, Professor Tuomo Karttunen,
MD, PhD, for the opportunity to work at the Department of Pathology. Tuomo is
also greatly acknowledged for his wise comments and support during these years.
With his expertise on gastrointestinal pathology, he has made a significant
contribution to the completion of the thesis.
I wish to express my deepest gratitude to my supervisor, Professor Markus
Mäkinen, MD, PhD, for his guidance and advice on both research and life in
general during these years. Without his vast knowledge and optimism, the
outcome of this thesis could not have been as good as it was. Markus has created
a humane atmosphere for his research group, which I also greatly value.
I appreciate and thank the official pre-examiners of this dissertation,
Professor Timo Paavonen, MD, PhD, and Docent Jari Sundström, MD, PhD, for
their insightful comments that have made a notable improvement in the
manuscript. I also thank Anna Vuolteenaho, MA, for her excellent linguistic
editing of the manuscript.
I wish to express my warmest thanks to the members of our research group,
Tiina Kantola, MSc, Anne-Mari Moilanen, PhD, Päivi Sirniö, MSc, Anne
Tuomisto, PhD, and Riitta Vuento, for their collaboration. Anne is, specifically,
acknowledged for her inspiring comments and guidance. I am also deeply grateful
to Riitta for her expertise and vast efforts in the preparation of the study material,
as well as for her friendship.
For significant collaboration and participation in this work I also want to
acknowledge Risto Bloigu, MSc, Jan Böhm, MD, PhD, Professor Karl-Heinz
Herzig, MD, PhD, Toni Karhu, MSc, Kai Klintrup, MD, PhD, Professor Jyrki
Mäkelä, MD, PhD, Professor Tuula Salo, DDS, PhD, Professor Timo Sorsa, DDS,
PhD, Taina Tervahartiala, DDS, PhD, and Juha Vornanen, MD. Tuula is,
especially, acknowledged for her cheerful encouragement in the early stages of
my work.
Chief Department Physicians, Docent Paavo Pääkkö, MD, PhD, and Docent
Helena Autio-Harmainen, MD, PhD, are thanked for giving me great facilities to
work at the Oulu University Hospital. I would also like to acknowledge other
pathologists and residents working in the hospital for their support and guidance
during these years.
9
My thanks are also owed to all the staff at the Department of Pathology for
their encouragement and for the laboratory and technical assistance. The teaching
staff, Docent Kirsi-Maria Haapasaari, MD, PhD, Johanna Mäkinen, MD, and
Vesa-Matti Pohjanen, MD, are, especially, thanked for their friendship.
I cannot thank enough my parents, Raija and Eero, who have supported me
and taught me critical and logical thinking from an early age. I wish to thank my
brother Henri for his friendship and for the hard workouts during these years. I
also wish to thank all my friends for taking my thoughts away from research
every now and then (and Jaakko Kangas also for stimulating research-related
conversations).
Above all, my thanks are owed to my wonderful wife and co-researcher Sara
for her continuous love and support. We have had the most enjoyable moments
both in and out of work that have given me the drive to push forward with this
research with a fruitful outcome.
I acknowledge the financial support for this thesis provided by the Academy
of Finland, Emil Aaltonen Foundation, Finnish Cancer Foundation, Finnish
Medical Foundation, Northern Finland Cancer Foundation, Orion-Farmos
Research Foundation, Oulu University Scholarship Foundation, and Vatsatautien
tutkimussäätiö.
Oulu, October 2014
10
Juha Väyrynen
Abbreviations
AACR
APC
BMI
BRAF
CD
CEA
CIMP
CIN
CLR
CRC
CRP
CRT
CSS
CT
CT-S
DAB
DC
DFS
DNA
ECM
EGFR
EMT
ESMO
e.g.
FoxP3
GPS
H&E
HP
IBD
IEL
IFMA
IFN
IM
iNOS
IL
American Association for Cancer Research
adenomatous polyposis coli
body mass index
v-raf murine sarcoma viral oncogene homolog B1
cluster of differentiation
carcinoembryonic antigen
CpG island methylator phenotype
chromosomal instability
colorectal cancer associated lymphoid reaction
colorectal cancer
C-reactive protein
chemoradiotherapy
cancer-specific survival
center of tumor
center of tumor, stromal
3,3'-diaminobenzidine
dendritic cell
disease-free survival
deoxyribonucleic acid
extracellular matrix
epidermal growth factor receptor
epithelial to mesenchymal transition
European Society for Medical Oncology
exempli gratia
forkhead box P3
Glasgow prognostic score
hematoxylin and eosin
hyperplastic polyp
inflammatory bowel disease
intraepithelial
immunofluorometric assay
interferon
invasive margin
inducible nitric oxide synthase
interleukin
11
i.e.
id est
KRAS
Kirsten rat sarcoma viral oncogene homolog
LOH
loss of heterozygosity
MAPK/ERK mitogen-activated protein kinases/ extracellular signal-regulated
kinases
MCA
methyl cyanoacrylate
MLH
MutL homolog
MMP
matrix metalloproteinase
MMR
mismatch repair
MPO
myeloperoxidase
MSH
MutS homolog
MSI
microsatellite instability
MSS
microsatellite stability
MYD88
myeloid differentiation primary response gene 88
NF-κB
nuclear factor-κB
NSAID
non-steroidal anti-inflammatory drug
OS
overall survival
ROC
receiver operating characteristics
ROS
reactive oxygen species
SSA
sessile serrated adenoma
STAT3
signal transducer and activator of transcription 3
TAA
tumor-associated antigen
TAM
tumor-associated macrophage
TGFβR2
transforming growth factor beta receptor 2
Th cell
T helper cell
TIMP
tissue inhibitor of metalloproteinases
TLR
Toll-like receptor
TNF
tumor necrosis factor
TNM
tumor, node, metastasis
TP53
tumor protein p53
TReg cell
regulatory T cell
TSA
traditional serrated adenoma
RAG-2
recombination-activating gene 2
RNA
ribonucleic acid
RT
radiotherapy
VEFG
vascular endothelial growth factor
WHO
World Health Organization
12
List of original publications
This thesis is based on the following publications, which are referred to throughout
the text by their Roman numerals:
I
Väyrynen JP, Vornanen JO, Sajanti S, Böhm JP, Tuomisto A, & Mäkinen MJ (2012) An
improved image analysis method for cell counting lends credibility to the prognostic
significance of T cells in colorectal cancer. Virchows Arch. 460(5): 455–465.
II Väyrynen JP, Tuomisto A, Klintrup K, Mäkelä J, Karttunen TJ, & Mäkinen MJ (2013)
Detailed analysis of inflammatory cell infiltration in colorectal cancer. Br. J. Cancer
109(7): 1839–1847.
III Väyrynen JP, Sajanti SA, Klintrup K, Mäkelä J, Herzig K-H, Karttunen TJ, Tuomisto A,
& Mäkinen MJ (2014) Characteristics and significance of colorectal cancer associated
lymphoid reaction. Int. J. Cancer 134(9): 2126–35.
IV Väyrynen JP, Vornanen J, Tervahartiala T, Sorsa T, Bloigu R, Salo T, Tuomisto A, &
Mäkinen MJ (2012) Serum MMP-8 levels increase in colorectal cancer and correlate with
disease course and inflammatory properties of primary tumors. Int. J. Cancer 131(4):
E463–74.
13
14
Contents
Abstract
Tiivistelmä
Acknowledgements
9
Abbreviations
11
List of original publications
13
Contents
15
1 Introduction
17
2 Review of the literature
19
2.1 Colorectal cancer epidemiology .............................................................. 19
2.1.1 Incidence ...................................................................................... 19
2.1.2 Risk factors ................................................................................... 19
2.2 Colorectal cancer classification ............................................................... 20
2.3 Colorectal cancer pathogenesis ............................................................... 20
2.3.1 Genomic and epigenetic mechanisms ........................................... 21
2.3.2 Morphological developmental pathways ...................................... 24
2.3.3 Intratumor heterogeneity and cancer stem cells ........................... 27
2.3.4 Invasion and metastasis ................................................................ 28
2.3.5 Immune system and inflammation ............................................... 31
2.3.6 Angiogenesis ................................................................................ 39
2.4 Colorectal cancer diagnosis and screening .............................................. 39
2.5 Colorectal cancer prognostic and predictive markers ............................. 40
2.5.1 Clinical and histopathological prognostic factors......................... 40
2.5.2 Inflammation-based prognostic markers ...................................... 46
2.5.3 Genetic prognostic and predictive markers .................................. 54
2.5.4 Blood and serum prognostic markers ........................................... 56
2.6 Colorectal cancer treatment..................................................................... 57
2.6.1 Surgical treatment ......................................................................... 57
2.6.2 Neoadjuvant treatment for rectal cancer ....................................... 58
2.6.3 Adjuvant treatment for colorectal cancer ..................................... 59
3 Aims of the study
61
4 Materials and methods
63
4.1 Patients (I-IV) ......................................................................................... 63
4.2 Control group (IV) .................................................................................. 64
4.3 Histopathological analysis (I-IV) ............................................................ 65
4.3.1 Stage and Grade (I-IV) ................................................................. 65
15
4.3.2 Necrosis (IV) ................................................................................ 65
4.3.3 Tumor budding (I) ........................................................................ 65
4.3.4 Peritumoral inflammatory reaction (II-IV) ................................... 65
4.3.5 Colorectal cancer associated lymphoid reaction (III-IV).............. 66
4.4 Immunohistochemistry (I-IV) ................................................................. 66
4.4.1 Tissue microarray (II, III) ............................................................. 66
4.4.2 Protocols (I-IV) ............................................................................ 67
4.4.3 Analysis of Immunohistochemistry (I-IV) ................................... 67
4.5 Serum analyses (IV) ................................................................................ 71
4.6 Measurement of intra- and inter-observer variation (I, III) ..................... 71
4.7 Statistical analyses (I-IV) ........................................................................ 71
5 Results
73
5.1 New methods for the evaluation of immune cell reaction ....................... 73
5.1.1 Computer-based immune cell counting ........................................ 73
5.1.2 CLR density .................................................................................. 73
5.2 Immune cell infiltration in colorectal cancer .......................................... 74
5.2.1 Characteristics of immune cell infiltration ................................... 74
5.2.2 Interrelationships between different immune cell types ............... 76
5.2.3 Relationships between immune cell infiltration and
clinical and pathological variables ............................................... 77
5.2.4 Prognostic value ........................................................................... 79
5.3 Systemic inflammatory biomarkers in colorectal cancer ........................ 80
5.3.1 Serum MMP-8 .............................................................................. 80
5.3.2 Other markers ............................................................................... 80
6 Discussion
81
6.1 New methods for the evaluation of immune cell reaction ....................... 81
6.1.1 Computer-based immune cell counting ........................................ 81
6.1.2 CLR density .................................................................................. 83
6.2 Immune cell infiltration in colorectal cancer .......................................... 84
6.2.1 T cells in colorectal cancer ........................................................... 84
6.2.2 Dendritic cells in colorectal cancer............................................... 85
6.2.3 Colorectal cancer associated lymphoid reaction ........................... 85
6.2.4 Future perspectives ....................................................................... 86
6.3 Systemic inflammatory biomarkers in colorectal cancer ........................ 88
7 Conclusions
91
References
93
Original publications
123
16
1
Introduction
Colorectal cancer (CRC) is one of the most common malignancies and causes of
cancer deaths in the Western world (Siegel et al. 2013). TNM staging is used in
the prognostic classification (Sobin & Wittekind 2002). In patients operated on in
the 1990s, five-year overall survival was 65%, ranging from 90% in stage I to less
than 10 % in stage IV (O’Connell et al. 2004). However, molecular heterogeneity
of the disease warrants the search for additional, complementary prognostic
markers (Jass 2007b).
Over the past decade, the immune system has increasingly been
acknowledged as an important contributor to cancer pathogenesis (Hanahan &
Weinberg 2011, Schreiber et al. 2011). It has been shown that immune cells can
establish an anti-tumor immune response (Koebel et al. 2007, Shankaran et al.
2001), and accordingly, numerous studies have associated increased immune cell
infiltration in CRC with better disease outcome (Roxburgh & McMillan 2012).
Especially, T cell infiltration has been associated with stage-independent
prognostic value (Galon et al. 2006, Pagès et al. 2005), and there is an
international initiative to incorporate the quantification of tumor-infiltrating T
cells into cancer classification (Galon et al. 2012, 2014). However, accurate,
reproducible analysis methods, as well as better understanding of the
interrelationships between different inflammatory markers would be important in
order to establish a valuable prognostic and potentially predictive tool.
In addition to tumor-infiltrating immune cells, systemic inflammatory
biomarkers and hematological parameters have also been shown to be able to
predict survival in CRC (Roxburgh & McMillan 2010). Especially, the Glasgow
prognostic score (GPS), consisting of serum levels of C-reactive protein (CRP)
and albumin, has been found to have strong prognostic value in several
independent cohorts (McMillan 2013). However, no serum prognostic markers
are currently regularly used in clinical work (Sturgeon et al. 2008).
Serum markers that would facilitate early detection and diagnosis of CRC
would also be valuable. Matrix metalloproteinases (MMPs) form a family of zincdependent endoproteases participating in extracellular matrix (ECM) degradation.
Serum levels of MMP-9 and tissue inhibitor of metalloproteinases 1 (TIMP-1)
have been found to be increased in CRC and have been proposed as potential
markers to aid the diagnosis of CRC (Hurst et al. 2007, Mroczko et al. 2010).
MMP-8 is regarded as an important regulator of immune responses (Van Lint &
Libert 2006) thanks to its capability to cleave several inflammatory mediators,
17
including CXCL5, CXCL8, CXCL9, and CCL2 (Van Lint & Libert 2007).
However, its serum levels and potential function in CRC had not been studied.
The aims of this work were to develop and validate accurate and reproducible
methods for the analysis of immune cell infiltration in CRC and to enlighten the
significance of various immune cell types and inflammatory markers in CRC.
Specific points of interest were the applicability of a color layer separation based
image analysis method to counting immune cells in CRC (I), the
interrelationships between different inflammatory cell types within colorectal
tumors (II), the characteristics and the significance of colorectal cancer associated
lymphoid reaction (CLR) (III), and the value of serum MMP-8 in discriminating
the CRC patients from healthy controls (IV).
18
2
Review of the literature
2.1
Colorectal cancer epidemiology
2.1.1 Incidence
CRC is one of the most common malignancies and causes of cancer deaths in the
Western world (Siegel et al. 2013). In patients operated on in the 1990s, five-year
overall survival was 65% (O’Connell et al. 2004). In Finland, more than 2,800
new cases were diagnosed in 2011, and the incidence was third highest after
breast cancer and prostate cancer (Finnish Cancer Registry 2013). Lifetime risk of
CRC is about 5% in the population in industrialized countries (Siegel et al. 2013).
CRC is rare in people under 40 years of age, and most patients are over 70 years
of age at the time of the diagnosis (Siegel et al. 2013).
2.1.2 Risk factors
The majority of CRC is sporadic. The differences in the incidence between
countries around the world (Siegel et al. 2013) as well as immigrant studies
(Dunn 1975, Kune et al. 1986, Shimizu et al. 1987) suggest that environmental
factors account for the majority of the disease risk. Of the dietary factors, high
consumption of red meat (Larsson & Wolk 2006) and heavy alcohol use (Fedirko
et al. 2011) have convincingly been associated with an increased CRC risk,
whereas a high intake of dietary fiber has been associated with a reduced CRC
risk (Aune et al. 2011). Other known risk factors for CRC include smoking
(Raimondi et al. 2008), overweight (Larsson & Wolk 2007), low level of physical
activity (Samad et al. 2005), and inflammatory bowel diseases (IBDs) (Eaden et
al. 2001, von Roon et al. 2007). The use of non-steroidal anti-inflammatory drugs
(NSAIDs) decreases the CRC risk (Din et al. 2010).
About 5% of CRCs arise in patients with a characterized germline mutation
(Kwak & Chung 2007), although twin studies have suggested that genetic factors
could account for up to 35% of the CRC risk (Lichtenstein et al. 2000). The most
common of the hereditary colorectal cancer syndromes are familial adenomatous
polyposis (FAP), with a germline mutation in adenomatous polyposis coli (APC)
tumor suppressor gene (Groden et al. 1991, Nishisho et al. 1991), and Lynch
syndrome, with a germline mutation in one of the mismatch repair (MMR)
19
systems of deoxyribonucleicacid (DNA) (Bronner et al. 1994, Fishel et al. 1993,
Leach et al. 1993, Papadopoulos et al. 1994).
2.2
Colorectal cancer classification
CRC is defined by the invasion of tumor cells through muscularis mucosae to
submucosa (Hamilton et al. 2010). Adenocarcinomas, originating from the
glandular epithelium, account for the vast majority of CRC (Hamilton et al. 2010,
Kang et al. 2007). Several histopathological subtypes of colorectal carcinomas
can be distinguished (Table 1). Other malignant colorectal tumors include
neuroendocrine tumors, gastrointestinal stromal tumors (GISTs) and lymphomas
(Hamilton et al. 2010).
Table 1. Histopathological subtypes of colorectal carcinoma.
Classification
Designating features
Adenocarcinoma, not otherwise
Glandular differentiation
specified
Mucinous adenocarcinoma
> 50% of the lesion is composed of extracellular mucin
Signet-ring cell carcinoma
Presence of > 50% of tumor cells with prominent intracytoplasmic
mucin
Serrated adenocarcinoma
Epithelial serrations, low nucleus-to-cytoplasm ratio, clear or
eosinophilic cytoplasm
Micropapillary adenocarcinoma
Tumor cells growing in papillary structures, which lack
fibrovascular cores
Medullary carcinoma
Sheets of malignant cells with vesicular nuclei, prominent nucleoli,
and abundant eosinophilic cytoplasm; prominent infiltration by
intraepithelial lymphocytes
Adenosquamous carcinoma
Areas of glandular and squamous differentiation
Undifferentiated carcinoma
Lack of morphological, immunohistochemical, and molecular
biology evidence of differentiation beyond that of an epithelial
tumor
Classification and designating features adapted from Hamilton et al. 2010.
2.3
Colorectal cancer pathogenesis
The hallmarks of cancer include sustaining proliferative signaling, evading
growth suppressors, activating invasion and metastasis, enabling replicative
immortality, inducing angiogenesis, resisting cell death, deregulating cellular
energetics, and avoiding immune destruction (Hanahan & Weinberg 2011).
20
Colorectal tumors acquire these traits in the multi-step process of carcinogenesis
(Fearon & Vogelstein 1990). The importance of alterations in oncogenes and
tumor suppressor genes was evident by the 1990s (Vogelstein et al. 1988), while
the significance of epigenetic changes was highlighted in the late 1990s and early
2000s (Herman et al. 1998, Jones & Laird 1999). The research in the past decade
has further highlighted the significance of tumor-host interactions during the
process of carcinogenesis (Hanahan & Weinberg 2011).
2.3.1 Genomic and epigenetic mechanisms
Oncogenes and tumor suppressor genes
Oncogenes are defined as genes that promote tumor initiation or progression
(Croce 2008). The human genome contains several proto-oncogenes that can be
transformed into oncogenes by point mutations, chromosome translocations or
gene amplification, which cause an increase in their expression or an alteration in
the structure of their protein product (Croce 2008, Nishimura & Sekiya 1987).
The products of oncogenes can be classified into six groups (Table 2).
Table 2. Classification of oncogenes.
Classification
Function
Transcription factor
Controls ribonucleic acid (RNA) synthesis
Chromatin remodeler
Controls epigenetic alterations of DNA, thus
modulating RNA synthesis
Growth factor
Stimulates cell growth
Growth factor receptor
Mediates growth factor signaling
Signal transducer
Transmits an extracellular signal into a functional
change within the cell
Apoptosis regulator
Controls programmed cell death
Classification adapted from Croce 2008.
While oncogenes mostly increase tumor cell proliferation, the products of tumor
suppressor genes act to inhibit cell proliferation (Weinberg 1991). In addition to
‘gatekeeper’ genes, forming a network of proteins that prevent uncontrolled
growth, the family of tumor suppressor genes includes ‘caretaker’ genes,
maintaining the integrity of the genome (Kinzler & Vogelstein 1997). Usually,
one functioning allele of a tumor suppressor gene is enough to sustain its normal
function, and thus, inactivation of both alleles is required for loss-of-function,
21
which is known as the ‘two-hit hypothesis’ (Knudson 1971). Table 3 presents a
group of oncogenes and tumor suppressor genes commonly associated with CRC
pathogenesis.
Table 3. Oncogenes and tumor suppressor genes commonly associated with CRC
pathogenesis.
Gene
Significance of the gene product
References
Activation of MAPK-ERK signal
Bos et al. 1987
Oncogenes
KRAS
transduction, inhibition of apoptosis,
promotion of cell survival
BRAF
Activation of MAPK-ERK signal
Davies et al. 2002
transduction, inhibition of apoptosis,
promotion of cell survival
β-catenin
Activation of Wnt signaling that regulates
Morin et al. 1997
cell proliferation and invasion
Tumor suppressor genes
APC
Inhibition of Wnt signaling via degrading β- Morin et al. 1997
catenin
TP53
Cell cycle regulation
Baker et al. 1990
TGFβR2
Receptor that is responsible for TGFβ
Markowitz et al. 1995
pathway signaling mediating growth arrest
and apoptosis
SMAD2 and -4
Important component of TGFβ pathway
Thiagalingam et al. 1996
signaling mediating growth arrest and
apoptosis
MLH1, MSH2, and MLH6 Enzymes contributing to DNA mismatch
Fishel et al. 1993, Herman et
repair and maintaining the stability of DNA al. 1998, Miyaki et al. 1997,
microsatellites
Papadopoulos et al. 1994,
Strand et al. 1993
Modified from Markowitz & Bertagnolli 2009.
Genomic and epigenetic instability
Genomic and epigenetic instabilities exist in human cancers, enabling the cancer
cells to acquire a sufficient amount of genetic changes to generate a malignant
tumor (Issa 2004, Lengauer et al. 1998, Loeb 1991). Chromosomal instability
(CIN), defined as cell-to-cell variability of gain or loss of whole chromosomes or
fractions of chromosomes (Geigl et al. 2008), is the most prevalent form of
genomic instabilities in CRC, present in the majority of cases (Lengauer et al.
22
1997). In about 15% of CRC, the mismatch repair (MMR) system of DNA is
deficient, resulting in microsatellite instability (MSI) (Boland & Goel 2010,
Boland et al. 1998). CIN and MSI can be detected in CRC precursor lesions,
adenomas, indicating that genomic destabilization is an early step in CRC
development (Shih et al. 2001, Stoler et al. 1999).
The mechanisms underlying CIN include defects in chromosome cohesion,
mitotic checkpoint function, centrosome copy number, and cell-cycle regulation
(Thompson et al. 2010). Aneuploidy is an effective way to inactivate the
functioning allele of tumor suppressor genes (loss of heterozygosity; LOH), such
as APC and TP53, and is often present in chromosomally unstable CRCs (Fearon
& Vogelstein 1990).
DNA MMR is a process that has been highly conserved during evolution, and
comprises homologs of bacterial MutS (MSH) and MutL (MLH) enzymes. It is
responsible of strand-specific recognition and correction of mispaired bases that
arise during DNA replication (Modrich & Lahue 1996). A defective MMR system
results in microsatellite instability (MSI), defined as insertions or deletions in
DNA microsatellite repeat sequences (Boland et al. 1998, Strand et al. 1993,
Umar et al. 1994). MSI is further classified into MSI-high (MSI-H) with
alterations in 30% or more of the studied markers and MSI-low (MSI-L) with
alterations in less than 30% of the studied markers (Boland et al. 1998). CRCs
with MSI are characterized by mutations in specific tumor suppressor genes
containing microsatellites, e.g., TGFβR2 (Kim et al. 2013).
Lynch syndrome is an autosomal dominant disease with a germline mutation
in MSH2 or MLH1 (Bronner et al. 1994, Fishel et al. 1993, Leach et al. 1993,
Papadopoulos et al. 1994), or less frequently, in other MMR enzymes such as
MSH6 (Miyaki et al. 1997). MMR deficiency arises according to Knudson’s twohit hypothesis (Knudson 1971), so that the loss of wild-type allele is required to
cause a phenotypic effect (Hemminki et al. 1994). The average age of CRC onset
in Lynch syndrome is about 45 years (Lynch et al. 2008). Lynch syndrome
represents less than 5% of CRC (Kwak & Chung 2007), while the majority of
MMR deficiency and MSI in CRC results from epigenetic modifications (Herman
et al. 1998, Kane et al. 1997).
DNA methylation is a post-replication modification, which is typically found
in cytosines that are part of the dinucleotide sequence CpG (Jaenisch & Bird
2003). About half of all genes have a CpG-rich promoter but most of the promoter
CpG islands are normally unmethylated (Issa 2004). However, a group of CRCs
present with a CpG island methylator phenotype (CIMP) (Toyota et al. 1999),
23
resulting in inactivation of specific caretaker and gatekeeper genes, often
including MLH1 (Herman et al. 1998, Kane et al. 1997, Veigl et al. 1998). Thus,
in sporadic CRC, epigenetic instability and MSI are often closely connected (Goel
et al. 2007, Weisenberger et al. 2006). Like MSI, CIMP can also be classified into
CIMP-low (CIMP-L) and CIMP-high (CIMP-H) according to its extent (Ogino et
al. 2006).
2.3.2 Morphological developmental pathways
Several models have been developed to mirror the development of CRC (Fearon
& Vogelstein 1990, Mäkinen 2007). A study that analyzed the sequences of
20,857 transcripts from 18,191 human genes in 11 CRCs found that each
individual cancer contains about 80 amino acid-altering mutations that are absent
in normal cells (Wood et al. 2007). It is not possible that such a high number of
genetic changes occur in the same order in each tumor. Indeed, over the past
decades, it has become evident that CRCs form a morphologically and genetically
heterogeneous group that develops via multiple pathways (Jass 2007a).
The form of genomic and epigenetic instability (CIN, MSI, and CIMP) the
tumor cells possess is considered one of the most important factors for the
categorization of CRCs, since different forms of genetic instability are
accompanied by specific genetic changes that are rare in other types (Goel et al.
2007, Kim et al. 2013). One of the most established classifications
compartmentalizes CRCs based on the presence of MSI (or microsatellite
stability, MSS), CIMP, and BRAF and KRAS mutations: (1) CIMP-H/MSIH/BRAF mutation; (2) CIMP-H/MSI-L or MSS/BRAF mutation; (3) CIMPL/MSS or MSI-L/KRAS mutation; (4) CIMP-neg/MSS; and (5) CIMP-neg/MSIH (Jass 2007a). The genetic properties of the tumors are also reflected by their
morphology.
Precursor lesions
The majority of CRCs arise from adenomas that are premalignant tumors of
epithelial tissue with glandular origin (Fearon & Vogelstein 1990, Jackman &
Mayo 1951, Muto et al. 1975). Macroscopically, the vast majority of adenomas
have been considered to be polypoid, but studies utilizing dyes such as indigo
carmine have indicated that about third of adenomas may be flat or depressed
(Rembacken et al. 2000, Saitoh et al. 2001). Microscopically, traditional
24
adenomas can be grouped into tubular, villous, and tubulovillous (Hamilton et al.
2010, Shinya & Wolff 1979). The designating feature present in all traditional
adenomas is dysplasia of the epithelium which can be classified into low-grade
and high-grade (Hamilton et al. 2010).
Serrated polyps form a group of lesions characterized by a sawtooth-like
infolding of the surface and crypt epithelium (Table 4) (Mäkinen 2007, Snover et
al. 2010). The group includes lesions with variable malignant potential, the best
characterized of which are hyperplastic polyp (HP), sessile serrated adenoma
(SSA), and traditional serrated adenoma (TSA). HPs are the most common
serrated lesions, characterized by serrations confined to the upper parts of the
crypts (Snover et al. 2010). Small, distal HPs are considered innocuous lesions,
but large ones arising in the proximal colon may resemble SSAs and harbor
malignant potential (Goldstein et al. 2003, Lin et al. 2005). HPs and SSAs do not
generally show dysplasia, although SSAs may develop it with progression
towards carcinoma (Lash et al. 2010). Conversely, TSAs often present with
dysplasia (Torlakovic et al. 2008).
Table 4. Benign and premalignant epithelial tumors of the colon and rectum.
Classification
Designating features
Traditional adenomas
Presence of dysplastic epithelium
Tubular adenoma
Tubular glands
Villous adenoma
Leaf- or fingerlike projections of the epithelium overlying lamina
propria
Tubulovillous adenoma
Serrated polyps
Hyperplastic polyp
Mixture of tubular and villous components; villous component 25–75%
Sawtooth-like infolding of the surface and crypt epithelium
Serrations confined to the upper parts of the crypts, no cytological
atypia
Sessile serrated adenoma
Distortion of the normal crypt architecture: dilated and T- or L-shaped
crypts, alterations in the position of proliferative zone; vesicular nuclei
Traditional serrated adenoma Ectopic crypt formation (ECF); cytological atypia
Classification and designating features adapted from Hamilton et al. 2010, Mäkinen 2007, Torlakovic et
al. 2008, Snover et al. 2010.
Adenoma-carcinoma pathway
Vogelstein and co-workers were first to describe a model of genetic changes
occurring in colorectal carcinogenesis (Fearon & Vogelstein 1990, Vogelstein et
al. 1988). Although later studies have indicated that CRC is a heterogeneous
25
disease and there is a need for alternative developmental pathways (Jass 2007a),
the model still represents a valuable portrayal of the typical development of the
most common form of sporadic CRCs (CIMP-neg/MSS).
One of the first events in the development of CIMP-neg/MSS CRCs is
usually the inactivation of APC tumor suppressor that is present in the majority of
sporadic CRCs and tubular adenomas (Fig. 1) (Powell et al. 1992). It is
considered to have an important role in the initiation of CIN (Fodde et al. 2001).
Also the activation of KRAS oncogene mostly occurs in early adenomas
(Vogelstein et al. 1988), contributing to the activation of multiple intracellular
signal pathways, including the MAPK/ERK pathway. Chromosome 18q loss,
generally manifesting as the third step after APC loss and KRAS activation, leads
to the losses of SMAD4 and SMAD2 and therefore to the abolishment of TGF-β
signaling (Hahn et al. 1996, Thiagalingam et al. 1996). Mutations in TP53 tumor
suppressor gene are common in diverse types of human cancers (Hollstein et al.
1991). In colorectal carcinogenesis, the inactivation of TP53 generally occurs as a
late event (Baker et al. 1990).
Normal
epithelium
Early
adenoma
APC
inactivation
KRAS
mutation
Carcinoma
Late
adenoma
18q LOH
TP53
inactivation
Progressive chromosomal instability
Fig. 1. Genetic changes commonly associated with the pathogenesis of CRC with
chromosomal instability. Modified from Fearon 2011, Kinzler & Vogelstein 1996.
Serrated pathway
During the past fifteen years, the malignant potential of serrated polyps has been
established (Goldstein et al. 2003, Mäkinen et al. 2001). The serrated route from
SSA to serrated adenocarcinoma is characterized by CIMP and MSI (Fig. 2)
(Mäkinen 2007), and the majority of sporadic CRCs with MSI-H are considered
to follow it (Jass 2007a). An early change in the route, present in more than 70%
of SSAs (Spring et al. 2006), is BRAF mutation, most commonly BRAF V600E,
26
which results in a constitutively activated enzyme and the activation of the
mitogen-activated protein kinases/extracellular signal-regulated kinases
(MAP/ERK) signaling pathway. Conversely, TSAs frequently carry KRAS
mutations and show MSS or MSI-L (O’Brien et al. 2006). The position of TSA in
the serrated pathway of CRC is controversial. However, it has recently been
shown that about 50% of endoscopically removed TSAs are accompanied by
surrounding lesions with features of HP or SSA, indicating that a proportion of
TSAs may develop from these lesions (Kim et al. 2013).
Normal
epithelium
SSA
BRAF
mutation
Serrated
carcinoma
SSA with
dysplasia
MLH1
inactivation
TGFβRII
inactivation
Progressive DNA methylation
Progressive microsatellite instability
Fig. 2. Genetic changes commonly associated with the pathogenesis of serrated
colorectal adenocarcinoma. Modified from Mäkinen 2007, Snover 2011.
2.3.3 Intratumor heterogeneity and cancer stem cells
Intratumor heterogeneity is a phenomenon characterized by regions and cells with
diverse genetic and epigenetic changes, morphology, and behavior within a single
tumor and its metastases (Almendro et al. 2013). The phenomenon was
highlighted by a recent study utilizing whole-exome sequencing of biopsy
samples taken from different tumor areas and metastases from patients with renal
cell carcinoma, which showed that 63–69% of somatic mutations were not
detectable across every tumor region (Gerlinger et al. 2012). Accordingly, also
CRC has been shown to present with heterogeneity within the primary tumors and
between primary tumors and metastases in, e.g., activating mutations of KRAS
(Baldus et al. 2010). Intratumor heterogeneity may represent a challenge for
personalized medicine and biomarker development.
Accumulating evidence suggests that not all tumor cells possess equal ability
to proliferate. Cancer stem cells were defined as “cells within a tumor that possess
27
the capacity to self-renew and to cause the heterogeneous lineages of cancer cells
that comprise the tumor” by an American Association for Cancer Research
(AACR) workshop (Clarke et al. 2006). The first malignancy in which cells with
stem-cell-like characteristics were detected was acute myeloid leukemia (Bonnet
& Dick 1997).
In a tumor model of nonobese diabetic/severe combined immunodeficiency
(NOD/SCID) mice xenografted with human colon cancer cells (O’Brien et al.
2007), it was shown that there was only one cancer cell in 5.7×104 unfractionated
tumor cells capable of tumor initiation. All of these cells were CD133 + but only
one CD133+ cell in 262 was capable of tumor initiation. Xenografts generated
from both tumor bulk and CD133+ colon cancer cells resembled the original
patient tumor. This finding suggests that also CRC cells are hierarchically
organized and a proportion of CD133+ cells in the tumor represent CRC stem
cells. That would hold important implications for therapeutic strategies that could
target the cancer-initiating cells (Kreso et al. 2014). However, it is still unclear
whether there is interconversion between cells capable and incapable of tumor
initiation, which would decrease the importance of targeting these cells with the
treatments. Moreover, there is a need for more specific markers for CRC stem
cells than CD133 in order to be able to further characterize their genetic
properties, function, and clinical significance.
2.3.4 Invasion and metastasis
The presence of CRC is histologically defined by the invasion through the
muscularis mucosae into the submucosa (Hamilton et al. 2010). The patterns of
tumor cell invasion can be classified into individual-cell migration, multicellular
migration, and expansive growth without migration, which can be further divided
into subcategories (Table 5, Fig. 3). The migration mechanisms of an individual
cell are similar to those occurring in normal non-neoplastic cells in physiological
conditions, including cell polarization and protrusion, adhesion formation, actinand myosin-based contraction, and rear detachment (Lauffenburger & Horwitz
1996, Ridley et al. 2003). Different patterns of invasion are guided by the
expression of cell-matrix adhesion molecules (e.g., integrins), cell-cell adhesion
molecules (e.g., cadherins), matrix-degrading enzymes (e.g., MMPs), and cell-cell
communication molecules (e.g., chemokines) (Friedl et al. 2012).
28
Table 5. Patterns of cancer cell invasion.
Pattern of invasion
Designating features
Individual-cell migration
Tumor cells invading as single cells; absence of cell-cell
adhesion (e.g., down-regulation of cadherin expression)
Ameboid single-cell migration
Low levels of cell-matrix adhesion (e.g., down-regulation of
integrin expression)
Mesenchymal single-cell migration
Multicellular migration
High levels of cell-matrix adhesion
Tumor cells invading as cell strands, sheets, files or
clusters
Multicellular streaming
Individual cells moving one after another using the same
path within the tissue (e.g., guided by a chemotactic
gradient)
Collective cell migration
Migration as a cohesive, multicellular group; high levels of
cell-cell adhesion
Expansive growth without migration
Proliferating cell masses with intact cell-cell junctions,
leading to outward pushing of surrounding tissue structures
Classification and designating features adapted from Friedl & Alexander 2011, Friedl et al. 2012.
Individual cell
migration
Ameboid
Multicellular
streaming
Collective cell
migration
Expansive growth
without migration
Mesenchymal
Fig. 3. Patterns of cancer cell invasion. Arrows indicate the direction of invasion.
Modified from Friedl & Alexander 2011, Friedl et al. 2012.
Each tumor frequently presents with multiple patterns of invasion (Friedl et al.
2012). About one in four CRCs shows infiltrative tumor border configuration,
characterized by finger-like protrusions of the invasive front and representing
collective cell migration as strands, while the rest show a rather expansive tumor
border configuration (Jass et al. 1996). At high magnification, tumor buds —
defined as isolated tumor cells or clusters of two to four cells at the invasive
margin of the tumor — can be observed in the majority of CRCs (Hase et al.
29
1993, Ueno et al. 2002), and cytoplasmic pseudofragments — i.e., dendritic
processes of the budding cells — are present in half of the patients with highgrade budding, (Shinto et al. 2005). Tumor budding is considered to represent
weakening of cell-cell adhesions and it often includes individual cell migration
(Natalwala et al. 2008). Accordingly, it has been associated with decreased
expression of the cell adhesion molecule E-cadherin (Zlobec et al. 2007a).
CRC commonly uses lymphatic vessels (Minsky et al. 1989) and blood
vessels (Krasna et al. 1988) as routes of metastasis. The epithelial to
mesenchymal transition (EMT) and single cell migration may enhance the
efficacy of metastasis (Christiansen & Rajasekaran 2006). However, clusters of
circulating tumor cells can be observed in CRC (Molnar et al. 2001) and other
carcinomas including lung cancer (Hou et al. 2011), suggesting that collective
vascular invasion may also take place. The phenotype of circulating tumor cells
may influence the site of metastasis, as proposed by a human colon cancer
xenograft mouse model that reported CD110+ cells being more likely to form liver
metastases and CUB domain-containing protein 1 expressing cells being more
likely to form lung metastases (Gao et al. 2013).
Matrix metalloproteinases
MMPs are a family of structurally related but genetically distinct zinc-dependent
endoproteases participating in ECM degradation and thus facilitating tumor
invasion (Stetler-Stevenson et al. 1993). MMP functions are regulated at the
levels of gene expression, zymogen activation, interaction with ECM, and
endogenous regulatory proteins, most notably TIMPs (Visse & Nagase 2003).
CRC shows increased expression of several MMPs including MMP-1, -3, -7, -9, 10, -11, -12, and -14 (Asano et al. 2008), supporting their relevance in CRC
pathogenesis.
In addition to ECM degradation and tumor invasion, MMPs may also
contribute to other functions in CRC, since in the past two decades, it has been
established that some of the MMPs also participate in the regulation of growth
signaling, apoptosis, angiogenesis, and immune responses (Egeblad & Werb
2002). Especially, MMP-8 has been shown to have an important role in
controlling immune responses through its capability to cleave inflammatory
mediators, including CXCL5, CXCL8, CXCL9, and CCL2 (Van Lint & Libert
2007). Knockout mice models have also associated MMP-8 with a protective role
30
against cancer (Balbin et al. 2003, Korpi et al. 2008). However, little is known of
the function of MMP-8 in CRC.
2.3.5 Immune system and inflammation
In the past decade, tumor-host interactions have increasingly been acknowledged
as important players in cancer pathogenesis (Hanahan & Weinberg 2011). In
addition to tumor cells, tumors comprise, e.g., fibroblasts, blood vessel
endothelium, muscle cells, and immune cells (Tlsty & Coussens 2006). It has
been established that the immune system can elicit an anti-tumor immune
response (Koebel et al. 2007, Shankaran et al. 2001), and accordingly, numerous
studies have associated increased immune cell infiltration in CRC with better
disease outcome (Roxburgh & McMillan 2012). However, certain patterns of
inflammation can also promote the development as well as the progression of
cancer (Mantovani et al. 2008).
The basics of the immune system function
The immune system is an interacting network of organs, tissues, cells, and cell
products that detects, repels, and eradicates pathogens and foreign molecules
(Parkin & Cohen 2001). The immune system can be classified into the innate and
adaptive immune systems, of which innate immunity mediates immediate, nonspecific immune responses by, e.g., granulocytes and macrophages, while
adaptive immunity mediates antigen-specific immune responses by lymphocytes
(Medzhitov & Janeway 1997). The functions associated with some of the major
immune cell types are presented in Table 6.
31
Table 6. Functions associated with some of the major immune cell types.
Cell type
Functions
References
Lymphocytes
T cells
T helper cells
Cell-mediated adaptive immunity
Recruitment of other immune cells; activation
Zhu & Paul 2010
of cytotoxic T cells and macrophages; help of
maturation of B cells into plasma cells
Cytotoxic T cells
B cells
Cytolytic destruction of target cells
Barry & Bleackley 2002
Humoral, antibody-mediated immunity
Pieper et al. 2013
Cytolytic destruction of target cells,
Kolaczkowska & Kubes 2013
Granulocytes
Neutrophils
phagocytosis, and the secretion of
proinflammatory mediators in the acute
inflammatory responses
Eosinophils
Cytolytic destruction of target cells and the
Rothenberg & Hogan 2006
secretion of proinflammatory mediators in
parasitic infections and allergic reactions
Basophils
Secretion of proinflammatory mediators in
Min 2008
allergic reactions, as well as in pathogen
defense
Macrophages
Phagocytosis, antigen presentation, and the
Murray & Wynn 2011
secretion of inflammatory mediators to recruit
other immune cells
Dendritic cells
Antigen capture and presentation, T cell
Banchereau et al. 2000
activation, and the secretion of inflammatory
mediators to recruit other immune cells
Mast cells
Secretion of proinflammatory mediators in
Abraham & St John 2010
allergic reactions as well as in pathogen
defense
The innate and adaptive immune systems are highly integrated, and the innate
response generally precedes and is essential for the adaptive response (Medzhitov
& Janeway 1997). Acute inflammation is usually the initial response to infectious
agents and tissue injury (Medzhitov 2008), and it is characterized by tissue
infiltration of neutrophils and other cells of innate immunity. If the acute
inflammatory response fails to eradicate the pathogen or if the tissue damage is
persistent, chronic inflammatory responses arise, characterized by increased tissue
infiltration of macrophages and lymphocytes (Medzhitov 2008), as well as the
generation of tertiary lymphoid tissue, i.e., lymphoid follicles, where several
processes enhancing the adaptive immunity can take place, including T-cell
32
priming, clonal expansion, affinity maturation, and immunoglobulin class
switching (Table 7) (Aloisi & Pujol-Borrell 2006). These processes also occur in
the secondary lymphoid tissue, i.e., lymph nodes and spleen (Aloisi & PujolBorrell 2006, Pieper et al. 2013). To regulate the immune responses, the immune
cells secrete cytokines that comprise a broad category of small proteins
contributing to cell growth, differentiation, and activation (Commins et al. 2010).
Table 7. Important events in the generation of adaptive immune responses.
Event
Definition
T cell priming
A process that takes place when a specific antigen is presented for
the first time to a naïve T lymphocyte, causing it to differentiate into
an effector cell (e.g., Th cell or cytotoxic T cell) or a memory cell
Antigen presentation
A process in which DCs, macrophages, and other immune cell types
display the T cells an antigen to enable its recognition
Clonal expansion
A process in which primed lymphocytes proliferate and amplify their
population
B cell affinity maturation
A process by which B cells produce antibodies with increased
affinity for antigen through somatic hypermutation and clonal
selection
Somatic hypermutation
A process where point mutations accumulate in the variable region
genes of immunoglobulin heavy and light chains genes, leading to
diversity in the antibody repertoire.
Clonal selection
A process in which only the B cells with the highest affinities for
antigen are selected to survive.
Immunoglobulin class switching
A process in which a B cell changes its antibody production from
one class to another, e.g., from IgM to IgG
Definitions adapted from Aloisi & Pujol-Borrell 2006, Pieper et al. 2013.
Especially, CD4+ helper T cells (Th cells) have critical roles in the adaptive
immunity, contributing to the recruitment of other immune cell types, to the
activation of cytotoxic T cells and macrophages, and to the maturation of B cells
into plasma cells (Zhu & Paul 2010). They can be categorized according to their
cytokine production as well as transcription factor expression. Understanding on
the functional properties of Th cells has improved in the recent decade, leading to
the discovery of new cell lineages (Zhu & Paul 2010). The best characterized four
Th cell lineages are presented in Table 8, and other proposed lineages include Th3
cells (Weiner 2001), Th9 cells (Schlapbach et al. 2014), and follicular Th cells
(Cannons et al. 2013).
33
+
Table 8. Four best characterized subsets of CD4 Th cells.
Th cell subset
Characteristic transcription
Cytokines critical for
factor
induction
Cytokine products
Th1
T-bet
IL-12 + IFNγ
IFNγ
Th2
GATA3
IL-4 + IL-2, IL7, TSLP
IL-4, IL-5, IL-10, IL-13
Th17
RORγt
TGFβ + IL6, IL-21, IL-23
IL-17a, IL-17f, IL-21, IL-22
TReg
FoxP3
TGFβ + IL2
TGFβ
Definitions adapted from Zhu & Paul 2010.
Immunosurveillance
Already in the early 1900s, it was suggested that the immune system can suppress
tumor development (Ehrlich 1909). However, contemporary methodology did not
allow to experimentally test the suggestion and it took more than fifty years until
the hypothesis of immunosurveillance was established, stating that immune cells
can recognize and eliminate nascent transformed cells (Burnet 1970). Animal
models were used in testing the hypothesis but no difference was found in
spontaneous or Methyl cyanoacrylate (MCA) induced cancer development
between athymic mice and controls (Rygaard & Povlsen 1974, Stutman 1974,
1979), implying that the immunosurveillance hypothesis was incorrect. However,
it is now known that athymic mice produce low amounts of T cells (Ikehara et al.
1984), not being completely immunodeficient.
The immunosurveillance hypothesis was again reinforced in consequence of
the development of knockout mice models in the late 1990s and early 2000s,
allowing the examination of the significance of individual genes in cancer. These
models confirmed that several strains of mice lacking specific components of the
immune system are susceptible to both chemically induced and spontaneous
carcinogenesis. These components, concluded to contribute to cancer
immunosurveillance, include interferon-γ (IFN-γ) and perforin that are important
in the function of cytotoxic T cells (Street et al. 2001, 2002) and recombinationactivating gene 2 (RAG-2) that is essential for the generation of mature B and T
lymphocytes (Shankaran et al. 2001).
Also several pieces of evidence from human studies support the concept of
immunosurveillance. First, the use of immunosuppressive drugs after organ
transplantation has been shown to increase cancer risk (Pfeiffer et al. 2011). For
example, Nordic kidney transplantation patients have a more than three times
higher risk for CRC relative to the general population (Birkeland et al. 1995).
34
Second, intensive immune cell infiltration is associated with improved survival in
CRC (Roxburgh & McMillan 2012), as well as several other solid tumors
(Fridman et al. 2012). Third, circulating T cells specific for tumor-associated
antigens (TAAs) have been found in patients with different solid tumors,
including CRC (Nagorsen et al. 2000) and melanoma (Lee et al. 1999).
Immunoediting
The immunoediting hypothesis was established in the early 2000s to complement
the limitations of the immunosurveillance hypothesis (Dunn et al. 2002). It
acknowledges the Darwinian selection pressure produced by the immune system
trying to eliminate the tumor cells. Moreover, the events leading to tumor
progression are further elucidated.
The foundation of the hypothesis was established with experiments with
RAG-2 knockout mice (Shankaran et al. 2001). The researchers chemically
induced sarcomas in the RAG2−/− mice and wild-type mice. The tumors from both
RAG2−/− mice and wild type mice grew progressively when transplanted into
RAG2−/− mice. Instead, wild-type mice rejected eight of twenty of the tumors
derived form RAG2−/− mice but none of the tumors from wild-type mice. This
finding indicated that the tumors originating in RAG2−/− mice were more
immunogenic, suggesting that the immune system shapes the properties of the
cancer cells.
According to the immunoediting theory, the interactions between tumor and
host can be classified into three phases: elimination, equilibrium, and escape
(Schreiber et al. 2011).
Elimination. It is thought that the immune system can eliminate most
transformed cells before the development of a clinically detectable tumor
(Schreiber et al. 2011). The mechanisms of immune system activation in cancer
are under research. The malignant colorectal tumors contain about 80 amino acidaltering mutations that are absent in normal cells (Wood et al. 2007), potentially
leading to the expression of TAAs, i.e., proteins that the immune system can
recognize as altered. Moreover, as tumor cells proliferate, dying cells may release
damage-associated molecular patterns (DAMPs) (Rakoff-Nahoum & Medzhitov
2009), potentially acting as danger signals, inducing the activation of immune
system (Matzinger 1994).
Equilibrium. Equilibrium describes the phase in which the immune system
can restrict the tumor growth but, in the process, selects tumor cell variants with
35
increasing capabilities to survive from immune destruction. In addition to the
earlier described hallmark study of Shankaran et al. (2001), the existence of an
equilibrium phase has been more directly shown in a model of immunocompetent
mice (Koebel et al. 2007). The mice were first injected with MCA. At 200 days
after the injection, fifteen of nineteen tumor-free mice were treated weekly with
anti-CD4/-CD8/-IFNγ antibodies. After this depletion of the immune system,
tumors swiftly appeared at the site of the MCA injection in half of the mice,
indicating that the immune system was maintaining occult cancer in an
equilibrium state.
Also clinical evidence supports the existence of an equilibrium state, since
there are reports of organ transplantation patients developing cancer in the
transplanted organ soon after the transplantation. For example, two kidney
transplantation patients — having received kidneys from the same donor who had
had melanoma 16 years previously but was thought to be cured — developed
metastatic melanoma in one to two years after transplantation without evidence of
primary cutaneous tumor (MacKie et al. 2003). Moreover, recurrences of cancer
can be seen after years of asymptomatic phase (Stearns et al. 2007), and
colorectal adenomas, when left unresected, may spontaneously regress in size
(Hofstad et al. 1996).
Escape. As a consequence of constant immune selection pressure, the tumor
cells develop traits that help them to escape from immune control (Shankaran et
al. 2001). Accordingly, advanced CRC shows lower numbers of tumor-infiltrating
inflammatory cells (Klintrup et al. 2005). Moreover, the patients with metastatic
tumors often present with increased immunological tolerance towards TAAs, the
mechanisms of which may include ignorance (low antigen concentration or
ineffective antigen presentation), anergy (lack of costimulatory signals to the
lymphocytes), and active, cell-mediated immunosuppression by, e.g., regulatory T
cells (Zou 2005). In CRC, the specific mechanisms of tumor escape from immune
control are not well-defined but may include, e.g., the induction of T cell death
through the release of proapoptotic microvesicles (Huber et al. 2005) and the
downregulation of major histocompatibility complex (MHC) class I expression
(Simpson et al. 2010).
Tumor promoting inflammation
Certain patterns of inflammation can promote the development as well as the
progression of cancer (Mantovani et al. 2008). Convincing evidence links IBDs
36
— ulcerative colitis (Eaden et al. 2001) and Crohn’s disease (von Roon et al.
2007) — with increased CRC risk, and therefore, regular endoscopic surveillance
is recommended for IBD patients (Itzkowitz & Present 2005). Conversely, the use
of non-steroidal anti-inflammatory drugs (NSAIDs) decreases the CRC risk (Din
et al. 2010).
The distinctive difference between the inflammatory reaction observed in
IBD and the anti-tumor immune response is the target of the immune attack. In
cancer, the immune response is targeted towards the transformed cells, as
indicated by, e.g., the presence of circulating T cells specific for TAAs (Lee et al.
1999, Nagorsen et al. 2000), while in IBDs it has been suggested to result from an
inappropriate inflammatory response against intestinal microbes (Abraham & Cho
2009).
With their potential to cause DNA mutations, reactive oxygen species (ROS)
is considered a contributor to increased cancer risk related to inflammation
(Wiseman & Halliwell 1996). Recent studies have also connected inflammation
with increased proliferative signaling and angiogenesis, as well as the inhibition
of apoptosis (Mantovani et al. 2008). More specifically, inflammatory cells are
considered important sources of cytokines and chemokines (e.g., IL-1β),
proteinases (e.g., MMPs), and growth factors (e.g., VEGF) that favor tumor
growth (Hanahan & Coussens 2012). The signaling pathways associated with
cancer-promoting inflammation function downstream of oncogenic mutations
(Mantovani et al. 2008).
One of the mediators of cancer-promoting inflammation is considered to be
the activation of transcription factor nuclear factor-κB (NF-κB) signaling,
downstream from, e.g., Toll-like receptor (TLR) – MyD88 pathway (RakoffNahoum & Medzhitov 2007) and the pathways of inflammatory cytokines TNF-α
and IL-1β (Gilmore 2006). Utilizing conditional knockout mice, it has been
established that inactivation of NF-κB signaling attenuates tumor formation in
inflammation-associated hepatocellular cancer (Pikarsky et al. 2004) and colitisassociated cancer (Greten et al. 2004). These findings have been attributed to the
ability of NF-κB to increase the synthesis of pro-survival and pro-proliferative
molecules, proinflammatory cytokines, adhesion molecules, and ROS (BenNeriah & Karin 2011).
Like NF-κB, signal transducer and activator of transcription 3 (STAT3) is a
downstream mediator of numerous cytokines, as well as oncogenes (Yu et al.
2009). It has been shown to increase tumor cell survival, invasion, and
proliferation (Yu et al. 2009), and mice with STAT3 conditional deletion in
37
enterocytes are less susceptible to tumors in a colitis-associated cancer model
(Grivennikov et al. 2009).
To summarize the potential role of inflammation in cancer initiation and
progression, it has been hypothesized that cancer and inflammation are connected
by two pathways, intrinsic and extrinsic (Mantovani et al. 2008). The intrinsic
pathway is activated by oncogenic changes in neoplasia and the extrinsic pathway
stems from factors not related to cancer (e.g., pathogens, IBD). Both pathways
lead to the increased production of inflammatory mediators with potential
capabilities to promote the development and progression of cancer such as
proinflammatory cytokines through NF-κB, and STAT3 (Mantovani et al. 2008).
However, this model does not acknowledge tumor immunosurveillance.
Therefore, this review adopts a modified version of the original model (Fig. 4),
with an additional TAA-driven intrinsic pathway leading to an anti-tumor immune
response, but also accompanied by potential capabilities to promote the
development and progression of cancer through, e.g., NF-κB, and STAT3.
1. Oncogen-driven
intrinsic pathway
3. Extrinsic pathway
Oncogen activation
Transcription
factor (NF-κB,
STAT3)
activation in
tumor cells
Inflammation
or infection
Chemokine and
cytokine
production
by tumor cells
2. TAA-driven intrinsic pathway
Genetic
alterations
Immune response
against TAAs
Generation
of TAAs
Cancer
immunosurveillance
Inflammatory
cell
recruitment
Chemokine
and cytokine
production by
inflammatory
cells, tumor
cells and
stromal cells
Transcription
factor (NF-κB,
STAT3)
activation in
tumor cells,
inflammatory
cells, and
stromal cells
Tumor-promoting
inflammation
- Cell proliferation
and survival
- Angiogenesis
- Tumor cell
invasion
- Inhibition
of apoptosis
Fig. 4. Pathways connecting inflammation and cancer. Modified from Mantovani et al.
2008.
38
2.3.6 Angiogenesis
Tumors require blood vessels in order to acquire nutrients and oxygen (Hanahan
& Weinberg 2011). The signaling molecule vascular endothelial growth factor
(VEGF) harbors a central role in angiogenesis regulation (Carmeliet 2005) and is
frequently overexpressed in CRC (Ishigami et al. 1998). In CRC, high VEFG
expression (Ishigami et al. 1998, Lee et al. 2000) and high blood vessel density
(Tanigawa et al. 1997) have been associated with worse prognosis, indicating that
the tumors with effective angiogenesis show aggressive behavior. In addition to
tumor cells, the inflammatory cells in tumor stroma are important sources of
angiogenesis regulatory molecules (Zumsteg & Christofori 2009), and breast
cancer mouse models have indicated that tumor-associated macrophages (TAMs),
especially, are important in pressing the angiogenic switch (Lin et al. 2006).
2.4
Colorectal cancer diagnosis and screening
CRC patients frequently present to primary care with abdominal symptoms,
including rectal bleeding, diarrhea, loss of weight, abdominal pain, and anemia
(Jellema et al. 2010). The diagnosis of CRC is most often made by colonoscopy,
an endoscopic procedure that enables visualization of the entire mucosa of the
colon and rectum (Hazewinkel & Dekker 2011).
Different methods for CRC screening have been suggested, including fecal
occult-blood screening (Mandel et al. 2000), sigmoidoscopy (Schoen et al. 2012),
and computed tomographic colonography (Pickhardt et al. 2007). No serum
markers for screening have been validated for clinical work (Sturgeon et al.
2008).
In Finland, an organized CRC screening program with fecal occult blood test
as a public health policy was started in 2004 and it covered one third of the target
population by 2007 (Malila et al. 2011). The test sensitivity — the proportion of
the diseases the test is able to identify in those screened — in Finland in 20042006 was 54.6% (Malila et al. 2008). An invasive colorectal cancer was
diagnosed in 8.2% of the fecal occult blood positive subjects at screening or
during follow-up in 2004-2006 and the testing was considered cost-effective
(Paimela et al. 2010).
39
2.5
Colorectal cancer prognostic and predictive markers
Despite the overall improvement in CRC survival in the past decades,
understanding of why individual patients get a recurrence while others do not
remains poor (Walther et al. 2009). Prognostic markers provide information about
the patients’ cancer outcome, while predictive markers indicate sensitivity or
resistance to a specific therapy (Oldenhuis et al. 2008). The current standard for
CRC prognostication is clinicopathological staging, while potential molecular
prognostic and predictive markers have attracted vast interest in the past decades
(Walther et al. 2009).
Several parameters can be used in the measurement of survival time (Punt et
al. 2007). Overall survival (OS) — time from diagnosis to death, irrespective of
cause — is frequently used, when the cause of death is not specified, while causespecific survival (or cancer-specific survival CSS) — time to death caused by the
same cancer — can be calculated if the cause of death information is available
(Heinävaara et al. 2002, Punt et al. 2007). In the past decades, the use of diseasefree survival (DFS) — the period after curative treatment when no disease can be
detected — has become more frequent in the clinical trials as well as prognostic
studies, offering an earlier accomplishment of sufficient numbers of endpoints
relative to OS and CSS (Abrams 2005, Birgisson et al. 2011).
2.5.1 Clinical and histopathological prognostic factors
TNM Stage
Colorectal cancer staging is based on TNM classification (Sobin et al. 2009), T
denoting primary tumor, N regional lymph node metastasis, and M distant
metastasis. It is more accurate than Dukes’ classification (Dukes 1932) and its
modifications (Turnbull et al. 1967), which were used earlier for many decades.
The stages A-D in the Turnbull (1967) modification roughly correspond to stages
I-IV in TNM6 and TNM7 (Sobin et al. 2009). In patients operated on in the
1990s, the OS ranged from 90% in stage I to less than 10% in stage IV
(O’Connell et al. 2004). In addition to guiding the prognostic classification, tumor
stage is the most important factor directing the treatment of the patients (Quirke et
al. 2007).
The changes from TNM6 to TNM7 have been relatively modest, so that the
main T, N, and M categories and stages I, II, III, and IV can be compared between
40
TNM6 and TNM7 (Table 9, Table 10). An important change is the categorization
of tumor deposits in the pericolorectal adipose tissue without histological
evidence of residual lymph node, which are classified in the N category as N1c in
TNM7 but counted as lymph nodes in TNM6 if harboring a smooth contour, or
classified in T category and blood vessel invasion if harboring an irregular
contour (Nagtegaal et al. 2012, Sobin et al. 2009, Sobin & Wittekind 2002).
Table 9. TNM6 and TNM7 Classification.
Classification
TNM6
TNM7
TX
Primary tumor cannot be assessed
Primary tumor cannot be assessed
T0
No evidence of primary tumor
No evidence of primary tumor
Tis
Carcinoma in situ: intraepithelial or
Carcinoma in situ: intraepithelial or
invasion of lamina propria
invasion of lamina propria
T1
Tumor invades submucosa
Tumor invades submucosa
T2
Tumor invades muscularis propria
Tumor invades muscularis propria
T3
Tumor invades through the
Tumor invades through the muscularis
muscularis propria into subserosa
propria into subserosa or into non-
or into non-peritonealized pericolic
peritonealized pericolic or perirectal
or perirectal tissues
tissues
Primary tumor (T)
T4
Tumor directly invades other organs Tumor directly invades other organs or
or structures and/or perforates
structures and/or perforates visceral
visceral peritoneum
peritoneum
T4a
-
Tumor perforates visceral peritoneum
T4b
-
Tumor directly invades other organs or
structures
Regional lymph nodes (N)
NX
Regional lymph nodes cannot be
Regional lymph nodes cannot be
assessed
assessed
N0
No regional lymph node metastasis No regional lymph node metastasis
N1
Metastasis in 1–3 regional lymph
Metastasis in 1–3 regional lymph nodes
nodes
N1a
-
Metastasis in one regional lymph node
N1b
-
Metastasis in 2–3 regional lymph nodes
N1c
-
Tumor deposit(s) in the subserosa, or in
the nonperitonealized pericolic or
perirectal tissues without regional
lymph node metastasis
N2
N2a
Metastasis in 4 or more regional
Metastasis in 4 or more regional lymph
lymph nodes
nodes
-
Metastasis in 4–6 regional lymph nodes
41
Classification
N2b
TNM6
TNM7
-
Metastasis in 7 or more regional lymph
nodes
Distant metastasis (M)
MX
Distant metastasis cannot be
Distant metastasis cannot be assessed
assessed
M0
No distant metastasis
No distant metastasis
M1
Distant metastasis
Distant metastasis
-
Metastasis confined to one organ or
M1a
lymph node metastasis outside regional
lymph nodes
M1b
-
Metastasis in more than one organ or
the peritoneum
Adapted from Sobin & Wittekind 2002, Sobin et al. 2009.
Table 10. Stage Classification.
Stage
Dukes’ (Turnbull
Definition in TNM6
Definition in TNM7
modification)
0
Tis, N0, M0
Tis, N0, M0
I
A
T1–2, N0, M0
T1–2, N0, M0
II
B
T3–4, N0, M0
T3–4, N0, M0
IIA
B
T3, N0, M0
T3, N0, M0
IIB
B
T4, N0, M0
T4a, N0, M0
IIC
B
-
T4b, N0, M0
C
T1–4, N1–2, M0
T1–4, N1–2, M0
IIIA
C
T1–2, N1, M0
T1–2, N1, M0 or T1, N2a, M0
IIIB
C
T3–4, N1, M0
T3–4a, N1, M0 or T2–3, N2a,
IIIC
C
T1–4, N2, M0
D
T1–4, N0-2, M1
T1–4, N0-2, M1
IVA
D
-
T1–4, N0-2, M1a
IVB
D
-
T1–4, N0-2, M1b
III
M0 or T1-2, N2b, M0
T4a, N2a, M0 or T3–4a, N2b,
M0 or T4b, N1–2, M0
IV
Adapted from Sobin & Wittekind 2002, Sobin et al. 2009, Turnbull et al. 1967.
Lymph node examination
The number of lymph nodes examined is dependent on the number of lymph
nodes present in the tissue, the surgical technique, and the examination of the
tissue by the pathologist. A low number of examined nodes has been associated
42
with poor survival in several independent large cohorts (Le Voyer et al. 2003,
Sarli et al. 2005, Stocchi et al. 2011, Swanson et al. 2003). This may be related to
the quality of the examination of the surgical specimens by a pathologist.
Accurate staging associates with correct choices of therapies. Moreover, it has
been hypothesized that a decreased number of examined lymph nodes may reflect
a diminished immune response (Sarli et al. 2005). Preoperative radiotherapy
(Nagtegaal et al. 2002) and chemoradiotherapy (Morcos et al. 2010) in rectal
cancer result in a decrease in lymph node yield. However, it has been reported
that the number of lymph nodes in these specimens does not influence survival
(Rullier et al. 2008).
Residual tumor and resection margins
The prognosis of CRC is influenced by the completeness of tumor removal at the
time of surgery (Hamilton et al. 2010, Sobin et al. 2009), which can be evaluated
utilizing the residual tumor (R) classification as presented in Table 11. In rectal
cancer, the circumferential (radial) resection margin adjacent to the deepest point
of tumor invasion has been found to be a powerful predictor of survival and the
development of distal metastasis (Nagtegaal & Quirke 2008). Short longitudinal
(proximal and distal) resection margins (less than 2–5 cm, depending on the
location of the tumor and the type of the resection) are also considered to
associate with adverse prognosis in colon cancer and, especially, in rectal cancer
(Bernstein et al. 2012, Nelson et al. 2001).
Table 11. Residual tumor classification.
Classification
Definition
RX
The presence of residual tumor cannot be assessed
R0
No residual tumor; all margins histologically negative
R1
Incomplete tumor resection with microscopic surgical margin involvement
R2
Incomplete tumor resection with macroscopic residual tumor
Adapted from Sobin et al. 2009, Wittekind et al. 2002.
Bowel obstruction and perforation
Emergency operative interventions in CRC are required in cases of bowel
obstruction and perforation, which have been associated with poor survival and,
especially, with increased perioperative mortality (Chen & Sheen-Chen 2000).
43
Grade of differentiation
The current WHO classification categorizes colorectal adenocarcinomas into well,
moderately, and poorly differentiated adenocarcinomas, and undifferentiated
carcinomas based on the percentage of gland formation (Table 12), but also
various other grading criteria have been suggested (Compton et al. 2000).
Specific types of CRC, such as signet ring cell carcinomas, are not graded
because these tumors in general behave like high grade tumors. High grade (3–4)
has been associated with worse prognosis in several large cohorts independent of
tumor stage (Chapuis et al. 1985, Halvorsen & Seim 1988, Newland et al. 1994).
Table 12. Grade classification.
Grade
Category
Definition
1
Well-differentiated
>95% with gland formation
2
Moderately differentiated
50–95% with gland formation
3
Poorly differentiated
<50% with gland formation
4
Undifferentiated
No evidence of differentiation
Adapted from Hamilton et al. 2010.
Blood vessel invasion, lymph vessel invasion, and perineural invasion
Blood vessel invasion (Chapuis et al. 1985, Newland et al. 1994, Roxburgh et al.
2010), lymphatic vessel invasion (Akagi et al. 2013, Minsky et al. 1989), and
perineural invasion (Liebig et al. 2009) have been reported to be stageindependent markers for worse prognosis in CRC. In some cases, their
observation can be difficult utilizing sections stained with hematoxylin and eosin
(H&E), and histochemical and immunohistochemical methods (Table 13) may
improve the accuracy of their assessment (Kojima et al. 2013, van Wyk et al.
2013).
Table 13. Histochemical and immunohistochemical methods for the detection of
lymph vessel invasion and blood vessel invasion.
Method
References
Lymphatic invasion
Podoplanin (D2-40)
Ishii et al. 2009, Liang et al. 2007, Matsumoto et al.
2007, Suzuki et al. 2009
Blood vessel invasion
Elastica
44
Roxburgh et al. 2010, Akifumi Suzuki et al. 2009
Tumor border configuration
Infiltrative tumor border, characterized by diffuse, irregular tumor borders and
finger-like processes of tumor cells invading the surrounding stroma (Fig. 5), is
present in about 25% of CRC (Jass et al. 1996). It is associated with adverse
prognosis in CRC, independent of tumor stage (Jass et al. 1987, Morikawa et al.
2012, Zlobec et al. 2009). It can be best evaluated with low magnification
(Koelzer & Lugli 2014).
Using a high magnification, tumor budding (Fig. 5), composed of isolated
tumor cells or clusters of two to five cells at the invasive margin of the tumor, can
be observed in the majority of CRC (Hase et al. 1993, Ueno et al. 2002).
Intensive budding is associated with a poor prognosis independent of tumor stage
(Hase et al. 1993, Hörkkö et al. 2006, Ueno et al. 2002, Zlobec et al. 2011).
a
b
c
d
Fig. 5. Representative images of tumor border configuration and tumor budding. a)
Infiltrative growth pattern characterized by poorly demarcated tumor borders and
streaming dissection of muscularis propria. (b) A well-demarcated pushing tumor
border. (c) Intensive tumor budding defined as individual cells or clusters of up to five
cells. (d) No tumor budding can be observed.
45
2.5.2 Inflammation-based prognostic markers
This issue is reviewed in detail, because it is one of the main topics of the thesis.
Colorectal tumors are infiltrated by a heterogeneous group of immune cells in
various tumor locations (Fig. 6). Several general inflammatory classifications as
well as specific inflammatory cell markers have been associated with stageindependent prognostic value in CRC (Roxburgh & McMillan 2012).
CT-IEL
CT-S
CT-IEL
CT
IM
CLR
Fig. 6. Colorectal cancer associated immune cell infiltrate in different tumor locations.
The locations can be divided into intratumoral (CT: center of tumor) and peritumoral
(IM: invasive margin). Intratumorally, intraepithelial (IEL) and stromal (S) locations can
be distinguished. Colorectal cancer associated lymphoid reaction (CLR) is defined as
transmural lymphoid aggregates surrounding the tumor.
General inflammatory classifications
Dense peritumoral inflammatory reaction is associated with better survival of the
CRC patients independent of tumor stage (Halvorsen & Seim 1989, Jass 1986,
46
Jass et al. 1987, Klintrup et al. 2005, Ogino et al. 2009, Roxburgh et al. 2009).
Different methods utilized in its evaluation from H&E slides are portrayed in
Table 14.
Table 14. Some of the most frequently applied methods for the evaluation of
peritumoral inflammatory cell infiltration in colorectal cancer.
References
Method
Jass 1986, Jass et al. 1987, 1996
Two-tiered classification into low- and high-grade according to the
presence of distinctive connective tissue mantle at the invasive
margin scattered with lymphocytes and other inflammatory cells
Halvorsen & Seim 1989
Two-tiered classification of the amount of inflammatory cells along
the entire tumor edge away from areas of frank abscess
formation, classified into prominent and inconspicuous
Klintrup et al. 2005
Two-tiered classification of peritumoral inflammatory infiltrate,
where low-grade denotes mild or patchy immune cell infiltrate and
high-grade denotes a band-like immune cell infiltrate with
evidence of the destruction of cancer cell islets
Ogino et al. 2009
Four-tiered scoring of the discrete lymphoid reactions surrounding
tumor into 0 (absent), 1+ (mild), 2+ (moderate), or 3+ (marked)
Crohn’s-like lymphoid reaction
A subset of CRCs exhibits CLR, an inflammatory reaction pattern comprising
transmural lymphoid aggregates (Fig. 6) (Graham & Appelman 1990). It has been
associated with better survival in CRC (Adams & Morris 1997, Buckowitz et al.
2005, Harrison et al. 1994, Murphy et al. 2000, Ogino et al. 2009). However, the
stage-independent prognostic value of CLR, as well as its biological mechanisms
and cellular composition have not been well-defined.
T cells
High infiltration of CD3+, CD8+, and CD45RO+ T cells in different tumor
locations has almost consistently been associated with better survival in CRC and
has been linked with stage-independent prognostic value, although not replicated
in all of the studies (Table 15). Immunoscore (Galon et al. 2012, 2014), composed
of computer-assisted combined evaluation of two of the three markers (CD3,
CD8, CD45RO) in two regions (CT, IM) has been reported to have superior
prognostic significance relative to TNM classification (Mlecnik et al. 2011, Pagès
47
et al. 2009). Consequently, there is an international initiative to include
Immunoscore in cancer classification (Galon et al. 2012, 2014).
+
+
+
Table 15. Prognostic significance of CD3 and CD8 , and CD45RO T cells.
Reference
Marker
N
Stage Location TMA Comp Continuous OS CSS DFS Independent
variables
prognostic
value
Naito et al. 1998 CD8
131
I–IV
CT-IEL
No
No
4-tiered
+
Yes
Guidoboni et al.
CD3,
109
II–III
CT-IEL
No
No
Yes
+
Yes
2001
CD8
Nagtegaal et al.
CD3,
160
I–III
CT-S,
No
No
3-tiered
+
No
2001
CD8
Chiba et al. 2004 CD8
Pagès et al.
IM
371
I–IV
CT-IEL
No
No
Yes
CD45RO 415
I–IV
CT, IM
Yes
Yes
Yes
+
+
+
Yes
Yes
I–IV
CT, IM
Yes
Yes
Yes
+
+
Yes
CT, IM
Yes
Yes
Yes
+
+
Yes,
IM
Yes
No
Yes
+
Yes
+
No
2005
Galon et al. 2006 CD3
415
Pagès et al.
CD8,
411, I–II
2009
CD45RO 212
Lugli et al. 2009
CD8
combined
279, I–III
191
Salama et al.
CD8,
2009
CD45RO
Deschoolmeeste CD3,
r et al. 2010
CD8
Nosho et al.
CD3,
2010
CD8,
967
II–III
CT
Yes
Yes
Yes
215
I–IV
CT, IM
No
No
4-tiered
+
+
No
768
I–IV
CT-IEL
Yes
Yes
Yes
+
+
Only
CD45RO
CD45RO
Peng et al. 2010 CD3,
68
IIIb
CT-S
No
No
Yes
+
No
CD3
462
I–IV
CT-IEL
Yes
No
Yes
+
Yes
CD3
484
I–III
CT-S,
No
No
4-tiered
+
Yes
Yes
Yes
Yes
CD45RO
Simpson et al.
2010
Dahlin et al.
2011
CT-IEL,
IM
Mlecnik et al.
CD3,
415,
2011
CD8,
184
CT, IM
+
+
+
Yes,
combined
CD45RO
Richards et al.
CD3,
2014
CD8,
365
I–III
CT-S,
CT-IEL,
No
No
4-tiered
+
Yes, CD3
(IM), CD8
CD45RO
IM
(CT-IEL)
Abbreviations: Comp: computer; CSS: cancer-specific survival; CT: tumor center; DFS: disease-free
survival; IEL: intraepithelial; IM: invasive margin; OS: overall survival; S: stromal; TMA: tissue microarray.
48
FoxP3+ regulatory T (TReg) cells are immunosuppressive cells essential for
maintaining peripheral tolerance. It was reported that the recruitment of TReg cells
in ovarian carcinoma suppressed tumor-specific T cell immunity and predicted
reduced survival (Curiel et al. 2004), and FoxP3+ cell infiltration has also been
associated with adverse prognosis in breast cancer (Bates et al. 2006). However,
in CRC, most studies have reported an association between higher FoxP3 + cell
infiltration and better prognosis (Table 16). The mechanisms underlying this
inconsistency between different types of solid tumors are not clear.
Table 16. Prognostic significance of Regulatory T cells.
Reference
Marker
N
Stage Location TMA Comp Continuous OS CSS DFS Independent
variables
prognostic
value
Salama et al.
FoxP3
967
II–III
CT
Yes
Yes
Yes
+
Sinicrope et al.
FoxP3/
160
II–III
CT-IEL
No
No
Yes
2009
CD3 ratio
Frey et al. 2010
FoxP3
1420 I–IV
CT
Yes
No
Yes
Nosho et al.
FoxP3
768
I–IV
CT-IEL
Yes
Yes
Yes
+
FoxP3
87
II
CT-S,
No
Yes
Yes
0
Yes
2009
-
Yes
+
Yes
+
No
2010
Lee et al. 2010
+
Yes, CT-IEL
+
Not
CT-IEL
Tosolini et al.
FoxP3
415
I–IV
CT, IM
Yes
Yes
Yes
Yoon et al. 2012 FoxP3
216
II–III
CT-S,
Yes
No
Yes
No
No
4-tiered
2011
estimated
+
Yes
CT-IEL
Richards et al.
FoxP3
2014
365
I–III
CT-S,
+
No
CT-IEL,
IM
Abbreviations: Comp: computer; CSS: cancer-specific survival; CT: tumor center; DFS: disease-free
survival; IEL: intraepithelial; IM: invasive margin; OS: overall survival; S: stromal; TMA: tissue microarray.
Natural killer cells
A few studies have assessed the prognostic value of natural killer cells in CRC,
utilizing CD56 and CD57 as markers in their identification, and have suggested
that higher natural killer cell density may associate with improved survival (Table
17).
49
Table 17. Prognostic significance of natural killer cells.
Reference
Marker
N
Stage Location TMA Comp Continuous OS CSS DFS Independent
variables
prognostic
value
Coca et al. 1997 CD57
157
I–III
CT
No
No
3-tiered
+
+
Yes
Nagtegaal et al.
160
I–III
CT-S,
No
No
3-tiered
0
+
No
No
No
Yes
+
No
CD56
2001
IM
Menon et al.
CD56,
2004
CD57
93
II–III
CT-S,
CT-IEL,
IM
Abbreviations: Comp: computer; CSS: cancer-specific survival; CT: tumor center; DFS: disease-free
survival; IEL: intraepithelial; IM: invasive margin; OS: overall survival; S: stromal; TMA: tissue microarray.
Dendritic cells
A variety of DC markers exist. CD1a is generally expressed on immature DCs,
while CD83 has been found to be stably expressed on activated, mature DCs (Cao
et al. 2005). Dendritic cells also express S-100 protein that is present in cells
derived from the neural crest (Zimmer et al. 1995). It has been reported that
mature DCs make clusters with T cells in the invasive margin of CRC to promote
T cell activation (Suzuki et al. 2002). However, few studies have addressed the
prognostic significance of different dendritic cell populations in CRC (Table 18).
Table 18. Prognostic significance of dendritic cells.
Reference
Marker
N
Stage Location TMA Comp Continuous OS CSS DFS Independent
variables
prognostic
value
Dadabayev et al. S-100
104
II–III
2004
CT-S,
No
No
Yes
0
CT-IEL,
Not
evaluated
IM
Sandel et al.
S-100,
2005
CD1a
104
II–III
CT-S,
No
No
Yes
+
CT-IEL,
Not
evaluated
IM
Nagorsen et al.
2007
S-100
40
I–IV
CT-S,
CT-IEL
No
No
Yes
+
Not
evaluated
Abbreviations: Comp: computer; CSS: cancer-specific survival; CT: tumor center; DFS: disease-free
survival; IEL: intraepithelial; IM: invasive margin; OS: overall survival; S: stromal; TMA: tissue microarray
50
Macrophages
High macrophage infiltration at the IM of the tumors has been linked with
favorable prognosis in CRC in several studies (Table 19). In addition to
contributing to tumor cell phagocytosis, macrophages may control the immune
reactions by the secretion of cytokines and growth factors (Mantovani et al.
2002). The alternatively activated M2 macrophages (characterized by, e.g.,
CD163 expression and IL-10 production) have anti-inflammatory activity and
have been hypothesized to promote tumor growth, while the classically activated
M1 macrophages (characterized by, e.g., inducible nitric oxide synthase, iNOS,
expression and IL-12 production) have been thought to contribute to anti-tumor
immune responses (Mantovani et al. 2002). However, Edin et al. (2012) recently
reported that CD163- and iNOS-expressing macrophages harbor similar
prognostic value. Instead, Ålgars et al. (2012) utilized Stabilin-1 as a marker for
M2 macrophages and found that their abundance associated with poor prognosis
irrespective of CD68+ macrophages.
Table 19. Prognostic significance of macrophages.
Reference
Marker
N
Stage Location TMA Comp Continuous OS CSS DFS Independent
variables
prognostic
value
Nagtegaal et al.
CD68
160
I–III
2001
Lackner et al.
CT-S,
No
No
3-tiered
+
+
No
IM
CD68
70
II–III
CT, IM
No
No
Yes
+
Yes, IM
CD68
117
I–IV
CT-S,
No
No
4-tiered
0
No
2004
Baeten et al.
2006
CT-IEL,
IM
Forssell et al.
CD68
488
I–IV
IM
No
No
4-tiered
CD163
40
I–IV
CT-S,
No
No
Yes
+
Yes
2007
Nagorsen et al.
2007
Ålgars et al.
+
Not
CT-IEL
evaluated
Stabilin-1 159
II–IV
CT, IM
No
No
4-tiered
-
Yes
CD163,
I–IV
IM
No
No
4-tiered
+
No
2012
Edin et al. 2012
485
iNOS
Abbreviations: Comp: computer; CSS: cancer-specific survival; CT: tumor center; DFS: disease-free
survival; IEL: intraepithelial; IM: invasive margin; OS: overall survival; S: stromal; TMA: tissue microarray.
51
Neutrophils
In histological specimens, neutrophils can be detected with several different
markers, including neutrophil elastase, CD66b, and myeloperoxidase (MPO), all
of which have been found to have high sensitivity and specificity for neutrophils,
although neutrophil elastase and MPO label a population of monocytes, basophils
and eosinophils with a lower intensity (Paulsen et al. 2013, Pulford et al. 1988).
The prognostic significance of neutrophil infiltration in CRC is controversial
(Table 20).
Table 20. Prognostic significance of neutrophils.
Reference
Marker
N
Stage Location TMA Comp Continuous OS CSS DFS Independent
variables
prognostic
value
Nielsen et al.
H&E
584
I–IV
1999
Nagtegaal et al.
Sub-
No
No
Yes
+
No
No
3-tiered
0
No
mucosa
Elastase 160
I–III
2001
CT-S,
+
No
IM
Rao et al. 2012
CD66b
229
I–IV
CT
Yes
No
Yes
-
Yes
Droeser et al.
MPO
1491 I–IV
CT
Yes
No
Yes
+
Yes
2013
Abbreviations: Comp: computer; CSS: cancer-specific survival; CT: tumor center; DFS: disease-free
survival; IM: invasive margin; OS: overall survival; S: stromal; TMA: tissue microarray.
Eosinophils
A few studies have addressed the prognostic significance of eosinophils in CRC
and have indicated that their abundance may indicate better survival (Table 21).
52
Table 21. Prognostic significance of eosinophils.
Reference
Marker
N
Stage Location TMA Comp Continuous OS CSS DFS Independent
variables
prognostic
value
Pretlow et al.
Giemsa
70
II–III
CT
No
No
Yes
+
Not
Fisher et al. 1989 H&E
331
I–III
CT
No
No
Yes
+
No
Nielsen et al.
584
I–IV
Sub-
No
No
Yes
+
Yes
1983
evaluated
H&E
1999
Fernández-
mucosa
H&E
126
I–III
CT
No
No
4-tiered
+
+
Yes
EG-2
160
I–III
CT-S,
No
No
3-tiered
+
+
Only IM
Aceñero et al.
2000
Nagtegaal et al.
2001
IM
Abbreviations: Comp: computer; CSS: cancer-specific survival; CT: tumor center; DFS: disease-free
survival; IM: invasive margin; OS: overall survival; S: stromal; TMA: tissue microarray.
Mast cells
In cancer, mast cells have been attributed both protective and promoting roles,
involving controlling of anti-tumor immune response and contributing to
angiogenesis (Khazaie et al. 2011). The studies evaluating the prognostic
significance of mast cells in CRC have been controversial (Table 22).
53
Table 22. Prognostic significance of mast cells.
Reference
Marker
N
Stage Location TMA Comp Continuous OS CSS DFS Independent
variables
prognostic
value
Pretlow et al.
Giemsa
70
II–III
CT
No
No
Yes
0
Not
Fisher et al. 1989 H&E
331
I–III
CT
No
No
Yes
-
Yes
Nielsen et al.
584
I–IV
Sub-
No
No
Yes
+
Yes
No
No
3-tiered
+
1983
evaluated
H&E
1999
Nagtegaal et al.
mucosa
Tryptase 160
I–III
2001
Acikalin et al.
CT-S,
+
Only IM
-
No
IM
Giemsa
60
I–IV
CT
No
No
Yes
Xia et al. 2011
Tryptase 93
IIIB
CT-S
No
No
Yes
0
Wu et al. 2013
Tryptase 325
I–III
CT-S
No
No
Yes
-
2005
No
-
Yes
Abbreviations: Comp: computer; CSS: cancer-specific survival; CT: tumor center; DFS: disease-free
survival; IM: invasive margin; OS: overall survival; S: stromal; TMA: tissue microarray.
2.5.3 Genetic prognostic and predictive markers
The prognostic significance of the major genetic changes associated with CRC
pathogenesis (Fearon & Vogelstein 1990, Jass 2007a) has been under extensive
research during the past decades. However, with the exception of activating
mutation in RAS oncogene as a factor influencing epidermal growth factor
receptor (EGFR) treatment outcome (Amado et al. 2008, Douillard et al. 2013,
Karapetis et al. 2008, Lièvre et al. 2006), other markers are currently rarely
employed in clinical decision-making.
Microsatellite instability and chromosomal instability
Numerous studies have evaluated the prognostic value of MSI and CIN. The
results have been gathered as large meta-analyses, which indicate that MSI
associates with better prognosis (hazard ratio, HR for OS 0.65, 95% confidence
interval, CI 0.59-0.71) and CIN with worse prognosis (HR for OS 1.45, 95% CI
1.35-1.55) (Popat et al. 2005, Walther et al. 2008).
MSI induces the generation of novel tumor-specific frameshift peptides,
potentially increasing the immunogenicity (Schwitalle et al. 2008), and it has
been hypothesized that the enhanced immune response against the tumors with
54
MSI is one of the contributing factors to the prognostic effect of MSI (Smyrk et
al. 2001).
MSI has also been reported to predict poor response to 5-fluorouracil-based
chemotherapy in several large cohorts (Ribic et al. 2003, Sargent et al. 2010). On
the contrary, an analysis of 2,141 CRC adjuvant trial patients proposed that stage
III CRC patients with MSI benefit from 5-fluorouracil-based adjuvant treatment
(Sinicrope et al. 2011). In conclusion, although the data on the predictive value of
MMR status on 5-fluorouracil based chemotherapy is inconclusive, there is
evidence supporting the validity of MSI in identifying a group of stage II CRC
patients with a low likelihood of recurrence and who are therefore unlikely to
benefit from chemotherapy (Schmoll et al. 2012).
KRAS, NRAS and BRAF
The prognostic significance of KRAS mutation status is controversial with some
studies associating it with adverse prognosis (Eklöf et al. 2013, Richman et al.
2009) and others with little prognostic value (Fariña-Sarasqueta et al. 2010,
Popovici et al. 2013, Roth et al. 2010). A recent meta-analysis that included 23
studies indicated that KRAS mutations overall do not correlate with CRC
prognosis (HR for OS 1.04, 95% CI 0.99–1.10) (Ren et al. 2012).
KRAS and NRAS have predictive value in CRC, since patients with RASmutated tumors do not benefit from EGFR antibody therapy (Amado et al. 2008,
Douillard et al. 2013, Karapetis et al. 2008, Lièvre et al. 2006). RAS gene family
members are downstream mediators of EGFR in the MAPK-ERK pathway
(Roberts & Der 2007).
BRAFV600E mutation has been reported to associate with poor prognosis in
stage II–III (Fariña-Sarasqueta et al. 2010, Popovici et al. 2013, Roth et al. 2010),
as well as stage IV CRC (Richman et al. 2009), although conflicting reports also
exist (Hutchins et al. 2011). A recent meta-analysis provided BRAF mutation a
HR for OS of 2.24 (95% CI 1.82–2.83) for 26 studies that met the inclusion
criteria (Safaee Ardekani et al. 2012). An activating mutation in BRAF, located
downstream RAS in the MAPK-ERK pathway, has also been linked with
resistance to EGFR antibody treatment (Di Nicolantonio et al. 2008).
55
EGFR gene copy number
An increase in EGFR gene copy number, as assessed by fluorescence and silver in
situ hybridization, has been linked with response to anti-EGFR treatment
(Sartore-Bianchi et al. 2007, Ålgars et al. 2011). However, the results of in situ
hybridization can be hard to interpret, and a standardized and validated scoring
system is needed before the test can be utilized in clinical practice (SartoreBianchi et al. 2012, Ålgars et al. 2014).
Loss of heterozygosity in chromosome 18q
A meta-analysis of 17 studies (Popat & Houlston 2005) suggested that CRCs with
chromosome 18q loss have poorer prognosis. There was, however, evidence of
substantial publication bias. Therefore, further large-scale studies have been
conducted, and they have indicated that 18q LOH does not associate with patient
survival (Bertagnolli et al. 2011, Ogino et al. 2009, Popat et al. 2007). Moreover,
the potential value of 18q LOH as an independent prognostic marker is
questionable, since it is a marker of CIN (Ogino et al. 2007), which is itself
associated with worse prognosis (Walther et al. 2008).
TP53
A meta-analysis of 61 studies (Munro et al. 2005) reported mutations in TP53 to
associate with worse prognosis in CRC (relative risk 1.31, 95% CI 1.19–1.45).
However, there was evidence of both publication bias and heterogeneity of
results, which made it difficult to draw firm conclusions. A sequencing-based
prospective study on 3,583 stage I–IV CRC patients indicated that TP53 mutation
itself does not carry prognostic significance (Russo et al. 2005), while specific
mutations in specific tumor sites may be associated with the outcome.
2.5.4 Blood and serum prognostic markers
Tumor progression and metastasis is also reflected at the systemic level
(McAllister & Weinberg 2014). Indeed, a number of systemic protein markers and
hematological parameters have been associated with prognostic significance in
CRC (Duffy et al. 2007, Sturgeon et al. 2008). Carcinoembryonic antigen (CEA)
56
is the most widely used marker in clinical work, and its higher preoperative
concentrations have been found to associate with worse survival (Duffy 2001).
Systemic inflammatory markers have also shown promise in CRC
prognostication (Roxburgh & McMillan 2010). Especially, the Glasgow
prognostic score (GPS) (McMillan 2013) — comprised of serum levels of Creactive protein (CRP) and albumin — and blood neutrophil/lymphocyte ratio
(Ding et al. 2010, Walsh et al. 2005) have been found to have strong prognostic
value in several independent cohorts. However, more validation is still needed,
and GPS or neutrophil/lymphocyte ratio are not currently frequently utilized in
clinical work (Duffy et al. 2007, Sturgeon et al. 2008).
Proteolytic activity that is induced in tumor microenvironment is reflected by
increased systemic levels of several MMPs in CRC, including MMP-7 (Maurel et
al. 2007) and MMP-9 (Hurst et al. 2007, Mroczko et al. 2010). Furthermore,
systemic levels of some MMPs, including MMP-1 (Tahara et al. 2010) and MMP7 (Maurel et al. 2007), have been reported to have prognostic significance.
However, more studies are needed to determine their potential value in clinical
practice.
2.6
Colorectal cancer treatment
Surgery is the primary modality of treatment for CRC, and resection is the only
therapy required for early-stage CRC (Nelson et al. 2001). Adjuvant
chemotherapy, radiotherapy (RT), or chemoradiotherapy (CRT) reduces the
mortality in surgically treated patients with a high risk of recurrence (André et al.
2004), and neoadjuvant RT or CRT improves the results of the treatment of
locally advanced rectal cancer (Aklilu & Eng 2011, Onaitis et al. 2001). In
addition to the traditional cytotoxic drugs, the last two decades have led to the
introduction of monoclonal antibodies in CRC treatment (Cunningham et al.
2004, Hurwitz et al. 2004).
2.6.1 Surgical treatment
The standard operative treatments for CRC are portrayed in Table 23. The target
is to remove the tumor along with the associated lymphatics en bloc with 5–10 cm
of normal bowel on either side of the primary tumor (Nelson et al. 2001). Usually,
the remaining parts of the bowel are anastomosed together. However, in the
abdominoperineal resection of the rectum, also the anus is removed and the end of
57
the remaining sigmoid colon is brought to the surface of the abdomen as a
colostomy (Nagtegaal et al. 2005).
Table 23. Standard surgical treatments of colorectal cancer.
Operation
Indications
Characteristics
Reference
Right hemicolectomy
Tumor in caecum or in,
Resection of the proximal
Lezoche et al. 2002
ascending or transverse
colon
colon
Left hemicolectomy
Tumor in descending or
Resection of the distal colon
Lezoche et al. 2002
transverse colon
Transverse colectomy
Tumor in transverse colon Resection of the transverse
Schlachta et al. 2007
colon
Sigmoid resection
Tumor in sigmoid colon
Resection of the sigmoid
Fowler & White 1991
colon
Anterior resection of
Tumor in proximal or mid-
Resection of rectum and
the rectum, total
rectum
lymphovascular fatty tissue
mesorectal excision
Enker et al. 1995
surrounding the rectum with
the preservation of anal
sphincter
Abdominoperineal
resection of the rectum
Tumor in distal rectum
Resection of the anus and the Nagtegaal et al. 2005
rectum along with
surrounding tissues
In addition to the resection of the primary tumor, the resection of colorectal liver
metastases in selected patients has been slowly adopted as the standard of care
during the last 20 years (Tomlinson et al. 2007). The criteria for resectability are
not standardized and depend on technical aspects (Schmoll et al. 2012). In a
series of 612 consecutive patients, the median CSS was 44 months after the
resection and the survival curve reached a plateau 10 years after the operation,
representing a cure rate of 17% (Tomlinson et al. 2007).
2.6.2 Neoadjuvant treatment for rectal cancer
Neoadjuvant therapy for locally advanced rectal cancer may reduce the risk of
local relapse, improve resectability, help to preserve the sphincter function, and
help to avoid stoma (Glimelius et al. 2013, Kapiteijn et al. 2001). The European
Society for Medical Oncology (ESMO) guidelines recommend preoperative RT
or CRT for locally advanced rectal tumors, with exact criteria varying depending
on tumor location (Glimelius et al. 2013, Schmoll et al. 2012). There are two
58
main modalities of treatment, short-course RT with 5×5 Gy followed by
immediate surgery and long-course CRT with 50.4 Gy in 25-28 fractions with
surgery after a 4- to 8-week break (Glimelius et al. 2013).
2.6.3 Adjuvant treatment for colorectal cancer
Adjuvant treatment is given after surgery to colon cancer patients with a high risk
of recurrence (Schmoll et al. 2012). For several decades, leucovorin and 5Fluorouracil (5-FU) have formed the basis of the treatment, and their combination
has been shown to reduce recurrence rate by 41% and overall death rate by 33%
relative to surgery alone in stage III disease (Moertel et al. 1990). The FOLFOX
regimen is based on leucovorin, 5-FU, and oxaliplatin, and improves the survival
relative to leucovorin and 5-FU alone (André et al. 2004).
The role of adjuvant therapy in stage II colon cancer is controversial. The
ESMO guidelines recommend therapy only for high-risk stage II patients, e.g., to
those with pT4 depth of invasion or the presence of vascular or lymphatic or
perineural invasion (Schmoll et al. 2012).
The available data from randomized trials for different adjuvant treatment
modalities for rectal cancer after preoperative RT or CRT are partly controversial
(Glimelius et al. 2013, Schmoll et al. 2012). Although the level of scientific
evidence for sufficient benefit is much lower than in colon cancer, 5-FU alone or
in combination with leucovorin can be given to stage III or high-risk stage II
patients (Glimelius et al. 2013).
During the last decade, the treatment of metastatic CRC has advanced
(Kemeny 2013). In addition to the increasing recognition of the potential to resect
liver metastases, there are now more options in chemotherapy. The standard
treatment regimens are still based on 5-FU but also new monoclonal antibodies
have been introduced to the treatment and have been shown to bring advances in
the survival (Schmoll et al. 2012). The monoclonal antibodies used in the
treatment of metastatic CRC include bevacizumab (Hurwitz et al. 2004), a
monoclonal antibody against VEGF, and cetuximab (Cunningham et al. 2004)
and panitumunab (Van Cutsem et al. 2007), monoclonal antibodies against EGFR.
59
60
3
Aims of the study
The present work focused on the characteristics and the significance of immune cell
infiltration and inflammatory biomarkers in CRC. The specific objectives were:
1.
2.
3.
4.
5.
6.
To test the applicability of a color channel separation based image analysis
method for immune cell counting in CRC (I) and the applicability of CLR
density counting for the evaluation of CLR (III).
To determine the interrelationships between different inflammatory cell types
within colorectal tumors (II, III).
To evaluate the prognostic value of T cells and other tumor-infiltrating
immune cells (I, II).
To enlighten the characteristics and significance of CLR (III).
To characterize the associations between serum MMP-8 levels and CRCassociated inflammatory infiltrate (IV).
To assess the sensitivity and specificity of serum MMP-8 in discriminating
the CRC patients from healthy controls (IV).
61
62
4
Materials and methods
4.1
Patients (I-IV)
The studies were based on two independent cohorts of CRC patients, and Cohort
2 was further divided into Cohort 2a (no preoperative treatments) and Cohort 2b
(preoperative RT or CRT) (Table 24). The studies were approved by the Ethical
Committee of Oulu University Hospital.
Table 24. Patient characteristics.
Characteristic
Cohort 1 (n=418)
Cohort 2a (n=117)
Cohort 2b (n=32)
Studies
I, III
II, III, IV
III, IV
Time of operation
1986–1996
2006–2010
2006–2010
Prospective recruitment
No
Yes
Yes
Tissue microarray
No
Yes
Yes
Serum samples
No
Yes
Yes
Age, mean (SD)
67.7 (12.4)
67.7 (11.2)
63.4 (10.3)
Male
200 (47.8%)
58 (49.6%)
22 (68.8%)
Female
218 (52.2%)
59 (50.4%)
10 (31.2%)
Yes
0 (0%)
0 (0%)
32 (100%)
No
418 (100%)
117 (100%)
0 (0%)
Proximal colon
130 (31.1%)
49 (41.9%)
0 (0%)
Distal colon
116 (27.8%)
28 (23.9%)
0 (0%)
Rectum
172 (41.1%)
40 (34.2%)
32 (100%)
1
101 (24.2%)
16 (13.8%)
5 (15.6%)
2
246 (58.9%)
86 (74.1%)
22 (68.8%)
3
71 (17.0%)
14 (12.1%)
5 (15.6%)
I
90 (21.5%)
19 (16.5%)
8 (25.0%)
II
180 (43.1%)
46 (40.0%)
9 (28.1%)
III
98 (23.4%)
32 (27.8%)
14 (43.8%)
IV
550 (12.0%)
18 (15.7%)
1 (3.1%)
MMR Proficient
362 (91.0%)
105 (90.5%)
32 (100%)
MMR Deficient
36 (9.0%)
11 (9.5%)
0 (0%)
Gender
Preoperative radiotherapy
or chemoradiotherapy
Location of tumor
Grade
Stage
Mismatch repair (MMR)
screening status
63
Cohort 1 was comprised of 418 (89.7%) of a consecutive series of 466 CRC
patients, operated on in Oulu University Hospital between 1986 and 1996
(Hörkkö et al. 2006). The cases were retrieved from the archives of the
Department of Pathology, Oulu University Hospital, and regraded by TNM6
classification for these studies (Sobin & Wittekind 2002). Forty-eight (10.3%)
patients were excluded from the studies because of inadequacy of the material to
reliably conduct TNM staging and other histological evaluations. Of all the
included patients, 350 (83.7%) had 60-month follow-up data from the Finnish
Cancer Registry. All 418 patients were included in Study III, whereas 235
(67.1%) of 350 patients with follow-up were selected for Study I.
A total of 344 patients were operated on in Oulu University Hospital between
2006 and 2010. Of these patients, 149 (43.3%) prospectively recruited patients
who had signed an informed consent for the study were included in Cohort 2.
Patients with earlier or simultaneously diagnosed other malignant diseases were
excluded.
Preoperative staging of Cohort 2 was done by computer tomography and the
local staging of rectal cancer was done by magnetic resonance imaging. Thirtytwo patients with locally advanced rectal cancer in Cohort 2 received preoperative
RT or CRT: 24 of them received a short-course RT, whereas eight received a longcourse CRT or RT. Cohort 2 was divided into Cohort 2a (no preoperative
treatments) and Cohort 2b (preoperative RT or CRT), due to the potential effects
of preoperative treatments on the histological properties of the tumors (Nagtegaal
et al. 2002). Cohort 2a was included in studies II, III, and IV, while Cohort 2b
was included in studies III and IV.
Clinical details of the patients were collected from the clinical records (age,
gender, treatments, recurrences) (Cohort 1, Cohort 2) and by a questionnaire
(height, weight, medication and previous illnesses) (Cohort 2). Height and weight
were used to calculate body mass index (BMI).
4.2
Control group (IV)
Eighty-three healthy age- and sex-matched controls were recruited for Cohort 2.
Controls younger than 65 years were healthy blood donors (Finnish Red Cross,
Oulu, Finland), and those aged 65 years or more were recruited from patients
undergoing cataract surgery in Oulu University Hospital. Because of the
regulations in blood donation, the exclusion criteria for blood donor controls
included too low or high hemoglobin levels (outside 135–195 g/L for men and
64
125–175 g/L for women), trauma or operation during the preceding 4 months,
chronic diseases like coronary artery disease, stroke or cancer, organ
transplantation, and acute infections.
4.3
Histopathological analysis (I-IV)
Samples from surgical specimens had been fixed in 10% buffered formalin and
embedded in paraffin. Five-micrometer sections had been cut and stained with
H&E.
4.3.1 Stage and Grade (I-IV)
The staging for both cohorts was performed according to TNM6 (Sobin &
Wittekind 2002) and the grading of differentiation according to WHO criteria
(Hamilton et al. 2010). On average, 15 (median 12, interquartile range 8–19,
range 0–62) lymph nodes were examined in Cohort 2, whereas this information
was not available for Cohort 1.
4.3.2 Necrosis (IV)
The H&E stained sections were graded for the amount of necrosis using a threegrade scale: NG0 denoted rare areas of necrosis, NG1 denoted frequent small
areas of necrosis, and NG2 denoted broad areas of necrosis. The evaluations were
done independently by two researchers after which the cases with divergent
evaluations were viewed again and mutual agreement was achieved.
4.3.3 Tumor budding (I)
Tumor budding was evaluated as present when narrow strands or clusters of
cancer cells of one to three cells in width were observed extending beyond the
tumor margin (Hörkkö et al. 2006).
4.3.4 Peritumoral inflammatory reaction (II-IV)
Peritumoral inflammatory reaction was evaluated from H&E stained sections
utilizing the Klintrup-Mäkinen (2005) method. A score of 0 was given when there
was no increase of inflammatory cells, 1 denoted mild and patchy increase of
65
inflammatory cells, a score of 2 was given when inflammatory cells formed a
band-like infiltrate at the invasive margin with some evidence of destruction of
cancer cell islets, and a score of 3 denoted a very prominent inflammatory
reaction with frequent destruction of cancer cell islets. The scores were classified
as low-grade (scores 0 and 1) and high-grade (scores 2 and 3).
4.3.5 Colorectal cancer associated lymphoid reaction (III-IV)
CLR was defined as lymphoid structures surrounding the primary tumors, not
associating with either mucosa (thus excluding mucosa-associated lymphoid
tissue) or pre-existing lymph nodes. Its extent was evaluated according to the
criteria established by Graham and Appelman (1990) (III, IV), where cases were
classified into three classes: CLR0 (no reaction) denoting no or at most one single
lymphoid aggregate in all tumor sections, CLR1 (mild reaction) defined as
occasional lymphoid aggregates with rare or absent germinal centers, and CLR2
(intense reaction) denoting numerous lymphoid aggregates with germinal centers.
A more detailed classification was adopted (III), based on counting the
lymphoid follicles. CLR density was defined as “the number of CLR follicles/the
length of the invasive front”. Lymphoid follicles with germinal centers were
counted separately. The average diameter of the lymphoid follicles was
determined using a scale placed on the ocular lens. The histological layer
(submucosa/muscularis propria/serosa) with the highest concentration of
lymphoid follicles with or without germinal centers was determined.
4.4
Immunohistochemistry (I-IV)
4.4.1 Tissue microarray (II, III)
For Cohort 2, a TMA was constructed to facilitate the analysis of densities of
multiple inflammatory cell types. The H&E slides were used to select the
locations for the sampling. Depending on the size of the tumor, a total of 1–4
(median 3) cores of 3.0 mm diameter were manually sampled for each case
yielding an overall tumor area of 7.1–28.3 mm2. One to three (median 2) of these
cores were acquired from the IM of the tumors containing the point of deepest
invasion and the rest were sampled from the CT. The necrotic areas were avoided.
66
4.4.2 Protocols (I-IV)
Section of 3.5 µm cut from paraffin-embedded specimens were deparaffinized in
xylene and rehydrated through graded alcohols. For antigen retrieval, the sections
were pre-treated with Tris-EDTA buffer (pH 9.0) in a microwave oven at 800 W
for 2 min and at 150 W for 15 min. After cooling down to room temperature and
neutralizing endogenous peroxidase activity, the sections were incubated at room
temperature with primary antibodies (Table 25). Bound antibodies were detected
using the EnVision system (Dako, Copenhagen, Denmark), except for MLH1,
which was detected using the NovoLink Polymer detection system (Leica
Biosystems, Newcastle, UK). 3,3’-Diaminobenzidine (DAB) was used as the
chromogen and hematoxylin as the counterstain.
Table 25. Antibodies and protocols used in immunohistochemistry.
Cell type
Antigen
Type
Clone
Dilution Incubation
Studies
T cells
CD3
monoclonal Novocastra
Manufacturer
PS1
1:50
30 min
I, II, III
Cytotoxic T cells
CD8
monoclonal Novocastra
4B11
1:200
30 min
II, III
Regulatory T cells FoxP3
monoclonal Abcam
236A/E7
1:100
30 min
I, II, III
B cells
CD20
monoclonal DAKO
L26
1:1000 30 min
II, III
Macrophages
CD68
monoclonal DAKO
PG-M1
1:100
30 min
II, III
Neutrophils
Neutrophil monoclonal DAKO
NP57
1:200
30 min
II, III
monoclonal DAKO
AA1
1:2000 30 min
II, III
elastase
Mast cells
Mast cell
tryptase
Mature DCs
CD83
monoclonal Abcam
1H4b
1:25
2 hr
II, III
Immature DCs
CD1a
monoclonal DAKO
O10
1:200
30 min
II, III
Proliferating cells Ki-67
monoclonal DAKO
MIB-1
1:300
30 min
III
MLH1+ cells
MLH1
monoclonal BD-Pharmingen G168-15
1:200
1 hr
II, III, IV
MSH2+ cells
MSH2
monoclonal BD-Pharmingen G219-
1:150
1 hr
II, III, IV
1:500
1 hr
IV
1129
MMP-8+ cells
MMP-8
polyclonal
non-commercial
4.4.3 Analysis of Immunohistochemistry (I-IV)
MMR Enzymes (II-IV)
The expression was evaluated positive if there was any staining in the cancer cell
nuclei and negative if there was no staining in any of the cancer cell nuclei.
Normal proliferating tissue, e.g., crypt epithelium or germinal centers of
67
lymphoid follicles, was used as an internal positive control. Cancer cells devoid
of the expression of either MLH1 or MSH2 were considered mismatch repair
(MMR) enzyme deficient, while others were considered MMR-proficient. MLH1
and MSH2 immunohistochemistry for MSI screening has earlier been attributed
92.3% sensitivity and 100% specificity in a series of 1,144 cases (Lindor &
Burgart 2002).
Computer-based analysis to calculate tumor infiltrating immune cells (I-III)
Images were captured from the IM and from the stromal and intraepithelial parts
of CT with an Olympus DP25 camera (Olympus, Center Valley, PA) attached to a
Nikon Eclipse E600 microscope (Nikon, Tokyo, Japan) using 20× and 10×
objectives.
The computer-assisted image analyses were conducted using ImageJ v1.44
(Abramoff et al. 2004), a Java-based open source image processing software. The
cell counting method consisted of six phases (Fig. 7). The commands were
recorded as a macro for ImageJ enabling a continuous, automated analysis. To
facilitate quality control, the macro was programmed to save a result image for
each calculation (Fig. 8).
68
a
b
c
d
e
f
g
Fig. 7. Method used for counting immune cells. (a) Original image. (b–g) The cell
counting method consisting of six phases. (b) Rolling ball method for background
subtraction (Sternberg 1983). (c) Color deconvolution for the separation of DAB layer
(Ruifrok & Johnston 2001). (d) Brightness threshold for the acquisition of a binary
image. (e) Gaussian blur for smoothening of the threshold. (f) Watershed method for
the segmentation of cells touching each other (Beucher & Meyer 1993). (g) Analyze
particles tool for calculating the cell count based on the size and shape of the objects
(Abramoff et al. 2004). An ellipse indicates a counted cell.
69
Fig. 8. Result image of the image analysis. Original captured picture (intratumoral
+
CD3 T cells) is presented as the upper image, and the counted cells have been
marked with dark grey shading in the lower image.
70
4.5
Serum analyses (IV)
Preoperative serum samples of Cohort 2 and serum samples of their age- and
gender-matched controls were centrifuged, after which the supernatants were
collected and stored at -70°C until analysis. Serum MMP-8 concentrations were
determined by a time-resolved immunofluorometric assay (IFMA) (Medix
Biochemica, Kauniainen, Finland) according to the manufacturer’s instructions
with a serum dilution of 1:5 (Tuomainen et al. 2007). TIMP-1 ELISA (R&D
Systems, Minneapolis, MN) was performed according to the manufacturer’s
instructions with 1:300 dilutions of the serum.
4.6
Measurement of intra- and inter-observer variation (I, III)
Peritumoral T cells of 34 randomly selected cases were used in testing the validity
of the automated computer-based cell counting method (I). The positive cells
were counted with both automated cell counting method and manually from the
same images by three independent evaluators. Pearson correlation coefficients
were used in the measurement of the accuracy of the computer-based immune cell
counting.
To test the reproducibility of the evaluation of CLR density (III), two
observers independently conducted CLR density evaluations on 43 randomly
selected patients. The agreement was measured for both CLR density as a
continuous variable (Pearson r) and CLR density as two-tiered variable using a
cut-off of 0.38 follicles/mm (κ score).
4.7
Statistical analyses (I-IV)
Normally distributed continuous variables were presented as mean (standard
deviation), whereas other continuous variables were presented as median
(interquartile range). The statistical analyses were carried out using statistical
analysis software PASW Statistics 18 (IBM, Chicago, IL) (IV) or IBM SPSS
Statistics 19 (I-III). Statistical significances of the associations between
categorical and continuous variables were analyzed by Mann-Whitney U test
(comparing two classes) or Kruskal-Wallis test (comparing three or more classes)
(II, III, and IV). The associations between two categorical variables were
analyzed by crosstabulation and χ2 test or Fisher’s exact test (II and IV). Pearson
correlation coefficients (r) were used to assess the correlations between two
71
normally distributed continuous variables (I-IV). Multiple linear regression
analysis was used to model the relationship between two or more explanatory
variables and a response variable (IV). The Kaplan-Meier method and log-rank
test, as well as Cox’s proportional hazards regression models were used in
survival analyses (I, II, and III). In all the tests, a two-tailed, exact p value less
than 0.05 was considered statistically significant.
Receiver operating characteristics (ROC) analysis is a method where
sensitivity and 1-specificity values are plotted at various cut-off points to evaluate
the discriminatory capacity of a marker and to determine optimal threshold values
(Zlobec et al. 2007b). It was used in determining optimal cut-off points with the
shortest distance to the coordinate (0,1) for the categorization of continuous
variables (I-IV).
Hierarchical clustering is a method which aims to identify the structure and
relationships of groups based on a multivariate profile. In hierarchical clustering
of different inflammatory cell types, the nearest neighbor method with
standardized squared Euclidean distance was applied (II), denoting that the
clusters were sequentially combined into larger clusters and two clusters
separated by the shortest distance were combined at each step. The squared
Euclidian distance method increased the importance of large distances while
weakening the importance of small distances.
72
5
Results
5.1
New methods for the evaluation of immune cell reaction
In these studies, two new methods for the evaluation of immune cell infiltration in
CRC were adopted and validated.
5.1.1 Computer-based immune cell counting
To test the accuracy of the new method for automated computer-based immune
cell counting (I), a median of five (range, 2–11) images were obtained from the
IM and a median of four (range, 2–7) from CT-S in the samples of 34 CRC cases.
The CD3+ cell densities were counted with both automated cell counting method
and manually from the same images by three independent evaluators. The
automated cell counting method achieved an almost perfect correlation with
manual cell counting from the same images (Pearson r=960–0.987), indicating
that the automated counting was accurate. The slight variation was found to be a
result of either weakly positive immunoreaction in the T cells or background
staining.
Three additional series of images were captured from the same sections to
map the effect of image capturing on the cell counts and thus evaluate the overall
reproducibility of the immune cell assessment. Although more variation was
observed, the correlations between different image series were still excellent
(Pearson r = 0.832–0.934), indicating that the number of images captured for each
case was adequate.
5.1.2 CLR density
To estimate the reproducibility of the new method for the evaluation of CLR, two
observers independently calculated CLR density (the number of CLR follicles/the
length of the invasive front) on 43 randomly selected patients. After one month,
another CLR density calculation was performed to evaluate the intra-observer
variation. The intra-observer agreement (r=0.970; κ=0.814) and the inter-observer
agreement (r=0.910–0.93; κ=0.720–0.813) were excellent, indicating that the
CLR density evaluation was reproducible.
73
5.2
Immune cell infiltration in colorectal cancer
5.2.1 Characteristics of immune cell infiltration
Of the 117 cases in Cohort 2a, 65 (55.6%) showed a high-grade KlintrupMäkinen score, signifying a band-like inflammatory infiltrate at the IM with
evidence of cancer cell destruction (II). Immunohistochemistry was used to
further characterize the inflammatory infiltrate at the IM and in the CT (Fig. 9).
The CD3+ T cells were the most frequent both at the IM and in the CT, followed
by CD68+ cells, CD8+ T cells, and FoxP3+ T cells. At the IM, the median CD8+
and FoxP3+ T-cell counts were 30.4% and 26.7% of the amount of CD3 + T cells,
respectively, and in the CT-S, 19.3% and 29.8%, respectively. The inflammatory
infiltrate at the IM was, in general, heavier than that in the CT-S.
a
b
c
d
e
f
g
h
Fig. 9. Representative examples of immunohistochemical determination of eight types
+
of immune cells at the invasive margin of colorectal cancer. (a) CD3 T cells. (b) CD8
+
+
+
T cells. (c) FoxP3 T cells. (d) CD68 macrophages. (e) CD83 dendritic cells. (f) CD1a
+
+
dendritic cells. (g) Tryptase mast cells. (h) Elastase neutrophils.
74
+
+
When evaluating CLR (III), at least one peritumoral lymphoid follicle was
recognized in 411 of 418 (98.3%) patients in Cohort 1 and 147 of 149 (98.7%)
patients in Cohort 2 (Fig. 10). No granulomas were detected. CLR density
showed substantial positive correlations with the average follicle diameter
(Cohort 1, Pearson r=0.515; Cohort 2, Pearson r=0.655) and the density of
lymphoid follicles with germinal centers (Cohort 1, r=0.614; Cohort 2, r=0.814).
In most cases, the highest density of the lymphoid aggregates was located at the
border of muscularis propria and serosa (Cohort 1, n=250, 60.8%; Cohort 2,
n=81, 55.1%) or in muscularis propria (Cohort 1, n=123, 29.9%; Cohort 2, n=50,
34.0%).
Fig. 10. Representative example of intensive colorectal cancer associated lymphoid
reaction (CLR), which is defined as lymphoid aggregates surrounding the tumor.
The composition of CLR was analyzed by immunohistochemistry, and CD20+ B
cells had the highest average positive area percentage (60.8% of the follicle),
followed by CD3+ T cells (38.0%), CD68+ cells (11.1%), FoxP3+ T cells (0.40%)
and CD83+ mature DCs (0.36%). Ki-67 immunohistochemistry indicated high
75
proliferation rate at the germinal centers and also a few proliferating cells in the
majority of the lymphoid aggregates without germinal centers.
5.2.2 Interrelationships between different immune cell types
The interrelationships between different inflammatory cells were analyzed by
calculating Pearson’s correlation coefficients and by hierarchical clustering of the
inflammatory cell markers in Cohort 2a (II). Different inflammatory cells had
high positive correlations with each other, except for mast cells and CD1a+
immature DCs, which also clustered furthest from T cells in hierarchical
clustering (Fig. 11). The CD83+ mature DCs clustered with T cells. Immune cell
counts of each cell type within different tumor locations showed substantial
concordance, with Pearson r varying from 0.434 (CD83) to 0.714 (CD3).
0
5
10
15
20
25
CD3, CT-IEL
CD8, CT-IEL
CD8, CT-S
FoxP3, IM
FoxP3, CT-S
CD8, IM
CD3, IM
CD3, CT-S
CD83, IM
CD83, CT-S
CD68, IM
CD68, CT-S
Neutrophil, IM
Neutrophil, CT-S
CD1a, IM
CD1a, CT-S
Mast cell, IM
Mast cell, CT-S
Fig. 11. Hierarchical clustering of eight immune cell types in different tumor locations.
Abbreviations: CT: tumor center; IEL: intraepithelial; IM: invasive margin; S: stromal.
In cohort 2a, a high Klintrup-Mäkinen score associated with higher densities of
CD3+, CD8+, and FoxP3+ T cells, CD68+ cells, CD83+ mature DCs, and
76
neutrophils (II). Although based on the evaluation of the inflammatory reaction at
the IM, the classification had also high correlation with the densities of
inflammatory cells in CT.
In cohort 2a, CLR density had positive correlations with the densities of
CD83+ mature DCs and T cells (CD3+, CD8+ and FoxP3+), whereas neutrophils,
mast cells, CD68+ macrophages and CD1a+ immature DCs did not show
significant associations with CLR density (III).
5.2.3 Relationships between immune cell infiltration and clinical and
pathological variables
In Cohort 2a (II), the Klintrup-Mäkinen score correlated inversely with stage
(p=1.2E−3). In a more detailed analysis, higher TNM stage, in particular stage IV,
associated especially with lower densities of FoxP3+, CD3+, and CD8+ T cells, as
well as CD83+ DCs (Table 26). Conversely, mast cells, stromal CD68+ cells,
stromal CD1a+ cells, and stromal neutrophils did not have significant associations
with stage. CLR density (III) showed a tendency towards higher values in lower
stages in Cohort 2a (Table 26). In Cohort 1, high CLR density associated
significantly with low stage (p=3.2E−3).
77
Table 26. Immune cell infiltration in different stages.
Cell type and location
TNM Stage
p value
I (n=19)
II (n=46)
III (n=32)
IV (n=18)
1120.2 (668.3–
566.9 (397.1–
573.5 (307.9–
205.2 (146.1–
1253.3)
867.7)
927.8)
434.4)
735.1 (412.7–
517.7 (223.9–
379.6 (225.1–
223.6 (110.8–
1187.4)
858.6)
651.5)
510.3)
Immune cells
CD3, IM
CD3, CT-S
CD3, CT-IEL
72.1 (23.9–159.4) 26.1 (10.2–97.8) 22.7 (14.1–78.7) 10.6 (4.8–35.6)
CD8, IM
265.5 (159.4–
184.1 (100.2–
149.5 (74.1–
495.9)
381.1)
436.1)
175.9 (42.2–
98.8 (55.1–210.4) 91.7 (26.8–237.8) 25.6 (13.5–84.7)
CD8, CT-S
1.5E−5
6.6E−3
2.8E−3
95.0 (25.0–176.3) 4.7E−3
8.5E−3
260.3)
CD8, CT-IEL
23.9 (10.6–112.6) 22.0 (6.6–63.3)
27.3 (4.2–59.5)
6.2 (1.7–19.0)
FoxP3, IM
276.7 (222.8–
158.8 (85.3–
147.7 (74.8–
54.2 (27.0–106.6) 1.6E−7
416.2)
312.7)
280.2)
250.9 (156.5–
142.8 (91.0–
121.7 (63.7–
389.2)
381.9)
284.3)
619.0 (269.9–
647.1 (390.1–
495.9 (292.8–
361.1 (246.8–
975.4)
899.9)
778.0)
544.5)
277.9 (186.4–
410.3 (224.2–
393.7 (187.6–
311.3 (189.3–
607.2)
597.0)
637.5)
476.3)
16.2 (11.14–
10.4 (1.8–21.0)
10.6 (5.6–21.8)
4.0 (2.0–11.9)
0.012
5.8 (1.0–15.3)
0.208
FoxP3, CT-S
CD68, IM
CD68, CT-S
CD1a, IM
42.5 (20.2–73.6)
0.012
9.7E−6
0.055
0.629
25.32)
CD1a, CT-S
10.6 (7.6–22.9)
10.1 (2.7–15.3)
7.3 (3.5–12.9)
CD83, IM
14.1 (7.0–21.7)
6.3 (3.24–11.5)
8.57 (2.26–12.7) 2.3 (0.88–6.51)
3.2E−4
CD83, CT-S
7.0 (2.6–16.3)
4.1 (1.7–7.7)
5.4 (2.7–8.7)
8.6E−3
Mast cell tryptase,
65.7 (29.9–105.5) 38. (24.4–82.1)
1.9 (0.55–4.9)
39.9 (24.0–69.8) 39.0 (24.2–50.1)
0.299
56.3 (35.2–91.4) 36.1 (17.4–72.7) 37.2 (25.4–60.5) 39.3 (20.5–46.6)
0.163
98.5 (11.7–397.9) 60.7 (14.1–273.5) 52.1 (10.8–291.5) 9.1 (4.8–40.8)
0.079
56.3 (9.4–123.1) 39.9 (10.6–166.3) 32.5 (7.6–100.8) 25.3 (8.79–128.6)
0.545
IM
Mast cell tryptase,
CT-S
Neutrophil elastase,
IM
Neutrophil elastase,
CT-S
Colorectal cancer associated lymphoid reaction (CLR)
CLR Density
0.44 (0.14–0.93) 0.59 (0.20–0.95) 0.34 (0.15–1.00) 0.27 (0.15–0.69)
0.234
2
Based on cohort 2a. Numbers indicate “median (interquartile range) number of cells/mm ” for immune cells
and “median (interquartile range) number of lymphoid follicles/mm of invasive front” for CLR. P values are for
Kruskal-Wallis test.
78
In cohort 2a, the MMR-deficient cases showed a trend towards a higher KlintrupMäkinen score (p=0.062), and in a detailed analysis, MMR deficiency associated
with increased amounts of CD3+ (IM: p=0.022; CT-S: p=0.223; CT-IEL:
p=0.019) and CD8+ (IM: p=0.014; CT-S: p=0.025; CT-IEL: p=0.013) T cells (II).
MMR deficiency also notably correlated with CLR density (III) (Cohort 1:
p=5.8E−5; Cohort 2a: p=5.2E−3).
5.2.4 Prognostic value
Eighty (68.4%) of the 117 patients in Cohort 2a, of whom 15 (18.8%) had a
recurrence, had 24-month follow-up data for DFS (II), while 350 (83.7%) of the
418 patients in Cohort1 had 60-month follow-up data for CSS (I, III).
Kaplan-Meier analysis in Cohort 2a indicated that four-tiered KlintrupMäkinen score (p=0.024), CD3+ T cells at the IM (p=0.037), as well as FoxP3+ T
cells (IM: p=0.049; CT-S: p=2.7E−3) had significant associations with improved
DFS (II). However, the short follow-up did not enable a construction of sensible
multivariate survival models (II).
In Cohort 1, high CLR density (≥0.38 follicles/mm) (p=4.5E−6) and high
Klintrup-Mäkinen score (p=1.4E−12) were associated with increased CSS (III).
Combined four-tiered evaluation of CLR density and Klintrup-Mäkinen score
improved the discriminatory capacity of the individual markers (p=1.6E−13). Cox
regression analysis indicated that the CLR density (HR 0.54, 95% CI 0.37–0.80)
and Klintrup-Mäkinen score (HR 0.43, 95% CI 0.27–0.67) had prognostic value
independent of TNM classification, WHO grade, tumor location, and MMR
screening status.
In a subset of 235 patients in Cohort 1, it was established that CD3+ T cell
density has prognostic value (HR 0.49, 95% CI 0.28–0.85) independent of TNM
classification, WHO grade, tumor location, and tumor budding (I). However, a
comparative analysis with Klintrup-Mäkinen score and CLR density in a subset of
300 patients in Cohort 1 suggested that CD3+ T cells provide no additional value
relative to Klintrup-Mäkinen score and CLR density (III).
79
5.3
Systemic inflammatory biomarkers in colorectal cancer
5.3.1 Serum MMP-8
The median serum MMP-8 levels of the patients in Cohort 2a was more than three
times higher than that of the age- and gender-matched healthy controls (63.0 vs.
17.2 ng/mL, p=1.5E−9) (IV). A ROC analysis indicated an area under the curve
(AUC) of 0.751 (95% CI 0.685–0.817) in separating the patients from the
controls. Using a cut-off value of 63.4 ng/mL, the specificity was 90.4% and the
sensitivity 50.0%.
Serum MMP-8 levels were next correlated with clinicopathological
characteristics. Higher levels were observed in advanced stage (p=4.5E−4). Of the
inflammatory parameters studied, higher serum MMP-8 levels associated with a
lower Klintrup-Mäkinen score (p=0.041) and lower-grade CLR (p=0.0057). A
positive correlation was observed between serum MMP-8 levels and the extent of
tumor necrosis (p=0.0024). Of the hematological parameters, high S-MMP-8,
most notably, associated with high blood neutrophil count (Pearson r=0.523). In a
multiple linear regression model, the four best predictors of high serum MMP-8
levels were high blood neutrophil count, the presence of distant metastases, lowgrade CLR and low BMI.
Possible sources of elevated serum MMP-8 levels in CRC were further
evaluated by immunohistochemical examination of the tumor specimen. In all
five tumor samples analyzed, necrotic areas and neutrophils were constantly
positive for MMP-8. The expression of MMP-8 in a few cancer cells, restricted to
0.1–5% of the cells, was identifiable in two of the five tumor samples. The cancer
cells expressing MMP-8 were not located in any particular part within the tumors.
Epithelial cells in normal colon mucosa did not express MMP-8.
5.3.2 Other markers
The correlations between CLR density and several markers of systemic
inflammation were studied in Cohort 2a (III). However, no significant
correlations were found between CLR density and blood leucocyte counts
(p=0.159-0.865), CRP (p=0.064), and GPS (p=0.441).
80
6
Discussion
For the past decades, the prognostication in CRC has been based on TNM staging
(Sobin et al. 2009). In patients operated on in the 1990s, five-year OS was 65%,
ranging from 90% in stage I to less than 10% in stage IV (O’Connell et al. 2004).
However, molecular heterogeneity of the disease warrants the search for
additional, complementary prognostic markers (Jass 2007b).
It has been established that the immune system and immune cell infiltration
influence cancer outcome (Fridman et al. 2012, Shankaran et al. 2001), and there
is an international initiative to incorporate immune cell infiltration into cancer
classification (Galon et al. 2012, 2014). Accurate analysis methods are important
for reliable and reproducible results. The present studies validate new, objective
methods for the analysis of immune cell infiltration and provide insight into the
significance of various immune cell types and inflammatory markers in CRC.
6.1
New methods for the evaluation of immune cell reaction
A new method for immune cell counting — based on separating DAB and
hematoxylin color layers with ImageJ, a freely available image analysis software
— was described and was found accurate (I). The quantitative evaluation of CLR
density was also established to show excellent intra-observer and inter-observer
agreement (III).
6.1.1 Computer-based immune cell counting
Earlier, studies have utilized a variety of methods in the analysis of immune cell
infiltration in CRC, each with a number of advantages and disadvantages. Manual
classification into two to four categories has been commonly used and is quick to
conduct (Forssell et al. 2007, Graham & Appelman 1990, Jass et al. 1987, Naito
et al. 1998). However, it is subjective and the lack of continuous variables also
limits the applicability of statistical methods including ROC analysis and linear
regression and can lead to difficulties in comparing the results of different studies
(Walker 2006, Zlobec et al. 2007b). Manual cell counting from captured images is
exact, if performed carefully, and it was used as a method to compare with
automated computer assisted cell counting. It was found that cell counts
determined by automated cell counting had nearly perfect correlation with the
manual cell counts from the same images (Pearson r=960-0.987), indicating that
81
the adopted counting method was accurate. Supporting the rationale behind the
computer-assisted counting relative to manual counting, computer-assisted
counting needs only to be supervised whereas manual counting is time-consuming
(Ong et al. 2010).
Since the late 1980s when the first methods were developed (Bacus et al.
1988), the precision of commercially available computer-based platforms for the
analysis of immunohistochemistry has been proven in a number of applications,
including the analysis of estrogen receptor status in breast cancer (Gokhale et al.
2007), cytokeratin expression in CRC (Ong et al. 2010), immune cell counting in
CRC (Pagès et al. 2005) and Hodgkin lymphoma (Lejeune et al. 2008). However,
the availability of commercial automated analysis equipment is still limited.
Therefore, freely available methods, such as the one that was adopted and
validated in Study I, offer a valuable opportunity to improve the accuracy of the
analysis of immunohistochemistry.
ImageJ is free image analysis software that is widely used in medical research
(Abramoff et al. 2004), including analysis of radiography (Sustercic & Sersa
2012, Tharwat et al. 2014) and immunohistochemistry (Ozerdem et al. 2013,
Tuominen et al. 2012). It offered a versatile platform to combine functions that
had earlier been described into a macro, which was capable of accurately
counting immune cell densities in the CRC specimens. A slightly modified
version of the macro would also be able to count the percentage of positive
nuclei. Indeed, although independently compiled, Immunoratio — a plugin for
ImageJ that was validated for the analysis of estrogen receptor, progesterone
receptor and Ki-67 — is based on many of the same functions that were used in
the immune cell counting macro validated in this study (Tuominen et al. 2010).
Moreover, Immunomembrane — a plugin for ImageJ capable of the evaluation of
membranous human epidermal growth factor receptor 2 staining — was recently
released (Tuominen et al. 2012). Thus, a variety of ImageJ-based tools for the
analysis of immunohistochemistry now exist and image analysis based on the
same approaches can also be carried out using other freely available image
analysis programs like CellProfiler (Lamprecht et al. 2007).
The potential sources of error in new methods need to be identified (Walker
2006) (Table 27). In Study I, the minor differences in the cell counts by the
computer-aided method and manual counting from the same images mostly
resulted from either substantial background staining or weak positivity in the
desired cells. Those differences could be detected by the revision of the result
82
images created by the cell counting macro (Fig. 8), which is an important part of
quality control when utilizing the automated cell counting method.
Table 27. Potential sources of error in automated cell counting and methods of their
prevention.
Type of error
Source
Method of prevention
1. Immunopositive cell counted as A. Weak positivity in the
Standardized and validated staining
negative
protocols, e.g., specific antibodies,
desired cells
standardized section thickness and
incubation practices, and proper
positive and negative controls
2. Immunonegative cell counted
B. Too high upper threshold
Adequate familiarization with the
value for cell size
counting method and its calibration
C. Too low upper threshold
Adequate familiarization with the
value for brightness
counting method and its calibration
A. Background staining
Standardized and validated staining
as positive
protocols
B. Too low lower threshold
Adequate familiarization with the
value for cell size
counting method and its calibration
C. Too high upper threshold
Adequate familiarization with the
value for brightness
counting method and its calibration
3. Part of background counted as A. Background staining
Standardized and validated staining
positive
protocols
B. Too high upper threshold
Adequate familiarization with the
value for brightness
counting method and its calibration
4. Two or more cells touching
Inadequate segmentation
Development of an improved
each other counted as one
method
segmentation method; However, rarely
5. One cell counted as two or
Inadequate segmentation
Development of an improved
more cells
method
segmentation method; However, rarely
causes significant error
causes significant error
6.1.2 CLR density
CLR density calculation was described as a new, objective method to
quantitatively evaluate the transmural lymphoid reaction surrounding colorectal
tumors (III). As computer-based immune cell counting, it benefits from
objectivity and the applicability of statistical methods such as ROC analysis and
linear regression (Walker 2006, Zlobec et al. 2007b). Earlier, qualitative criteria
suggested by Graham and Appelman (1990) have been frequently utilized, but our
83
results indicate that the prognostic value of CLR density is superior to GrahamAppelman criteria. Recently, also another suggestion for objective criteria for the
evaluation of CLR was made (Ueno et al. 2013). The researchers found that the
size of the largest lymphoid aggregate of 1 mm or higher strongly associated with
lower recurrence and improved survival independent of tumor stage. This method
yielded a κ score of 0.67 for inter-observer agreement, which was comparable to
that of CLR density in this study (inter-observer κ=0.720–0.813). Future studies
are required to evaluate whether a combined evaluation of CLR density and
follicle size can improve the prognostic value relative to individual evaluations.
6.2
Immune cell infiltration in colorectal cancer
The densities of eight inflammatory cell types — including markers of both
adaptive (CD3, CD8, and FoxP3) and innate immunity (CD68, neutrophil
elastase, and mast cell tryptase), as well as antigen-presenting cells (APCs)
(CD1a, CD68, and CD83) serving as a link between the two (Banchereau et al.
2000) — were calculated in Cohort 2 utilizing the computer-assisted method to
enlighten the interrelationships between different types of tumor-infiltrating
immune cells in CRC (II). Also CLR density was correlated with other markers
(III). The results indicated that there are high positive correlations between the
densities of tumor-infiltrating CD3+, CD8+, and FoxP3+ T cells, CD83+ DCs,
CD68+ macrophages, and neutrophils, whereas CD1a+ DCs and mast cells show
weaker correlation with other cell types.
6.2.1 T cells in colorectal cancer
T lymphocytes, the hallmark of cell-mediated adaptive immunity, are considered
essential in tumor immunosurveillance (Schreiber et al. 2011, Shankaran et al.
2001), and their abundance has been associated with improved survival in CRC
(Table 15) as well as in other solid tumors (Fridman et al. 2012). The results of
these studies support their prognostic value, since CD3+ T cells at the IM, as well
as FoxP3+ T cells at the IM and in the CT-S associated with improved DFS in 24month follow-up in Cohort 2a (II), and the density of CD3+ T cells predicted
improved CSS in a subset of 235 patients of Cohort 1 independent of tumor stage
(I). Different types of T cells had high positive correlations between each other
and formed a group on the top of the dendrogram in the hierarchical cluster
analysis (Fig. 11).
84
Some discrepancy exists about the significance of TReg cells in cancer. High
TReg cell infiltration has been associated with poor survival in, e.g., ovarian
(Curiel et al. 2004) and breast cancer (Bates et al. 2006), which is in accordance
with the role of TReg cells in suppressing the immune responses (Zou, 2006).
However, the results of these studies support the majority of the published results
associating TReg cells with a favorable outcome in CRC (Table 16) since a high
FoxP3+ T-cell count in the CT-S had the highest association with improved DFS
of all the individual cell markers and FoxP3+ T cells clustered along with other T
cells in hierarchical clustering analysis (Fig. 11) (II). The mechanisms accounting
for the impact of TReg cells in CRC and for the inconsistencies in their roles in
different cancers merit further research.
6.2.2 Dendritic cells in colorectal cancer
DCs are important APCs responsible for the induction of adaptive immune
responses (Banchereau et al. 2000). After capturing antigens, immature DCs
mostly reside in lymph nodes to mature and present antigens to T cells. The
significance of tumor-infiltrating mature DCs in CRC immunity was originally
described by Suzuki et al. (2002), who found that mature DCs make small
aggregates with T cells in the IM of CRC to promote T-cell activation. In
agreement with this finding, high numbers of mature DCs were found both at the
IM and in the CT-S (II). This suggests that after antigen capture, some of the DCs
reside in tumor stroma, mature, and potentially contribute to T-cell activation.
This phenomenon has also been reported to occur in other malignancies, such as
non-small-cell lung cancer (Dieu-Nosjean et al. 2008). The results of this study
indicate that CD1a+ immature DCs do not associate with tumor stage and they
also clustered far apart from other cells in hierarchical clustering, whereas CD83 +
mature DCs had a strong association with lower stage and clustered along with
CD3+ T cells (Fig. 11). This result supports the importance of tumor-infiltrating
mature DCs in effective T cell responses against the tumor and encourages further
studies to address different DC subtypes in CRC.
6.2.3 Colorectal cancer associated lymphoid reaction
Study III evaluated the significance of CLR by correlating CLR density with
clinicopathological variables and the densities of tumor-infiltrating immune cells.
Of all the analyzed cell types, the number of peritumoral CD83+ mature DCs had
85
the highest positive correlation with CLR density (III), suggesting an important
role for mature DCs in the development of CLR or shared background factors
between mature DCs and CLR. CLR density also notably correlated with the
densities of T cells at the IM and in the CT. High CLR density was associated
with low tumor stage, but also correlated with better survival regardless of stage.
Moreover, high Ki-67 activity was observed in the germinal centers of CLR
follicles, pointing out that it represents an area of immune cell proliferation.
Taken together, these findings suggest that CLR contributes to the adaptive
antitumor immunity along with T cells and mature DCs.
Shortly after Study III was published, also another study evaluating the
structure of CLR and its relation to tumor infiltrating T cells and patient survival
was released (Di Caro et al. 2014). The authors added to the structural analysis
that we conducted by demonstrating that the lymphoid follicles surrounding the
tumors contained peripheral node addressin expressing high-endothelial venules
(Di Caro et al. 2014), which have shown to enable circulating lymphocytes to
directly enter the tissue (Aloisi & Pujol-Borrell 2006). This finding further
enlightens the mechanisms of CLR formation. Moreover, utilizing a retrospective
cohort of 351 stage II and III CRC patients, the authors confirmed our results of
intensive CLR associating with increased numbers of tumor-infiltrating T cells
and beneficial clinical outcome (Di Caro et al. 2014).
The adaptive immune responses against the tumor are modulated by tumor
immunogenicity (Buckowitz et al. 2005, Shankaran et al. 2001). Present in about
15% of CRC (Boland & Goel 2010), MSI induces the generation of novel tumorspecific frameshift peptides (Schwitalle et al. 2008), potentially increasing the
immunogenicity. Accordingly, MMR deficiency associated with high CLR
density (III) and high densities of CD3+ and CD8+ T cells (II). However, the
prognostic value of CLR density was independent of MMR deficiency (III),
suggesting that CLR likely also reflects several other tumor- and host-related
factors accounting for tumor immunogenicity, potentially including, e.g.,
decreased HLA expression (Simpson et al. 2010).
6.2.4 Future perspectives
There is a need to standardize the analysis of immune cell infiltration in CRC to
provide a useful prognostic and potentially predictive tool (Galon et al. 2014,
2012). The stage-independent prognostic value of T cells has been convincingly
demonstrated (Table 15), and there is also an international initiative to incorporate
86
Immunoscore into cancer classification (Galon et al. 2012, 2014). The results of
these studies support the validity of CD3 and CD8 as representative inflammatory
markers in CRC (I, II). Furthermore, the results propose that the computation of
cell densities from multiple locations improves the prognostic value relative to the
determination in one location (I). However, the Cox regression models (III)
suggest that CD3 immunohistochemistry does not give any additional prognostic
value compared with inflammatory reaction scoring from the H&E stained
sections (Klintrup-Mäkinen score and CLR density). Also another study was
recently published which indicated that Immunoscore and the Klintrup-Mäkinen
score exhibit similar survival relationships (Richards et al. 2014).
However, the evaluation of the Klintrup-Mäkinen score is subjective, while
Immunoscore counting, CLR density calculation, and other evaluations based on
cell or structure counting benefit from higher objectivity and continuous nature of
gathered data. Therefore, these types of evaluations are more likely to yield
reproducible information that can subsequently be applied into clinical decisionmaking in the Western world. Especially, ongoing large scale studies are expected
to validate the clinical significance of the densities of tumor-infiltrating T cells
(Galon et al. 2014). Conversely, the evaluation of immune cell infiltration from
H&E slides has the advantage of lower cost and better availability of the
methodology, which could be valuable for countries with no financial resources
for immunohistochemical or molecular biological approaches.
In future, the evaluation of immune cell infiltration has also potential to help
to predict the response to the treatments in CRC and other malignancies (Ascierto
et al. 2013). Ipilimumab — a monoclonal antibody against cytotoxic T
lymphocyte associated antigen (CTLA-4), a protein receptor that downregulates
the immune system — has recently been introduced in the treatment of metastatic
melanoma with promising results (Hodi et al. 2010) and other immunomodulative
treatments, including programmed death 1 (PD-1) antagonists (Hamid et al. 2013)
and OX40 agonists (Curti et al. 2013), are currently evaluated in clinical trials.
No predictive markers for ipilimumab treatment in melanoma have yet been
established, although a recent study associated a high number of tumorinfiltrating FoxP3+ cells with a positive response to therapy (Hamid et al. 2011).
A number of studies have also evaluated immunomodulative therapies in CRC but
the results have been less promising than in melanoma. For example, in patients
with metastatic CRC in whom standard treatments had failed, tremelimumab, a
CTLA-4 monoclonal antibody, did not show clinically meaningful single-agent
activity (Chung et al. 2010). However, extensive research on potential
87
immunomodulative therapies in CRC is ongoing, and because of its strong
prognostic value, it is also under investigation whether the immune cell infiltrate
predicts response to traditional adjuvant treatments in, e.g., stage II CRC patients
(Galon et al. 2012). Interestingly, a recent study based on 55 patients indicated
that the density of CD3+ and CD8+ T cells in the preoperative rectal cancer
biopsies could predict the response to neoadjuvant CRT (Anitei et al. 2014).
However, the results need to be validated before they can be applied into clinical
practice.
6.3
Systemic inflammatory biomarkers in colorectal cancer
In Study IV, it was established that the median serum MMP-8 level of CRC
patients is more than three times higher than that of age- and sex-matched
controls. Earlier, serum or plasma levels of MMP-8 have been shown to be
elevated, e.g., in Helicobacter pylori gastritis (Rautelin et al. 2009) and several
cardiovascular diseases (Pradhan-Palikhe et al. 2010, Tuomainen et al. 2007).
MMP-8 plays a notable role in regulating inflammatory reactions. Produced
mainly by neutrophils, it has been thought to contribute particularly to the acute
inflammation (Van Lint & Libert 2006) by the cleavage of chemokines and
cytokines such as CXCL5, CXCL8, CXCL9 and CCL2 to either inactivate them
or increase their potency (Van Lint & Libert 2007). In a MMP-8 knockout mouse
skin cancer experiment, Balbin et al. (2003) observed that one day after
carcinogen injection, MMP-8-deficient mice developed a weaker and more
diffuse neutrophil influx to the area of carcinogen injection than wild-type mice.
However, 7 to 28 days after the injection, a sustained inflammatory response was
observed in the MMP-8-deficient mice. This suggests that MMP-8 contributes to
neutrophil recruitment during acute inflammation but is also involved in resolving
chronic inflammation, which is supported by subsequent studies (Cox et al. 2010,
Gutierrez-Fernandez et al. 2007). Based on this experimental data, it can be
hypothesized that the association between lower serum MMP-8 and more intense
CLR might stem from the proteolytic modification of chemokines and cytokines
by MMP-8. During the progression of CRC, the excess of MMP-8 might help to
resolve the immune response against the tumor, thus contributing to tumor escape
from immunosurveillance. However, the hypothesis needs to be addressed by
further studies with a more experimental study design.
No peripheral blood markers are currently regularly used in the screening or
diagnostics of CRC, while CEA is the marker most frequently used in the follow88
up (Sturgeon et al. 2008). In this study, serum MMP-8 achieved a good accuracy
in separating CRC patients from healthy controls with an AUC of 0.751 in ROC
analysis. However, the study has its limitations in this regard, because only the
differences in serum MMP-8 between CRC patients and healthy age and gender
matched controls were analyzed, instead of patients with gastrointestinal
symptoms. Therefore, the potential value of serum MMP-8 in CRC screening,
diagnostics or surveillance needs to be confirmed by subsequent studies.
89
90
7
Conclusions
The present studies enlighten the significance of various immune cell types and
inflammatory biomarkers in CRC. Based on the results, the following conclusions
were made:
1.
2.
3.
4.
5.
6.
Color layer separation based image analysis provides an accurate and
reproducible method for counting immune cells in CRC. CLR density
counting is a reproducible method for the evaluation of CLR.
There are high positive correlations between the densities of tumor
infiltrating CD3+, CD8+, and FoxP3+ T cells, CD83+ DCs, CD68+
macrophages, and neutrophils, whereas CD1a+ DCs and mast cells show
weaker correlation with other cell types.
High T cell density in the tumor samples predicts a favorable outcome in
CRC.
High CLR density correlates with low tumor stage, but also correlates with
better survival regardless of stage, suggesting that it represents a relevant
prognostic indicator in CRC. The numbers of tumor-infiltrating T cells
correlate closely with the CLR density, suggesting that the CLR plays a role
in adaptive antitumor immunity.
Intense CLR associates with low serum MMP-8 levels, suggesting that
MMP-8 may reflect or be involved in the regulation of CRC-associated
inflammatory reactions.
Serum MMP-8 shows a good accuracy in discriminating the CRC patients
from healthy controls but its potential value in CRC diagnostics, surveillance,
and prognostication remains to be determined.
91
92
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121
122
Original publications
I
Väyrynen JP, Vornanen JO, Sajanti S, Böhm JP, Tuomisto A, & Mäkinen MJ (2012) An
improved image analysis method for cell counting lends credibility to the prognostic
significance of T cells in colorectal cancer. Virchows Arch. 460(5): 455–465.
II Väyrynen JP, Tuomisto A, Klintrup K, Mäkelä J, Karttunen TJ, & Mäkinen MJ (2013)
Detailed analysis of inflammatory cell infiltration in colorectal cancer. Br. J. Cancer
109(7): 1839–1847.
III Väyrynen JP, Sajanti SA, Klintrup K, Mäkelä J, Herzig K-H, Karttunen TJ, Tuomisto A,
& Mäkinen MJ (2014) Characteristics and significance of colorectal cancer associated
lymphoid reaction. Int. J. Cancer 134(9): 2126–35.
IV Väyrynen JP, Vornanen J, Tervahartiala T, Sorsa T, Bloigu R, Salo T, Tuomisto A, &
Mäkinen MJ (2012) Serum MMP-8 levels increase in colorectal cancer and correlate with
disease course and inflammatory properties of primary tumors. Int. J. Cancer 131(4):
E463–74.
Reprinted with permission from Springer (I), Nature Publishing Group under a
Creative Commons Attribution-NonCommercial-ShareAlike 3.0 Unported
License (II), and John Wiley & Sons (III, IV).
Original publications are not included in the electronic version of the dissertation.
123
124
ACTA UNIVERSITATIS OULUENSIS
SERIES D MEDICA
1254. Finnilä, Mikko A. J. (2014) Bone toxicity of persistent organic pollutants
1255. Starck, Tuomo (2014) Dimensionality, noise separation and full frequency band
perspectives of ICA in resting state fMRI : investigations into ICA in resting state
fMRI
1256. Karhu, Jaana (2014) Severe community- acquired pneumonia – studies on imaging,
etiology, treatment, and outcome among intensive care patients
1257. Lahti, Anniina (2014) Epidemiological study on trends and characteristics of
suicide among children and adolescents in Finland
1258. Nyyssönen, Virva (2014) Transvaginal mesh-augmented procedures in gynecology
: outcomes after female urinary incontinence and pelvic organ prolapse surgery
1259. Kummu, Outi (2014) Humoral immune response to carbamyl-epitopes in
atherosclerosis
1260. Jokinen, Elina (2014) Targeted therapy sensitivity and resistance in solid
malignancies
1261. Amegah, Adeladza Kofi (2014) Household fuel and garbage combustion, street
vending activities and adverse pregnancy outcomes : Evidence from Urban Ghana
1262. Roisko, Riikka (2014) Parental Communication Deviance as a risk factor for
thought disorders and schizophrenia spectrum disorders in offspring : The Finnish
Adoptive Family Study
1263. Åström, Pirjo (2014) Regulatory mechanisms mediating matrix metalloproteinase8 effects in oral tissue repair and tongue cancer
1264. Haikola, Britta (2014) Oral health among Finns aged 60 years and older :
edentulousness, fixed prostheses, dental infections detected from radiographs
and their associating factors
1265. Manninen, Anna-Leena (2014) Clinical applications of radiophotoluminescence
(RPL) dosimetry in evaluation of patient radiation exposure in radiology :
Determination of absorbed and effective dose
1266. Kuusisto, Sanna (2014) Effects of heavy alcohol intake on lipoproteins,
adiponectin and cardiovascular risk
1267. Kiviniemi, Marjo (2014) Mortality, disability, psychiatric treatment and medication
in first-onset schizophrenia in Finland : the register linkage study
1268. Kallio, Merja (2014) Neurally adjusted ventilatory assist in pediatric intensive care
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D 1269
OULU 2014
UNIV ER S IT Y OF OULU P. O. BR[ 00 FI-90014 UNIVERSITY OF OULU FINLAND
U N I V E R S I TAT I S
S E R I E S
SCIENTIAE RERUM NATURALIUM
Professor Esa Hohtola
HUMANIORA
University Lecturer Santeri Palviainen
TECHNICA
Postdoctoral research fellow Sanna Taskila
ACTA
IMMUNE CELL INFILTRATION
AND INFLAMMATORY
BIOMARKERS IN
COLORECTAL CANCER
MEDICA
Professor Olli Vuolteenaho
SCIENTIAE RERUM SOCIALIUM
University Lecturer Veli-Matti Ulvinen
SCRIPTA ACADEMICA
Director Sinikka Eskelinen
OECONOMICA
Professor Jari Juga
EDITOR IN CHIEF
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ISBN 978-952-62-0640-0 (Paperback)
ISBN 978-952-62-0641-7 (PDF)
ISSN 0355-3221 (Print)
ISSN 1796-2234 (Online)
U N I V E R S I T AT I S O U L U E N S I S
Juha Väyrynen
E D I T O R S
Juha Väyrynen
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