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Transcript
Genetic Profiling of Changes Underlying Different Sized Human Rotator Cuff Tendon Tears
+1Chaudhury, S; 1Xia, Z; 1Hulley, PA; 2Marchi, E; 1Carr, AJ
+1Nuffield Department of Orthopedics, Rheumatology and Musculoskeletal Sciences, University of Oxford, Oxford, UK
2
Bioinformatics Department, Institute Molecular Medicine, University of Oxford, Oxford, UK
[email protected]
INTRODUCTION:
Successfully managing rotator cuff (RC) tears remains a challenge
due to high failure rates following surgical repairs. There is increasing
evidence for a multi-stage model of RC tendon tears, wherein healing is
affected by tear size. Larger tears are associated with poorer scores and
function, and are more likely to re-rupture after surgical repairs
compared to smaller tears [1]. The aetiology of RC tears is not a purely
mechanical phenomenon, but also involves underlying biochemical
changes which are often classified as part of intrinsic degeneration.
Recent evidence suggests that the cellular, vascular and extracellular
matrix composition, as well as the metabolism and viability, of the torn
tendon edge changes significantly as the tear size increases [2]. The
underlying pathophysiology however is not fully understood. Changes
in the production and remodelling of the RC extracellular matrix (ECM)
are likely to be important determinants of RC tendinopathy as they affect
structural integrity and the ability to transmit loads.
Microarray analysis allows identification of changes in mRNA
transcription for thousands of genes. This technology has previously
demonstrated upregulation of cytokines and apoptosis markers in torn
human and rat tendons [3]. Understanding alterations in gene expression
between tear groups may offer greater insight into tear pathogenesis, as
well as differences in healing and failure rates. By identifying
modifiable targets related to failure, this important knowledge may help
to guide treatment strategies and future research.
It was hypothesized that massive human RC tendon tears will have
different gene expression profiles when compared to normal RC
tendons. We also hypothesized that massive tendon tears can be
differentiated from smaller tendon tears using microarray analysis. We
hypothesized that many of the altered genes will be related to the ECM
composition, as it plays a fundamental role in tendon structure and
transmission of loads. This study aimed to perform the first genome
wide microarray analysis of differences in human gene expression
profiles between normal, small and massive RC tendons tears.
METHODS:
The gene expression profiles of 28 human RC tendons were analyzed
using microarrays representing the entire genome. 11 massive (>5cm)
and 5 small (<1cm) chronically torn RC tendon specimens were
obtained intraoperatively from tear edges, and compared to 12 age and
gender matched normal controls. Approval for the study was obtained
from our institutional review board.
RNA was extracted from the small biopsy specimens. To ensure
high quality RNA, only specimens with an RNA integrity number of
greater than 6.8 were used. Gene expression analysis was conducted
using Agilent single color arrays. 28 microarrays were run with >
44,000 probes which hybridized with fluorescent labeled cDNA, and
were detected by scanning. Microarray data analysis was performed
using GeneSpring GX and TIGR MeV software. Genes were considered
to be significant if they had a more than 2 fold change and p < 0.05
(Mann Whitney test). To assess changes in specific pathways and
functional groups, the microarray data was analysed using Gene
Ontology terms and with Gene Set Enrichment Analysis.
To validate altered genes and pathways suggested by the microarray,
real-time quantitative polymerase chain reaction (rtq-PCR) was used to
confirm expression for selected genes: matrix metalloproteinase (MMP)3, interleukin (IL)-8, a disintegrin and metalloproteinase (ADAM)-15,
forkhead box (FOX)-F2 and aggrecan (ACAN). GAPDH was used as a
housekeeper to assess the accuracy of the PCR technique. Altered
protein expression was confirmed using immunohistochemistry.
specifically for MMP-3, BMP-5 and SAA.
RESULTS:
Numerous insightful gene changes and pathway changes were detected.
165 genes had altered expression between the normal and small tears
group, 181 between small and massive tears, and the greatest number of
258 genes changed in massive tears compared to normals.
We focused upon genes related to ECM components. Expression of
genes encoding collagen 4,12 and 14 was downregulated in small tears
rather than massive tears whereas the collagen 9 gene COL9A3 was
downregulated in both small and massive tears. With regards to ECM
remodeling, MMP-3,-10,-12,-13,-15, -21,-25 and ADAMs-12,-15,-22
were significantly upregulated in tears. Other key changes included
upregulation of aggrecan in massive tendon tears compared to normal
controls, but not in small tears (p < 0.05, > 2-fold change). Amyloid A1
was downregulated in the small and massive tear groups when compared
to normals, but was unchanged between the tears groups. BMP-5 was
upregulated in small tears only when compared to normals. Some genes
related to the FOX family were both up and downregulated. As part of
the chemotaxis pathway, IL-3,-10,-13,-15,-18 were upregulated in tears,
whereas downregulation of IL-1,-8,-11,-27, was seen. Previously
reported gene expression changes in heat shock proteins, IL-1, MMP-3
and cyclooxygenase (COX-1) were also detected by our microarray
analysis [4]. Common tendon markers such as scleraxis, decorin and
tenascin-C were not altered between normal and torn rotator cuff groups.
However tenomodulin showed a >2-fold increase between normal and
small tears, as well as between small and massive tears.
Gene changes suggested by the microarray were also detected using
qRT-PCR. Immunohistochemistry confirmed increased BMP-5
expression in small tears, and increased MMP-3 expression in both small
and massive tears compared to normal tendons.
Figure 1: Expression profiles of normal, small and massive rotator cuff
tendon samples displayed as a heat map. The x-axis shows distinction
between normal and all torn tendons, with a small degree of overlap
between small and massive tears. Expression profiles are indicated by
red (upregulation) and green (repression).
DISCUSSION:
This study is the first genome wide analysis of rotator cuff tears to
our knowledge. The gene expression profiles of normal, small and
massive RC tear groups suggested they are biologically distinct groups.
We have identified a significant role for ECM related genes such as
MMPs and ADAMs in RC tear pathogenesis. This suggests that
upregulation of the reported ECM genes may play key roles in the
development of tears, as they may reflect a disruption in the balance
between ECM synthesis and degradation. Aggrecan was specifically
upregulated in massive tears, suggesting a potentially important role for
chondroplasia in the pathogenesis of massive tears. BMP-5 upregulation
may contribute to the development or healing response to small tears.
Our study confirmed altered gene expression in pathways reported in
previous studies, and has identified a number of novel pathways which
are affected between the different tendon groups studied. The
highlighted changes in MMPs in either pathogenesis or adaptation to
tears, encourage further studies about the suggested role of MMP
inhibitors in the treatment of RC tendon tears as MMPs are critical for
healing and cell migration [5]. Further investigation is required to
determine whether some of these genes may potentially have a role as
biomarkers of failure. Modulating these ECM pathways may be a useful
treatment strategy for improving clinical outcomes.
REFERENCES:
1. Sugaya, H., et al., JBJS, 2007. 89A(5): p. 953-960.
2. Matthews, T.J.W., et al., JBJS(B), 2006. 88(4): p. 489-495.
3. Millar, N.L., et al.,JBJS(B), 2009. 91B(3): p. 417-424.
4. Blaine, T.A., et al., JSES, 2005. 14(1): p. 84S-89S.
5. Bedi, A., et al., JSES. 2010. p. 384-91.
Paper No. 397 • ORS 2011 Annual Meeting