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Methods to Detect Microbes in the Environment
ENVR 133 – Part 2
Mark D. Sobsey
Detection of Pathogens by Detection and
Amplification of Nucleic Acids
Nucleic Acid Hybridization: potentially very useful, but:
(i) high detection limits (about 100-1000 genomic targets or
more)
(ii) large sample volumes; impractical for most hybridization
protocols without further concentration
(iii) hybridization reaction failures (false negatives)
and ambiguities (false positives) due to sample-related
interferences and non-specific reactions, and
(iv) uncertainties about whether positive reactions are truly
indicative of infectious pathogens.
2
Some Methods for Molecular Genetic Detection & Typing of Microbes
Method
Basis
Resolution
Advantages
Disadvantages
Gene Probes
(Nucleic Acid
Hybridization)
Genome segment
length
polymorphism
analysis:
electropherotyping
PCR and
RT-PCR
Probe
Specificity
Variable:
formatspecific
Subtypes
Easy; Rapid;
Low/Med. $
Insensitive
Must amplify
RFLP Analysis,
PFGE, Ribotyping
Oligonucleotide
fingerprinting
Restriction Variable
enzyme
cuts
RNAaseT1 Subtypes
cleavage
RNase protection
assay
Probe
specificity
Segment
length
Primer
Specificity
Variable
Subtypes
Easy, Rapid, Low $ Does not detect mutations,
Only applicable to
segmented genomes (some
viruses), Insensitive (needs
high titer)
Moderate Difficulty; Technical; Variable Time,
Flexible; Specific; Med. $; Product
Varuable Speed;
Confirmation Needed
Moderate $
Easy-Moderate,
Need restriction sites and
Rapid, Variable $
good enzymes. Consider
variability of target NA
Applicable to RNA; Technical electrophoresis
Detects point
method; Med. $
mutations
Applicable to RNA Technical; Uses radioactive
viruses & other
probe
RNA
3
Progress in Detection of Environmental Pathogens by
Nucleic Acid Hybridization
Cons: early 1990s
•
•
•
•
High detection limits (>1000 genomic targets)
Sample volumes too large without concentration
False (-) and false (+) due to sample interferences
Uncertain if positive reactions truly indicate infectious pathogens
Pros: late 1990s
• Confirm identity of PCR and RT-PCR products
– Oligoprobe hybridization
• Detect PCR products as they are generated
– Labeled primers
• Simultaneously genotype many gene targets with multiple probes
– Reverse Line Blot Hybridization Assay (caliciviruses)
4
Agarose Gel Electrophoresis
• Separate nucleic acid fragments in
an agarose gel
• Resolves small DNA molecules:
0.1 to 50 kb
• % agarose determines resolution
of DNA size:
– 0.3% w/v: resolves 5 to 50 kb
– 2% w/v resolves 0.1 to 2 kb
• Resolving large molecules (up to
500 kb) requires specialized
methods
– Pulse-field gel electrophoresis
(PFGE)
DNA
marker
ladder
Specific
DNA
fragment
5
Direct Detection of Viruses and Other Microbes by
Nucleic Acid Amplification
For viruses not growing in lab hosts:
• Detect directly by in-vitro amplification of their nucleic
acids
• PCR (DNA viruses) or RT-PCR (RNA viruses)
• Amplify nucleic acids (105-106 times)
– Detect by oligoprobe hybridization
OR:
• Amplify nucleic acids and detect in real-time by
fluorescent signal as primers are incorporated during
amplification
– Taqman PCR with LightCycler
6
Nucleic Acid Amplification - PCR
7
Example: RT-PCR and Oligoprobe Detection of
Enteroviruses in Water
•Filter
•Elute
•Precipitate
•Extract RNA
•RT-PCR
•Oligoprobe
(10 ul sample)
8
Real-Time PCR and Quantitative Fluorogenic Detection
• Molecular beacon. Several 5'
bases form base pairs with
several 3' bases; reporter and
quencher in close proximity.
– If reporter is excited by light,
its emission is absorbed by
quencher & no fluorescence is
detected.
• Detection of PCR product by
molecular beacon.
– Beacon binds to PCR product
and fluoresces when excited
by the appropriate  of light.
– [Fluorescence] proportional to
[PCR product amplified]
9
Real-Time, Multiplex RT-PCR:
Hepatitis A Virus (HAV) and Enteroviruses (EV)
• Fluorescent probes to
simultaneously detect HAV and EV
(CVB3).
• HAV and EV primer pairs gave
predicted 244 and 145-bp products.
– Detect <10 genomic RNA copies
• Evaluated for virus detection in
spiked water concentrate.
• Fluorogenic reporter probes (FAMand ROX-labeled) specifically
detected HAV or enterovirus,
respectively.
• No amplified products from viruses
not belong to these group.
1 2 3 4 5 6 78
1. Std, 100 bp fragments
2. CVB3 , 145 bp
3. negative control
4. HAV, 244 bp
5.negative control
6. CVB3 and HAV
7.negative control
8. Std, 100 bp fragments
10
Assessing DNA Polymorphisms to Detect and
Characterize Specific Bacteria
• Molecular methods used to group or type bacteria based on
genomic homogeniety or diversity
• Identifies groups of closely-related isolates (presumed to
arise from a common ancestor in the same chain of
transmission) and divergent, epidemiologically unrelated
isolates arising from independent sources.
• Restriction fragment length polymorphisms: variable and
distinct size fragments of DNA detected by cutting DNA at
unique sites using specific restriction endonucleases
– Macrorestriction analysis
– Ribotyping: cutting DNA amplifies from 16S ribosomal RNA
– Restriction analysis of virulence-associated genes
• Arbitrary-primed PCR (Randomly Amplified Polymorphic DNA)
11
Restriction Endonucleases used in Molecular Biology
12
Restriction Fragment Polymorphisms
• Variations in DNA sequences are manifest as
changes in some recognition sites for specific
restriction endonuclease enzymes
• Alters size and number of DNA fragments
obtained from restriction enzyme digestion of
chromosomal DNA
• Whole genomic DNA: macrorestriction analysis
• Specific gene(s): ribotyping (rRNA operons)
13
Example: Macrorestriction Analysis of E. coli Isolates
14
RFLP Analysis Procedure
• Isolate chromosomal DNA
• Digest DNA with restriction endonuclease
• Agarose gel electrophoresis
– Macrorestriction analysis
• Southern blotting and hybridization
– Transfer DNA from gel to membrane (cellulose or
nylon)
– Hybridize with labeled probe to gene of interest
• e.g., rDNA
– Ribotype
15
DNA from electrophoresed gel (left) is transferred to membrane filter by
contact and DNA on membrane is hybridized with specific probe(s) (right)
16
Ribotyping
• Gene-specific RFLP for polymorphisms in rRNA genes
(rDNA)
• Identify rDNA fragments from electrophoresed chromosomal
restriction digests by Southern hybridization
• Use specific restriction enzymes with good discrimination
abilities to generate restriction patterns from rDNA
• rRNA is found in all bacteria
• Some sequences are highly conserved and are common in
broad groups (genera); can identify genus as first step with
broad rRNA probe
• rDNA has less but sufficient variability compared to other
genes to type specific species and strains of related bacteria
17
18
19
RFLP of Other Genes
• Species-specific genes as targets for RFLP
• Virulence genes
–
–
–
–
Toxins
Pili
Flagellar genes
Outer membrane protein genes
20
Arbitrarily-Primed PCR (Randomly Amplified
Polymorphic DNA or RAPID)
• Identifies strain-specific variations in DNA
• Use arbitrarily-chosen primers pairs (10- to 20-mers) to
amplify chromosomal DNA under non-stringent conditions
• Variations in DNA sequences of different strains will give
differences in numbers and sizes of their PCR products
• Provides a unique DNA fingerprint
• Limited number of patterns or groups per species of
bacterium
• Problems in reproducability and interpretation have occurred
21
Repetitive Element-PCR (Rep-PCR)
• PCR amplify specific fragments of chromosomal
DNA lying between known repeat motifs of the
chromosome
• Use two outwardly directed primers for the
repeat element at high stringency to generate
unique DNA products that are strain-specific.
22
Detecting Active or Viable Pathogens Using Nucleic Acid
Targets
Detect short-lived nucleic acids present in only
viable/infectious microbes:
– ribosomal RNA
– messenger RNA
– genomic RNA of viruses (large amplicons)
• Detect pathogen nucleic acid by fluorescent in-situ
hybridization (FISH)
– applied to bacteria, protozoan cysts and oocysts, as
well as viruses in infected cell cultures
• (see pictures in later slides)
23
Infectious Microbe Detection by Nucleic Acid Amplification
Target RNA (viral RNA or mRNA)
Viruses (and other microbes)
growing slowly or without
visible signs of growth:
Reverse transcribe 
• Detect rapidly by amplification
of nucleic acids produced in
cells or by vial nucleic acids in
host cells
Polymerase Chain
Reaction Amplification
(PCR)
– Integrated cell culture-PCR (or
RT-PCR) for viruses
– mRNA in viable cells
Nucleic acids in cells
or in virus-infected
infected cells
24
Detecting Infectious Viruses by Direct Nucleic
Acid Analysis - A Functional Approach
Infectious
• Direct nucleic acid analysis alone
does not assure detection of
infectious viruses
Noninfectious
– Nucleic acid still present in
inactivated viruses or free in the
sample (water, etc.)
• Infectious viruses have intact surface
chemistries (epitopes) that react with
host cells to initiate virus infection
– The presence of functional surface
epitopes for binding to cell receptors
is evidence of virus infectivity
Nucleic
acid
Cell
Receptor
In
Out
25
Virus Capture Plus RT-PCR to Detect Infectious
Viruses - The sCAR System
• The cell receptor gene for Coxsackieviruses and
Adenoviruses has been cloned and expressed,
producing a soluble protein receptor, sCAR
• Expressed, purified and bound sCAR to solid
phases to capture infectious Coxsackieviruses
from environmental samples
– The nucleic acid of the sCAR-captured viruses is RT-PCR
amplified for detection and quantitation
26
Application of sCAR with Para-Magnetic Beads for
Virus Particle Capture and then RT-PCR
sCAR
purification
Covalent coupling
to paramagnetic beads
Culture + media;
:sCAR produced
Blocking
post-coupling
: sCAR
: Virus Particle
: Blocking protein
Sample
containing
viruses
(RT-) PCR
NA
extraction
Amine Terminated Support Magnetic Bead : BioSpheres(Biosource)
Pre-coated to provide available amine groups for covalent coupling
of proteins or other ligands by glutaraldehyde-mediated coupling method
27
Ligand Capture of CVB3 Followed by RT-PCR
(Magnetic Bead-sCAR-CVB3)
200bp
SM
103 100
10
Ligand capture
1
0.1
103 100
+
PFU
Bead control
Ligand capture: capture of CVB3 with magnetic beads coupled with purified sCAR
Bead control : Reaction of CVB3 with BSA coated magnetic bead
Magnetic Bead : BioSpheres (Amine Terminated Support)
Viral RNA extraction: QIAamp kit
28
Microbe Nucleic Acid Detection by DNA Microarrays
or “Gene Chip” Technology
Generate/obtain DNA complimentary to genes
(sequences) of interest;
– 1000s of different ones
Apply tiny quantities of each different one onto
solid surfaces at defined positions
– “gene chip” or “DNA microarray”
Isolate or amplify target NA of interest and label
with a fluorescent probe
Apply sample NA to the “gene chip” surface
– Sample NA binds to specific DNA probes on
chip surface; wash away unbound NA
Detect bound DNA or RNA by fluorescence after
laser excitation
Analyze hybridization data using imaging
systems and computer software
Fluorescing Gene Chip or
DNA Microarray
29
Microscopic Detection of Pathogens:
Still Widely Used in Clinical Diagnostic Microbiology
C. parvum
oocysts ~5 um
diam.
Acid fast stain of
fecal preparation
30
Microscopic and Imaging Detection of Pathogens
• Still widely used for parasites and bacteria
• Specific staining and advanced imaging to distinguish
target from non-target organisms
– Differential interference contrast microscopy
– Confocal laser microscopy
• Distinguish infectious from non-infectious organisms
– Combine with infectivity, viability or activity assays
• Overcome sample size limitation due to presence of nontarget particles
– Flow cytometry and other advanced imaging
techniques
– Advanced imaging methods require expensive
hardware
31
Fluorescent In Situ Hybridization - FISH
• Bacteria of the
target group are red
• Other bacteria are
blue
(artificial colors)
32
FISH:
DAPI-stained Bacteria Incubated with INT (Tetrazolium Salt)
Enhanced image with
artificial colors.
•Blue: DAPI stain
•Red: INT grains;
indicate respiratory
active bacteria.
33
Cryptosporidium parvum
Differential Interference Contrast Microscopy
Image courtesy of O.D. “Chip” Simmons, III
34
Cryptosporidium parvum:
Microscopic Analysis of NC field isolate
Immunofluorescence
Differential Interference
Contrast
DAPI stain
Images courtesy of O.D. “Chip” Simmons, III
35
Pathogen Detection by Biochemical Methods
• Enzymatic activities unique to target microbe
• Signature Biolipid Analysis:
– Detection of unique biolipids by gas-chromatography,
mass spectrometry and other advanced organic
analytical methods
• Extract and purify from cells
• Analyze
• Other biochemical markers unique to a specific pathogen
or class of pathogens.
36
Summary Detecting and Quantifying Microbes in the Environment
• Get representative samples
• Recover the microbes from the samples
– may have to separate, concentrate and purify
• very low numbers lots of other similar objects and other
stuff (interferences)
• Analyze for the recovered microbes:
– observe and count them - microscopy/imaging
– culture them on media or in live hosts
– detect them as antigens (immunoassays)
– detect their genetic material (nucleic acid assays)
– detect their unique or characteristic chemical properties or
other properties (e.g., antibiotic resistance)
37
Future Directions in Microbial Detection in the
Environment
• Rapid and Sensitive Pathogen Detection Methods
– Molecular detection for real-time or near real-time monitoring
of pathogens (BT agents, too).
• Real-time PCR
• Couple with methods to selectively recover and detect
potentially infectious microbes
• Enrich for virulence genes of microbes in environmental
media - early warning/alerts system
• Nucleic acid microarrays (“gene chips”) for 1000s at a time
– Culture plus molecular or immunodetection
• Detect pathogen nucleic acids or antigens early in microbial
proliferation in culture
38