qPCR in Infectious Disease Testing
Infographic
Published: October 28, 2024
|
Isabel Ely, PhD
Isabel joined Technology Networks in June 2024 as a Science Writer and Editor after completing her PhD in human physiology from the University of Nottingham. Her research focused on the importance of dietary protein and exercise in maximizing muscle health in advancing age. She also holds a BSc in exercise and sport sciences from the University of Exeter and an MRes in medicine and health from the University of Nottingham.
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Credit: Technology Networks
Infectious diseases are a major global cause of morbidity and mortality, seriously affecting public health and socioeconomic stability.
Since its inception, real-time polymerase chain reaction (qPCR) has become one of the most widespread in vitro diagnostic techniques for evaluating and managing infectious diseases.
Download this infographic to learn more about:
- The discovery and differing methods of PCR
- The steps involved in a qPCR experiment
- Uses of qPCR in infectious disease testing
Extension
Real-time polymerase chain reaction (qPCR) has become one of the most
widespread in vitro diagnostic techniques for evaluating and managing
infectious diseases.
In this infographic, we explore the discovery of qPCR, what happens during
qPCR and examples where qPCR is used in infectious disease testing.
The
of
Real-time polymerase chain reaction (qPCR) has become one of the most
widespread in vitro diagnostic techniques for evaluating and managing
infectious diseases.
In this infographic, we explore the discovery of qPCR, what happens during
qPCR and examples where qPCR is used in infectious disease testing.
On the back of a receipt in 1983, American biochemist Kary
Mullis detailed an idea of reproducing the DNA replication
process that takes place in cells in a laboratory tube.
The first description of PCR using Taq polymerase was
published in Science in 1985.
Mullis’ discovery earned him the Nobel Prize for Chemistry
in 1993, with PCR becoming one of the most important
scientific advances of the 20th century.
has come a
PCR is used to amplify a specific DNA fragment of interest from a template DNA. There are now
varying methods of PCR that can be used for sample analysis. These include:
PCR Sometimes called end-point PCR, the products are
evaluated at the end of the amplification process,
typically by agarose gel electrophoresis. Thus,
traditional PCR is semi-quantitative compared to
other methods.
Measurements are taken at the end of each
amplification cycle using fluorescent reporters.
Thus, the actual amplification process itself is
tracked rather than just the final product making it
fully quantitative. qPCR
Rather than DNA the starting material in RT-qPCR is RNA. A reverse transcription step is
incorporated to convert the RNA to complementary DNA (cDNA) before the normal
qPCR amplification
RT-qPCR
Samples are diluted and partitioned to the extent that single template molecules can
be amplified. The products are detected using fluorescent probes.
dqPCR
What is needed for a
DNA (to be amplified)
DNA primers
PCR
Buffer
Deoxynucleotide
triphosphates
(dNTPs)
DNA polymerase
Flurescence probes
or dye
From a practical perspective, a qPCR experiment is relatively
straightforward and can be completed in a few hours.
In general, a qPCR experiment involves:
AKA a PCR template or
template DNA
Primers are short pieces
of single-stranded DNA
(approximately 15–30
bases) which are required
by DNA polymerases to
indicate where they need
to initiate amplification.
Enables detection of target amplification.
For example, an intercalating dye (e.g.
SYBR® Green) displays weak fluorescence
in its unbound form, and a strong
fluorescent signal when bound to doublestranded
DNA.
All PCR reactions require a DNA
polymerase that can work at
high temperatures.
DNA polymerases are enzymes
that create DNA molecules by
assembling nucleotides
Taq polymerase is commonly
used.
Serve as the building blocks to
synthesize the new strands of
DNA and include the four basic
DNA nucleotides (dATP, dCTP,
dGTP, and dTTP).
Ensures that
optimal
conditions are
maintained
throughout the
PCR reaction
DNA template
DNA primers
Buffer solution
Action of SYBR Green I Dye
1. Dye in solution emits
low florescence
2. Emission of the
flurescence by binding
dNTPs
DNA polymerase
denaturation
Extension
annealing
Template DNA is heated to 95 °C for a few seconds.
DNA strands separate due to hydrogen bonds
breaking between them.
The
temperature
is raised to optimal
temperature (~72 °C) for DNA
polymerase. DNA polymerase binds to one
end of each primer and synthesizes new
strands of DNA, complementary to the
template DNA. The fluorescence produced by
the probes/dye is detected by the fluorimeter
and recorded by the computer.
The
reaction
mixture is cooled
for 30 seconds to 1 minute.
Annealing temperatures are usually
50–65 °C. The optimal temperature depends
on the primers’ length and sequence.
5’ 3’
3’ 5’
DNA
94-95°C
5’
3’ 5’ 3’ 5’
3’
DNA
Polymerase
72°C
3’
since 1983
of
On the back of a receipt in 1983, American biochemist Kary
Mullis detailed an idea of reproducing the DNA replication
process that takes place in cells in a laboratory tube.
The first description of PCR using Taq polymerase was
published in Science in 1985.
Mullis’ discovery earned him the Nobel Prize for Chemistry
in 1993, with PCR becoming one of the most important
scientific advances of the 20th century.
has come a
since 1983
PCR is used to amplify a specific DNA fragment of interest from a template DNA. There are now
varying methods of PCR that can be used for sample analysis. These include:
Sometimes called end-point PCR, the products are
PCR
evaluated at the end of the amplification process,
typically by agarose gel electrophoresis. Thus,
traditional PCR is semi-quantitative compared to
other methods.
Measurements are taken at the end of each
qPCR
amplification cycle using fluorescent reporters.
Thus, the actual amplification process itself is
tracked rather than just the final product making it
fully quantitative.
RT-qPCR
Rather than DNA the starting material in RT-qPCR is RNA. A reverse transcription step is
incorporated to convert the RNA to complementary DNA (cDNA) before the normal
qPCR amplificatio
dqPCR
Samples are diluted and partitioned to the extent that single template molecules can
be amplified. The products are detected using fluorescent probes.
What is needed for a
From a practical perspective, a qPCR experiment is relatively
straightforward and can be completed in a few hours.
In general, a qPCR experiment involves:
1
2
DNA (to be amplified)
DNA polymerase
AKA a PCR template or
All PCR reactions require a DNA
template DNA
polymerase that can work at
high temperatures.
DNA polymerases are enzymes
that create DNA molecules by
assembling nucleotides
Taq polymerase is commonly
used.
DNA template
DNA polymerase
3
4
DNA primers
Primers are short pieces
Deoxynucleotide
of single-stranded DNA
(approximately 15–30
triphosphates
bases) which are required
by DNA polymerases to
(dNTPs)
indicate where they need
to initiate amplification
Serve as the building blocks to
synthesize the new strands of
DNA and include the four basic
DNA nucleotides (dATP, dCTP,
dGTP, and dTTP).
DNA primers
dNTPs
5
6
Flurescence probes
PCR
or dye
Buffer
Ensures that
Enables detection of target amplification
optimal
For example, an intercalating dye (e.g.
conditions are
SYBR® Green) displays weak fluorescenc
R®
maintained
in its unbound form, and a strong
throughout the
fluorescent signal when bound to double
PCR reaction
stranded
DNA.
Action of SYBR Green I Dye
1. Dye in solution emits
2. Emission of the
Buffer solution
low florescenc
flurescence by binding
Standard
overview
denaturation
1
Template DNA is heated to 95 °C for a few seconds.
DNA strands separate due to hydrogen bonds
breaking between them.
5’
3’
94-95°C
DNA
3
2
3’
5’
The
The
temperature
reaction
is raised to optimal
mixture is cooled
temperature (~72 °C) for DNA
for 30 seconds to 1 minute.
polymerase. DNA polymerase binds to one
Annealing temperatures are usually
end of each primer and synthesizes new
50–65 °C. The optimal temperature depends
strands of DNA, complementary to the
on the primers’ length and sequence.
template DNA. The fluorescence produced by
the probes/dye is detected by the fluorimete
and recorded by the computer.
5’
3’
3’
5’
3’
3’
72°C
50-65°C
F
DNA
Primer
Polymerase
F
3’
5’
3’
3’
5’
3’
5’
The
is then
By repeating the cycle 30 times, the double-stranded DNA molecules present at the beginning
are converted into over 130 million new double-stranded molecules, each a copy of the region of
the starting molecule delineated by the annealing sites of the two primers.
AMPLIFICATION OF A SPECIFIC DNA SEQUENCE
DNA template
THE
DNA
DNA
Buer
REACTION
primers
dNTPs
polymerase
solution
THERMAL
3’
5’
CYCLER
Denaturation
5’
3’
25-40 cycles
5’
3’
Annealing
5’
3’
3’
5’
5’
3’
Elongation
3’
5’
3’
5’
Products
Cycle 1
Cycle 2
Cycle 3
Cycle 4
Using
to identify
Selecting the appropriate
diagnostic techniques for
Infectious diseases are a major
the rapid identification of
global cause of morbidity
pathogens is crucial for clinical
and mortality, seriously
disease diagnosis and public
affecting public health and
health management.
socioeconomic stability.
qPCR has a well-established place in both infectious disease diagnostics of humans,
animals and plants and in the detection of genetic markers, such as mutations. qPCR
can also be used on environmental samples to help epidemiologists monitor and predict
the spread of disease.
Quantitative data can help estimate pathogenic load, potentially informing treatment or
management decisions.
Mycobacterium tuberculosis
One of the earliest recognized applications of PCR for clinical
practice was M. tuberculosis detection.
Standard testing before qPCR was introduced often consisted of
culture-based experiments. These techniques resulted in inherent
delays in test results which, given how important early detection
is for infected patients, was a significant drawback for these
standard testing techniques. Resultingly, qPCR has significantl
improved the time from obtaining a sample to receiving test
results can be generated.
SARS-CoV-2
One of the most recent examples of qPCR (specificall
RT-qPCR) uses in infectious disease testing, was
throughout the COVID-19 pandemic.
RT-qPCR was used to convert RNA from a SARS-CoV-2
sample to its cDNA sequence. The DNA would then be
amplified by qPCR.
COVID-19 diagnostic test using RT-qPCR Technique
1
2
Nasopharyngeal
Collected
swab
specimen
Cotton swab is inserted into
Specimen is stored at
nostril to absorb secretions.
2-8ºC for up to 72 hours
or proceeded for RNA
extraction.
3
RNA extraction
Purified RNA is extracted from
deactivated virus.
Deactivated SARS-CoV-2
Purified DNA
4
5
RT-qPCR
Test results
Purified RNA is reverse
Positive SARS-CoV-2
transcribed to cDNA an
patients cross the
amplified by qPCR.
threshold line with 40.00
cycles (<40.00 Ct).
Positive
Threshold
Reverse - Transcription
Negative
Cycles
Researchers estimate that RT-qPCR can detect as little as ~1,000 copies of viral RNA per milliliter or
10 copies per analytical limit of detection. This means diagnosing someone as COVID-19 positive
is possible even when their sample contains a very small amount of virus.
Other tests – such as the rapid antigen test – were also developed throughout the COVID-19
pandemic to aid with mass testing. Below is a comparison between RT-qPCR and antigen testing
for SARS-CoV-2:
Antigen
RT-qPCR
test
Tests for genetic material (RNA)
Tests for pathogen proteins
Less rapid test results produced
Rapid test results produced
(a few days)
(within minutes)
Less convenient
Highly convenient
Highly specifi
Reduced specificit
Very low viral load needed
High viral load needed
Low occurrence of false
False-negative results are more
negative
results
common (i.e. there can be too few
virus proteins present in the sample
to register positive on the test)
Benefits of
in
testing
The use of qPCR allows for rapid triage and the administration of early aggressive targeted
therapies, appropriate isolation of contagious patients and diminished antibiotic resistance.
Patients with unrecognized or difficult-to-diagnose infections can be identified and treated more
quickly with qPCR. Inpatient stays may reduce alongside reduced iatrogenic events.
To fully understand the benefits of qPCR, further research is needed on the societal benefits of the
technology with attention to the relative costs of novel diagnostics concerning existing standards
and how this may contribute to reducing healthcare costs.
long way
experiment?
experiment
repeated...
Infectious Disease
Infectious Disease
discovery
nnealing
Fluorescence
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