实验概要
Quantitative PCR involves co-amplification of two templates: a constant amount of a preparation containing the desired target sequence and varying amounts of a reference template. After amplification, the concentration of the target sequence in the preparation of nucleic acid under test is established by interpolation into a standard curve. Quantitation of nucleic acids by PCR is best performed by real-time PCR. However, the following robust protocol, which uses radioactivity to quantify PCRproducts, remains useful when a real-time instrument is unavailable. The method can be easily adapted to other methods of quantification such as fluorometry.
主要试剂
Reagents and Solutions |
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Enzymes and Buffers |
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Nucleic Acids/Oligonucleotides |
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Radiolabeled Compounds |
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Gels/Loading Buffers |
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Additional Items |
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实验步骤
1.
Design and prepare a reference template suitable for the task at hand.
Measure the concentration of the reference template as carefully as
possible, preferably by fluorometry. Alternatively, estimate the amount
of reference template after gel electrophoresis and ethidium bromide
staining.
2. Make a series of tenfold dilutions (in H2O) containing concentrations of the reference template ranging from 10-6 to 10-12 M. After using the dilutions (Step 3), they should be stored at -70°C for later use in Step 8.
3.
If starting from RNA, denature the target RNA by incubating aliquots
for 5 minutes at 75°C, followed by rapid chilling in ice water. Then,
without delay, set up a series of reverse transcription reactions
containing increasing amounts of reference template in sterile 0.5-ml
microfuge tubes. For each reaction in the series, prepare the following:
10x amplification buffer | 2 µl |
20 mM solution of four dNTPs (pH 8.0) | 1 µl |
20 µM antisense primer | 2.5 µl |
approximately 20 units/ µl placental RNase inhibitor | 1 µl |
50 mM MgCl2 | 1 µl |
denatured target RNA | 10 pg to 1.0 µg |
100-200 units/ µl reverse transcriptase | 1 µl |
tenfold dilution of reference template | 1 µl |
H2O | to 20 µl |
Incubate the reaction for 60 minutes at 37°C and then denature the reverse transcriptase by heating to 95°C for 20 minutes.
4.
In sterile 0.5-ml microfuge tubes, amplification tubes, or the wells of
a sterile microtiter plate, set up amplification reactions with each
reaction in the series from Step 3:
reverse transcriptase reaction (Step 3) or target DNA | 1 µl |
20 µlM sense primer | 1.5 µl |
20 µlM antisense primer | 1.25 µl |
10x amplification buffer | 5 µl |
[α-32P]dCTP (3000 Ci/mmole) | 10 µCi |
20 mM solution of four dNTPs | 1 µl |
thermostable DNA polymerase | 2 units |
H2O | to 50 µl |
注意事项
1.
Do not reduce the concentration of unlabeled dCTP in the reaction
mixture to increase the specific activity of the precursor pool. There
is a danger that the amount of the nucleotide could become limiting at
late stages in the amplification reaction.
2. If the thermal cycler
is not fitted with a heated lid, overlay the reaction mixtures with 1
drop (~50 µl) of light mineral oil. Alternatively, place a bead of wax
into the tube if using hot start PCR. Place the tubes or the microtiter
plate in the thermal cycler.
3. Amplify the nucleic acids using the denaturation, annealing, and polymerization times and temperatures listed in the table.
Cycle Number | Denaturation Polymerization | Annealing | |
30 cycles | 30 sec at 95°C | 30 sec at 55°C | 1 min at 72°C |
Last cycle | 1 min at 94°C | 30 sec at 55°C | 1 min at 72°C |
Times and temperatures may need to be adapted to suit the particular reaction conditions.
When using a reference template that differs from the target sequence in size:
4. Analyze and quantitate the amplified products.
(1)
Analyze the sizes of the amplified products in a 20- µl aliquot of each
of the reactions by gel electrophoresis and autoradiography.
(2) Excise the amplified bands of the control template and target sequences from the gel and measure the amount of radioactivity in each band in a liquid scintillation counter. Alternatively, scan the gel with the appropriate detector (e.g., GEHealthcare scanner or phosphorimager).
(3) Calculate the relative amounts of the two radiolabeled DNAs in each of the PCRs.
(4) Correct the amount of radioactivity to allow for differences in the molecular weights of the two radiolabeled DNAs
When using a reference template that contains a novel restriction site or lacks a naturally occurring site:
(1) Heat the samples to 94°C for 5 minutes following the final round of amplification.
(2) Allow the samples to cool gradually to room temperature and then digest a 20-µl aliquot of each of the reactions with the appropriate restriction enzyme
(3) Analyze the sizes of the amplified DNA fragments by gel electrophoresis and autoradiography or phosphorimaging.
(4) Excise the amplified bands of the control template and target sequences from the gel and measure the amount of radioactivity in each band in a liquid scintillation counter. Alternatively, scan the gel with the appropriate detector (e.g., GEHealthcare scanner or phosphorimager).
(5) Calculate the relative amounts of the two radiolabeled DNAs in each of the PCRs.
5. Correct the amount of radioactivity to allow for differences in the molecular weights of the two radiolabeled DNAs.
(1) Examine the results to determine the concentration of reference
template that yields approximately the same amount of amplified product
as the target sequence. Set up a second series of amplification
reactions (please see Step 4) containing a narrower range of
concentrations of reference template.
It is best to generate this series of dilutions from the appropriate tenfold dilution of the reference template (Step 2).
(2) Repeat Steps 5-7. For each
amplification reaction, measure the ratio of the yield of amplified
reference template to the yield of amplified target sequence. Plot this
ratio against the amount of reference template added to each
amplification reaction. From the resulting straight line, determine the
equivalence point (i.e., the amount of reference template that gives
exactly the same quantity of amplified product as the target sequence in
the reaction). Calculate the concentration of the target sequence in
the original sample.