Griffin:Nested RT-PCR: Difference between revisions
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== | ==Nested PCR overview== | ||
The amplification of RNA requires the conversion of the RNA substrate into DNA. This is achieved through the use of a reverse transcriptase such as AMV RT (avian myeloblastis virus reverse transcriptase) or M-MuLV RT (moloney murine leukemia virus reverse transcriptase). The resulting cDNA can be used as a template for a standard PCR. | The amplification of RNA requires the conversion of the RNA substrate into DNA. This is achieved through the use of a reverse transcriptase such as AMV RT (avian myeloblastis virus reverse transcriptase) or M-MuLV RT (moloney murine leukemia virus reverse transcriptase). The resulting cDNA can be used as a template for a standard PCR. | ||
| Line 37: | Line 37: | ||
*Prepare a solution containing: | *Prepare a solution containing: | ||
a) 5 | a) 5 ul 10x PCR buffer (with or without MgCl2) | ||
b) 5 | b) 5 ul 25 mM MgCl2 (It may be necessary to vary the MgCl2 concentration, 2.5 mM final concentration recommended.) | ||
c) 1 | c) 1 ul 10 mM dNTP | ||
d) 1 | d) 1 ul primer pair A | ||
e) 1 | e) 1 ul Taq DNA polymerase | ||
f) 2 | f) 2 ul cDNA and add water to 50 ul | ||
===First PCR amplification parameters=== | ===First PCR amplification parameters=== | ||
| Line 65: | Line 65: | ||
*Prepare a solution containing: | *Prepare a solution containing: | ||
a) 5 | a) 5 ul 10x PCR buffer (with or without MgCl2) | ||
b) 5 | b) 5 ul 25 mM MgCl2 (It may be necessary to vary the MgCl2 concentration, 2.5 mM final concentration recommended.) | ||
c) 1 | c) 1 ul 10 mM dNTP | ||
d) 1 | d) 1 ul primer pair B | ||
e) 1 | e) 1 ul Taq DNA polymerase | ||
f) 1–5 | f) 1–5 ul first PCR product and add water to 50 ul | ||
===Second PCR amplification parameters=== | ===Second PCR amplification parameters=== | ||
Revision as of 11:53, 17 October 2008
Nested PCR overview
The amplification of RNA requires the conversion of the RNA substrate into DNA. This is achieved through the use of a reverse transcriptase such as AMV RT (avian myeloblastis virus reverse transcriptase) or M-MuLV RT (moloney murine leukemia virus reverse transcriptase). The resulting cDNA can be used as a template for a standard PCR.
Nested PCR means that two pairs of PCR primers were used for a single locus. The first pair generates an amplicon within the locus as seen in any PCR experiment. The second pair of primers (nested primers) bind within the first amplicon and produce a second PCR product that will be shorter than the first one. The logic behind this strategy is that if the wrong locus were amplified by mistake, the probability is very low that it would also be amplified a second time by a second pair of primers.
Primer Tm Values
Tm values for PCR primers generally range between 55-60 C (19-21 nt, GC% approx. 55%). The A and B nested primer sets share similar base pair length, GC% and Tm values.
Nested PCR utilizes two pairs of PCR primers for a single locus. The first primer pair A set amplifies within the locus. The second primer pair B set (nested primers) then binds within the 'A' amplicon to produce a second nested 'B' amplicon.
Reagents
- Reverse Transcriptase
- Deoxynucleotide Mix, dATP, dCPT, dGTP, dTTP, 10 mM each, in sterile double-distilled water, pH 8.5
- Reaction Buffer, 10x conc., 1.05 ml; 100 mM Tris-HCl, 500 mM KCl, pH 8.3 (20°C)
- MgCl2 Stock Solution, 2 x 1.3 ml each 25 mM MgCl2
- Gelatin, 0.05% gelatin (w/v)
- Oligo-p(dT)15 Primer, 0.02 A260 units/µl (0.8 µg/µl)
- RNase Inhibitor, 50 U/µl
- Sterile Water
PCR Optimization
- MgCl2 concentrations may vary depending on the template, primer, and dNTP concentrations in the amplification reaction. To optimize conditions, use a MgCl2 titration, generally between 0.5 and 10 mM.
- Primer concentrations may vary; typical final concentrations range from 0.01 to 0.5
- The amount of cDNA utilized in RT-PCR reactions may vary depending on the nature of the RNA template; typically, 5 ul of the cDNA of reverse transcribed total RNA, 20 ul of the cDNA resulting from reverse transcribed poly(A)+ RNA, or 20
- Addition of Gelatin (0.01 mg/ml final) stabilizes Taq DNA polymerase during the PCR reaction, yielding more amplification product.
cDNA Synthesis (Reverse Transcription)
In a standard RT-PCR assay, varying amounts (1 u
First PCR reaction
- Prepare a solution containing:
a) 5 ul 10x PCR buffer (with or without MgCl2)
b) 5 ul 25 mM MgCl2 (It may be necessary to vary the MgCl2 concentration, 2.5 mM final concentration recommended.)
c) 1 ul 10 mM dNTP
d) 1 ul primer pair A
e) 1 ul Taq DNA polymerase
f) 2 ul cDNA and add water to 50 ul
First PCR amplification parameters
Perform 15–35 cycles of PCR. Annealing and extension conditions are primer and template dependent and must be determined empirically for each template-primer pair. Tm values for PCR primers generally range between 55-60 C
- Denaturation 96°C, 1.5 minute
- Annealing 57°C, 1 minute
- Polymerization (35 cycles) 72°C, 2 minutes
- Link; Extension (1 cycle) 70°C, 5 minutes
- Link to a 4°C Soak file.
NOTE: Addition of Gelatin (0.01 mg/ml final) stabilizes Taq DNA polymerase, yielding more amplification product.
Second (nested) PCR reaction
- Prepare a solution containing:
a) 5 ul 10x PCR buffer (with or without MgCl2)
b) 5 ul 25 mM MgCl2 (It may be necessary to vary the MgCl2 concentration, 2.5 mM final concentration recommended.)
c) 1 ul 10 mM dNTP
d) 1 ul primer pair B
e) 1 ul Taq DNA polymerase
f) 1–5 ul first PCR product and add water to 50 ul
Second PCR amplification parameters
Perform 15-25 cycles of PCR. Annealing and extension conditions are primer and template dependent and must be determined empirically for each template-primer pair. Tm values for PCR primers generally range between 55-60 C
- Denaturation 96°C, 1.5 minute
- Annealing 57°C, 1 minute
- Polymerization (35 cycles) 72°C, 2 minutes
- Link; Extension (1 cycle) 70°C, 5 minutes
- Link to a 4°C Soak file.
NOTE: Addition of Gelatin (0.01 mg/ml final) stabilizes Taq DNA polymerase, yielding more amplification product.
- PCR products are visualized by agarose gel electrophoresis stained with an appropriate dye.
References
Roche Applied Science Cat. No. 11 483 188 001
Santa Cruz Biotechnology, Inc.
Sambrook, J., Fritsch, E.M. and Maniatis, T. (1989) Molecular Cloning: A Laboratory Manual, 2nd Edition, Cold Spring Harbor Laboratory, Cold Spring Harbor, New York, pp. 14.16, 14.20.
