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Principles of RACE
Rapid Amplification of cDNA Ends (RACE) is a procedure for amplification of nucleic acid sequences from a messenger RNA template between a defined internal site and either the 3´ or the 5´ end of the mRNA (1). This methodology of amplification with single-sided specificity has been described as “one-sided” PCR (2) or “anchored” PCR (3). PCR requires two sequence-specific primers that flank the sequence to be amplified (4,5). However, to amplify and characterize regions of unknown sequences, this requirement imposes a limitation (3). 3´ RACE takes advantage of the natural poly(A) tail found in mRNA as a generic priming site for PCR. In this procedure, mRNAs are converted into cDNA using reverse transcriptase (RT) and an oligo-dT adapter primer. Specific cDNA is then amplified by PCR using a gene-specific primer (GSP) that anneals to a region of known exon sequences and an adapter primer that targets the poly(A) tail region. This permits the capture of unknown 3´-mRNA sequences that lie between the exon and the poly(A) tail. 5´ RACE uses an antisense gene specific primer for the synthesis of specific cDNA by reverse transcriptase.
Prior to PCR, a TdT-tailing step attaches an adapter sequence to the unknown 5´ sequences of the cDNA. Specific cDNA is then amplified by PCR using a GSP that anneals in a region of known exon sequences and an adapter primer that targets the 5´ terminus. RACE has been used for amplification and cloning of rare mRNAs (6) and may be applied to existing cDNA libraries (7). Additionally, RACE products can be directly sequenced without any intermediate cloning steps (8,9), or the products may be used to prepare probes (10). Products generated by the 3´ and 5´ RACE procedures may be combined to generate full-length cDNAs (10,11). Lastly, the RACE procedures may be utilized in conjunction with exon-trapping methods (12) to enable amplification and subsequent characterization of unknown coding sequences.
Summary of the 3´ RACE System
The 3´ RACE procedure is summarized as follows. First strand cDNA synthesis is initiated at the poly(A) tail of mRNA using the adapter primer (AP). After first strand cDNA synthesis, the original mRNA template is destroyed with RNase H, which is specific for RNA:DNA heteroduplex molecules. Amplification is performed, without intermediate organic extractions or ethanol precipitations, using two primers: one is a user-designed GSP that anneals to a site located within the cDNA molecule; the other is a universal amplification primer that targets the mRNA of the cDNA complementary to the 3´ end of the mRNA. Two universal amplification primers are provided with the system. The universal amplification primer (UAP) is designed for the rapid and efficient cloning of RACE products using the uracil DNA glycosylase (UDG) cloning method (13–16). The abridged universal amplification primer (AUAP) is homologous to the adapter sequence used to prime first strand cDNA synthesis.
Since the 3´ RACE System utilizes the poly(A) tail region as an initial priming site, multiple amplification products may be synthesized, depending on the degree of specificity conferred by the GSP. To generate a specific amplification product, the user may find it advantageous to design a second “nested” GSP, as recommended by Frohman et al. (10) and reamplify the RACE products; this procedure is discussed in greater detail at the end of this chapter
Isolation of Total RNA
One of the most important factors preceding the synthesis of substantially full-length cDNA is the isolation of intact RNA. The quality of the RNA dictates the maximum amount of sequence information that can be converted into cDNA. Thus, it is important to optimize the isolation of RNA from a given biological source and to prevent adventitious introduction of RNases (17) and inhibitors of reverse transcriptase such as guanidinium salts, SDS and EDTA (18). RNA can be isolated using a variety of methods. The recommended method for 3´ RACE is the guanidine isothiocyanate/acid-phenol method originally described by Chomzynski and Sacchi (19). The TRIzol Reagent method is an improvement of the original single-step method of Chomczynski and Sacchi (20) and can be used for the preparation of RNA from as little as 103 cells or milligram quantities of tissue (21). Total RNA isolated with Invitrogen TRIzol Reagent is undegraded and essentially free of protein and DNA contamination. For the isolation of RNA from small quantities of sample (<106 cells or <10 mg tissue) without using phenol, the GlassMAX RNA Microisolation Spin Cartridge System is recommended (22).
Total RNA isolated by these methods may contain small amounts of genomic DNA that may subsequently be amplified along with the target cDNA. The presence of this DNA is not likely to cause problems because it lacks the poly(A) region present in the mRNA analyte. As a precaution, however, we recommend performing a control experiment without reverse transcriptase to determine whether a given fragment is of genomic DNA or of cDNA origin. Products generated in the absence of RT are of genomic origin. If your application requires removal of all genomic DNA from your RNA preparation, refer to DNase I Digestion of RNA Preparation.
First Strand cDNA Synthesis from Total RNA
The first strand cDNA synthesis reaction is catalyzed by Invitrogen SuperScript II RT. This enzyme is a mutant of M-MLV RT that has been engineered to reduce RNase H activity, resulting in greater yields and more full-length synthesis (23,24,25). The enzyme exhibits increased thermal stability and may be used at temperatures up to 50°C. In addition, SuperScript II RT is not inhibited significantly by ribosomal and transfer RNA and may be used to synthesize first strand cDNA from a total RNA preparation. The RNA template is removed from the cDNA:RNA hybrid molecule by digestion with RNase H after cDNA synthesis to increase the sensitivity of PCR (26). The AP which primes first strand cDNA synthesis, has been engineered to contain three restriction endonuclease sites and a Not I half-site. Inclusion of these sequences in the primer may facilitate post-amplification cloning using either a restriction endonuclease-based (27) or a T4 DNA polymerase-based (28) method. Because the AP initiates cDNA synthesis at the poly(A) region of the mRNA, it effectively selects for polyadenylated mRNAs; thus, oligo(dT)-selection for poly(A)+ RNA is typically not necessary although incorporating this step may facilitate the detection of rare mRNA transcripts.
Amplification of a Target cDNA
Amplification of a target cDNA requires priming with two oligonucleotides and Taq DNA polymerase. The sense amplification primer is the user-provided GSP,which is specific for the particular gene or sequence of interest and may be designed to include sequence elements that facilitate subsequent cloning steps. The antisense amplification primer is one of the two universal amplification primers provided with the system. The AUAP contains a restriction endonuclease site sequence (adapter region) homologous to the adapter region of the AP. The UAP is composed of the same adapter region plus a dUMP-containing sequence at the 5´ end of the primer required for UDG-mediated cloning. The UAP should not be used to prime DNA synthesis with any archaeobacterial polymerase (e.g., Pyrococcus furiosus, Pyrococcus woesei, etc.) or any long PCR enzyme mixture (e.g., Elongase® Enzyme Mix) that contains one of these enzymes due to the inhibition of polymerase activity by dUMP-containing DNA. Both the AUAP and the UAP will function in PCR at annealing temperatures up to 68°C.e
Design of the Gene-Specific Primer
Efficient and specific PCR amplification is highly dependent on primer design. This is especially true for RACE applications since the PCR is carried out with only a single GSP. In general, effective primers form stable duplexes with their target sequences, are highly specific for their target sequences, and are free of secondary structure such as hairpin loops and dimers (29–31). Additionally, the complementarity of primer 3´-termini must be minimized since primer-dimer artifacts may significantly reduce PCR efficiency. Therefore, dimer formation with the AUAP or UAP primer, as well as itself, should be reduced. Computer algorithms that have been developed (32–35) and are commercially available often facilitate this analysis. Discussion of primer design for RACE applications may be found in Frohman (11) and Loh (6). It should be noted that in cases where only limited peptide sequence information is available, a degenerate GSP may be prepared. The AUAP and UAP included wit the system have been engineered to function at PCR annealing temperatures up to 68°C and to facilitate the cloning step. The user-defined GSPs need to be compatible with the cloning method. Add the following to the 5’ end of the GSP: for UDG cloning: 5´–CAU CAU CAU CAU–3´ (use with UAP) for T4 DNA polymerase cloning: 5´–CGA–3´ (use with AUAP)
Nested Amplification
The AP is designed to synthesize first strand cDNA from all polyadenylated mRNAs. The sequence specificity in the amplification reaction is therefore derived solely from the GSP. Often, a second “nested” GSP may be utilized in conjunction with the AUAP or UAP in a second amplification reaction to give the 3´ RACE procedure the specificity of a second primer (9). The nested GSP can anneal immediately adjacent to the first GSP or at sequences within the cDNA further downstream. The nested amplification reaction may be conveniently conducted using a plug of agarose from the gel analysis of the initial 3´ RACE reaction (see Nested Amplification from an Agarose Plug). Ultimately, the 3´ RACE procedure should produce a single, prominent band on an agarose gel. When performing 3´ RACE with a nested primer, sequences specific for subsequent cloning manipulations (see Design of the Gene-Specific Primer) must be designed into the nested GSP.
Cloning of Amplification Products
Conventional cloning methods that typically involve end-repair and blunt-end cloning can be problematic for amplified products (36–38). An alternative is a rapid and efficient method involving the use of UDG (13–16). This method requires that the user design a GSP containing containing a 5'-(CAU)4 sequence. Incorporation of dUMP into the GSP may be accomplished on most automated synthesizers or with Invitrogen Custom Primers (see Design of the Gene-Specific Primer). The product of the 3´ RACE reaction primed with the UAP and the dUMP-containing GSP is treated with UDG, which converts dUMP residues to abasic sites (39,40), to generate 3´ overhangs. The directional nature of the UDG cloning process can be exploited to lend an added level of specificity to the RACE procedure. Only amplification product that results from priming by both the UAP and the appropriately designed GSP are efficient substrates for UDG cloning. Another alternative to conventional cloning methods uses the 3´ to 5´ exonuclease activity of T4 DNA polymerase as the basis for cloning as described by Stoker (28). In this procedure, the AUAP is used in the amplification reaction, and the 3´ RACE products are treated with T4 DNA polymerase to generate a Not I 5´ overhang. Similarly, the user may design a site into the GSP (see Design of the Gene-Specific Primer). Another approach to cloning is to digest the 3´ RACE product using one of the restriction endonuclease sites designed into the AUAP. The user may also design unique restriction sites into the GSP, exploit a site present in the cDNA sequence or end-repair the 3´ RACE product prior to restriction endonuclease digestion (37).
Components
Components are provided in sufficient quantities to perform 20 separate reactions, each converting 1-5 μg of total RNA into first strand cDNA. A control RNA and amplification primers are included in the system to verify performance of the first strand cDNA synthesis reaction and subsequent amplification. Note: The 3´ RACE System does not include Taq DNA polymerase or the reagents required for cloning. Store the 3´ RACE System at –20°C.
Component | Amount |
---|---|
10X PCR buffer [200 mM Tris-HCl (pH 8.4), 500 mM KCl] | 500 μl |
25 mM MgCl2 | 500 μl |
10 mM dNTP mix (10 mM each dATP, dCTP, dGTP, dTTP) | 100 μl |
0.1 M DTT | 100 μl |
SuperScript™ II Reverse Transcriptase (RT, 200 units/μl) | 20 μl |
adapter primer (AP, 10 μM) | 20 μl |
universal amplification primer (UAP, 10 μM) | 20 μl |
abridged universal amplification primer (AUAP, 10 μM) | 20 μl |
E. coli RNase H (2 units/μl) | 20 μl |
DEPC-treated water | 1.2 ml |
control RNA (50 ng/μl) | 10 μl |
control gene-specific primer (GSP, 10 μM) | 20 μl |
Advance Preparations
Please review the protocols before using this system. You will need the following items not included in the system:
Protocol 1. First Strand cDNA Synthesis
This procedure converts 1 to 5 μg of total RNA into first strand cDNA. Poly(A)+ RNA may be used in this protocol, but is typically not necessary. A control RNA is included in the 3´ RACE System as an aid in verifying that the system performs in your hands. If you decide to use the control RNA as a template for first strand synthesis, simply substitute 2 μl of control RNA (100 ng) in the first strand reaction for your total RNA.
Component | Volume (μl) |
---|---|
10X PCR buffer | 2 |
25 mM MgCl2 | 2 |
10 mM dNTP mix | 1 |
0.1 M DTT | 2 |
Component | Volume (μl) |
---|---|
10X PCR buffer | 5 |
25 mM MgCl2 | 3 |
autoclaved, distilled water | 36.5 |
10 mM dNTP mix | 1 |
GSP (prepared as 10 μM solution) | 1 |
AUAP (10 μM) or UAP (10 μM) | 1 |
Taq DNA polymerase (2 to 5 units/μl) | 0.5 |
General Suggestions
Problem | Possible Cause | Suggested Remedy |
---|---|---|
No bands after electrophoretic analysis of amplified products | Procedural error in first strand cDNA synthesis or PCR | Use the control RNA to verify the efficiency of the first strand reaction (see Testing the 3´ RACE System). |
RNase contamination | Add the control RNA to the sample to determine if RNase is present in the first strand reaction. Maintain aseptic conditions to prevent RNase contamination (see Minimizing RNase Contamination). Use RNase inhibitor during first strand cDNA synthesis. | |
Inhibitors of RT present | Remove inhibitors by ethanol precipitation of the mRNA preparation before the first strand reaction. Include a 70% (v/v) ethanol wash of the mRNA pellet. Notes: Inhibitors of RT include sodium dodecyl sulfate (SDS), EDTA, guanidinium salts, glycerol (>35%), sodium pyrophosphate, and spermidine (18). Test for the presence of inhibitors by mixing 1 μg of sample RNA ± control RNA and compare yields of first strand cDNA or PCR product. | |
Polysaccharide and small RNA (tRNA and 5SRNA) coprecipitation with mRNA | Ethanol-precipitate the RNA preparation; treat the pellet as described in Lithium Chloride Purification of RNA Preparation (17). | |
Target mRNA contains strong transcriptional pauses | Maintain an elevated temperature after the annealing step and increase the temperature of first strand reaction (up to 50°C) (see Alternative Protocol for First Strand cDNA Synthesis of Transcripts with High GC Content). | |
Too much first strand reaction was used in the PCR | Dilute cDNA reaction 10- to 100-fold. Use no more than 10% of the first strand product in PCR. | |
Polymerase from an archaeobacteria was used with dUMP primers | Use AUAP and non-dUMP GSP in PCR using Elongase® or an archaeobacterial polymerase Use Taq DNA polymerase for PCR with the UAP and dUMP containing GSP. | |
Unexpected bands after electrophoretic analysis of “nested” amplification products | Contamination by genomic DNA | To test if products were derived from genomic DNA, perform first strand reaction without SuperScript II RT. Pretreat RNA as described in DNase I Digestion of RNA Preparation. |
Spurious priming in the PCR | Vary the parameters of the PCR according to Taq DNA polymerase instructions and/or use hot start for PCR. Incorporate a preamplification heating step (44,45). | |
Poor cloning efficiency | Inefficient ligation | Increase the incubation time in the ligation reaction; decrease the temperature. Ensure the removal of dNTPs prior to ligation by chromatographic separation. Ensure the removal of vector stuffer fragments by chromatographic separation. |
Poor restriction endonuclease digestion due to residual bound Taq DNA polymerase | Treat the PCR products with proteinase K (47) (see Proteinase K Treatment of 3´ RACE Products). | |
Restriction endonuclease does not digest at the end of molecule | Add nucleotides to 5´ end of primer. Use a different restriction endonuclease. |
The control RNA provided with the 3´ RACE System can be used to troubleshoot both the first strand reaction and the amplification reaction. Use the following protocols, as needed, to troubleshoot for particular problems. To perform th 3´ RACE procedure using the control RNA, you may need the following items, in addition to those listed in Advance Preparations.
First Strand cDNA Synthesis
Component | Tube A | Tube B |
---|---|---|
control RNA (50 ng/μl) | 2 | 2 |
AP (10 μM) | 1 | 1 |
DEPC-treated water | 8 | 9 |
final volume | 11 | 12 |
Component | Tube A | Tube B |
---|---|---|
10X PCR buffer | 2 | 2 |
25 mM MgCl2 | 2 | 2 |
10 mM dNTP mix | 1 | 1 |
0.1 M DTT | 2 | 2 |
SuperScript II RT (200 units/μl) | 1 | 1 |
For Research Use Only. Not for use in diagnostic procedures.