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A modified simple RFLP-PCR method for single nucleotide polymorphism (SNP) typing
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     IState Key Laboratory of Bioreactor Engineering, Institute of Biochemistry, East China University of Science and Technology, Shanghai, P.R. China

    IIShanghai Bioengineering Research Center, Shanghai, China

    ABSTRACT

    We describe a modified single nucleotide polymorphism (SNP) typing method based on the restriction fragment length polymorphism polymerase chain reaction (RFLP-PCR). This is a simple, economical method without the need for special equipment. For most SNP loci, a common restriction endonuclease (Hind III, EcoR I or BamH I) recognizing site (RER) can be introduced into one allelic form, but not the other by two rounds of mismatched PCR. The flanking regions can be changed by as many as five bases after PCR amplification with specially designed mismatching primers so the genotypes can be distinguished after digestion of the PCR products with corresponding endonucleases.

    Key words: SNP genotyping, PCR-RFLP, RER site.

    With the completion of the Human Genome Project, about 5.3 million single nucleotide polymorphisms (SNPs) have been found in the human genome, which means that every 600 base pairs there exists one SNP (Patil et al., 2001). Thus, by studying SNP typing information, researchers can investigate disease-associated genes and analyze the genetic structure of a population. Compared with many other methods, such as Taqman assay, the ligase detection reaction and D-HPLC (Kirk et al., 2002), developed in recent years, RFLP-PCR is relatively simple and economical (Haliassos et al., 1989) but the original RFLP-PCR method has several limitations, including the fact that the flanking regions of most SNP loci do not have appropriate restriction endonuclease recognizing site (RER) sites for typing. Some researchers have improved the method by changing one or two bases of the sequence adjacent to the SNP with mismatching primers to create a RER site for typing (Hiesh et al., 2001), but the substitution of one or two bases is not competent enough to introduce a RER sequence, usually 4-6 bp long, to most of the anticipated regions. Therefore, the improved method is still not applicable for most SNP typing and sometimes the created RER sites can only be recognized by rare restriction endonucleases that are expensive or with low digestion efficiency.

    In this study we used specially designed mismatching PCR primers to introduce a common Hind III, EcoR I or BamH I RER site into the flanking regions of the SNP loci by changing 4 to 5 bases after two rounds of PCR amplification for typing. The first round reaction system consisted of 1-5 ng of genomic DNA isolated from Chinese population (described below) peripheral leukocytes using phenol-chloroform methods (Joseph et al., 2001), 200 mM dNTPs mixture, 2.0 mM MgCl2, 1.0 μM of each of the forward and reverse primers and 0.5 u of Taq polymerase (TaKaRa) in a final volume of 5 μL of reaction mixture. The first round PCR reaction was performed using an initial denaturation of 5 min at 94 °C followed by 14 denaturation cycles of 30 s at 94 °C, a first annealing step of 30 s at 63 °C in the first cycle decreased by 0.5 °C per cycle, a second annealing step of 10 s at 45 °C and extension for 50 s at 72 °C. This was followed by 30 cycles of 30 s at 94 °C, 5 s at 65 °C, 30 s at 56 °C, 10 s at 45 °C and 50 s at 72 °C, and a final extension of 7 min at 72 °C. The first round products were diluted 10 times and used as templates for the second round reactions in which 1 μL of the diluted PCR products was added to a final reaction volume of 30 μL containing 200 μM dNTPs mixture, 1.5 mM MgCl2, 3.0 μM of each of the specially designed forward and reverse primers and 2 u of Taq polymerase (TaKaRa). The reaction program was set to an initial denaturation of 5 min at 94 °C followed by 45 cycles of 30 s at 94 °C, 40 s at 56 °C, 10 s at 45 °C and 50 s at 72 °C, and then a final extension of 5 min at 72 °C.

    After two rounds of amplification, a common RER site was introduced into the product of one allele (usually the wild type) of the SNP (see Figure 1) and 2 μL of the PCR products was digested by the corresponding endonuclease before electrophoresis on 3% (w/v) agarose gel and the genotypes separated.

    We used the methodology described above to type three CYP3A4 gene SNPs (CYP3A41B, CYP3A46 and rs#2242480) in a female population consisting of 196 apparently healthy Chinese volunteers who are freshman of East China University of Science and Technology (ECUST) come from everywhere of china, and they are with an age range of from 17 to 19 years. This study was approved by the Medical Ethics Committee of the ECUST and informed consent was obtained from each volunteer.

    For genotyping, blood samples (5 mL) were taken from each individual and genomic DNA extracted by a standard method (Joseph et al., 2001) and used in the reactions as described above. The PCR reactions was carried out as the method described above, the primers used are shown in Table 1 with substituted bases in boldface type, the amplified products and their enzymatic digestion being shown in Figure 2. The CYP3A4 gene encodes a member of Cytochrome P450 family, which play important roles in the oxidative and reductive metabolism of a variety of endogenous and exogenous compounds and contains some SNPs which have been thought to be associated with drug metabolism and the development of puberty (Kitada et al., 1987; Waxman et al., 1988). With the method described above, three RER sites (Hind III, EcoR I and BamH I) were introduced successfully for typing the three selected SNPs on CYP3A4 gene.

    In the Chinese population investigated by us the RFLP-PCR allele frequencies were zero for the CYP3A41B allele, 0.0052 for the CYP3A46 allele and 0.219 for the rs#2242480 allele, which are similar to the results obtained by Heish et al. (2001) for Taiwanese Chinese population (CYP3A41B = 0, CYP3A46 = 0.004902 and rs#2242480 = 0.248).

    Most researchers believed that primers with 3' mismatching nucleotide sequences would not function well in PCR reactions (Lawyer FC et al., 1989). To investigate the effects of the primers on the PCR reaction, we synthesized three reversal primers complementary to the rs# 2242480 sequence and which had a different number of mismatching bases at the their 3' ends, R1 with no 3' mismatched bases, R2 with two 3' mismatches and R3 with three mismatches (Table 2, substituted bases in boldface type). We performed PCR reactions using different thermocycling regimes (described above) and found that during the first 25 cycles the amplification efficiency decreased with the number of 3' mismatched bases increased but that after 35 cycles different primers rarely resulted in any differences and enough PCR products can be obtained for RFLP typing. The amplifying efficiency of primers with two mismatching bases at different positions at the 3' end (R4-R9, also show in table 2) was also studied and the results showed that there was little difference among the primers after 40 cycles.

    Though the method is applicable for most sequences containing a SNP, in some instances the primers must be carefully designed. An anticipated HindIII recognition site can not be introduced to the sequence 5'- G1A2A3A4 A5 G6T7G8C9 C10A11(C)T12 C13T14C15T 16A17T18A19G20C 21T22 G23A24G25-3' (NCBI GenBank no. AF209389) in which one A(C) polymorphism is at the 11th position (indicated by boldface and italic type). However, if the underlined bases were designed to be changed to A(C)AGCTT, the nucleotide at the 11th or 12th position would be missed after PCR amplification. Further experiments showed that when two adjoining adenine (A) and thymine (T) bases exist in the sequence (e.g. ATCG) either the A or T base is missing from the PCR product if we try to substitute A with T or T with A to get a new sequence such as AACG or TTCG. We suppose that either of the two adjoining bases might have been skipped when the mismatching primer anneals with the template in the reaction. However, a similar phenomenon has not been found in the case of adjoining C's and G's.

    Currently, SNP typing is becoming more and more popular in genetic research and some typing methods have been developed which need no special instrumentation, including allele specific PCR (AS-PCR) and mutagenically separated PCR (MS-PCR) (Underhill et al., 1996; Rust, et al., 1993) but unspecific amplification is inevitable when using these techniques and this introduces some difficulties into these SNP typing methods. This means that RFLP-PCR is a simple and reliable method for SNP typing and our methodology outlined in this paper has greatly expanded its application. For most SNPs, a common RER site can be easily introduced into the one allelic form of the SNP and the RFLP typing can be carried out with a cheap DNA sample and without any special instrumentation. In most instances, even five mismatching bases could be introduced into the DNA after two rounds of PCR (i.e. two in the first round and three in the second round) using this modified method. The result also proves that PCR amplification has only relative specificity, and implies that previous typing methods (such as MS-PCR and AS-PCR) based on specific amplification may lead to unreliable results if carried out without extensive optimization.

    Acknowledgments

    This research is supported by National Nature Science Foundation of China (30300198). The authors deeply appreciate Dr. Wenjun Guo for his kind help in revising the English of this paper.

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