A genome walking strategy for the identification of nucleotide sequences adjacent to known regions

Wristwatch PCR: A Versatile and Efficient Genome Walking Strategy

Genome walking is a method used to retrieve unknown flanking DNA. Here, we reported wristwatch (WW) PCR, an efficient genome walking technique mediated by WW primers (WWPs). WWPs feature 5′- and 3′-overlap and a heterologous interval. Therefore, a wristwatch-like structure can be formed between WWPs under relatively low temperatures. Each WW-PCR set is composed of three nested (primary, secondary, and tertiary) PCRs individually performed by three WWPs. The WWP is arbitrarily annealed somewhere on the genome in the one low-stringency cycle of the primary PCR, or directionally to the previous WWP site in one reduced-stringency cycle of the secondary/tertiary PCR, producing a pool of single-stranded DNAs (ssDNAs). A target ssDNA incorporates a gene-specific primer (GSP) complementary at the 3′-end and the WWP at the 5′-end and thus can be exponentially amplified in the next high-stringency cycles. Nevertheless, a non-target ssDNA cannot be amplified as it lacks a perfect binding site for any primers. The practicability of the WW-PCR was validated by successfully accessing unknown regions flanking Lactobacillus brevis CD0817 glutamate decarboxylase gene and the hygromycin gene of rice. The WW-PCR is an attractive alternative to the existing genome walking techniques.

Simple innovative adaptor to improve genome walking with convenient PCR

BACKGROUND

Various polymerase chain reaction (PCR)-based methods have been applied for the development of genome walking (GW) technique. These methods which could be based on the application of restriction enzymes or primers have various efficiencies to identify the unknown nucleotide sequences. The present study was conducted to design a new innovative double-strand adaptor using MAP30 gene sequence of Momordica charantia plant as a model to improve genome walking with convenient PCR.

RESULTS

The adaptor was designed using multiple restriction sites of Hind III, BamH I, EcoR I, and Bgl II enzymes with no restriction site in a known sequence of the MAP30 gene. In addition, no modification was required to add phosphate, amine, or other groups to the adaptor, since restriction enzyme digestion of double-strand adaptor provided the 5' phosphate group. Here, preparation of the phosphate group in the genomic DNA of the plant digestion with restriction enzymes was performed followed by ligation with digested adaptor containing 5' phosphate group.

CONCLUSION

PCR was done to amplify the unknown sequence using MAP30 gene-specific primer and adaptor primer. Results confirmed the ability of the technique for successful identification of the sequence. Consequently, a newly designed adaptor in the developed technique reduced the time and cost of the method compared to the conventional genome walking; also, cloning and culturing of bacterial steps could be eliminated.

A Simple Genome Walking Strategy to Isolate Unknown Genomic Regions Using Long Primer and RAPD Primer

Background

Genome walking is a DNA-cloning methodology that is used to isolate unknown genomic regions adjacent to known sequences. However, the existing genome-walking methods have their own limitations.

Objectives

Our aim was to provide a simple and efficient genome-walking technology.

Material and Methods

In this paper, we developed a novel PCR strategy (termed SLRA PCR) that uses a single long primer (SLP), a set of gene specific primers (GSP), and a random amplified polymorphic DNA (RAPD) primer for genome walking. SLRA PCR consists of two processes: the first amplification using SLP, and three successive rounds of nested PCR amplified by GSP and RAPD primer. The novelty of the approach lies in the use of long primers (SLP and GSP) and same annealing and extension temperature 68℃ in combination. This method offers higher amplification efficiency, superior versatility, and greater simplicity compared with conventional randomly primed PCR methods for genome walking.

Results

The promoter regions and the first introns of the insulin-like androgenic gland hormone (IAG) gene and the hemocyanin gene of Macrobrachium nipponense were cloned using SLRA PCR, respectively.

Conclusions

This genome walking strategy can be applied to a wide range of genomes.

Stepwise partially overlapping primer-based PCR for genome walking

A stepwise partially overlapping primer-based PCR (SWPOP-PCR) method for isolating flanking unknown DNA regions was developed, which comprises three rounds of nested PCRs sequentially driven by SWPOP primer-nested specific primer pairs. SWPOP primer set is characterized by a partial overlap of 10 bp with 3′-part of the latter primer is identical to 5′-part of the former one, which makes the SWPOP primer in use anneal to SWPOP site of the prior PCR product only at relatively low temperature. For each PCR, target single-stranded DNA primed by the SWPOP primer in the exclusive one low-stringency cycle is converted into double-stranded form in the following high-stringency cycle due to the presence of a perfect annealing site for the specific primer. This double-stranded DNA bounded by the specific primer and the SWPOP primer is exponentially amplified in the remaining high-stringency cycles. Non-target single-stranded DNA, however, cannot be amplified given the lack of perfect complementary sequences for any primers. Therefore, the partial overlap of a SWPOP primer set preferentially synthesizes target products but inhibits nonspecific amplification. We successfully exploited SWPOP-PCR to obtain the DNA sequences flanking glutamate decarboxylase gene (gadA) locus in Lactobacillus brevis NCL912 and hygromycin gene (hyg) integrated in rice.

Recent advances in universal TA cloning methods for use in function studies

As one of the simplest and most efficient cloning methods, T-vector-based TA cloning has been widely used for cloning of single genes and construction of DNA libraries. This approach is especially suitable for high-throughput cloning of diverse DNA fragments since inserts can be cloned without knowledge of their sequence; it is therefore an ideal tool for high-throughput analysis of protein structure and function. Although most of the currently available T-vectors can only be used for cloning purposes, some novel variants with improved functions have be developed. This review focuses on recent developments of universal TA cloning methods and T-vectors constructed for function studies.

Partially overlapping primer-based PCR for genome walking

Current genome walking methods are cumbersome to perform and can result in non-specific products. Here, we demonstrate the use of partially overlapping primer-based PCR (POP-PCR), a direct genome walking technique for the isolation of unknown flanking regions. This method exploits the partially overlapping characteristic at the 3’ ends of a set of POP primers (walking primers), which guarantees that the POP primer only anneals to the POP site of the preceding PCR product at relatively low temperatures. POP primer adaptation priming at the genomic DNA/POP site occurs only once due to one low-/reduced-stringency cycle in each nested PCR, resulting in the synthesis of a pool of single-stranded DNA molecules. Of this pool, the target single-stranded DNA is replicated to the double-stranded form bound by the specific primer and the POP primer in the subsequent high-stringency cycle due to the presence of the specific primer-binding site. The non-target single stranded DNA does not become double stranded due to the absence of a binding site for any of the primers. Therefore, the POP-PCR enriches target DNA while suppressing non-target products. We successfully used POP-PCR to retrieve flanking regions bordering the gadA locus in Lactobacillus brevis NCL912, malQ in Pichia pastoris GS115, the human aldolase A gene, and hyg in rice.