A novel method to perform genomic walks using a combination of single strand DNA circularization and rolling circle amplification

Characterization of regions flanking a known sequence within a genome, known as genome walking, is a cornerstone technique in modern genetic analysis. In the present work we have developed a new PCR-dependent, directional genome walking protocol based on the unique circularization property of a novel DNA ligase, CircLigase. In the first step, PCR based primer extension is performed using a phosphorylated primer, designed to extend from the boundary of the known sequence, into the flanking region. This linear amplification results in the generation of single-stranded (ss) DNA, which is then circularized using CircLigase. Using the hyperbranching activity of Phi29 DNA polymerase, the circular ssDNA is then linearized by rolling circle amplification, resulting in copious amounts of double stranded concatameric DNA. Nested primers are used to amplify the flanking sequence using inverse PCR. The products are resolved on an agarose gel and the bands whose mobility change due to the nested location of the primer combination used are identified, extracted, and cloned into a plasmid vector for sequencing. Empirical proof for this concept was generated on two antimicrobial biosynthetic genes in Pseudomonas sp. LBUM300. Using the hcnB and phlD genes as starting points, ca 1 kb of flanking sequences were successfully isolated. The use of locus specific primers ensured both directionality and specificity of the walks, alleviating the generation of spurious amplicons, typically observed in randomly primed walking protocols. The presented genome walking protocol could be applied to any microbial genome and requires only 100-150 bp of prior sequence information. The proposed methodology does not entail laborious testing of restriction enzymes or adaptor ligation. This is the first report of a successful application of the novel ligase enzyme, CircLigase for genomic walking purposes.     

A high-throughput genome-walking method and its use for cloning unknown flanking sequences

We developed a PCR-based high-throughput genome-walking protocol. The novelty of this protocol is in the random introduction of unique walker primer binding sites into different regions of the genome efficiently by taking advantage of the rolling circle mode of DNA synthesis by Phi29 DNA polymerase after annealing the partially degenerate primers to the denatured genomic DNA. The inherent strand-displacement activity of the Phi29 DNA polymerase displaces the 5′ ends of downstream strands and DNA synthesis continues, resulting in a large number of overlapping fragments that cover the whole genome with the unique walker adapter attached to the 5′ end of all the genomic DNA fragments. The directional genome walking can be performed using a locus-specific primer and the walker primer and Phi29 DNA polymerase-amplified genomic DNA fragments as template. The locus-specific primer will determine the position and direction of the genome walk. Two rounds of successive PCR amplifications by locus-specific and walker primers and their corresponding nested primers effectively amplify the flanking DNA fragments. The desired PCR fragment can be either cloned or sequenced directly using another nested, locus-specific primer. We successfully used this protocol to isolate and sequence 5′ flanking regions/promoters of selected plant genes.     

A novel PCR strategy for high-efficiency, automated site-directed mutagenesis

We have developed a novel three-primer, one-step PCR-based method for site-directed mutagenesis. This method takes advantage of the fact that template plasmid DNA cannot be efficiently denatured at its reannealing temperature (T_ra), which is otherwise a troublesome problem in regular PCR. Two flanking primers and one mutagenic primer with different melting temperatures (T_m) are used together in a single PCR tube continuously without any intervention. A single-stranded mutagenic DNA (smDNA) is synthesized utilizing the high T_m mutagenic primer at a high annealing temperature, which prevents the priming of the low T_m primers (i.e. the two flanking primers). A megaprimer is then produced using this smDNA as the template at a denaturing temperature that prevents wild-type template DNA activity. The desired mutant DNA is then obtained by cycling again through these first two steps, resulting in a mutagenic efficiency of 100% in all tested cases. This highly automated method not only eliminates the necessity of any intermediate manipulation and accomplishes the mutagenesis process in a single round of PCR but, most notably, enables complete success of mutagenesis. This novel method is also both cost and time efficient and fully automated.     

A primer-based approach to genome walking

A genome walking strategy based on annealing and ligation of single-stranded DNA primers to 3′ overhangs following restriction endonuclease digestion was developed. A set of primers contains 4 nucleotides at the 3′ end that are complementary to overhangs formed by restriction endonucleasesApaI;PstI;SacI andSphI. Following ligation, 5′ end overhangs are formed on the DNA, which serves as sites for the adaptor primers and nested primers for PCR amplification in combination with the gene-specific primers. This strategy was verified by the amplification of up to 4 kb of a potato leafroll virus full-length infectious clone. The procedure could be adopted to target any upstream and downstream regions flanking known sequences within the plant genome.     

NGS-PrimerPlex: High-throughput primer design for multiplex polymerase chain reactions

Multiplex polymerase chain reaction (PCR) has multiple applications in molecular biology, including developing new targeted next-generation sequencing (NGS) panels. We present NGS-PrimerPlex, an efficient and versatile command-line application that designs primers for different refined types of amplicon-based genome target enrichment. It supports nested and anchored multiplex PCR, redistribution among multiplex reactions of primers constructed earlier, and extension of existing NGS-panels. The primer design process takes into consideration the formation of secondary structures, non-target amplicons between all primers of a pool, primers and high-frequent genome single-nucleotide polymorphisms (SNPs) overlapping. Moreover, users of NGS-PrimerPlex are free from manually defining input genome regions, because it can be done automatically from a list of genes or their parts like exon or codon numbers. Using the program, the NGS-panel for sequencing the LRRK2 gene coding regions was created, and 354 DNA samples were studied successfully with a median coverage of 97.4% of target regions by at least 30 reads. To show that NGS-PrimerPlex can also be applied for bacterial genomes, we designed primers to detect foodborne pathogens Salmonella enterica, Escherichia coli O157:H7, Listeria monocytogenes, and Staphylococcus aureus considering variable positions of the genomes.     

The complete mitochondrial genome of the intertidal copepod Tigriopus sp. (Copepoda, Harpactidae) from Korea and phylogenetic considerations

This paper reports on the basic characteristics of the mitochondrial genome of the intertidal copepod Tigriopus sp. from Korea, including its structural organization, base composition of rRNAs and protein-encoding genes, and the secondary structure of tRNAs. We amplified the complete mitochondrial DNA of the intertidal copepod Tigriopus sp. from Korea (sampling site Busan) by long-polymerase chain reaction (long-PCR) with conserved primers and sequenced this mitogenome by primer walking using flanking sequences as sequencing primers. The primer informations were obtained as expressed sequence tags (ESTs) from Tigriopus sp. The resultant Tigriopus sp. mitochondrial DNA sequence was 14,301 bp with a conserved structural organization, compared to that of T. japonicus from Japan with significant differences in several protein-coding regions including rRNAs, although the genomic organization of the mitochondrial genome was identical. In order to investigate biogeographic differences within the genus Tigriopus, we analyzed the CO1 gene by sequencing. This way, we compared several Tigriopus species from Korea, Japan, Hong Kong and Taiwan as well as other related species such as T. californicus, T. brevicornis and T. fulvus. The results further support the notion that the copepods display significantly different genomes within the same genus. These findings provide valuable genomic information for further studies on the population genetics and speciation processes within the genus Tigriopus.     

Gene stability in transgenic aspen (Populus). I. Flanking DNA sequences and T-DNA structure

The stability of transgenes in the genome of transformed plants depends strongly on their correct physical integration into the host genome as well as on flanking target DNA sequences. For long-lived species like trees, however, no information is available so far concerning inactivation or loss of transgenes due to gene silencing or somatic genome rearrangement events. In this study, four independently transformed 35S-rolC transgenic hybrid aspen plants (Populus tremula L.?×?tremuloides Michx.), each harbouring one copy of the transgene, were investigated during continuous growth in the greenhouse. In one of these transgenic lines (Esch5:35S-rolC-##1) individuals frequently show phenotypic reversions, while in the remaining three lines (Esch5:35S-rolC-#3, -#5, -#16) the gene was essentially stable. Molecular analysis including PCR, Southern and Northern assays clearly showed that the transgene had been lost in the revertant tissue of the unstable line. Sequencing of T-DNA right and left borders, and flanking DNA regions, in all four transgenic aspen lines revealed no differences either in the type of flanking DNA (G-C to A-T ratio) or with respect to the presence of enhancers or MAR (matrix associated repeats)-like structures. Primers located within the left and right flanking regions in the three stable lines could be used to recover the target sites from the untransformed plants. This was not possible, however, with the unstable line, indicating that at least one flanking sequence does not derive from the plant target DNA but is of unknown origin. PCR using other primer pairs, and inverse PCR analysis, revealed an additional truncated T-DNA copy of 1050 nucleotides adjacent to the left border of the complete copy in this line. Sequencing of this truncated T-DNA revealed that it represented an inverted copy of part of the right half of the original construct. This special feature would allow the inverted repeat to pair with right border sequences of the complete copy. This would explain the frequently observed reversion resulting in transgene loss as due to intrachromosomal base-pairing leading to double-stranded loops of single-stranded DNA during mitotic cell divisions.     

Bioluminescent reporters for identification of gene allelic variants

A method for single nucleotide polymorphism identification was developed, which was based on the primer extension reaction (PEXT) followed by bioluminescent solid-phase microassay. Recombinant Ca²⁺-regulated photoprotein obelin and coelenterazine-dependent Renilla muelleri luciferase were used as reporters. The study was performed as an example of SNP genotyping of the human F5 gene encoding human Factor V Leiden polymorphism 1691 G??A (R506Q). Genomic DNA was amplified by PCR using primers flanking polymorphic site of 140 base pairs. PCR products were used as templates for two PEXT reactions using two primers containing 3??-terminal nucleotides, which were complementary to either normal or mutant alleles. If the template and allele-specific primer were completely complementary, the latter was elongated with DNA polymerase. The resulting extension product contained biotin residue due to the presence of biotinylated deoxyuridine triphosphate (B-dUTP) in the reaction mixture. The products were analyzed using obelin-streptavidin conjugates. The optimal PEXT-reaction conditions were found, which ensured a high reliability of SNP genotyping. A new approach to simultaneously revealing both alleles in one well was developed using two bioluminescent reporters. The efficiency of the proposed approach was shown in the study of clinical DNA samples.     

Conserved PCR primer set designing for closely-related species to complete mitochondrial genome sequencing using a sliding window-based PSO algorithm

Background

Complete mitochondrial (mt) genome sequencing is becoming increasingly common for phylogenetic reconstruction and as a model for genome evolution. For long template sequencing, i.e., like the entire mtDNA, it is essential to design primers for Polymerase Chain Reaction (PCR) amplicons which are partly overlapping each other. The presented chromosome walking strategy provides the overlapping design to solve the problem for unreliable sequencing data at the 5′ end and provides the effective sequencing. However, current algorithms and tools are mostly focused on the primer design for a local region in the genomic sequence. Accordingly, it is still challenging to provide the primer sets for the entire mtDNA.

Methodology/Principal Findings

The purpose of this study is to develop an integrated primer design algorithm for entire mt genome in general, and for the common primer sets for closely-related species in particular. We introduce ClustalW to generate the multiple sequence alignment needed to find the conserved sequences in closely-related species. These conserved sequences are suitable for designing the common primers for the entire mtDNA. Using a heuristic algorithm particle swarm optimization (PSO), all the designed primers were computationally validated to fit the common primer design constraints, such as the melting temperature, primer length and GC content, PCR product length, secondary structure, specificity, and terminal limitation. The overlap requirement for PCR amplicons in the entire mtDNA is satisfied by defining the overlapping region with the sliding window technology. Finally, primer sets were designed within the overlapping region. The primer sets for the entire mtDNA sequences were successfully demonstrated in the example of two closely-related fish species. The pseudo code for the primer design algorithm is provided.

Conclusions/Significance

In conclusion, it can be said that our proposed sliding window-based PSO algorithm provides the necessary primer sets for the entire mt genome amplification and sequencing.     

A tailing genome walking method suitable for genomes with high local GC content

The tailing genome walking strategies are simple and efficient. However, they sometimes can be restricted due to the low stringency of homo-oligomeric primers. Here we modified their conventional tailing step by adding polythymidine and polyguanine to the target single-stranded DNA (ssDNA). The tailed ssDNA was then amplified exponentially with a specific primer in the known region and a primer comprising 5′ polycytosine and 3′ polyadenosine. The successful application of this novel method for identifying integration sites mediated by φC31 integrase in goat genome indicates that the method is more suitable for genomes with high complexity and local GC content.     

Transposon mutagenesis: Cloning of chromosomal DNA from the site of Tn916 insertion using polymerase chain reaction

A protocol that allows fast recovery and further analyses of chromosomal DNA adjacent to the Tn916 site of insertion is described. The procedure is based on single specific primer PCR amplification using restricted chromosomal DNA ligated into a suitable vector. Two primers, one Tn916-specific and the second vector-specific, allow amplification of the chromosomal DNA flanking the site of insertion.     

Genome walking of large fragments: an improved method

The PCR-based genome walking method has been commonly used to isolate upstream regions from known cDNA sequences. The limitation of this technique is based on the location of the restriction site upstream to the gene-specific primer in the genome; hence, different restriction enzymes have to be used to isolate larger upstream fragments. In this paper, we present the advantageous use of partial and size-selected DNA as templates for genome walking, in isolating larger upstream fragments. We have successfully tested this approach to isolate larger upstream fragments using the FailSafe PCR System. Use of partial digestion and size selection can provide better chances in obtaining larger flanking regions of known DNA sequence, when compared to use of total digested DNA.     

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

To identify the transposon insertion sites in a soil actinomycete, Saccharopolyspora spinosa, a genome walking approach, termed SPTA-PCR, was developed. In SPTA-PCR, a simple procedure consisting of TA cloning and a high stringency PCR, following the single primer-mediated, randomly-primed PCR, can eliminate non-target DNA fragments and obtain target fragments specifically. Using SPTA-PCR, the DNA sequence adjacent to the highly conserved region of lectin coding gene in onion plant, Allium chinense, was also cloned.     

Targeted cloning of a subfamily of LINE-1 elements by subfamily-specific LINE-1-PCR

Subfamily-specific LINE-1 PCR (SSL1-PCR) is the targeted amplification and cloning of defined subfamilies of LINE-1 elements and their flanking sequences. The targeting is accomplished by incorporating a subfamily-specific sequence difference at the 3 end of a LINE-1 PCR primer and pairing it with a primer to an anchor ligated within the flanking region. SSL1-PCR was demonstrated by targeting amplification of a Mus spretus-specific LINE-1 subfamily. The amplified fragments were cloned to make an SSL1-PCR library, which was found to be 100-fold enriched for the targeted elements. PCR primers were synthesized based on the sequence flanking the LINE-1 element of four different clones. Three of the clones were recovered from Mus spretus DNA. A fourth clone was recovered from a congenic mouse containing both Mus spretus and Mus domesticus DNA. Amplification between these flanking primers and LINE-1 PCR primers produced a product in Mus spretus and not in Mus domesticus. These dimorphisms were further verified to be due to insertion of Mus spretus-specific LINE-1 elements into Mus spretus DNA and not into Mus domesticus DNA.     

Straight Walk: A modified method of ligation-mediated genome walking for plant species with large genomes

Polymerase chain reaction (PCR)-based genome walking techniques are commonly used to clone unknown genomic regions flanking known sequences. However, these methods are typically problematic when applied to highly complex DNA templates isolated from plants with large genomes. Here we describe a reliable and efficient genome walking method that is particularly effective for plants with large genomes. Our ligation-mediated PCR method, Straight Walk, has improved sensitivity and specificity due to optimization of sequences of adaptors and adaptor primers. Successful genome walking in lily, which has one of the largest genomes in plants, indicates that Straight Walk is applicable for most plant species.     

A-T linker adapter polymerase chain reaction for determining flanking sequences by rescuing inverse PCR or thermal asymmetric interlaced PCR products

The polymerase chain reaction (PCR)-based genome walking method has been extensively used to isolate unknown flanking sequences, whereas nonspecific products are always inevitable. To resolve these problems, we developed a new strategy to isolate the unknown flanking sequences by combining A-T linker adapter PCR with inverse PCR (I–PCR) or thermal asymmetric interlaced PCR (TAIL–PCR). The result showed that this method can be efficiently achieved with the flanking sequence from the Arabidopsis mutant and papain gene. Our study provides researchers with an additional method for determining genomic DNA flanking sequences to identify the target band from bulk of bands and to eliminate the cloning step for sequencing.     

Generation of anNco I restriction site for translational fusions using PCR-mediated,site-directed mutagenesis

A polymerase chain reaction-based method of site-directed mutagenesis was used to introduce anNco I restriction site on the translation start site of a tomato peroxidase gene. This quick and efficient method utilized two overlapping synthetic oligonucleotide primers containing the requisite base pair changes on the ATG translation start site and two flanking primers in PCR. The resulting DNA amplified fragments were fused together byNco I digestion at the mutated ends followed by a T4 ligation reaction. A rapid alternative method utilizing the overlapping fragments and the flanking primers in PCR can also be used for ligating the two fragments. Cloning and sequencing of the PCR-amplified fragments provided additional evidence for the presence of the site-specific mutations. Unique restriction sites upstream and downstream of the site-specific mutation allows for the easy transfer of this mutated region into the wild type peroxidase gene.     

Template-blocking PCR: An advanced PCR technique for genome walking

This article describes the development of an improved method for the isolation of genomic fragments adjacent to a known DNA sequence based on a cassette ligation-mediated polymerase chain reaction (PCR) technique. To reduce the nonspecific amplification of PCR-based genome walking, the 3′ ends of the restriction enzyme-digested genomic DNA fragments were blocked with dideoxynucleoside triphosphate (ddNTP) and ligated with properly designed cassettes. The modified genomic DNA fragments flanked with cassettes were used as a template for the amplification of a target gene with a gene-specific primer (GSP) and a cassette primer (CP). The ddNTP blocking of the genomic DNA ends significantly reduced the nonspecific amplification and resulted in a simple and rapid walking along the genome. The efficiency of the template-blocking PCR method was confirmed by a carefully designed control experiment. The method was successfully applied for the cloning of the PGK1 promoter from Pichia ciferrii and two novel cellulase genes from Penicillium sp.     

SiteFinding-PCR: a simple and efficient PCR method for chromosome walking

In this paper, we present a novel PCR method, termed SiteFinding-PCR, for gene or chromosome walking. The PCR was primed by a SiteFinder at a low temperature, and then the target molecules were amplified exponentially with gene-specific and SiteFinder primers, and screened out by another gene-specific primer and a vector primer. However, non-target molecules could not be amplified exponentially owing to the suppression effect of stem–loop structure and could not be screened out. This simple method proved to be efficient, reliable, inexpensive and time-saving, and may be suitable for the molecules for which gene-specific primers are available. More importantly, large DNA fragments can be obtained easily using this method. To demonstrate the feasibility and efficiency of SiteFinding-PCR, we employed this method to do chromosome walking and obtained 16 positive results from 17 samples.     

A simple and efficient method for constructing high resolution physical maps.

This paper describes a simple and efficient walking method for constructing high resolution physical maps and discusses its applications to genome analysis. The method is an integration of three strategies: (1) use of a highly redundant library of 3Kb-long subclones; (2) construction of a multidimensional pool from the library; (3) direct application of a PCR (polymerase chain reaction)-based screening technique to the pooled library, with two PCR primers, one from the end of the subcloning vector and the other from the leading edge of the walk. This technique allows not only detection of each overlapping subclone but simultaneous determination of its orientation and the size of its overlap. The end of the subclone with the smallest overlap is sequenced and a primer is designed for the next step in the walk. Iteration of the screening procedure with minimum overlapping subclones results in completion of the high resolution map. Using this method, a 3Kb-resolution map was constructed from an 80Kb region of the bithorax complex of Drosophila melanogaster. The method is general enough to be applicable to DNA from other species, and simple enough to be automated.