应用接头PCR克隆慢病毒介导的转基因小鼠整合位点旁侧序列

目的为鉴定慢病毒介导的转基因小鼠中外源基因的整合位点信息,应用接头PCR克隆整合位点旁侧序列。方法小鼠基因组总DNA酶解后与设计的接头片段连接,根据慢病毒的LTR序列设计巢式PCR引物,克隆转基因小鼠整合位点旁侧序列。结果成功克隆到转基因小鼠整合位点的旁侧序列,经过测序定位于小鼠染色体上。结论作为反向PCR的改进,本方法可用于转基因小鼠整合位点旁侧序列的克隆,为分析整合位点与外源基因表达之间的关系等提供了科学依据。     

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 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.     

IRAP and REMAP for retrotransposon-based genotyping and fingerprinting

Retrotransposons can be used as markers because their integration creates new joints between genomic DNA and their conserved ends. To detect polymorphisms for retrotransposon insertion, marker systems generally rely on PCR amplification between these ends and some component of flanking genomic DNA. We have developed two methods, retrotransposon-microsatellite amplified polymorphism (REMAP) analysis and inter-retrotransposon amplified polymorphism (IRAP) analysis, that require neither restriction enzyme digestion nor ligation to generate the marker bands. The IRAP products are generated from two nearby retrotransposons using outward-facing primers. In REMAP, amplification between retrotransposons proximal to simple sequence repeats (microsatellites) produces the marker bands. Here, we describe protocols for the IRAP and REMAP techniques, including methods for PCR amplification with a single primer or with two primers and for agarose gel electrophoresis of the product using optimal electrophoresis buffers and conditions. This protocol can be completed in 1-2 d.     

Cloning and direct sequencing of plant promoters using primer-adapter mediated PCR on DNA coupled to a magnetic solid phase.

A method that allows amplification and direct sequencing or cloning of an unknown DNA segment flanked by a known sequence is described using barley genomic DNA. The method avoids the step of circularization necessary for inverse PCR by ligation of primer-adapters to restricted genomic DNA. Specificity is achieved in the first amplification step; linear PCR with a biotinylated primer complementary to the known flanking sequence (primer 1-B) produces a single-stranded product that is purified employing streptavidin-coated magnetic beads. After this step, which removes genomic DNA, two rounds of exponential PCR are performed, first with the adapter-primer and primer 1 and second with primer 1 substituted by a nested primer 2. If the second primer is biotinylated, the product can be sequenced directly using solid-phase sequencing. We have employed this method to sequence directly and to clone the promoters of two late embryogenesis-abundant (Lea) genes (B19.4 and B19.3) from barley. Lea B19.4 and B19.3 encode putative desiccation-protective proteins that act in the final stages of embryogenesis and have previously been cloned as cDNAs. We demonstrate here that their proximal promoter regions are very similar (80% identity) and that both contain putative abscisic acid-responsive elements.     

Rapid amplification of genomic ends (RAGE) as a simple method to clone flanking genomic DNA

This report describes the amplification of upstream genomic sequences using the polymerase chain reaction (PCR) based solely on downstream DNA information from a cDNA clone. In this novel and rapid technique, genomic DNA (gDNA) is first incubated with a restriction enzyme that recognizes a site within the 5′ end of a gene, followed by denaturation and polyadenylation of its free 3′ ends with terminal transferase. The modified gDNA is then used as template for PCR using a gene-specific primer complementary to a sequence in the 3′ end of its cDNA and an anchored deoxyoligothymidine primer. A second round of PCR is then performed with a second, nested gene-specific primer and the anchor sequence primer. The resulting PCR product is cloned and its sequence determined. Three independent plant genomic clones were isolated using this method that exhibited complete sequence identity to their cDNAs and to the primers used in the amplification.     

AFLP: a new technique for DNA fingerprinting.

A novel DNA fingerprinting technique called AFLP is described. The AFLP technique is based on the selective PCR amplification of restriction fragments from a total digest of genomic DNA. The technique involves three steps: (i) restriction of the DNA and ligation of oligonucleotide adapters, (ii) selective amplification of sets of restriction fragments, and (iii) gel analysis of the amplified fragments. PCR amplification of restriction fragments is achieved by using the adapter and restriction site sequence as target sites for primer annealing. The selective amplification is achieved by the use of primers that extend into the restriction fragments, amplifying only those fragments in which the primer extensions match the nucleotides flanking the restriction sites. Using this method, sets of restriction fragments may be visualized by PCR without knowledge of nucleotide sequence. The method allows the specific co-amplification of high numbers of restriction fragments. The number of fragments that can be analyzed simultaneously, however, is dependent on the resolution of the detection system. Typically 50-100 restriction fragments are amplified and detected on denaturing polyacrylamide gels. The AFLP technique provides a novel and very powerful DNA fingerprinting technique for DNAs of any origin or complexity.     

Rapid development of gene-tagged microsatellite markers from bacterial artificial chromosome clones using anchored TAA repeat primers

We developed a technique to improve the efficiency of producing TAA repeat microsatellite markers linked to interspecific conserved genes. Template DNA was prepared from cultures derived from single bacterial artificial chromosome (BAC) colonies using a simple alkaline lysis miniprep. The presence of conserved genes in each BAC clone was verified by sequencing with gene-specific primers. The BAC templates were directly sequenced using short tandem repeat-anchored primers (STRAPs), consisting of TAA repeats with one or two unique 3' terminal bases. At least one STRAP provided sufficient 3' flanking sequence from each clone for the design of a BAC-specific primer. The BAC-specific primer was used to sequence back through the tandem repeat and obtain 5' flanking sequence, and a second BAC-specific primer was designed for microsatellite genotype analysis. This technique quickly provided microsatellite markers with an average of 15 tandem repeats for the BAC clones tested. The identification of polymorphic microsatellite loci in these clones permits the identification of alleles linked to candidate genes, placement of conserved genes on genetic linkage maps, and integration of linkage and physical maps.     

利用Red重组系统快速构建基因打靶载体

基因敲除小鼠模型是在哺乳动物体内研究基因功能最可靠的方法之一。利用常规的分子克隆的方法构建基因打靶载体往往工作周期长,对于难度特别大的基因有时甚至无法完成打靶载体的构建。通过合理应用Red重组系统和低拷贝中间载体,利用50bp的同源重组序列直接从BAC载体中克隆了长片段的小鼠基因组序列;将得到的基因组序列再次通过重组和改造,构建了Gpr56等基因的完全敲除并带有报告基因的打靶载体,实现了打靶载体的快速构建。     

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.     

MARA: a novel approach for highly multiplexed locus-specific SNP genotyping using high-density DNA oligonucleotide arrays

We have developed a locus-specific DNA target preparation method for highly multiplexed single nucleotide polymorphism (SNP) genotyping called MARA (Multiplexed Anchored Runoff Amplification). The approach uses a single primer per SNP in conjunction with restriction enzyme digested, adapter-ligated human genomic DNA. Each primer is composed of common sequence at the 5′ end followed by locus-specific sequence at the 3′ end. Following a primary reaction in which locus-specific products are generated, a secondary universal amplification is carried out using a generic primer pair corresponding to the oligonucleotide and genomic DNA adapter sequences. Allele discrimination is achieved by hybridization to high-density DNA oligonucleotide arrays. Initial multiplex reactions containing either 250 primers or 750 primers across nine DNA samples demonstrated an average sample call rate of ~95% for 250- and 750-plex MARA. We have also evaluated >1000- and 4000-primer plex MARA to genotype SNPs from human chromosome 21. We have identified a subset of SNPs corresponding to a primer conversion rate of ~75%, which show an average call rate over 95% and concordance >99% across seven DNA samples. Thus, MARA may potentially improve the throughput of SNP genotyping when coupled with allele discrimination on high-density arrays by allowing levels of multiplexing during target generation that far exceed the capacity of traditional multiplex PCR.     

Gene splicing and mutagenesis by PCR-driven overlap extension

Extension of overlapping gene segments by PCR is a simple, versatile technique for site-directed mutagenesis and gene splicing. Initial PCRs generate overlapping gene segments that are then used as template DNA for another PCR to create a full-length product. Internal primers generate overlapping, complementary 3' ends on the intermediate segments and introduce nucleotide substitutions, insertions or deletions for site-directed mutagenesis, or for gene splicing, encode the nucleotides found at the junction of adjoining gene segments. Overlapping strands of these intermediate products hybridize at this 3' region in a subsequent PCR and are extended to generate the full-length product amplified by flanking primers that can include restriction enzyme sites for inserting the product into an expression vector for cloning purposes. The highly efficient generation of mutant or chimeric genes by this method can easily be accomplished with standard laboratory reagents in approximately 1 week.     

Development of primer sets designed for use with the PCR to amplify conserved genes from filamentous ascomycetes.

We constructed nine sets of oligonucleotide primers on the basis of the results of DNA hybridization of cloned genes from Neurospora crassa and Aspergillus nidulans to the genomes of select filamentous ascomycetes and deuteromycetes (with filamentous ascomycete affiliations). Nine sets of primers were designed to amplify segments of DNA that span one or more introns in conserved genes. PCR DNA amplification with the nine primer sets with genomic DNA from ascomycetes, deuteromycetes, basidiomycetes, and plants revealed that five of the primer sets amplified a product only from DNA of the filamentous ascomycetes and deuteromycetes. The five primer sets were constructed from the N. crassa genes for histone 3, histone 4, beta-tubulin, and the plasma membrane ATPase. With these five primer sets, polymorphisms were observed in both the size of and restriction enzyme sites in the amplified products from the filamentous ascomycetes. The primer sets described here may provide useful tools for phylogenetic studies and genome analyses in filamentous ascomycetes and deuteromycetes (with ascomycete affiliations), as well as for the rapid differentiation of fungal species by PCR.     

Seamless gene engineering using RNA- and DNA-overhang cloning

Here we describe two methods for generating DNA fragments with single-stranded overhangs, like those generated by the activity of many restriction enzymes, by simple methods that do not involve DNA digestion. The methods, RNA-overhang cloning (ROC) and DNA-overhang cloning (DOC), generate polymerase chain reaction (PCR) products composed of double-stranded (ds) DNA flanked by single-stranded (ss) RNA or DNA overhangs. The overhangs can be used to recombine DNA fragments at any sequence location, creating "perfect" chimeric genes composed of DNA fragments that have been joined without the insertion, deletion, or alteration of even a single base pair. The ROC method entails using PCR primers that contain regions of RNA sequence that cannot be copied by certain thermostable DNA polymerases. Using such a chimeric primer in PCR would yield a product with a 5' overhang identical to the sequence of the RNA component of the primer, which can be used for directional ligation of the amplified product to other preselected DNA molecules. This method provides complete control over both the length and sequence of the overhangs, and eliminates the need for restriction enzymes as tools for gene engineering.     

New strategy for identification of novel Cry-type genes from Bacillus thuringiensis strains

We designed five degenerate primers for detection of novel cry genes from Bacillus thuringiensis strains. An efficient strategy was developed based on a two-step PCR approach with these primers in five pair combinations. In the first step, only one of the primer pairs is used in the PCR, which allows amplification of DNA fragments encoding protein regions that include consensus domains of representative proteins belonging to different Cry groups. A second PCR is performed by using the first-step amplification products as DNA templates and the set of five primer combinations. Cloning and sequencing of the last-step amplicons allow both the identification of known cry genes encoding Cry proteins covering a wide phylogenetic distance and the detection and characterization of cry-related sequences from novel B. thuringiensis isolates.     

粘虫核型多角体病毒919bp片段的PCR双链直接序列测定

本文发展了ＰＣＲ克隆和亚克隆技术制备ＤＮＡ测序模板。首先,我们用ｐＵＣ／Ｍ１３系列质粒的通用正反向引物ＰＣＲ扩增出质粒ｐＢｌｕｅｓｃｒｉｐｔＫＳＤＮＡ的多克隆位点及其侧翼序列,用ＥｃｏＲＶ和ＸｈｏＩ消化成为左右两个引物多克隆臂,与粘虫核型多角体病毒（ＬｓＮＰＶ）的ＥｃｏＲＶ和ＸｈｏＩ约４００ｂｐ和５００ｂｐ片段分别连接,经ＰＣＲ扩增,得到两端具有上述正反向引物结合位点的测序模板,用ｄｄＮＴＰ链终止法／ＰＣＲ扩增／银染色,从片段两端测定了全部９１９ｂｐ序列,这种ｄｄＮＴＰ／ＰＣＲ／银染测序法简化了操作,大大缩短了测序模板的制备时间,易于实现自动化操作。     

Restriction enzyme site-directed amplification PCR: a tool to identify regions flanking a marker DNA

An innovative combination of various recently described molecular methods was set up to efficiently identify regions flanking a marker DNA in insertional mutants of Chlamydomonas. The technique is named restriction enzyme site-directed amplification PCR (RESDA-PCR) and is based on the random distribution of frequent restriction sites in a genome and on a special design of primers. The primer design is based on the presence of a restriction site included in a low degenerated sequence at the 3' end and of a specific adapter sequence at the 5' end, with the two ends being linked by a polyinosine bridge. Specific primers of the marker DNA combined with the degenerated primers allow amplification of DNA fragments adjacent to the marker insertion by using two rounds of either short or long cycling procedures. Amplified fragments from 0.3 to 2 kb or more are routinely obtained at sufficient purity and quantity for direct sequencing. This method is fast, is reliable (87% success rate), and can be easily extrapolated to any organism and marker DNA by designing the appropriate primers. A procedure involving the PCR over enzyme digest fragments is also proposed for when, exceptionally, positive results are not obtained.     

A convenient and robust method for construction of combinatorial and random mutant libraries

Here we describe a convenient and robust ligase-independent method for construction of combinatorial and random mutant libraries. The homologous genes flanked by plasmid-derived DNA sequences are fragmented, and the random fragments are reassembled in a self-priming polymerase reaction to obtain chimeric genes. The product is then mixed with linearized vector and two pairs of flanking primers, followed by assembly of the chimeric genes and linearized vector by PCR to introduce recombinant plasmids of a combinatorial library. Commonly, it is difficult to find proper restriction sites during the construction of recombinant plasmids after DNA shuffling with multiple homologous genes. However, this disadvantage can be overcome by using the ligase-independent method because the steps of DNA digestion and ligation can be avoided during library construction. Similarly, DNA sequences with random mutations introduced by error-prone PCR can be used to construct recombinant plasmids of a random mutant library with this method. Additionally, this method can meet the needs of large and comprehensive DNA library construction.     

PCR-based approach for detection of novel Bacillus thuringiensis cry genes.

A two-step strategy, named exclusive PCR or E-PCR, has been developed to overcome the main limitation of PCR, which is the detection of already-known sequences only. This strategy allows the ability to detect and further clone and sequence genes for which no specific primers are available and in which a variable region exists between two conserved regions. This approach has been applied to Bacillus thuringiensis cryI genes by the use of mixtures of degenerate and specific primers recognizing well-known sequences. The first step allows the accurate identification of already-characterized cryI genes by the use of three primers. During the second step, the same sets of primers are used to exclude known sequences and to positively detect cryI genes unrecognized by any specific primer. The method, as well as its application to detect, clone, and sequence a novel cryIB gene, is described in this article.     

USER friendly DNA engineering and cloning method by uracil excision

Here we report a PCR-based DNA engineering technique for seamless assembly of recombinant molecules from multiple components. We create cloning vector and target molecules flanked with compatible single-stranded (ss) extensions. The vector contains a cassette with two inversely oriented nicking endonuclease sites separated by restriction endonuclease site(s). The spacer sequences between the nicking and restriction sites are tailored to create ss extensions of custom sequence. The vector is then linearized by digestion with nicking and restriction endonucleases. To generate target molecules, a single deoxyuridine (dU) residue is placed 6–10nt away from the 5′-end of each PCR primer. 5′ of dU the primer sequence is compatible either with an ss extension on the vector or with the ss extension of the next-in-line PCR product. After amplification, the dU is excised from the PCR products with the USER enzyme leaving PCR products flanked by 3′ ss extensions. When mixed together, the linearized vector and PCR products directionally assemble into a recombinant molecule through complementary ss extensions. By varying the design of the PCR primers, the protocol is easily adapted to perform one or more simultaneous DNA manipulations such as directional cloning, site-specific mutagenesis, sequence insertion or deletion and sequence assembly.