Direct DNA sequence determination from total genomic DNA.

It is possible to perform a combined amplification and sequencing reaction ('DEXAS') directly from complex DNA mixtures by using two thermostable DNA polymerases, one that favours the incorporation of deoxynucleotides over dideoxynucleotides, and one which has a decreased ability to discriminate between these two nucleotide forms. During cycles of thermal denaturation, annealing and extension, the former enzyme primarily amplifies the target sequence whereas the latter enzyme primarily performs a sequencing reaction. This method allows the determination of single-copy nuclear DNA sequences from amounts of human genomic DNA comparable to those used to amplify nucleotide sequences by the polymerase chain reaction. Thus, DNA sequences can be easily determined directly from total genomic DNA.     

Sequence specific detection of DNA using nicking endonuclease signal amplification (NESA)

We have developed a new method for identifying specific single- or double-stranded DNA sequences called nicking endonuclease signal amplification (NESA). A probe and target DNA anneal to create a restriction site that is recognized by a strand-specific endonuclease that cleaves the probe into two pieces leaving the target DNA intact. The target DNA can then act as a template for fresh probe and the process of hybridization, cleavage and dissociation repeats. Laser-induced fluorescence coupled with capillary electrophoresis was used to measure the probe cleavage products. The reaction is rapid; full cleavage of probe occurs within one minute under ideal conditions. The reaction is specific since it requires complete complementarity between the oligonucleotide and the template at the restriction site and sufficient complementarity overall to allow hybridization. We show that both Bacillus subtilis and B. anthracis genomic DNA can be detected and specifically differentiated from DNA of other Bacillus species. When combined with multiple displacement amplification, detection of a single copy target from less than 30 cfu is possible. This method should be applicable whenever there is a requirement to detect a specific DNA sequence. Other applications include SNP analysis and genotyping. The reaction is inherently simple to multiplex and is amenable to automation.     

Identification and resolution of artifacts in bisulfite sequencing

Bisulfite sequencing has become the most widely used application to detect 5-methylcytosine (5-MeC) in DNA, and provides a reliable way of detecting any methylated cytosine at single-molecule resolution in any sequence context. The process of bisulfite treatment exploits the different sensitivity of cytosine and 5-MeC to deamination by bisulfite under acidic conditions, in which cytosine undergoes conversion to uracil while 5-MeC remains unreactive. In this article, we address the more commonly encountered experimental artifacts associated with bisulfite sequencing, and provide methods for the detection and elimination of these artifacts. In particular, we focus on conditions that inhibit complete bisulfite-mediated conversion of cytosines in a target sequence, and demonstrate the necessity of complete protein removal from DNA samples prior to bisulfite treatment. We also include a brief summary of the experimental protocol for bisulfite treatment and tips for designing polymerase chain reaction (PCR) primers to amplify from bisulfite-treated DNA.     

High sensitivity mapping of methylated cytosines.

An understanding of DNA methylation and its potential role in gene control during development, aging and cancer has been hampered by a lack of sensitive methods which can resolve exact methylation patterns from only small quantities of DNA. We have now developed a genomic sequencing technique which is capable of detecting every methylated cytosine on both strands of any target sequence, using DNA isolated from fewer than 100 cells. In this method, sodium bisulphite is used to convert cytosine residues to uracil residues in single-stranded DNA, under conditions whereby 5-methylcytosine remains non-reactive. The converted DNA is amplified with specific primers and sequenced. All the cytosine residues remaining in the sequence represent previously methylated cytosines in the genome. The work described has defined procedures that maximise the efficiency of denaturation, bisulphite conversion and amplification, to permit methylation mapping of single genes from small amounts of genomic DNA, readily available from germ cells and early developmental stages.     

An improved method for DNA isolation from polyphenols rich leaf samples of Annona squamosa L.

A reliable and efficient method for isolating Annona squamosa L. genomic DNA, free from polyphenols and polysaccharides has been developed. Different methods involving use of CTAB and SDS with or without modifications were used. A CTAB based extraction method which uses diatomite to remove polyphenols and polysaccharides proved to be the best. This method allowed recovery of good quality DNA in sufficient quantity suitable for complete digestion by restriction endonucleases and amplifiable in polymerase chain reaction as compared to other methods.     

Use of DNA-protein interaction to isolate specific genomic DNA sequences.

We describe a simple and rapid method for the isolation of specific genomic DNA sequences recognized by DNA-binding proteins. This procedure consists of four steps: (1) restriction enzyme digestion and size fractionation of genomic DNA; (2) DNA--protein binding using the gel mobility-shift assay; (3) ligation of isolated DNA fragments followed by transformation of Escherichia coli; and (4) screening of recombinant clones for inserts containing specific DNA--protein binding sequences. We have used this protocol to isolate human DNA sequences, 100-200 bp in size, that are recognized by both partially purified and affinity purified proteins. Unlike other procedures designed to identify genomic target sequences, the method described does not require polymerase chain reaction or successive immunoprecipitations.     

DNA甲基化分析中重亚硫酸盐处理DNA转化效率的评估方法

为建立一种评估重亚硫酸盐处理DNA样本后胞嘧啶转化效率的有效方法,以两组不同的TaqMan qPCR检测梯度稀释的重亚硫酸盐处理和未处理的DNA标准品,建立转化与未转化的DNA Ct值以及对应的DNA拷贝数的标准曲线。使用相同的探针定量检测重亚硫酸盐处理后的DNA样本评估转化效率。结果显示该方法应用两组探针,根据相应的标准曲线,精确评估样本经重亚硫酸盐处理的转化效率。使用已知转化和未转化拷贝数的混合DNA作为模板,证实了该方法的可靠性。同时也对不同重亚硫酸盐试剂盒处理DNA的转化效率进行了评估,结果显示,该方法能够有效地评估DNA样品重亚硫酸盐的转化效率,为DNA甲基化准确分析提供了可靠快捷的方法。     

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.     

Detection and measurement of PCR bias in quantitative methylation analysis of bisulphite-treated DNA.

Methylation analysis of individual cytosines in genomic DNA can be determined quantitatively by bisulphite treatment and PCR amplification of the target DNA sequence, followed by restriction enzyme digestion or sequencing. Methylated and unmethylated molecules, however, have different sequences after bisulphite conversion. For some sequences this can result in bias during the PCR amplification leading to an inaccurate estimate of methylation. PCR bias is sequence dependent and often strand-specific. This study presents a simple method for detection and measurement of PCR bias for any set of primers, and investigates parameters for overcoming PCR bias.     

Quantitative analysis of total mitochondrial DNA: competitive polymerase chain reaction versus real-time polymerase chain reaction

An efficient and effective method for quantification of small amounts of nucleic acids contained within a sample specimen would be an important diagnostic tool for determining the content of mitochondrial DNA (mtDNA) in situations where the depletion thereof may be a contributing factor to the exhibited pathology phenotype. This study compares two quantification assays for calculating the total mtDNA molecule number per nanogram of total genomic DNA isolated from human blood, through the amplification of a 613-bp region on the mtDNA molecule. In one case, the mtDNA copy number was calculated by standard competitive polymerase chain reaction (PCR) technique that involves co-amplification of target DNA with various dilutions of a nonhomologous internal competitor that has the same primer binding sites as the target sequence, and subsequent determination of an equivalence point of target and competitor concentrations. In the second method, the calculation of copy number involved extrapolation from the fluorescence versus copy number standard curve generated by real-time PCR using various dilutions of the target amplicon sequence. While the mtDNA copy number was comparable using the two methods (4.92 +/- 1.01 x 10(4) molecules/ng total genomic DNA using competitive PCR vs 4.90 +/- 0.84 x 10(4) molecules/ng total genomic DNA using real-time PCR), both inter- and intraexperimental variance were significantly lower using the real-time PCR analysis. On the basis of reproducibility, assay complexity, and overall efficiency, including the time requirement and number of PCR reactions necessary for the analysis of a single sample, we recommend the real-time PCR quantification method described here, as its versatility and effectiveness will undoubtedly be of great use in various kinds of research related to mitochondrial DNA damage- and depletion-associated disorders.     

Affordable de novo generation of fish mitogenomes using amplification-free enrichment of mitochondrial DNA and deep sequencing of long fragments

Biomonitoring surveys make use of metabarcoding tools to describe the community composition. These studies match their sequencing results against public genomic databases to identify the species. However, mitochondrial genomic reference data are yet incomplete, only a few genes may be available, or the suitability of existing sequence data is suboptimal for species level resolution. Here, we present a dedicated and cost-effective workflow with no DNA amplification for generating complete fish mitogenomes for the purpose of strengthening fish mitochondrial databases. Two different strategies using long fragment sequencing with Oxford Nanopore technology coupled with mitochondrial DNA enrichment were used. One where the enrichment is achieved by preferential isolation of mitochondria followed by DNA extraction and nuclear DNA depletion (“mitoenrichment”). A second enrichment approach takes advantage of the CRISPR Cas9 targeted scission on previously dephosphorylated DNA (“targeted mitosequencing”). The sequencing results varied between tissue, species, and integrity of the DNA. The mitoenrichment method yielded 0.17%–12.33% of sequences on target and a mean coverage ranging from 74.9 to 805-fold. The targeted mitosequencing experiment from native genomic DNA yielded 1.83%–55% of sequences on target and a 38 to 2123-fold mean coverage. These produced complete mitogenomes of species with homopolymeric regions, tandem repeats, and gene rearrangements. We demonstrate that deep sequencing of long fragments of native fish DNA can be achieved with low computational resources in a cost-effective manner, opening the discovery of mitogenomes of nonmodel or understudied fish taxa to a broad range of laboratories worldwide.     

基于CRISPR编辑系统的DNA片段删除技术

基于CRISPR/Cas9系统的基因组编辑技术已成为基因功能研究和遗传修饰的重要工具。在引导RNA的引导下,Cas9蛋白对基因组靶位点进行精准切割产生DNA双链断裂(DSB),借助细胞内的DSB修复机制,可实现基因组靶位点碱基的缺失、插入或者替换,甚至发生片段删除。该文介绍了基于CRISPR/Cas9基因组编辑系统的D...     

Sequential DEXAS: a method for obtaining DNA sequences from genomic DNA and blood in one reaction

Sequential DEXAS (direct exponential amplification and sequencing), a one step amplification and sequencing procedure that allows accurate, inexpensive and rapid DNA sequence determination directly from genomic DNA, is described. This method relies on the simultaneous use of two DNA polymerases that differ both in their ability to incorporate dideoxynucleotides and in the time at which they are activated during the reaction. One enzyme, which incorporates deoxynucleotides and performs amplification of the target DNA sequence, is supplied in an active state whereas the other enzyme, which incorporates dideoxynucleotides and performs the sequencing reaction, is supplied in an inactive state but becomes activated by a temperature step during the thermocycling. Thus, in the initial stage of the reaction, target amplification occurs, while in the second stage the sequencing reaction takes place. We show that Sequential DEXAS yields high quality sequencing results directly from genomic DNA as well as directly from human blood without any prior isolation or purification of DNA.     

Long-read whole-genome methylation patterning using enzymatic base conversion and nanopore sequencing

Long-read whole-genome sequencing analysis of DNA methylation would provide useful information on the chromosomal context of gene expression regulation. Here we describe the development of a method that improves the read length generated by using the bisulfite-sequencing-based approach. In this method, we combined recently developed enzymatic base conversion, where an unmethylated cytosine (C) should be converted to thymine (T), with nanopore sequencing. After methylation-sensitive base conversion, the sequencing library was constructed using long-range polymerase chain reaction. This type of analysis is possible using a minimum of 1 ng genomic DNA, and an N50 read length of 3.4–7.6 kb is achieved. To analyze the produced data, which contained a substantial number of base mismatches due to sequence conversion and an inaccurate base read of the nanopore sequencing, a new analytical pipeline was constructed. To demonstrate the performance of long-read methylation sequencing, breast cancer cell lines and clinical specimens were subjected to analysis, which revealed the chromosomal methylation context of key cancer-related genes, allele-specific methylated genes, and repetitive or deletion regions. This method should convert the intractable specimens for which the amount of available genomic DNA is limited to the tractable targets.     

Comparison of three methods of parasitoid polydnavirus genomic DNA isolation to facilitate polydnavirus genomic sequencing

A major long-term goal of polydnavirus (PDV) genome research is to identify novel virally encoded molecules that may serve as biopesticides to target insect pests that threaten agriculture and human health. As PDV viral replication in cell culture in vitro has not yet been achieved, several thousands of wasps must be dissected to yield enough viral DNA from the adult ovaries to carry out PDV genomic sequencing. This study compares three methods of PDV genomic DNA isolation for the PDV of Cotesia flavipes, which parasitizes the sugarcane borer, Diatraea saccharalis, preparatory to sequencing the C. flavipes bracovirus genome. Two of these protocols incorporate phenol-chloroform DNA extraction steps in the procedure and the third protocol uses a modified Qiagen DNA kit method to extract viral DNA. The latter method proved significantly less time-consuming and more cost-effective. Efforts are currently underway to bioengineer insect pathogenic viruses with PDV genes, so that their gene products will enhance baculovirus virulence for agricultural insect pests, either via suppression of the immune system of the host or by PDV-mediated induction of its developmental arrest. Sequencing a growing number of complete PDV genomes will enhance those efforts, which will be facilitated by the study reported here.     

BE3型胞嘧啶碱基编辑器在谷氨酸棒杆菌中的开发及应用

碱基编辑技术结合了CRISPR/Cas系统的靶向特异性与碱基脱氨酶的催化活性,因其不产生双链DNA断裂、不需要外源DNA模板、不依赖同源重组修复,自开发以来,便受到研究者的追捧,在哺乳动物细胞、植物、微生物等领域相继得到开发与应用。为了进一步丰富碱基编辑系统在谷氨酸棒杆菌中的应用,将鼠源胞嘧啶脱氨酶(rAPOBEC1)与nCas9蛋白融合,实现了在谷氨酸棒杆菌中C到T的编辑,编辑比例较低(0-20%);在上述融合蛋白C端添加UGI蛋白,构建BE3型胞嘧啶碱基编辑器,抑制体内的DNA碱基切除修复机制,显著的提高了碱基编辑效率,使得C到T的碱基编辑效率高达90%;为了简化操作,将双质粒碱基编辑系统优化为单质粒碱基编辑系统,并显著提高转化效率;最后通过单质粒碱基编辑系统对基因组中其他位点的编辑测试,进一步证明了BE3型碱基编辑器在谷氨酸棒杆菌中的高效性,同时发现该碱基编辑器具有较宽的编辑窗口(PAM上游-11到-19位),有助于覆盖更多的基因组靶标位点,为谷氨酸棒杆菌的基因组改造提供了更多的工具选择。     

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.     

Comparison and critical evaluation of PCR-mediated methods to walk along the sequence of genomic DNA

Although researchers can access information on the entire genomic DNA sequence of typical research organisms, convenient genome walking methods in the laboratory are still needed. For the analysis of microorganisms, these methods are especially useful because the available genetic information is often scarce or limited. Many genomic walking methods are based on the polymerase chain reaction (PCR), and useful methods have been developed. This report reviews the methodologies of PCR-mediated genomic walking methods and evaluates their efficiency and usefulness to help microbiologists to select the appropriate method for each target microorganism. The concept and specific features, such as advantages and disadvantages, of five major PCR-mediated genomic walking methods (random PCR, inverse PCR, panhandle PCR, cassette PCR, and rapid amplification of genomic ends) are briefly described. The improved methods and their characteristics are listed, and a report of experimental comparison of such methods is also introduced briefly. Each of these methods has both advantages and disadvantages, and there is a trade-off between the specificity of target amplification and the ease of the method. The cassette PCR seems to be a standard method, but suitable method should be selected in consideration of the characteristics of the material.