Application of the Duplex-Specific Nuclease Preference Method to the Analysis of Single Nucleotide Polymorphisms in Human Genes

A new modification of the single nucleotide polymorphism (SNP) analysis (DSNP, duplex-specific nuclease preference) method using the duplex-specific nuclease from the king crab was proposed. The method was used to study SNPs in the following human genes: kRAS, nRAS, hRAS, and p53, the genes of blood coagulation factor V, methyltetrahydrofolate reductase, prothrombin, and apolipoprotein E and a deletion in the BRCA1 gene. DSNP was shown to be useful for the estimation of the mutant allele content in DNA samples. A system for the simultaneous identification of several adjacent single-nucleotide polymorphisms in the kRAS gene was proposed. The approaches could be used to develop test systems for the detection of SNPs in human genes.     

A method for the preparation of normalized cDNA libraries enriched with full-length sequences

We developed a new method for the preparation of normalized cDNA libraries enriched with full-length sequences. It is based on the properties of the recently characterized duplex-specific nuclease from the hepatopancreas of the Kamchatka crab. The duplex-specific nuclease is thermostable, it effectively cleaves double-stranded DNA and is inactive toward single-stranded DNA (Shagin et al., Genome Res., 2002, vol. 12, pp. 1935-1942). Our method enables the normalization of cDNA samples enriched with full-length sequences without use of laborious and ineffective stages of physical separation. The efficiency of the method was demonstrated in model experiments using cDNA samples from several human tissues.     

Thermolabile duplex-specific nuclease

Using random mutagenesis of the gene encoding duplex-specific nuclease from the king crab we found a new mutant that retained all properties of the wild-type protein, but exhibited a much lower thermal stability. This enzyme, denoted thermolabile duplex-specific nuclease (DSN-TL), exhibits high processivity and selective cleavage of dsDNA. The inactivation temperature for DSN-TL is 15–20°C lower than that of the widely used DNase I and shrimp nuclease, and its catalytic activity is more than 10 times higher. Moreover, DSN-TL is resistant to proteinase K treatment. These properties make DSN-TL very useful for removing genomic DNA from RNA samples intended for quantitative RT-PCR.     

A method for the preparation of normalized cDNA libraries enriched with full-length sequences

We developed a new method for the preparation of normalized cDNA libraries enriched with full-length sequences. It is based on the properties of the recently characterized duplex-specific nuclease from the hepatopancreas of the Kamchatka crab. The duplex-specific nuclease is thermostable, effectively cleaves double-stranded DNA, and is inactive toward single-stranded DNA (Shagin et al., Genome Res., 2002, vol. 12, pp. 1935–1942). Our method enables the normalization of cDNA samples enriched with full-length sequences without use of laborious and ineffective stages of physical separation. The efficiency of the method was demonstrated in model experiments using cDNA samples from several human tissues.__________Translated from Bioorganicheskaya Khimiya, Vol. 31, No. 2, 2005, pp. 186–194.Original Russian Text Copyright © 2005 by Zhulidov, Bogdanova, Shcheglov, Shagina, Wagner, Khazpekov, Kozhemyako, Lukyanov, Shagin.     

DSN Depletion is a Simple Method to Remove Selected Transcripts from cDNA Populations

A novel DSN-depletion method allows elimination of selected sequences from full-length-enriched cDNA libraries. Depleted cDNA can be applied for subsequent EST sequencing, expression cloning, and functional screening approaches. The method employs specific features of the kamchatka crab duplex-specific nuclease (DSN). This thermostable enzyme is specific for double-stranded (ds) DNA, and is thus used for selective degradation of ds DNA in complex nucleic acids. DSN depletion is performed prior to library cloning, and includes the following steps: target cDNA is mixed with excess driver DNA (representing fragments of the genes to be eliminated), denatured, and allowed to hybridize. During hybridization, driver molecules form hybrids with the target sequences, leading to their removal from the ss DNA fraction. Next, the ds DNA fraction is hydrolyzed by DSN, and the ss fraction is amplified using long-distance PCR. DSN depletion has been tested in model experiments. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

SNPs detection by a single-strand specific nuclease on a PNA zip-code microarray

In this report, a reliable peptide nucleic acid (PNA) microarray-based method for accurately detecting single nucleotide polymorphism (SNP) in human genes is described. The technique relies on the mismatched cleavage activity of a single-strand specific (SSS) nuclease. PCR amplification was performed to prepare gene fragments containing the mutation sites. The amplified fragments were then employed as templates for the SSS nuclease reaction using chimeric probes, modified with biotin at the 5' end and extended with a unique anchoring zip-code complement sequence at the 3' end. The SSS nuclease promotes cleavage of heteroduplex DNAs at base mismatched positions to produce crumbled chimeric probes in the presence of imperfectly matching template strands. In contrast, the probes remain intact when they interact with perfectly matched template strands. Only the non-fragmented probes generate fluorescence signals after treatment with streptavidin-Cy3 on the PNA zip-code array. This methodology was used to successfully genotype selected Korean-specific BRCA mutation sites with wild type and mutant samples. The investigation has led to the development of a reliable SSS nuclease-based system for the diagnosis of human genetic mutations or SNPs.     

Allelic variation in gene expression identified through computational analysis of the dbEST database

Differential expression between the two alleles of an individual and between people with different genotypes has been commonly observed. Quantitative differences in gene expression between people may provide the genetic basis for the phenotypic difference between individuals and may be the primary cause of complex diseases. In this paper, we developed a computational method to identify genes that displayed allelic variation in gene expression in human EST libraries. To model allele-specific gene expression, we first identified EST libraries in which both A and B alleles were expressed and then identified allelic variation in gene expression based on the EST counts for each allele using a binomial test. Among 1107 SNPs that had a sufficient number of ESTs for the analysis, 524 (47%) displayed allelic variation in at least one cDNA library. We verified experimentally the allelic variation in gene expression for 6 of these SNPs. The frequency of allelic variation observed in EST libraries was similar to the previous studies using the SNP chip and primer extension method. We found that genes that displayed allelic variation were distributed throughout the human genome and were enriched in certain chromosome regions. The SNPs and genes identified in this study will provide a rich source for evaluating the effects of those SNPs and associated haplotypes in human health and diseases.     

SNPs associated with body weight and backfat thickness in two pig breeds identified by a genome-wide association study

Growth and fat deposition are important economic traits due to the influence on production in pigs. In this study, a dataset of 1200 pigs with 345,570 SNPs genotyped by sequencing (GBS) was used to conduct a GWAS with single-marker regression method to identify SNPs associated with body weight and backfat thickness (BFT) and to search for candidate genes in Landrace and Yorkshire pigs. A total of 27 and 13 significant SNPs were associated with body weight and BFT, respectively. In the region of 149.85–149.89 Mb on SSC6, the SNP (SSC6: 149876737) for body weight and the SNP (SSC6: 149876507) for BFT were in the same locus region (a gap of 230 bp). Two SNPs were located in the DOCK7 gene, which is a protein-coding gene that plays an important role in pigmentation. Two SNPs located on SSC8: 54567459 and SSC11: 33043081 were found to overlap weight and BFT; however, no candidate gene was found in these regions. In addition, based on other significant SNPs, two positional candidate genes, NSRP1 and CADPS, were proposed to influence weight. In conclusion, this is the first study report using GBS data to identify the significant SNPs for weight and BFT. A total of four particularly interesting SNPs and one potential candidate genes (DOCK7) were found for these traits in domestic pigs. This study improves our knowledge to better understand the complex genetic architecture of weight and BFT, but further validation studies of these candidate loci and genes are recommended in pigs     

Application of the duplex-specific nuclease for fast analysis of single nucleotide polymorphisms and detection of target DNA in complex PCR products

We have developed a simple method for fast analysis of single nucleotide polymorphisms and identification of target clones from cloned complex PCR products. The method utilizes Kamchatka crab duplex-specific nuclease and universal fluorescent probe and is alternative to laborious screening procedures using radioactive probes, restriction analysis followed by gel electrophoresis or expensive sequencing. The method efficacy was demonstrated in several model experiments.     

The use of duplex-specific crab nuclease for rapid analysis of single-nucleotide polymorphisms and the detection of DNA targets in complex PCR products

A rapid method for single-nucleotide polymorphism analysis and the detection of target clones after cloning of complex PCR products based on the use of duplex-specific crab nuclease and a universal fluorescent probe has been developed. The method is an alternative to the labor-intensive procedures of clone screening employing radioactively labeled probes, gel-based restriction analysis, and costly sequencing. The efficiency of the novel method has been demonstrated in a range of model systems.     

香菇三个功能基因部分序列的单核苷酸多态性分析

以15个香菇栽培品种为材料,对尿嘧啶核苷酸-胞嘧啶核苷酸激酶基因(UMP-CMP kinase gene,uck1)、分裂原活化蛋白激酶基因(mitogen-activated protein kinase gene,mapk)和外切β-1,3葡聚糖酶基因(exo-β-1,3-glucanase-encoding gene,exg1)进行了部分序列的单核苷酸多态性(single nucleotide polymorphism,SNP)分析。结果表明,测序中出现的双峰,是菌丝双核体细胞中两细胞核之间的差异造成的。在采用uck1、mapk和exg1的3,126bp中,共发现48处多态性位点,发生频率为1/65bp,其中36个属于转换、12个为颠换。从群体发生频率上,38个属于超过10%的常见SNP,10个属于罕见SNP。不同基因的SNP发生频率不同,uck1、mapk和exg1的SNP发生频率分别为1.40%、0.82%和2.41%。外显子区SNP数量高于内含子,3个基因在外显子区域分布28个,内含子分布20个。外显子的28个SNP位点中,11个为错义突变,17个为同义突变。错义突变引起了编码氨基酸的改变。对SNP位点的聚类分析表明,15个栽培品种间存在的多态性位点在1–36之间,15个品种的SNP类型不同。uck1,mapk,exg1的SNP可用于香菇栽培品种的鉴别。     

PRPS2基因启动子区的单核苷酸多态性(英文)

人类基因组变异主要以单核苷酸多态性 (SNPs)为主 .采用多荧光标记的PCR单链构象多态性分析法 (MF PCR SSCP)对磷酰核糖焦磷酸合成酶亚基Ⅱ (PRPS2 )基因启动子区的序列进行了SNP的筛选 ,对筛选到的阳性片段进行序列分析以确定SNP的类型及位置 .在 1 5kb的启动子区发现了 2个SNP (- 10 79t c ,- 1110a g) .研究结果为PRPS2基因SNPs的数据库提供了新的信息 .     

Mining functional gene modules linked with rheumatoid arthritis using a SNP-SNP network

The identification of functional gene modules that are derived from integration of information from different types of networks is a powerful strategy for interpreting the etiology of complex diseases such as rheumatoid arthritis (RA). Genetic variants are known to increase the risk of developing RA. Here, a novel method, the construction of a genetic network, was used to mine functional gene modules linked with RA. A polymorphism interaction analy-sis (PIA) algorithm was used to obtain cooperating single nucleotide polymorphisms (SNPs) that contribute to RA disease. The acquired SNP pairs were used to construct a SNP-SNP network. Sub-networks defined by hub SNPs were then extracted and turned into gene modules by mapping SNPs to genes using dbSNP database. We per-formed Gene Ontology (GO) analysis on each gene module, and some GO terms enriched in the gene modules can be used to investigate clustered gene function for better understanding RA pathogenesis. This method was applied to the Genetic Analysis Workshop 15 (GAW 15) RA dataset. The results show that genes involved in func-tional gene modules, such as CD160 (rs744877) and RUNX1 (rs2051179), are especially relevant to RA, which is supported by previous reports. Furthermore, the 43 SNPs involved in the identified gene modules were found to be the best classifiers when used as variables for sample classification.     

Nonsynonymous single-nucleotide polymorphisms of the human apoptosis-related endonuclease--DNA fragmentation factor beta polypeptide, endonuclease G, and Flap endonuclease-1--genes show a low degree of genetic heterogeneity

DNA fragmentation factor beta (DFFB) polypeptide, endonuclease G (EndoG), and Flap endonuclease-1 (FEN-1) are responsible for DNA fragmentation, a hallmark of apoptosis. Although the human homologs of these genes show three, four, and six nonsynonymous single-nucleotide polymorphisms (SNPs), respectively, data on their genotype distributions in populations worldwide are limited. In this context, the objectives of this study were to elucidate the genetic heterogeneity of all these SNPs in wide-ranging populations, and thereby to clarify the genetic background of these apoptosis-related endonucleases in human populations. We investigated the genotype distribution of their SNPs in 13 different populations of healthy Asians, Africans, and Caucasians using novel genotyping methods. Among the 13 SNPs in the 3 genes, only 3 were found to be polymorphic: R196K and K277R in the DFFB gene, and S12L in the EndoG gene. All 6 SNPs in the FEN-1 gene were entirely monoallelic. Although it remains unclear whether each SNP would exert any effect on endonuclease functions, these genes appear to exhibit low degree of genetic heterogeneity with regard to nonsynonymous SNPs. These findings allow us to conclude that human apoptosis-related endonucleases, similarly to other human DNase genes, revealed previously, are well conserved at the protein level during the course of human evolution.     

Cloning of polymorphisms (COP): enrichment of polymorphic sequences from complex genomes

Here we describe a new procedure (cloning of polymorphisms, COP) for enrichment of single nucleotide polymorphisms (SNPs) that represent restriction fragment length polymorphisms (RFLPs). COP would be applicable to the isolation of SNPs from particular regions of the genome, e.g. CpG islands, chromosomal bands, YACs or PAC contigs. A combination of digestion with restriction enzymes, treatment with uracil-DNA glycosylase and mung bean nuclease, PCR amplification and purification with streptavidin magnetic beads was used to isolate polymorphic sequences from the genomes of two human samples. After only two cycles of enrichment, 80% of the isolated clones were found to contain RFLPs. A simple method for the PCR detection of these polymorphisms was also developed.