利用动态等位基因特异性杂交技术进行单核苷酸多态高通量分型

动态等位基因特异性杂交(dynamic allele-specific hybridization, DASH)是新发展起来的一种单核苷酸多态(single nucleotide polymorphisms, SNP)等位基因分型技术,具有快速、经济、准确、高通量、重复性好等优点.利用DASH技术,对96份正常人外周血DNA样品成功地进行了两个SNP位点的基因分型,并摸索实验条件,对该技术进行了优化.     

SNPs基因分型技术

介绍了SNP的概念、特点,集中讨论了各种技术的原理及优缺点,并对目前SNP在遗传图的绘制、疾病防治、药物设计及法医学等方面的应用及研究进展进行了综述。     

单核苷酸多态概述

单核苷酸多态ＳＮＰ是遍布于基因组中的一种ＤＮＡ序列变化类型,人类基因组中平均约每一千碱基中有一个。单核苷酸多态是一种双等位型多态,群体中出现的频率大于１％或２％者视为多态,低于１％或２％的则视为突变。由于其具有高信息量、高密度又便于自动化操作的特点,单核苷酸多态在遗传性疾病基因的克隆和药物的设计与开发方面具有广阔的应用前景。本文对单核苷酸的概念、特点、应用前景,及其研究应用的一些问题作一综述。     

高通量SNP基因分型技术研究进展

在后基因组时代,单核苷酸多态性研究已迅速成为了生物医学许多领域的焦点。发展可靠、敏感、经济、稳定、高通量的SNP基因分型技术已迫在眉睫。本文主要着重于高通量SNP基因分型技术的原理、利弊以及这些技术在这个领域过去几年中的进展。     

单核苷酸多态性基因分型技术原理与进展

在基因组规模了解遗传变异与生物功能之间的关系可望为生物学带来全新的深入认识。本从等位基因分型机理、反应形式和检测方法等三个方面讨论SNP分型方法的现状,并简要介绍了目前应用的一些分型方法。     

NGX6基因单核苷酸多态及与鼻咽癌的相关性

NGX6基因是本研究室在鼻咽癌 9p最小共同缺失区内新克隆的鼻咽癌候选抑瘤基因。通过采用病例 对照研究方法 ,利用动态等位基因杂交 (DASH)技术对 10 5例鼻咽癌患者和 183例正常人NGX6基因的 2个单核苷酸多态 (SNP)进行了分型 ,经相关分析发现 ,位于NGX6基因上游调控区的SNPrs8792 84与鼻咽癌发病存在显著相关性 ,基因型CT和TT的相对危险度分别为 3.93和 2 .2 7。实验结果进一步支持了NGX6基因与鼻咽癌的发生发展可能存在密切关系 ,SNPrs8792 84由于处在NGX6基因上游调控区域 ,其多态类型可能在某种程度上影响NGX6基因的表达调控 ,从而与鼻咽癌发病相关     

海洋生物单核苷酸多态性基因分型技术的研究进展

单核苷酸多态性(single nucleotide polymorphism,SNP)是一类广泛分布于基因组中由单个碱基差异引起的DNA序列变异,SNP标记是第三代分子标记的代表。随着大规模测序技术的快速发展,大量的候选SNP位点被发现,候选SNP位点的发掘需要合适的分型技术。从等位基因分型机制、反应方式和检测等位基因方法等方面介绍当前海洋生物SNP分型技术的研究进展,以期为不同试验目的的研究选择合适的SNP分型技术提供参考。     

梅花鹿生长激素基因单核苷酸多态与产茸量性状的相关性

以梅花鹿的生长激素基因(GH)作为候选基因, 分析该基因对梅花鹿产茸量性状的影响。以吉林农业大学鹿场提供的梅花鹿为实验群体, 采用单链构象多态性(PCR-SSCP)和DNA测序的方法检测了GH基因单核苷酸多态性(SNPs), 针对该群体的特点建立合适的统计分析模型, 并进行了GH基因多态性与产茸量的相关分析。结果表明, GH基因对梅花鹿的产茸量有一定影响。G→A突变产生的3种基因型间的第五锯产茸量存在一定的差异(P<0.2), BB基因型个体在第五锯的产茸量与AA基因型个体之间有一定的差异(P<0.2)。     

泛肽相关蛋白基因UBAP1单核苷酸多态及与鼻咽癌的相关研究

UBAP1基因是在鼻咽癌9p最小共同缺失区内新克隆的鼻咽癌候选抑瘤基因,通过采用病例-对照研究方法,对105例鼻咽癌患者和183例正常人UBAP1基因的5个单核苷酸多态(SNPs)用测序法进行了分型,在实验过程中,偶然发现了一个新的SNP位点,并已登录至dbSNP（登录号：rs3135929）.经相关分析发现,位于UBAP1基因第6外显子中的SNP rs1049557与鼻咽癌发病存在显著相关性,基因型GG和GC的相对危险度分别为1.64和1.31.实验结果进一步支持了UBAP1基因与鼻咽癌的发生发展可能存在密切关系,SNP rs1049557由于处在UBAP1基因下游3′非翻译区,其多态类型可能在某种程度上影响UBAP1基因的表达调控,从而与鼻咽癌发病相关.     

一个新硝基还原酶基因NOR1编码区单核苷酸多态及与鼻咽癌的关联分析

NOR1基因是中南大学湘雅医学院肿瘤研究所克隆的一个鼻咽癌表达下调新基因,生物信息学预测NOR1基因含有硝基还原酶结构域,该基因可能参与亚硝胺类化学致癌物在体内的代谢过程,从而与鼻咽癌的发生密切相关.通过采用病例-对照的研究方法,利用测序技术对144名鼻咽癌患者和匹配的144名正常人NOR1基因编码区单核苷酸多态(coding region single nucleotide polymorphisms, cSNPs)进行基因分型,关联分析结果显示所检测到的两个cSNPs之间存在连锁不平衡,且均与鼻咽癌发病相关,两个cSNPs及它们所组成的单倍型相对危险度分别为1.36、1.64和1.37.两个cSNPs的多态性改变均使NOR1基因编码蛋白一级结构发生了变化,这种改变可能影响NOR1基因编码蛋白的结构和功能.研究进一步支持了NOR1基因与鼻咽癌的发生发展可能存在密切的关系.     

高通量飞行时间质谱基因分型方法的研究

为了考察飞行时间质谱基因分型方法 (MALDI-TOF) 的位点分型成功率和分型结果质量的关系,分析了 96 个 SNPs 位点的近 10 000 个基因分型数据 (用 MALDI-TOF “4 重”实验方法检测 ). 结果显示,位点分型成功率和分型结果的质量显著正相关 . 分型成功率低于 82% 的 SNP 位点,其高质量结果占的比例开始逐渐降低 . 提示 82% 的分型成功率可以作为衡量分型结果质量的数据点 . 为了进一步提高通量并降低成本,在 MALDI-TOF “ 4 重”实验方法的基础上,发展了两种“准 8 重”实验方法 . 用新的实验方法检测了 95 个样本的 32 个 SNPs 位点 . 结果显示“混合准 8 重”实验方法与“ 4 重”实验方法相比无显著差异,而“复点准 8 重”的结果差于“ 4 重”分型方法 .     

水稻单核苷酸多态性及其应用现状

单核苷酸多态性（single nucleotide polymorphisms, SNPs）在水稻中数量多,分布密度高,遗传稳定性高。水稻SNPs的发现方法主要有对样本DNA的PCR产物直接测序、从SSR区段检测SNPs和从基因组序列直接搜索等。目前已有多种基因分型技术运用到了水稻SNPs检测,SNPs检测的高度自动化使水稻SNPs基因分型非常方便。单核苷酸多态性在水稻遗传图谱的构建、基因克隆和功能基因组学研究、标记辅助选择育种、遗传资源分类及物种进化等方面的应用具有巨大潜力。     

High throughput SNP genotyping with two mini-sequencing assays

Single nucleotide polymorphisms (SNPs) are veryimportant markers that can be used in many areas such asevolutionary genetics [1], disease-susceptibility genes[2,3], personalized medicine and forensics. Only about20% of human polymorphisms are length polymorphisms,whereas about 80% of human polymorphisms areSNPs. Kruglyak et al. [4] reported that there were about11,000,000 SNPs in the world population. There are many kinds of SNP genotyping technology[5,6]: some are only suitable to low …     

单核苷酸多态性检测方法的研究进展

单核苷酸多态性（single nucleotide polymorphism, SNP）的研究已成为人类后基因组时代的主要内容之一。因此建立高度自动化和高通量的SNP检测分析技术十分重要。文章系统地介绍了最新发展的几种SNP检测技术的原理和检测平台,详细阐述了等位基因特异性杂交、内切酶酶切技术、引物延伸法、寡核苷酸连接反应等SNP检测原理,以及平板读数仪、基因芯片、微球阵列技术和质谱仪等检测平台,并对SNP高通量检测技术的发展进行了展望。     

Multiplex single nucleotide polymorphism (SNP)-based genotyping in allohexaploid wheat using padlock probes

Single nucleotide polymorphisms are the most common polymorphism in plant and animal genomes and, as such, are the logical choice for marker-assisted selection. However, many plants are also polyploid, and marker-assisted selection can be complicated by the presence of highly similar, but non-allelic, homoeologous sequences. Despite this, there is practical and academic demand for high-throughput genotyping in several polyploid crop species, such as allohexaploid wheat. In this paper, we present such a system, which utilizes public single nucleotide polymorphisms previously identified in both agronomically important genes and in randomly selected, mapped, expressed sequence tags developed by the wheat community. To achieve relatively high levels of multiplexing, we used non-amplified genomic DNA and padlock probe pairs, together with high annealing temperatures, to differentiate between similar sequences in the wheat genome. Our results suggest that padlock probes are capable of discriminating between homoeologous sequences and hence can be used to efficiently genotype wheat varieties.     

Characterization of a Wheat Breeders’ Array suitable for high‐throughput SNP genotyping of global accessions of hexaploid bread wheat (Triticum aestivum)

Targeted selection and inbreeding have resulted in a lack of genetic diversity in elite hexaploid bread wheat accessions. Reduced diversity can be a limiting factor in the breeding of high yielding varieties and crucially can mean reduced resilience in the face of changing climate and resource pressures. Recent technological advances have enabled the development of molecular markers for use in the assessment and utilization of genetic diversity in hexaploid wheat. Starting with a large collection of 819 571 previously characterized wheat markers, here we describe the identification of 35 143 single nucleotide polymorphism‐based markers, which are highly suited to the genotyping of elite hexaploid wheat accessions. To assess their suitability, the markers have been validated using a commercial high‐density Affymetrix Axiom^® genotyping array (the Wheat Breeders’ Array), in a high‐throughput 384 microplate configuration, to characterize a diverse global collection of wheat accessions including landraces and elite lines derived from commercial breeding communities. We demonstrate that the Wheat Breeders’ Array is also suitable for generating high‐density genetic maps of previously uncharacterized populations and for characterizing novel genetic diversity produced by mutagenesis. To facilitate the use of the array by the wheat community, the markers, the associated sequence and the genotype information have been made available through the interactive web site ‘CerealsDB’.     

High throughput genotyping technologies.

A comprehensive genetic map containing several hundred microsatellite markers resulted from a large microsatellite mapping project. This was the first real study that introduced high throughput methods to the genetic community. This map and the concurrent technological advances, which will briefly be reviewed, led to further numerous mapping investigations of simple and complex diseases. The annotated draft sequence of approximately three billion base pairs (bp) of the human genome has been completed much sooner than many imagined, due to considerable technological advancements and the international enterprise that resulted. This was a major development for the genetics community, but is only the precursor to the next phase of studying and understanding the variation within the human genome. The awareness of the differences may help us understand the effects on the genetics of the variation between individuals and disease. It is these variations at the nucleotide level that determine the physiological differences, or phenotypes of each individual, including all biological functions at the cellular and body level. Single nucleotide polymorphisms (SNPs) will provide the next high density map, and be the genetic tool to study these genetic variations. There are many sources of SNPs and exhaustive numbers of methods of SNP detection to be considered. The focus in this paper will be on the merits of selected, varied SNP typing methodologies that are emerging to genotype many individuals with the required huge number of SNPs to make the study of complex diseases and pharmacogenomics a practical and economically viable option.     

四引物PCR扩增反应的单管SNP快速测定法

建立一种在单管中进行单核苷酸多型性 (SNP)快速测定的高效廉价方法 .以人ABCA1基因中的I82 3M为研究对象 ,设计 4种引物进行PCR扩增 ,其中两种引物用于扩增一段含有SNP位点的DNA片段 ,另两种引物为SNP位点特异性引物 ,4种引物在单管中同时进行PCR扩增反应 ,根据延伸产物的长度确定SNP的类型 .为提高SNP测定的特异性 ,在特异性引物的 3′端倒数第 3个碱基引入了一个人为错配碱基 ,使引物的错误延伸率显著降低 ,大大提高了SNP分析的准确性 .实验结果表明 ,所建立的方法简单 ,操作简便 ,可在单管中完成SNP的测定反应 .