全基因组扩增技术原理及研究进展

DNA芯片及下一代测序等高通量技术的发展极大促进了分子生物学技术在各领域的广泛应用,但此时样品数量与质量往往是制约研究进行的重要因素,全基因组扩增技术(Whole genome amplification,WGA)则可有效解决这一问题,其可使极微量目标基因组DNA同时得到扩增从而提供满足高通量分析研究所需的起始材料。高效可靠的全基因组扩增技术使基于单细胞水平的大规模全基因组分析成为现实,且随着研究的不断深入,对全基因组扩增技术提出了更高的要求。对过去常用的以及近期发展的全基因组扩增技术进行了概述,阐明了各种方法的原理,并对各种方法的特点从原理上进行了分析总结,以期为全基因组扩增技术的应用提供一定的参考。     

法医遗传学研究和鉴定中的伦理问题

法医遗传学主要以人体生物检材为对象,通过检测遗传信息解决与法律相关的生物检材鉴识问题,为侦查提供线索,为审判提供证据,往往涉及到众多伦理问题。本文提出伦理学在法医遗传学研究和鉴定中的应用基本原则,并对检材/样本收集、法医DNA表型分析、法医遗传系谱学分析、法医DNA数据库建设和应用、亲子鉴定和亲缘鉴定、法医遗传学科研数据交流和共享等方面涉及的伦理问题进行了分析,提示法医遗传学从业人员在研究和鉴定中要充分考虑伦理问题,建议有关部门制定法医遗传学具体的伦理要求,建立伦理审查制度,加强从业人员伦理学培训。     

基于PLP-LDR-HRCA策略进行微量DNA分析——rs17750303位点分型

增强PCR和全基因组扩增是当前微量DNA分析的主要策略,但是,由于DNA模板量过少,受随机效应影响显著,往往不能得到可靠的DNA分型结果.本文提出一种新的检验策略:PLP-LDR-HRCA,尝试微量DNA检材的SNPs分型研究.选择rs17750303位点,并设计等位基因特异性锁式探针,采用连接酶检测反应来识别等位基因,而后采用超分支滚环扩增反应来放大检测信号.结果表明,PLP-LDR-HRCA反应特异性好,灵敏度高,能够直接鉴别微量基因组DNA模板中待测SNP位点,rs17750303纯合型样品(AA型或CC型)和杂合型样品(AC型)准确分型所需最少模板量分别为20pg和30pg.对于增强PCR和全基因组扩增技术不能有效检验的微量检材,PLP-LDR-PCR策略独具优势,可能具有较大的开发价值.     

不同单细胞全基因组扩增方法的比较及MALBAC在辅助生殖中的应用

单细胞全基因组扩增(whole genome amplification, WGA)是指在单细胞水平对全基因组进行扩增的新技术,其原理是将分离的单个细胞的微量全基因组DNA进行扩增,获得高覆盖率的完整的基因组后进行高通量测序,用于揭示细胞异质性。目前,WGA方法主要包括引物延伸预扩增(primer extension preamplification PCR, PEP-PCR)、简并寡核苷酸引物PCR (degenerate oligonucleotide primed PCR, DOP-PCR)、多重置换扩增(multiple displacement amplification, MDA)、多次退火环状循环扩增(multiple annealing and looping-based amplification cycles, MALBAC)等。本文对不同的单细胞WGA方法的原理及应用情况分别进行了阐述,并对其扩增效率进行评价和比较,包括基因组覆盖度、均一性、重现性、SNV (single-nucleotide variants)和CNV (copy number variants)检测力等。综合对比不同单细胞WGA方法后发现,MALBAC的扩增均一性最高、等位基因脱扣率最低、重现性最好,且对于CNV和SNV的检测效果最好。本文还阐述了MALBAC技术在人类单精子减数重组、非整倍体分析以及人类卵细胞基因组研究中的应用。     

血清中提取DNA进行个人身份识别鉴定

在法医物证学实际案例中,最常见的生物检材是全血、人体组织、毛发、口腔脱落上皮细胞(口腔拭子)等,传统认为血清中没有DNA存在,不能作为法医生物检材应用于法医学实践。本文应用微量的人体血清进行了成功的DNA分型检测,有效的进行了个人身份的识别。现报道如下:     

用聚合酶链反应-指纹图法分析HLA-DRB基因型

将不同个体的DNA经聚合酶链反应(PCR)扩增其HLA-DRB基因的高度多态区域,扩增产物经12％的聚丙烯酰胺凝胶电泳,照像后分析不同个体的指纹图型。PCR-指纹图法(PCR-Fingerprinting)为一种简便,快速的基因分析方法,可加速无关骨髓供者的筛选,它在器官移植及法医的个体识别中有一定实用价值。     

温室白粉虱SCAR分子鉴定技术的建立及应用

温室白粉虱Trialeurodes vaporariorum是为害我国蔬菜作物的重大害虫之一。本研究采用随机扩增多态性DNA(Random Amplified Polymorphic DNA,RAPD)技术对温室白粉虱进行研究,筛选出一条620bp的特异性片段(GenBank登录号为JQ690764),据此片段的测序结果设计一对特异性的序列特异性扩增区(Sequence characterized Amplified Region,SCAR)标记(Tv-F和Tv-R),可成功从室内饲养的和从不同地区田间采集的温室白粉虱的基因组DNA中扩增出一条412bp的特异性条带,而不能从供试的其他粉虱类害虫中扩增出该相应条带。单头温室白粉虱成虫的基因组DNA稀释1000倍时,该SCAR标记仍可成功扩增出预期条带,显示出极高的灵敏度。该SCAR标记对温室白粉虱的基因组DNA扩增重复性和稳定性好,且操作简便,灵敏度高,可用于样品的大规模检测,为田间温室白粉虱的快速识别鉴定及其有效防治提供了技术基础。     

SNP与基因检测及表达中的RCA技术

滚环扩增(rollingcircleamplification,RCA)技术是一种新的分子生物学检测方法。该方法不仅可以在体外等温条件下对核酸进行高度特异性的检测,而且还可通过线性或指数扩增来进行信号级联放大,其灵敏度能达到1个拷贝的核酸分子,因此,可用于痕量分子的检测。目前,滚环扩增技术广泛应用于全基因组DNA检测、核酸测序、单核苷酸多态性、DNA芯片及蛋白质芯片分析等领域。     

成功检出22年前精斑DNA一例

在各类现场检材中,由于所处环境的温度、湿度、光、化学及生物等因素的作用,DNA会发生降解,对于降解比较严重检材的检验是目前法医DNA检验的难点。本文通过对检材的观察及案情的分析,弃用常规检验精斑的两步法,选取恰当的方法提取精斑类检材,采用多种试剂盒对降解较严重的检材进行提纯、检验,从而取得完整分型。     

用于分析土壤微生物结构变化规律的变性梯度凝胶电泳条件研究

研究确定土壤微生物基因组DNA提取方法、PCR扩增条件、DGGE电泳条件,为进一步研究分析土壤中微生物结构变化规律提供理论依据。土壤微生物基因组DNA提取采用直接法和间接法进行比较; PCR扩增条件调整扩增体系、DGGE电泳条件调整变性剂范围,并对其结果进行比较分析。通过对DGGE电泳相关条件的研究,结果显示,土壤中粗基因组DNA采用直接法提取,然后进行纯化; PCR扩增体系中加入BSA,DGGE电泳系统组成中变性剂浓度范围为35%～55%。确定了土壤微生物基因组DNA提取方法、PCR扩增条件、DGGE电泳条件,为后续的相关研究提供理论依据。     

人头发DNA的提取及其基因扩增

头发是犯罪现场最容易得到的材料之一。本文报道从人的头发中提取DNA的方法以及利用PCR(聚合酶链反应)技术,从少量人发DNA扩增大量拷贝数的基因片段。对基因扩增得到的大量基因片段进行进一步的基因分析,将为法医物证学提供客观证据,具有重要价值。     

Genotyping DNA isolated from UV irradiated human bloodstains using whole genome amplification

Molecular Biology Reports - Analysis of DNA polymorphisms are the primary technique used for personal identification in forensic cases. However, DNA samples collected as evidence from crime scenes...     

High fidelity of whole-genome amplified DNA on high-density single nucleotide polymorphism arrays

Current microarray technology allows researchers to genotype a large number of SNPs with relatively small amounts of DNA. Nevertheless, researchers and clinicians still frequently face the problem of acquiring enough high-quality DNA for analysis. Whole-genome amplification (WGA) methods offer a solution for this problem, and earlier studies have shown that WGA samples perform reasonably well in small-scale genetic analyses (e.g. Affymetrix 10K array). To determine the performance of WGA products on a large-scale genotyping array, we compared the Affymetrix 250K array genotyping results of genomic DNA and their WGA products from four individuals. Our results indicate that WGA product performs well on the 250K array compared to genomic DNA, especially when using the BRLMM calling algorithm. WGA samples have high call rates (97.5% on average, compared to 99.4% for genomic DNA) and excellent concordance rates with their corresponding genomic DNA samples (98.7% on average). In addition, no apparent systematic genomic amplification bias can be detected. This study demonstrates that, although there is a slight decrease in the total call rates, WGA methods provide a reliable approach for increasing the amount of DNA samples for use with a common SNP genotyping array.     

Forensic DNA and bioinformatics

The field of forensic science is increasingly based on biomolecular data and many European countries are establishing forensic databases to store DNA profiles of crime scenes of known offenders and apply DNA testing. The field is boosted by statistical and technological advances such as DNA microarray sequencing, TFT biosensors, machine learning algorithms, in particular Bayesian networks, which provide an effective way of evidence organization and inference. The aim of this article is to discuss the state of art potentialities of bioinformatics in forensic DNA science. We also discuss how bioinformatics will address issues related to privacy rights such as those raised from large scale integration of crime, public health and population genetic susceptibility-to-diseases databases.     

Monodisperse Picoliter Droplets for Low-Bias and Contamination-Free Reactions in Single-Cell Whole Genome Amplification

Whole genome amplification (WGA) is essential for obtaining genome sequences from single bacterial cells because the quantity of template DNA contained in a single cell is very low. Multiple displacement amplification (MDA), using Phi29 DNA polymerase and random primers, is the most widely used method for single-cell WGA. However, single-cell MDA usually results in uneven genome coverage because of amplification bias, background amplification of contaminating DNA, and formation of chimeras by linking of non-contiguous chromosomal regions. Here, we present a novel MDA method, termed droplet MDA, that minimizes amplification bias and amplification of contaminants by using picoliter-sized droplets for compartmentalized WGA reactions. Extracted DNA fragments from a lysed cell in MDA mixture are divided into 10⁵ droplets (67 pL) within minutes via flow through simple microfluidic channels. Compartmentalized genome fragments can be individually amplified in these droplets without the risk of encounter with reagent-borne or environmental contaminants. Following quality assessment of WGA products from single Escherichia coli cells, we showed that droplet MDA minimized unexpected amplification and improved the percentage of genome recovery from 59% to 89%. Our results demonstrate that microfluidic-generated droplets show potential as an efficient tool for effective amplification of low-input DNA for single-cell genomics and greatly reduce the cost and labor investment required for determination of nearly complete genome sequences of uncultured bacteria from environmental samples.     

Whole genome amplification of Chelex-extracted DNA from a single mite: a method for studying genetics of the predatory mite Phytoseiulus persimilis

We developed and optimized a method using Chelex DNA extraction followed by whole genome amplification (WGA) to overcome problems conducting molecular genetic studies due to the limited amount of DNA obtainable from individual small organisms such as predatory mites. The DNA from a single mite, Phytoseiulus persimilis Athias-Henrot (Acari: Phytoseiidae), isolated in Chelex suspension was subjected to WGA. More than 1000-fold amplification of the DNA was achieved using as little as 0.03 ng genomic DNA template. The DNA obtained by the WGA was used for polymerase chain reaction followed by direct sequencing. From WGA DNA, nuclear DNA intergenic spacers ITS1 and ITS2 and a mitochondrial DNA 12S marker were tested in three different geographical populations of the predatory mite: California, the Netherlands, and Sicily. We found a total of four different alleles of the 12S in the Sicilian population, but no polymorphism was identified in the ITS marker. The combination of Chelex DNA extraction and WGA is thus shown to be a simple and robust technique for examining molecular markers for multiple loci by using individual mites. We conclude that the methods, Chelex extraction of DNA followed by WGA, provide a large quantity of DNA template that can be used for multiple PCR reactions useful for genetic studies requiring the genotypes of individual mites.     

Genome amplification of single sperm using multiple displacement amplification

Sperm typing is an effective way to study recombination rate on a fine scale in regions of interest. There are two strategies for the amplification of single meiotic recombinants: repulsion-phase allele-specific PCR and whole genome amplification (WGA). The former can selectively amplify single recombinant molecules from a batch of sperm but is not scalable for high-throughput operation. Currently, primer extension pre-amplification is the only method used in WGA of single sperm, whereas it has limited capacity to produce high-coverage products enough for the analysis of local recombination rate in multiple large regions. Here, we applied for the first time a recently developed WGA method, multiple displacement amplification (MDA), to amplify single sperm DNA, and demonstrated its great potential for producing high-yield and high-coverage products. In a 50 μl reaction, 76 or 93% of loci can be amplified at least 2500- or 250-fold, respectively, from single sperm DNA, and second-round MDA can further offer >200-fold amplification. The MDA products are usable for a variety of genetic applications, including sequencing and microsatellite marker and single nucleotide polymorphism (SNP) analysis. The use of MDA in single sperm amplification may open a new era for studies on local recombination rates.     

Use of whole genome amplification and comparative genomic hybridisation to detect chromosomal copy number alterations in cell line material and tumour tissue

We have established that whole genome amplification (WGA), in conjunction with genomic DNA array comparative genomic hybridisation (gaCGH) allows for the identification of genome-wide copy number abnormalities (CNAs) in DNA extracted from both cell line and patient material. To determine the fidelity and reproducibility of WGA to detect copy number imbalances using gaCGH, well characterized cell line genomic DNA was analysed. The gaCGH data obtained from non-amplified DNA and amplified DNA for the neuroblastoma cell line NUB7 and a paediatric medulloblastoma patient was almost identical. In addition, laser capture microdissection (LCM) of prostate tumour cells and subsequent WGA allowed for the detection of a number of CNAs that may not have been identified if DNA had been extracted in bulk from heterogeneous tissue. The results presented here demonstrate the use of WGA for generating sufficient DNA for gaCGH analysis without the introduction of significant sequence representation bias. The combination of amplification and gaCGH using DNA extracted from archival patient material has the potential for permitting the studying of DNA from small cancerous or pre-cancerous foci, which may help to identify potential genomic markers for early diagnosis.     

Whole-genome multiple displacement amplification from single cells

Multiple displacement amplification (MDA) is a recently described method of whole-genome amplification (WGA) that has proven efficient in the amplification of small amounts of DNA, including DNA from single cells. Compared with PCR-based WGA methods, MDA generates DNA with a higher molecular weight and shows better genome coverage. This protocol was developed for preimplantation genetic diagnosis, and details a method for performing single-cell MDA using the phi29 DNA polymerase. It can also be useful for the amplification of other minute quantities of DNA, such as from forensic material or microdissected tissue. The protocol includes the collection and lysis of single cells, and all materials and steps involved in the MDA reaction. The whole procedure takes 3 h and generates 1-2 microg of DNA from a single cell, which is suitable for multiple downstream applications, such as sequencing, short tandem repeat analysis or array comparative genomic hybridization.     

Whole genome amplification strategy for forensic genetic analysis using single or few cell equivalents of genomic DNA

Evidentiary items sometimes contain an insufficient quantity of DNA for routine forensic genetic analysis. These so-called low copy number DNA samples (< 100 pg of genomic DNA) often fall below the sensitivity limitations of routine DNA analysis methods. Theoretically, one way of making such intractable samples amenable to analysis would be to increase the number of starting genomes available for subsequent STR (short tandem repeat) analysis by a whole genome amplification strategy (WGA). Although numerous studies employing WGA have focused primarily on clinical applications, few in-depth studies have been conducted to evaluate the potential usefulness of these methods in forensic casework. After an initial evaluation of existing methods, a modified WGA strategy was developed that appears to have utility for low copy number forensic casework specimens. The method employs a slight, but important, modification of the "improved primer extension preamplification PCR" method (I-PEP-PCR), which we term mIPEP (modified-I-PEP-PCR). Complete autosomal STR and Y-STR (Y chromosome short tandem repeat) profiles were routinely obtained with 5 pg of template DNA, which is equivalent to 1-2 diploid cells. Remarkably, partial Y- and autosomal STR profiles were obtained from mIPEP-treated DNA recovered from bloodstains exposed to the outside environment for 1 year whereas non-mIPEP-treated samples did not produce profiles. STR profiles were obtained from contact DNA from single dermal ridge fingerprints when the DNA was subjected to prior mIPEP amplification but not when the mIPEP step was omitted.