X染色体STR基因座的法医学研究进展

对X染色体的结构特征、遗传特征等相关基础知识及其短串联重复序列(STR)基因座在法医学领域的研究历史、现状, 复合扩增的研究动态和应用等方面进行了综述。同时收集了国内外X染色体STR 基因座在法医DNA工作者实践中的研究和应用资料, 分析了X染色体STR基因座在法医学应用中的利弊, 以促进X染色体STR基因座在法医学实践中的应用。     

9号染色体10个STR基因座的遗传制图

运用小规模实验初步探讨了以中国人群为基础的遗传图绘制工作的必要性。18个无关汉族3代家系共131份血样采自甘肃省白银地区,常规PCR扩增9号染色体的10个STR基因座,采用非变性聚丙烯酰凝胶电泳分析。PCR产物经克隆测序确定核心序列重复次数,采用标准命名法命名各等位基因,用POPGENE软件包计算各基因座等位基因频率,并进行Hardy-Weiberg平衡检验,用Linkage软件包进行各基因座之间连锁关系分析。根据连锁分析结果绘制了中国人群由10个STR基因座构成的9号染色体遗传图。基于中国人群体的9号染色体10个STR连分析锁分析结果与GDB检索结果之间存在较显著的差异,这种差异同时表现在个别基因座之间和0号染色体遗传图总长度上。男、女遗传结果之间在较显著的差异,这种差异同时表现在个别基因之间和9号染色体总长度上。男、女遗传图总长度为129．21cM和178．4cM,均大高加索入。说明了在运用GDB数据之前,有必要根据实验群体进行基因座的初步评估,并且有必要对基于中国人群体的遗传图进行进一步的研究。     

DXS6804/DXS9896/GATA144D04基因座在中国汉族群体中的遗传多态性及其法医学应用

为了调查X染色体上DXS6804、DXS9896和GATA144D04等3个STR基因座在中国汉族群体的遗传多态性及其法医学应用价值,来用PCR和聚丙烯酰胺凝胶电泳对X染色体3个STR基因座进行分型,并检验女性基因型频率分布是否符合Hardy Weinberg平衡,计算法医学常用各种概率。DXS6804、DXS9896和GATA144D04的非父排除率分别为0 5990、0 6220、0 4280,表明3个STR基因座在中国汉族群体均具有遗传多态性,χ2检验表明女性的基因型频率分布符合Hardy Weinberg平衡。X染色体上的基因座DXS6804、DXS9896和GATA144D04在中国汉族群体中具有较高的遗传多态性,可应用于法医学检验和群体遗传学分析。     

新Y-STR DYS605在山西汉族人群中的多态性分布

为了应用更多的Y染色体特异性STR基因座以用于法医学和人类遗传学研究,用PCR结合PAGE技术检测128例山西汉族无关男性DYS605等位基因分布状况。结果显示：山西地区汉族男性DYS605基因座观察到22,21,20,19,18共5个等位基因,基因频率分别为0．0156;0．1797;0．4531;0．2891;0．0625。等位基因20和19之间的电泳距离在非变性胶上非常接近,要有足够的电泳距离才能区分。测序表明该基因座包括3个串联重复区,其中一个为可变重复区。20例女性DNA未发现扩增产物。     

福建畲族群体17个Y-STR基因座单倍型及遗传关系

应用Y-filerTM试剂盒及基因分型技术,检测152份福建畲族无关男性个体17个Y-STR基因座的多态性分布,计算等位基因频率及单倍型多样性,并结合已公开发表的其他11个群体相应基因座的单倍型资料,分析福建畲族群体遗传距离和聚类关系。福建畲族DYS385a/b基因座检出50种单倍型,其余15个Y-STR基因座分别检出3-11个等位基因,基因多样性GD值在0.4037(DYS391)～0.9725(DYS385a/b);观察到DYS19和DYS390基因座双等位基因和DYS385a/b基因座三等位基因,以及DYS448等部分基因座出现的"off-ladder"等位基因现象。17个Y-STR基因座共同构成的单倍型144种,其中138种单倍型出现1次,5种出现2次,1种出现4次,累计GD值为0.9990。从遗传距离分析发现,福建畲族与浙江汉族之间的遗传距离最近(0.0042),与青海藏族(0.2378)之间的遗传距离相对较远。福建畲族最靠近由台湾群体、浙江汉族、南方汉族等典型南方汉族群体聚成的分支区域。结果表明该17个Y-STR基因座在福建畲族群体中具有丰富的遗传多态性,对建立Y染色体STR数据库,研究群体遗传学和进行法医学应用有重要意义。     

21- 三体综合征亲子鉴定一例暨文献复习

目的:对亲子鉴定中检出的三带型等位基因座进一步探讨其发生原因,与同行共享。方法:亲子鉴定中发现一个体两个等位基因座(D21S11和Penta D)检出三等位基因,进一步采集其静脉血进行血细胞培养作染色体分析。结果:该个体染色体核型为:47,XY,+21。结论:染色体为三体型的个体在基因检测时能检测到三等位基因。     

克里雅河下游封闭人群DYS19和DYS390多态性研究

本文以居住于塔克拉玛干沙漠当中克里雅河下游地区封闭人群(51例男性)为研究对象,采用基因扫描对其DYS19和DYS390两个STR基因座进行基因扫描研究其遗传多态性。对于DYS19基因座,克里雅河下游的封闭人群等位基因分布呈现“M”形分布,以DYS19*14和DYS19*16最常见,基因频率分别为0.353和0．510;对于DYS390基因座,其人群等位基因分布也并非呈现“钟形”分布,而是以DYS390*21和DYS390“24两种基因型基因频率最高,并且DYS390*21为此人群等位基因重复次数最少的基因型,基因频率分别为0．235和0．431,这可能是提示克里雅河下游的封闭人群的来源包含两个不同的群体分支。     

DXS6804/DXS9896/GATA144D04基因座在中国汉族群体中的遗传多态性及其法医学应用Genetic

为了调查X染色体上DXS6804、DXS9896和 GATA144D04等3个STR基因座在中国汉族群体的遗传多态性及其法医学应用价值,来用PCR和聚丙烯酰胺凝胶电泳对X染色体3个STR基因座进行分型,并检验女性基因型频率分布是否符合Hardy-Weinberg平衡,计算法医学常用各种概率。DXS6804、DXS9896和 GATA144D04的非父排除率分别为0.5990、0.6220、0.4280,表明3个STR基因座在中国汉族群体均具有遗传多态性,χ2检验表明女性的基因型频率分布符合Hardy-Weinberg平衡。X染色体上的基因座DXS6804、DXS9896和 GATA144D04在中国汉族群体中具有较高的遗传多态性,可应用于法医学检验和群体遗传学分析。 Abstract： To investigate the genetic polymorphisms of three short tandem repeats loci of chromosome X in Chinese Han population in Chengdu area and its use in forensic science. Three X-chromosome linked short tandom repeat loci were analyzed by PCR followed by polyacrylamide gel electrophoresis. Hardy-Weinberg equilibrium was tested and forensic interested value was calculated .The power of exlcution of DXS6804、DXS9896和 GATA144D04 is 0.5990、0.6220、0.4280,respectively. The result showed that all the three STR loci were polymorphic among 100 unrelated females and 120 unrelated males from Chinese Han population. χ2 tests demonstrated that genotype frequencies in females did not depart from Hardy-Weinberg equilibrium. Three X-chromosome linked short tandem repeat loci have high polymorphism, they can be applied to forensic medicine and population genetics.     

用多重PCR检测上海地区汉族人群9个STR基因座的多态性

利用多重PCR和四色荧光（5－FAM,JOE,NED和ROX）自动化检测技术调查上海地区汉族人群D3S1358、vWA、FGA、D8S1179、D21S11、D18S51、D5S818、D13S317、D7S820等9个STR基因座多态性分布并计算 该9个基因座的的基因频率（Pi)、个体鉴别力（DP）、无偏倚期望杂合性（H）、多态性信息含量（PIC）和非父排除概率（PE）。结果显示：9个STR基因座的基因型分布符合Hardy-Weinberg平衡,9个STR基因座中FGA基因座的DP值最高为0.9584,D8S1179的H值最高为0.9403,D18S51的PIC值最高为0.8560,D18S51的PE值最高为0.7391,9个STR基因座累积个体鉴别力（CDP)为0.9999996,累积非父排除能力（CPE）为0.99991。9个STR基因座适合作为中国人群的遗传标志,用于人类学、遗传疾病基因连锁分析、法医学亲子鉴定和个体识别等研究领域。     

陕西汉族人群12号染色体上7个STR基因座的遗传多态性分析

分析了中国汉族人群中12号染色体上7个短串联重复序列（short tandem repeat,STR）基因座的多态性。 采用荧光标记基因扫描对12号染色体上D12S1718、D12S1675、D12S358、D12S367、D12S1638、D12S1646和D12S1682基因座在80名陕西咸阳、榆林汉族人中的遗传多态性进行分析。结果在中国汉族人群中, D12S1718、D12S1675、D12S358、D12S367、D12S1638、D12S1646和D12S1682基因座分别检出7、10、8、8、6、9和11个等位基因,10、17、18、18、14、18和26个基因型,杂合度分别为44.28％、66.10％、78.89％、77.89％、73.69％、74.55％和82.39％。表明这7个STR基因座在中国人群中有较好的多态性,其基因型分布均符合Hard－Weinberg平衡（P>0.05）。     

Standardization and conversion of marker polymorphism measures

Large scale gene mapping efforts in domestic animals have generated and mapped a large number of genetic markers that are useful for mapping quantitative trait and disease loci and for DNA diagnostic purposes such as parentage testing. Marker polymorphism is an important criterion for selecting genetic markers in planning experiment for mapping quantitative trait loci or for DNA diagnostic purposes. Current formulations of marker polymorphism measures are functions of marker allele frequencies. In this study, two measures of marker polymorphism that are available from gene mapping studies and do not require allele frequencies were proposed and analyzed: the observed polymorphic information content (PIC) and the observed family information content (FIC). The observed FIC was more stable than the observed PIC because the observed FIC is unaffected by the variation in the frequency of heterozygous parents. However, both FIC and PIC are dependent on the gene mapping design. The effective number of alleles is recommended as a tool to standardize marker polymorphism measures so that polymorphism of different markers can be compared on an equal basis, and to obtain a new polymorphism measure (such an exclusion probability) from an existing measure (such as FIC). The usage of the effective number of alleles to standardize FIC, PIC and exclusion probabilities is illustrated using genetic markers in a published linkage map.     

Number of STR Repeats as a Potential New Quantitative Genetic Marker for Complex Diseases, Illustrated by Schizophrenia

It has proved difficult to find strong and replicable genetic linkages for complex diseases, since each susceptibility gene makes only a modest contribution to onset. This is partly because high-efficacy genetic markers are not usually available. The aim of this article is to explore the possibility that the total number of tandem repeats in one STR locus, rather than the frequencies of different alleles, is a higher efficacy quantitative genetic marker. DNA samples were collected from schizophrenic patients and from a control population. Alleles of the short tandem repeats (STR) loci D3S1358, vWA, and FGA were determined using the STR Profiler Plus PCR amplification kit. The two groups did not differ statistically in the frequencies of alleles at the D3S1358, vWA, or FGA loci. However, a significant difference was obtained in the vWA locus when the total number of core unit repeats was compared between the schizophrenia and control groups (33.28+/-2.61 vs. 32.35+/-2.58, P<0.05). It seems that the number of STR repeats may be a new, quantitative, and higher efficacy genetic marker for directly indicating genetic predisposition to complex hereditary diseases such as schizophrenia.     

Standardization and conversion of marker polymorphism measures

Abstract

Large scale gene mapping efforts in domestic animals have generated and mapped a large number of genetic markers that are useful for mapping quantitative trait and disease loci and for DNA diagnostic purposes such as parentage testing. Marker polymorphism is an important criterion for selecting genetic markers in planning experiment for mapping quantitative trait loci or for DNA diagnostic purposes. Current formulations of marker polymorphism measures are functions of marker allele frequencies. In this study, two measures of marker polymorphism that are available from gene mapping studies and do not require allele frequencies were proposed and analyzed: the observed polymorphic information content (PIC) and the observed family information content (FIC). The observed FIC was more stable than the observed PIC because the observed FIC is unaffected by the variation in the frequency of heterozygous parents. However, both FIC and PIC are dependent on the gene mapping design. The effective number of alleles is recommended as a tool to standardize marker polymorphism measures so that polymorphism of different markers can be compared on an qual basis, and to obtain a new polymorphism measure (such an exclusion probability) from an existing measure (such as FIC). The usage of the effective number of alleles to standardize FIC, PIC and exclusion probabilities is illustrated using genetic markers in a published linkage map.     

Methods for the production of multi-marker strains

Summary The production of a multi-marker strain given a series of strains each carrying a single marker will require a considerable investment in time and resources when based on a series of formal crosses. Such strains can be produced rapidly and with only minimal resources by recurrent cycles of random mating and selection, with selection based on the number of desired alleles carried.     

Spurious linkage between markers in QTL mapping

Selective genotyping of extreme progeny is a powerful method to increase the information content per individual when looking for quantitative trait loci (QTLs) using molecular markers for which a map is known. However, if marker information from the selected individuals is used to construct the map of the markers, this can lead to distorted segregation of the markers that in turn can lead to the estimation of a spurious linkage between independently inherited markers. The mistaken estimation of linkage between independently inherited markers will occur when there are two (or more) independently inherited QTLs linked to two (or more) markers and the same individuals are used to estimate the map of the markers and to do the QTL estimation. The incorrect linkage occurs because in selecting individuals from the tails of the phenotypic distribution we will also be selecting certain combinations of the markers instead of obtaining a random sample of the true distribution of the marker genotypes. Analytical results are outlined and the analyses of a simulated data set illustrate the problems that could arise when data from individuals chosen by selective genotyping are incorrectly employed to construct a marker map. A strategy is proposed to remedy this problem.     

Exclusion probabilities for pedigree testing farm animals

Pedigree testing, using genetic markers, may be undertaken for a variety of situations, of which the classical paternity testing is only one. This has not always been made clear in the literature. Exclusion probabilities associated with various testing situations, including the use of autosomal or X-linked codominant marker systems with any number of alleles, are presented. These formulae can be used to determine the appropriate exclusion probability for the situation being investigated. One such situation is where sire groups of progeny are to be verified without knowledge of the dams' genotypes, in which case the classical paternity exclusion probability is too high, and if used may result in an optimistic declaration about the progeny that have not been excluded. On the other hand, if mating pairs are known then incorrect progeny can be excluded at a higher rate than suggested by paternity exclusion calculations. The formulae also assist in determining the usefulness of X-linked markers, particularly if the pedigree checks involve progeny of only one sex. A system of notation that is useful for the algebraic manipulation of genetic probabilities, including exclusion probabilities as presented here, is also given.     

Marker-assisted introgression using non-unique marker alleles II: selection on probability of presence of the introgressed allele

If marker alleles that identify a gene for introgression are not completely unique to the different base populations, the trait allele can be lost quickly during the process of backcrossing. This study considers ways to deal with incompletely informative markers in order to retain the desired allele. Selection was based on the probability of the presence of the desired (introgressed) trait allele, which was calculated for each marker genotype, using a single marker or a diallelic or triallelic marker bracket. The percentage of individuals retaining the introgressed allele was calculated over five generations of backcrossing, for selected fractions between 0 and 1, for marker alleles that could occur in both base populations. The best results were obtained with a rather large selected fraction, when all individuals, heterozygous and homozygous for the most desirable allele at the marker loci, were selected. Additional selection against marker homozygotes (which might have the highest probability of carrying the desired-trait allele, but produce uninformative gametes) altered the optimum selected fraction, making the selected fraction more consistently inversely related to a better retention of the desired-trait allele. A marker bracket was found to give a better retention of the desired-trait allele than a single marker and triallelic markers were better than diallelic markers, giving a retention of almost 50%. The earlier that preselection of parents (on informativeness) took place the better the overall result; preselection should occur preferably in the base populations. Preselection could make marker alleles unique to alternative base populations and markers would effectively become fully informative. Selection in the base populations might not be possible or not desirable, for example, because of the available number of individuals. This is unlikely to be a problem when parents are paired up to exclude any common marker alleles.     

Toward molecular diagnostics of mood disorders in psychiatry

Mental disorders are highly prevalent and often difficult to diagnose. There is a significant gap between advances in their pharmacotherapy and the present lack of objective biologic tests for diagnosis. The special complexity of diagnosis in psychiatry is related to the absence of objective diagnostic "gold standards", co-morbidity, heterogeneity and equifinality, quantitative trait loci, and locus heterogeneity. Here, we review recent findings relating to diagnostic, pathophysiological, and linkage markers for mood disorders at the biochemical level involving monoamine neurotransmitters, hormones, and signal-transducing G proteins. Identification of biological diagnostic markers could enable segregating mood disorders to several biologically different subtypes. New-era methods and strategies involving genomics, proteomics, multi-marker approach and single nucleotide polymorphisms have the potential to revolutionize future diagnosis in psychiatry.     

Recombinogenic properties of Pyrococcus furiosus strain COM1 enable rapid selection of targeted mutants

We recently reported the isolation of a mutant of Pyrococcus furiosus, COM1, that is naturally and efficiently competent for DNA uptake. While we do not know the exact nature of this mutation, the combined transformation and recombination frequencies of this strain allow marker replacement by direct selection using linear DNA. In testing the limits of its recombination efficiency, we discovered that marker replacement was possible with as few as 40 nucleotides of flanking homology to the target region. We utilized this ability to design a strategy for selection of constructed deletions using PCR products with subsequent excision, or "pop-out," of the selected marker. We used this method to construct a "markerless" deletion of the trpAB locus in the GLW101 (COM1 ΔpyrF) background to generate a strain (JFW02) that is a tight tryptophan auxotroph, providing a genetic background with two auxotrophic markers for further strain construction. The utility of trpAB as a selectable marker was demonstrated using prototrophic selection of plasmids and genomic DNA containing the wild-type trpAB alleles. A deletion of radB was also constructed that, surprisingly, had no obvious effect on either recombination or transformation, suggesting that its gene product is not involved in the COM1 phenotype. Attempts to construct a radA deletion mutation were unsuccessful, suggesting that this may be an essential gene. The ease and speed of this procedure will facilitate the construction of strains with multiple genetic changes and allow the construction of mutants with deletions of virtually any nonessential gene.     

A large population genetic study of 15 autosomal short tandem repeat loci for establishment of Korean DNA Profile Database

Genotyping of highly polymorphic short tandem repeat (STR) markers is widely used for the genetic identification of individuals in forensic DNA analyses and in paternity disputes. The National DNA Profile Databank recently established by the DNA Identification Act in Korea contains the computerized STR DNA profiles of individuals convicted of crimes. For the establishment of a large autosomal STR loci population database, 1805 samples were obtained at random from Korean individuals and 15 autosomal STR markers were analyzed using the AmpFlSTR Identifiler PCR Amplification kit. For the 15 autosomal STR markers, no deviations from the Hardy-Weinberg equilibrium were observed. The most informative locus in our data set was the D2S1338 with a discrimination power of 0.9699. The combined matching probability was 1.521 × 10⁻¹⁷. This large STR profile dataset including atypical alleles will be important for the establishment of the Korean DNA database and for forensic applications.