猪3号染色体九个微卫星位点的遗传多态性研究和遗传图谱构建

从已公布的猪 3号染色体连锁图谱中选取 9个微卫星位点 ,分析了这些位点在大白猪×梅山猪资源家系F2代 140头个体上的多态性 ,利用Crimap软件分别构建了猪 3号染色体两性平均连锁图谱以及公、母畜连锁图谱。结果表明 :各位点等位基因数为 2～ 4个 ,杂合度为 0 .436～ 0 .6 5 6 ,多态信息含量为 0 .35 1～ 0 .5 82 ;本研究所构建的平均连锁图谱全长为 16 1.1cM ,公、母畜连锁图谱全长分别为 135 .8cM和 188.7cM。与USDA所公布的连锁图谱相比 ,两者的标记顺序一致 ,但我们的图谱标记间隔偏大。     

猪1、3号染色体微卫星位点多态性及遗传连锁图谱的构建

利用 3头英系大白猪和 7头梅山猪为父母本建立了F2 参考家系。F1 公猪 5头 ,母猪 2 3头 ,随机交配产生 147个F2 个体。根据美国肉畜研究中心 (USDA MARC)公布的猪遗传连锁图谱 ,在 1号和 3号染色体上等间隔 (2 0cM)选择 8个和 9个微卫星标记 ,对参考家系全部的F0 、F1 和F2 个体进行扩增 ,获得各标记位点基因型。研究结果表明 ,等位基因数介于 2到 5之间 ,平均每位点 3.35个等位基因 ;部分等位基因片段长度超过USDA MARC所报道的结果。标记位点杂合度为 0 .385 3～ 0 .70 97,平均 0 .5 795。有信息的减数分裂数为 35～ 30 5 ,平均 2 40。利用此参考家系和CRI MAP软件包构建的 1号和 3号染色体图谱分别长 182 .3cM和 180 .2cM。 1号染色体的母畜图谱短于公畜图谱 ,而 3号染色体正好相反。与USDA MARC报道相比较 ,微卫星排列顺序与报道相同 ,但 1号染色体长 44 .8cM ,3号染色体长 6 3.3cM。此连锁图的构建为以后的数量性状基因位点 (quantitativetraitloci,QTLs)定位奠定了基础。     

猪2号染色体遗传连锁图谱的构建与QTL定位分析

构建了猪2号染色体的遗传连锁图谱,并进一步进行了重要生产性状数量性状位点的定位,结果表明,7个微卫星位点均为中高度多态性位点,多态信息含量为0．40182－0．58477,可以满足遗传连锁图谱构建的要求,构建的资源家系遗传连锁图谱总长152．9cM,位点的排列顺序与USDA结果一致,但除了Sw2516与Sw1201标记区间外,所有标记区间距离均大于USDA图谱,将连锁图谱与性状记忆结合起来,进一步进行了猪数量性状位点定位的研究,在2号染色体发现了显著影响活体估测瘦肉率等活体估测性状的QTLs,此外还发现眼肌高度和背最长肌大理石纹的QTLs,其中影响活体估测瘦肉率的QTL达到了染色体显著的水平（P＜0．01）,且解释性状的表型变异达21．55％,影响眼肌高度和背最长肌大理石纹的QTLs分别可以解释10．12％和10．97％的表型变异,影响活体估测性状的QTLs加性效应与显性效应作用方向相反,影响眼肌高度的QTL加性效应与显性效应相同,在大白猪中具有增效等位基因,定位的QTLs效应较大,为在群体中开展分子标记辅助育种奠定了理论基础。     

微卫星标记对资源猪群的遗传分析和连锁图谱构建

在猪数量性状位点的定位研究中,标记的使用和图谱的构建是很重要的。本研究从猪的第4、6、7、8和13染色体上选取39个微卫星标记,在来源于约克夏和梅山214头猪组成的资源群中,分析了遗传特征并构建了图谱。研究表明,平均等位基因数、平均观察杂合度(Ho)和平均多态信息含量(PIC)在F1和F2代中分别为:3.2,0.528,0.463和3.2,0.496,0.447。结果表明大多数微卫星标记位点表现为中高度杂合性。在资源群体中,平均有信息减数分裂数是217.4(44-316),而各染色体上两性平均图谱的长度分别是:172.3cM(SSC4),168.7cM(SSC6),191.7cM(SSC7),197.3cM(SSC8),178.3cM(SSC13)。与USDA-MARC的参考图谱相比,标记位点的顺序相同,但长度均较长。雌雄两性图谱相比,第4和第6染色体上雌性图谱长于雄性图谱;而在另外3条染色体上,则雄性图谱长于雌性图谱。结果显示了标记位点在资源猪群的遗传特征和遗传关系,其连锁图谱可用于今后的QTL定位。     

凉山半细毛羊1号染色体微卫星遗传连锁图谱的构建

实验选择绵羊1号条染色体上的9个微卫星标记,采用父系半同胞家系群体（共387个个体）构建凉山半细毛羊1号染色体遗传连锁图。建立的资源参考家系通过20个微卫星标记进行了系谱确证。试验结果表明,9个标记的等位基因数变化范围为5~15个,杂合度在0.202~0.831之间,平均杂合度为0.617,各标记的平均多态信息含量PIC=0.604。构建的凉山半细毛羊1号条染色体遗传连锁图总长度311.0 cM,与美国肉畜中心（USDA）和国际绵羊作图中心（IMF）构建的绵羊1号条染色遗传连锁图结果基本一致。可用于下一步的QTL定位研究。     

猪F2设计资源家系中4条染色体微卫星标记分析

利用中国地方猪种蓝塘猪(16头母猪)与外来品种长白猪(8头公猪)按F2设计建立资源家系, 根据美国肉畜中心(USDA-MARC 2.0)公布的猪连锁图谱, 在1、4、7和8号染色体上间隔10~20 cM选择一个微卫星标记, 共31个标记, 采用WAVEÒ核苷酸片段分析系统和ABI 377 DNA序列分析仪检测资源群体的P、F1和F2代个体微卫星的基因型, 对其基因频率、杂合度和多态信息含量等进行统计分析。结果发现: 利用ABI 377检测的猪1、4和8号染色体上的有效微卫星标记21个, 其中13个标记的18个等位基因片段大小超过了网上已报道的结果, 发现新等位基因的标记占62%; 在31个微卫星标记中, 杂合度(h)在0.043~0.7855之间, 总平均杂合度为0.6460, 其中70%座位的h>0.60; 总平均多态信息含量(PIC)为0.5949, 有77.4%位点的PIC>0.5。统计分析结果表明, 选用的微卫星标记能够较好地提供标记信息, 为进一步在该家系中进行猪重要性状的QTL定位打下了良好的基础。     

利用商品猪群定位猪耳型QTL

由 19头杂种公猪 [皮特兰× (皮特兰×汉普夏 ) ]、5 2头杂种母猪 [Leicoma× (大约克×长白 ) ]及其 332头后代组成的商品群作为参考家系 ,选择 172个微卫星标记和 3个 1类标记 (RYR1、PRKAG3、PIT1)对参考家系的个体进行遗传标记分型 ,构建了猪的整个基因组微卫星连锁图谱。按照线性评分的方法 (竖耳 :1分 ;垂耳 :- 1分 ;半垂耳 :0分 )测定猪的耳型表型值。耳型测定值的平均值为 0 .2 3,标准差为 0 .82。应用最小二乘回归方法对耳型的QTL进行定位 ,结果仅在 6号染色体的末端 (Sw1881和Sw32 2 )之间以 1%基因组显著性水平检测出 1个耳型基因位点 ,而在其他染色体上即使 10 %染色体显著性水平上也没有发现QTL。     

利用两个测序水稻品种构建微卫星连锁图谱

利用已完成基因组测序的两个水稻品种日本晴和931l的数据库成功开发出水稻微卫星新标记,并利用由90个单株组成的日本晴×9311 F2作图群体,构建了一张包含152个SSR标记位点、覆盖基因组总长度2 455.7 cM的连锁图谱,有46个SSR新标记为自主开发,该图谱标记间的平均遗传距离为16.16 cM;并将未能在Temnykh等人(2001)构建的图谱上定位的微卫星标记RM345和RM494定位在第6染色体上.通过与Temnykh等人(2001)和兰涛等人(2003)所构建的图谱从作图群体的类型和大小、标记的类型和数量、标记在染色体上的线性排列顺序等几个方面进行比较,所绘制的图谱其标记在染色体线性排列上与Temnykh等人绘制的图谱具有很高的一致性,达93.81%.     

两个常染色体显性遗传寻常性鱼鳞病家系致病基因的定位

为了对寻常性鱼鳞病的致病基因进行定位, 收集了2个湖南寻常性鱼鳞病家系, 采集外周血, 提取基因组DNA, 采用1号染色体和10号染色体上2个已知寻常性鱼鳞病位点的微卫星标记对这两个家系进行基因分型和连锁分析。结果显示, 寻常性鱼鳞病家系1的致病基因位于D1S498(1q21)附近, 与已知定位区间重叠; 寻常性鱼鳞病家系2的致病基因位点与已知的寻常性鱼鳞病位点不连锁, 可能存在新的致病基因位点。     

水稻籼粳交F2、F6群体遗传连锁图谱的比较分析

以部分基因组和全基因组测序水稻籼稻(O sativa L. indica)品种“培矮64S”(Pei’ai 64S♀)和粳稻(O sativa L. japonica)品种“日本晴”(Nipponbare♂)为构图亲本, 选取F2代180个株系为作图群体, 构建含138个微卫星位点的水稻遗传连锁图谱, 覆盖基因组2 046.2 cM, 平均图距17.1 cM, 即F2 图谱; 采用单粒传法获得F2:6 代330个株系, 用相同的多态性标记分析F6群体, 构建含92个标记连锁图谱, 覆盖基因组2 563.5 cM, 平均图距27.86 cM, 即F6图谱; F2、F6图谱在连锁群数、定位标记数、标记的位置顺序、遗传图距、平均图距等方面发生了较大变化, 并对产生这些差异的原因进行了初步分析。     

Microsatellite Variability and Its Relationship with Growth, Egg Production, and Immunocompetence Traits in Chickens

Variability of microsatellites and a possible relationship with growth, egg production, and immunocompetence traits were estimated for six crossbred chicken populations of White Leghorn. Nine microsatellite markers were explored; an association study used the least square maximum-likelihood method on 170 birds of six genetic groups. Seven microsatellites were polymorphic, with two to four alleles. The polymorphism information content (PIC) of five markers was more than 52%. Microsatellites MCW0041, ADL0210, and MCW0110 were significantly (P < 0.05) associated with egg production traits. Genotype 33 of MCW0041 had the highest egg production, up to 64 and 72 weeks of age. Genotypes 11 and 13 of this marker produced the lowest number of eggs. The heterozygous genotype 34 of ADL0210 had the highest egg production, up to 52, 64, and 72 weeks of age. Homozygote 11 of MCW0110 produced the highest number of eggs, up to 28 weeks of age. MCW0041 was significantly (P < 0.05) associated with body weight at 28 and 40 weeks of age. No microsatellite was significantly associated with egg weight at any age, with age at sexual maturity, or with immune response to sheep RBC.     

孔雀微卫星引物筛选及其遗传多样性分析

利用29对鸡微卫星标记对孔雀基因组DNA进行种间扩增, 发现14对引物能扩增出特异性条带, 每对引物扩增的平均等位基因数为1.71, 有7对引物具有较丰富的多态性, 其中MCW0080和MCW0098最为理想。蓝孔雀和绿孔雀群体间和群体内的遗传分析结果表明, 绿孔雀和蓝孔雀两个群体的期望杂合度分别为0.7422和0.6943, 群体间的遗传分化系数为0.078, Reynolds’遗传距离和基因流分别为0.0603和3.896, 结果显示这两个孔雀群体的杂合度和遗传多样性水平都很低, 且有相互混杂的趋势。     

Mapping the Naked Neck (NA) and Polydactyly (PO) mutants of the chicken with microsatellite molecular markers

The bulked segregant analysis methodology has been used to map, with microsatellite markers, two morphological mutations in the chicken: polydactyly (PO) and naked neck (NA). These autosomal mutations show partial dominance for NA, and dominance with incomplete penetrance for PO. They were mapped previously to different linkage groups of the classical map, PO to the linkage group IV and NA being linked to the erythrocyte antigen CPPP. An informative family of 70 offspring was produced by mating a sire, heterozygous for each of the mutations, to 7 dams homozygous recessive for each locus. Three DNA pools were prepared, pool PO included 20 chicks exhibiting at least one extra-toe, pool NA included 20 non-polydactyly chicks showing the typical phenotype associated with heterozygosity for the naked neck mutation, and pool NP included 20 chicks exhibiting neither of the mutant phenotypes. Typings were done on an ABI-373 automatic sequencer with 147 microsatellite markers covering most of the genome. An unbalanced distribution of sire marker alleles were detected between pool PO, and pools NA and NP, for two markers of chromosome 2p, MCW0082 and MCW0247. A linkage analysis taking into account the incomplete penetrance of polydactyly (80%) was performed with additional markers of this region and showed that the closest marker to the PO locus was MCW0071 (5 cM, lod score = 9). MCW0071 lies within the engrailed gene EN2 in the chicken. In the mouse, the homologous gene maps on chromosome 5, close to the hemimelic extra-toes mutation Hx. In the case of the NA locus, markers of chromosome 3 were selected because CPPP was mapped on this chromosome. Analysis of individual typings showed a linkage of 5.7 cM (lod score = 13) between the NA locus and ADL0237 in the distal region of chromosome 3q. These results contribute to connecting the former classical map to the molecular genetic map of the chicken, and open the way to the identification of the molecular nature of two developmental mutations of the chicken that are known to occur in many breeds of chickens.     

A panel of polymorphic microsatellite markers in Himalayan monal Lophophorus impejanus developed by cross-species amplification and their applicability in other Galliformes

Isolation and development of new microsatellite markers for any species is still labour-intensive and requires substantial inputs of time, money and expertise. Therefore, cross-species microsatellite amplification can be an effective way in obtaining microsatellite loci for closely related taxa in bird species. We have reported microsatellite loci for Himalayan monal for the first time. Fifteen microsatellite markers developed for chicken were cross-amplified in Himalayan monal. All the tested 15 microsatellite markers were polymorphic, with mean (± s.e.) allelic number of 4 ± 1.51, ranging 2–7 per locus. The observed heterozygosity in the population ranged between 0.285 and 0.714, with mean (± s.e.) of 0.499 ± 0.125, indicating considerable genetic variation in this population. While 12 loci conformed to Hardy–Weinberg equilibrium (P > 0.05), 3 loci, i.e. MCW0295, MCW0081, MCW0330 deviated from it (P < 0.05). No evidence for linkage disequilibrium was observed among pair of loci. Our study show that these 15 microsatellites loci could be employed in population genetic studies for Himalayan monal and their applicability in Jungle Bush Quail, Grey francolin and Kalij pheasant.

     

A chicken linkage map based on microsatellite markers genotyped on a Japanese Large Game and White Leghorn cross

A detailed linkage map is necessary for efficient detection of quantitative trait loci (QTL) in chicken resource populations. In this study, microsatellite markers isolated from a (CA)n-enriched library (designated as ABR Markers) were mapped using a population developed from a cross between Japanese Game and White Leghorn chickens. In total, 296 markers including 193 ABR, 43 MCW, 31 ADL, 22 LEI, 3 HUJ, 2 GCT, 1 UMA and 1 ROS were mapped by linkage to chicken chromosomes 1-14, 17-21, 23, 24, 26-28 and Z. In addition, five markers were assigned to the map based on the chicken draft genomic sequence, bringing the total number of markers on the map to 301. The resulting linkage map will contribute to QTL mapping in chicken.     

An amplified fragment length polymorphism map of the silkworm

The silkworm (Bombyx mori L.) is a lepidopteran insect with a long history of significant agricultural value. We have constructed the first amplified fragment length polymorphism (AFLP) genetic linkage map of the silkworm B. mori at a LOD score of 2.5. The mapping AFLP markers were genotyped in 47 progeny from a backcross population of the cross no. 782 x od100. A total of 1248 (60.7%) polymorphic AFLP markers were detected with 35 PstI/TaqI primer combinations. Each of the primer combinations generated an average of 35.7 polymorphic AFLP markers. A total of 545 (44%) polymorphic markers are consistent with the expected segregation ratio of 1:1 at the significance level of P = 0.05. Of the 545 polymorphic markers, 356 were assigned to 30 linkage groups. The number of markers on linkage groups ranged from 4 to 36. There were 21 major linkage groups with 7-36 markers and 9 relatively small linkage groups with 4-6 markers. The 30 linkage groups varied in length from 37.4 to 691.0 cM. The total length of this AFLP linkage map was 6512 cM. Genetic distances between two neighboring markers on the same linkage group ranged from 0.2 to 47 cM with an average of 18.2 cM. The sex-linked gene od was located between the markers P1T3B40 and P3T3B27 at the end of group 3, indicating that AFLP linkage group 3 was the Z (sex) chromosome. This work provides an essential basic map for constructing a denser linkage map and for mapping genes underlying agronomically important traits in the silkworm B. mori L.     

A composite genetic map of the parasitoid wasp Trichogramma brassicae based on RAPD markers.

Three linkage maps of the genome of the microhymenopteran Trichogramma brassicae were constructed from the analysis of segregation of random amplified polymorphic DNA markers in three F2 populations. These populations were composed of the haploid male progeny of several virgin F1 females, which resulted from the breeding of four parental lines that were nearly fixed for different random amplified polymorphic DNA markers and that were polymorphic for longevity and fecundity characters. As the order of markers common to the three mapping populations was found to be well conserved, a composite linkage map was constructed. Eighty-four markers were organized into five linkage groups and two pairs. The mean interval between two markers was 17.7 cM, and the map spanned 1330 cM.     

A physical map of the 20q12-q13.1 region associated with type 2 diabetes

Several recent genetic studies have suggested linkage of Type 2 diabetes (non-insulin-dependent diabetes mellitus) susceptibility to a region of chromosome 20q12-q13.1. To facilitate the identification and cloning of a diabetes susceptibility gene(s) in this region, we have constructed correlated radiation hybrid and YAC/BAC contig physical maps of the region. A high-resolution radiation hybrid map encompassing 9.5 Mb between the PLC and the CEBPB genes was constructed using 68 markers: 25 polymorphic markers, 15 known genes, 21 ESTs, and 7 random genomic sequences. The physical order of the polymorphic markers within this radiation hybrid map is consistent with published genetic maps. A YAC/BAC contig that gives continuous coverage between PLC and CEBPB was also constructed. This contig was constructed from 24 YACs, 34 BACs, and 1 P1 phage clone onto which 71 markers were mapped: 23 polymorphic markers, 12 genes, 24 ESTs, and 12 random genomic sequences. The radiation hybrid map and YAC/BAC physical map enable precise mapping of newly identified transcribed sequences and polymorphic markers that will aid in linkage and linkage disequilibrium studies and facilitate identification and cloning of candidate Type 2 diabetes susceptibility genes residing in 20q12-q13.1.     

Evaluation of inter-simple sequence repeat analysis for mapping in Citrus and extension of the genetic linkage map

Inter-simple sequence repeat (ISSR) analysis was evaluated for its usefulness in generating markers to extend the genetic linkage map of Citrus using a backcross population previously mapped with restriction fragment length polymorphism (RFLP), random amplified polymorphic DNA (RAPD) and isozyme markers. ISSR markers were obtained through the simple technique of PCR followed by analysis on agarose gels, using simple sequence repeat (SSR) primers. Optimization of reaction conditions was achieved for 50% of the SSR primers screened, and the primers amplified reproducible polymorphic bands in the parents and progeny of the backcross population. Mendelian segregation of the polymorphic bands was demonstrated, with an insignificant number of skewed loci. Most of the SSR primers produced dominant loci; however co-dominance was observed with loci derived from three primers. A new genetic map was produced by combining the segregation data for the ISSR markers and data for the RFLP, RAPD and isozyme markers from the previous map and creating genetic linkages among all the markers using JoinMap 2.0 mapping software. The new map has an improved distribution of markers along the linkage groups with fewer gaps, and marker order showed partial or complete conservation in the linkage groups. The incorporation of ISSR markers into the genetic linkage map demonstrates that ISSR markers are suitable for genetic mapping in Citrus. Received: 3 February 2000 / Accepted: 12 May 2000     

Genetic variability in three native Iranian chicken populations of the Khorasan province based on microsatellite markers

This paper represents the results of a study on the genetic diversity in three native chicken populations (Barred, Brown and Black) of Khorasan, a province in northeastern Iran, by using four microsatellite markers (MCW0005, MCW0016, MCW0018 and MCW0034). Average number of alleles was found to be 5.25 per locus across all populations. The examined populations were characterized by a high level of genetic variability as assessed by computing the expected and observed heterozygosities, and polymorphism information content. The authors consider the results of this investigation as an accumulation of data in a research program concerning genetic characteristics of the native chicken populations of Iran that have not been surveyed yet.