贵州小型香猪基因组DNA的AFLP检测研究

报道了AFLP标记在研究贵州小型香猪遗传多性方面的应用和该品系猪个体基因组DNA的AFLP扩增结果,分析了贵州小型香猪的群体遗传结构。实验应用10条AFLP引物,用PstⅠ酶切,对17头猪基因组DNA进行AFLP反应,共获得116个AFLP标记,单引物获得的标记数在2－22间,贵州小型香猪群体相似系数AFLP研究结果为0．866（0．760－0．967）,该研究为贵州小型香猪的遗传稳定性提供了相关的参数,准确评价尚待和其它品种猪对研究后确定。     

贵州小型香猪基因组DNA的AFLP检测研究

报道了AFLP标记在研究贵州小型香猪遗传多态性方面的应用和该品系猪个体基因组DNA的AFLP扩增结果,分析了贵州小型香猪的群体遗传结构.实验应用10条AFLP引物,用PstⅠ酶切,对17头猪基因组DNA进行AFLP反应,共获得116个AFLP标记,单引物获得的标记数在2～22间,贵州小型香猪群体相似系数AFLP研究结果为0.866(0.760～0.967),该研究为评价贵州小型香猪的遗传稳定性提供了相关的参数,准确评价尚待和其它品种猪对比研究后确定。 Abstract:We reported the application of AFIP markers to detect genetic polymorphic loci in Guizhou miniaturc pig and their amplified AFLP results.Their genetic construction Of the population was also analysed.TenAFLP primers were used,genomic DNAs from 17 pigs were restrictive by pst I,116 AFLP markers were obtained,the obtaining marker numbers of individual primer were between 2~22.The results indicate as the following:(1)AFLP marker is suitable for analysing genetic polymorphism in pig;(2)The similarty index of population in Guizhou miniaturc pigs was 0.866(0.760~0.967).The study provides a uscful parameter with appraise genetic stability of Guizhou miniature pigs.     

山西瘦肉型猪(SD-Ⅲ系)基因组DNA的AFLP检测研究

用分子标记AFLP对山西瘦肉型猪(SDⅢ-系)进行纯度检测,旨在为评价该猪种的遗传特性提供相关参数。实验共用8条引物,对25头猪进行了基因组DNA的分析,共获得171个AFLP标记,单引物获得的标记数在3个~15个之间,群体相似系数为0.928(0.892~0.978);遗传距离为0.072(0.022~0.108)。结果表明:AFLP适宜于基因组DNA遗传结构检测;SDⅢ-系猪纯度较高。     

AFLP和RAPD标记技术在栉孔扇贝遗传多样性研究中的应用比较

AFLP和RAPD标记技术是近年来发展最快的基于PCR基础上的两种DNA标记技术,本文比较了两种标记技术在我国栉孔扇贝群体遗传多样性研究中的应用。共筛选20个RAPD引物和7个AFLP引物组合,检测到AFLP标记的有效等位基因数和平均多态信息量稍低于RAPD标记,但AFLP标记在每单位分析中扩增到的野生和养殖群体的多态性条带数(23．8,24．8)分别高于RAPD标记(5．6,5．6),AFLP多态性检测效率显著高于RAPD标记。AFLP和RAPD两种标记技术所揭示的野生种群与养殖群体间的近交系数、遗传距离两项指标均表明,我国栉孔扇贝养殖群体和野生种群之间尚未出现明显的遗传分化。研究结果表明：RAPD和AFLP这两种标记技术均可用于栉孔扇贝遗传多样性的分析,其分析结果是一致的。     

贵州地方山羊品种的RAPD分析

用180条引物对黔东南小香羊、贵州白山羊、贵州黑山羊和黔北麻羊4个贵州地方山羊品种(种群),以及南江黄羊和波尔山羊进行RAPD分析,其中27条引物扩增出多态性图谱。这27条引物共扩增出281条带,多态带为115条,平均多态频率为40．92％(范围20％～80％);每条引物平均扩增条带为10．41条(范围4～16条);扩增带分子量在210～2800bp。贵州白山羊与贵州黑山羊之间的遗传距离指数(0．0605)最小,而波尔山羊与其他品种之间的遗传距离指数(0．1059～0．1488)最大。NJ法聚类结果显示,贵州白山羊与贵州黑山羊间的亲缘关系最近,其次为黔北麻羊,而黔东南小香羊与其他3个贵州地方品种的亲缘关系较南江黄羊还远。分析表明,黔东南小香羊在遗传上为一独立的品种;而贵州地方山羊品种间具有较近的亲缘关系,遗传变异较小,具有较高的遗传稳定性。     

河北省大豆推广品种遗传多样性分析

利用主要农艺性状以及SSR和AFLP2种分子标记,对河北省41个大豆推广品种进行遗传多样性分析,以便为种质资源利用和创新提供依据。农艺性状聚类结果将41个材料划分为3个类群和2个特殊品种,聚类结果与材料系谱来源相差悬殊,不能反映材料间亲缘关系。SSR和AFLP数据聚类结果将41个材料划分为4个SAG（SSR and AFLP—basedgroups）分子类群。30对SSR引物共检测出135个等位变异,平均每个位点上有4．47个等位变异,SSR的遗传多样性指数（Simpson）分布范围为0．0928～0．7800,平均值为0、6442。10对AFLP引物共扩增出93个多态性标记,平均每对引物9．3个多态性标记。品种间的遗传相似系数（GS）变化范围为0．5877～0．9868,平均值变化范围为0．6732～0．7653,总体平均值为0.7237,遗传相似系数较高,说明材料间遗传变异较小。     

茄子耐盐种质资源遗传多样性的SRAP和ISSR分析

利用SRAP和ISSR分子标记,研究了14份耐盐茄子种质资源的遗传多样性,结果表明,2种标记均能揭示材料间较高的遗传多样性,其中ISSR标记多态性略高于SRAP标记。在SRAP分析中,每对引物组合可扩增出8-15条DNA片段,平均为12．12条：26对SRAP引物组合共扩增出315条DNA片段,其中263条具有多态性,多态性比率为83．49％;材料间遗传相似系数变化范围为0．212～0．923,平均值为0．755。在ISSR分析中,每个引物可获得5～16条DNA片段,平均为10．87条;15个ISSR引物共扩增出163条DNA片段,其中141条具有多态性,多态性比率为86．50％;材料间遗传相似系数变幅为0．333-0．957,平均值为0．736。聚类分析表明,2种标记都能将供试材料完全区分开来,聚类结果具有一定的相似性,但也存在明显差异。Mantel相关分析表明,SRAP分析与ISSR分析的相关性达到极显著性水平（r=0．904,P〈0．01）。     

AFLP分子标记技术在昆虫学研究中的应用

AFLP分子标记技术是一种建立在PCR技术和RFLP标记基础上的新的DNA指纹分析技术 ,具有多态性丰富、结果稳定可靠、重复性好、所需DNA量少、可以在不知道基因组序列的情况下进行研究等特点 ,现已广泛用于构建遗传图谱、遗传多样性研究、系统进化及分类学、遗传育种和品质鉴定以及基因定位等方面。该文介绍了AFLP标记技术的原理以及在昆虫学研究中的应用。     

白鲢和鳙鱼的随机扩增多态DNA分析

根据鱼类外周血细胞都有核的特点,采用从冷冻和低渗双重处理分离的细胞核提取基因组DNA.以此法获得的白鲢和鳙鱼的基因组DNA为模板,和Operon公司生产的OPN和OPM两个组共40个随机引物,对这两种鱼进行了随机扩增多态DNA(RAPD)分析;确定了对这两种鱼基因组相关区域可进行随机PCR扩增的有效引物,特别是哪些可产生种群内或群体的RAPD遗传标记,即可产生个体特异性和群体特异性RAPD带谱的引物.讨论了RAPD遗传分子标记在鱼类遗传,特别是遗传多样性研究,和鱼类种质资源评估和管理中的应用前景问题.     

东北梅花鹿居群内亲缘关系的AFLP指纹分析

用扩增片段的长度多态性(amplified fragment length polymorphism,AFLP)标记分析研究了东北梅花鹿同一居群内27个个体的亲缘关系,并以此作为优良种鹿选育种的辅助手段。筛选出9对AFLP引物组合,用EcoRⅠ/MseⅠ双酶切,对27只东北梅花鹿基因组DNA进行AFLP检测,共获得15 169条扩增带,检测出多态性条带11 443,多态性比率78.43%,平均每对引物检测到1 271个多态性位点。群体内相似系数AFLP研究结果,平均为0.7841(0.6809-0.8648),27只鹿聚为Ⅰ和Ⅱ两大类群,Ⅱ大类群分为5组,说明该鹿群个体间有较丰富的遗传变异,且与人工定向选配种有关。Ⅱ-4组群体内相似系数最高,在0.82以上,个体之间遗传距离最小在0.1354-0.1563之间,与繁殖记录的亲缘关系基本一致。该研究表明AFLP指纹技术用于梅花鹿遗传多态性分析,品种鉴定及亲缘关系分析是可行的。     

Genetic diversity in European pigs utilizing amplified fragment length polymorphism markers

The use of DNA markers to evaluate genetic diversity is an important component of the management of animal genetic resources. The Food and Agriculture Organisation of the United Nations (FAO) has published a list of recommended microsatellite markers for such studies; however, other markers are potential alternatives. This paper describes results obtained with a set of amplified fragment length polymorphism (AFLP) markers as part of a genetic diversity study of European pig breeds that also utilized microsatellite markers. Data from 148 AFLP markers genotyped across samples from 58 European and one Chinese breed were analysed. The results were compared with previous analyses of data from 50 microsatellite markers genotyped on the same animals. The AFLP markers had an average within-breed heterozygosity of 0.124 but there was wide variation, with individual markers being monomorphic in 3-98% of the populations. The biallelic and dominant nature of AFLP markers creates a challenge for their use in genetic diversity studies as each individual marker contains limited information and AFLPs only provide indirect estimates of the allelic frequencies that are needed to estimate genetic distances. Nonetheless, AFLP marker-based characterization of genetic distances was consistent with expectations based on breed and regional distributions and produced a similar pattern to that obtained with microsatellites. Thus, data from AFLP markers can be combined with microsatellite data for measuring genetic diversity.     

Use of locus-specific AFLP markers to construct a high-density molecular map in barley

 By using 25 primer combinations, 563 AFLP markers segregating in a recombinant inbred population (103 lines, F₉) derived from L94/Vada were generated. The 38 AFLP markers in common to the existing AFLP/RFLP combined Proctor/Nudinka map, one STS marker, and four phenotypic markers with known map positions, were used to assign present AFLP linkage groups to barley chromosomes. The constructed high-density molecular map contains 561 AFLP markers, three morphological markers, one disease resistance gene and one STS marker, and covers a 1062-cM genetic distance, corresponding to an average of one marker per 1.9 cM. However, extremely uneven distributions of AFLP markers and strong clustering of markers around the centromere were identified in the present AFLP map. Around the centromeric region, 289 markers cover a genetic distance of 155 cM, corresponding to one marker per 0.5 cM; on the distal parts, 906 cM were covered by 277 markers, corresponding to one marker per 3.3 cM. Three gaps larger than 20 cM still exist on chromosomes 1, 3 and 5. A skeletal map with a uniform distribution of markers can be extracted from the high-density map, and can be applied to detect and map loci underlying quantitative traits. However, the application of this map is restricted to barley species since hardly any marker in common to a closely related Triticum species could be identified. Received: 16 June 1997 / Accepted: 9 October 1997     

利用微卫星标记分析七品种（类群）小型猪的遗传多样性

采用世界粮农组织（FAO）和国际动物遗传学会（ISAG）推荐的27个微卫星,对久仰香猪、剑白香猪、从江香猪、环江香猪、黑香猪（贵州省种猪场）、五指山猪和滇南小耳猪等我国7小型猪种（类群）及杜洛克、长白和大白等3个外来猪种的群内遗传变异性和群间遗传差异进行了分析。结果表明,7个小型猪品种（类群）均有较高的群内遗传变异,但久仰、剑白、从江和环江4个香猪类群的群内遗传变异（平均多态信息含量（PIC）为0.61～0.64）显著低于其他3个小型猪种（平均PIC为0.80～0.84）。久仰、剑白、从江和环江4个香猪类群彼此间的遗传差异较小（奈氏标准遗传距离为0.12~0.22）,但它们与其他3个小型猪种有较大的遗传差异（奈氏标准遗传距离为1.61～1.96）,与3个外来猪种的遗传差异更大（奈氏标准遗传距离为1.99～3.30）。通过聚类分析,可将这些猪种清晰地分为3大类,久仰、剑白、从江和环江4个香猪类群紧密地聚为一类,其他3个小型猪种聚为一类,3个外来猪种聚为另一类。这一结果基本符合这些猪种的地理分布和品种来源。
     

Amplified fragment length polymorphism (AFLP) analysis of the genetic structure of the zebra mussel, Dreissena polymorpha, in the Mississippi River

1. We predicted that zebra mussel, Dreissena polymorpha (Pallas), genetic structure in the Mississippi River would follow a model of invasive species genetics, which predicts low genetic structure among populations of recently established species. This prediction was upheld in our previous genetic study using allozymes, however, one locus yielded anomalous results. 2. We employed amplified fragment length polymorphism (AFLP) analysis as a neutral marker to assess the amount of genetic structure within and among populations, and as a test of expected population structure from both invasion genetic theory, and the results from our previous study. 3. There was greater spatial differentiation, as measured by F_st, observed using AFLP's than for allozymes (P < 0.001). There was no evidence that AFLP variation conformed to an isolation by distance model, and genetic relationships of populations, as measured by AFLP markers, were not similar to those detected in our allozyme survey. 4. The lack of concordance between these two genetic marker systems probably reflects their differential responses to drift, migration, and selection occurring during this rapid invasion. Strong population structure is counter to predictions that populations of invasive species will not be differentiated, as with observations based on allozyme markers. Therefore, newly established species may require genetic surveys using multiple marker systems to evaluate population structure.     

Genetic diversity analysis in sorghum germplasm as estimated by AFLP, SSR and morpho-agronomical markers

A comparison of the different methods of the estimation of genetic diversity is important to evaluate their utility as a tool in germplasm conservation and plant breeding. Amplified fragment length polymorphism (AFLP), microsatellites or SSR and morphological traits markers were used to evaluate 45 sorghum germplasm for genetic diversity assessment and discrimination power. The mean polymorphism information content (PIC) values were 0.65 (AFLPs) and 0.46 (SSRs). The average pairwise genetic distance estimates were 0.57 (morphological traits), 0.62 (AFLPs) and 0.60 (SSRs) markers data sets. The Shannon diversity index was higher for morphological traits (0.678) than AFLP (0.487) and SSR (0.539). The correlation coefficients obtained by the Mantel matrix correspondence test, which was used to compare the cophenetic matrices for the different markers, showed that estimated values of genetic relationship given for AFLP and SSR markers, as well as for morphological and SSR markers were significantly related (p <0.001). However, morphological and AFLP data showed non-significant correlation (p >0.05). Both data sets from AFLP and SSR allowed all accessions to be uniquely identified; two accessions could not be distinguished by the morphological data. In summary, AFLP and SSR markers proved to be efficient tools in assessing the genetic variability among sorghum genotypes. The patterns of variation appeared to be consistent for the three marker systems, and they can be used for designing breeding programmes, conservation of germplasm and management of sorghum genetic resources.     

Genetic relatedness and genetic diversity of ornamental mei (Prunus mume Sieb. et Zucc.) as analysed by AFLP markers

The genetic diversity and genetic relatedness of mei (Prunus mume; 2n = 16) were studied using amplified fragment length polymorphism (AFLP) markers. Eight EcoRI–PstI AFLP primer combinations were applied to 121 distinct genotypes of mei cultivars and related species. A total of 508 AFLP product bands were produced, of which 382 were polymorphic. The unweighted pair group method with arithmetic averages analysis was carried out based on these AFLP markers. From this analysis, “Qugeng Mei,” “Yan Mei,” “Chaodou Mei,” and mei cultivars were seen to share the same P. mume genetic stem. The AFLP data were able to clearly discriminate P. mume from other species in the genus Prunus, with P. armeniaca aligning as its closest related species. Two major groups and nine subgroups of mei flower were identified, and there was a strong coincidence of these AFLP-based groupings with the respective morphological characters of the accessions. The genetic diversity of mei accessions was greatest in the Yunnan Province and decreased toward Eastern China and Japan, so supporting the hypothesis that the southwest of China represents the genetic diversity center of the species.     

The integration of mutant loci affecting maize endosperm development in a dense genetic map using an AFLP-based procedure

In this paper, 10 mutations conditioning the appearance of defective, miniature or collapsed endosperm, but with normal sporophyte development, were considered. Homozygous mutant kernels have reduced grain weight, kernel size, density and, in some of these, higher than normal seed protein content. The mutant loci were integrated into a high-resolution genetic map in order to associate them to specific genes. We have placed 1167 AFLP markers on a consensus map using IBM2 as a backbone and reaching an average of 1 marker every 1.9 cM. We have identified AFLP markers linked to all individual mutant alleles. BSA was adopted to screen the largest possible number of primer combinations on homozygous F₃ mutant and wild type plants. The ten mutant loci are linked to the closest AFLP or SSR markers with distances ranging from 0 to 17.9 cM. The genes we have defined by the existence of mendelian mutants can now be considered good candidates for testing the association to QT loci. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

DNA methylation and AFLP marker distribution in the soybean genome

Amplified fragment length polymorphisms (AFLPs) have become important markers for genetic mapping because of their ability to reliably detect variation at a large number of loci. We report here the dissimilar distribution of two types of AFLP markers generated using restriction enzymes with varying sensitivities to cytosine methylation in the soybean genome. Initially, AFLP markers were placed on a scaffold map of 165 RFLP markers mapped in 42 recombinant inbred (F_6:7) lines. These markers were selected from a map of over 500 RFLPs analyzed in 300 recombinant inbred (F_6:7) lines generated by crossing BSR101×PI437.654. The randomness of AFLP marker map position was tested using a Poisson-model distribution. We found that AFLP markers generated using EcoRI/MseI deviated significantly from a random distribution, with 34% of the markers displaying dense clustering. In contrast to the EcoRI/MseI AFLP markers, PstI/MseI-generated AFLP markers did not cluster and were under represented in the EcoRI/MseI marker clusters. The restriction enzyme PstI is notably sensitive to cytosine methylation, and these results suggest that this sensitivity affected the distribution of the AFLP markers generated using this enzyme in the soybean genome. The common presence of one EcoRI/MseI AFLP cluster per linkage group and the infrequent presence of markers sensitive to methylation in these clusters are consistent with the low recombination frequency and the high level of cytosine methylation observed in the heterochromatic regions surrounding centromeres. Thus, the dense EcoRI/MseI AFLP marker clusters may be revealing structural features of the soybean genome, including the genetic locations of centromeres. Received: 5 November 1998 / Accepted: 20 February 1999     

The uses of AFLP for detecting DNA polymorphism, genotype identification and genetic diversity between yeasts isolated from Mexican agave-distilled beverages and from grape musts

AIMS: The objectives were to determine the variability and to compare the genetic diversity obtained using amplified fragment length polymorphism (AFLP) markers in analyses of wine, tequila, mezcal, sotol and raicilla yeasts. METHODS AND RESULTS: A molecular characterization of yeasts isolated from Mexican agave musts, has been performed by AFLP marker analysis, using reference wine strains from Italian and South African regions. CONCLUSIONS: A direct co-relation between genetic profile, origin and fermentation process of strains was found especially in strains isolated from agave must. In addition, unique molecular markers were obtained for all the strains using six combination primers, confirming the discriminatory power of AFLP markers. SIGNIFICANCE AND IMPACT OF THE STUDY: This is the first report of molecular characterization between yeasts isolated from different Mexican traditional agave-distilled beverages, which shows high genetic differences with respect to wine strains.