共显性分子标记基因型数据转换为二元型数据的处理软件及其在研究种质资源遗传多样性中的意义

遗传多样性研究是植物种质资源有效利用和保护的重要基础.遗传多样性研究所采用的分子标记工具主要有显性和共显性两种,两种不同类型的分子标记将产生不同的数据类型.显性分子标记产生二元型数据,共显性分子标记产生基因型数据.数据形式不同给遗传多样性的分析和研究带来多方面的困难,不同类型数据之间的互相比较也需要将基因型数据进行二元型转换.本研究基于Excel平台,设计开发了将基因型数据转换成二元型数据的处理软件.该软件按照基因型数据向二元型数据转换的原理,可以将庞大的分子标记基因型数据矩阵,迅速、高效、准确地转换成二元型(0、1)数据矩阵.利用显性分子标记ISSR和共显性分子标记SSR对野生大豆居群遗传多样性的案例分析表明,将共显性分子标记的基因型数据转换为二元型数据,有利于种质资源遗传多样性研究中不同分子标记获取的遗传多样性结果之间的比较和综合分析.     

分子标记在食（药）用真菌遗传多样性研究中的应用

食（药）用真菌在经济和生态方面都具有重要意义,其遗传多样性研究是资源可持续利用和生物保护学研究的基础,有利于食（药）用真菌种质资源的收集、保存、评价和利用,也有助于其分类学、系统学及进化等的研究。遗传多样性的研究方法很多,分子标记是目前最常用最有效的方法之一。综合分析了分子标记在食（药）用真菌遗传多样性研究中的应用,比较了各种标记的应用范围、优缺点,探讨了分子标记用于食（药）用真菌遗传多样性评价的前景及问题。     

高粱遗传转化研究进展

高粱（Sorghum bicolor）是一种重要的多用途作物, 其遗传转化研究对于高粱的分子育种和分子遗传学基础研究都具有重要意义。该文对高粱遗传转化的方法、标记基因、遗传转化的启动子和受体系统进行了综述, 并提出了今后高粱遗传转化应当集中研究的问题。     

遗传标记及其在林木研究中的应用

遗传标记经历了形态标记、细胞学标记、生化标记和分子标记等4个阶段,其中分子标记的发展最为迅猛和有效。本文比较了几种主要分子标记方法的特点,为更好地利用分子标记提供了理论依据,并对分子标记在林木遗传多样性研究、遗传育种、DNA指纹图谱的构建、亲缘关系鉴定及分类研究等方面的应用做了介绍。     

葛根资源遗传多样性和性状关联分析

通过研究葛根资源的遗传多样性和葛根表型性状与分子标记的关联分析,为葛根的分子育种和指纹图谱构建提供理论依据。鉴定分析了127份不同来源葛根资源的10个表型性状,并用ISSR标记研究127份葛根资源的遗传多样性,对ISSR标记与表型性状进行关联分析。表型性状鉴定结果显示葛根资源的10个性状变异大、多样性较好。利用ISSR标记获得多态性条带109条,平均每个引物扩增5.73条、平均Nei's基因多样性0.2085、平均Shannon's指数0.3378,最远遗传距离为0.46。ISSR分子标记聚类分析将127份资源聚为两大类,群体结构分析和PCo A分析结果类似将127份资源分为2个亚群。GLM分析发现3个与茸毛性状关联标记,MLM分析未发现与表型性状关联的标记。本研究收集的资源遗传多样性较好,葛根分子标记聚类结果与地域关系不大,综合GLM和MLM关联分析结果,本试验未发现与表型关联位点。     

基于分型测序技术的粒用高粱遗传多样性和群体结构分析

了解粒用高粱的遗传多样性和群体结构,能有效提高粒用高粱新品种的选育效率。本研究利用基因分型测序技术(GBS,genotyping by sequencing)对120份粒用高粱材料开展了全基因组基因分型,共获得了3456个多态性的SNP标记,其多态性信息含量指数(PIC,polymorphism information content)介于0.013～0.574之间,平均值为0.381。根据SNP标记在120份高粱材料中的基因分型数据,计算了材料间的遗传距离,其变异范围为0.084～0.613,平均遗传距离为0.365。群体进化树分析和主成分分析都将120份高粱材料划分为3个类群,类群1主要由包括美国材料MN-3609在内的亲缘关系较远的高粱材料组成,类群2主要由中国北方的高粱材料组成,类群3主要由中国南方的高粱材料组成。群体结构分析表明,当K=3时,ΔK取得最大值,说明120份高粱材料可以划分为3个类群,其划分结果与群体进化树分析和主成分分析基本一致。本研究从基因型多样性水平上阐释了粒用高粱的遗传背景和群体结构,为中国粒用高粱新品种的选育提供了理论依据。     

分子标记在啤酒花种质资源研究中的应用

该论文利用分子生物学中常用的DNA分子标记对世界各地现存的野生和栽培的啤酒花种质资源遗传多样性研究的应用进展做一综述。通过查阅和研读20世纪90年代以来发表的各类文献进行归纳总结。发现DNA分子标记相比形态学标记和细胞学标记具有结果准确、稳定的特点,常用的分子标记技术有RAPD、RFLP、ISSR、SSR、AFLP、EST等;研究发现北美洲的啤酒花遗传多样性要高于欧洲的啤酒花,基因变异程度也相对较高;野生啤酒花的基因序列具有丰富的基因多样性,可在分子杂交遗传育种中作为一个种质去改善栽培品种的某些不良性状。因此,利用分子标记研究啤酒花的遗传多样性将对啤酒花的优良育种提供理论指导和技术支持,目前较为理想的技术是SSR和AFLP。     

鸡的遗传多样性的研究方法及研究进展

遗传多样性是生物学研究中的一个重要领域,研究鸡的遗传多样性,不仅能加强生物多样性的保护。同时对起源进化、分类鉴定及遗传育种等都有重要的意义。本文对目前DNA水平鸡的遗传多样性的研究方法和研究进展进行了详细的阐述。重点介绍了DNA分子标记的特征;概括了在鸡遗传多样性分子标记的方法,包括微卫星分子标记(SSR)、扩增片段长度多态性(AFLP)、随机扩增多态性标记(RAPD)、限制性片段长度多态性标记(RFLP)和单核苷酸多态性标记(SNP)。本文综述了最近有关鸡DNA水平的遗传多样性的研究方法在系统学、遗传结构、生物地理等研究中的应用情况;提出在研究鸡遗传多样性时,可根据研究的目的,选择合适的方法。     

松花型花椰菜主要品种鉴定的分子标记分析

利用RAPD、ISSR和SRAP 3种分子标记对我国南方地区松花型花椰菜主栽品种进行鉴定,分析了品种间的遗传多样性。3种标记共产生370条扩增带,238条为多态性条带,其多态率为64.32%。其中只有SRAP标记的引物m e1/em1可将20个品种全部鉴别。遗传相似系数分析表明,松花型花椰菜品种之间的亲缘关系较近,遗传背景比较狭窄。聚类分析表明品种间的亲缘关系与熟性、地理分布相关。研究表明,分子标记能有效地应用于花椰菜品种鉴定,且综合多种分子标记分析品种间的遗传多样性将更加准确可靠。     

分子标记在家畜遗传多样性研究中的应用

家畜遗传多样性是生物多样性的重要组成部分,与人类未来的生存与发展密切相关。中国拥有丰富的地方家畜品种资源,但由于保种不当和盲目引进外来品种进行杂交、资金缺乏等原因,许多品种已濒临灭绝。如何保存利用好我国优良的家畜遗传资源已成为越来越严峻的问题。随着生物学技术的不断发展与完善,许多分子标记技术已经应用于畜禽遗传资源的研究。简要介绍了在家畜遗传多样性研究中应用最广的几种分子标记及其特性,讨论了在家畜遗传多样性的研究中如何选用适当的分子标记。     

Assessment of genetic diversity and relationship among a collection of US sweet sorghum germplasm by SSR markers

Sweet sorghum (Sorghum bicolor L.) is a type of cultivated sorghums and has been recognized widely as potential alternative source of bio-fuel because of its high fermentable sugar content in the stalk. A substantial variation of sugar content and related traits is known to exist in US sweet sorghum. The objectives of the study were to assess the genetic diversity and relationship among the US sweet sorghum cultivars and lines using SSR markers and to examine the genetic variability within sweet sorghum accessions for sugar content. Sixty-eight sweet sorghum and four grain sorghum cultivars and lines were genotyped with 41 SSR markers that generated 132 alleles with an average of 3.22 alleles per locus. Polymorphism information content (PIC) value, a measure of gene diversity, was 0.40 with a range of 0.03–0.87. The genetic similarity co-efficient was estimated based on the segregation of the 132 SSR alleles. Clustering analysis based on the genetic similarity (GS) grouped the 72 sorghum accessions into 10 distinct clusters. Grouping based on clustering analysis was in good agreement with available pedigree and genetic background information. The study has revealed the genetic relationship of cultivars with unknown parentage to those with known parentage. A number of diverse pairs of sweet sorghum accessions were identified which were polymorphic at many SSR loci and significantly different for sugar content as well. Information generated from this study can be used to select parents for hybrid development to maximize the sugar content and total biomass, and development of segregating populations to map genes controlling sugar content in sweet sorghum.     

Genetic structure and diversity of wild sorghum populations (<Emphasis Type="Italic">Sorghum</Emphasis> spp.) from different eco-geographical regions of Kenya

Wild sorghums are extremely diverse phenotypically, genetically and geographically. However, there is an apparent lack of knowledge on the genetic structure and diversity of wild sorghum populations within and between various eco-geographical regions. This is a major obstacle to both their effective conservation and potential use in breeding programs. The objective of this study was to assess the genetic diversity and structure of wild sorghum populations across a range of eco-geographical conditions in Kenya. Sixty-two wild sorghum populations collected from the 4 main sorghum growing regions in Kenya were genotyped using 18 simple sequence repeat markers. The study showed that wild sorghum is highly variable with the Coast region displaying the highest diversity. Analysis of molecular variance showed a significant variance component within and among wild sorghum populations within regions. The genetic structure of wild sorghum populations indicated that gene flow is not restricted to populations within the same geographic region. A weak regional differentiation was found among populations, reflecting human intervention in shaping wild sorghum genetic structure through seed-mediated gene flow. The sympatric occurrence of wild and cultivated sorghums coupled with extensive seed-mediated gene flow, suggests a potential crop-to-wild gene flow and vice versa across the regions. Wild sorghum displayed a mixed mating system. The wide range of estimated outcrossing rates indicate that some environmental conditions may exist where self-fertilisation is favoured while others cross-pollination is more advantageous.     

Genetic diversity in sorghum (Sorghum bicolor (L.) Moench) accessions of Zambia as revealed by simple sequence repeats (SSR)

Twenty seven accessions of sorghum conserved in the national gene bank of Zambia, representing two of the three agroecological regions of the country, were investigated using simple sequence repeats (SSR) markers in order to determine the extent and distribution of its genetic diversity. We used 10 microsatellite primer-pairs, which generated 2-9 alleles per locus and a total of 44 alleles across the 27 accessions. The observed heterozygosity (Ho(P) ) among the accessions ranged from 0 to 0.19 with an average of 0.04 whereas the average expected heterozygosity (He(P) ) among accessions was 0.07 in line with the fact that sorghum is predominately inbreeder. The analysis of molecular variance (AMOVA) revealed that 82% of the total genetic variation was attributable to the genetic variation among accessions (F(ST) = 0.824; p < 0.001) whereas the genetic variation within accessions accounted for 18% of the total genetic variation. AMOVA on sorghum accessions grouped based on four ethnic groups (Soli, Chikunda, Lozi and Tonga) associated with collection sites revealed a highly significant variation among groups (23%; p < 0.001). Although cluster analysis grouped most accessions according to their sites of collection, some accessions that originated from the same site were placed under different clusters. In addition to the extent and pattern of genetic diversity, consideration should also be given to other factors such as ecogeographic and ethnic differences when sampling sorghum genetic resources for rational and efficient conservation and utilization in the breeding program.     

Assessment of genetic diversity among sorghum landraces and their wild/weedy relatives in western Kenya using simple sequence repeat (SSR) markers

Understanding the extent of gene exchange between cultivated sorghum and its wild/weedy relatives and the evolutionary processes (including farmers’ practices) that act to shape the structure of genetic diversity within and between them is an important aspect for germplasm conservation strategies, biosafety risk assessment, and crop improvement programs. In this study, molecular characterization and genetic diversity analyses were conducted on wild, weedy and cultivated sorghums collected at a local-scale in a traditional farming system in the Lambwe Valley of western Kenya. Nine simple sequence repeat (SSR) markers were used to genotype 294 cultivated sorghum and 200 wild sorghum individuals. The nine SSR markers were highly polymorphic with a number of alleles that varied from 2 to 19. Overall, wild sorghums had higher genetic diversity, observed heterozygosity, total number of alleles, polymorphic information content and more genotypes per locus than the cultivated types. A Mantel test demonstrated that there was significant isolation-by-distance for wilds and cultivated materials. STRUCTURE, cluster and principal coordinate analyses consistently assigned wild and cultivated individuals to different groups but failed to place hybrids/weedy types as a single separate group from wilds. Our results provide strong evidence of significant genetic diversity retained within wilds, larger divergence between wild and cultivated materials and reduced gene flow than those previously reported in Kenya. These results demonstrate the value of the Lambwe Valley region as a genetic reservoir and the importance to conduct genetic diversity studies at the local scale to design and execute appropriate in situ conservation programs and policies.     

Genetic diversity of elite sweet sorghum genotypes assessed by SSR markers

To determine genetic diversity among 47 elite sweet sorghum (Sorghum bicolor ssp. bicolor L.) genotypes, 46 simple sequence repeat (SSR) markers evenly distributed on all 10 chromosomes were selected. All SSR markers used were polymorphic among the genotypes studied. A total of 228 alleles were identified with an average of 4.96 alleles per marker. Furthermore, the genotypes studied showed medium genetic diversity. Clustering analysis grouped the 47 genotypes into 5 distinct clusters.     

Genetic diversity assessment in Somali sorghum (<Emphasis Type="Italic">Sorghum bicolor</Emphasis> (L.) Moench) accessions using microsatellite markers

In the north-western region of Somalia, bordering Ethiopia, sorghum represents an important resources for human and animal nutrition. The critical situation of Somalia is threatening the preservation of this valuable resource and it becomes urgent to develop a strategy of correct evaluation of the sorghum germplasm in order to promote conservation and preservation programs. Microsatellites, also known as Simple Sequence Repeats (SSRs), are reproducible molecular markers useful in assessing the level of genetic diversity of plants. A total of 5 sorghum SSR-specific primer pairs were used to assess the genetic diversity of Somali sorghum landraces. Extensive variation was found at the microsatellite loci analysed, except for a locus that resulted in a monomorphic for some accessions. Considerable differences were found between total and effective number of alleles indicating non uniform allele frequency. Moreover allele frequency at a single locus significantly changed among accessions. Total gene diversity calculated for each locus ranged from 0.44 to 0.79. Most of the genetic diversity occurred within accessions demonstrating that accessions are not under selection processes and/or there is a continuous exchange of genes between sorghum populations. In any case, the patterns of clustering were significantly affected by the presence/absence of some alleles with high discriminant weight. Accessions Carabi, Abaadiro, Masego Cas and Masego Cad represent distinct genotypes confirming finding observed in previous phenotypic studies. The results highlight the central role of local farmers in maintaining and shaping local germplasm.     

Restriction fragment variation in the nuclear and chloroplast genomes of cultivated and wild Sorghum bicolor

Summary Fifty-six accessions of cultivated and wild sorghum were surveyed for genetic diversity using 50 low-copy-number nuclear DNA sequence probes to detect restriction fragment length polymorphisms (RFLPs). These probes revealed greater genetic diversity in wild sorghum than in cultivated sorghum, including a larger number of alleles per locus and a greater portion of polymorphic loci in wild sorghum. In comparison to previously published isozyme analyses of the same accessions, RFLP analysis reveals a greater number of alleles per locus. Furthermore, many RFLP alleles have frequencies between 0.25–0.75, while the vast majority of isozyme alleles are either rare (< 0.25) or near fixation (> 0.75). Correlations between genetic and geographic distances among the accessions were stronger when calculated with RFLP than with isozyme data. Systematic relationships revealed by nuclear and chloroplast restriction site analysis indicate that cultivated sorghum is derived from the wild ssp. arundinaceum. The portion of the wild gene pool most genetically similar to the cultivars is from central-northeastern Africa. Previous published data also suggested that this is most likely the principal area of domestication of sorghum. Introgression between wild and cultivated sorghum was inferred from disconcordant relationships shown by nuclear and chloroplast DNA markers. Introgression apparently occurs infrequently enough that the crop and its wild relatives maintain distinct genetic constitutions.     

Niger-wide assessment of in situ sorghum genetic diversity with microsatellite markers

Understanding the geographical, environmental and social patterns of genetic diversity on different spatial scales is key to the sustainable in situ management of genetic resources. However, few surveys have been conducted on crop genetic diversity using exhaustive in situ germplasm collections on a country scale and such data are missing for sorghum in sub-Saharan Africa, its centre of origin. We report here a genetic analysis of 484 sorghum varieties collected in 79 villages evenly distributed across Niger, using 28 microsatellite markers. We found a high level of SSR diversity in Niger. Diversity varied between eastern and western Niger, and allelic richness was lower in the eastern part of the country. Genetic differentiation between botanical races was the first structuring factor (Fst = 0.19), but the geographical distribution and the ethnic group to which farmers belonged were also significantly associated with genetic diversity partitioning. Gene pools are poorly differentiated among climatic zones. The geographical situation of Niger, where typical western African (guinea), central African (caudatum) and eastern Sahelian African (durra) sorghum races converge, explained the high observed genetic diversity and was responsible for the interactions among the ethnic, geographical and botanical structure revealed in our study. After correcting for the structure of botanical races, spatial correlation of genetic diversity was still detected within 100 km, which may hint at limited seed exchanges between farmers. Sorghum domestication history, in relation to the spatial organisation of human societies, is therefore key information for sorghum in situ conservation programs in sub-Saharan Africa. Electronic supplementary material The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Genetic diversity among elite Sorghum lines revealed by restriction fragment length polymorphisms and random amplified polymorphic DNAs

The genetic diversity of sorghum, as compared to corn, is less well characterized at the genetic and molecular levels despite its worldwide economic importance. The objectives of this study were to: (1) investigate genetic diversity for restriction fragment length polymorphism (RFLPs) and random amplified polymorphic DNAs (RAPDs) in elite sorghum lines, (2) compare similarities based on molecular markers with pedigree relationships, and (3) examine the potential of RFLPs and RAPDs for assigning sorghum lines to the A/B (sterile) and R (restorer) groups. Using four restriction enzymes, polymorphism was detected with 61% of the RFLP probes used, compared to 77% of the random primers. One hundred and sixteen (64%) probe-enzyme combinations yielded multiple-band profiles compared to 98% of the random primers. RFLP profiles generated 290 polymorphic bands compared to 177 polymorphic RAPDs. Pair-wise comparisons of polymorphic RFLPs and RAPDs were used to calculate Nei and Jaccard coefficients. These were employed to generate phenograms using UPGMA and neighborjoining clustering methods. Analysis of RFLP data with Jaccard's coefficient and neighbor-joining clustering produced the phenogram with the closest topology to the known pedigree.Contribution of the College of Agricultural Sciences, Texas Tech University, Journal No. T-4-365     

Assessing population genetic structure of sorghum landraces from North-western Morocco using allozyme and microsatellite markers

 The level of genetic diversity and the population genetic structure of sorghum landraces from North-western Morocco have been investigated based on direct field-sampling using both allozyme and microsatellite markers. As expected, microsatellite markers showed a much higher degree of polymorphism than allozymes, but relative measures of genetic structure such as Wright’s inbreeding coefficient F _IS and Nei’s coefficient of genetic differentiation G _ST were similar for the two sets of markers. Substantial inbreeding was found to occur within fields, which confirms that sorghum is predominantly selfing under cultivation. Most of the genetic diversity in Moroccan landraces occurs within fields (more than 85%), as opposed to among fields or among regions, a result which contrasts to those of studies based on accessions from germplasm collections. It is suggested that individual fields of sorghum constitute valuable units of conservation in the context of in situ conservation practices. Received: 8 December 1998 / Accepted: 28 December 1998