7个品种变叶木过氧化物酶同工酶分析

本试验对7个品种变叶木的形态特征进行比较,并利用聚丙烯酰胺凝胶电泳,对各品种过氧化物酶同工酶进行分析。结果表明,各品种的过氧化物酶同工酶谱不一;7个品种变叶木共有14条谱带,2号谱带最多为11条,5号谱带最少为6条;其谱带分为3个区(A=0~0.18,B=0.18~0.35,C=0.35~0.5);并对7个品种的亲缘关系进行聚类分析。     

我国西北春麦区小麦育成品种遗传多样性的AFLP分析

对我国西北春麦区56份小麦育成品种应用扩增片段长度多态性(Amplified Fragment Length Polmorphics,简称AFLP)分子标记技术进行遗传多样性分析。共用24对引物组合进行扩增,每对引物组合的平均多态性条带为14．7,多态性百分率为24．4,而多态性信息指数PIC范围为0．11～0．44,平均0．22。结合品种的系谱亲缘关系分析,得知依据AFLP数据的类群划分结果与品种的亲缘系谱关系基本一致,表明AFLP技术用于种质鉴定和遗传多样性研究是有效的、可取的;同时。对如何合理应用AFLP数据中的多态性带和共有带进行聚类分析,及如何正确对待小麦核心种质构建中的形态和农艺性状数据与分子数据的问题作了进一步的探讨。仅用多态性谱带产生的相似系数矩阵与用所有扩增谱带产生的相似系数矩阵之间的相关系数r=0．86,表明在利用AFLP进行品种间遗传关系分析时,利用所有扩增产物的信息是必要的;如果仅仅是为了鉴剐品种或压缩样品,完全可以只考虑多态性扩增产物。利用AFLP分子数据和田间数据对56份材料进行主成分分析(PCO),发现用田间数据产生的PCO图,材料之间分散,遗传关系不很明了,进一步压缩样品难度较大;而分子数据产生的PCO图,可将材料分成明显的五类,聚类结果与品种系谱基本相吻合,为进一步压缩样品提供了科学依据。形态数据与分子数据聚类的结果差异较大,相关系数仅为0．310因此,在利用田间数据的基础上,必须兼顾和利用DNA数据,才能保证所建立核心种质的代表性。这也是一条比较科学、经济和可行的途径。     

SSR水平上甘、青两省春小麦品种间的遗传多样性现状及演变趋势

利用22对SSR引物的扩增结果计算品种间的Jaccard相似系数,在此基础上用UP(GMA方法进行了聚类分析,检测了43个春小麦品种间在DNA水平上的遗传变异。22对引物共扩增出102条多态性带,平均每对引物可扩增出4．64条多态性带,具有较好的多态性。SSR水平上43个品种间遗传距离变异范围为0.2222～0.8393,平均遗传距离GD％=0．6055。43个品种聚为两大类,除佛手麦自成一类外,其余42个品种聚为第二大类。聚类结果真实地反映了品种间基因型差异。历史上地方品种间SSR水平上的遗传变异最大,育成品种遗传多样性水平总体上呈下降趋势,且低于地方品种和引进品种。1BL／1RS易位片段特异性引物Rye检测结果显示,共有7个品种含有1RS片段,结果需进一步证实和深入研究。     

蚕豆种质资源清蛋白遗传多样性分析?

利用SDS-PAGE对101份蚕豆种质资源进行了清蛋白遗传多样性分析,共检测出蛋白带2625条。除共有带外,迁移率不同的谱带类型36种,其中相对分子量为92kD、75kD、62kD、40kD、34kD、17kD、13kD的谱带在检测的种质材料中出现的频率最高,分别为92.08%、90.10%、99.01%、95.05%、95.05%、98.02%、95.05%。其余29种谱带类型具有较强的多态性,多态性谱带平均为16.09条,多态性比例为44.69%。每份种质材料的清蛋白谱带数介于21～31条之间,平均25.99条;供试种质间遗传相似系数0.6111～0.9722,平均0.7122。3个地理类群内多样性指数0.9879,类群间多样性指数0.0121,表明蚕豆清蛋白的变异主要来源于类群内。聚类分析将参试种质分为6类,与以往蚕豆种质分类研究结果类似,表明清蛋白能在一定程度上反映种质间的亲缘关系。研究结果对于蚕豆蛋白质品质育种具有一定的参考价值。     

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。     

应用RAPD标记分析黑麦属品种的遗传多样性

四川农业大学小麦研究所侯永翠、郑有良、魏育明等研究人员对黑麦遗传多样性课题作了研究。他们采用随机扩增多态性DNA(RAPD)标记 ,对黑麦属 (SecaleL) 7个品种共 1 2份材料进行了遗传多样性检测 ,发现被检测材料间RAPD标记多态性较高 ,在 4 0个随机引物中 ,有 2 5个引物约占整个的 6 2 .5 %的扩增产物具有多态性。这 2 5个中共扩增出 1 6 7条带 ,其中 89条带约占 5 3.2 %具有多态性 ,每个引物可扩增出 1～ 1 0条多态性带 ,平均为 3～ 6条。RAPD标记遗传距离GD变异范围为 0 .1 382～ 0 .4 5 1 2 ,平均为 0 .2 71 2。通过聚类分析表…     

SRAP技术研究烟粉虱遗传多样性

采用AFLP、SRAP2种标记方法分别对2个烟粉虱Bemisia tabaci Gennadius种群(一品红、甘蓝)的多态性进行分析。结果表明,(1)2种方法平均每对引物组合产生的条带数分别为29.4和21.8。(2)AFLP法每对引物组合产生10～23条多态性带,平均17.20条,多态性带的比例平均为57.93%。SRAP法每对引物组合产生5～18条多态性带,平均13.3条,多态性带的比例平均为60.59%。(3)前者的基因多样性范围为0.1503～0.2838,平均为0.2297;后者的基因多样性范围为0.0977～0.2911,平均为0.2332。证明利用SRAP技术和AFLP技术研究烟粉虱的遗传多样性是有效的。     

用AFLP分析广东省鲜食橄榄品种资源遗传多样性

从64对引物组合中筛选出6对谱带清晰、多态性高的引物组合,对63个橄榄品种扩增,共扩增出417条多态性电泳谱带,多态性比率达100%,揭示了橄榄品种的遗传多样性。利用UPGMA对供试橄榄品种聚类,建立AFLP聚类图。结果表明:63份材料之间的遗传相似性系数为0.0606~0.7619,相似系数为0.312时,可将供试材料分为7个品种群,其中第1群包括45个品种,以‘潮阳甜榄’为代表,还可细分成3个组;第2群包括5个品种,以‘大纳甜’为代表;第3群包括4个品种,以‘潮阳三棱’为代表;第4群包括‘土甜’、‘文祠三棱’和‘早花三棱’3个品种;第5群包括‘铁条’和‘细粒’两个品种;第6群包括‘广太甜种’、‘西土’、‘鸡心’和‘车酸1号’4个品种;第7群只有‘凤湖橄榄’1个品种,与其他品种群亲缘关系较远,可能发生变异。     

用AFLP技术分析四川核桃资源的遗传多样性

 利用AFLP分子标记技术, 运用EcoRⅠ/MseⅠ双酶切组合, 选用多态性高、分辨力强的4对选择性扩增引物组合E32/M48、E33/M61、E35/M61、E33/M62分别对四川省3个野生核桃(Juglans regia)种群和1个野生铁核桃(J. sigillata)种群共46个样品进行遗传多样性分析、居群遗传结构分析及种属关系探讨。结果表明: 1)共扩增出244个遗传位点, 其中146个多态位点, 多态率为59.84%; 核桃群体组和铁核桃群体的多态性百分率分别为55.33%和52.05%, 两个物种遗传多态性水平相当; 核桃群体组所检出的位点平均有效等位基因数Ae、Nei’s基因多样度H、平均Shannon信息指数I分别为1.322 9、0.190 8和0.286 3, 而铁核桃群体分别为1.339 9、0.196 1和0.289 8, 铁核桃群体遗传多样性水平略高于核桃群体。2)群体间特异带及群体间共有带占总扩增带数的15.16%, 其中铁核桃群体特异谱带最多, 群体特异谱带揭示了群体间的遗传差异及相似性。3) Shannon信息指数(I)、Nei’s基因多样性指数(H)和分子方差分析(AMOVA)表明核桃遗传多样性在群体间和群体内的分布分别为14.36%和85.64%、12.6%和87.4%、11.07%和88.93%, 表明群体内的遗传多样性大于群体间的遗传多样性; 核桃群体组与铁核桃群体的变异主要存在于群体组内, 组间的遗传变异仅占总变异的9.35%, 两者间的遗传分化系数Gst为0.093 5, 与AMOVA分析结果一致。4) 4个群体的Nei’s遗传距离在0.038 2～0.069 2之间, 遗传一致度在0.933 2～0.962 5之间, 表现出较高的遗传相似性; 运用Nei’s遗传一致度对供试种群进行了UPGMA聚类, 结果表明核桃的3个群体优先聚类, 大渡河流域群体与甘南地区群体聚类最近。AFLP所检测出的结果既是核桃与铁核桃生物学特性的反映, 又是其各自生态学特性的反映, 该研究结果对核桃种质资源的保护和育种提供一定的理论依据。     

秦巴山区野板栗居群遗传多样性AFLP分析

利用荧光AFLP标记技术对来自秦巴山区的野板栗10个居群共262个单株进行遗传多样性研究.10对AFLP引物共扩增出1297条谱带,其中多态性位点数1011个,多态位点百分率为77.95%;Nei's基因多样性指数为0.1439～0.2046,总体为0.2518;Shannon信息指数的变异范围为0.1972～0.2895,总体为0.4089;甘肃地区野板栗居群遗传多样性水平最高,陕西宝鸡居群的遗传多样性水平最低.AMOVA分析表明野板栗居群闻的遗传变异占总变异的17.51%,居群内变异占69.76%.UPGMA聚类可将供试10个居群划分为3类,聚类结果表现出明显的地域性.     

家蚕AFLP连锁框架图谱的构建

利用改进的AFLP分子标记方法,对家蚕Bombyx mori回交一代BC1群体进行连锁图谱的构建。经17组AFLP引物的选择性扩增,共得到430个多态位点,卡方检验后有253个为有效位点。利用Mapmaker/Exp (Version 3.0b)软件作连锁分析,其中163个标记分属28个连锁群,连锁群标记数变化范围是2～28个,平均每个连锁群标记数为5.8个,该图覆盖的基因组长度为2.998.9cM(图距单位),连锁群长度变化范围为4.5～652.8 cM,连锁群的平均长度为107.1 cM,平均图距为4.5～36.7 cM。     

漆树品种的AFLP分析及评价(简报)

漆树(Toxicodendron vernicifluum(stokes)F.A.Barkley)隶属于漆树科(Anacardiaceae)漆树属(Tox- icodendron)的落叶乔木,是我国重要的特用经济林木。漆树栽培与生漆使用在我国已有几千年的历史,在长期栽培过程中形成了许多农家品种,它们具有一定的形态特点,适应一定的生长环境,并具有产漆量高、生漆品质好等特性。     

Molecular Analysis of Chickpea (Cicer arietinum L) Cultivars Using AFLP and STMS Markers

Fifteen AFLP and eighteen STMS primer pairs were employed to reveal genetic diversity and relationship in twenty-one cultivars of chickpea (Cicer arietinum L). Fifteen AFLP primer pairs generated 1804 amplicons, out of which 1732 amplicons (96%) were polymorphic and 600 amplicons (∼33%) were genotype specific. Eighteen polymorphic STMS primer pairs generated 64 amplicons with an average of 3.55 amplicons per primer pair. Polymorphic information content (PIC) varied from 0.52 to 1.0 for STMS markers. The genetic similarity between cultivars varied from 0.30 to 0.85 for AFLP and 0.22 to 0.83 for STMS markers. Dendrogram constructed after combining both AFLP and STMS markers data with Bootstrap analysis, grouped all the cultivars into four clusters. Association of varietal type and flower colour was observed as cultivars E 100Ymu and Nabin (Both Desi type and pink flower) clustered together in the dendrogram.     

Evaluation of AFLPs for germplasm fingerprinting and assessment of genetic diversity in cultivars of tomato (Lycopersicon esculentum L.).

Cultivated tomato (L. esculentum L.) germplasm exhibits limited genetic variation compared with wild Lycopersicon species. Amplified fragment length polymorphism (AFLP) markers were used to evaluate genetic variation among 74 cultivars, primarily from California, and to fingerprint germplasm to determine if cultivar-specific patterns could be obtained. All 74 cultivars were genotyped using 26 AFLP primer combinations; of the 1092 bands scored, 102 AFLP bands (9.3%) were polymorphic. Pair-wise genetic similarity coefficients (Jaccard and Nei-Li) were calculated. Jaccard coefficients varied from 0.16 to 0.98 among cultivar pairs, and 72% of pair-wise comparisons exceeded 0.5. UPGMA (unweighted pair-group method with arithmetic averaging) clustering and principle component analysis revealed four main clusters, I-IV; most modern hybrid cultivars grouped in II, whereas most vintage cultivars grouped in I. Clusters III and IV contained three and two cultivars, respectively. Some groups of cultivars closely related by pedigree exhibited high bootstrap values, but lower values (<50%) were obtained for cluster II and its four subgroups. Unique fingerprints for all 74 cultivars were obtained by a minimum of seven AFLP primer pairs, despite inclusion of some closely related cultivars. This study demonstrated that AFLP markers are effective for obtaining unique fingerprints of, and assessing genetic diversity among, tomato cultivars.     

Establishment of AFLP technique and assessment of primer combinations for mei flower

Mei flower is one of the most famous ornamental flowers in eastern Asia for its blossoming in early spring. Amplified fragment length polymorphism (AFLP) is one of the most frequently used techniques for analysis of genetic variation and is used herein for the first time inPrunus mume. This research provides a detailed and modified AFLP protocol for Mei genomic DNA digested withEcoRI/PstI restriction endonuclease combinations. The 10 best primer pairs of high polymorphism were screened from 256 primer combinations that could reliably and repetitively distinguish 14 Mei samples and would be suitable for genetic analysis of more cultivars. Ten primer pairs produced up to a total of 524 AFLP bands and up to 233 polymorphic bands. The ratio of polymorphic bands scoped from 35.71% to 59.67%, and the average ratio was 44.46% in the 10 primers. AFLP is an effective, inexpensive, and timesaving technique for the genetic differentiation of the Mei cultivars, as evidenced in this study.     

Molecular AFLP-marking of genotypes of pepper (Capsicum annuum) cultivars

The results of AFLP study of 14 Capsicum annuum cultivars are presented. Notwithstanding the known low genomic variation of large-fruited sweet pepper, AFLP analysis proved to be suitable for detecting polymorphism and genotyping pepper cultivars. Nine primer pairs were selected to allow identification of the cultivars under study. Among-cultivar polymorphism detectable with these primers was estimated at 16.5%. A characteristic AFLP pattern was obtained for each cultivar. Several cultivar-specific fragments were revealed for seven cultivars. On the basis of the AFLP data, genetic distances between cultivars were computed and a tree was constructed by means of hierarchic cluster analysis (UPGMA) with the Jacquard coefficient. It was assumed that this information is useful in breeding programs involving the cultivars examined.     

Comparison of the volatile components of some mango cultivars

Three cultivars of mango from Sri Lanka (Jaffna, Willard and Parrot) were analysed for their volatile aroma components. The total concentrations of volatiles obtained were ca 251, 422 and 628 μg per kg of fresh fruit, respectively. Terpenes were the main volatiles of all three cultivars, with monoterpene hydrocarbons contributing 50–63 % w/w of the total volatiles and sesquiterpene hydrocarbons 14–19 %. Whilst the major volatile of Jaffna mango was cis-β-ocimene (38 %), α-terpinolene was the major volatile of the other two cultivars (32 % and 35 %). Esters were produced by all cultivars (2–16 %), Jaffna yielding most, the majority being unsaturated (12 %). Willard mango gave particularly high levels of non-terpene hydrocarbons (19 %), including a range of six long-chain alkanes (8 %), not detected in the other cultivars.     

Molecular AFLP Analysis of the Genotypes of Pepper Capsicum annuum Cultivars

The results of AFLP study of 14 Capsicum annuum cultivars are presented. In spite of the known low genomic variation of large-fruited sweet pepper, AFLP analysis proved to be suitable for detecting polymorphism and genotyping pepper cultivars. Nine primer pairs were selected to allow identification of the cultivars under study. Among-cultivar polymorphism detectable with these primers was estimated at 16.5%. A characteristic AFLP pattern was obtained for each cultivar. Several cultivar-specific fragments were revealed for seven cultivars. On the basis of the AFLP data, genetic distances between cultivars were determined and a tree was constructed by means of hierarchic cluster analysis (UPGMA) with the Jacquard coefficient. It was assumed that this information is useful in breeding programs involving the cultivars examined.     

Identification of molecular markers in soybean comparing RFLP,RAPD and AFLP DNA mapping techniques

Three different DNA mapping techniques—RFLP, RAPD and AFLP—were used on identical soybean germplasm to compare their ability to identify markers in the development of a genetic linkage map. Polymorphisms present in fourteen different soybean cultivars were demonstrated using all three techniques. AFLP, a novel PCR-based technique, was able to identify multiple polymorphic bands in a denaturing gel using 60 of 64 primer pairs tested. AFLP relies on primers designed in part on sequences for endonuclease restriction sites and on three selective nucleotides. The 60 diagnostic primer pairs tested for AFLP analysis each distinguished on average six polymorphic bands. Using specific primers designed for soybean fromEco RI andMse I restriction site sequences and three selective nucleotides, as many as 12 polymorphic bands per primer could be obtained with AFLP techniques. Only 35% of the RAPD reactions identified a polymorphic band using the same soybean cultivars, and in those positive reactions, typically only one or two polymorphic bands per gel were found. Identification of polymorphic bands using RFLP techniques was the most cumbersome, because Southern blotting and probe hybridization were required. Over 50% of the soybean RFLP probes examined failed to distinguish even a single polymorphic band, and the RFLP probes that did distinguish polymorphic bands seldom identified more than one polymorphic band. We conclude that, among the three techniques tested, AFLP is the most useful.     

Assessment of genetic variation withinBrassica campestris cultivars using amplified fragment length polymorphism and random amplification of polymorphic DNA markers

Genetic relationships were evaluated among nine cultivars ofBrassica campestris by employing random amplification of polymorphic DNA (RAPD) and amplified fragment length polymorphism (AFLP) markers. RAPDs generated a total of 125 bands using 13 decamer primers (an average of 9.6 bands per assay) of which nearly 80% were polymorphic. The per cent polymorphism ranged from 60–100%. AFLP, on the other hand generated a total of 319 markers, an average of 64 bands per assay. Of these, 213 were polymorphic in nature (66.8%). AFLP methodology detected polymorphism more efficiently than RAPD approach due to a greater number of loci assayed per reaction. Cultivar-specific bands were identified, for some cultivars using RAPD, and for most cultivars with AFLP. Genetic similarity matrix, based on Jaccard’s index detected coefficients ranging from 0.42 to 0.73 for RAPD, and from 0.48 to 0.925 for AFLPs indicating a wide genetic base. Cluster analyses using data generated by both RAPD and AFLP markers, clearly separated the yellow seeded, self-compatible cultivars from the brown seeded, self-incompatible cultivars although AFLP markers were able to group the cultivars more accurately. The higher genetic variation detected by AFLP in comparison to RAPD was also reflected in the topography of the phenetic dendrograms obtained. These results have been discussed in light of other studies and the relative efficiency of the marker systems for germplasm evaluation.