附子野生资源群体遗传多样性的RAPD分析

应用RAPD标记分析了分布在附子主栽区四川、重庆、陕西及湖北16个野生乌头种群的遗传变异。24个引物共检测到643个RAPD位点,多态位点602个,总的多态位点百分率达93．5％。Shannon多样性和Nei遗传分化结果一致显示重庆酉阳种群和重庆城口种群遗传多样性最高,四川盐源种群和陕西勉县种群的遗传多样性最低。Shannon指数测出的种群内的遗传变异（57．6％）略占优势,群体间的遗传分化达到42．4％;Nei基因分化系数（GST）达40．0％;分子方差分析（AMOVA）发现群体间遗传变异仅为25．37％;种群每代迁移数Nm为0．756。Nei相似性系数的UPGMA分析结果显示该地区的野生乌头分布上有一定的地域性,特别是同为附子道地产地江油供种的北川、安县和青川种群间遗传关系密切,说明种质资源在道地药材形成中具有重要作用。研究结果表明,附子主要栽培地区的乌头野生种群之间存在较大的遗传分化,遗传多样性较高,遗传种质资源较丰富,存在一定的特异性资源,为进一步开发利用乌头（川乌、附子）提供了丰富的种质资源。     

芽孢杆菌TS02特异RAPD标记的SCAR标记转化和验证

利用自主分离的蜡状芽孢杆菌菌株TS02, 采用RAPD方法对TS02及其同源性相近的5株芽孢杆菌(地衣芽孢杆菌、枯草芽孢杆菌、凝结芽孢杆菌、巨大芽孢杆菌、短小芽孢杆菌) 进行了RAPD条带特异性分析, 从TS02基因组中筛选获得了一个533 bp的特异RAPD标记TSR1。TSR1克隆、测序后, 根据其序列设计出一对特异引物P1/P2进行扩增, 结果只在TS02中扩增得到目的片段, 而其余对照菌株扩增为阴性, 从而证明试验得到了在种水平上对该菌种进行准确鉴定的特异SCAR标记。     

基于RAPD的群体标记法分析苜蓿种质遗传多样性

苜蓿种质资源的分子遗传多样性分析对于种质资源保存和育种利用具有重要指导意义。本研究选用群体标记法对来自甘肃省的16个苜蓿品种的DNA进行RAPD扩增,旨在研究其遗传多样性,并在此基础上筛选品种特异性引物用于进一步的品种鉴定。依据16个苜蓿品种间的Roger’s遗传距离进行UPGMA聚类分析结果显示,品种间亲缘关系与其选育背景紧密相关,供试的16个品种被划为4个类群,其中,匍匐型品种Jindera与其他直立型品种差异显著,自成1个类群,引进品种和甘肃省内具有国外种质来源的育成品种被划为同1类群,而甘肃地方品种聚为2个类群。10个RAPD引物中有4个引物OPE4、OPE5、OPE6和OPE7分别检测到5个品种甘农3号、甘杂27、Jindera、陇东和Algonuin的特异性条带,可进一步用于开发设计特异性引物进行品种鉴定工作。以上结果进一步证实,利用RAPD标记研究苜蓿系谱发育关系和选择杂交亲本应采用群体标记法。     

大麻性别的RAPD和SCAR分子标记

利用随机扩增多态性DNA（random amplified polymorphic DNA,RAPD)技术获得与大麻性别连锁的分子标记,将10株雄性大麻或10株雌性麻的单个DNA样品等量混合分别组成雄性或雌性DNA池（DNApool),以提供具有相同遗传背景的雄,雄性DNA样品。每个随机引物分别用三个不同的循环程序进行PCR扩增,在30个随机引物中,用引物S401扩增得到一条约2．5kb雄性多态性片段,对该片段进行了克隆和序列分析 ,并根据序列分析结果将上述RAPD分子标记转化为重复性和特异性更好的SCAR（Sequence characterized amplified regions)分子标记。     

水稻苯达松敏感致死基因的RAPD标记和SCAR标记

利用RAPD技术对水稻品种农林 8号 (含苯达松抗性基因Ben)和其突变体农林 8号m (含苯达松敏感致死基因ben)进行标记 ,从 36 0个 10bp寡核苷酸随机引物中筛选出 5个引物产生的 7个RAPD标记。经对多态性标记的克隆和序列分析 ,再设计PCR引物 ,将其中 4个RAPD标记OPG18/ 94 3、OPG18/ 972、OPD10 / 12 4 8和OPF0 3/ 1198转化成SCAR标记SCAR/G18/ 883、SCAR/G18/ 890、SCAR/G18/ 919/ 94 8、SCAR/D10 / 12 37、SCAR/F0 3/ 1186。通过对农林 8号×农林 8号mF2 分离群体 32 0个单株的连锁分析及在 1对含ben基因的近等基因系H12 1和Hben12 1中验证 ,标记SCAR/G18/ 883、SCAR/G18/ 890、SCAR/G18/ 919/ 94 8与Ben或ben基因共分离 ,SCAR/D10 / 12 37与Ben基因的遗传距离为 (14 .8± 2 .1)cM。经Southernblotting分析并结合F2 代分离比例表明 ,标记OPG18/ 94 3、OPG18/ 972及其转化的SCAR标记在基因组中为单拷贝序列 ,且OPG18/ 94 3和OPG18/ 972为一对等位STS位点。这是首次报道与ben或Ben基因相连锁的分子标记。本研究为利用分子标记辅助ben基因的转育及利用图位克隆技术分离ben基因提供了有用的分子标记。     

利用RAPD标记评价小豆种质遗传多样性

本研究利用10个RAPD引物对180份小豆种质的基因组DNA进行扩增,共扩增出44条带,其中35条具有多态性,比例为79．5％,平均每个引物扩增出3．5条多态性带;平均遗传距离为0．274,变异幅度为0．05－0．60,平均遗传多样性指数为0．692;基于RAPD标记,把180份小豆种质聚类划分为4个组群,该组群的划分与小豆的生态地域性似乎不存在明显的相关性。     

利用RAPD标记分析大麦种质资源的遗传多样性

利用RAPD标记对19份西藏近缘野生大麦材料、33份我国不同省市的地方品种以及8份国外引进大麦品种共60份大麦种质资源的遗传多样性进行检测.结果表明材料间遗传差异明显.32个RAPD引物中,有25个引物(占78.13%)可扩增出清晰且具多态性的条带,另外7个引物能扩增出1～3条清晰但无多态性的条带.每个引物可扩增出1～8条多态性带,平均为3.72条.32个引物共产生119条DNA片段,其中87条具有多态性,多态性比率(PPB)为73.11%,平均多态信息量(PIC)为0.434;每个位点平均有效等位基因数(Ne)为2.304;材料间遗传相似系数GS变化范围为0.757～0.981,平均值为0.871.19份来源于西藏的近缘野生大麦材料间GS值变幅为0.818～0.969,平均为0.892;33份我国栽培大麦地方品种间的GS值变化范围为0.783～0.981,平均为0.879;8份分别来自8个国家的栽培大麦品种间的GS值变幅为0.820～0.956,平均为0.882.根据RAPD标记分析的结果,对60份大麦种质资源进行聚类分析,在平均GS值0.871水平上60份大麦材料可聚为5类,聚类结果能在一定程度上反应材料的地理分布关系,但某些相同地理来源的材料也较分散地分布在整个聚类树中.本研究从分子水平上进一步证明了我国栽培大麦丰富的遗传多样性,是世界栽培大麦的遗传多样性中心之一.     

利用RAPD标记分析北美鹅掌楸与鹅掌楸种间遗传多样性

利用ＲＡＰＤ标记技术对鹅掌楸属（Ｌｉｒｉｏｄｅｎｄｒｏｎ Ｌ．）２个现存种鹅掌楸（Ｌｉｒｉｏｄｅｎｄｒｏｎ ｃｈｉｎｅｎｓｅ （Ｈｅｍｓｌ．）Ｓａｒｇ）和北美鹅掌楸（Ｌｉｒｉｏｄｅｎｄｒｏｎ ｔｕｌｉｐｉｆｅｒａ ｌｉｎｎ．）的遗传多样性进行分析,结果表明：２个种都有较高的遗传多样性,但北美鹅掌楸的遗传多样性水平高于鹅掌楸;鹅掌楸的遗传变异主要来自地理种源内,而北美鹅掌楸的遗传变异主要来自地理种源     

大麻性别的RAPD和SCAR分子标记

利用随机扩增多态性DNA(randomamplifiedpolymorphicDNA,RAPD)技术获得与大麻性别连锁的分子标记.将10株雄性大麻或10株雌性大麻的单个DNA样品等量混合分别组成雄性或雌性DNA池(DNApool),以提供具有相同遗传背景的雌、雄性DNA样品.每个随机引物分别用三个不同的循环程序进行PCR扩增.在30个随机引物中,用引物401扩增得到一条约2.5kb雄性多态性片段.对该片段进行了克隆和序列分析,并根据序列分析结果将上述RAPD分子标记转化为重复性和特异性更好的SCAR(sequencecharacterizedamplifiedregions)分子标记.     

南蛇藤雌性性别相关的RAPD和SCAR标记

南蛇藤(Celastrus orbiculatus Thunb)属卫矛科南蛇藤属落叶藤本植物,是中国传统中药材,雌雄异株,少量雄全同株。由于目前在分子水平上对南蛇藤性别差异的研究较少,极大地限制了对其的开发利用。本研究利用RAPD分子标记对南蛇藤雌株、雄株和雄全同株进行了差异比较。100个引物中有5个引物(S127、S140、S148、S174及S111)在不同性别南蛇藤的基因组DNA中扩增到存在明显差异的条带。根据序列分析的结果将RAPD引物转化成特异性较强的SCAR引物后,仅引物S111扩增出一条雌性特异性条带。序列分析发现,该片段包含两个超过100个氨基酸的开放阅读框,其功能有待进一步的研究。     

短沟对虾两个野生群体遗传多样性的RAPD分析

利用RAPD标记技术检测了厦门和汕头沿海2个短沟对虾群体基因组DNA的多态性,并对其遗传多样性进行了分析。从40条随机引物中筛选出13个10bp引物。共扩增出65条清晰可重复的DNA片段,片断长度为100—2200bp,在2个群体间没有检测到特异的片段。厦门和汕头群体的多态片段比例分别为87．69％和89．23％,杂合度分别为0．212和0．218,遗传多样性指数分别为0．2847和0．2913,两群体间的遗传距离为0．018,FST值为0．004。可见两野生群体种质资源仍然维持在良好水平,遗传分化程度很低,可能是同一种群,具有进一步开发的潜力。     

Analysis of genetic diversity in red clover (Trifolium pratense L.) breeding populations as revealed by RAPD genetic markers.

Red clover is an important forage legume species for temperate regions and very little is known about the genetic organization of its breeding populations. We used random amplified polymorphic DNA (RAPD) genetic markers to address the genetic diversity and the distribution of variation in 20 breeding populations and cultivars from Chile, Argentina, Uruguay, and Switzerland. Genetic distances were calculated for all possible pairwise combinations. A high level of polymorphism was found and the proportion of polymorphic loci across populations was 74.2%. A population derived from a non-certified seedlot displayed a higher proportion of polymorphic loci than its respective certified seedlot. Gene diversity values and population genetics parameters suggest that the populations analyzed are diverse. An analysis of molecular variance (AMOVA) revealed that the largest proportion of variation (80.4%) resides at the within population level. RAPD markers are a useful tool for red clover breeding programs. A dendrogram based on genetic distances divided the breeding populations analyzed into three distinct groups. The amount and partition of diversity observed can be of value in identifying the populations that parents of synthetic cultivars are derived from and to exploit the variation available in the populations analyzed.     

Analysis of genetic variability of South American wild rice populations (Oryza glumaepatula) with isozymes and RAPD markers

The knowledge of population structure and genetic diversity of wild relatives of rice is needed to investigate their evolutionary history and potential use in breeding programs. Very little is known about the wild rice species ( Oryza spp.), particularly those that are native to South America. A study using isozyme and RAPD markers was conducted to estimate the level of genetic diversity of four South American wild rice populations ( Oryza glumaepatula ) recently collected in the Amazon forest and western Brazil rivers. F -statistics and genetic diversity parameters calculated from isozyme and RAPD markers indicated high values for inbreeding coefficients and differentiation among the four populations. In agreement with this, a pattern of greater variation between than within populations was observed with both types of markers. These findings were corroborated by an AMOVA analysis, which indicated that a large portion of the total genetic variation was attributed to regional divergence. The partition of the AMOVA analysis among populations showed that most of the genetic diversity was due to differences among populations. This distribution pattern of genetic variation of O. glumaepatula populations is in agreement with the expectation for an autogamous species and provides important baseline data for conservation and collection strategies for this species.     

我国部分金莲花种质资源遗传多样性的RAPD研究

用RAPD标记对来自不同产地的24份金莲花种质从分子水平开展遗传多样性研究,为综合评价我国金莲花资源现状及植物资源的合理保护提供参考。结果显示,30条RAPD引物共扩增获得194条清晰可辨条带,其中多态性条带108条,多态性位点百分率为55.67%,金莲花总多样性指数为0.1460,居群内遗传多样性为0.0591,Shannon’s多样性指数为0.2248;通过UPGMA进行聚类分析,将24份金莲花种质划分为3个大类,根据总遗传多样性和居群内遗传多样性计算不同居群间遗传分化系数为0.6902,基因流估计平均值为0.2244。研究结果表明,目前我国金莲花种质资源的遗传多样性指数偏低,应该尽快采取相应措施,对不同金莲花资源进行合理保护。     

Identification of Prunus armeniaca cultivars by RAPD and SCAR markers

Nineteen cultivars of apricot (Prunus armeniaca) were distinguished using random amplified polymorphic DNA (RAPD) markers. One decamer out of 44 used was useful to differentiate cultivars of the Campania Region from those of Northern Italy, North America and Greece. A sequence characterized amplified region (SCAR) marker was obtained. The results provide a protocol to fingerprint DNA of apricots as an efficient way to quality control and fraud prevention.     

Analysis of genetic diversity and structure in Ethiopian populations of Phytolacca dodecandra using RAPD

The genetic diversity and structure in 17 wild populations (249 individuals) of Phytolacca dodecandra (endod) sampled along altitudinal gradients of 1600-3000 meters above sea level (m.a.s.l.) in Ethiopia was studied using random amplified polymorphic DNA (RAPD). A total of 70 polymorphic loci (P) scored from 12 RAPD primers were used to calculate different diversity indices within and between populations, habitats, geographical regions, climatic zones and altitude groups. The number of polymorphic loci and overall Shannon information measure (H) in the populations varied from 30 to 55 and from 0.228 to 0.418, respectively. In general, differences in population variability were found significantly correlated to effective population size. Both P and H were significantly higher in an undisturbed than in a disturbed habitat, and in the lowland and central-highland than in the highland altitude group. However, for both parameters the differences were not statistically significant between regions and climatic zones. Genetic distance between populations varied from 0.301 to 0.628. Cluster analysis performed using the genetic distance matrix revealed a clear separation of the highland populations (2501-3000 m.a.s.l.) from those of the lowland/central-highlands (1600-2500 m.a.s.l.) irrespective of their geographical regions and climatic zones. Analysis of molecular variance (AMOVA) indicated that differences in habitat, geographical regions and climatic zones explained 4.6%, 2.5% and 4.6%, respectively. But none of these differences were significant. Altitude explained 17.2% of the total variance and was highly significant. The data, therefore, clearly indicated the association of genetic structure in endod with altitude. The proportion of RAPD variation found among populations (21.2-35.0%) was somewhat intermediate between values reported for selfing and outcrossing species. The fixation index (FST) values (0.350 to 0.384) indicated very high genetic differentiation among populations.     

基于RAPD标记的南苍术居群遗传多样性分析

采用RAPD标记技术对分布于江苏小九华山、小汤山和湖山,安徽金寨和芜湖以及湖北保康和英山的7个南苍术〔Atractylodes lancea(Thunb.)DC.〕野生居群的28个单株基因组总DNA进行PCR扩增,在此基础上分析居群的遗传多样性及遗传分化,并采用聚类分析法对居群的遗传关系进行分析。结果表明:用18条RAPD引物共扩增出193条带,其中多态性条带111条,多态性条带百分率(PPB)为57.51%;平均每条引物扩增出10.72条带,其中多态性条带6.17条。从省级水平看,安徽居群的PPB、有效等位基因数(Ne)、Nei’s基因多样性指数(H)和Shannon信息指数(I)均最低,而湖北居群的Ne、H和I均最高,但江苏居群的PPB最高;从居群水平看,湖北保康居群的PPB、Ne、H和I均最高,而安徽金寨居群均最低。7个居群的基因分化系数和基因流分别为0.206 5和1.921 5,说明7个居群总遗传变异的20.65%存在于居群间、79.35%存在于居群内。7个居群间的遗传距离为0.150 7～0.252 1,其中,安徽金寨和芜湖居群间最小(0.150 7),江苏湖山和安徽芜湖居群间最大(0.252 1)。基于遗传距离的聚类分析结果表明:7个居群可分为2组,湖北保康居群单独成组,其他6个居群聚为另一组;来自同一居群的单株均聚在一起。研究结果提示:南苍术居群间的遗传多样性较低,居群间无明显的遗传分化。     

Spatially dependent genetic diversity within and between colonies of wild raspberry Rubus idaeus detected using RAPD markers

In the Tayside region of Scotland, red raspberry Rubus idaeus exists both as extensive plantations of clonally propagated cultivars, and as wild populations that inhabit both the cultivated areas and uncultivated uplands to the north. In order to explore the genetic diversity of the wild populations and their degree of similarity to the plantation clones, individual plants in wild populations were sampled from four distinct sites along a 25-km transect northwards from the area of cultivation. The genetic material of each of 45 individuals and the commercial cv. Glen Clova were examined using six RAPD primers giving a total of 63 variable bands. Some identical banding patterns were observed, suggesting vegetative growth up to 20 m, but populations consisted mainly of genetically distinct individuals. Similarity matrices based on the marker bands showed, without exception, that plants were more similar within a site than between sites. None of the populations was closely related to the cv. Glen Clova. Although the most northerly site had the largest proportion of rare bands, there was no general trend between within-site diversity, or similarity to the cultivar, and position on the north-south line. All four sites had unique bands and bands not displayed by the cultivar. However, the genetic diversity of a site appeared to increase as the extent of the sampled area increased, implying that the genetic variation was spatially dependent. For example, maximum and minimum similarities were 100 and 80%, respectively, at interplant distances of 2 m; 100 and 60% at distances of 20 m; 85 and 55% at 200 m and 70 and 40% at 20 km.