中国甘蓝型油菜遗传多样性的RAPD分子标记

本文利用ＲＡＰＤ方法和统计学分析,对我国７省市和国外引进的总计４０份甘蓝型油菜品种的遗传多样性进行了研究。结果表明,４０个品种的甘蓝型油菜存在着广泛的遗传变异,根据ＲＡＰＤ指纹图谱,通过在ＤＮＡ分子水平上的聚类分析可以将它们分为３大类群,反映出这些品种之间的亲缘关系,并对如何引进甘蓝型油菜资源进行了初浅的讨论。     

分子水平的遗传多样性及其测量方法

遗传多样性水平是一项很重要的数据。目前从分子水平量化遗传多样性的方法以等位酶分析、ＲＦＬＰ分析和ＲＡＰＤ分析为代表。遗传变异在基因组中并非随机分布,所以取样方式对分析结果的影响不容忽视。本文叙述了遗传变异的产生和分布,并以此为基础比较了上述３种分析方法的理论与实践。     

利用RFLP、SSR、AFLP和RAPD标记分析玉米自交系遗传多样性的比较研究

利用 ＲＦＬＰ、ＳＳＲ．ＡＦＬＰ和ＲＡＰＤ ４种分子标记方法研究了 １５个玉米（Ｚｅａ ｍａｙｓ Ｌ．）自交系的遗传多样性,同时对４种标记系统进行比较。在供试材料中筛选到具多态性的ＲＦＬＰ探针酶组合５６个,６６对ＳＳＲ引物,２０个ＲＡＰＤ引物和９个ＡＦＬＰ引物组合,分别检测到多态性带１６７、２０１、８７和１０８条。ＳＳＲ标记位点的平均多态性信息量（ＰＩＣ）最大（０．５４）,ＡＦＬＰ标记位点最小（０．３６）,但ＡＦＬＰ标记具有最高的多态性检测效率（Ａｉ,３２．２）。４种分子标记所得遗传相似系数相关性显著,比较相关系数表明 ＲＡＰＤ可靠性较低。依据 ４种分子标记结果将 １５个供试自交系划分为塘四平头、旅大红骨、兰卡斯特、瑞德和ＰＮ共５个类群,与系谱分析基本一致。认为ＳＳＲ和ＲＦＬＰ两种分子标记方法适合进行玉米种质遗传多样性的研究。     

甘蓝型油菜与蓝花子远缘杂交及双二倍体的合成研究

甘蓝型油菜品种奥罗×蓝花子杂种Ｆ-１,平均配对构型为１２．１Ⅰ＋６．５３Ⅱ＋０．４１Ⅲ＋０．１８Ⅳ＋０．１８Ⅴ,Ａ、Ｃ染色体组与Ｒ染色体间存在配对,它们之间具有一定的同源性。在甘蓝型油菜与蓝花子的杂种Ｆ-１代中,存在一种染色体不配对的减数分裂类型。这一类型中有少量可形成平衡的不减数配子。提供了油菜与蓝花子远缘杂种回交结实的细胞学根据。在ＭＳ＋０．２ｍｇ／ＬＮＡＡ＋３ｍｇ／ＬＢＡ＋１ｇ／Ｌ秋水仙碱＋３０ｇ／Ｌ蔗糖＋８ｇ／Ｌ琼脂的培养基中,接种甘蓝型油菜奥罗与蓝花子的杂种Ｆ-１进行加倍处理,经快速繁殖后,获得大量的染色体数为２ｎ＝５６的双二倍体幼苗。上述双二倍体自交结实,在减数分裂中绝大多数细胞形成２８个二价体,个别形成２６个二价体和１个四价体。上述技术在油菜与蓝花子远缘杂交中首次解决了用常规方法不易获取远种杂种稳定双二倍体的难题。甘蓝型油菜品种Ａｌｔｅｘ×蓝花子杂种Ｆ-１代,长时间的快速繁殖后,出现了染色体丢失和加倍,有形成１９条染色体的配子回复到甘蓝型油菜染色体组成的趋势。在油菜远缘杂种中发现了类似于球茎大麦远缘杂种中染色体丢失的现象。     

通过白菜型油菜和埃塞俄比亚芥的Ar和Cc基因组导入创造甘蓝型油菜新材料

油菜是目前我国主要种植的油料作物之一,但现有的种质资源限制了产量的进一步提高。本研究采取了一种新的育种方式来增加甘蓝型油菜的种质资源,即通过远缘杂交结合分子标记辅助选择的方式将白菜型油菜的Ar基因组和埃塞俄比亚芥的Cc对现有的甘蓝型油菜品种的基因组(AnAnCnCn)进行部分替换。通过对五倍体杂交后代(ArAnBcCcCn)进行染色体选择,找到了染色体数目为38的材料。为了和现有的甘蓝型油菜进行区分,得到的新材料被认定为甘蓝型油菜新材料。实验结果表明,得到的部分甘蓝型油菜新材料具有基本正常的减数分裂过程、正常的花粉萌发以及胚囊发育过程,这说明甘蓝型油菜新材料达到了遗传平衡。分子标记分析表明:甘蓝型油菜新材料的约50%的基因组被白菜型油菜的Ar基因组和埃塞俄比亚芥的Cc替换,并且这些甘蓝型油菜新材料之间具有丰富的遗传多样性。因此,白菜型油菜的Ar基因组和埃塞俄比亚芥的Cc基因组导入对于丰富现有的甘蓝型油菜种质资源具有明显的效果。     

微卫星DNA和AFLP标记在水稻分子标记连锁图上的分布

以一个栽培稻（ＯｒｙｚａｓａｔｉｖａＬ．ｓｐ．ｉｎｄｉｃａ）和野生稻（Ｏ．ｒｕｆｉｐｏｇｏｎＧｒｉｆ）杂交的Ｆ２作图群体以及由该群体构建的ＲＦＬＰ标记连锁图,分析了微卫星ＤＮＡ和ＡＦＬＰ标记的多态性、遗传行为及其在染色体上的分布。共定位了２８个微卫星ＤＮＡ标记和１７２个ＡＦＬＰ标记。２８个微卫星ＤＮＡ标记中有６个为华中农业大学作物遗传改良国家重点实验室根据数据库中序列而设计,其余２２个来自美国Ｃｏｒｎｅｌ大学已发表的结果。１７２个ＡＦＬＰ标记出自２５对引物扩增得到的２２８个多态性带的片段。这些标记分布于水稻的１２条染色体。将此２００个ＰＣＲ标记与华中农业大学作物遗传改良国家重点实验室构建的ＲＦＬＰ连锁图整合,得到一张含６１２个分子标记位点的遗传连锁图。     

利用RFLP,SSR,AFLP和RAPD标记分析玉米自效系遗传多样性的比较研究

利用ＲＦＬＰ、ＳＳＲ、ＡＦＬＰ和ＲＡＰＤ４种分子标记方法研究了１５个玉米（Ｚｅａ ｍａｙｓ Ｌ．）自交系的遗传多样性,同时对４种标记系统进行比较。在供试材料中筛选到具多态性的ＲＦＬＰ探针酶组合５６个,６７６对ＳＳＲ引物,２０个ＲＡＰＤ引物和９个ＡＦＬＰ引物组合,分别检测到多态性带１６７、２０１、８７和１０８条。ＳＳＲ标记位点的平均多态性检测效率（Ａｉ,３２．２）。４种分子标记所得遗传相似自交系划分     

AFLP标记在果树遗传育种研究中的应用

1993年 ,Ｚａｂｅａｕ等发明了一项专利技术 ,扩增片段长度多态性 (ａｍｐｌｉｆｉｅｄｆｒａｇｍｅｎｔｌｅｎｇｔｈｐｏｌｙｍｏｒｐｈｉｓｍ ,ＡＦＬＰ) ,该技术结合了ＲＦＬＰ技术和ＰＣＲ技术的优点 ,以其高效性和高重复性等特点 ,被广泛应用于多种植物的遗传育种研究。1 .ＡＦＬＰ技术的原理和特点ＡＦＬＰ技术是基于对限制性片段的选择性扩增 ,基因组ＤＮＡ被限制性内切酶切割后 ,将限制性片段末端连上双链接头 ,根据接头序列和相邻的限制性位点序列设计引物对限制性片段进行扩增。扩增产物经电泳检测后再比较其谱带的差异。ＡＦＬＰ…     

应用荧光原位杂交和RFLP标记检测多小穗小麦新种质10-A中的黑麦染色质

利用ＡＰＡＧＥ、荧光原位杂交技术和ＲＦＬＰ标记,对导入黑麦（ＳｅｃａｌｅｃｅｒｅａｌｅＬ．）多小穗等性状创制的小麦新种质１０＿Ａ进行了分子标记检测。ＡＰＡＧＥ分析发现,１０＿Ａ与其他１ＲＳ／１ＢＬ易位系一样,含有１ＲＳ的醇溶蛋白标记位点Ｇｌｄ１Ｂ３。以黑麦基因组总ＤＮＡ作探针,用中国春（Ｔｒｉｔｉｃｕｍａｅｓｔｉｖｕｍｃｖ．ＣｈｉｎｅｓｅＳｐｒｉｎｇ）基因组ＤＮＡ作封阻,与１０＿Ａ根尖细胞有丝分裂染色体进行荧光原位杂交。结果表明,黑麦的１ＲＳ易位到１０＿Ａ中。用２５个ＲＦＬＰ探针进行Ｓｏｕｔｈｅｒｎ分析,进一步发现１０＿Ａ的１ＢＳ特异限制性片段发生丢失,代之以黑麦１ＲＳ的特异限制性片段,而位于其他染色体上的特异限制性片段未发生缺失。据此认为,多小穗小麦新种质１０＿Ａ属于１ＲＳ／１ＢＬ易位系。同时还讨论了１０＿Ａ在小麦遗传改良中的利用情况。     

AFLP分子标记及其在植物育种上的应用

扩增酶切片段多态性（ＡｍｐｌｉｆｉｅｄＲｓｔｒｉｃｉｔｏｎｆｒａｇｍｅｎｔｐｏｌｙｍｏｒｐｈｉｓｍ,简称ＡＦＬＰ）是由Ｚａｂｅａｕ等１９９２年发明的一项新的ＤＮＡ指纹技术,它结合了ＲＦＬＰ和ＰＣＲ技术的特点,具有ＲＦＬＰ技术的可靠性和ＰＣＲ技术高效性,其基本原理是对基因组ＤＮＡ酶切片段的选择性扩增,ＡＦＬＰ扩增片段的谱带数取决于采用的内切酶及引物３′端选择碱基的种类数目和所研究基因组的复杂性,实验     

RFLP和AFLP分析白菜型油菜和甘蓝型油菜遗传多样性及其在油菜改良中的应用价值

采用RFLP和AFLP标记对来自中国和欧美的7份甘蓝型油菜和22份白菜型油菜进行了遗传多样性分析。在这29份材料中,166个酶-探针组合和2对AFLP引物共检测到1477个RFLP标记和183个AFLP标记。RFLP数据显示以拟南芥EST克隆作探针比用油菜基因组克隆做探针能检测到更多的多态性位点,且采用EcoR Ⅰ或BamH Ⅰ酶切比HindⅢ酶切多态性好,白菜型油菜和甘蓝型油菜中基因的拷贝数平均都为3个左右。UPGMA聚类分析表明中国白菜型油菜的遗传多样性比甘蓝型油菜和欧美白菜型油菜丰富,欧美甘蓝型油菜与欧美白菜型油菜聚为一类,而与中国甘蓝型油菜差异更大。中国白菜型油菜丰富的遗传多样性为中国甘蓝型油菜的改良提供了宝贵的资源,揭示了利用白菜型油菜A基因组和甘蓝型油菜A基因组间亚基因组杂种优势的可能性。     

Comparison of rapeseed cultivars and resynthesized lines based on allozyme and RFLP markers

It has frequently been suggested to use the resynthesis of rapeseed (Brassica napus) from B. campestris and B. oleracea to broaden its genetic base. The objective of the present study is twofold: (1) to compare the genetic variation within resynthesized rapeseed with a world-wide collection of oilseed rape cultivars, and (2) to compare genetic distances estimated from RFLP markers with distances estimated from a relatively small number of allozyme markers. We investigated 17 resynthesized lines and 24 rapeseed cultivars. Genetic distances were estimated either based on the electrophoresis of seven allozymes, with a total of 38 different bands, or based on RFLP data of 51 probe/enzyme combinations, with a total of 355 different bands. The results of allozyme and RFLP analyses agreed reasonably well. Genetic distances, estimated from two independent sets of RFLP data with 25 and 26 probe/enzyme combinations respectively, were highly correlated; hence about 50 RFLP markers are sufficient to characterize rapeseed material with a large genetic diversity. The cultivars were clustered into three groups: (1) spring rapeseed of European and Northern American origin, (2) winter rapeseed of European and Northern American origin, and (3) rapeseed of Asian origin. Several of the resynthesized rapeseed lines were similar to European winter rapeseed cultivars, whereas others had quite unique patterns. It is concluded, that resynthesized rapeseed is a valuable source for broadening the genetic variation in present breeding material of Brassica napus. However, different lines differ widely in their suitability for this purpose.     

Mapping the mosaic of ancestral genotypes in a cultivar of oilseed rape (Brassica napus) selected via pedigree breeding.

Recent oilseed rape breeding has produced low glucosinolate cultivars that yield proteinaceous meal suitable for animal feed. The low glucosinolate character was introduced into modern cultivars from Brassica napus 'Bronowski', a cultivar that is agronomically inferior in most other respects. Residual segments of 'Bronowski' genotype in modern cultivars probably cause reduced yield, poorer winter hardiness, and lower oil content. The quantity and distribution of the 'Bronowski' genotype in the modern oilseed rape cultivar Brassica napus 'Tapidor' was investigated using a segregating population derived from a cross between 'Tapidor' and its high glucosinolate progenitor. This population was analyzed with 65 informative Brassica RFLP probes and a genetic linkage map, based on the segregation at 77 polymorphic loci, was constructed. The mapping identified 15 residual segments of donor genotype in 'Tapidor', which together occupy approximately 29% of the B. napus genome. Mapping the loci that control variation for the accumulation of total seed glucosinolates in the segregating population has identified three loci that together explain >90% of the variation for this character. All of these loci are in donor segments of the 'Tapidor' genome. This result shows the extent to which conventional breeding programmes have difficulty in eliminating residual segments of donor genotype from elite material.     

SSR标记对不同黄籽甘蓝型油菜亲本材料的遗传分析

杂交育种中,亲本选配是育种成败的关键。本研究以重庆市油菜工程技术研究中心提供的180份甘蓝型黄子油菜亲本种质为材料,应用分布于不同连锁群的60对SSR标记进行了分析,共检测出308个标记位点,每对引物在不同亲本材料之间的等位基因数在1～11个之间,平均位点为5.1个。其中多态性位点207个,多态率达67.2%。对SSR扩增结果进行UPGMA分析,在遗传距离0.566处,180个品种(系)分为3个类群,聚类结果与种质来源比较一致,本研究为甘蓝型油菜黄子杂交育种和优势组合的选配提供了理论依据。     

用EST-SSR标记检测我国甘蓝型油菜品种的遗传多样性

杂交育种依然是我国油菜育种的主要方法,杂种优势的利用仍然是提高产量的重要途径.为了解我国甘蓝型油菜的遗传变异,采用16个EST-SSR标记对近年来推广的91个品种的遗传多样性进行了分析.共扩增到100个条带,其中84个多态性带,多态性比率为84%.平均每对引物扩增的带数和多态性带数分别为6.25个和5.25个.多态性信息含量(PIC)变化在0.022-0.926之间,平均为0.677,所揭示的基因型数变化于2-24之间,平均为12.44个.供试材料间遗传距离变幅较大(0.0530-0.7223之间),说明它们具有广泛的遗传变异.其中,杂交种和2000年以后育成品种的遗传基础较宽,遗传多样性分别明显高于常规品种和2000年以前育成的品种.按非加权成对平均数法(UPGMA)进行的聚类分析显示,在遗传距离为0.313处,参试材料可以分为三大类,其中,包含87份材料的第一大类在遗传距离为0.233处又可进一步分为10个亚类.聚类结果与系谱来源基本一致,比较真实反映了所用材料的遗传变异情况.     

Divergent patterns of allelic diversity from similar origins: the case of oilseed rape (Brassica napus L.) in China and Australia.

Oilseed rape (Brassica napus) in Australia and China have similar origins, with introductions from Europe, Canada, and Japan in the mid 20th century, and there has been some interchange of germplasm between China and Australia since that time. Allelic diversity of 72 B. napus genotypes representing contemporary germplasm in Australia and China, including samples from India, Europe, and Canada, was characterized by 55 polymorphic simple sequence repeat (SSR) markers spanning the entire B. napus genome. Hierarchical clustering and two-dimensional multidimensional scaling identified a Chinese group (China-1) that was separated from "mixed group" of Australian, Chinese (China-2), European, and Canadian lines. A small group from India was distinctly separated from all other B. napus genotypes. Chinese genotypes, especially in the China-1 group, have inherited unique alleles from interspecific crossing, primarily with B. rapa, and the China-2 group has many alleles in common with Australian genotypes. The concept of "private alleles" is introduced to describe both the greater genetic diversity and the genetic distinctiveness of Chinese germplasm, compared with Australian germplasm, after 50 years of breeding from similar origins.     

Phenetic relationships and levels of variability detected by restriction fragment length polymorphism and random amplified polymorphic DNA analysis of cultivated and wild accessions of Lycopersicon esculentum.

Random amplified polymorphic DNA (RAPD) and restriction fragment length polymorphism (RFLP) markers were used to assess the variability in tomato germplasm (Lycopersicon esculentum Mill.), which included 46 accessions from the following groups: vintage cultivars, modern cultivars, South American regional cultivars, and wild L. esculentum van cerasiforme. Two L. cheesmanii accessions served as an outgroup. The 48 accessions were monomorphic at 135 of the 215 RAPDs loci and 31 of the 48 RFLP loci that were assayed. Alleles were identified that distinguished the five groups and many of the cultivars. The frequency of polymorphic loci was low in vintage cultivars, with less than 2.8% of the loci being variable within the group. In contrast, introgression of wild germplasm into modern cultivars has increased the polymorphic loci to 11.6%, whereas within the group of regional cultivars linkage drag and outcrossing may be responsible for the further increase to 20.3%. These levels of genetic variability were lower in comparison to the 24.5% polymorphic loci of cerasiforme, a group that may contain unutilized desirable traits. The small genetic distance from the vintage cultivars to several of the widely distributed regionals and cerasiformes indicated that proximity of vintage cultivars in Latin America may have resulted in intercrossing of these materials with the wilder germplasm. RAPDs appear promising for both germplasm fingerprinting and as a predictor of genetic diversity for plant breeding applications.     

走马胎种质资源遗传多样性的ISSR分析

走马胎( Ardisia gigantifolia)是紫金牛科( Myrsinaceae)紫金牛属( Ardisia)多年生小灌木植物。走马胎作为我国传统中药材,已有多年的药用历史。目前,走马胎不再局限于临床药用,在食疗和保健方面的开发利用崭露头角,大大扩展了其应用范围。随着走马胎市场需求量的增大,野生走马胎植物被过度采挖,导致野生走马胎资源几乎枯竭。人工栽培走马胎逐渐成为供应药用市场的主力军,但是人工栽培走马胎种质、种子来源混杂,常会造成质量和疗效的不稳定,而利用分子标记技术可以从分子水平上对走马胎进行种质的区分和评价。该研究利用ISSR分子标记技术,对来自广西地区的36份走马胎种质资源进行了遗传多样性分析,采用POPGEN32软件进行数据分析,用UPGMA软件绘制聚类图。结果表明：14条ISSR引物共检测到136个清晰的扩增位点,多态性位点112个,多态位点百分率为82.35％;Nei’ s基因多样性指数( H)为0.2965,Shannon多样性指数(I)为0.4417,基因分化系数(Gst)为0.8558。个体间的遗传相似系数为0.6678~0.8382,平均为0.7391。基于聚类分析可知,所有的个体被划分为5类,其中绝大多数来自相同或者邻近地区的个体严格按照地理位置聚为相同的一类或者亚类,只有少数个体在归类上与地理位置相悖。研究证明ISSR分子标记技术在评价走马胎种质资源亲缘关系和遗传变异等方面有很好的适用。该研究结果为该药用植物的种质资源评估和引种栽培提供了科学依据。     

Simple sequence repeat (SSR) analysis for assessment of genetic variability in apricot germplasm

Thirty SSR primer combinations, developed from peach SSR-enriched genomic libraries and BAC libraries of peach [ Prunus persica (L.) Batsch.], were tested for cross amplification with 74 apricot ( Prunus armeniaca L.) germplasm accessions. Twelve primer pairs amplified 14 polymorphic SSR loci useful for discriminating most apricot cultivars, as well as for investigating patterns of variation in apricot germplasm. Levels of polymorphism were higher than the levels described using other codominant marker systems (i.e., isozymes, RFLP markers). Overall, 107 alleles were identified, and all but 11 accessions were unambiguously discriminated. Genetic differentiation of native germplasm into traditional ecogeographical groups was low, with a high level of genetic identity (> 0.75) between the groups. However, neighbor joining cluster analysis of marker distances between cultivars reflected the complex history of apricot domestication, producing groupings not evidently based on the geographical origin of the cultivars. Distant positioning of Chinese cultivars on UPGMA and neighbor joining dendrograms supports the authors' consideration of Chinese apricots as subspecies, Prunus armeniaca var. ansu Maxim., rather than a separate species.