基于ISSR标记的62个朱顶红品种的遗传关系分析及指纹图谱构建

采用ISSR标记方法分析了62个朱顶红(Hippeastrum spp.)品种(包含60个引自荷兰的品种和2个苏州本地品种)的遗传多样性,并采用UPGMA法对62个朱顶红品种进行聚类分析.在此基础上,通过特异性条带的比较及筛选,采用黑白方格示意图法构建了供试品种的ISSR指纹图谱.扩增结果显示:用11条引物从62个朱顶红品种的基因组DNA中共扩增出118条带,其中多态性条带109条,多态性条带百分率达92.4％,有5条引物扩增条带的多态性条带百分率达100.0％.62个品种间的遗传相似系数变幅较大,为0.371 4～0.842 9,表明各品种间存在丰富的遗传变异和遗传多样性.聚类分析结果显示:在遗传相似系数0.63处62个品种被分为7组,多数形态相似的品种被聚在一起;其中形态相似的白色单瓣品种间遗传相似系数较高(约0.8),大多聚在一起,表明它们同源性较高;而2个苏州本地品种间遗传相似系数最高(0.842 9),表明它们可能具有同一来源.品种‘小红星’在引物UBC873扩增图谱的450 bp处有1条特异性条带,而品种‘精灵’在引物UBC835扩增图谱的3 000 bp处有1条特异缺失条带,这2条特异性条带可分别用于品种‘小红星’和‘精灵’的鉴定.基于引物UBC835和UBC873的ISSR扩增条带组合构建了供试的62个朱顶红品种的ISSR指纹图谱,采用这一指纹图谱可对供试的所有朱顶红品种进行鉴定.     

基于ISSR标记的黄河下游区域鲁桑地方品种遗传关系分析

应用ISSR分子标记技术对来自黄河下游区域(山东省和河北省)的46个鲁桑[Morus alba var. multicaulis (Perrott. ) Loud. ]地方品种的遗传多样性进行了分析;并基于遗传相似系数、采用UPGMA法对这些地方品种的遗传关系进行了研究.结果表明,用15个ISSR引物从46个鲁桑地方品种的总DNA中共扩增出109条带,其中多态性条带81条,多态性条带百分率为74.31%,表明供试的鲁桑地方品种间存在丰富的遗传多样性;46个地方品种间的遗传相似系数为0.602～0.898,相对偏高.聚类分析结果显示,46个鲁桑地方品种被分为2类,其中,第1类包含来自河北的品种'冀丰'和'冀黄鲁选',第2类包含其余44个品种;后者还能进一步分成9个亚类,其中A、E、F、G、H和I亚类所包含的36个品种均来自山东,组成B、C和D亚类的品种分别来自河北和山东;此外,E亚类仅包含'白条擗桑'1个品种,是46个品种中惟一的三倍体品种.研究结果显示,基于ISSR标记分析的46个鲁桑地方品种的遗传关系与地理分布具有一定的相关性.     

51个春兰(Cymbidium goeringii)品种的AFLP遗传多样性分析

为了揭示春兰品种的遗传多样性和亲缘关系,为春兰种质资源的有效利用和开发提供依据,采用AFLP技术对51个春兰品种进行了遗传多样性分析,经筛选得到了8对条带清晰、多态性高的引物,共扩增出1315条DNA片段,其中多态性条带为1217条,平均1对引物扩增条带164条,多态性带152条,多态性位点频率为92.5%,表明春兰品种具有丰富的遗传多态性。49个品种含有特有带。51个品种间遗传相似系数变化范围为0.501~0.716,聚类分析表明,51个春兰品种共分为5个类群,来自同一地区的品种并没有聚在一起,表明春兰品种的遗传背景混乱。AFLP分子标记技术能有效地分析春兰品种的遗传多样性和亲缘关系。     

中国主要黑芝麻品种的遗传多样性分析

利用SRAP和SSR各23对引物对20个中国主要黑芝麻品种进行了遗传多样性分析。结果显示,23对SRAP引物共扩增出DNA带672条,其中多态性带152条,比率为22.62%,平均每对引物扩增总带数和多态性条带分别为29.22条和6.61条。23对SSR多态性引物共扩增出DNA带92条,每对引物扩增出3~6条,平均4.00条;每对引物扩增出多态性带1~5条,平均3.09条,多态性带比率平均为77.17%。20个黑芝麻品种间的遗传相似系数为0.8547~0.9804,遗传距离为0.0159~0.0921,遗传多样性匮乏,遗传基础狭窄。聚类结果表明,来自主产区江西的11个品种明显聚在一起,且江西黑芝麻品种的遗传相似系数高于其他省份品种,遗传距离低于其他省份品种,与其他省份品种的差异均达到极显著水平。加强资源引进和利用是拓宽中国黑芝麻品种遗传基础的迫切要求。     

红掌品种亲缘关系SRAP分析

利用相关序列扩增多态性（SRAP）分子标记,从100对引物组合中筛选出 26对多态性高、条带清晰的SRAP引物,对33个红掌品种进行遗传多样性和亲缘关系分析。结果如下：（1）26对引物共扩增出366条条带,其中有314条多态性条带,多态性比率为85.79%。引物组合产生的条带数在9～23之间,平均每对引物组合扩增出14.1条和12.1条多态性条带。（2）根据SRAP扩增结果,利用UPGMA法进行聚类分析,33份材料的遗传相似系数在0.55～0.94之间,在遗传相似系数0.786处可将33个红掌品种分为5个类群。结果表明,供试品种遗传多样性丰富,本研究为品种鉴定和杂交育种提供了参考信息。     

40个黄皮品种的ISSR分析

采用ISSR-PCR分子标记技术对40个黄皮品种的遗传多样性进行分析。从96条ISSR引物中筛选出15条引物用于PCR扩增,共扩增出165条带,其中多态性条带100条,多态性比率为60.6%。应用SPSS软件计算各品种间的Jaccard相似系数介于0.714~1.000,UPGMA法将40个品种分成5组。     

甘薯品种的SRAP遗传多样性分析

利用分子标记SRAP技术,对36个甘薯品种进行了DNA多态性分析。选取6对引物扩增甘薯基因组DNA,共获得112条带,其中110条为多态性条带,平均每对引物提供18个标记信息。由UPMGA方法得到的聚类分析结果表明了36个品种间的遗传关系。相似系数在0.62~0.92之间,品种间有较高的遗传相似性;在聚类树中,亚洲品种和美洲品种之间没有明显的遗传分化,表明甘薯品种间没有明显的地理差异;近缘野生种与育成品种聚在一起,没有明显的遗传分化,这意味着它们之间有较高的遗传相似度;中国育成品种聚在一起,表明它们之间的遗传相似度很高。     

蝴蝶兰种质资源遗传多样性的ISSR分析

利用ISSR分子标记对24个蝴蝶兰(Phalaenopsis)栽培品种进行了遗传多样性分析.筛选出的12个ISSR引物共扩增出301条清晰的谱带,其中多态性条带268条,多态性比率为89.1%.品种间的遗传相似系数在0.37～0.93之间,表明品种间具有较高的遗传多样性.UPGMA聚类分析可将供试材料分为3组,分类结果与材料来源及花器官表型具有密切的关系.     

8份广西产绞股蓝种质的RAPD引物筛选及其遗传多样性分析

本研究的目的在于筛选合适的RAPD随机引物,应用RAPD技术对药用植物绞股蓝进行遗传多样性分析,并构建DNA指纹图谱。研究结果表明,我们利用生物信息学方法挑选出的20条引物中有19条引物的扩增条带清晰且多态性好;在清晰稳定出现的354条带中,294条具有多态性;其中有3条引物的扩增条带可清楚区分绞股蓝与混淆品种乌蔹莓,可建立其DNA指纹图谱。按UPGMA法进行聚类分析,计算其遗传相似系数,结果显示,8份绞股蓝供试材料聚为两类,聚类结果与其地理区域远近和生长环境一致。本研究中筛选出的19条引物适用于绞股蓝遗传多样性分析,且获得的DNA指纹图谱可用于鉴别绞股蓝。     

节瓜自交系遗传多样性的ISSR分析

利用ISSR分子标记技术对36份节瓜自交系进行遗传多样性分析。从100条ISSR引物中筛选出14条多态性明显、条带清晰、反应稳定的引物,对36份节瓜材料基因组DNA进行扩增,共扩增出76条清晰稳定的条带,其中多态性条带45条,多态性比例为59.21%。36份材料间遗传相似系数在0.57~0.96之间,表明材料间遗传多样性较为狭窄。聚类分析结果显示,以遗传相似系数0.76为阈值时,可将36份节瓜自交系材料聚为3类,分类结果与供试材料的地理来源较为吻合。基于聚类分析结果,可为今后节瓜的新品种选育、遗传改良以及分子遗传连锁图谱构建的杂交亲本选择提供科学依据。     

Practical strategy for identification of single nucleotide polymorphisms in fruiting mei (Prunus mume Sieb. et zucc.) from amplified fragment length polymorphism fragments

Single nucleotide polymorphism (SNP) is the most abundant form of genetic variation among individuals within a species. SNPs can be used as markers for gene discovery and for assessment of diversity. We established a practical strategy for identification of SNPs in fruiting mei (Prunus mume Sieb. et Zucc.) from amplified fragment length polymorphism (AFLP) fragments. The main modification of this procedure was optimization of the reamplification of bands excised from an AFLP gel by using a single enzyme (EcoRI) in digestion reaction to generate large AFLP fragments and to lower the number of bands on gels, using lower-concentration polyacrylamide gels (4%) and loading each sample into 4 continuous lanes, using a newly modified protocol for purification of AFLP bands from the gel, and using additional cycles for reamplification of AFLP bands. In this study, 15 groups of bands with identical migration distances from 10 fruiting mei cultivars were selected for purification. Eighty-one of the 150 chosen bands were successfully reamplified, and 67 of these reamplified polymerase chain reaction products yielded reliable sequences belonging to 13 groups. The alignment of 13 group sequences yielded 95 SNPs, for a total of 5252 bp. Among these SNPs, 73 were heterozygous in the loci of some individual cultivars. The SNP distribution was 58% transition, 40% transversion, and 2% indels. There was also 1 dinucleotide polymorphism and 1 tetranucleotide deletion.     

Local genetic differentiation among populations of the mass-flowering tropical shrub Erythroxylum havanense (Erythroxylaceae)

This study is aimed to understand the role of life-history traits in determining the genetic structure of populations. We used Erythroxylum havanense, a distylous shrub with synchronous and massive patterns of flowering and fruiting. We suggest that the high concentration of ephemeral resources produced by mass flowering satiates both pollinators and frugivores, restricting gene flow and leading to genetic differentiation among populations. Using random amplified polymorphic DNAs as genetic markers, we estimated genetic diversity and structure statistics to quantify the amount and distribution of genetic variation within and among five populations from the Pacific coast of Mexico. High levels of genetic variation within populations and significant differentiation among populations located very near to each other were found. Furthermore, spatial autocorrelation analysis indicated the presence of significant genetic structure at short spatial distances. We suggest that by influencing the foraging behavior of pollinators and frugivores, mass flowering may produce the observed patterns of genetic structure, while small differences in flowering or fruiting phenology could further reinforce the isolation of nearby populations.     

陆地棉开花成铃性状的遗传研究Ⅲ.不同发育阶段的遗传规律

对4个陆地棉品种(系)双列杂交实验的2年观察资料按包括基因型×环境互作的加性-显性遗传模型进行不同发育阶段开花成铃规律的遗传分析。方差分析表明,开花成铃早期主要受显性效应控制,至中后期加性效应作用逐渐增强,基因型×环境互作效应相对较小。不同发育阶段平均开花成铃数与总铃数的相关分析表明,8月1日前加性相关系数为负数或零值,但存在显著或极显著的显性正相关,8月1日后则相反。不同发育阶段平均开花成铃数的条件遗传分析发现不同时期的基因活动强度不同,7月下旬及8月上中旬最大;检测间隔(t-k)对探讨花铃期基因活动规律有重要作用;选择调查周期时应兼顾实验目的、实验环境条件、入选性状及所处的发育阶段。     

Genome-Wide Discovery of DNA Polymorphisms in Mei (<Emphasis Type="Italic">Prunus mume</Emphasis> Sieb. et Zucc.), an Ornamental Woody Plant,with Contrasting Tree Architecture and their Functional Relevance for Weeping Trait

Next-generation sequencing technologies provide opportunities to ascertain the genetic basis of phenotypic differences, even in the closely related cultivars via detection of large amount of DNA polymorphisms. In this study, we performed whole-genome re-sequencing of two mei cultivars with contrasting tree architecture. 75.87 million 100 bp pair-end reads were generated, with 92 % coverage of the genome. Re-sequencing data of two former upright mei cultivars were applied for detecting DNA polymorphisms, since we were more interested in variations conferring weeping trait. Applying stringent parameters, 157,317 mutual single nucleotide polymorphisms (SNPs) and 15,064 mutual insertions-deletions (InDels) were detected and found unevenly distributed within and among the mei chromosomes, which lead to the discovery of 220 high-density, 463 low-density SNP regions together with 80 high-density InDel regions. Additionally, 322 large-effect SNPs and 433 large-effect InDels were detected, and 10.09 % of the SNPs were observed in coding regions. 5.25 % SNPs in coding regions resulted in non-synonymous changes. Ninety SNPs were chosen randomly for validation using high-resolution melt analysis. 93.3 % of the candidate SNPs contained the predicted SNPs. Pfam analysis was further conducted to better understand SNP effects on gene functions. DNA polymorphisms of two known QTL loci conferring weeping trait and their functional effect were also analyzed thoroughly. This study highlights promising functional markers for molecular breeding and a whole-genome genetic basis of weeping trait in mei.     

电子顺磁共振法测定清栓酶在沙鼠脑缺血再灌流损伤中的抗自由基作用

本文设计了沙鼠脑缺血再灌流实验模型,以清拴酶作脑缺血后静脉注射再灌流模型和非药物再灌流模型组对照,用电子顺磁共振法(ESR)测定脑组织自由基波谱,结果清栓酶组出现自由基信号很弱,接近正常组,显著区别于未用药脑缺血再灌流30分钟和60分钟组(P<0.01),证明清栓酶有抗自由基和再灌注损伤的作用.     

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.     

Genetic linkage map construction and QTL identification of juvenile growth traits in Torreya grandis

Mei, Prunus mume Sieb. et Zucc., is an ornamental plant popular in East Asia and, as an important member of genus Prunus, has played a pivotal role in systematic studies of the Rosaceae. However, the genetic architecture of botanical traits in this species remains elusive. This paper represents the first genome-wide mapping study of quantitative trait loci (QTLs) that affect stem growth and form, leaf morphology and leaf anatomy in an intraspecific cross derived from two different mei cultivars. Genetic mapping based on a high-density linkage map constricted from 120 SSRs and 1,484 SNPs led to the detection of multiple QTLs for each trait, some of which exert pleiotropic effects on correlative traits. Each QTL explains 3-12% of the phenotypic variance. Several leaf size traits were found to share common QTLs, whereas growth-related traits and plant form traits might be controlled by a different set of QTLs. Our findings provide unique insights into the genetic control of tree growth and architecture in mei and help to develop an efficient breeding program for selecting superior mei cultivars.     

Low genetic differentiation among seasonal cohorts in Senecio vulgaris as revealed by amplified fragment length polymorphism analysis

Common groundsel, Senecio vulgaris (Asteraceae), is a highly selfing semelparous ephemeral weed that belongs to the few plant species in central Europe capable of growing, flowering and fruiting all year round. In temperate climates, flowering S. vulgaris cohorts were found to appear up to three times per year. Using amplified fragment length polymorphism (AFLP) molecular markers we examined temporal genetic differentiation among spring, summer and autumn cohorts at each of seven sites located in two regions in Switzerland. Strong genetic differentiation among cohorts may indicate the existence of seasonal races of S. vulgaris, reproductively isolated by nonoverlapping flowering phenologies. Analysis of molecular variance (amova) revealed that < 2.5% of the AFLP variation resided among cohorts within sites, whereas there was significant genetic differentiation among plants from different sites (15.6%) and among individuals within cohorts (81.9%). Significant genetic differentiation was also observed between the two regions. Isolation-by-distance was found on a regional scale, but not on a local scale. Gene flow was estimated to be approximately 15-fold higher among cohorts within sites than among sites. We further found, on average, similar levels of genetic diversity within the three seasonal cohorts. The results of this study demonstrate that season of growth represents a weak barrier for genetic exchange among S. vulgaris populations and does not affect molecular variance. Therefore, there is no evidence for the existence of seasonally specialized races of S. vulgaris. We discuss some implications of the results for the biological control of S. vulgaris using a native rust fungus.