芥菜型油菜芥酸和廿碳烯酸的遗传

本试验研究了芥菜型油菜种子油中芥酸和廿碳烯酸含量的遗传。结果表明,芥菜型油菜芥酸含量 和廿碳烯酸含量的遗传行为与甘蓝型油菜十分相似。二者均受种子的胚基因型控制,与母体植株的基 因型无关。芥酸含盘受两对显性效应很小的加性基因控制,廿碳烯酸受两对具有重叠作用的显性基因 控制。低芥酸总是与低廿碳烯酸相联系。世代均值分析表明,芥酸符合加性显性模型,以加性效应为 主。廿碳烯酸不符合加显模型,但符合二基因互作模型,基因效应以显性作用为主。     

甘蓝型油菜芥酸含量的主基因＋多基因遗传

应用植物数量性状主基因＋多基因混合遗传模型对甘蓝型油菜无芥酸品种HSTC     

甘蓝型油菜芥酸含量的SSR标记分析

目的：探讨高芥酸材料与低芥酸材料杂交效果,为促进高芥酸油菜育种的研究。方法：采用高芥酸材料与低芥酸材料杂交的F2群体作为材料,研究其遗传性状,并对亲本间的芥酸含量进行了SSR标记分析。结果：发现F2群体中的单株芥酸含量受两对基因控制,其遗传规律符合由一对基因控制的分离比例,得到CB10364、Ra2-E12两个共显性标记。结论：CB10364标记与芥酸含量紧密连锁,单株带型为CB10364-a的芥酸含量〈6%,单株带型为CB10364-h的芥酸含量6%～36%,带型为CB10364-b的芥酸含量〉36%,能较好的区分群体的芥酸含量,该结果可促进高芥酸油菜的育种研究。     

甘蓝型油菜芥酸含量的SSR 标记分析

目的:探讨高芥酸材料与低芥酸材料杂交效果,为促进高芥酸油菜育种的研究。方法:采用高芥酸材料与低芥酸材料杂交的F2群体作为材料,研究其遗传性状,并对亲本间的芥酸含量进行了SSR标记分析。结果:发现F2群体中的单株芥酸含量受两对基因控制,其遗传规律符合由一对基因控制的分离比例,得到CB10364、Ra2-E12两个共显性标记。结论:CB10364标记与芥酸含量紧密连锁,单株带型为CB10364-a的芥酸含量<6%,单株带型为CB10364-h的芥酸含量6%～36%,带型为CB10364-b的芥酸含量>36%,能较好的区分群体的芥酸含量,该结果可促进高芥酸油菜的育种研究。     

人工合成甘蓝型油菜中花色与芥酸含量的遗传连锁分析

利用人工合成的甘蓝型油菜品系．No．2127-17(白花、有芥酸)与加拿大双低甘蓝型油菜品种Quantum(黄花、低芥酸)配制杂交组合。对亲本、F1、BC1、F2和DH(doubled haploid)5个世代的花色及芥酸含量进行分析,结果表明：花色受单基因控制,且白花对黄花为显性;芥酸含量仅表现出一对基因的差异且具有加性效应的遗传模式。花色和芥酸含量的连锁分析表明：白花与高芥酸紧密连锁．在DH群体中重组频率为5．8％。采用集团分离分析法(Bulked Segregant Analysis,BSA),从685条10个碱基的随机引物筛选到一个与黄花和低芥酸含量紧密连锁的RAPD标记S92-1400。在遗传图谱上黄花基因和低芥酸基因距离S92-1400标记的图距分别为2．2cM和5．4cM。     

环氧二十碳三烯酸与肺部疾病的研究进展

环氧二十碳三烯酸(epoxyeicosatrienoic acids,EETs)是一种具有强大生物活性的内生脂质环氧化合物.EETs在肺组织疾病中具有抗炎症反应、抗氧化活性、诱导肺血管收缩、促进细胞增殖等作用,可成为多种肺部疾病防治的新型靶点.本文就EETs的作用机制及其在肺部疾病中的研究进展进行了归纳总结.     

甘蓝型油菜主要农艺性状的遗传模型和基因效应分析

本文以甘蓝型优质油菜(81008×Tower)正反交各12个世代的资料,按照4种不同的遗传模型,对包括单株产量在内的8个农艺性状的遗传方式进行了详尽地分析。结果表明:所有性状的遗传皆不符合简单的加性-显性模型,上位性效应普遍存在,且对世代平均数有较大影响;单株产量及几个产量性状的遗传均受重复型互作基因的控制,杂种优势需利用三基因或多基因间的互作效应。     

不同芥酸含量油菜品系FAD2基因克隆测序分析

对高芥酸品系M136、0Coγ辐照得到的高芥酸油菜突变体H27和低芥酸品系742的FAD2基因克隆并测序。结果发现,FAD2基因存在两个拷贝FAD2.1(1155bp)、FAD2.2(1140bp)。H27的FAD2.1与M13序列相同,但FAD2.2核苷酸序列中M13在409位点A(腺嘌呤)变成了T(鸟嘌呤),导致密码子由AGA变换为TGA(终止密码子),使H27中的FAD2.2基因的功能丧失,这可能是芥酸含量的提高原因。     

陕北黄芥芥酸含量的主基因+多基因遗传分析

以吴旗黄芥×长安芥菜组合的6个世代P1、P2、F1、B1、B2和F2群体为材料,利用植物数量性状主基因+多基因模型的多世代联合分析方法研究了该组合芥酸含量的遗传特征.结果表明:吴旗黄芥×长安芥菜组合芥酸含量受2对加性-显性-上位性主基因+加性-显性-上位性多基因(E模型)控制.主基因效应中,加性效应大于显性效应,第一对主基因加性效应(da)和显性效应(ha)分别为-4.718 0和4.419 5;第二对主基因的加性效应(db)和显性效应(hb)分别-4.005 8和2.023 7;2对主基因对芥酸含量的贡献差异较大,第二对主基因加性和显性效应之和占第一对主基因加性和显性效应之和的65.98%;2对主基因间存在一定的互作效应(绝对值在0.338 7～3.694 1),其中第一对主基因显性×第二对主基因加性效应(jba)较大,为3.694 1.B1、B2和F2群体芥酸含量主基因遗传率分别为68.83%、44.76%和87.99%;多基因遗传率分别为20.29%、41.21%和0,F2代表现出较高的遗传力,可在早期世代对芥酸含量进行选择.     

甘蓝型油菜含油量的主基因+多基因遗传效应分析

应用多世代联合分析数量性状主基因和多基因混合遗传的统计方法,分析了甘蓝型油菜两个组合的5个世代——亲本P1、P2、F1、F2和F2：3家系材料含油量的遗传效应。结果表明,分离世代F2及F2：3家系含油量次数分布均呈混合的正态分布,符合主基因＋多基因的遗传特征。D-2模型是该项研究两个甘蓝型油菜杂交组合含油量的最适遗传模型,含油量的遗传是由一对加性主基因和加-显性多基因共同控制的。组合1（1141Bx垦C1-1）主基因加性效应值为-1．74,表明亲本1141B中主基因位点上的等位基因降低含油量,而亲本垦C1-1中的等位基因增加含油量。多基因加性效应值和显性效应值分别为1．20和-1．93;F2的主基因遗传力和多基因遗传力分别为68．21％和27．17％;F2：3的主基因遗传力和多基因遗传力分别为81．70％和16．80％。组合2（32Bx垦C1-2）主基因加性效应值为-3．74,表明亲本32B中主基因位点上的等位基因降低含油量,而亲本垦C1-2中的等位基因增加含油量。多基因加性效应值和显性效应值分别为-1．99和0．93;F2的主基因遗传力和多基因遗传力分别为66．20％,和28．10％;F2：3的主基因遗传力和多基因遗传力为81．00％和14．90％。两组合在F2：3家系世代含油量的主基因遗传力均较F2高,因此认为高含油量育种中在F2：3家系进行选择效率较高。     

甘蓝型油菜矮秆突变材料99CDAM的发现及遗传分析

随着杂种优势的利用,油菜株高增加了20cm以上,导致油菜生长后期倒伏的风险加大。通过利用特殊矮秆基因来控制株高将是解决倒伏问题的有效方法。在甘蓝型油菜自交多代品系中发现了一个株高85cm左右的矮秆突变株99CDAM,该突变株具有开花早、分枝多等优良特性,产量性状和品质性状较好,各性状都能稳定遗传,具有重要的育种价值。对99CDAM和高秆品系2091、7045和7350的正反交F1以及99CDAM和2091的F2、BC1及F2:3代的遗传分析结果表明： 99CDAM的矮秆性状受3对隐性基因控制,存在母体细胞质效应,与以往的甘蓝型矮秆油菜有明显的区别。     

Very long chain and hydroxylated fatty acids in offspring of somatic hybrids between Brassica napus and Lesquerella fendleri

 Offspring of somatic hybrids between the zero-erucic acid rapeseed cv Hanna and Lesquerella fendleri were analysed regarding their fatty acid profiles. In the first back-cross generation one plant was found that produced a seed containing up to 16.5% erucic acid and 15% eicosaenoic acid (Line 1), as well as a seed having 4.3% ricinoleic acid (Line 2). This was interpreted as due to a contribution of elongase and hydroxylase genes from the L. fendleri genome since these two fatty acids are not produced in the recipient rapeseed cultivar Hanna. Crosses between Line 1 and cv Hanna resulted in the production of seeds with 35% erucic acid (F₂). Furthermore, crosses between the F₂ plants and the rapeseed cultivar Gulle, producing 35% erucic acid in the seeds, resulted in F₃ seeds with 48% erucic acid. The highest amount of erucic acid, 61.5%, was found in the F₆ generation after crossing Line 1 with a high erucic acid rapeseed line, HEAR, followed by self-fertilisation for two generations. When performing Southern-blot analysis on the F₆ plants, seven of the nine analysed plants hybridised with the L. fendleri species-specific repetitive probe. The presence of the hydroxylase gene was also observed in the F₆ generation of Line 1 according to Southern-blot analysis. Hybridisation with a hydroxylase probe was seen although no hydroxy fatty acids could be detected in any of the F₆ plants. In parallel, Line 2 was crossed with HEAR cv Gulle and self fertilised. No hydroxy fatty acids were detected in the F₂ generation of Line 2 and no specific hybridisation patterns could be found in the Southern-blot analysis. Received: 12 December 1998 / Accepted: 4 January 1999     

Evidence for spontaneous diploid androgenesis in Brassica napus L.

Summary Seeds of androgenetic origin were obtained among the F₁ progenies of two crosses between resynthesized and cultivated forms of Brassica napus. The high-erucic, white-flowered, resynthesized line No7076 acted as the female, and the zero-erucic, yellow-flowered, cultivars Topas and Puma, as males. No androgenetic seeds were obtained in the reciprocal crosses. Resynthesized rape could thus be of potential use for the production of androgenetic plants. Of special interest is the high frequency (21%) of spontaneous androgenesis observed in one of the two crosses. One plant, determined from erucic acid content and flower colour analysis as androgenetic, had a diploid chromosome number. Further knowledge about the genetic control of spontaneous androgenesis in the present material and the origin of the cytoplasm in androgenetic plants are required in order to exploit this phenomenon in practical plant breeding.     

油菜BnMKK4全长基因的克隆及表达分析

从‘陇油6号’油菜中克隆得到了一个新的BnMKK4基因的cDNA,全长1317bp,其中包括993bp的开放阅读框,159bp的5’非翻译区（5^1UTR）,165bp的3。非翻译区（3’UTR）。与拟南芥AtMKK4有很高的同源性,因此命名为BnMKK4（GenBank登录号JF268686）。该基因编码330个氨基酸的蛋白质,分子量36．5kDa,等电点为9．01。实时荧光定量PCR结果显示该基因表达受低温胁迫和盐胁迫的诱导,表明该基因在油菜适应低温胁迫和盐胁迫的过程中发挥作用。     

Intergeneric Somatic Hybridization Between Brassica napus L. and Sinapis alba L.

Electrically induced protoplast fusion was used to produce somatic hybrids between Brassica napus L. and Sinapis alba L. Seven hybrids were obtained and verified by the simple sequence repeat and cleaved amplified polymorphic sequence analysis of the genefael, indicating that the characteristic bands from S. alba were present in the hybrids. The hybridity was also confirmed by chromosome number counting because the hybrids possessed 62 chromosomes, corresponding to the sum of fusion-parent chromosomes. Chromosome pairing at meiosis was predominantly normal, which led to high pollen fertility,ranging from 66% to 77%. All hybrids were grown to full maturity and could be fertilized and set seed after self-pollination or back-crosses with B. napus. The morphology of the hybrids resembled characteristics from both parental species. An analysis of the fatty acid composition in the seeds of F1 plants was conducted and the seeds were found to contain different amounts of erucic acid, ranging from 11.0% to 52.1%.