受辐照窄颖赖草花粉DNA进入小麦胚囊的电镜自显影证据及杂种原位杂交鉴定

采用3H 胸腺嘧啶标记窄颖赖草 (Leymusangustus)花粉结合电镜自显影的方法证明受辐照窄颖赖草花粉DNA进入了小麦胚囊 ,运用基因组原位杂交技术证明所得杂种为真杂种 ,经辐照花粉获得的普通小麦J 1 1与窄颖赖草杂种中窄颖赖草染色体发生了数目和结构变异     

小麦-鹅观草易位系T7A/1Rk#1的选育与鉴定

将小麦-鹅观草del1Rk#1L二体添加系的花粉用10 Gy 60Co γ射线照射处理,给小麦中国春授粉,获得杂种。综合利用C-分带、GISH、顺次C带/45SrDNA-FISH和顺次GISH/45SrDNA-FISH等分子细胞遗传学技术在M2代筛选和鉴定出1个涉及小麦7A和鹅观草1Rk#1染色体的相互易位染色体系,并获得1Rk#1染色体的1个45SrDNA位标,该位标和其对应的红色GISH-带纹能够特异地识别1Rk#1染色体短臂。对M2代群体染色体组成分析和测交分析表明,两条易位染色体在后代中以共分离方式成对出现,且易位通过雌配子的传递率高于雄配子。综合2004、2005和2006 3年的赤霉病抗性鉴定结果表明：该易位系对赤霉病表现部分抗病,但抗性表现在不同年份、不同地点有差异。试验还证明花粉辐射是诱导小麦-外缘物种染色体易位的有效方法。     

甘薯近缘野生种Ipomoea trifida(4x) GISH分析

以甘薯近缘野生种I. trifida (2x)为探针, 与I. trifida (4x) 2个株系“695104”和“697288”的体细胞染色体进行基因组荧光原位杂交, 结果显示, 2株系都与I. trifida (2x)有很近的亲缘关系, 但2株系的信号存在差异。“695104”几乎所有染色体整条都有均匀明亮的信号, 应为I. trifida (2x)基因组直接加倍而来;而 “697288”与“695104”不同, 虽然各条染色体也均有杂交信号, 但信号的区域与亮度有差异, 较为复杂, 可分为三种情况。第1种是整条染色体有均匀明亮的信号, 亮度与分布区域同“695104” , 有41条;第2种是几乎整条染色体有信号, 但亮度较第一种暗, 有14条;第3种为染色体部分区域有信号, 亮度较前二者更暗, 有5条。推测 “697288”是在加倍同时或之后又发生了基因组重组与部分变异。     

小麦-滨麦2D/2Ns异代换系DM2411的分子细胞遗传学鉴定

为进一步挖掘利用滨麦优异基因,并丰富小麦遗传种质资源,利用形态学、细胞遗传学、基因组原位杂交(Genomic in situ hybridization,GISH)、EST-STS分子标记、SSR分子标记等技术,对从八倍体小滨麦M842-16和硬粒小麦D4286杂交F_7代材料中筛选出的1个遗传稳定的小滨麦异代换系DM2411进行了鉴定。细胞遗传学观察表明,DM2411的染色体主要构型为2n=42=21Ⅱ,遗传稳定。根尖体细胞和花粉母细胞的原位杂交研究表明,DM2411含有1对滨麦Ns基因组。SSR分析表明,DM2411可能缺失了小麦2D染色体。EST分析表明,DM2411可能含有滨麦2Ns染色体。形态学调查表明,DM2411的株高极显著降低。     

栽培稻、斑点野生稻、药用野生稻基因组比较分析

以栽培稻总DNA为探针,对栽培稻(AA)自身、斑点野生稻(BB)以及药用野生稻(CC)体细胞染色体进行基因组荧光原位杂交(GISH),并以斑点野生稻总DNA为探针,对自身和药用野生稻体细胞染色体进行基因组荧光原位杂交,以此研究A、B、C 3个基因组型之间的关系.结果显示,A、B、C基因组之间都存在较高的同源性,其中AA与CC之间的信号最强,BB基因组与AA基因组次之,BB基因组与CC基因组的信号最弱.说明A、B、C 3个基因组之间的亲缘关系,A与C最近,B与C最远.     

栉孔扇贝和虾夷扇贝杂交子代的GISH鉴定及其免疫学特性

以栉孔扇贝[Chlamys farreri（Jones et Preston）]（♀）和虾夷扇贝（Patinopecten yessoensis）（♂）杂交子代担轮幼虫为材料，分别用栉孔扇贝和虾夷扇贝基因组作探针，采用基因组荧光原位杂交（GISH）的方法，对杂交后代杂交子的确切身份进行初步鉴定。结果表明，子代分别继承了双亲各一套染色体（n=19），为真正的杂交种。为了解杂交扇贝的免疫学特性，在自然海域栉孔扇贝大规模死亡的情况下，分别对杂交扇贝及其亲本3个扇贝群体血细胞的胞内活性氧含量（ROIs）、血清凝集素效价（HA）、溶菌酶活力（LSZ）、抑菌活力、酚氧化酶活性（P0）、过氧化氢酶（CAT）、超氧化物歧化酶（SOD）以及酸性磷酸酶（ACP）和碱性磷酸酶（ALP）等9种非特异性免疫学指标进行测定。结果表明，栉孔扇贝除ROIs、SOD、ACP等3个指标显著低于虾夷扇贝外（P〈0．01），其他6种指标均高于虾夷扇贝，且除血清凝集素效价外均达显著水平（P〈0．05）。在杂交子代中，上述免疫指标除SOD活性低于低值亲本外（P〉0．6），其余8种免疫指标均介于双亲之间。杂交子代在9种免疫指标中有8种与母本无显著性差异，而子代与父本之间9种免疫指标中有7种达显著差异（P〈0．05）。这些结果说明，杂交扇贝在非特异性免疫上存在明显的偏母性特征，这点与子代在外形特征上的偏母性相吻合。因此杂交扇贝相对于其母本在生产实践中表现出的一定程度的抗逆优势可能与非特异性免疫无明显关系。[中国水产科学，2006，13（4）：597—602]     

小麦 黑麦大穗型衍生后代的分子细胞学鉴定

为创制大穗型小麦种质材料,利用具有大穗多小穗性状的小麦-黑麦双二倍体材料"兰小黑"和普通小麦杂交得到一批大穗型衍生后代.综合采用基因组原位杂交(GISH)、SCAR标记、微卫星(SSR)和醇溶蛋白(A-PAGE)技术对这些大穗型后代中的8个单株进行分子细胞学鉴定.结果表明,GISH检测后代含2个外源信号;1RS特异SCAR标记检测后代均含有黑麦1.5 kb的1RS特征条带;醇溶蛋白检测后代都出现了黑麦碱基因Sec-1特征条带.筛选小麦21条染色体长短臂上各6对引物,结果发现只有1BS上的3对引物未扩增出1BS的条带,其余引物均扩增出了各自的相应条带.由此确定这8株小麦-黑麦大穗型衍生后代为1BL/1RS易位材料.     

Genomic structure of androgenic progeny of pentaploid hybrids, Festuca arundinacea × Lolium multiflorum

To assess the usefulness of the doubled haploid (DH) method in the breeding of forage grasses, a sample of anther-derived progeny of pentaploid F₁ hybrids of Festuca arundinacea × Lolium multifiorum was karyotyped using genomic in situ hybridization (GISH). The technique allowed scoring of the total number of chromosomes, the number of chromosomes contributed by each parent, and the number and positions of the Festuca-Lolium translocation breakpoints. Among 27 plants analysed, 13 belonged to three clones, effectively reducing the number of different progeny karyotyped to 17. These included 10 haploids, five doubled haploids and two plants for which the origins could not be explained. In all plants analysed, a mixture of chromosomes of both parents was present, including an average of 1.88 intergeneric translocations per plant. The translocation breakpoints were distributed along almost the entire length of the chromosome arms. Chromosome variation among androgenic progeny appeared much wider than that in the conventional backcross but low vigour and high mortality suggest that this additional variation may be difficult to exploit directly in breeding. However, a change in the pattern of recombination makes the entire genome accessible to manipulation.     

Characterization of a wheat–Thinopyron intermedium substitution line with resistance to powdery mildew

Among the progenies of a hybrid between common wheat Triticum aestivum L. cv. Yannong 15 and Thinopyron intermedium, plant E99018 was identified with the chromosome number 2n = 42 and stable agronomic traits. An analysis of the metaphase chromosome pairing indicated that it formed 21 bivalents but that 2 univalents were present in the F₁ hybrid of this plant with common wheat. Resistance verification by race 15 and with mixed races of Blumeria graminis f. sp. tritici at the seedling and adult stages showed that at both stages, the plant was immune to powdery mildew. In situ hybridization with the genomic Th. intermedium and the St genome DNAs as probes and wheat DNA as a block has shown that it contained a pair of Th. intermedium chromosomes. On the basis of the hybridization pattern of the St genome probe to the critical chromosome, a conclusion was reached that this pair of chromosomes belonged to the E genome. Therefore, plant E99018 was a spontaneously formed substitution line. An analysis by 116 SSR markers indicated that the substituted wheat chromosome was 2D and the most likely substitution in E99018 is 2E(2D).     

Designing grasses with a future – combining the attributes of Lolium and Festuca

Lolium species (considered the ideal grasses for European agriculture) are not sufficiently robust to meet many of the environmental challenges that face extensive agriculture in less favoured areas. Fortunately, adaptations to abiotic and biotic stresses exist amongst Festuca species related closely to Lolium. The complex of species has an enormous wealth of genetic variability and potentiality for genetic exchange, thus offering unique opportunities for the production of versatile hybrid varieties with new combinations of useful characters suited to modern grassland farming. The attributes of Lolium and Festuca can be combined into a single genotype by amphiploidy or alternatively, a limited number of characters can be selectively introgressed from Festucainto Lolium or vice versa. Androgenesis of the interspecific hybrids can generate genotypes combining characters that may not be recovered by sexual backcrossing. Genomic in situ hybridization(GISH) can differentially ‘paint’ the chromosomes of Lolium and Festuca and identify Lolium-Festuca recombinant chromosomes. GISH is valuable in the analysis of amphiploids, introgressions and androgenic genotypes and can be used to physically map introgressed traits. Introgression mapping is a powerful new approach to the mapping of traits and arises from a fusion of physical and genetic mapping. For example, in a diploidLolium introgression genotype with only one introgressed Festucasegment, the gene(s) for any Festucaderived trait expressed by the plant must be located within the segment. Using GISH and molecular markers, a dense but highly localised map of the Festuca segment is made in isolation of the Loliumgenome – this may simplify QTL analysis. This revised version was published online in July 2006 with corrections to the Cover Date.