几类异源细胞质1B/1R、非1B/1R型小麦雄性不育系育性恢复性的比较研究

利用具有粘果山羊草 Aegilops kotschyi 、易变山羊草 Ae.variabilis 、偏凸山羊草 Ae.ventricosa 和二角山羊草 Ae.bicornis 异源细胞质的粘、易、偏和二角型 1B/ 1R、非 1B/ 1R型小麦雄性不育系为母本 ,一些优良小麦品种 系 为父本进行杂交 ,就 4类异源细胞质 1B/ 1R、非 1B/ 1R型不育系的育性恢复性进行比较研究 ,结果表明 : 1 4类异质 1B/ 1R、非 1B/ 1R型杂种自交结实率均低于相应普质杂种 ,说明由于核质不协调 ,4类异源细胞质对不育系育性恢复表现出一定的负效应 ; 2 非 1B/ 1R型杂种自交结实率明显高于 1B/ 1R型杂种 ,并达极显著差异 ,说明恢复性除受异源细胞质影响外 ,还与核内染色体核型密切相关 ; 3 非 1B/ 1R型杂种恢复度均在 6 5 %以上 ,大于 80 %的组合占 6 0 %以上 ,且变异范围较小 ,有望进一步研究利用 ; 4 1B/ 1R型杂种恢复度不高且变异较大 ,与1B· 1B/ 1R杂合染色体在减数分裂过程中的异常行为密切相关 ;而非 1B/ 1R型杂种由于不含 1B· 1B/ 1R杂合染色体 ,减数分裂过程中染色体行为相对稳定 ,易恢复且恢复度高 ,很有实际利用前景     

粘类小麦细胞质雄性不育系的RAPD分析

利用250条10-聚寡核苷酸随机引物对具粘果山羊草(Aegilops kotschyi)、易变山羊草(Ae.variabilis)、偏凸山羊草(Ae.ventricosa)和二角山羊草(Ae．bicornis)细胞质不育系及其保持系5-1的总DNA进行了RAPD多态性分析,其中31条引物对4种不育系及其保持系总DNA均无扩增,217条引物扩增条带完全相同。有2条随机引物在2种不育系之间有特异的扩增片段,其中引物S22在偏凸山羊草细胞质雄性不育系基因组DNA中扩增出分子量约为1600bp的特异带,引物S202在粘果山羊草细胞质雄性不育系基因组DNA中扩增出约1300bp特异带。线粒体基因组DNA的RAPD分析表明,4种不育系及其保持系mtDNA存在明显的差异。证明了S22—1600为偏凸山羊草细胞质不育系及其mtDNA基因组DNA的RAPD特异片段．S202—1300可能为粘果山羊草细胞质不育系及其ctDNA基因组DNA的RAPD特异片段。     

二角山羊草细胞质小麦雄性不育系的育性特异性分析

利用大量小麦亲本材料和优良品种(系)与具有粘果、易变、偏凸和二角山羊草细胞质的小麦雄性不育系杂交,并对其杂交F1过氧化物同工酶进行了分析,结果表明：(1)二角山羊草细胞质与小麦核内的遗传物质组成两个不同的核质互作不育系统,粘、易、偏型不育系育性基本表现一致,而二角型不育系除了与前三种不育系具有相同的1BL／1RS保持系以外,对某些小麦近缘植物的杂交后代材料还表现出育性特异性。(2)粘、易、偏和二角型同核异质不育系5-1及其与V9125杂交F1过氧化物同工酶分析表明,粘、易、偏和二角型不育系5-1过氧化物同工酶带型基本表现一致,粘、易、偏不育系5-1与V9125杂交F1过氧化物同工酶带型基本表现一致,而二角型不育系5-1杂交F1过氧化物同工酶则表现出酶带减少变弱。     

山羊草属不同细胞质对小麦籽粒蛋白含量及组分的影响研究

以山羊草属（Aegilops)6种不同异源细咆质的异质小麦品系Chris为材料,与生产上广泛种植的9个常规小麦品种正反杂交,系统地研究了供试6种蚌源细胞质对其F1籽粒蛋白含量的影响,同时对单芒山草(Ae．uniaristata)、二角山羊草(Ae.bicorins)细胞质对籽粒蛋门组分含量的影响亦进行了研究。结果表明：(1)在以6种异源细胞质材料为母本的杂交组合中,78%的组合其蛋白含量高于反交对照。尤以单芒、二角山羊草细胞质的正效应最为显著,平均提高2个以上百分点,最高达3．7个百分点。(2)供试单芒、二角异源细胞质对籽粒清蛋白和球蛋白的含量影响最大,对醇溶蛋白和谷蛋白含量的影响相对较小,其效应值大小因特定组合而异。(3)供试异源细胞质对籽粒蛋白质含量和组成的影响均存在显著的核质互作效应。通过异源细胞质的途径来改良小麦籽粒的蛋白含量和组分是一条有效可行的方法,只要选择合适的核质组合即可达到改良目的。     

APAGE技术在小麦细胞质雄性不育系选育中的应用研究

利用大量小麦亲本材料和优良品种(系)与具有粘果、易变、偏凸和二角山羊草细胞质的小麦雄性不育系杂交,筛选出一系列保持系。利用APAGE(酸性聚丙烯酰胺凝胶电泳)技术对其进行了醇溶蛋白电泳图谱分析,发现大部分保持系表现出1BL/lRS易位系的1RS醇溶蛋白标记位点GldlB3。利用细胞学镜鉴,发现含有GldlB3标记位点的保持系均只含有两个随体,而不含有GldlB3标记位点的保持系均含有4个随体,证明了GldlB3标记位点与两个随体数的一致性。粘、易、偏型不育系育性基本表现一致,而二角型不育系除了与前3种不育系具有相同的保持系以外,对某些小麦品种(系)还表现出育性特异性。同时还讨论了ANGE技术在快速筛选小麦细胞质雄性不育保持系中的作用,为非1BL/1RS不育系的选育提供了必要的手段。     

二角型非1B/1R 小麦CMS不育恢复体系的建立

通过对具有二角山羊草细胞质的1B/1R型小麦雄性不育系m s(A e.bicorn is)-5-1回交置换,获得了新型二角山羊草细胞质小麦雄性不育系m s(A e.bicor)-V 9125和m s(A e.bicor)-M 853.利用染色体制片、分子标记、原位杂交和酸性聚丙烯酰胺凝胶电泳对其保持系V 9125和M 853进行分子细胞遗传学检测,并对其育性恢复性机理进行了初步研究.结果表明:(1)V 9125和M 853均为非1B/1R易位系.V 9125为小麦-簇毛麦易位系,m s(A e.bicor)-V 9125是二角山羊草细胞质与普通小麦核背景中簇毛麦外源染色体互作产生的一类新的核质互作不育系.(2)M 853为小麦-滨麦易位系,m s(A e.bicor)-M 853是二角山羊草细胞质与普通小麦核背景中滨麦外源染色体互作产生的一类新的核质互作不育系.(3)利用一些普通小麦品种(系)与这两个不育系杂交,m s(A e.bicor)-V 9125和m s(A e.bicor)-M 853仅与T 6-3杂交育性得到恢复,且恢复度较高,变异小,而与其它大部分普通小麦杂交F1表现雄性不育,且扬花期花药不外露.而m s(A e.bicor)-5-1与包括T 6-3在内的普通小麦品种(系)杂交F1育性得到不同程度的恢复.从而得出结论,二角山羊草细胞质与小麦细胞核的互作存在两个不同的不育-恢复系统.     

两类二角山羊草细胞质小麦雄性不育系的细胞学研究

对具有二角山羊草(Aegilops bicornis)细胞质的同质异核1BL／1RS型小麦雄性不育系ms(Ae．bicornis)-5-1和非1BL／1RS不育系ms(Ae．bicornis)一V9125进行了花药发育细胞学分析。幼穗染色体制片显示,1BL／1RS不育系ms(Ae．bicornis)-5—1减数分裂正常,非1BL／1RS不育系ms(Ae．bicornis)-V9125减数分裂期染色体排列不整齐,出现不正常的四分体和含微核的小孢子。花药发育的细胞学观察表明,1BL／1RS不育系ms(Ae．bicornis)-5—1表现为染败,花药各壁层的发育是正常的;BC3代的非1BL／1RS不育系ms(Ae．bicornis)-V9125表现为园败,且发生了药室合并现象,从细胞学角度证明了二角型小麦不育系存在两个核质互作不育系统。     

“缺体回交法”选育普通小麦—山羊草异代换系的研究

利用从兰单体自交分离得到的5个自花结实的4D缺体小麦(映72180、块天选15等)作母本与11个山羊草(Ae.speltoides, Ae.sharonensis等)杂交,再以4D缺体为轮回亲本对杂种进行回交,借助于幼胚培养技术,获得了缺天选15×拟斯卑尔脱山羊草二体异代换系,缺72180×沙融山羊草单体异代换系。代换系生长发育良好,育性基本正常,表明山羊草的4S染色体能够补偿小麦缺失的4D染色体的功能。证明利用“缺体回交法”选育普通小麦—山羊草异代换系是有效的和可行的。     

基因从普通小麦向山羊草属植物漂移可能性研究

分别以山羊草属4个不同的种为母本,以普通小麦为父本杂交,将获得的杂种再进行回交和自交。结果表明,不同种与普通小麦的可交配性存在较大差异,在人工多次授粉并有激素处理的条件下,粗山羊草与普通小麦的杂交结实率最高,2个基因型Ae42和Y92的杂交结实率分别为46.49%和22.58%;其次为卵穗山羊草,2个基因型Ae23和Y100的杂交结实率分别为12.11%和14.76%;柱穗山羊草位列第3,2个基因型Ae7和Y145的杂交结实率分别为2.23%和8.50%;拟斯卑尔脱山羊草最低,基因型Ae48的杂交结实率只有0.19%。不同种的杂种胚产生愈伤组织率不同,柱穗山羊草/小麦表现较高的水平,卵穗山羊草/小麦次之,粗山羊草/小麦第3,拟斯卑尔脱山羊草/小麦最低。卵穗山羊草/小麦的杂种幼胚直接成苗率最高,其次为粗山羊草/小麦,柱穗山羊草/小麦居第3位。山羊草与普通小麦杂种的育性较低,在自然状态下,只有卵穗山羊草/小麦能够自交结实,但自交结实率仅为0.044%,其他杂种自交不能结实。在人工多次授粉并激素处理条件下,用父、母本回交的结实率:卵穗山羊草/普通小麦组合分别为4.36%和3.71%,柱穗山羊草/普通小麦组合分别为0...     

普通小麦三种细胞质雄性不育系线粒体DNA的比较研究

对细胞质分别来源于粘果山羊草（Ａｅ．ｋｏｔｓｃｈｙｉ）、偏凸山羊草（Ａｅ．ｖｅｎｔｒｉｃｏｓａ）、提莫菲维（Ｔ．ｔｉｍｏｐｈｅｅｖｉ）的３种普通小麦雄性不育系,其相应保持系和共有的一种恢复系的ｍｔＤＮＡ进行了ＲＦＬＰ比较分析。发现Ｋ型和Ｖ型不育系的ｍｔＤＮＡ在组织结构上不同于Ｔ型,说明Ｋ、Ｖ型不育系是有别于Ｔ型的两种新不育类型。Ｋ型、Ｖ型不育系的ｍｔＤＮＡ与保持系和恢复系显著不同,推测ｍｔＤＮＡ与小麦细胞质雄性不育性有关。实验同时发现Ｔ型不育系与其保持系的ｍｔＤＮＡ非常相似,对这种相似性的原因进行了讨论。     

粘类非1BL/1RS小麦CMS基因定向选择及其育性特性的研究

对携有不同不育基因的4个粘类小麦雄性不育系进行了定向选择与鉴定,并对其育性特性进行研究,以选育更具应用价值的粘类非1BL/1RS小麦雄性不育系,推动三系杂交小麦的实际应用.结果表明:(1)根尖体细胞随体鉴定和A-PAGE技术分析筛选出的SP4、莫迦小麦为非1BL/1RS类型,其它供试不育系均属于1BL/1RS类型;(2)减数分裂及成熟花粉粒形态观察,粘类非1BL/1RS小麦雄性不育系其不育性是在整个配子发育过程中连续产生的,且在B型不育细胞质背景下,SP4和莫迦小麦的花粉细胞学形态与在K、Ven型2种不育细胞质背景下的不同,B型不育细胞质背景下SP4和莫迦不育系的花粉萌发率比K、Ven型不育细胞质背景下的花粉萌发率高;(3)以不同来源不育基因培育成的粘类K、Ven型非1BL/1RS不育系育性恢复性测定发现,SP4、莫迦小麦2种雄性不育系育性恢复性有一定差异,莫迦小麦不育类型育性恢复性高于SP4.     

Structural and Expressional Variation Analyses of Mitochondrial Genomes Reveal Candidate Transcripts for the SV Cytoplasmic Male Sterility in Wheat (Triticum aestivum L.)

Common wheat (Triticum aestivum L.) is one of the most important crops,and intra-specific wheat hybrids have obvious heterosis in yield and protein quality.Therefore,utilization of hybrid wheat varieties offers an effective way to increase yield and nutrition.Cytoplasmic male sterility (CMS) systems are a useful genetic tool for hybrid crop breeding,and are ideal models for studying the genetic interaction and cooperative function of mitochondrial and nuclear genomes in plants (Schnable and Wise,1998;Hanson and Bentolila,2004).The breeding of hybrid wheat using male sterility caused by the cytoplasm of T.timopheevii has been studied since the early 1960's.But it is unsuccessful because there are some deficiencies in the practical application of this cytoplasm,including limited restoration resources,thin seeds,pre-harvest sprouting and lower germination rate (Wilson and Ross,1962).The Sv type of cytoplasmic male sterility (CMS-Sv) in wheat is general accessions for four types of CMS lines that were derived from four Aegilops species:Ae.kotschyi,Ae.variabilis,Ae.ventricosa,and Ae.bicornis.Based on the observation of alloplasmic lines produced in all possible combinations between 12 wheat nuclear genotypes and 47 cytoplasms of two related genera,Triticum (wheat) and Aegilops,Ogihara and Tsunewaki (1988) concluded that the D2-cytoplasm of Ae.crassa and its relatives,N-cytoplasm of Ae.uniaristata,and SV-cytoplasm of Ae.kotschyi and its relatives might be used as the alternative male sterile cytoplasm to replace the T.timopheevii cytoplasm for hybrid wheat breeding.Ikeguchi et al.(1999) proposed that spring-type hybrid wheat may be bred by combination of the 1BL-1RS chromosome and Ae.kotschyi cytoplasm with a new fertility-restorer gene discovered in a wheat variety Kitamiharu 48.Zhang et al.(1996) also proposed the use of CMS-Sv lines as the most effective male sterile cytoplasm.     

几类异质1BL／1RS小麦雄性不育系诱导孤雌生殖性的研究

系统调查了4种异质（即偏凸,粘果,易变和二角山羊草细胞质）1BL/1RS小麦雄性不育系与其一系列异质同核系,同质异核系,异质异核系杂交,回交世代诱导孤雌生殖性的遗传变异规律,染色体分裂行为和对外表现特点,结果表明：1、异源细胞质与小麦1BL/1RS核型专一互作,有着消弱同源染色体配对,提高中期单价体细胞率的作用;2、特定细胞质背景下,专一核型内细胞单价体频率高低与诱导孤雌生殖性的频率直接相关;3、1BL/1RS易位染色体中易位片所存在系列差异以及1BL/1RS易位染色体外基因型背景不同,诱导孤雌生殖性的频率明显不同;4、提高或抑制不同杂交,回交世代间孤雌生殖频率,不育系母本或不同基因型父本有着同等重要的作用。选择最佳父母本组合杂交可明显提高或降低后代群体中的孤雌生殖性频率。     

几类异质小麦雄性不育系育性恢复性的细胞遗传学研究

系统调查了4类异质(粘果、易变、偏凸、二角山羊草细胞质)1BL/lRS、非1BL/1RS小麦雄性不育系与其恢复系杂种F减数分裂中期Ⅰ出现单价体细胞频率,以及后期Ⅰ出现落后染色体和染色体桥细胞频率,并对中、后期染色体变异率与杂种F自交结实率进行了相关分析.结果表明(1)1BL/1RS型杂种在中期Ⅰ、后期Ⅰ染色体变异率要明显高于非1BL/1RS杂种;(2)4类异源细胞质在非1BL/1RS杂种中有着明显提高单价体细胞频率的作用;(3)在1BL/1RS杂种中,1B@1BL/1RS杂合核型染色体联会松弛,对单价体频率的影响远大于异源细胞质的影响;(4)1BL/1RS型杂种自交结实率与中期出现单价体细胞频率不直接相关,而与后期出现落后染色体和染色体桥细胞的频率呈高度负相关;(5)非1BL/1RS型杂种在减数分裂中、后期染色体行为相对稳定,易恢复且恢复度高,很有实际利用价值.     

Cytoplasmic effects on DNA methylation between male sterile lines and the maintainer in wheat (Triticum aestivum L.)

Male sterile cytoplasm plays an important role in hybrid wheat, and three-line system including male sterile (A line), its maintainer (B line) and restoring (R line) has played a major role in wheat hybrid production. It is well known that DNA methylation plays an important role in gene expression regulation during biological development in wheat. However, no reports are available on DNA methylation affected by different male sterile cytoplasms in hybrid wheat. We employed a methylation-sensitive amplified polymorphism technique to characterize nuclear DNA methylation in three male sterile cytoplasms. A and B lines share the same nucleus, but have different cytoplasms which is male sterile for the A and fertile for the B. The results revealed a relationship of DNA methylation at these sites specifically with male sterile cytoplasms, as well as male sterility, since the only difference between the A lines and B line was the cytoplasm. The DNA methylation was markedly affected by male sterile cytoplasms. K-type cytoplasm affected the methylation to a much greater degree than T-type and S-type cytoplasms, as indicated by the ratio of methylated sites, ratio of fully methylated sites, and polymorphism between A lines and B line for these cytoplasms. The genetic distance between the cytoplasm and nucleus for the K-type is much greater than for the T- and S-types because the former is between Aegilops genus and Triticum genus and the latter is within Triticum genus between Triticum spelta and Triticum timopheevii species. Thus, this difference in genetic distance may be responsible for the variation in methylation that we observed.     

QTL analysis of fertility-restoration against cytoplasmic male sterility in wheat

The cytoplasm of Triticum timopheevi causes cytoplasmic male sterility (CMS) in common wheat (T. aestivum) cv. 'Chinese Spring' (CS), and that of Aegilops kotschyi causes CMS in spelt wheat (T. spelta) var. duhamelianum (Sp). CS has fertility-restoring (Rf) genes against the latter cytoplasm and Sp has the ones against the former. To know the genetic system concerning to CMS, we crossed 66 F8 recombinant inbred lines (RILs) derived from a cross between CS and Sp as males to the alloplasmic lines of CS and Sp having the cytoplasms of T. timopheevi and Ae. kotschyi, respectively. The fertilities of respective F1 plants derived from the crosses were examined for QTL analysis. The major QTLs detected in both systems were located on the short arm of chromosome 1B. One minor QTL on chromosome 2B was also commonly detected in both of the systems, while other minor QTLs against T timopheevi cytoplasm were distributed on the chromosomes 2A, 4B, and 6A.