甘蓝型油菜隐性细胞核雄性不育的研究及利用

甘蓝型油菜隐性细胞核雄性不育系育性稳定、无负效应、易转育且恢复源广,在油菜杂种优势利用中被广泛利用.目前我国主要利用的隐性细胞核雄性不育系有2类:双基因隐性细胞核雄性不育以及由2对基因互作控制的核不育类型.随着这2类不育系不育基因相继被克隆,人们对甘蓝型油菜细胞核雄性不育的分子作用机理已经有一定了解.本文综述了在甘蓝型油菜核不育分子机理的研究方面的进展,在此基础上提出了繁殖甘蓝型油菜核不育系全不育系群体可行的途径,展现了油菜细胞核雄性不育杂种优势利用广阔的前景.     

EMS诱变甘蓝型油菜M_2代群体的表型突变研究

利用4种浓度EMS处理甘蓝型油菜NJ7982种子,选取其中诱变效果好的处理(0.4%EMS),研究其后代突变型和突变频率。对4.8万株的M2代群体鉴定结果表明,6种器官性状在群体中均出现了突变。子叶突变性状包括3子叶、子叶黄化等,占群体的0.22%;叶片突变性状包括黄化叶、白化叶、紫色叶、上卷叶、下卷叶等,占0.74%;花器突变性状包括紫色花蕾、死蕾、3花瓣、6花瓣、白色瓣、花瓣黄白镶嵌、花瓣皱缩、完全不育、部分可育等,占9.38%;株型突变性状包括矮秆、紫茎等,占4.98%;角果突变性状包括粗角、长角、紫角等,占2.79%;种皮黄色,占0.40%;总的表型突变频率为18.51%。这些遗传多样性的突变材料,为甘蓝型油菜种质创新及品种遗传改良提供基础性材料。     

合成甘蓝型油菜中双隐性雄性核不育材料的发现及遗传规律分析

从甘蓝型油菜与白菜型油菜的种间杂交获得的甘蓝型油菜(Brassica napus)中发现了雄性不育单株,兄妹交株系和不育株与甘蓝型油菜常规杂交F1和F2株系的育性分离分析表明,该不育材料属于双隐性雄性核不育类型.利用育性分离株系的可育株自交和可育株与不育株间兄妹交等方法筛选出7个纯合可育株系,等位测验表明这7个纯合可育株系(B1～B7)中存在两种基因型:Ms1Ms1ms2ms2和ms1ms1Ms2MS2.该材料对油菜核不育基因定位和杂种优势利用研究有重要意义.     

甘蓝型油菜新型不育系花器特征及mtDNA的RAPD分析

对新选育的甘蓝型油菜PL CMS不育系和Pol CMS及Ogu CMS不育系材料花器形态进行比较,并对3种不育系10份材料mtDNA进行RAPD分析.结果表明,新选育的PL CMS不育系与Pol CMS、Ogu CMS在花瓣长和宽、花冠直径、雄蕊大小等形态特征方面有极显著差异;mtDNA分析结果表明,新发现的细胞质雄性不育材料L04-02A、L04-05A、L04-01A为同一类型的细胞质雄性不育系,它们与Pol CMS及Ogu CMS不育材料有很大差异,由此推知PL CMS不育系是一种新型甘蓝型油菜不育系.     

一种新型无花瓣油菜突变不育系花器官的形态解剖研究

在自育的甘蓝型油菜(Brassica napus)无花瓣品系AP197中, 发现并育成由4对隐性核基因控制的无花瓣油菜突变不育系AMS971。AMS是一种雄蕊心皮化为不结实的假性雌蕊而引起的新的雄性不育类型, 不育性非常彻底, 其植株形态特征与AP197相同。比较花器官发现, AMS971除一个正常的雌蕊外,还有6个梭形的心皮化假性雌蕊。假心皮化雌蕊上部变成近似倒U形的柱头结构区, 下部是完全突变的半开裂心皮, 其上着生4~14个不等的裸露的幼小胚珠; 蜜腺比正常油菜小, 数目为0~4个, 这与AP197没有差异。AMS971的四轮花器官由于突变造成了大小和重量的重新分配。推断AMS为类似拟南芥属B功能缺失的突变体。     

一种新型无花瓣油菜突变不育系花器官的形态解剖研究

在自育的甘蓝型油菜(Brassica napus)无花瓣品系AP197中,发现并育成由4对隐性核基因控制的无花瓣油菜突变不育系AMS971.AMS是一种雄蕊心皮化为不结实的假性雌蕊而引起的新的雄性不育类型,不育性非常彻底,其植株形态特征与AP197相同.比较花器官发现,AMS971除一个正常的雌蕊外,还有6个梭形的心皮化假性雌蕊.假心皮化雌蕊上部变成近似倒U形的柱头结构区,下部是完全突变的半开裂心皮,其上着生4～14个不等的裸露的幼小胚珠;蜜腺比正常油菜小,数目为0～4个,这与AP197没有差异.AMS971的四轮花器官由于突变造成了大小和重量的重新分配.推断AMS为类似拟南芥属B功能缺失的突变体.     

远缘杂交油菜核不育系的创建及其细胞学和形态学研究

在甘蓝型油菜与诸葛菜以及芥菜型油菜与诸葛菜属间杂交后代中分别发现1个和3个不育材料,经杂交和多代近交育成了相应的甘蓝型油菜不育系。通过对核不育系体细胞鉴定表明,所有新发现的不育系染色体数为38,均已恢复到甘蓝型油菜。这些不育系绝大部分花粉母细胞（PMC）在中期Ⅰ、后期Ⅰ和后期Ⅱ 3个时期染色体行为表现正常,但不同时期的PMC均会出现一定比例的异常现象,主要表现为染色体落后或染色体桥等。这些不育系属于单核败育型,不育株与可育株的花器形态差异明显,不育系还存在不同程度的死蕾等特点。通过对花器生长过程的研究,发现不育株雌蕊生长随雄蕊败育进程逐渐加快,而可育株雌蕊生长则存在两个生长缓慢阶段。此外,文章还讨论了这些不育系的应用前景。     

芥菜型油菜细胞质雄性不育系WJS01A的比较鉴定北大核心CSCD

芥菜型油菜细胞质雄性不育(CMS)系WJS01A是一种稳定不育系,其败育彻底,不受环境条件的影响。该研究从形态、细胞特征、遗传和分子生物学等方面对WJS01A进行鉴定,以揭示其败育机制,为该不育系在油菜育种中的应用提供理论基础。结果表明:(1)不育系WJS01A的花序结构与正常芥菜型油菜差异不大,但在花蕾饱满度、花朵张开度及花瓣长度和宽度方面略低于正常的芥菜型油菜;它的雌蕊发育正常,但花药、花丝缩短,致使雄蕊高度显著低于柱头,花药白化无花粉产生。(2)将WJS01A衍生的甘蓝型油菜背景不育系WNJ01A以及Polima(Pol)、Ogura(Ogu)和Kosena(Kos)不育系分别与其恢复系或保持系测交,结果显示来源于WJS01A的不育类型与Pol、Ogu和Kos等材料的恢保关系明显不同,仅Hui01可以恢复WNJ01A的育性。(3)不育系WJS01A属于无花粉囊型不育,败育时期为花药原基到孢原细胞时期。(4)线粒体不育基因多重PCR可以明显区分WJS01A、WNJ01A与Pol、Ogu、Kos,但是目前的引物组合不能区分WJS01A与正常的芥菜型油菜。(5)线粒体基因组的限制性片段长度多态性(RFLP)分析表明,在所检测的8个探针/酶组合中均可以将不育系WJS01A与其他4种细胞质雄性不育系区分开,说明WJS01A是一种显著不同于Pol、Ogu和Kos等的细胞质雄性不育类型。WJS01A的利用可以丰富和拓宽当前油菜杂种优势利用的遗传基础,为缓解当前油菜杂种优势利用中不育胞质单一性问题提供新的种质。     

无花瓣油菜雄蕊心皮化突变体细胞学观察及基因表达分析

油菜是我国重要的油料作物,油菜花器官具有典型的十字花科特点,无花瓣油菜在花期不存在花冠层,这种特点有助于提高油菜产量,预防茵核病的传播。雄蕊心皮化是指花器官的雄蕊结构被具有类似于雌蕊结构的器官代替,这不仅造成了花器官结构的变化也导致了雄性不育。本文通过对无花瓣油菜雄蕊心皮化突变不育分离群体中的雄性可育株和不育株的比较研究,发现心皮化现象是由遗传因素引起的。细胞学观察发现,雄蕊心皮化在花器官发育的早期就已经产生,心皮化的雄蕊中着生类似于胚珠的结构,其顶端细胞的形态和排列方式也与雌蕊柱头相似。花发育相关基因的表达分析表明,B组基因彳丹在不育株3轮花器中的表达都比可育株低,特别是在第二轮花器官中这种差异最为突出。而A组基因AP1在不育株第二轮花器官中的表达量较可育株高。c组基因AGL8、SHPI、SHP2、NAP在不育株心皮化的第二轮花器官中表达都较可育株中高。     

谷子显性雄性核不育基因的发现与利用

植物界的雄性不育现象绝大部分都是由隐 性雄性不育基因控制的。1978年我们在澳大利 亚谷和吐鲁番谷的杂交后代中发现一份雄性不 育材料。从1978-1984年7个世代的遗传表 现为：和400个谷子普通品种杂交,其不育株 自由授粉、其不育株和分离出来的可育株杂交、 和原父回交,F,就出现育性分离,不育与可育的 比率都为1：1;其可育株后代育性不分离;其不 育株自交子一代育性分离,不育与可育的比率 为3:1。如此证明,这份雄性不育材料的不育 性是受显性雄性不育基因控制的。     

谷子雄性不育系1066A不育基因和黄苗基因的染色体定位

以谷子(Setaria italica (L.) Beauv.)雄性不育系1066A为母本,豫谷1号三体(1～7)及四体8和四体9作父本进行杂交,应用初级三体分析法,进行了谷子雄性不育基因和黄苗基因的染色体定位研究.通过配置大量杂交组合和反复授粉,利用豫谷1号三体的极少量花粉,获得了三体2～9的F1代杂种,各杂种三体的形态与豫谷1号三体基本相似,略有差异,苗色呈绿色且可育.杂种F2植株的苗色和育性都产生分离.结果是三体3、5、7、8、9的F2代分离出的可育株与不育株之比为3∶1,三体6的可育株与不育株之比为14∶1 (χ2=0.012,P=0.01).杂种F2分离出的绿苗与黄苗之比只有三体7为12∶1 (χ2=0.36, P=0.01),其他均为3∶1.因此,可以确定1066A的不育基因为隐性单基因,位于第6号染色体上,该品系的黄苗基因也是隐性单基因,位于第7号染色体上.     

茄子功能性雄性不育的遗传及其与果紫色基因连锁关系的研究

采用新育成的茄子功能性雄性不育系uGA 1-MS和2个栽培品种,进行双亲本杂交世代遗传试验,发现F_1和B_2代植株皆雄性正常,B_2和F_2代可育株和不育株呈1:1和3:1分离,表明茄子功能性雄性不育性状由单隐性基因支配,用基因符号fms表示。连锁测验数据表明基因+/fms与果紫色基因X/x紧密连锁。预期该雄性不育性可在茄子杂种优势育种和种子生产上加以利用。     

蛋用鹌鹑伴性羽色基因互作与连锁的关系

本研究首次发现了鹌鹑伴性羽基因的基因互作关系并进行了遗传验证.试验证明,鹌鹑的栗羽、黄羽和白羽是Z染色体上两个有连锁关系的基因座B/b和Y/y相互作用的结果.B和b为一对等位基因,不控制任何性状,只与色素的合成有关,B为有色基因,b为白化基因,B对b为显性;Y和y为另一对等位基因,分别控制栗羽和黄羽,Y对y为显性.栗羽和黄羽的表现取决于有色基因B的存在,B与Y相互作用产生栗羽,B与y相互作用产生黄羽,白羽是白化基因b对Y和y上位作用的结果.B/b和Y/y两基因座在雄性表现出一定的互换率,在雌性为完全连锁.这一研究补充和发展了以前人们对鹌鹑羽色伴性遗传的研究,为人们利用鹌鹑羽色进行自别雌雄配套系生产提供了重要的遗传学基础。 Abstract:The interaction of sex-linked gene for plumage color in quails was first discovered and identified by genetictest.It was proved that the phenotypic expressions of the maroon feather,the yellow feather and the white feather result from the interaction between B/b and Y/y loci in the Z-chromosome.The allele B and b have something to do with the composition of pigment in plumage and nothing to do with any relative characters,the coloured gene B is dominant to its albino allele b.The maroon and yellow feather constituted a pair of relative characters determined by a couple of alleles Y and y,the maroon feather was caused by a dominant allele Y,and the yellow feather caused by a recessive allele y.But the phenotypic expression of maroon and yellow was decided by the present of the coloured gene B in Z-chromosome,the maroon feather was the result of interaction between gene B and Y,the yellow feather was result of interaction between gene B and y.The white was caused by a recessive albino gene b which epistasis to gene Y and y.The incomplete linkage was present between B/b and Y/y in Z-chromosome in male and complete linkage in female.This research enriches and delelops the earlier studies of the sex-linked inheritance of plumage color.It provides an important genetic basis for the quail autosexing system production by means of plumage color.     

甘蓝型油菜雄性不育系160S育性转换与利用

以甘蓝型油菜雄性不育系160S为试验材料,分别在自然栽种和人工控温条件下对其花器官形态变化、花粉育性转换和杂种优势等进行了初步研究,以探讨植物温敏雄性不育的发生机制。结果表明:环境温度对160S的花器官形态及育性转换具有明显的作用,高温可使花瓣变小,雄蕊退化,花粉活力、角粒数与自交有效结角率降低,表现为低温可育、高温不育,育性变化趋势表现为完全可育-半不育-彻底败育。160S恢复源广泛,且具有较好的配合力和杂种优势,为利用两系法生产油菜杂交种提供了一个较好的途径。     

矮败蓝标型小麦不育系的选育与研究

利用蓝粒太谷核不育硬粒小麦89-2343[AABB 4D(MS2)/4E]与普通小麦7739-3(2n=42)杂交、回交所产生的蓝粒可育株与白粒矮败材料杂交、回交,育成了一份矮败蓝粒小麦.选用13份遗传背景不同的白粒普通小麦与之杂交、回交,育成了13份矮败蓝粒小麦.对后代的粒色和育性分离进行分析,蓝粒矮败不育株占22.1%,白粒非矮秆可育株占77.7%,表明蓝粒基因、Ms2和Rht10均位于附加染色体上,且连锁紧密;但不同轮回亲本,矮败蓝粒的传递率有差异,477A的传递率最高,接近50%.细胞学分析表明矮败蓝粒小麦仍为单体附加系;探讨了矮败蓝粒小麦在群体改良和杂种小麦生产中的应用.     

Genetics and cytology of a new genic male-sterile soybean [Glycine max (L.) Merr.]

 Genetic and cytological studies were conducted with a new male-sterile, female-fertile soybean [Glycine max (L.) Merr.] mutant. This mutant was completely male sterile and was inherited as a single-recessive gene. No differences in female or male gamete transmission of the recessive allele were observed between reciprocal cross-pollinations in the F₁ or F₂ generations. This mutant was not allelic to any previously identified soybean genic male-sterile mutants: ms1, ms2, ms3, ms4, ms5, or ms6. No linkage was detected between sterility and flower color (W1 locus), or between sterility and pubescence color (T1 locus). Light microscopic and cytological observations of microsporogenesis in fertile and sterile anthers were conducted. The structure of microspore mother cells (MMC) in male-sterile plants was identical to the MMCs in male-fertile plants. Enzyme extraction analyses showed that there was no callase activity in male-sterile anthers, and this suggests that sterility was caused by retention of the callose walls, which normally are degraded around tetrads at the late tetrad stage. The tapetum from male-sterile anthers also showed abnormalities at the tetrad stage and later stages, which were expressed by an unusual formation of vacuoles, and by accumulation of densely staining material. At maturity, anthers from sterile plants were devoid of pollen grains. Received: 13 May 1996 / Revision accepted: 19 August 1996     

A new source of cytoplasmic male sterility in maize induced by the nuclear gene,iojap

Summary Cytoplasmic male sterility (cms) was found in plants derived from the F₂ progeny of fertile, normal cytoplasm plants of the inbred R181 pollinated with a genetic stock carrying the recessive nuclear gene, iojap. The male sterile plants were maintained by back-crossing with the inbred W182BN which maintains all known sources of cytoplasmic male sterility. The new male sterile progeny were found to exhibit stable male sterility under field conditions in two environments. However, they were partially fertile in the hot, dry summer of 1983 at Aurora, NY. It was found that these lines were restored by lines that characteristically restore cms S group cytoplasms. Pollen phenotype studies indicated that the restoration was gametophytic in nature, also characteristic of the cms S group. Agarose gel electrophoresis of undigested mitochondrial DNA (mtDNA) from these steriles indicated that these lines have the S-1 and S-2 episomes characteristic of the cms S group. Restriction endonuclease digest patterns of mtDNA from these sterile lines digested with BamH I indicated that these steriles fit into the CA subgroup of the cms S group. The new source of cms has been designated cms Ij-1.     

欧报春（Primula vulgaris）不同花色与色素关系及花色遗传初步分析

为了掌握欧报春各花色遗传规律服务于良种生产,通过对欧报春各色花进行色素吸收光谱和薄层层析分析,进行不同花色杂交研究,分析了欧报春各色花所含色素类型及各花色遗传规律。结果显示欧报春群体含多种花色素,单株也可含有多种花色素,形成多变的粉色、红色及蓝色花。黄色深浅主要由类胡萝卜素含量决定。白色对粉色及黄色为隐性遗传,黄色、粉色为显性遗传并有数量遗传特征,黄色与粉色独立遗传。蓝色为多基因控制的隐性遗传,并具有数量遗传特征。     

Antisense inhibition of a nuclear gene,BrDAD1, in Brassica causes male sterility that is restorable with jasmonic acid treatment

Male sterility is widely used for the production of hybrid seeds, but the use of genic male sterility is rather limited because of difficulty in maintaining homozygous male sterile plants. Recently, the DEFECTIVE IN ANTHER DEHISCENCE 1 (DAD1) gene, which encodes a phospholipase A1 involved in the first step of the jasmonic acid (JA) biosynthesis pathway, was isolated from a male sterile Arabidopsis mutant. To utilize this gene in Brassica crops, we characterized the BrDAD1 gene, the putative ortholog of DAD1 in Brassica rapa. Out of 25 plants transformed with an antisense gene constructed from the BrDAD1, 3 plants showed a defect of anther dehiscence at the flower bud opening stage and produced inviable pollen. One of the three showed male sterility only, but the other two showed a delay or a lack of flower opening in addition to male sterility. The male sterile and flower-opening phenotypes were rescued by the application of JA as well as linolenic acid. Furthermore, all these characteristics were inherited to the next generation. The present results demonstrate a novel control system for hybrid seed production by the use of nuclear genes.