在杂交作物分子育种中利用普通核雄性不育的几个可能途径

由一对隐性基因控制的普通核雄性不育性遗传方式能够满足对植物最佳雄性不育系选育的要求,是水稻等作物杂种优势利用的极好遗传工具。如果能解决其不育系繁殖问题,将优于现有的其他杂种优势利用方式。克隆出普通核雄性不育性的可育基因,通过叶绿体转化,将核雄性不育性可育基因向普通核雄性不育株细胞质转移,创造普通核雄性不育株的保持系;通过种子成熟后表达的启动子;和以位点特异性重组技术为基础的基因开关以及化学诱导启动子的利用,都可能繁殖出100％不育株率的普通核雄性不育系,创造普通核雄性不育性利用的新途径,对植物杂种优势利用产业有十分重要的意义。     

在杂交作物分子育种中利用普通核雄性不育的几个可能途径

由一对隐性基因控制的普通核雄性不育性遗传方式能够满足对植物最佳雄性不育系选育的要求,是水稻等作物杂种优势利用的极好遗传工具。如果能解决其不育系繁殖问题,将优于现有的其他杂种优势利用方式。克隆出普通核雄性不育性的可育基因,通过叶绿体转化,将核雄性不育性可育基因向普通核雄性不育株细胞质转移,创造普通核雄性不育株的保持系;通过种子成熟后表达的启动子;和以位点特异性重组技术为基础的基因开关以及化学诱导启动子的利用,都可能繁殖出100%不育株率的普通核雄性不育系,创造普通核雄性不育性利用的新途径,对植物杂种优势利用产业有十分重要的意义。     

植物核型雄性不育在我国的研究现状及其应用展望

利用植物雄性不育性生产杂交种子,使多种作物获得杂种优势,以达到增产的目的,是现代农业科学最主要的成就之一。早在50年代末和60年代初,中国科学院遗传研究所就从美国引进了高粱三系(3197A,3197B,恢复系五号),并在我国率先进行了植物雄性不育遗传理论的研究和运用这种制种技术获得杂种优势,为国家增产粮食的示范推广工作,使全国广大育种工作者从实践中认识到这一有别于传统的杂交育种工作的优越性,从而掀起了全国性的利用植物雄性不育获得杂种优势的育种高潮。     

转基因雄性不育油菜选育的简介

转基因雄性不育油菜选育的简介彭仁旺,周雪荣,方荣祥,陈正华,莽克强（中国科学院微生物研究所,北京１０００８０;中国科学院遗传研究所,北京１００１０１）杂种优势的利用是作物生产中用以提高产量、改进品质的重要措施之一,通过雄性不育系培植杂种是杂种优势利用...     

棉麻纤维作物雄性不育研究进展及展望

棉麻是我国重要天然纤维作物。本文对我国棉麻作物雄性不育的类型、雄性不育的选育及雄性不育的机理等研究进展进行了综述,并讨论了棉麻作物雄性不育研究发展方向与杂种优势利用有关问题,同时提出了雄性不育系选育的思路。     

转基因雄性不育系及其在杂种种子生产上的应用

雄性不育为农作物杂种优势的利用开辟了一条经济有效的途径。本综述了利用生物技术培育转基因雄性不育的多种策略,以及繁育用作大田配制杂交种的母本雄性不育系的新方法;探讨了其应用于商业化杂种生产的重要性及前景。     

玉米花药发育的细胞生物学与分子遗传学的研究方法

雄性不育技术在玉米杂种优势利用和杂交种生产中发挥着重要作用,玉米花药发育和雄性不育的细胞生物学与分子遗传学研究是雄性不育技术利用的前提和基础。玉米花药发育是一个复杂的生物学过程,需要孢子体基因与配子体基因的协同表达调控。从玉米花药的形态结构、花药发育时期的划分、花药败育类型、花药发育的细胞学研究方法、花药发育的组学研究方法、花药发育分子遗传学研究方法等方面进行综述,以期为玉米核不育机制研究与雄性不育技术产业化应用提供方法学指导。     

玉米核雄性不育的分子机制研究与应用分析

玉米细胞核雄性不育突变体是研究花粉发育和减数分裂的理想材料,也是杂种优势利用的重要种质资源。随着分子生物技术的快速发展,部分玉米细胞核雄性不育基因陆续被成功克隆,为其在工程不育化杂交种生产中的应用奠定了基础。综述了近年来对玉米细胞核雄性不育的细胞学鉴定、基因克隆和分子机制的研究进展,并对其应用途径和前景进行了分析。     

小麦雄性不育研究进展

雄性不育是植物中的一种普遍现象,而雄性不育是利用杂种优势提高作物产量和品质的基础,因此小麦雄性不育的理论机制研究对农业生产具有重要的指导意义.对小麦雄性不育类型及遗传、生理生化不育机制、定位及分子生物学研究进行了综述,并探讨了今后该领域的研究前景.     

雄性不育在作物杂种优势中的应用途径分析

雄性不育是植物雄性细胞或生殖器官丧失生理机能的现象,该现象的利用大大提高了杂交种生产的效率。植物雄性不育包含细胞质雄性不育、不受环境影响的核雄性不育、光温敏型雄性不育及化学诱导的雄性不育。这些不育类型也已经被以三系或二系的方式应用于很多作物的杂交种生产中。综述了雄性不育各个途径的研究进展及其在作物杂种优势中的应用。     

Effects on Fertility in Transgenic Tobacco by Localized Expression of ipt Gene

The isopenteryl transferase (ipt) gene from Agrobacterium tumefaciens (Smith et Townsend) Conn was driven under the tobacco TA29 promoter and introduced into tobacco ( Nicotiana tabacum L.) plants by A. tumefaciens mediated transformation. PCR and Southern blot analysis confirmed that the ipt gene has integrated into the genomes of tobacco plants. The expression pattern of this chimeric TA29-ipt gene in the transgenic plants was studied, and the endogenous cytokinin level in different organs was assayed by ELISA method. The results showed that the cytokinin content in the androecium of transgenic plants increased 3-4 times as compared with the control, and some changes of the fertility of the TA29-ipt transgenic plants have been observed.     

Anther-specific expression of ipt gene in transgenic tobacco and its effect on plant development

Isopentenyl transferase (ipt) gene from Agrobacterium tumefaciens T-DNA was placed under the control of a TA29 promoter which expresses specifically in anther. The chimeric TA29-ipt gene was transferred to tobacco plants. During flowering, mRNA of the ipt gene in the anthers of the transgenic plants accumulated and the level of iPA + iPs increased 3–4-fold in the leaves, petals, pistils, and stamens compared with those in the wild type plants. This cytokinin increase affected various aspects in development indicating that the alterations of endogenous cytokinin level by using anther-specific expression of the TA29-ipt gene affected morphology, floral organ systems and reproductivity of the transgenic plants.     

水稻谷蛋白启动子驱动下的ipt基因在转基因烟草中的表达

利用农杆菌系统介导 ,采用叶盘转化法 ,将在水稻谷蛋白启动子驱动下的外源ipt基因导入烟草植株中 ,经过抗生素筛选、PCR与测序分析检测出转基因植株。成熟的转基因烟草种子经过ELISA细胞分裂素试剂盒检测 ,发现iPAs含量为对照的 2 .43倍 ,此外 ,种子的重量也增加了 7.8%。     

Inducible isopentenyl transferase as a high-efficiency marker for plant transformation.

Overexpression of the isopentenyltransferase gene (ipt) from the Ti-plasmid of Agrobacterium tumefaciens increases cytokinin levels, leading to generation of shoots from transformed plant cells. When combined with a dexamethasone-inducible system for controlling expression, ipt expression can be used to select for transgenic regenerants without using an antibiotic-resistance marker. The combined system allows efficient cointroduction of multiple genes (in addition to ipt) and produces transgenic plants without morphological or developmental defects.     

The Role of Cytokinin Biosynthetic Gene in Regulating the Expression of a Class of Pathogenesis-Related Protein Genes in Tobacco Plants

The expression characteristics of a class of pathogenesis-related protein (PR) genes, namely basic chitinase, β-1, 3-glucanase, osmotin and extensin, were studied in tobacco (Nicotiana tabacum cv. Wisconsin 38) plants. RNA blot hybridization showed that these four genes were regulated in a developmental and organ-specific manner in tobacco. In the transgenic fascicular shoots which contained the active cytokinin biosynthetic gene (ipt gene) from Agrobacterium tumefaciens, the expressions of these four genes were co-regulated by overproduction of endogenous cytokinins and vector effect. Cytokinins reduced the expressions while vector effect induced the expressions of these four genes. Heat shock also de creased the steady-state levels of the four RNAs. These data suggest a complex regulation of PR genes.     

Induction of Male Sterility in Oilseed Rape by TA29-Barnase Gene

Chimaeric TA29-Barnase gene was introduced into oilseed rape (Brassica napus) of good quality and high yield by Agrobacteriurn tumefaciens transformation. The transgenic plants were obtained and transformed genome was determined by Southern blot analysis. About 90~/40 TA29-Barnase transgenic plants were male sterile. However, about 80% transgenic plants turned to be male fertile at temperature higher than 25 ℃. It suggested that male sterility of these transgenic plants was probably temperature sensitive.     

Male Sterile Tobacco Plants Obtained by Genetical-Engineering

Chimaeric TA29-barnase gene was obtained by fusing tobacco anther-specific promoter TA29, barnase gene and NOS terminator and was inserted into a plant expression yector containing bromoxynil-resistant bxn gene and then introduced into tobacco plants. Some transgenic tobacco plants were resistant to 1.0 × 10-3 mol/L bromoxynil. At about 26℃, all of the 9 transgenic plants were male fertile; However, at 20℃, 7 out of 11 transgenic plants were male sterile.