雄性不育基因工程及其在园艺植物中的应用

利用基因工程创造植物雄性不育是近年研究的活跃领域之一。本文较全面地综述了创造雄性不育的各种基因工程途径,包括通过核酸酶基因的特异空间表达、使胼胝质提前降解、利用反义基因、改变某些激素含量与比例、导入细胞质雄性不育的有关基因、将特异启动子与催化产生某种毒素的酶基因结合转化植物、通过共抑制、通过双重转基因系杂交及一些新的设想如RNAi、凋亡;及上述不育系的保持与恢复的各种基因工程途径,包括利用引起雄性不育基因的抑制基因、利用雄性不育基因的反义基因、通过化学调控、利用定位重组系统。文中还尽可能列出了上述技术在园艺植物中的应用情况,并就该技术存在的问题与发展前景进行了探讨。     

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。     

基因工程培育可恢复的植物雄性不育系的研究进展

植物雄性不育是植物杂种优势利用的资源, 具有重要的生产利用价值。植物雄性不育可从自然突变、人工诱变和远缘杂交中发现, 现在可通过细胞工程和基因工程等方法来创造。文章综述了利用基因工程方法制备雄性不育品系及其相应的育性恢复策略, 分为“单组分策略”和“双组分策略”。其中利用“单组分策略”制备的不育植株是条件型雄性不育(可逆转的雄性不育), 它能在特定的条件下实现雄性可育与不育的转换, 实践中可直接作为两用系(不育系和保持系)用于两系法杂交制种; “双组分策略”是利用基因互作和亲本杂交直接培育雄性不育系, 或利用基因互作原理分别研制不育系和恢复系, 用于三系法生产杂交种。文章分析了 “单组分策略”和“双组分策略”的基因工程方法培育雄性不育系及其相应育性恢复策略优缺点, 对以上两种技术路线在实际应用中的现状作了分析和展望。     

植物雄性不育基因的研究进展

本文概述了植物雄性核不育基因的分子标记及其定位,综述了植物细胞质雄性不育中不育系与保持系在叶绿体和线粒体基因组的结构、转录和翻译产物方面的差异以及和雄性不育之间的可能关系,以及恢复系中的恢复基因分子水平的研究现状;讨论了环境条件如光周期和温度对雄性不育的影响在分子水平上的研究现状,指出了植物雄性不育基因研究方面存在的问题和解决的思路。     

植物雄性不育基因的研究进展

本文概述了植物雄性核不育基因的分子标记及其定位,综述了植物细胞质雄性不育中不育系与保持系在叶绿体和线粒体基因组的结构、转录和翻译产物方面的差异以及和雄性不育之间的可能关系,以及恢复系中的恢复基因分子水平的研究现状;讨论了环境条件光周期和温度对雄性不育的影响在分子水平上的研究现状,指出了植物雄性不育基因研究方面存在的问题和解决贩思路。     

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。     

植物雄性不育基因工程的研究及应用(综述)

本文基于植物花粉花药的发育分子生物学研究成果,介绍了几种创造基因工程核雄性不育系和胞质雄性不育系的途径,保持与恢复基因工程雄性不育系的途径和雄性不育基因工程应用中亟待解决的问题.     

植物细胞质雄性不育性与育性恢复的分子生物学研究进展

植物细胞质雄性不育性与育性恢复的分子机理一直是分子生物学的研究热点。文章综述了近十年来的主要研究进展。包括：1、线粒体不育相关区域的确定及其特点;2、不育相关区域的表达谱;3、产生细胞质雄性不育的可能机理;4、恢复基因的可能调控方式;5、恢复基因的遗传、定位及其特征等。拟兰芥、水稻等模式植物线粒体基因组测序工作已经完成,其有关生物学信息及后续研究将极大地推动植物细胞质雄性不育研究取得更快进展。     

植物基因互作型显性核不育材料的新假说

植物基因互作型显性核不育材料的新假说刘秉华（中国农业科学院作物育种栽培研究所北京１０００８１）植物雄性不育是一种常见的自然现象,有的受遗传基因控制,有的则由于外界环境条件影响所致。显性基因控制的雄性不育称为显性核不育。在通常情况下,显性核不育材料的异...     

植物细胞质雄性不育及其育性恢复的分子基础

植物细胞质雄性不育是广泛存在于高等植物中的现象,其表现为母性遗传、花粉败育,但雌蕊正常。细胞质雄性不育在杂交种子生产中起着重要作用,研究其分子作用机制有利于更有效地利用细胞质雄性不育。随着一些不育基因和恢复基因相继被克隆,人们对一些细胞质雄性不育和恢复系统的分子作用机理已经有一定了解。本文综述了近年来对植物细胞质雄性不育基因和恢复基因作用机理研究的进展。     

基因工程（核）雄性不育小麦研究展望

基因工程是创造核雄性不育基因的一个新途径。通过综述大量资料,探讨了利用基因工程创造雄性不育的机制,并论述了其在小麦上应用的可能性及发展前景。     

Combination of reversible male sterility and doubled haploid production by targeted inactivation of cytoplasmic glutamine synthetase in developing anthers and pollen

Reversible male sterility and doubled haploid plant production are two valuable technologies in F₁-hybrid breeding. F₁-hybrids combine uniformity with high yield and improved agronomic traits, and provide self-acting intellectual property protection. We have developed an F₁-hybrid seed technology based on the metabolic engineering of glutamine in developing tobacco anthers and pollen. Cytosolic glutamine synthetase (GS1) was inactivated in tobacco by introducing mutated tobacco GS genes fused to the tapetum-specific TA29 and microspore-specific NTM19 promoters. Pollen in primary transformants aborted close to the first pollen mitosis, resulting in male sterility. A non-segregating population of homozygous doubled haploid male-sterile plants was generated through microspore embryogenesis. Fertility restoration was achieved by spraying plants with glutamine, or by pollination with pollen matured in vitro in glutamine-containing medium. The combination of reversible male sterility with doubled haploid production results in an innovative environmentally friendly breeding technology. Tapetum-mediated sporophytic male sterility is of use in foliage crops, whereas microspore-specific gametophytic male sterility can be applied to any field crop. Both types of sterility preclude the release of transgenic pollen into the environment.     

小麦雄性不育遗传及基因定位研究进展

雄性不育的研究对于杂种优势的利用具有重要意义。本文综述了小麦雄性不育遗传及基因定位研究进展,介绍了小麦雄性不育的基因工程,对小麦雄性不育的应用进行了讨论。 Abstract:The study of plant male sterility plays an important role on utilization of heterosis.This paper reviews the current status of the studies of the heredity and mapping of the male sterile genes in wheat and the gene engineering of wheat male sterility.The application of male sterility in wheat breeding is discussed.     

The molecular biology of cytoplasmically inherited male sterility and prospects for its engineering

Nucleocytoplasmic male sterilities are binary genetic systems driven by mitochondrial, maternally inherited genes that induce male sterility and a female phenotype and which are overcome by nuclear restorers of fertility. They contribute to the reproductive biology and evolution of natural populations and are valuable tools for the commercial production of hybrid seeds in crops. For species with no natural form of cytoplasmic male sterility, such sterility can in some cases be introduced from different, but related, species through sexual crosses or somatic hybridisation. Somatic hybridisation is the only technique currently available for manipulating plant mitochondrial genomes. Recent successes in plastid transformation have opened up entirely new perspectives for the engineering of cytoplasmic male sterilities in transplastomic plants.     

利用基因工程创造植物雄性不育的策略

本文对利用基因工程创造植物雄性不育系和恢复系的研究进展进行了综述,并对其在杂种优势利用中的应用前景进行了展望。 Abstract：The progress in studies on induction of male sterili ty and restorer line in plant by gene engineering was reviewed.The prospects on application of this method in heteriosis utilization were discussed.     

Genetically engineered cytoplasmic male sterility

Cytoplasmic male sterility, conditioned by some maternally inherited plant mitochondrial genomes, is the most expedient method to produce uniform populations of pollen-sterile plants on a commercial scale. Plant mitochondrial genomes are not currently amenable to genetic transformation, but genetic manipulation of the plastid genome allows engineering of maternally inherited traits in some species. A recent study has shown that the Acinetobacter beta-ketothiolase gene, expressed in the Nicotiana tabacum plastid, conditions maternally inherited male sterility, laying the groundwork for new approaches to control pollen fertility in crop plants.     

雄性不育基因工程及其在蔬菜上的应用

基因工程是创造雄性不育的一种新途径。概述了雄性不育基因工程的主要方法 ,并且对利用基因工程创造蔬菜雄性不育系和恢复系的研究进展进行了综述 ,探讨了这一技术在蔬菜上的应用前景。     

Silencing of phosphoethanolamine N-methyltransferase results in temperature-sensitive male sterility and salt hypersensitivity in Arabidopsis

S-Adenosyl-L-methionine:phosphoethanolamine N-methyltransferase (PEAMT; EC 2.1.1.103) catalyzes the key step in choline (Cho) biosynthesis, the N-methylation of phosphoethanolamine. Cho is a vital precursor of the membrane phospholipid phosphatidylcholine, which accounts for 40 to 60% of lipids in nonplastid plant membranes. Certain plants use Cho to produce the osmoprotectant glycine betaine, which confers resistance to salinity, drought, and other stresses. An Arabidopsis mutant, t365, in which the PEAMT gene is silenced, was identified using a new sense/antisense RNA expression system. t365 mutant plants displayed multiple morphological phenotypes, including pale-green leaves, early senescence, and temperature-sensitive male sterility. Moreover, t365 mutant plants produced much less Cho and were hypersensitive to salinity. These results demonstrate that Cho biosynthesis not only plays an important role in plant growth and development but also contributes to tolerance to environmental stresses. The temperature-sensitive male sterility caused by PEAMT silencing may have a potential application in agriculture for engineering temperature-sensitive male sterility in important crop plants.     

植物花药花粉特异性基因的调控序列

植物的花药发育和花粉成熟过程中,有大量的基因表达,其中有许多是花药和花粉组织特异性的,本文介绍了几种已知的花药和花粉特异性基因及其上游调控序列,井简单地介绍了花药特异性的启动子在植物基因工程中的应用。