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。     

甘蓝胞质雄性不育系及其保持系花药和叶片生化特性分析

对甘蓝胞质雄性不育系CMS158及其保持系花药激素、游离氨基酸和叶片叶绿素含量进行了比较研究。结果表明,不育系花药KT和IAA含量极显著低于保持系,GA含量不育系和保持系没有显著差异。游离氨基酸总量不育系花药极显著高于保持系,脯氨酸和胱氨酸含量不育系花药极显著低于保持系,赖氨酸含量两系无明显差异,苏氨酸在两系中均未检出,其余氨基酸含量均是不育系花药高于保持系;不育系花药中丝氨酸含量最高,保持系花药中脯氨酸含量最高,两系中天冬氨酸和脯氨酸含量的差异最大。叶片叶绿素含量不育系和保持系无显著差异。     

Genetics of Male and Female Sterility in Hybrids of Drosophila pseudoobscura and D. persimilis

The genetic basis of male and female sterility in hybrids of Drosophila pseudoobscura-Drosophila persimilis was studied using backcross analysis. Previous studies indirectly assessed male fertility by measuring testis size; these studies concluded that male sterility results from an X chromosome-autosome imbalance. By directly scoring for the production of motile sperm, male sterility is shown to be largely due to an incompatibility between genes on the X and Y chromosomes of these two species. These species have diverged at a minimum of nine loci affecting hybrid male fertility. Semisterility of hybrid females appears to result from an X chromosome-cytoplasm interaction; the X chromosome thus has the largest effect on sterility in both male and female hybrids. This is apparently the first analysis of the genetic basis of female sterility, or of sterility/inviability affecting both sexes, in an animal hybridization.     

辣椒雄性不育系与保持系花药POD、SOD和EST同工酶表达差异研究

利用辣椒质核互作雄性不育材料,采用聚丙酰胺凝胶垂直板电泳技术,研究了在花药发育不同时期,甜椒和辣椒核质互作雄性不育系及其保持系POD、SOD和EST同工酶的差异.结果表明:不育系与保持系,在花药发育的不同时期POD同工酶表达种类及表达活性之间存在差异,其中甜椒不育系在减数分裂期POD同工酶的活性非常低,辣椒雄性不育系在减数分裂期及花粉成熟期分别多一条POD特征带.不育系与保持系之间SOD同工酶的表达活性及其表达种类无明显差异.在减数分裂期和花粉成熟期,甜椒和辣椒不育系与保持系花药EST同工酶酶带均存在明显的差异.     

The Genetics of Reproductive Isolation in the Drosophila Simulans Clade: X Vs. Autosomal Effects and Male Vs. Female Effects

A strong effect of homozygous autosomal regions on reproductive isolation was found for crosses between the species in the Drosophila simulans clade. Second chromosome regions were introgressed from D. mauritiana and D. sechellia into D. simulans and tested for their homozygous effects on hybrid male and hybrid female sterility and inviability. Most introgressions are fertile as heterozygotes, yet produce sterile male offspring when made homozygous. The density of homozygous autosomal factors contributing to hybrid male sterility is comparable to the density of X chromosome factors for this level of resolution. Female sterility was also revealed, yet the disparity between male and female levels of sterility was great, with male sterility being up to 23 times greater than female sterility. Complete hybrid inviability was also associated with some regions of the second chromosome, yet there were no strong sex differences. In conclusion, we find no evidence to support a strong X chromosome bias in the evolution of hybrid sterility or inviability but do find a very strong sex bias in the evolution of hybrid sterility. In light of these findings, we reevaluate the current models proposed to explain the genetic pattern of reproductive isolation.     

丹参雄性不育系Sh-B的鉴定与花粉发育过程的解剖学研究

在显微水平上对新发现的丹参雄性不育系Sh-B花药发育过程进行了解剖学观察,并对其花粉活力和结实率进行了鉴定。结果显示:根据花器官及花药的形态、大小以及花丝的长度,可以将Sh-B不育株分为3个不育类型,即Sh-B1、Sh-B2和Sh-B3。这3种不育类型均属于雄性不育,其花丝不到正常可育株的1/2,花药干瘪而瘦小,内无花粉粒或花粉无活力;其根、茎、叶以及种子形态结构与正常可育植株基本相似。产生雄性不育的主要原因有:花粉囊药室内壁纤维层加厚,影响花药壁开裂;小孢子母细胞周围不产生胼胝质或产生的胼胝质很少;绒毡层细胞延迟解体;花粉粒畸形。在其花药发育的小孢子母细胞时期、四分体形成前期、单核期、双核期均可能产生雄性不育的小孢子或花粉粒。     

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.     

Ecological and genetic factors contributing to the low frequency of male sterility in Chamaecrista Fasciculata (Fabaceae)

Bumble bee pollinated Chamaecrista fasciculata provides pollen as the sole reward to its pollinators. Male sterility, expressed as an absence or nearly complete absence of pollen production, occurs in low frequency in populations of C. fasciculata. Here we describe experiments, using C. fasciculata, to examine frequently cited determinants of the spread and maintenance of male sterility: compensation and the genetic basis of male sterility. In addition, we examine the role the pollination system plays in determining the reproductive success of the male steriles. Seventeen populations in Maryland, Illinois, and Kansas were surveyed and found to range from 0 to 6% male sterility per population. An artificial population of male-sterile simulants and hermaphrodites was created to examine how the local frequency of nonrewarding male steriles might affect male-sterile female reproductive success. Male steriles performed equally poorly, with respect to seed production, whether surrounded by other male-sterile simulants or hermaphrodites. Compensation was examined by comparison of male steriles and hermaphrodites with respect to several reproductive and nonreproductive characters. Male steriles outperformed hermaphrodites in terms of nonreproductive biomass, but performed equally in terms of ovule number and produced many fewer flowers. The genetic basis of male sterility was examined by performing both intra- and interpopulational crosses of male steriles to hermaphrodites and indicate that male sterility is not purely cytoplasmic. The low frequency of male sterility in C. fasciculata populations may reflect reduced female reproductive success because of pollinator avoidance, lack of reproductive compensation, and a mode of inheritance that is not purely cytoplasmic.     

洋葱细胞质雄性不育系101A的分子鉴定

根据文献报道设计引物序列,对洋葱细胞质雄性不育系101A进行PCR扩增,结果表明:洋葱细胞质雄性不育系101A属于S型细胞质雄性不育类型,其特异片段位于叶绿体基因组。     

Misregulation of spermatogenesis genes in Drosophila hybrids is lineage‐specific and driven by the combined effects of sterility and fast male regulatory divergence

Hybrid male sterility is a common outcome of crosses between different species. Gene expression studies have found that a number of spermatogenesis genes are differentially expressed in sterile hybrid males, compared with parental species. Late‐stage sperm development genes are particularly likely to be misexpressed, with fewer early‐stage genes affected. Thus, a link has been posited between misexpression and sterility. A more recent alternative explanation for hybrid gene misexpression has been that it is independent of sterility and driven by divergent evolution of male‐specific regulatory elements between species (faster male hypothesis). The faster male hypothesis predicts that misregulation of spermatogenesis genes should be independent of sterility and approximately the same in both hybrids, whereas sterility should only affect gene expression in sterile hybrids. To test the faster male hypothesis vs. the effect of sterility on gene misexpression, we analyse spermatogenesis gene expression in different species pairs of the Drosophila phylogeny, where hybrid male sterility occurs in only one direction of the interspecies cross (i.e. unidirectional sterility). We find significant differences among genes in misexpression with effects that are lineage‐specific and caused by sterility or fast male regulatory divergence.     

小麦中雄性不育同源序列的分离、鉴定及表达分析

利用拟南芥中已克隆的雄性核不育基因MS2和水稻中假定雄性不育蛋白的保守区域,设计一对简并引物,并在太谷核不育小麦可育株及不育株花药中进行扩增,得到了一条134bp的片段。以该片段为基础,通过电子延伸得到一个长为1604bp的序列,该序列编码的氨基酸包含一段由200个氨基酸组成的雄性不育保守区。RT-PCR结果表明,该雄性不育同源序列只在小麦可育花药中表达,而在小麦败育花药、叶片和根中不表达,说明该雄性不育同源序列为花药发育特异基因。     

水稻雄性不育突变体ms102的鉴定和基因定位

水稻(Oryza sativa)隐性核雄性不育突变体是第三代杂交水稻技术的核心。为了挖掘优质雄性不育突变体, 该研究通过筛选优质籼稻黄华占(HHZ)的甲基磺酸乙酯(EMS)诱变突变体库, 获得1个雄性不育突变体ms102 (male sterility mutant 102)。该突变体营养生长正常, 但花药不开裂, 花粉败育。细胞学分析表明, 突变体花药绒毡层不能正常降解, 导致小孢子发育异常; 遗传分析表明, 该突变体的不育表型由1个已报道编码酰基转移酶的DPW2基因突变造成。研究获得了1个隐性核雄性不育突变体, 进一步证实了DPW2基因在水稻花药发育中的功能。     

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.     

Cytological and Comparative Proteomic Analyses on Male Sterility in Brassica napus L. Induced by the Chemical Hybridization Agent Monosulphuron Ester Sodium

Male sterility induced by a chemical hybridization agent (CHA) is an important tool for utilizing crop heterosis. Monosulphuron ester sodium (MES), a new acetolactate synthase-inhibitor herbicide belonging to the sulphonylurea family, has been developed as an effective CHA to induce male sterility in rapeseed (Brassica napus L.). To understand MES-induced male sterility in rapeseed better, comparative cytological and proteomic analyses were conducted in this study. Cytological analysis indicated that defective tapetal cells and abnormal microspores were gradually generated in the developing anthers of MES-treated plants at various development stages, resulting in unviable microspores and male sterility. A total of 141 differentially expressed proteins between the MES-treated and control plants were revealed, and 131 of them were further identified by MALDI-TOF/TOF MS. Most of these proteins decreased in abundance in tissues of MES-treated rapeseed plants, and only a few increased. Notably, some proteins were absent or induced in developing anthers after MES treatment. These proteins were involved in several processes that may be crucial for tapetum and microspore development. Down-regulation of these proteins may disrupt the coordination of developmental and metabolic processes, resulting in defective tapetum and abnormal microspores that lead to male sterility in MES-treated plants. Accordingly, a simple model of CHA-MES-induced male sterility in rapeseed was established. This study is the first cytological and dynamic proteomic investigation on CHA-MES-induced male sterility in rapeseed, and the results provide new insights into the molecular events of male sterility.     

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。     

Inbreeding effect on male and female fertility and inheritance of male sterility in Nemophila menziesii (Hydrophyllaceae)

Models of the evolution of gynodioecy assume that inbreeding affects male and female fertility equally and ignore quantitative variation in sex expression. The objectives of this study were to assess inbreeding effects, genetic background, and plant maturity on male and female fertility and the mechanism of male sterility inheritance for Nemophila menziesii (Hydrophyllaceae). Frequency of male-sterile flowers, number of anthers and ovules, and percentage of viable pollen were measured on plants from different pedigrees and five inbreeding levels (F = 0, 0.0625, 0.25, 0.5, and 0.75). Quantitative variation in male sterility was evident. As inbreeding increased, anther and ovule number decreased; the effect on anther number was greater than on ovule number. Pedigrees varied in number of male-sterile flowers and inbreeding effects. Frequency of male-sterile flowers was greatest among first flowers. No trade-off between male and female fertility was detected. A model attributing male sterility to a cytoplasmic locus and restoration to male fertility to a nuclear locus accounted for the distribution of complete sterility and hermaphroditism over the pedigrees. This study suggests that models of the evolution and maintenance of gynodioecy should allow for quantitative variation in male and female fertility components due to inbreeding, pedigree, and plant maturity.     

利用生物技术创建主要作物雄性不育杂交育种和制种的技术体系

雄性不育技术在作物杂种优势利用和杂交种生产中发挥着重要作用。基于核质互作雄性不育的“三系法”与光温敏核不育的“两系法”已经在水稻等主要作物的杂交制种中获得了广泛应用,但是存在着资源利用效率低、育性不稳定、易受外界环境影响等诸多问题。近三十年来,利用生物技术创建不同类型的植物雄性不育系取得了一系列突破性进展。主要针对玉米、水稻、小麦三大作物的基因工程雄性不育技术的最新进展进行总结,特别详细地描述了本实验室最近研究创制的玉米多控不育技术体系,以期为相关研究和产业化应用提供技术参考。     

玉米核雄性不育材料的研究及其分子育种中的利用

玉米核雄性不育材料是宝贵的种质资源。本文概述了玉米核雄性不育材料的发现、研究和利用的最新进展情况,重点针对核不育基因在染色体上的定位、细胞学研究和标记性状的利用进行了简要综述,并对这一宝贵的种质资源在生物技术迅速发展条件下的利用提出了新构想。     

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。     

Expression of Engineered Nuclear Male Sterility in Brassica napus (Genetics,Morphology, Cytology,and Sensitivity to Temperature)

A dominant genetic male sterility trait obtained through transformation in rapeseed (Brassica napus) was studied in the progenies of 11 transformed plants. The gene conferring the male sterility consists of a ribonuclease gene under the control of a tapetum-specific promoter. Two ribonuclease genes, RNase T1 and barnase, were used. The chimaeric ribonuclease gene was linked to the bialophos-resistance gene, which confers resistance to the herbicide phosphinotricine (PPT). The resistance to the herbicide was used as a dominant marker for the male sterility trait. The study presented here concerns three aspects of this engineered male sterility: genetics correlated with the segregation of the T-DNA in the progenies; expression of the male sterility in relation to the morphology and cytology of the androecium; and stability of the engineered male sterility under different culture conditions. Correct segregation, 50% male-sterile, PPT-resistant plants, and 50% male-fertile, susceptible plants were observed in the progeny of seven transformants. The most prominent morphological change in the male-sterile flowers was a noticeable reduction in the length of the stamen filament. The first disturbances of microsporogenesis were observed from the free microspore stage and were followed by a simultaneous degeneration of microspore and tapetal cell content. At anthesis, the sterile anthers contained only empty exines. In some cases, reversion to fertility of male-sterile plants has been observed. Both ribonuclease genes are susceptible to instability. Instability of the RNase T1-male sterility trait increased at temperatures higher than 25[deg] C. Our results do not allow us to confirm this observation for the barnase male-sterile plants. However, the male-sterile plants of the progeny of two independent RNase T1 transformants were stably male sterile under all conditions studied.