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。     

Development of a novel recessive genetic male sterility system for hybrid seed production in maize and other cross‐pollinating crops

We have developed a novel hybridization platform that utilizes nuclear male sterility to produce hybrids in maize and other cross‐pollinating crops. A key component of this platform is a process termed Seed Production Technology (SPT). This process incorporates a transgenic SPT maintainer line capable of propagating nontransgenic nuclear male‐sterile lines for use as female parents in hybrid production. The maize SPT maintainer line is a homozygous recessive male sterile transformed with a SPT construct containing (i) a complementary wild‐type male fertility gene to restore fertility, (ii) an α‐amylase gene to disrupt pollination and (iii) a seed colour marker gene. The sporophytic wild‐type allele complements the recessive mutation, enabling the development of pollen grains, all of which carry the recessive allele but with only half carrying the SPT transgenes. Pollen grains with the SPT transgenes exhibit starch depletion resulting from expression of α‐amylase and are unable to germinate. Pollen grains that do not carry the SPT transgenes are nontransgenic and are able to fertilize homozygous mutant plants, resulting in nontransgenic male‐sterile progeny for use as female parents. Because transgenic SPT maintainer seeds express a red fluorescent protein, they can be detected and efficiently separated from seeds that do not contain the SPT transgenes by mechanical colour sorting. The SPT process has the potential to replace current approaches to pollen control in commercial maize hybrid seed production. It also has important applications for other cross‐pollinating crops where it can unlock the potential for greater hybrid productivity through expanding the parental germplasm pool.     

Use of functional male sterility in seed production of tomato hybrids

The aim of our research is the elaboration of a simple method of tomato hybrid seed production at the development of hybrids F₁ (common and parthenocarpic) on the basis of functional male sterility for ecological conditions of Belarus. The results of study of tomato flowering biology are discussed. The optimal term for pollination without emasculation of functional male sterile forms Z-313 and B-3-1-8 is the 3-6-th days and parthenocarpic functional male sterile forms B-2-2, B-2-5, B-2-6, ą-3, ą-4, Z-1-3 — the 2-4-th days after the phase of yellow-green bud. Forms with short pistil (C-9464, C-3-1, ą-2) may be used in hybrid seed production after the removal of filaments directly before pollination. The existence of a marker gene (potato leaf) gives a good possibility to reject non-hybrid seedlings.     

Functional male sterility in tomato (Lycopersicon esculentum Mill.) and its application in hybrid seed production

Advantages and disadvantages in using functional male sterility (positional sterile — ps, positional sterile 2 — ps 2, and excerted stigma — ex) in tomato hybrid seed production and attempts to elaborate systems for their more efficacious use in breeding were discussed in this review. It was concluded that the application of one of these types of sterility, (ps 2) in practice, although in a limited number of countries, showed the functional male sterility in tomato was a potential not to be underestimated in developing approaches that aimed at reducting the time and cost associated with hybrid seed production.     

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.     

A biotechnology‐based male‐sterility system for hybrid seed production in tomato

Incorporating male sterility into hybrid seed production reduces its cost and ensures high varietal purity. Despite these advantages, male‐sterile lines have not been widely used to produce tomato (Solanum lycopersicum) hybrid seeds. We describe the development of a biotechnology‐based breeding platform that utilized genic male sterility to produce hybrid seeds. In this platform, we generated a novel male‐sterile tomato line by clustered regularly interspaced short palindromic repeat (CRISPR)/CRISPR‐associated protein 9 (Cas9)‐mediated mutagenesis of a stamen‐specific gene SlSTR1 and devised a transgenic maintainer by transforming male‐sterile plants with a fertility‐restoration gene linked to a seedling‐colour gene. Offspring of crosses between a hemizygous maintainer and the homozygous male‐sterile plant segregated into 50% non‐transgenic male‐sterile plants and 50% male‐fertile maintainer plants, which could be easily distinguished by seedling colour. This system has great practical potential for hybrid seed breeding and production as it overcomes the problems intrinsic to other male‐sterility systems and can be easily adapted for a range of tomato cultivars and diverse vegetable crops.     

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。     

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.     

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。     

Tight linkage between a nuclear male-sterile locus and an enzyme marker in tomato

Summary The linkage relationship of a nuclear male sterile locus, ms-10, was tested with two enzyme marker loci known to be on the same chromosome (long arm of chromosome 2). The results indicate the gene order is Est-1 — 18 cM — Prx-2 — 1.5 cM — ms-10. The linkage intensity of ms-10 and Prx-2 (1.5 cM) suggests that Prx-2 might provide a selectable marker for male-sterility. In accordance with this idea, the ms-10 allele was placed in cis with a rare-allele of Prx-2 (Prx-2 ¹). Selection on the basis of the codominant Prx-2 ¹ allele should allow for more rapid and efficient transfer of the recessive male sterile allele into an array of genetic backgrounds, thus promoting its use in hybrid seed production.     

国内辣椒雄性不育育种及分子生物学研究进展

辣椒是常异花授粉植物,杂种制种成本较高。利用雄性不育育种可以降低杂种成本,近年来成为育种单位及科研院所研究的热点。介绍了国内开展辣椒雄性不育育种的情况,阐述了有关辣椒雄性不育研究的进展,涉及已被利用的遗传类型、不育系的来源和恢复系的研究,对近年来开发的不育和保持基因标记、恢复基因标记、基因的克隆进展进行了描述,为国内辣椒育种研究者提供参考。     

Somatic transfer of cytoplasmic traits in Brassica napus L. by haploid protoplast fusion

Summary Fusions between protoplasts from haploid cytoplasmic atrazine resistant (CATR) and haploid cytoplasmic male sterile (CMS) Brassica napus plants were used to produce a diploid CMS/CATR cybrid. The hybrid nature of the cytoplasm was confirmed by comparing the EcoRI restriction fragment patterns of chloroplast and mitochondrial DNA from the cybrid with the parental patterns. The advantages of using haploid protoplasts for fusion experiments as well as the utilization of the CMS/CATR cybrid for hybrid seed production are discussed.     

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。     

Natural variation of MS2 confers male fertility and drives hybrid breeding in soybean

A complete and genetically stable male sterile line with high outcrossing rate is a prerequisite for the development of commercial hybrid soybean. It was reported in the last century that the soybean male sterile ms2 mutant has the highest record with seed set. Here we report the cloning and characterization of the MS2 gene in soybean, which encodes a protein that is specifically expressed in the anther. MS2 functions in the tapetum and microspore by directly regulating genes involved in the biosynthesis of secondary metabolites and the lipid metabolism, which is essential for the formation of microspore cell wall. Through comparison of the field performance with the widely used male sterile mutants in the same genetic background, we demonstrated that the ms2 mutant conducts the best in outcrossing rate and makes it an ideal tool in building a cost-effective hybrid system for soybean.     

Introduction of a gene from fertility restored radish (Raphanus sativus) into Brassica napus by fusion of X-irradiated protoplasts from a radish restorer line and iodacetoamide-treated protoplasts from a cytoplasmic male-sterile cybrid of B. napus

To establish a cytoplasmic male-sterile/restored fertility (cms-Rf) system for F₁ seed production in Brassica napus, we transferred a gene from fertillity restored radish to B. napus by protoplast fusion. X-irradiated protoplasts, isolated from shoots of Raphanus sativus cv Kosena (Rf line), were fused with iodoacetamide-treated protoplasts of a B. napus cms cybrid. Among 300 regenerated plants, six were male-fertile. The fertile plants were characterized for petal color, chromosome number and the percentage of viable pollen grains. Three fertile plants had aneuploid chromosome numbers and white or cream petals, which is a dominant marker in radish. Of these three plants, one which had 2n = 47 chromosomes and white petals was used for further backcrosses. After two backcrosses, chromosome number and petal color became identical to that of B. napus. No female sterility was observed in the BC₃ generations.     

Basic studies on hybrid wheat breeding

Summary The nuclei of 12 common wheats (genome constitution AABBDD) were placed into the cytoplasms of Aegilops kotschyi and Ae. variabilis (both C^uC^uS^vS^v) by repeated backcrosses. Using these nucleus-cytoplasm hybrids, male sterility-fertility restoration relationship was investigated. Male sterility was expressed by these cytoplasms only in Slm, Splt and Mch. The other nine common wheat nuclei gave normal fertility against these cytoplasms. These cytoplasms were compared with the Triticum timopheevi cytoplasm that is now widely used in the hybrid wheat breeding program in order to investigate their effects on important agronomic traits of the 12 common wheats: The kotschyi and variabilis cytoplasms were as good as the timopheevi cytoplasm in this respect.The F₁ hybrid between (kotschyi)- or (variabilis)-Splt and CS showed normal fertility. Segregation of the fertiles and steriles in their F₂ generations followed the simple Mendelian fashion, i.e., 3 fertile1 sterile. Thus, the fertility restoration in this case is mainly controlled by a single dominant gene which will be designated as Rfv1. To determine its location, ditelo-lBS and -lBL of CS were crossed as male parents to male sterile (kotschyi)- and (variabilis)-Splt. The F₁ hybrids between the male sterile Spit's and CS ditelo-lBS became male fertile, while those between the male sterile Spit's and CS ditelo-lBL became completely male sterile. Thus, the location of the gene Rfv1 has been determined to be on the short arm of chromosome lB of CS. Furthermore, a close relationship between the fertility-restoring genes and the nucleolus organizer region was pointed out.Finally, the schemes of breeding the male sterile lines of a cultivar with these cytoplasms, and its maintainer line were formulated. The following two points were considered as the advantages of the present male sterility-fertility restoration system over that using the timopheevi cytoplasm in breeding hybrid wheat: (1) easier fertility restoration in F₁ hybrids, and (2) no need of breeding the restorer line.This work was supported by a Grand-in-Aid from the Ministry of Education, No. 386002. Contribution from the Laboratory of Genetics, Faculty of Agriculture, Kyoto University, Japan, No. 420.