植物胞质雄性不育及育性恢复的分子机制研究进展(综述)

本文从与雄性不育有关的线粒体基因引起雄性不育的机理、雄性不育育性恢复机制以及育性恢复基因的克隆等方面,介绍国内外对植物细胞质雄性不育分子机理的研究进展,并对今后的研究进行讨论。     

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。     

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。     

植物细胞质雄性不育及其育性恢复的分子生物学研究进展

植物细胞质雄性不育（CMS）和恢复系统在作物杂交种子生产中具有重要的意义。综述了目前已发现的与植物CMS相关的线粒体DNA位点,育性恢复基因对CMS相关DNA位点表达的影响,育性恢复基因的分子标记定位、克隆,及育性恢复分子机理等方面的研究进展,并讨论了恢复基因在植物分子育种上的应用。     

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。     

植物细胞质雄性不育分子机理研究进展

本文从线粒体基因组、线粒体基因、线粒体转录RNA、线粒体蛋白、转基因植物以及花粉败育机理六个方面详细介绍了植物细胞质雄性不育分子生物学研究的技术和方法。综述了植物细胞质雄性不育分子机理研究的进展 ,并对植物细胞质雄性不育分子机理的前景作了展望。     

植物细胞质雄性不育分子机理研究进展

本文从线粒体基因组、线粒体基因、线粒体转录 RNA、 线粒体蛋白、转基因植物以及花粉败育机理六个方面详细介绍了植物细胞质雄性不育分子生物学研究的技术和方法。综述了植物细胞质雄性不育分子机理研究的进展,并对植物细胞质雄性不育分子机理的前景作了展望。     

植物CMS/Rf系统的基因克隆及其结构特征

细胞质雄性不育和恢复系统（CMS/Rf）在植物杂种优势利用中已被广泛应用。为阐明恢复基因在这一系统中的作用机理,众多研究者开展了恢复基因的定位和克隆研究。近年来,4个植物恢复基因的成功克隆有力地推动了这一研究领域的发展。本文综述了植物恢复基因的定位、克隆以及育性恢复分子机理的研究进展,并讨论了恢复基因在植物分子育种上的应用。     

油菜细胞质雄性不育与育性恢复机理的研究进展

油菜细胞质雄性不育不仅是研究核质互作的理想材料,同时也是杂种优势利用的最有效方式之一。目前对油菜细胞质雄性不育的研究主要包括不育基因的来源、不育基因的结构特征、不育基因的作用机理以及育性恢复的分子机制等。对目前国际上主要的油菜细胞质雄性不育类型(pol CMS、nap CMS、kos CMS、ogu CMS和tour CMS)在分子水平上的研究进展进行了综述。包括线粒体不育基因相关区域的确定和结构特点,不育形成的分子机理以及恢复基因的定位和作用机制等。     

水稻细胞质雄性不育及育性恢复研究进展

植物细胞质雄性不育(CMS)是广泛存在于自然界中的现象,主要表现为不能产生有功能的花粉从而导致不能正常受精结实的自然现象。CMS的起因源于受植物细胞质基因的影响表现出雄性不育的特征,目前研究表明为线粒体的基因引起的雄性不育。相应地,细胞核中存在某类基因能够编码一种蛋白使其育性得以恢复,这一类基因称为育性恢复基因(Rf genes)。杂交水稻的生产依赖于CMS的发掘和利用,并且这也是农作物增产的一条有效途径。迄今为止,水稻中CMS和育性恢复的相关研究较多,机理阐述相对比较深入,本文主要介绍水稻CMS及育性恢复基因的研究及CMS和育性恢复机理的最新研究进展,希望能为揭示水稻CMS与育性恢复机制以及其他作物的CMS/Rf研究提供参考,为新型杂交水稻的培育提供新思路。     

The fertility restorer gene, Rf2, for Lead Rice-type cytoplasmic male sterility of rice encodes a mitochondrial glycine-rich protein

Cytoplasmic male sterility (CMS) is associated with a mitochondrial mutation that causes an inability to produce fertile pollen. The fertility of CMS plants is restored in the presence of a nuclear-encoded fertility restorer (Rf) gene. In Lead Rice-type CMS, discovered in the indica variety 'Lead Rice', fertility of the CMS plant is restored by the single nuclear-encoded gene Rf2 in a gametophytic manner. We performed map-based cloning of Rf2, and proved that it encodes a protein consisting of 152 amino acids with a glycine-rich domain. Expression of Rf2 mRNA was detected in developing and mature anthers. An RF2-GFP fusion was shown to be targeted to mitochondria. Replacement of isoleucine by threonine at amino acid 78 of the RF2 protein was considered to be the cause of functional loss in the rf2 allele. As Rf2 does not encode a pentatricopeptide repeat protein, unlike a majority of previously identified Rf genes, the data from this study provide new insights into the mechanism for restoring fertility in CMS.     

Introgression and molecular tagging of <Emphasis Type="Italic">Rf</Emphasis><Subscript>4</Subscript>, a new male fertility restoration gene from wild sunflower <Emphasis Type="Italic">Helianthus maximiliani</Emphasis> L.

Cytoplasmic male sterility (CMS) and its fertility restoration (Rf) genes are critical tools for hybrid seed production to utilize heterosis. In sunflower, CMS PET1 and the associated Rf gene Rf (1) is the only source extensively used in commercial hybrid production. The objective of this research was to develop new sources of CMS and fertility restorers to broaden the genetic diversity of hybrid seed production. We identified a new type of CMS, named as CMS GIG2, from an interspecific cross between Helianthus giganteus accession1934 and H. annuus cv. HA 89. Based on reactions to a set of standard Rf testers, CMS GIG2 is different from all previously reported CMS types, including the CMS GIG1 from another H. giganteus accession. We also identified an Rf gene for CMS GIG2 from wild species H. maximiliani accession 1631. The CMS GIG2 and its restoration gene were introduced into HA 89 background through recurrent backcross and single plant selection techniques. Genetic analysis revealed that the CMS GIG2-Rf system is controlled by a completely dominant gene, named as Rf (4), and the gene additive and dominance effects were estimated as 39.9 and 42.2%, respectively, in the HA 89 background. The gene Rf (4) was mapped onto linkage group 3 with simple sequence repeat (SSR) markers and RFLP-derived STS-marker, and is about 0.9 cM away from the SSR marker ORS1114 based on a segregation population of 933 individuals. The CMS GIG2-Rf (4) system tagged by molecular markers provides an alternative genetic source for hybrid breeding in the sunflower crop.     

Mitochondrial ORF79 levels determine pollen abortion in cytoplasmic male sterile rice

Cytoplasmic male sterility (CMS) is an important agricultural trait characterized by lack of functional pollen, and caused by ectopic and defective mitochondrial gene expression. The pollen function in CMS plants is restored by the presence of nuclear‐encoded restorer of fertility (Rf) genes. Previously, we cloned Rf2, which restores the fertility of Lead Rice (LD)‐type CMS rice. However, neither the function of Rf2 nor the identity of the mitochondrial gene causing CMS has been determined in LD–CMS rice. Here, we show that the mitochondrial gene orf79 acts as a CMS‐associated gene in LD–CMS rice, similar to its role in BT–CMS rice originating from Chinsurah Boro II, and Rf2 weakly restores fertility in BT–CMS rice. We also show that RF2 promotes degradation of atp6–orf79 RNA in a different manner from that of RF1, which is the Rf gene product in BT–CMS rice. The amount of ORF79 protein in LD–CMS rice was one‐twentieth of the amount in BT–CMS rice. The difference in ORF79 protein levels probably accounts for the mild and severe pollen defects in LD–CMS and BT–CMS rice, respectively. In the presence of Rf2, accumulation of ORF79 was reduced to almost zero and 25% in LD–CMS and BT–CMS rice, respectively, which probably accounts for the complete and weak fertility restoration abilities of Rf2 in LD–CMS and BT–CMS rice, respectively. These observations indicate that the amount of ORF79 influences the pollen fertility in two strains of rice in which CMS is induced by orf79.     

Genetic characterization of a pentatricopeptide repeat protein gene,orf687, that restores fertility in the cytoplasmic male-sterile Kosena radish

Cytoplasmic male sterility (CMS) in plants is a maternally inherited inability to produce functional pollen, and is often associated with mitochondrial DNA abnormalities. Specific nuclear loci that suppress CMS, termed as restorers of fertility (Rf), have been identified. Previously, we identified an Rf for the CMS Kosena radish and used genetic analysis to identify the locus and create a contig covering the critical interval. To identify the Rf gene, we introduced each of the lambda and cosmid clones into the CMS Brassica napus and scored for fertility restoration. Fertility restoration was observed when one of the lambda clones was introduced into the CMS B. napus. Furthermore, introduction of a 4.7-kb BamHI/HpaI fragment of the lambda clone is enough to restore male fertility. A cDNA strand isolated from a positive fragment contained a predicted protein (ORF687) of 687 amino acids comprising 16 repeats of the 35-amino acid pentatricopeptide repeat (PPR) motif. Kosena CMS radish plants were found to express an allele of this gene possessing four substituted amino acids in the second and third repeats of the PPR suggesting that the domains formed by these repeats in ORF687 are essential for fertility restoration. Protein levels of the Kosena CMS-associated mitochondrial protein ORF125 were considerably reduced in plants in which fertility was restored, although mRNA expression was normal. Regarding the possible role for PPR-containing proteins in the regulation of the mitochondrial gene, we propose that ORF687 functions either directly or indirectly to lower the levels of ORF125, resulting in the restoration of fertility in CMS plants.     

The petunia restorer of fertility protein is part of a large mitochondrial complex that interacts with transcripts of the CMS-associated locus

A class of nuclear genes termed "restorers of fertility" (Rf) acts to suppress the expression of abnormal mitochondrial genes associated with cytoplasmic male sterility (CMS). In petunia, both the nuclear Rf gene and mitochondrial CMS-associated gene have previously been identified. The CMS-associated gene is an aberrant chimera in which portions of several mitochondrially encoded genes are fused to an unknown reading frame. The dominant Rf allele reduces the CMS-associated protein to nearly undetectable levels and alters the RNA population derived from the CMS locus, but its mechanism of action has not been determined. The petuniaRf gene is a member of the pentatricopeptide repeat gene family (PPR), an unusually large gene family in Arabidopsis (approximately 450 genes) compared with yeast (five genes) and mammalian genomes (six genes). The PPR gene family has been implicated in the control of organelle gene expression. To gain insight into the mode of action of PPR genes, we generated transgenic petunia plants expressing a functional tagged version of Rf. Analysis of the restorer protein revealed that it is part of a soluble mitochondrial inner-membrane-associated, RNase-sensitive high-molecular-weight protein complex. The complex is associated with mRNA derived from the CMS locus.     

Two non-allelic nuclear genes restore fertility in a gametophytic pattern and enhance abiotic stress tolerance in the hybrid rice plant

In indica rice, the HongLian (HL)-type combination of cytoplasmic male sterility (CMS) and fertility restoration (Rf) is widely used for the production of commercial hybrid seeds in China, Laos, Vietnam and other Southeast Asian countries. Generally, any member of the gametophytic fertility restoration system, 50% of the pollen in hybrid F(1) plants displays recovered sterility. In this study, however, a HL-type hybrid variety named HongLian You6 had approximately 75% normal (viable) pollen rather than the expected 50%. To resolve this discrepancy, several fertility segregation populations, including F(2) and BC(1)F(1) derived from the HL-CMS line Yuetai A crossed with the restorer line 9311, were constructed and subjected to genetic analysis. A gametophytic restoration model was discovered to involve two non-allelic nuclear restorer genes, Rf5 and Rf6. The Rf5 had been previously identified using a positional clone strategy. The Rf6 gene represents a new restorer gene locus, which was mapped to the short arm of chromosome 8. The hybrid F(1) plants containing one restorer gene, either Rf5 or Rf6, displayed 50% normal pollen grains with I(2)-KI solution; however, those with both Rf5 and Rf6 displayed 75% normal pollens. We also established that the hybrid F(1) plants including both non-allelic restorer genes exhibited an increased stable seed setting when subjected to stress versus the F(1) plants with only one restorer gene. Finally, we discuss the breeding scheme for the plant gametophytic CMS/Rf system.     

Cytoplasmic male sterility of rice with boro II cytoplasm is caused by a cytotoxic peptide and is restored by two related PPR motif genes via distinct modes of mRNA silencing

Cytoplasmic male sterility (CMS) and nucleus-controlled fertility restoration are widespread plant reproductive features that provide useful tools to exploit heterosis in crops. However, the molecular mechanism underlying this kind of cytoplasmic-nuclear interaction remains unclear. Here, we show in rice (Oryza sativa) with Boro II cytoplasm that an abnormal mitochondrial open reading frame, orf79, is cotranscribed with a duplicated atp6 (B-atp6) gene and encodes a cytotoxic peptide. Expression of orf79 in CMS lines and transgenic rice plants caused gametophytic male sterility. Immunoblot analysis showed that the ORF79 protein accumulates specifically in microspores. Two fertility restorer genes, Rf1a and Rf1b, were identified at the classical locus Rf-1 as members of a multigene cluster that encode pentatricopeptide repeat proteins. RF1A and RF1B are both targeted to mitochondria and can restore male fertility by blocking ORF79 production via endonucleolytic cleavage (RF1A) or degradation (RF1B) of dicistronic B-atp6/orf79 mRNA. In the presence of both restorers, RF1A was epistatic over RF1B in the mRNA processing. We have also shown that RF1A plays an additional role in promoting the editing of atp6 mRNAs, independent of its cleavage function.