MS1521是拟南芥花药发育的必需基因

通过对3个拟南芥（Arabidopsis thaliana）雄性不育突变体（ms1521,st350,st454）的分析,研究了MS1521基因在花药发育过程中的功能。ms1521是通过EMS诱变野生型拟南芥得到的一株突变体,遗传分析表明ms1521是隐性单核基因控制的。利用图位克隆的方法对不育基因MS1521进行了定位,结果将MS1521定位于拟南芥第一条染色体上26kb的区间内,该定位区间内有一个影响花器官形态建成的基因UFO。测序结果表明在ms1521突变体中UFO基因编码区的958bp处发生了单碱基突变,导致MS1521该位点的氨基酸由天冬酰胺变成了天冬氨酸。另外两个表型与ms1521相似的突变体st350和st454来自T-DNA插入突变体群体。测序结果表明突变体st350和st454分别在UFO基因编码区发生了提前终止突变。等位分析表明它们与MS1521基因是等位的。3个突变体营养生长期发育正常,但生殖生长发育出现异常：有的雄蕊只有花丝没有花药;或者有花药但花丝变短;或者雄蕊有正常的花丝和花药,花药中有可育的花粉,但药室不能开裂;最终导致突变体不育的表型。进一步细胞学观察发现药室不能开裂是由于药室内壁细胞纤维化和木质化增厚不明显造成的。以上这些结果表明MS1521基因在花药发育过程中起重要作用。     

拟南芥雄性不育突变体ms1502的遗传及定位分析

通过EMS诱变、背景纯化与遗传分析,从拟南芥（Arabidopsis thaliana）中筛选到了一棵隐性单基因控制的雄性不育突变体ms1502。细胞学观察发现,突变体在小孢子从四分体释放出后花药绒毡层过早衰亡,小孢子的内容物不正常地凝聚,最终无法形成正常的花粉粒。利用图位克隆的方法对该基因MSl502进行了定位,结果表明MS1502位于第4条染色体上分子标记F25124和T12H20之间105kb区间内。目前该区间内尚未见到花药发育必需基因（不育基因）的报道,因此MS1502是一个控制花粉发育的新基因。     

拟南芥雄性不育突变体ms1142的遗传定位与功能分析

经EMS诱变野生型拟南芥（Arabidopsis thaliana）群体筛选得到一株雄性不育突变体ms1142,突变体的果荚短小,不含种子。细胞学观察和扫描电镜结果表明,突变体花药发育过程中,花药中小孢子外壁异常、破裂,最后没有花粉形成。遗传分析表明,该突变体为隐性单核基因突变所致;利用图位克隆的方法将MS1142基因定位于第1条染色体的BAC克隆F16P17上44kb区间内,目前尚未见该区间内有雄性不育基因的报道。以上结果结合生物信息学分析表明,MS1142是一个新的调控花药发育的关键基因。该工作为花药发育关键基因MS1142的克隆及功能分析奠定了基础。     

拟南芥雄性不育突变体ms214的遗传与功能分析

经过EMS诱变、背景纯化以及遗传分析,得到一株隐性核基因控制的拟南芥雄性不育突变体ms214,用图位克隆的方法将突变基因MS214定位于拟南芥第一条染色体上顶端700kb的区间内。生物信息学分析发现,该区间内有一个与蜡质合成有关的基因CERl;测序分析表明在突变体ms214中,CERl基因第一个外显子上碱基由C^509变成了u^509的突变,导致CER蛋白在该处的氨基酸由脯氨酸^170变成了亮氨酸^170;等位实验结果表明ms214和cerl是等位突变体。ms214突变体的茎和果荚呈现出与野生型不同的亮绿色;组织切片观察结果表明,突变体花药发育各个时期无异常变化;扫描电镜观察发现ms214的茎和果荚的表皮没有蜡质的形成,但是突变体成熟花粉粒表面含油层异常,具有许多小的脂肪小滴。这些结果揭示了MS214蛋白质参与蜡质合成过程,而且脯氨酸^170是该蛋白质行使功能所必需的。     

拟南芥雄性不育突变体ms1142的遗传定位与功能分析

经EMS诱变野生型拟南芥(Arabidopsis thaliana)群体筛选得到一株雄性不育突变体ms1142, 突变体的果荚短小, 不含种子。细胞学观察和扫描电镜结果表明, 突变体花药发育过程中, 花药中小孢子外壁异常、破裂, 最后没有花粉形成。遗传分析表明, 该突变体为隐性单核基因突变所致; 利用图位克隆的方法将MS1142基因定位于第1条染色体的BAC克隆F16P17上44 kb区间内, 目前尚未见该区间内有雄性不育基因的报道。以上结果结合生物信息学分析表明, MS1142是一个新的调控花药发育的关键基因。该工作为花药发育关键基因MS1142的克隆及功能分析奠定了基础。     

ST273是拟南芥绒毡层和小孢子发育的必需基因

绒毡层在拟南芥花药花粉发育过程中具有重要作用,包括分泌降解胼胝质的胼胝质酶、为花粉壁的形成提供原料以及为小孢子发育提供营养物质.本文通过对拟南芥雄性不育突变体st273的分析,研究了ST273基因在花药花粉发育过程中的功能.st273是通过T-DNA插入诱变野生型拟南芥得到的一株突变体,遗传分析表明st273是单隐性核基因控制的.利用图位克隆的方法对不育基因ST273进行了定位,结果表明ST273基因与拟南芥第三条染色体上分子标记CIW11连锁.生物信息学分析发现该分子标记附近有一个调控花粉发育的基因TDF1.测序分析结果表明在st273突变体中,TDF1基因第三个外显子上459位的碱基发生了由G459变成了A459的单碱基变化,导致ST273基因该位点提前终止突变.等位分析结果表明st273与tdf1是等位突变体.st273突变体营养生长期发育正常,但生殖生长发育出现异常.亚历山大染色结果显示st273突变体花药中没有花粉.组织切片观察结果表明,突变体花药绒毡层异常肥大且空泡化,四分体不能正常释放小孢子,最终无法形成花粉.这些结果揭示了ST273蛋白质参与调控了绒毡层和小孢子发育过程.     

调控拟南芥花粉发育突变体zy1511的基因定位及特征分析

为了进一步研究花药花粉发育过程,我们通过EMS诱变,筛选到拟南芥雄性不育突变体zy1511。遗传分析表明,zy1511为隐性单位点突变。细胞学观察表明．突变体花药中小孢子从四分体释放出后绒毡层并没有开始退化,花药发育后期绒毡层依然部分存在。说明突变体花药绒毡层退化比野生型的要迟,因此,小孢子不能发育成正常花粉粒。利用图位克隆的方法将zv1511定位于第一条染色体上分子标记F25P12和T8L23之间134．kb的区间内。本项工作为zy1511基因的克隆及对花粉发育功能分析奠定了基础。目前尚未见到该区间内雄性不育基因的报道。因此,zy1511是控制花粉发育的尚未发现的关键基因。     

拟南芥雄性不育相关基因LDAD1&2的遗传定位(英文)

利用EMS诱变筛选手段分离到一株拟南芥类似花药不开裂雄性不育突变体(like-defective in anther de-hiscence,ldad),其果荚干瘪,花药不能开裂且花粉败育。遗传分析表明,突变体的表型受2个隐性基因控制;细胞学观察发现,在花药发育过程中伴随着小孢子的降解;通过图位克隆初步对ldad的2个突变位点分别定位,一个定位在1号染色体上SSLP标记F22L4与端粒之间171 kb的区间,另一个定位在5号染色体上SSLP标记T10O8与端粒间150 kb的区间内;生物信息学分析显示此区间内未见育性相关的已知基因。该研究的结果对进一步克隆LDAD1&2基因及探讨其在花药发育中的功能具有重要意义。     

一个控制拟南芥小孢子发育基因的定位

通过EMS诱变、背景纯化与遗传分析,从拟南芥突变群体中分离到一株单隐性核位点控制的雄性部分不育突变体pms15-16-2-3.细胞学观察表明,突变体在花药发育的过程中,中层细胞延迟降解,绒毡层细胞形态分化异常,出现异常的四分体,导致最终只能形成少量的花粉.利用图位克隆的方法对该基因进行了定位,结果表明PMSl5-16-2.3基因位于拟南芥第3条染色体BAC克隆T24C20 上的28 kb区间内.目前该区间内尚未见到控制小孢子发育基因的报道,因此该基因是一个控制小孢子发育的新基因.本研究结果对同的基因的克隆及其在化粉发育中的功能研究奠定了基础.     

水稻花粉发育的分子机理

水稻的小孢子母细胞在花粉囊中进行减数分裂产生小孢子,小孢子进一步发育成花粉粒。当花粉成熟时,花粉粒从花粉囊中释放出来进行受精。分子生物学的研究已经发现了一些参与这一过程的基因,包括控制花粉囊组织的分化、小孢子母细胞的减数分裂、小孢子的发育和花药的开裂等。本文旨在总结水稻花粉发育过程及其调控分子机制的研究进展。     

A Multicopper oxidase (Cj1516) and a CopA homologue (Cj1161) are major components of the copper homeostasis system of Campylobacter jejuni

Metal ion homeostasis mechanisms in the food-borne human pathogen Campylobacter jejuni are poorly understood. The Cj1516 gene product is homologous to the multicopper oxidase CueO, which is known to contribute to copper tolerance in Escherichia coli. Here we show, by optical absorbance and electron paramagnetic resonance spectroscopy, that purified recombinant Cj1516 contains both T1 and trinuclear copper centers, which are characteristic of multicopper oxidases. Inductively coupled plasma mass spectrometry revealed that the protein contained approximately six copper atoms per polypeptide. The presence of an N-terminal “twin arginine” signal sequence suggested a periplasmic location for Cj1516, which was confirmed by the presence of p-phenylenediamine (p-PD) oxidase activity in periplasmic fractions of wild-type but not Cj1516 mutant cells. Kinetic studies showed that the pure protein exhibited p-PD, ferroxidase, and cuprous oxidase activities and was able to oxidize an analogue of the bacterial siderophore anthrachelin (3,4-dihydroxybenzoate), although no iron uptake impairment was observed in a Cj1516 mutant. However, this mutant was very sensitive to increased copper levels in minimal media, suggesting a role in copper tolerance. This was supported by increased expression of the Cj1516 gene in copper-rich media. A mutation in a second gene, the Cj1161c gene, encoding a putative CopA homologue, was also found to result in copper hypersensitivity, and a Cj1516 Cj1161c double mutant was found to be more copper sensitive than either single mutant. These observations and the apparent lack of alternative copper tolerance systems suggest that Cj1516 (CueO) and Cj1161 (CopA) are major proteins involved in copper homeostasis in C. jejuni.     

ST273 Is Essential for Tapetum and Microspore Development in Arabidopsis thaliana*

In Arabidopsis, the tapetum plays important roles in anther and pollen development by providing enzymes for callose dissolution, materials for pollen wall formation, and nutrients for microspore development. This paper describes the functional analyses of the ST273 gene in anther and pollen development by using Arabidopsis male sterile mutant st273. Mutant st273 was identified from a T DNA insertion mutant population, and genetic analysis showed that st273 mutant was controlled by a single recessive nuclear gene. A map based cloning approach was used, and ST273 gene was mapped to be linked to a molecular marker CIW11 on chromosome 3. Bioinformatics analysis revealed that there is a TDF1 gene near the marker CIW11. Sequencing analysis indicated that st273 mutant had a G459 to A459 base pair change in the third exon of TDF1 gene, which resulted in premature termination mutation in this region. Allelism test indicated that ST273 and TDF1 belong to the same locus. The mutant plant grows normally during the vegetative growth stage, but show developmental defects at the reproductive growth stage. Alexander staining showed that there was no pollen in the mature anther locule. Cytology observation indicated that the mutant tapetum was enlarged and vacuolated, the tetrads could not release the microspores timely, and finally no pollen was formed in the anther. These results demonstrated that ST273 protein plays an important role in tapetum and microspore development.     

The Post-meiotic Deficicent Anther1 （PDA1） gene is required for post-meiotic anther development in rice

To understand the molecular mechanism of male reproductive development in the model crop rice,we isolated a complete male sterile mutant post-meiotic deficient anther1 (pda1) from a γ-ray-treated rice mutant library.Genetic analysis revealed that the pda1 mutant was controlled by a recessive nucleus gene.The pda1 mutant anther seemed smaller with white appearance.Histological analysis demonstrated that the pda1 mutant anther undergoes normal early tapetum development without obvious altered meiosis.However,the pda1 mutant displayed obvious defects in postmeiotic tapetal development,abnormal degeneration occurred in the tapetal cells at stage 9 of anther development.Also we observed abnormal lipidic Ubisch bodies from the tapetal layer of the pda1 mutant,causing no obvious pollen exine formation.RT-PCR analysis indicated that the expression of genes involved in anther development including GAMYB,OsC4 and Wax-deficient anther1 (WDA1) was greatly reduced in the pda1 mutant anther.Using map-based cloning approach,the PDA1 gene was finely mapped between two markers HLF610 and HLF627 on chromosome 6 using 3,883 individuals of F2 population.The physical distance between HLF610 and HLF627 was about 194 kb.This work suggests that PDA1 is required for post-meiotic tapetal development and pollen/microspore formation in rice.     

Five gametophytic mutations affecting pollen development and pollen tube growth in Arabidopsis thaliana

Mutant analysis represents one of the most reliable approaches to identifying genes involved in plant development. The screening of the Versailles collection of Arabidopsis thaliana T-DNA insertion transformants has allowed us to isolate different mutations affecting male gametophytic functions and viability. Among several mutated lines, five have been extensively studied at the genetic, molecular, and cytological levels. For each mutant, several generations of selfing and outcrossing have been carried out, leading to the conclusion that all these mutations are tagged and affect only the male gametophyte. However, only one out of the five mutations is completely penetrant. A variable number of T-DNA copies has integrated in the mutant lines, although all segregate at one mutated locus. Two mutants could be defined as "early mutants": the mutated genes are presumably expressed during pollen grain maturation and their alteration leads to the production of nonfunctional pollen grains. Two other mutants could be defined as "late mutant" since their pollen is able to germinate but pollen tube growth is highly disturbed. Screening for segregation ratio distortions followed by thorough genetic analysis proved to be a powerful tool for identifying gametophytic mutations of all phases of pollen development.     

Cytochemical Analysis of Pollen Development in Wild-Type Arabidopsis and a Male-Sterile Mutant

Microsporogenesis has been examined in wild-type Arabidopsis thaliana and the nuclear male-sterile mutant BM3 by cytochemical staining. The mutant lacks adenine phosphoribosyltransferase, an enzyme of the purine salvage pathway that converts adenine to AMP. Pollen development in the mutant began to diverge from wild type just after meiosis, as the tetrads of microspores were released from their callose walls. The first indication of abnormal pollen development in the mutant was a darker staining of the microspore wall due to an incomplete synthesis of the intine. Vacuole formation was delayed and irregular in the mutant, and the majority of the mutant microspores failed to undergo mitotic divisions. Enzyme activities of alcohol dehydrogenase and esterases decreased in the mutant soon after meiosis and were undetectable in mature pollen grains of the mutant. RNA accumulation was also diminished. These results are discussed in relation to the possible role(s) of adenine salvage in pollen development.     

An Arabidopsis F-box protein regulates tapetum degeneration and pollen maturation during anther development

The Arabidopsis anther has a bilateral symmetry with four lobes, each consisting of four distinct layers of somatic cells from the outer to inner side: epidermis, endothecium, middle layer and tapetum. The tapetum is a layer of cells comprising the inner surface of the pollen wall. It plays an important role in anther development by providing enzymes, materials and nutrients required for pollen maturation. Genes and molecular mechanisms underlying tapetum formation and pollen wall biosynthesis have been studied in Arabidopsis. However, tapetum degeneration and anther dehiscence have not been well characterized at the molecular level. Here, we report that an Arabidopsis gene, designated reduced male fertility (RMF), regulates degeneration of tapetum and middle layer during anther development. The Arabidopsis dominant mutant rmf-1D overexpressing the RMF gene exhibited pleiotropic phenotypes, including dwarfed growth with small, dark-green leaves and low male fertility. Tapetum development and subsequent degeneration were impaired in the mutant. Accordingly, pollen maturation was disturbed, reducing the male fertility. In contrast, tapetum degeneration was somewhat accelerated in the RMF RNAi plants. The RMF gene was expressed predominantly in the anther, particularly in the pollen grains. Notably, the RMF protein contains an F-box motif and is localized to the nucleus. It physically interacts with the Arabidopsis-Skp1-like1 protein via the F-box motif. These observations indicate that the RMF gene encodes an F-box protein functioning in tapetum degeneration during anther development.