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.     

Postmeiotic development of pollen surface layers requires two Arabidopsis ABCG-type transporters

Key message

Two Arabidopsis ABC transporters, ABCG1 and ABCG16, are expressed in the tapetal layer, specifically after postmeiotic microspore release, and play important roles in pollen surface development.

Abstract

The male gametophytic cells of terrestrial plants, the pollen grains, travel far before fertilization, and thus require strong protective layers, which take the form of a pollen coat and a pollen wall. The protective surface structures are generated by the tapetum, the tissue surrounding the developing gametophytes. Many ABC transporters, including Arabidopsis thaliana ABCG1 and ABCG16, have been shown to play essential roles in the development of such protective layers. However, the details of the mechanism of their function remain to be clarified. In this study, we show that ABCG1 and ABCG16 are localized at the plasma membrane of tapetal cells, specifically after postmeiotic microspore release, and play critical roles in the postmeiotic stages of male gametophyte development. Consistent with this stage-specific expression, the abcg1 abcg16 double knockout mutant exhibited defects in pollen development after postmeiotic microspore release; their microspores lacked intact nexine and intine layers, exhibited defects in pollen mitosis I, displayed ectopic deposits of arabinogalactan proteins, failed to complete cytokinesis, and lacked sperm cells. Interestingly, the double mutant exhibited abnormalities in the internal structures of tapetal cells, too; the storage organelles of tapetal cells, tapetosomes and elaioplasts, were morphologically altered. Thus, this work reveals that the lack of ABCG1 and ABCG16 at the tapetal cell membrane causes a broad range of defects in pollen, as well as in tapetal cells themselves. Furthermore, these results suggest that normal pollen surface development is necessary for normal development of the pollen cytoplasm.

     

Effects of Introducing the Chimaeric Gene TA29 Barnase on the Tapetum and Pollen Development in Tobacco

The development of tapetum and pollen in transgenic tobacco (Nicotiana tabacum L. ) harboring a chimaeric gene TA29-Barnase was compared with that of the wild-type plant. The specific expression of the exogenous genes in anther led to premature tapetal degradation, which started at the early stage of meiosis and terminated at the tetrad stage. In the wild-type anthers, tapetal degradation started at the early stage of bicellular microgametophyte and ended at the later stage of pollen development. The cytological changes of tapetal degradation in the transgenic plants were characterized by vacuolization of the tapetal cells, then nuclear condensation, and consequent massive degradation of tapetal cells. Meanwhile, the pollen mother cells gradually degraded and became destroyed along with the progress of meiosis, leaving only a few which could successfully complete their meiosis to form microspores. This observation also indicated that the TA29-Barnase gene in anther was not uniformly expressed. In addition, the structural difference between the male sterility induced by exogenous gene and the natural sterile was also discussed.     

TA29—Barnase嵌合基因导入对烟草花药绒毡层及花粉发育的影响

比较研究了烟草(Nicotiana tabacum L.)TA29-Barnase转基因不育植株和正常植株的花药绒毡层及花粉发育的全过程。研究表明,外源基因在花药中特异表达导致绒毡层细胞的提前降解,这种降解一般在减数分裂早期开始,至四分体时期完成,而正常花药绒毡层的降解发生在二细胞雄配子体初期,至花粉发育的后期方才完成。转基因植株花药绒毡层的降解在细胞结构上表现为:最初发生细胞的液泡化,然后细胞核凝聚,最后整个细胞溃解。转基因植株的花粉母细胞则在减数分裂过程中逐渐降解、退化,只有少数花粉母细胞能够顺利完成减数分裂发育成小孢子。观察结果还表明外源基因在花药中的表达是不均一的。对转基因不育和自然败育在细胞结构上的不同表现进行了讨论。     

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.     

Calcium distribution in fertile and sterile anthers of thermosensitive male-sterile wheat

Calcium distribution in fertile and sterile anthers of a thermosensitive male-sterile wheat genotype was investigated using an antimonate precipitation method. During fertile anther development, before meiosis of the microspore mother cells, calcium precipitates were apparent in tapetal cells of the anther wall. After meiosis, precipitates were detected in the early microspores and accumulated in the large vacuole of late microspores. After microspore division, following decomposition of the large vacuole, precipitates decreased in the bicellular pollen. The earliest abnormality in calcium precipitate distribution detected during sterile pollen development was the greater accumulation of precipitates in the cytoplasm and nucleus of late microspores. The sterile microspore can divide to form bicellular pollen, but the large vacuole of sterile bicellular pollen did not decompose and greater abundance of precipitates was retained in the large vacuole. Abnormal distribution of calcium precipitates in sterile pollen precedes structural changes, suggesting that abnormal calcium metabolism is associated with pollen abortion.     

太空诱变玉米核不育材料花粉败育的细胞学观察(简报)

玉米是最早利用雄性不育系生产杂交种的作物之一。在玉米T型细胞质雄性不育杂交种遭受毁灭性病害侵袭之后,科学家认识到利用细胞质雄性不育制种存在潜在的遗传脆弱性,从此试图通过多种途径来创造新的雄性不育．并对雄性不育材料的遗传多样性进行研究。空间诱变育种是80年代于我国发展起来的新技术,在农作物品种改良和种质创新上已初见成效。[第一段]     

扁豆绒毡层发育的超微结构研究

应用透射电镜对扁豆绒毡层发育过程进行了研究,主要结果如下：１）首次发现扁豆绒毡层在发育过程中,经历了二交胞质重组（第一次始于减数分裂末期Ⅱ,第二次始于小孢子发育早期）,使绒毡层细胞的活动呈现３个高峰期（即小孢子母细胞减数分裂期、小孢子四分体期一小孢子早期、小孢子晚期－二胞花粉中期）。２绒毡层细胞的分泌作用有３种形式（渗透分泌、胞吐分泌和自溶）。３．首次观察到绒毡层细胞的内切向壁和径向壁经历了两个周     

Adenine phosphoribosyltransferase isoforms of Arabidopsis and their potential contributions to adenine and cytokinin metabolism

Adenine phosphoribosyltransferase (APT; EC 2.4.2.7) is a constitutively expressed enzyme involved in the one-step salvage of adenine to AMP. The Arabidopsis thaliana genome contains five sequences annotated as encoding APT or APT-like enzymes. Three of these have now been cloned, over-expressed and compared using kinetic analyses. At a cytosolic pH, all bind adenine efficiently based on their K_m values (0.8–2.6 µ M ), although APT1 metabolizes adenine at a rate 31–53 times faster than APT2 and APT3, respectively. Since APT also has a possible role in the interconversion of cytokinin bases to nucleotides, we characterized the activity of each isoform on zeatin, isopentenyladenine and benzyladenine. Based on their K_m values, APT2 and APT3 had much higher affinities than APT1 for all three cytokinins (15–440 µ M for APT2 and 3 vs. 1.8–2.5 m M for APT1); conversely the V_max values for APT2 and APT3 on these CK substrates showed the opposite trend, being 4- to 19-fold lower than those of APT1. Anti-peptide antibodies for APT1, APT2, and APT3 were prepared and used to examine the subcellular localization of each isoform. Based on these results, APT1 and APT3 appear to be cytosolic, while the localization of APT2 was inconclusive although sequence analysis implies that APT2 is also cytosolic. Each isoform was modelled against the crystal structure of APT from Leishmania donovani , and structural differences in substrate specificity-determining domains have been found. The estimated kinetic activities of these APTs suggest that they contribute primarily to adenine recycling, although an involvement in cytokinin interconversion cannot be discounted.     

PERSISTENT TAPETAL CELL1 encodes a PHD-finger protein that is required for tapetal cell death and pollen development in rice

In higher plants, timely degradation of tapetal cells, the innermost sporophytic cells of the anther wall layer, is a prerequisite for the development of viable pollen grains. However, relatively little is known about the mechanism underlying programmed tapetal cell development and degradation. Here, we report a key regulator in monocot rice (Oryza sativa), PERSISTANT TAPETAL CELL1 (PTC1), which controls programmed tapetal development and functional pollen formation. The evolutionary significance of PTC1 was revealed by partial genetic complementation of the homologous mutation MALE STERILITY1 (MS1) in the dicot Arabidopsis (Arabidopsis thaliana). PTC1 encodes a PHD-finger (for plant homeodomain) protein, which is expressed specifically in tapetal cells and microspores during anther development in stages 8 and 9, when the wild-type tapetal cells initiate a typical apoptosis-like cell death. Even though ptc1 mutants show phenotypic similarity to ms1 in a lack of tapetal DNA fragmentation, delayed tapetal degeneration, as well as abnormal pollen wall formation and aborted microspore development, the ptc1 mutant displays a previously unreported phenotype of uncontrolled tapetal proliferation and subsequent commencement of necrosis-like tapetal death. Microarray analysis indicated that 2,417 tapetum- and microspore-expressed genes, which are principally associated with tapetal development, degeneration, and pollen wall formation, had changed expression in ptc1 anthers. Moreover, the regulatory role of PTC1 in anther development was revealed by comparison with MS1 and other rice anther developmental regulators. These findings suggest a diversified and conserved switch of PTC1/MS1 in regulating programmed male reproductive development in both dicots and monocots, which provides new insights in plant anther development.     

水稻胞质雄性不育系珍汕97A及其保持系珍汕97B绒毡层发育过程中的Ca2+分布变化

利用焦锑酸钾沉淀法研究了野败不育系珍汕97A及其保持系珍汕97B绒毡层细胞的发育过程及其细胞中Ca2 的分布变化。研究发现保持系绒毡层细胞在单核花粉晚期才开始迅速解体,而不育系绒毡层细胞在花粉母细胞时期就开始出现核膜、细胞膜解体,此过程持续到二核花粉时期。珍汕97A绒毡层细胞从花粉母细胞时期开始,细胞质内有少量颗粒状的Ca2 沉淀;减数分裂时期,绒毡层细胞的内切向壁表面有大量大颗粒的Ca2 沉淀;单核花粉时期绒毡层细胞周围集聚一层Ca2 沉淀。而保持系绒毡层细胞遮花粉母细胞时期和减数分裂时期细胞内没有Ca2 沉淀;单核花粉时期绒毡层细胞内的Ca2 沉淀主要分布在解体的细胞质内。推测绒毡层细胞结构发育的异常和Ca2 的异常分布可能与花粉的败育有关。     

A Comparative Study of Anther and Pollen Development in Male Fertile and Male. Sterile Green Onion (Allium fistulosum L.)

Anther and pollen development in male-fertile and male-sterile green onions was studied. In the male-fertile line, both meiotic microspore mother ceils and tetrads have a callose wall. Mature pollen grains are 2-celled. The elongated generative cell with two bended ends displays a PAS positive cell wall. The tapetum has the character of both secretory and invasive types. From microspore stage onwards, many oil bodies or masses accumulate in the cytoplasm of the tapetal cells. The tapetum degenerates at middle 2-celled pollen stage. In male-sterile line, meiosis in microspore mother cells proceeds normally to form the tetrads. Pollen abortion occurs at microspore with vacuole stage. Two types of pollen abortion were observed. In type I, the protoplasts of the microspores contract and gradually disintegrate. At the same time the cytoplasm of microspores accumulates oil bodies which remain in the empty pollen. The tapetal cells behave normally up to the microspore stage and early stage of microspore abortion, but contain fewer oil bodies or masses than those in the male-fertilt line. At late stage of microspore abortion, three forms of the tapetal ceils can be observed: (1) the tapetal cells with degenerating protoplasts become flattened, (2) the tapetal cells enlarge but protoplasts retractor, (3) the cells break down and tile middle layer enlarges. In type Ⅱ, the cytoplasm degenerates earlier than the nucleus of the microspores and no protoplast is found in the anther locule. There are fibrous thickenings iii the endothecium of both types. It is difficult to verify whether the tapetum behavior and pollen abortion is the cause or the effect.     

Ultrastructural aspects and programmed cell death in the tapetal cells of Lathyrus undulatus Boiss

Programmed cell death (PCD) in the tapetum of Lathyrus undulatus L. was analyzed based on light, fluorescence and electron microscopy to characterize its spatial and temporal occurrence. Development and processes of PCD in secretory tapetal cells of Lathyrus undulatus L. were correlated with the sporogenous cells and pollen grains. At early stages of development the tapetal cells appeared similar to pollen mother cells, structurally. Concurrent with meiosis, tapetum expanded both tangentially and radially as vacuoles increased in size. Tapetal cells most fully developed at young microspore stage. However, tapetum underwent substantial changes in cell organization including nucleus morphology monitored by DAPI. The TUNEL staining confirmed the occurrence of intra-nucleosomal DNA cleavage. In addition to nuclear degeneration which is the first hallmark of PCD other diagnostic features were observed at vacuolated microspore stage intensely; such as chromatin condensation at the periphery of the nucleus, nuclear membrane degeneration, chromatin release to the cytoplasm, vacuole collapse according to tonoplast rupture, shrinkage of the cytoplasm, the increase and enlargement of the endoplasmic reticulum cisternae and disruption of the plasma membrane. After vacuole collapse due to possible release of hydrolytic enzymes the cell components degraded. Tapetal cells completely degenerated at bicellular pollen stage.     

Male sterility associated with APRT deficiency in Arabidopsis thaliana results from a mutation in the gene APT1

Four mutants of Arabidopsis thaliana that are deficient in adenine phosphoribosyl transferase (APRT) activity have been isolated by selecting for germination of seeds and growth of the plantlets on a medium containing 2,6-diaminopurine (DAP), a toxic analog of adenine. In all mutants, DAP resistance is due to a recessive nuclear mutation at a locus designated apt. The mutants are male sterile due to pollen abortion after meiosis. Furthermore, it has been shown that metabolism of cytokinins is impaired in the mutant BM3, which has the lowest level of APRT activity among the mutants tested. However, three different cDNAs encoding APRT have been isolated in A. thaliana and this raised the question of the nature of the mutation which results in low APRT activity. The mutation was genetically mapped to chromosome I and lies within 6 cM of the phenotypic marker dis2, indicating that the mutation affects the APT1 gene, a result confirmed by sequencing of mutant alleles. The mutation in the allele apt1-3 is located at the 5′ splicing site of the third intron, and eliminates a BstNI restriction site, as verified by Southern blotting and PCR fragment length analysis.     

白菜细胞核雄性不育花药的细胞化学观察

对一种由一对隐性基因控制的白菜细胞核雄性不育和可育株的花药进行了细胞学和组织化学研究。种子播种后,有1／4植株为不育株,其余的为可育株。通过对不育株和可育株花药发育的细胞学观察,确认不育花粉的败育发生在小孢子发育时期。用组织化学的方法研究了可育株和不育株花药发育过程中的多糖和脂类的分布动态,发现在减数分裂前,可育花药和不育花药的药隔细胞中都储藏了大量的淀粉粒。二者的差异仅是不育花药的绒毡层细胞液泡化明显。在减数分裂后的小孢子发育时期,可育花药的绒毡层细胞具有将药隔细胞中的淀粉粒多糖吸收并转化成脂类的功能,小孢子及以后的二胞花粉中也积累了大量的脂类储藏物质。在不育花药中,虽然减数分裂后药隔细胞中的淀粉粒也都消失,但绒毡层细胞中的脂类物质相比很少,同时绒毡层细胞显示了明显的多糖反应,表明不育花药的绒毡层细胞将糖类转化为脂类的功能受阻。在小孢子的表面有些脂类物质,但在细胞质中却没有脂类积累。这一结果暗示在该种白菜细胞核雄性不育株中,由于花药绒毡层细胞转换多糖为脂类的功能失常,导致了小孢子的败育。     

ESCRT components ISTL1 andLIP5 are required for tapetal function and pollen viability

Pollen wall assembly is crucial for pollen development and plant fertility. The durable biopolymer sporopollenin and the constituents of the tryphine coat are delivered to developing pollen grains by the highly coordinated secretory activity of the surrounding tapetal cells. The role of membrane trafficking in this process, however, is largely unknown. In this study, we used Arabidopsis thaliana to characterize the role of two late-acting endosomal sorting complex required for transport (ESCRT) components, ISTL1 and LIP5, in tapetal function. Plants lacking ISTL1 and LIP5 form pollen with aberrant exine patterns, leading to partial pollen lethality. We found that ISTL1 and LIP5 are required for exocytosis of plasma membrane and secreted proteins in the tapetal cells at the free microspore stage, contributing to pollen wall development and tryphine deposition. Whereas the ESCRT machinery is well known for its role in endosomal trafficking, the function of ISTL1 and LIP5 in exocytosis is not a typical ESCRT function. The istl1 lip5 double mutants also show reduced intralumenal vesicle concatenation in multivesicular endosomes in both tapetal cells and developing pollen grains as well as morphological defects in early endosomes/trans-Golgi networks, suggesting that late ESCRT components function in the early endosomal pathway and exocytosis.

Endosomal sorting complex required for transport proteins ISTL1 and LIP5 are required for exocytosis of both plasma membrane and secreted proteins in tapetal cells during microspore formation.     

洋葱花药发育过程中的细胞化学研究(简报)

高等植物花药结构复杂,其发育更是一个迅速、多变的过程,如小孢子母细胞减数分裂期间的细胞质改组、胼胝质壁的形成与降解、大液泡的形成与消失、花粉内外壁的形成、绒毡层细胞的降解、营养物质的积累与转化等。除了上述花药组成细胞的形态和结构发生明显变化外。花药发育的另一个显著特点是以花粉为中心的营养物质单向运输和转化,尤其是小孢子有丝分裂形成二胞花粉后开始积累大量的营养储存物以供成熟花粉萌发时利用。