Mechanism of low‐temperature‐induced pollen failure in rice

Low‐temperature stress during microspore development alters cellular organization in rice anthers. The major cellular damage includes unusual starch accumulation in the plastids of the endothecium in postmeiotic anthers, abnormal vacuolation and hypertrophy of the tapetum, premature callose (1,3‐β‐glucan) breakdown and lack of normal pollen wall formation. These cellular lesions arise from damage to critical biochemical processes that include sugar metabolism in the anthers and its use by the microspores. Failure of utilization of the callose breakdown product and other microspore wall components like sporopollenin can also be considered as critical. In recent years, considerable progress has been made in the understanding of major biochemical processes including the expression of critical genes that are sensitive to low temperature in rice and cause male sterility. This paper combines a discussion of cellular organization and associated biochemical processes that are sensitive to low temperatures and provides an overview of the potential mechanisms of low‐temperature‐induced male sterility in rice.     

Cellular organisation in meiotic and early post-meiotic rice anthers

We have used fluorescent, confocal laser and transmission electron microscopy (TEM) to examine cellular organisations, including callose (1,3-beta-glucan) behaviour, in meiotic and early post-meiotic rice anthers. These features are critical for pollen formation and provide information to better understand pollen sterility caused by abiotic stress in rice and other monocotyledonous species. Among organelles during meiosis, abundant plastids, mitochondria and nuclei of the anther cells show distinctive features. Chloroplasts in the endothecium store starch and indicate a potential for photosynthetic activity. During meiosis, the middle layer cells are markedly compressed and at the tetrad stage are either vacuolated or filled with degenerating electron-opaque organelles. Viable mitochondria, stained with Rhodamine 123, are seen in the endothecium and tapetum, but the mitochondria in the middle layer are not stained during meiosis. The radial walls of the tapetum are disorganised and degenerating, indicating the formation of a syncytium; pro-orbicules are located at the locular walls at the tetrad stage. Immunohistochemical studies show that the sporogenous cells are entirely enveloped by a thick callosic layer at early meiosis. Cell plate callose was assembled in a plane between the dyad cells. In the tetrads, however, callose formed only at the centre, showing that the tetrad microspores are not enveloped but separated by callose walls. Thick, undulating electron-opaque walls around the tetrads indicate the beginning of exinous microspore wall differentiation.     

Anther wall and pollen development in Ophrys mammosa L. (Orchidaceae)

The objective of this study was to investigate anther wall and pollen development in Ophrys mammosa. Primary sporogen tissue resembles longitudinal cells with divided archeosporal cells. Thereafter these primary sporogen tissue cells re-divide anticlinally and periclinally forming secondary sporogen tissue. Microsporogenesis was successive type. Microgametogenesis occurred at the distal poles of the microspores. In addition, dense starch accumulation was detected in the pollen. Pollinia and massulae are separated from each other by dead cells filled with callose, according to histochemical preparations. The anther wall was a four-layered “monocotyledon” type. There was ring-like wall thickening in the endothecium. The tapetum is of the glandular type. When these two developmental processes are compared, it is seen that the anther wall has become mature by the sporogen tissue phase and is composed of only epidermis and endothecium at the beginning of microgametogenesis.     

LP28, a lily pollen-specific LEA-like protein, is located in the callosic cell wall during male gametogenesis

. LP28, a pollen-specific LEA-like protein identified in Lilium longiflorum purportedly related to the desiccation tolerance of pollen, was localized during male gametogenesis using immuno-electron microscopy. At premeiotic interphase, LP28 label is absent from the microsporocyte. LP28 label was first detected in the cell wall of the microsporocyte at meiotic prophase I. LP28 gradually increased as the cell wall thickened. In the dyad, after the first meiotic division, LP28 label also appeared in the septum. In the tetrad, after the second meiotic division, LP28 was detected throughout the cell wall, including the septa. Immunolabeling of callose during meiosis indicated that the appearance and localization of LP28 was very similar to that of callose. After the microspores were released from the tetrad by digesting the callosic cell wall, LP28 was not found in the microspores. In bicellular pollen, just after microspore mitosis, LP28 appeared in the generative cell wall, which also consisted of callose. After pollen germination, LP28 also accumulated in the callosic layer of the elongated pollen tube wall and the callose plug. Thus, LP28 colocalized with the callosic cell wall during male gametogenesis. The possible role of LP28 with respect to wall formation during meiosis and pollen development is discussed.     

低温预处理影响水稻花药培养效率的机理初探

低温预处理延缓药壁中层和绒毡层的降解,促进表皮层和药室内壁层的发育,延缓花药过氧化物酶同工酶活性的增强。处理期间花药可溶性蛋白质、淀粉酶同工酶潜带发生明显变化。处理期间花药的~3H-TdR渗入和花粉的发育、分裂,表明花粉存在合成和充实活动。绒毡层和花粉间存在囊泡,表皮层和药室内壁层之间存在多泡体的穿壁运动,说明低温处理中药壁向花粉输送雄核发育所需的物质。在进入正常培养初期,经过低温处理的花药药壁仍有表皮层和药室内壁层的发育,多细胞花粉出现提早、数量增加,花粉退化延缓。而未经处理的花药药壁各层均迅速降解,花粉大量退化。     

Cytochemical study of developing anthers of Amomum villosum Lour.

We analyzed anther development in Amomum villosum Lour. (Zingiberaceae) using the periodic acid-Schiff's technique and Sudan black staining to test for the presence of starch and lipids, respectively. Our analyses showed that microspore mother cells of A. villosum lack typical callose walls, and numerous lipid granules appear in the cells early in development. Some starch granules are present in anther wall cells, but not in tapetal cells. After meiosis, numerous lipid granules remain unchanged in the microspores. During microspore development, some small starch granules first appear in the central cell region, and then the starch granules increase in size. After microspore division, the bicellular pollen grains become filled with starch and lipids, and remain in this state until the pollen grains reach maturity. At anthesis, the anther wall of A. villosum consists of several layers of endothecium cells with an evidently thickened radial wall, and some layers of parenchyma cells containing numerous starch granules.     

雄性可育与雄性不育籽粒苋小孢子发育研究

栽培种籽粒苋（ＡｍａｒａｎｔｈｕｓｈｙｐｏｃｈｏｎｄｒｉａｃｕｓＬ。）是一种很有潜力的新型作物。它营养价值高、蛋白质含量丰富、氨基酸平衡好、耐旱、耐盐碱和酸、抗逆性强、适应性广,被认为是极有潜力的、为全球提供粮食的替代作物之一。但是籽粒苋千粒重仅０．７～１．２ｇ,种子易散落、植株易倒伏。而且,籽粒苋花冠微小、花期无限,难于采用人工去雄授粉进行杂交育种。于是,和许多其它植物一样,籽粒苋中也找到了雄性不育株。但是它的小孢子发育过程及其败育时期和不育特征尚不清楚,为它的杂交育种研究带来不便。本文通过电镜对雄性可育和不育的两种籽粒苋小孢子分别进行了观察。发现不育小孢子败育起始于四分体释放以后的单核花粉期。在此之前小孢子的发育是一样的。花粉分化早期,孢原组织分化出初级造孢组织、绒毡层、中间层、药壁内层和表皮层（图１）;造孢组织继续分裂,细胞不断扩大,形成小孢子母细胞（图２）;小孢子母细胞不断增大,周围积累胼胝质并逐渐与绒毡层分离,出现大液泡（图３）,小孢子母细胞减数分裂,四分体形成,包埋于胼胝质中;绒毡层有丝分裂,有双核细胞;大液泡消失;细胞壁开始降解（图４）。胼胝质逐渐消失,小孢子从四分体中释放以后（单核花粉期）,     

Tetrad pollen formation in quartet mutants of Arabidopsis thaliana is associated with persistence of pectic polysaccharides of the pollen mother cell wall

The quartet (qrt) mutants of Arabidopsis thaliana produce tetrad pollen in which microspores fail to separate during pollen development. Because the amount of callose deposition between microspores is correlated with tetrad pollen formation in other species, and because pectin is implicated as playing a role in cell adhesion, these cell-wall components in wild-type and mutant anthers were visualized by immunofluorescence microscopy at different stages of microsporogenesis. In wild-type, callose was detected around the pollen mother cell at the onset of meiosis and around the microspores during the tetrad stage. Microspores were released into the anther locule at the stage where callose was no longer detected. Deposition and degradation of callose during tetrad pollen formation in qrt1 and qrt2 mutants were indistinguishable from those in wild-type. Enzymatic removal of callose from wild-type microspores at the tetrad stage did not release the microspores, suggesting that callose removal is not sufficient to disperse the microspores in wild-type. Pectic components were detected in the primary wall of the pollen mother cell. This wall surrounded the callosic wall around the pollen mother cell and the microspores during the tetrad stage. In wild-type, pectic components of this wall were no longer detectable at the time of microspore release. However, in qrt1 and qrt2 mutants, pectic components of this wall persisted after callose degradation. This result suggests that failure of pectin degradation in the pollen mother cell wall is associated with tetrad pollen formation in qrt mutants, and indicates that QRT1 and QRT2 may be required for cell type-specific pectin degradation to separate microspores.     

山麦冬大小孢子发生及雌雄配子体发育研究

采用石蜡切片技术对百合科植物山麦冬大小孢子发生及雌雄配子体发育进行了观察研究。结果表明:(1)山麦冬花药具有4个花粉囊,花药壁的发育方式为基本型,花药壁完全分化时由表皮、药室内壁、中层及绒毡层组成。(2)绒毡层发育类型为分泌型,到四分体孢子彼此分离形成单细胞花粉阶段,绒毡层细胞开始解体退化,花粉成熟时绒毡层细胞完全消失;花粉母细胞减数分裂为连续型,四分体为左右对称形排列,成熟花粉为3-细胞花粉,单萌发沟。(3)子房3室,每室2枚胚珠,胚珠倒生型,双珠被,薄珠心,雌性孢原细胞不经过平周分裂而直接发育而成大孢子母细胞。(4)减数分裂后四分体大孢子呈线型或T型排列,合点端大孢子分化为功能大孢子,胚囊发育为蓼型;花粉母细胞减数分裂过程中,二分体、四分体细胞外方被胼胝质壁所包被,小孢子形成后胼胝质壁逐渐消失。该研究结果丰富了百合科植物生殖生物学研究的内容,也为探讨百合科植物的系统学研究提供了参考。     

七叶树小孢子发生及雄配子体发育研究

用石蜡切片法观察了七叶树花药的发育过程.结果表明:(1)雄蕊花药四室,花药壁完全分化时,从外到内依次是表皮、药室内壁、中层和绒毡层,花药壁发育为基本型.表皮细胞1层,发育过程中始终存在;药室内壁在花药成熟时形成带状纤维层加厚;幼小花药壁的中层3~4层细胞,在花药发育成熟时退化消失;绒毡层1层细胞,发育类型为分泌型,小孢子母细胞减数分裂时绒毡层开始退化解体,花药成熟完全消失,仅剩1层绒毡层膜.每一花药中有多列雄性孢原细胞,发生于幼小花药表皮下方;(2)小孢子母细胞减数分裂为同时型,四分体多呈正四面体排列;减数分裂过程中,小孢子母细胞外方被胼胝质壁所包被,小孢子形成后胼胝质壁逐渐消失.成熟花粉二细胞型,外形呈圆三角状,具三孔沟.     

Anther, pollen and tapetum development in safflower, Carthamus tinctorius L

In safflower, the anther wall at maturity consists of a single epidermis, an endothecium, a middle layer and the tapetum. The tapetum consists mainly of a single layer of cells. However, this single-layer appearance is punctuated by loci having ‘two-celled’ groupings due to additional periclinal divisions in some tapetal cells. Meiotic division in microsporocytes gives rise to tetrads of microspores. The primexine is formed around the protoplasts of microspores while they are still enveloped within the callose wall. Just prior to microgametogenesis, the microspores enlarge through the process of vacuolation, and the exine wall pattern becomes established. Microgametogenesis results in the formation of 3-celled pollen grains. The two elongated sperm cells appear to be connected. The exine wall is highly sculptured with a distinct tectum, columellae, a foot layer, an endexine and a thin intine. Similar to other members of the Asteraceae family, the tapetum is of the invasive type. The most novel finding of this study is that in addition to the presence of invasive tapetal cells, a small population of ‘non-invasive’ tapetal cells is also present. The tapetal cells next to the anther locules in direct contact with the microspores become invasive and start to grow into the space between developing microspores. These tapetal cells synthesize tryphine and eventually degenerate at the time of gametogenesis releasing their content into the anther locules. A smaller population of non-invasive tapetal cells is formed as a result of periclinal divisions at the time of tapetum differentiation. These cells are not exposed to the anther locules until the degeneration of the invasive tapetal cells. The non-invasive tapetal cells have a different cell fate as they synthesize pollenkitt. This material is responsible for allowing some pollen grains to adhere to each other and to the anther wall after anther dehiscence. This observation explains the out-crossing ability of Carthamus species and varieties in nature.     

Callose synthase (CalS5) is required for exine formation during microgametogenesis and for pollen viability in Arabidopsis

Callose (beta-1,3-glucan) is produced at different locations in response to biotic and abiotic cues. Arabidopsis contains 12 genes encoding callose synthase (CalS). We demonstrate that one of these genes, CalS5, encodes a callose synthase which is responsible for the synthesis of callose deposited at the primary cell wall of meiocytes, tetrads and microspores, and the expression of this gene is essential for exine formation in pollen wall. CalS5 encodes a transmembrane protein of 1923 amino acid residues with a molecular mass of 220 kDa. Knockout mutations of the CalS5 gene by T-DNA insertion resulted in a severe reduction in fertility. The reduced fertility in the cals5 mutants is attributed to the degeneration of microspores. However, megagametogenesis is not affected and the female gametes are completely fertile in cals5 mutants. The CalS5 gene is also expressed in other organs with the highest expression in meiocytes, tetrads, microspores and mature pollen. Callose deposition in the cals5 mutant was nearly completely lacking, suggesting that this gene is essential for the synthesis of callose in these tissues. As a result, the pollen exine wall was not formed properly, affecting the baculae and tectum structure and tryphine was deposited randomly as globular structures. These data suggest that callose synthesis has a vital function in building a properly sculpted exine, the integrity of which is essential for pollen viability.     

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。     

Study of male sterility in Taiwania cryptomerioides Hayata (Taxodiaceae)

Summary. A study of male sterility over a period of three consecutive years on a conifer species endemic to Taiwan, Taiwania cryptomerioides Hayata (Taxodiaceae), was done for this article. With the aids of fluorescence and electron microscopic observations, the ontogenic processes in the fertile and sterile microsporangia are compared, using samples collected from Chitou Experimental Forest and Yeou-Shoei-Keng Clonal Orchard of the National Taiwan University, Nantou, Taiwan. The development of male strobili occurred from August to the end of March. Microsporogenesis starts with the formation of the archesporium and ends with the maturation of 2-celled pollen grains within the dehiscing microsporangium. Before meiosis, there was no significant difference in ultrastructure between the fertile and sterile microsporangia. Asynchronous pollen development with various tetrad forms may occur in the same microsporangium of either fertile or sterile strobili. However, a callose wall was observable in the fertile dyad and tetrad, but not in the sterile one. After dissolution of the callose wall, the fertile microspores were released into the locule, while some sterile microspores still retained as tetrads or dyads with intertwining of exine walls in the proximal faces. As a result, there was no well developed lamellated endexine and no granulate ectexine or intine in the sterile microspores. Eventually, the intracellular structures in sterile microspores were dramatically collapsed before anthesis. The present study shows that the abortion in pollen development is possibly attributed to the absence of the callose wall. The importance of this structure to the male sterility of T. cryptomerioides is discussed. Correspondence and reprints: Department of Life Science, National Taiwan University, 106 Taipei, Taiwan.     

凤仙花花药发育中多糖和脂滴组织化学研究

以不同发育时期的凤仙花花药为实验材料,采用组织化学方法,对花药发育中的结构变化及多糖和脂滴物质分布进行观察。结果表明:(1)凤仙花的花药壁由6层细胞组成,包括1层表皮细胞,2层药室内壁细胞,2层中层细胞和1层绒毡层细胞。其中绒毡层细胞的形态不明显,很难与造孢细胞区分,且在小孢子母细胞时期退化。(2)在小孢子母细胞中出现了一些淀粉粒,但减数分裂后,早期小孢子中的淀粉粒消失,又出现了一些小的脂滴;随着花粉的发育,小孢子形成大液泡,晚期小孢子中的脂滴也消失;小孢子分裂形成二胞花粉后,营养细胞中的大液泡降解、消失,二胞花粉中又开始积累淀粉;接近开花时,成熟花粉中充满细胞质,其中包含了较多的淀粉粒和脂滴。(3)在凤仙花的花药发育中,绒毡层细胞很早退化,为小孢子母细胞和四分体小孢子提供了营养物质;其后的中层细胞退化则为后期花粉发育提供了营养物质。     

MS32-regulated timing of callose degradation during microsporogenesisin Arabidopsis is associated with the accumulation of stacked rough ER in tapetal cells

  In the male sterile32(ms32)mutant in Arabidopsis thaliana, pollen development is affected during meiosis of pollen mother cells (PMCs). In normal wild-type (WT) anthers, callose is deposited around PMCs before and during meiosis, and after meiosis the tetrads have a complete callose wall. In ms32, PMCs showed initial signs of some callose deposition before meiosis, but it was degraded soon after, as was part of the cellulosic wall around the PMCs. The early dissolution of callose in ms32 was associated with the occurrence of extensive stacks of rough ER (RER) in tapetal cells. The stacks of RER were also observed in the WT tapetum, but at a later stage, i.e., after the tetrads were formed and when callose is normally broken down for release of microspores. Based on these observations it is suggested that: (1) callose degradation around developing microspores is linked to the formation of RER in tapetal cells, which presumably synthesize and/or secrete callase into the anther locule, and (2) mutation in MS32 disrupts the timing of these events. Received: 27 April 1999 / Revision accepted: 21 June 1999     

Anther starch variations in Lilium during pollen development

Starch was cytologically localized and biochemically assayed in different anther cell layers of Lilium cv. Enchantment during pollen development and its presence was correlated with anther growth. Two phases could be distinguished: the first, the growth phase, extends from the beginning of meiosis to the vacuolated microspore stage and corresponds to maximum increase in anther size and weight. During this period, microspores lack amyloplasts and starch is degraded in the outer staminal wall layers. The tapetum does not contain starch reserves but accumulates a PAS-positive substance in its vacuole. The second phase, the maturation phase, begins with the late vacuolated microspore stage and lasts until pollen maturation. Anther growth is slowed during this phase. A wave of amylogenesis/ amylolysis occurs first in the late vacuolated-microspores and young pollen grains and, next, in the staminal envelopes. In the pollen grain, the cytoplasm of the vegetative cell is filled with starch, but amyloplasts are not detected in the generative cell. When pollen grains ripen, amylaceous reserves are replaced with lipids. In the staminal envelopes, the second amylogenesis is particularly evident in the endothecium and the middle layers; the peak of starch is reached at the young bicellular pollen grain stage; starch disappears from the anther wall early during the maturation phase. The wave of amylogenesis/amylolysis occurring in the staminal envelopes during the maturation phase is peculiar to Lilium. It is interpreted as a sudden increase in carbohydrate level caused by lower anther needs when the growth is completed. Staminal envelopes may act as a physiological buffer and regulate soluble sugar level in the anther. Stages of anther growth correlate with starch content variations and this suggests that during the growth phase, products of starch hydrolysis in the staminal envelopes may be consumed partly by anther cell layers and partly by microspores.     

Tapetum-Specific Expression of the Gene for an Endo-{beta}-1,3-glucanase Causes Male Sterility in Transgenic Tobacco

A cDNA for a pathogenesis-related endo-ß-1,3-glucanaseisolated from soybean, was fused to an anther tapetum-specificpromoter (Osg6B promoter) isolated from rice and the resultingchimeric gene was introduced into tobacco. The Osg6B promoterbecame active in the anther tapetum during formation of tetradsand the tapetal glucanase activity in the transgenic plantscaused in a significant reduction in the number of fertile pollengrains. Most of the pollen grains were aberrant in shape, lackedgerminal apertures and aggregate of the pollen grains. Granulesof ß-1,3-glucan, which have not previously been reported,were often observed to adhere to the surface of the pollen grains.Further observations revealed that the callose wall was almostabsent in the pollen tetrads of transgenic plants. In wild-typeplants, by contrast, the tetrads were surrounded by callosethat was degraded soon after the tetrad stage to release freemicrospores. Thus, the introduced gene for endo-ß-1,3-endoglucanaseunder the control of the Osg6B promoter caused digestion ofthe callose wall at the beginning of the tetrad stage, a timethat was just a little earlier than the time at which endogenousglucanase activity normal appears. These results demonstratethat premature dissolution of the callose wall in pollen tetradscauses male sterility and suggest that the time at which tapetallyproduced glucanase is activate is critical for the normal developmentof microspores. (Received September 29, 1994; Accepted January 30, 1995)