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.     

光(温)敏核不育水稻花药和小孢子发生的细胞化学

利用细胞化学方法,对光（温）敏核不育水稻农垦585和W6154S的花药和小孢子发生过程的观察结果表明,在可育条件下,其花药组织和小孢子发生过程不论形态结构还是细胞化学变化都基本一致。小孢子母细胞时期的药隔薄壁组织、药壁中层及药室内壁中分布了一些多糖颗粒,但到进入减数分裂时多糖颗粒基本消失。绒毡层在解体前一直富含细胞质,从染色反应看,它表现为小孢子母细胞时期的蛋白质向减数分裂开始后的多糖物质的转变过程。在不育条件下,农垦585在小孢子母细胞时期就出现异常,其败有时间比W6154S要稍早一些。两者最后都表现为典败,但W6154S的花药壁解体较为彻底,只剩下干皱的表皮和药室内壁,而农垦585的花药壁还有多层细胞结构。     

Secretory tapetum of Brassica oleracea L.: polarity and ultrastructural features

Summary The ultrastructure of the secretory, binucleate tapetum of Brassica oleracea in the micro spore mother cell (MMC) stage through to the mature pollen stage is reported. The tapetal cells differentiate as highly specialized cells whose development is involved in lipid accumulation in their final stage. They start breaking down just before anther dehiscence. Nuclei with dispersed chromatin, large nucleoli and many ribosomes in the cytoplasm characterize the tapetal cells. The wall-bearing tapetum phase ends at the tetrade stage. The dissolution of tapetal walls begins from the inner tangential wall oriented towards the loculus and proceeds gradually along the radial walls to the outer tangential one. The plasmodesmata transversing the radial walls between tapetal cells persist until the mature microspore, long after loss of the inner tangential wall. After wall dissolution, the tapetal protoplasts retain their integrity and position within the anther locule. The tapetal cell membrane is in direct contact with the exine of the microspores/pollen grains and forms tubular evaginations that increase its surface area and appear to be involved in the translocation of solutes from the tapetal cells to the microspores/ pollen grains. The tapetal cells exhibit a polarity expressed by spatial differentiation in the radial direction.     

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。     

Two male-sterile mutants of Zea Mays (Poaceae) with an extra cell division in the anther wall

Two recessive male-sterile mutants of maize with similar patterns of pollen abortion were studied. Genetic studies showed that one of the two mutations was allelic with a previously identified male-sterility locus (ms23) and the other mutation was in a newly identified male-sterility locus (ms32). Cytological characterization of homozygous mutants and fertile heterozygous control siblings was performed using brightfield, fluorescence, and electron microscopy. During normal anther development, the final anther wall periclinal division divides the secondary parietal anther wall layer into the middle layer and tapetum, forming an anther with four wall layers. This is followed by differentiation of the tapetal cells into protoplastic binucleate, secretory tissue. In both the ms23 and ms32 mutants, the prospective tapetal layer divided into two layers, termed t1 and t2, forming an anther with five wall layers. Neither the t1 nor the t2 layers differentiated normally into tapetal layers, as determined by examination of cell walls, nucleus number, and cytoplasmic organization. Pollen mother cells aborted after the onset of prophase I of meiosis, suggesting that an early developmental coordination may exist between tapetum and pollen mother cells.     

华木莲花药的发生发育

报道华木莲花药的结构和小孢子的形成与发育。华木莲雄蕊多数、离生;每一花药具4个花粉囊。花粉囊由1层表皮、1层纤维层、2层中层和2层绒毡层细胞组成。腺质绒毡层在小孢子发生发育过程中,呈现出解体-恢复-解体直至消失的现象。减数分裂为同时型,四分体主要为左右对称和四面体形。撒粉时的成熟花粉为二细胞结构。     

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.     

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.     

百合花药壁层的发育及组织化学研究

对生长在陕西留坝的百合的花药壁层发育过程,特别是绒毡层的发育做了形态学观察。其结果是：百合花药壁层的发育方式为基本型。花药绒毡层属腺质绒毡层类型。在单细胞花粉阶段后期,部分花粉粒壁一侧凹陷时,绒毡层细胞内切向面上出现乌氏体。随着发育阶段的推移,乌氏体的数量有所增加。在光学显微镜下观察：每个乌氏体只有一个乌氏体芯。在乌氏体出现时,也可观察到花粉外壁外层的出现。到二细胞花粉时,花药开裂之前,绒毡层细胞     

Receptor-like protein kinase 2 (RPK 2) is a novel factor controlling anther development in Arabidopsis thaliana

Receptor-like kinases (RLK) comprise a large gene family within the Arabidopsis genome and play important roles in plant growth and development as well as in hormone and stress responses. Here we report that a leucine-rich repeat receptor-like kinase (LRR-RLK), RECEPTOR-LIKE PROTEIN KINASE2 (RPK2), is a key regulator of anther development in Arabidopsis. Two RPK2 T-DNA insertional mutants (rpk2-1 and rpk2-2) displayed enhanced shoot growth and male sterility due to defects in anther dehiscence and pollen maturation. The rpk2 anthers only developed three cell layers surrounding the male gametophyte: the middle layer was not differentiated from inner secondary parietal cells. Pollen mother cells in rpk2 anthers could undergo meiosis, but subsequent differentiation of microspores was inhibited by tapetum hypertrophy, with most resulting pollen grains exhibiting highly aggregated morphologies. The presence of tetrads and microspores in individual anthers was observed during microspore formation, indicating that the developmental homeostasis of rpk2 anther locules was disrupted. Anther locules were finally crushed without stomium breakage, a phenomenon that was possibly caused by inadequate thickening and lignification of the endothecium. Microarray analyses revealed that many genes encoding metabolic enzymes, including those involved in cell wall metabolism and lignin biosynthesis, were downregulated throughout anther development in rpk2 mutants. RPK2 mRNA was abundant in the tapetum of wild-type anthers during microspore maturation. These results suggest that RPK2 controls tapetal cell fate by triggering subsequent tapetum degradation, and that mutating RPK2 impairs normal pollen maturation and anther dehiscence due to disruption of key metabolic pathways.     

Calcium distribution in fertile and sterile anthers of a photoperiod-sensitive genic male-sterile rice

Potassium antimonate was used to locate Ca²⁺ in fertile and sterile anthers of a photoperiod-sensitive genic male-sterile rice (Oryza sativa L. japonica). During the development of fertile anthers, abundant calcium precipitates accumulated in the anther walls and on the surface of pollen grains and Ubish bodies at the late developmental stage of the microspore, but not in the cytoplasm of pollen grains. Following the accumulation of starch grains in pollen, calcium precipitates on pollen walls diminished and increased in parenchymatous cells of the connective tissue. In sterile anthers, calcium precipitates were abundant in the middle layer and endothecium, but not in the tapetum, as was found in fertile anthers. A special cell wall was observed between the tapetum and middle layer of sterile anthers that appeared to relate to distinctive calcium accumulation patterns and poor pollen wall formation in the loculi. The formation of different patterns of antimonate-induced calcium precipitates in the anthers of photoperiod-sensitive genic male-sterile rice indicates that anomalies in the distribution of calcium accumulation correlate with the failure of pollen development and pollen abortion. Received: 30 May 1997 / Accepted: 5 July 1997     

毛竹的花药发育研究

竹类植物因有着较长的开花周期,其生殖生物学研究的报道相对较少。该研究采用石蜡切片与野外观察的方法,对毛竹花药的发育以及花药发育与花序的关系进行了研究。结果表明:毛竹的花药壁结构包括4层细胞:表皮细胞、药室内壁细胞、中层细胞和绒毡层细胞。药室内壁和中层都只有一层细胞,而且细胞形状较扁,花药发育后期药室内壁会逐渐降解,而中层则会完全解体消失。花药壁的发育为单子叶型,绒毡层为腺质型,而且只有一层,细胞径向较长,最后也会消失。小孢子母细胞减数分裂时,胞质分裂方式为连续型。形成的小孢子经一次有丝分裂后逐渐形成成熟花粉粒,大多为二细胞型,很少产生三细胞型。此外,还发现毛竹花药的发育与花序形态变化存在着相对应的关系。野外连续观察和切片发现,随着花序形态的不断发育变化,首先花药开始形成并不断分化,药壁备层也逐渐形成;接着小孢子逐渐成熟,备层也慢慢随之解体、消失;最后花药逐渐开裂并开始散粉。该研究结果不仅丰富了毛竹和竹类生殖生物学的研究内容,而且对毛竹种质的研究也具有重要意义。     

芡实绒毡层细胞发育的超微结构变化

芡实（ Ｅｕｒｙａｌｅｆｅｒｏｘ Ｓａｌｉｓｂ） 绒毡层细胞在小孢子母细胞时期, 质体出现明显的变形期,细胞中二核常相互贴近或呈嵌合状态, 细胞壁间层中胞间连丝发达。减数分裂期, 绒毡层细胞壁融解消失, 胞间连丝断离, 细胞间发育出现不同步现象。质体开始积累淀粉, 部分质体呈空泡状, 并出现质体膜内陷, 这与液泡具相似的功能。四分体时期, 绒毡层细胞内部结构开始解体。单核小孢子时期, 绒毡层细胞解体消失, 使小孢子后期发育的营养来源受到影响,作者认为这是生产上成熟花粉囊中花粉粒少而且发育不正常的主要原因之一。     

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.     

Emergence and patterning of the five cell types of the Zea mays anther locule

One fundamental difference between plants and animals is the existence of a germ-line in animals and its absence in plants. In flowering plants, the sexual organs (stamens and carpels) are composed almost entirely of somatic cells, a small subset of which switch to meiosis; however, the mechanism of meiotic cell fate acquisition is a long-standing botanical mystery. In the maize (Zea mays) anther microsporangium, the somatic tissues consist of four concentric cell layers that surround and support reproductive cells as they progress through meiosis and pollen maturation. Male sterility, defined as the absence of viable pollen, is a common phenotype in flowering plants, and many male sterile mutants have defects in somatic and reproductive cell fate acquisition. However, without a robust model of anther cell fate acquisition based on careful observation of wild-type anther ontogeny, interpretation of cell fate mutants is limited. To address this, the pattern of cell proliferation, expansion, and differentiation was tracked in three dimensions over 30 days of wild-type (W23) anther development, using anthers stained with propidium iodide (PI) and/or 5-ethynyl-2′-deoxyuridine (EdU) (S-phase label) and imaged by confocal microscopy. The pervading lineage model of anther development claims that new cell layers are generated by coordinated, oriented cell divisions in transient precursor cell types. In reconstructing anther cell division patterns, however, we can only confirm this for the origin of the middle layer (ml) and tapetum, while young anther development appears more complex. We find that each anther cell type undergoes a burst of cell division after specification with a characteristic pattern of both cell expansion and division. Comparisons between two inbreds lines and between ab- and adaxial anther florets indicated near identity: anther development is highly canalized and synchronized. Three classical models of plant organ development are tested and ruled out; however, local clustering of developmental events was identified for several processes, including the first evidence for a direct relationship between the development of ml and tapetal cells. We speculate that small groups of ml and tapetum cells function as a developmental unit dedicated to the development of a single pollen grain.     

Distribution of insoluble polysaccharides, neutral lipids, and proteins in the developing anthers of Campsis radicans (L.) Seem. (Bignoniaceae)

In this study, distribution of polysaccharides, lipids, and proteins in the developing anthers of Campsis radicans (L.) Seem. was examined from sporogenous cell stage to mature pollen, using cytochemical methods. To detect the distribution and dynamic changes of insoluble polysaccharides, lipid bodies, and proteins in the anthers through progressive developmental stages, semi-thin sections of anthers at different developmental stages were stained with periodic-acid-Schiff (PAS) reagent, Sudan black B, and Coomassie brilliant blue, respectively, and examined under light microscope. Ultrastructural observations with TEM were also carried out to determine the storage form of starch in the connective tissue, and storage form of lipids in the tapetal cells. In sporogenous cell stage, anther wall contains numerous insoluble polysaccharides. However, from the sporogenous cell stage to the vacuolated microspore stage, the amount of insoluble polysaccharides in the anther wall decreases gradually. At bicellular pollen stage, tapetum degenerates completely and polysaccharides are not seen in the anther wall. Lipid bodies are observed in the cytoplasm of both middle layer and tapetal cells at tetrad stage, whereas they disappear in the vacuolated microspore stage. Compared with polysaccharides, proteins are limited in the anther wall at early stages of development. During pollen development, polysaccharides, proteins, and lipid bodies are scarce in the cytoplasm of sporogenous cells, but their amount increases at premeiotic stage. From tetrad stage to bicellular pollen stage, microspore cytoplasm contains variable amount of insoluble polysaccharide grains, lipid and protein bodies. At bicellular pollen stage, plentiful amount of starch granules are stored in the cytoplasm of the pollen grains. Proteins and lipid bodies are also present in the cytoplasm.     

Development and cytochemistry of pollen and tapetum in Mitriostigma axillare (Rubiaceae)

The development of pollen grains and tapetum in Mitriostigma axillare (Rubiaceae) was studied from anther primordium to dehiscence. Anthers were freeze-cracked and studied with SEM. Embedded anthers were sectioned and studied with LM and TEM. Cytochemistry was performed in order to distinguish the different layers of the sporoderm and to determine its chemical nature at different development stages. The pollen grains remained as tetrads by partial fusion of the exine, probably because of reduced callose septa during the stage of microspore tetrads within callose envelopes. Characteristic features of the sporoderm were an irregular foot layer, an endexine composed of amalgamated granules, a transient granular-fibrous layer beneath the endexine, and a thin intine. During maturation of the exine, the endexine became chemically different from the ectexine. All layers of the sporoderm were reduced in thickness due to stretching during the engorgement of the pollen grains prior to dehiscence. The pollen grains were colpoidorate with a reticulate to microreticulate tectum covered with a scanty surface coating. The mature pollen grains were binucleate and contained a lot of starch grains. Thick intineous onci protruded through the apertures and formed papillae. About 50% of the microspores were aborted. The tapetum was of secretory type, probably with cycles of hyperactivity and protrusions of the cells into the locular cavity. No syncytium was formed and there were neither orbicules nor tapetal membrane.     

丹参小孢子发生和雄配子体发育过程的解剖学研究

在显微水平上对丹参小孢子发生和雄配子体的发育过程及其与不同发育阶段花蕾的外部形态的相关性进行了研究。结果表明：丹参有2枚雄蕊,每个花药具2个花粉囊．小孢子母细胞减数分裂属同时型,小孢子在四分体中的排列属四面体型。成熟花粉粒属3细胞型并有6个萌发沟。花粉囊壁发育属双子叶型,由4层细胞构成,即表皮、药室内壁、中层和绒毡层。绒毡层细胞为腺质,二核。植株花蕾肉眼可见,大小在1～1.5mm时雄蕊孢原细胞开始分化;花蕾长至9～12mm。即从钟型花萼的钟口肉眼可见乳白色花瓣时．形成成熟的雄配子体,雄配子体具有3细胞的花粉粒。     

Pollen development of Cardiocrinum giganteum (Wall.) Makina in China

In this article, we studied the pollen morphology and wall development, microsporogenesis, male gametophyte development, and anther wall structure changes during pollen development of Cardiocrinum giganteum (Wall.) Makina from the genus Cardiocrinum (Endl.) Lindl. (Liliaceae) using paraffin sections, scanning and transmission electron microscopy, and fluorescence microscopy. The results showed that C. giganteum has oval-shaped pollen with a single sulcus and reticulate ornamentation. The exine is of the semi-tectum type and can be divided into the tectum layer, columellate layer and basal layer. Meiosis in the microsporocyte is accompanied by successive cytokinesis. The mature pollen is three-celled. The anther wall prior to maturity is built by one layer of epidermis, 1–2 layers of endothecium cells, 4–5 middle layers and 2 layers of tapetum, while upon maturity it is only built by one layer of epidermis, one layer of endothecium cells and one middle layer. The tapetal cells are secretory, with two or more nuclei. Ubisch bodies originate from rough endoplasmic reticulum except a few from mitochondria.     

铁皮石斛花粉块结构及发育过程的解剖学特征研究北大核心CSCD

兰科植物的有性生殖特殊,每朵花只有1个花药,且花粉有聚集成块发育的特征。为了揭示铁皮石斛花粉块的发育特征,该研究以野生铁皮石斛不同时期的花药为材料,采用半薄切片和植物组织化学方法对其发育过程进行解剖学观察分析,并对成熟花粉块进行离体培养,观察花粉管的萌发状况。结果表明:(1)铁皮石斛花药壁由1层表皮细胞,2层药室内壁细胞,1层中层细胞和1层绒毡层细胞组成。开花时,绒毡层细胞退化,中层细胞没有退化,药室内壁细胞则形成纤维状细胞壁;药室中的小孢子母细胞没有明显的胼胝质壁结构。(2)小孢子发生属同时型,减数分裂后四分体小孢子不分散,以四合花粉状态发育,并进一步连接形成花粉块。(3)在小孢子发育中,孢粉素覆盖在整个花粉块表面形成花粉外壁,但花粉块内部的花粉没有花粉外壁结构;在花粉块表面的花粉外壁上未见花粉萌发孔。(4)在花粉离体萌发实验中,具有花粉外壁的花粉块表面花粉未见萌发,仅由花粉块内部的花粉萌发出花粉管。