Pectin secretion and distribution in the anther during pollen development in Lilium

Using the monoclonal antibodies JIM 5 and 7, pectin was immunolocalized and quantitatively assayed in three anther compartments of Lilium hybrida during pollen development. Pectin levels in both the anther wall and the loculus increased following meiosis, were maximal during the early microspore stages and declined during the remainder of pollen ontogenesis. In the microspores/pollen grains, pectin was detectable at low levels during the microspore stages but accumulated significantly during pollen maturation. During early microspore vacuolation, esterified pectin epitopes were detected both in the tapetum cytoplasm and vacuoles. In the anther loculus, the same epitopes were located simultaneously in undulations of the plasma membrane and in the locular fluid. At the end of microspore vacuolation, esterified pectin epitopes were present within the lipids of the pollenkitt, and released in the loculus at pollen mitosis. Unesterified pectin epitopes were hardly detectable in the cytoplasm of the young microspore but were as abundant in the primexine matrix as in the loculus. During pollen maturation, both unesterified and esterified pectin labelling accumulated in the cytoplasm of the vegetative cell, concurrently with starch degradation. In the mature pollen grain, unesterified pectin epitopes were located in the proximal intine whereas esterified pectin epitopes were deposited in the distal intine. These data suggest that during early microspore development, the tapetum secretes pectin, which is transferred to the primexine matrix via the locular fluid. Further, pectin is demonstrated to constitute a significant component of the pollen carbohydrate reserves in the mature grain of Lilium. Received: 3 July 2000 / Accepted: 19 October 2000     

Anther wall layers control pollen sugar nutrition inLilium

Summary Anthers ofLilium were for the first time investigated at the ultrastructural level in order to appreciate the possible ways of sugar transport in the microsporangium. Our results have shown that the cells of the outer anther wall layers and the cell of the connective were interconnected by plasmodesmata, thus allowing assimilates to travel through the symplasmic pathway from the vascular bundle to the most internal middle layer (ML 1). ML 1 was devoid of cell communication throughout pollen development. Tapetal cells were also lacking plasmodesmata on their external face towards ML 1, but adjacent tapetal cells developed lateral junctions: the tapetum could represent a syncytium. Sugars destinated to pollen in the loculus have then to cross the ML 1 and the tapetal layers by the apoplasmic pathway; it is suggested that these two envelopes could be involved in the control of sugar transport from the outer anther wall layers to the locular fluid. Before microspore mitosis, the tapetum degenerated but ML 1 remained structurally unchanged. During pollen development, the guard cells of stomata were lacking cell communication, and preserved their starch content, which could be the sign of photosynthesis within the anther wall. In order to check whether these structural disconnections in anther tissues corresponded to physiological barriers, isolated pollen and stamens were cultivated during the anther maturation phase, on a medium containing increasing concentrations of sucrose (0 M, 1/6 M, 1/2 M, 1 M). After 7 days of culture, isolated pollen was engorged with starch grains and was unable to germinate, whereas in cultivated stamens, pollen did not contain any starch grain: sporophytic tissues, however, accumulated abnormal amylaceous reserves. These results strongly suggest that the anther wall layers, in particular ML 1, starve pollen with sugars during its maturation. They are acting as a physiological buffer storing nutriment surplus in starch grains.Abbreviations ML 1 middle layer 1 - ML 2 middle layer 2 - PAS periodic acid Schiff - PATAg periodic acid thiosemicarbazide silver nitrate     

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.     

The effect of heat stress on tomato pollen characteristics is associated with changes in carbohydrate concentration in the developing anthers

Continuous exposure of tomato 'Trust' to high temperatures (day/night temperatures of 32/26 degrees C) markedly reduced the number of pollen grains per flower and decreased viability. The effect of heat stress on pollen viability was associated with alterations in carbohydrate metabolism in various parts of the anther during its development. Under control, favourable temperature conditions (28/22 degrees C), starch accumulated in the pollen grains, where it reached a maximum value 3 d before anthesis; it then diminished towards anthesis. During anther development, the concentration of total soluble sugars gradually increased in the anther walls and in the pollen grains (but not in the locular fluid), reaching a maximum at anthesis. Continuous exposure of the plants to high temperatures (32/26 degrees C) prevented the transient increase in starch concentration and led to decreases in the concentrations of soluble sugars in the anther walls and the pollen grains. In the locular fluid, however, a higher soluble sugar concentration was detected under the high-temperature regime throughout anther development. These results suggest that a major effect of heat stress on pollen development is a decrease in starch concentration 3 d before anthesis, which results in a decreased sugar concentration in the mature pollen grains. These events possibly contribute to the decreased pollen viability in tomato.     

From anther and pollen ripening to pollen presentation

The events and processes occurring between pollen maturation, opening of the anther and presentation of pollen to dispersing agents are described. In the final phases of pollen development, starch is always stored; this occurs before the anther opens. Depending on the species, this starch may be totally or partially transformed into: (a) other types of polysaccharides (fructans and rarely callose); (b) disaccharides (sucrose); (c) monosaccharides (glucose and fructose, all situated in the cytoplasm. While awaiting dispersing agents and during dispersal, polysaccharides, especially fructans, and sucrose may be interconverted to control osmotic pressure and prevent loss and uptake of water. Opening of the anther is preceded by disappearance of the locular fluid and in many cases by partial dehydration of the pollen. Pollen generally has a water content between 5 and 50%. Pollen with a high water content may or may not be able to control water retention during pollen exposure and dispersal. Pollen may be dispersed in monads or grouped in pollen dispersing units by the following mechanisms: (i). tangling of filamentous pollen; (ii). adhesion by viscous substances (pollenkitt, tryphine, elastoviscin) derived from the tapetum; (iii). common walls. When the anther opens, the pollen may be dispersed immediately, remain until dispersed (primary presentation), or be presented to pollinators in another part of the flower (secondary presentation).     

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。     

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。     

关苍术两性花与雌花花药的解剖学研究

苍术属(Atractylodes DC.)是菊科菜蓟族(Cynareae)刺苞亚族(Carlininae O. Hoffm.)的一个东亚特有属,世界上仅有7种,其中我国有5种。该研究以关苍术为材料,采用石蜡切片法比较研究了两性花和雌花的花药及雄配子体发育进程,并进一步探讨了其雌花产生花药退化的时期及原因。结果表明：(1)关苍术小孢子发育与花蕾长度间存在相关性,当花蕾长度在5 mm时进入花粉母细胞时期,花药壁已分化,在7~9 mm时处于四分体时期,大于11 mm时开始进入花粉粒时期。(2)关苍术花药5个,花粉囊4个,减数分裂属同时型,四分体以正四面体为主,属3-细胞型,萌发沟3个。(3)关苍术花粉囊壁发育属双子叶型,从外层的表皮、药室内壁,到内层的中层和绒毡层均由一层细胞构成,关苍术绒毡层为腺质绒毡层。(4)关苍术雌花花药退化发生在花药发育早期至四分体时期,表现为花药发育早期畸形、药壁分化异常、小孢子母细胞发育停滞在前期、绒毡层增生4个原因。该研究结果为苍术属植物的系统发育、物种形成和进化提供胚胎学依据。     

Structural changes during the first divisions of embryos resulting from anther and free microspore culture inBrassica napus

Summary Ultrastructural and cytochemical features of embryo development during anther and free microspore culture inBrassica napus have been followed from the late uninucleate microspore stage through the first embryonic division. On transfer to culture, the microspore cytoplasm possesses a large vacuole, often containing electron opaque aggregates, and a peripheral nucleus. Mitochondria, endoplasmic reticulum and starch-free plastids are distributed throughout the cytoplasm. The conditions of culture induce a number of major changes in the cytoplasmic organisation of the microspore. First, the central vacuole becomes fragmented allowing the nucleus to assume a central position within the cell. Secondly, starch synthesis commences in the plastids which, in turn, are seen to occupy a domain investing the nucleus. Thirdly, the cell develops a thick fibrillar wall, situated immediately adjacent to the intine of the immature pollen wall. Finally, the microspores develop large cytoplasmic aggregates of globular material. The nature of this substance remains unknown, but it remains present until the young embryos have reached the 30 cell stage. The first division of cultured microspores destined to become embryos is generally symmetrical, in contrast to the asymmetric division seen in normal development in vivo. Consideration is given to the differences observed between embryos developing from anthers and free microspores in culture.     

Floral organ growth and carbohydrate content during pollen development in Lilium

In order to understand floral sugar physiology, we correlated the growth of the organs with carbohydrate content in the flower of Lilium cv. “enchantment” during pollen development. In a previous work, we distinguished two phases in pollen ontogenesis: the anther growth phase, from the microspore mother cell until the vacuolated microspore, and the anther maturation phase, from the vacuolated microspore until anthesis. In the present work, we showed that during the growth phase, the anther underwent most of its size and dry weight growth, whereas the growth rate of nonanther organs was reduced. Anther and filament possessed the highest amounts of carbohydrates, which decreased progressively until the vacuolated microspore stage. During the maturation phase, sucrose and starch increased in all floral organs. Anther growth was completed at the Mi stage, whereas the nonanther organs began exponential growth. From these observations, we concluded that hierarchic nutritional correlations exist between the flower organs, in which the anther is the main actor: during the anther growth phase, the anther represents the highest sink strength floral organ, and mainly attracts assimilates through the filament. During the anther maturation phase, anther growth is achieved, its needs decrease, and assimilates are thus available for neighboring organs, which undergo intense growth until anthesis.     

Early signs of disruption of wheat anther development associated with the induction of male sterility by meiotic-stage water deficit

 Water deficit during meiosis in microspore mother cells of wheat (Triticum aestivum L.) induces male sterility, which reduces grain yield. In plants stressed during meiosis and then re-watered, division of microspore mother cells seems to proceed normally, but subsequent pollen development is arrested. Stress-affected anthers generally lack starch. We employed light microscopy in conjunction with histochemistry to compare the developmental anatomy of water-stress-affected and normal anthers. The earliest effects of stress, detectable between meiosis and young microspore stages, were the degeneration of meiocytes, loss of orientation of the reproductive cells, and abnormal vacuolization of tapetal cells. Other effects observed during subsequent developmental stages were deposition of starch in the connective tissue where it is normally not present, hypertrophy of the middle layer or endothecial cells, and deposition of sporopollenin-like substances in the anther loculus. The resulting pollen grains lacked both starch and intine. These results suggest that abnormal degeneration of the tapetum in water-stressed anthers coupled with a loss of orientation of the reproductive cells could be part of early events leading to abortion of microspores. Received: 19 July 1996 / Revision accepted: 6 November 1996     

Manipulation of division symmetry and developmental fate in cultures of potato microspores

The effect of media composition on microspore culture was investigated in one tetraploid and two diploid potatoes. The viability of microspores isolated from 4.5 to 5 mm buds was in the range of 33 to 52%. In media for anther culture, microspores showed no further development and lost viability within 2 days. In M1 medium containing mineral components, sucrose, uridine, cytidine, myo-inositol, glutamine and lactalbumin hydrolysate, 18 to 37% of microspores underwent mitosis within 14 days. Up to 95% of the divisions were symmetric and produced equal nuclei. Some symmetrically divided microspores eventually produced structures with 3 to 10 nuclei. The proportion of the total microspore population producing multinuclear structures reached 9% in diploid clones responsive to anther culture and 1 to 2% in recalcitrant cv. Borka. Symmetric mitoses in M1 medium were induced in the presence of glutamine and lactalbumin hydrolysate. Nucleosides and myo-inositol had no effect on microspore division. In the absence of all organic components except sucrose, most mitoses were asymmetric, formation of multinuclear structures was reduced and most pollen accumulated starch indicative of gametophytic fate. In complete M1 medium, starch accumulation was suppressed. Suppression also occurred in asymmetrically divided microspores, indicating a direct inhibition of pollen development independent of the mode of microspore division. This inhibitory effect of M1 medium might present a stress which triggers the induction of symmetric microspore division and subsequent formation of multinuclear structures. This revised version was published online in June 2006 with corrections to the Cover Date.     

The loculus content and tapetum during pollen development in Lilium

 The ratio of loculus volume to the volume of the entire anther began to increase from the microspore mother cell stage and reached 32.3% at anthesis. The content of the loculus was examined in Lilium during pollen development and two waves could be distinguished. From the premeiotic stage until the vacuolated microspore stage, the loculus consisted of neutral polysaccharides, pectins and proteins. These substances originated from tapetal activity from the premeiotic stage until the young microspore stage. Dictyosomes and rough endoplasmic reticulum seemed to be involved in tapetal secretion, although, in some mitochondria, vesicles progressively developed as early as premeiosis and increased until the young microspore stage, which could reveal their involvement in the secretion process. At this stage, numerous cytoplasmic vesticles containing material similar to the locular material fused with the plasma membrane of the tapetum so that vesicle content was in contact with the loculus. It seems that tapetal and callose wall degradation at the late tetrad stage may also have contributed to the production of material in the loculus. From pollen mitosis to anthesis, the anther loculus contained mainly the pollenkitt which was synthesized in the tapetum between the young microspore stage and the vacuolated microspore stage. At the young microspore stage, proplastids divided and developed into elaioplasts and smooth endoplasmic reticulum (SER) increased dramatically. Pollenkitt had a double origin: some droplets were extruded directly from the plastid stroma through the plastid envelopes; the others were unsaturated lipid globules, which presumably derived from the interaction between SER saccules and plastids. Received: 2 September 1997 / Revision accepted: 12 March 1998     

Importance of pre‐anthesis anther sink strength for maintenance of grain number during reproductive stage water stress in wheat

Reproductive stage water stress leads to spikelet sterility in wheat. Whereas drought stress at anthesis affects mainly grain size, stress at the young microspore stage of pollen development is characterized by abortion of pollen development and reduction in grain number. We identified genetic variability for drought tolerance at the reproductive stage. Drought‐tolerant wheat germplasm is able to maintain carbohydrate accumulation in the reproductive organs throughout the stress treatment. Starch depletion in the ovary of drought‐sensitive wheat is reversible upon re‐watering and cross‐pollination experiments indicate that the ovary is more resilient than the anther. The effect on anthers and pollen fertility is irreversible, suggesting that pollen sterility is the main cause of grain loss during drought conditions in wheat. The difference in storage carbohydrate accumulation in drought‐sensitive and drought‐tolerant wheat is correlated with differences in sugar profiles, cell wall invertase gene expression and expression of fructan biosynthesis genes in anther and ovary (sucrose : sucrose 1‐fructosyl‐transferase, 1‐SST; sucrose : fructan 6‐fructosyl‐transferase, 6‐SFT). Our results indicate that the ability to control and maintain sink strength and carbohydrate supply to anthers may be the key to maintaining pollen fertility and grain number in wheat and this mechanism may also provide protection against other abiotic stresses.     

Maize csmd1 exhibits pre-meiotic somatic and post-meiotic microspore and somatic defects but sustains anther growth

Maize male reproductive development is complex and lengthy, and anther formation and pollen maturation are precisely and spatiotemporally regulated. Here, we document that callose, somatic, and microspore defect 1 (csmd1), a new male-sterile mutant, has both pre-meiotic somatic and post-meiotic gametophyte and somatic defects. Chromosome behavior and cell developmental events were monitored by nuclear staining viewed by bright field microscopy; cell dimensions were charted by Volocity analysis of confocal microscopy images. Aniline blue staining and quantitative assays were performed to record callose deposition, and expression of three callose synthase genes was measured by qRT-PCR. Despite numerous defects and unlike other maize male-sterile mutants that show growth arrest coincident with locular defects, csmd1 anther elongation is nearly normal. Pre-meiotically and during prophase I, there is excess callose surrounding the meiocytes. Post-meiotically csmd1 epidermal cells have impaired elongation but excess longitudinal divisions, and uninucleate microspores cease growth; the microspore nucleoli degrade followed by cytoplasmic vacuolization and haploid cell collapse. The single vascular bundle within csmd1 anthers senesces precociously, coordinate with microspore death. Although csmd1 anther locules contain only epidermal and endothecial cells at maturity, locules are oval rather than collapsed, indicating that these two cell types suffice to maintain an open channel within each locule. Our data indicate that csmd1 encodes a crucial factor important for normal anther development in both somatic and haploid cells, that excess callose deposition does not cause meiotic arrest, and that developing pollen is not required for continued maize anther growth.     

雄性不育无籽刺梨花药发育过程中生理特性的初步研究

为探究无籽刺梨(Rosasterilis)雄性不育原因,采用1%I2-KI染色法观察花粉活性,并对无籽刺梨和正常可育刺梨(R.roburghii)花药不同发育时期的生理生化指标进行了研究。结果表明,无籽刺梨的败育花粉占95.5%,刺梨的正常花粉占99%。刺梨花药的可溶性蛋白质、可溶性糖和脯氨酸含量在各时期的总体变化趋势相似,可溶性淀粉含量呈上升趋势,而无籽刺梨花药的可溶性蛋白质、可溶性糖、淀粉和脯氨酸含量在各时期的变化无规律可循,且花粉成熟期这4种物质的含量均明显低于刺梨,即花粉成熟期缺少各营养物质的积累。在花药发育过程中,无籽刺梨的SOD活性均低于刺梨;MDA含量呈上升趋势,且上升幅度比刺梨大;MDA含量和POD活性均高于刺梨。因此,营养物质的匮乏和酶系统的紊乱可能是导致无籽刺梨雄性不育的原因。     

莴苣花药发育过程中钙的分布特征

减数分裂前,莴苣花药中的钙颗粒很少。减数分裂后,花药绒毡层细胞中的钙颗粒明显增加。同时在花药药室基质中也出现许多细小的钙颗粒。刚从四分体中释放出的小孢子内钙颗粒很少。伴随着花粉外壁物质在小孢子表面的沉积,钙颗粒开始积累在花粉壁部位。随后。小孢子中开始出现钙颗粒。当小孢子开始形成液泡后,钙颗粒向其中聚集,伴随着小液泡融合成大液泡。体积较大的钙颗粒主要集中在液泡中,而细胞质基质中的钙颗粒很少。随着二胞花粉中的大液泡消失,花粉细胞质中的钙颗粒变得很少。在以后的发育中,只有花粉壁中积累较多的钙颗粒。在莴苣花药发育过程中,钙与绒毡层细胞的退化和小孢子液泡形成以及二胞花粉中大液泡的消失有关。而花粉外壁表面积累丰富的钙与以后花粉的萌发有关。     

Histology of embryogenic responses in soybean anther culture

In order to clarify the embryogenic responses in soybean anther culture, anthers of four cultivars were cultured under known conditions to trigger androgenic response. A histological study was performed with anthers in vivo and with approximately 100 explants sampled after 9, 12, 15, 18, 21, 30 and 45 days of culture. In vitro culture triggered the frequent accumulation of phenolic compounds on the locular and anther surfaces, and also caused the destruction of cells and tissues in complex structure such as the tapetum, microspores and pollen grains. Somatic embryogenesis of unicellular origin was observed from the epidermis and the middle layer, and of multicellular origin from connective calluses. No androgenic response could be observed in the anthers of these four soybean genotypes, in the medium and conditions indicated. We point out to the need of changing the approach to the study of androgenesis in soybean, either by using culture conditions unfavourable to the proliferation of diploid tissues, or by culturing isolated microspores.     

Cytochemical investigation of genic male-sterility in Chinese cabbage

A genic male sterile Chinese cabbage, Brassica campestris L. ssp. chinensis Makino, was examined using cytological and cytochemical methods to characterize the process of pollen abortion in this plant. Thick sections of both fertile and sterile anthers at different developmental stages were stained using Toluidine Blue O, Periodic Acid-Schiff’s (PAS) reaction and Sudan Black B to detect cytochemical changes that may occur in the distribution of insoluble polysaccharide and lipid storage bodies. Pollen abortion in sterile anthers occurs at an early stage of microspore development. During early microspore development, reductions in the number of starch grains in the connective tissue of fertile anthers coincide with the accumulation of starch grains in cells of the anther wall. In the late microspore stage, a large vacuole forms in the microspore, and tapetal cells synthesize and accumulate lipid droplets. The cellular organization of tapetal cells in sterile anthers appears similar to that in fertile anthers, except for the absence of lipid droplets in cells of sterile anthers and diffusely labeled tapetal polysaccharides, suggesting defects in nutrient storage. Supported by National Natural Science Foundation of CHINA (30170060)