水稻马协不育与可育花药ATPase定位（简报）

Pb3 (po4)2-precipitation was used to study the ATPase activities both in fertile and sterile anthers of rice (Oryza sativa L. cv. Marxie). At big-vacuole pollen stage, tapetum of the fertile anthers showed high ATPase activity in their nuclei. In fertile pollen, ATPase was localized on the outside surface of the exine and in the nucleus both at big-vacuole and at bi-nucleate pollen stage. At late bi-nucleate pollen stage, a large amount of Pb3 (PO4)2 precipitated in endintine of the fertile pollen. In sterile anthers, tapetum was fully degenerated at big-vacuole pollen stage. In sterile pollen, ATPase was localized both on the plasmamembrane and in intine. These phenomena lasted to the bi-nucleate pollen stage. In addition, most of the sterile pollen did not show well-developed endintine. Based on the above results, we suggested that abortive tapetum could not provide enough nutrition for pollen development, and the high ATPase activity both on plasma membrane and in intine would likely result in ATP shortage in sterile anthers.     

水稻马协不育与可育花药ATPase定位(简报)

马协不育系系朱英国等用农家品种“马尾粘”的不育株与“协青早选”测交和回交选育成功的。超微结构研究表明马协不育花药单核边位期绒毡层提前解体,液泡膜破裂;不育花粉外壁基粒棒少,且分布不均匀;线粒体有大的电子透明区,二核期不育花粉中央大液泡崩溃。不育花药绒毡层提前解体可能影响花粉外壁合成及花粉营养供应,大量研究表明绒毡层发育异常与花粉败育密切相关,而液泡膜的破坏会导致水解酶类的泄     

The manifold characters of orbicules: structural diversity,systematic significance,and vectors for allergens

In the anthers of flowering plants, gymnosperms, and seed ferns, tiny (±1?μm) granules might occur on the radial and innermost tangential wall of secretory tapetum cells. These sporopollenin granules develop simultaneously with the pollen exine and are called orbicules or Ubisch bodies. The present paper focuses on two quite different topics associated with orbicules.

The morphological and ultrastructural diversity of orbicules in the order Gentianales is summarized, and it is demonstrated that orbicules are a plesiomorphic feature in the order. Furthermore, orbicule characters seemed to be correlated with evolutionary trends in pollen dispersal unit and tapetum type features.

In the second part, we report on our investigation of Corylus avellana L. (Hazel) pollen, using immunogold electron microscopy to gain an insight into the possible role that orbicules may play as a vector of pollen allergens. During the pollen season orbicules are dispersed into the atmosphere along with Hazel pollen grains. The localisation of homologues of the new birch pollen allergen Bet v 7 was studied at the subcellular level in Hazel anthers. The results of this study indicate that orbicules and pollen of Hazel might act as very effective vectors for homologues of Bet v 7 and that debris of Hazel anthers represent vectors of allergens after the pollen season.     

云南紫稻细胞质雄性不育系花药发育过程中Ca2+的分布特点

运用焦锑酸钾沉淀法研究了云南紫稻细胞质雄性不育系和保持系花药在发育过程中Ca^2 的分布特点。结果表明,保持系的花粉母细胞和小孢子的胞质内部基本无Ca^2 的沉淀,后期花粉外壁出现Ca^2 的沉淀;保持系早期的绒毡层细胞形态正常,胞内有少量Ca^2 沉淀,后期绒毡层细胞开始凋亡,胞质凝集,胞内出现大量Ca^2 的颗粒。不育系花粉母细胞在减数分裂时期败育,胞质液泡化,内部出现大量Ca^2 的沉淀;不育系绒毡层细胞形态正常,胞内无Ca^2 的沉淀。绒毡层与花粉母细胞、小孢子之间出现大量Ca^2 颗粒。探讨了不育系花药花粉母细胞中以及与绒毡层细胞之间Ca^2 的异常积累与雄性不育的关系。     

Localization of the Ca(2+)-binding protein, Bra r 1, in anthers and pollen tubes

Calcium plays an essential role during pollen development and pollen tube growth, and several Ca(2+)-binding proteins are expressed in anthers. We have previously reported that Brassica pollen allergens encoded by Bra r 1 and Bra r 2 show sequence similarities to Ca(2+)-binding proteins [Toriyama et al. (1995) Plant Mol. Biol. 29: 1157]. Herein, we report that both genes are expressed in the diploid tapetum and haploid microspores, as detected by in situ RNA hybridization. Immunoblot analysis revealed that Bra r 1 and Bra r 2 were accumulated in anthers during pollen development. When pollen grains were suspended in an aqueous solution, both proteins were mainly detected in the pollen extracellular fraction, indicating that Bra r 1 and Bra r 2 are released from the pollen upon hydration. Localization of Bra r 1 was further investigated in sections of anthers and pollen tubes. Bra r 1 was detected in the tapetum, microspores and pollen grains. In longitudinal sections of cross-pollinated pistils. Bra r 1 was detected throughout pollen tubes elongating in transmitting-tissue. These findings suggest that Bra r 1 may be involved in pollen-pistil interaction and pollen tube growth.     

水稻雄性半不育突变体的细胞学观察

TP-2是由水稻品种台北309自然突变的雄性半不育突变体。解剖小花后观察发现,突变体花药细长,干瘪,白色透明状,雌蕊正常。花粉活力检测结果表明:突变体水稻平均花粉粒活力率为57.599%,1个花粉囊里的花粉粒平均有436粒;正常材料台北309水稻平均花粉活力率为94.177%,1个花粉囊里的花粉粒有798粒。组织切片观察发现:突变体水稻从小孢子母细胞发育到减数分裂结束,和正常株相比较在形态上无显著差异,小孢子形成初期出现异常,绒毡层快速消融,小孢子在其发育过程中因得不到营养不能正常发育,产生的小孢子干瘪,呈不规则状,同时部分小孢子产生破裂消融现象,绒毡层不能正常降解可能是导致TP-2水稻小孢子异常发育的主要原因。通过以上观察,对进一步揭示TP-2突变体的不育机制提供了基本资料,对该材料的组配奠定了基础。     

Disposition of Pollen in situ and its Relevance to Anther/Pollen Culture

Disposition of pollen in immature anthers of Hordeum vulgareis illustrated by scanning and transmission electron microscopy.Freeze-fracture confirms that the pollen is confined to a uniseriatecolumn aligned against the tapetum. There is no free pollenin the lumen of the anther loculi. In contrast, in Nicotianatabacum and Paeonia lactlflora the pollen is disposed at randomand occupies the whole of each loculus. Freezing preserves thefluid content of the loculi, appearing in fracture profilesas an amorphous matrix in which the pollen is embedded. Thematrix, which generally obscures the tapetum, is present throughoutthe microspore phase but diminishes as the spores enlarge. Itis still present in N. tabacum and H. vulgare at the first pollendivision, fragmentary at this stage in P. lactiflora, but isno longer discernible in any of the species at the onset ofpollen-grain maturation. Pretreatment of excised Hordeum spikes at 4 ?C during the microsporephase, a prerequisite for anther/pollen culture, disrupts thenormal developmental sequence but does not alter the uniseriatedisposition. Before the spores start to divide, however, thetapetum degenerates and the fluid phase is dispersed. The observations are discussed in relation to isolated pollenculture, float culture of anthers and the switch in programmefrom gametophytic to sporophytic development. Key words: Pollen, Tapetum, Freeze-fracture     

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     

Anther structure and pollen development in Melicoccus lepidopetalus (Sapindaceae): An evolutionary approach to dioecy in the family

Anther and pollen development in staminate and pistillate flowers of dioecious Melicoccus lepidopetalus (Sapindaceae) were examined by light and electron microscopy. Young anthers are similar in both types of flowers; they consist of epidermis, endothecium, two to four middle layers and a secretory tapetum. The microspore tetrads are tetrahedral. The mature anther in staminate flowers presents compressed epidermal cells and endothecium cells with fibrillar thickenings. A single locule is formed in the theca by dissolution of the septum and pollen grains are shed at two-celled stage. The mature anthers of pistillate flowers differ anatomically from those of staminate flowers. The epidermis is not compressed, the endothecium does not develop fibrillar thickenings, middle layers and tapetum are generally persisting, and the stomium is nonfunctional. Microspore degeneration begins after meiosis of microspore mother cells. At anthesis, uninucleate microspores and pollen grains with vegetative and generative nuclei with no cytokinesis are observed. Some pollen walls display an abnormal exine deposition, whereas others show a well formed exine, although both are devoid of intine. These results suggest that in the evolution towards unisexuality, the developmental differences of anther wall tissues and pollen grains between pistillate and staminate flowers might become more pronounced in a derived condition, such as dioecy.     

The tapetum: Its form,function, and possible phylogeny inEmbryophyta

It appears that the tapetum is universally present in land plants, even though it is sometimes difficult to recognize, because it serves mostly as a tissue for meiocyte/spore nutrition. In addition to this main function, the tapetum has other functions, namely the production of the locular fluid, the production and release of callase, the conveying of P.A.S. positive material towards the loculus, the formation of exine precursors, viscin threads and orbicules (= Ubisch bodies), the production of sporophytic proteins and enzymes, and of pollenkitt/tryphine. Not all these functions are present in all land plants:Embryophyta. Two main tapetal types are usually distinguished in theSpermatophyta: the secretory or parietal type and the amoeboid or periplasmodial type; in lower groups, however, other types may be recognized, with greater or lesser differences. A hypothetical phylogenesis of the tapetum is proposed on the basis of its morphological appearance and of the nutritional relations with meiocytes/spores. The evolutionary trends of the tapeta tend towards a more and more intimate and increasingly greater contact with the spores/pollen grains. Three evolutionary trends can be recognized: 1) an intrusion of the tapetal cells between the spores, 2) a loss of tapetal cell walls, and 3) increasing nutrition through direct contact in narrow anthers.     

"Real" and Feed Pollen of Lagerstroemia indica: Ecophysiological Differences

Abstract: Lagerstroemia indica is heterantheric, its flowers bearing two kinds of stamens: six peripheral stamens with long, curved filaments and large anthers producing blue-green pollen, capable of emitting pollen tubes and fertilizing ovules; or a central tuft of 35 - 40 smaller anthers producing yellow feed pollen that does not germinate and is collected by insects, mainly bees. The two types of pollen differ in volume, number of pores, pore intine protrusion, wall structure, pollenkitt quality, hydration state, viability at anthesis, longevity and mono- and disaccharide composition. Although total sugar concentrations (glucose, fructose and sucrose) are the same in both types, relative concentrations are different, "real" pollen being sucrose-rich (S / [G + F] = 1.2) and feed pollen glucose-fructose-rich (S / [G + F] = 0.3). A lower degree of dehydration, pore intine protrusion and higher monosaccharide content could make feed pollen more digestible for pollinators. On the other hand, the cytological features of "real" pollen (high dehydration, higher sucrose content) points to longer viability and reproductive function.     

Anther Culture of Lolium temulentum, Festuca pratensis and Lolium x Festuca Hybrids. II. Anther and Pollen Development In Vivo and In Vitro

The various pathways of pollen development were investigatedin cultured anthers of Lolium temulentum, Festuca pratensisand the L. multiflorum x F. pratensis hybrid ‘Elmet’.In all three, development from the vegetative cell was the predominantpathway of pollen callus development. However, there were characteristicdifferences in the behaviour of the generative cell. In L. temulentumit remained attached to the pollen wall and degenerated, whereasin F. pratensis it divided. In ‘Elmet’ it detachedfrom the pollen wall and remained undivided. Both polarizedand unpolarized partitioned calluses were observed. Developmentof the fusion product of the vegetative and generative nucleiwere also observed in anthers of L. temulentum. Anomalous grainswere not found to be major source of pollen calluses. Sections of anthers of L. temulentum were used to investigatethe origin of S pollen grains, the small pale-staining grainswhich denote pollen dimorphism. Such grains form out of contactwith the tapetum and are therefore determined before or duringmeiosis (i.e. before harvest of anthers for culture). Sectionswere also used to demonstrate the influence of the durationof pretreatment on the development of the middle layer of theanther wall. Festuca pratensis, Lolium temulentum, Lolium x Festuca, anther culture, haploid, microspore, pollen     

Male-fertility genes expressed in male flower buds of Silene latifolia include homologs of anther-specific genes

When the female plant of Silene latifolia is infected with the smut fungus Microbotryum violaceum, its rudimentary stamens develop into anthers which contain fungus teliospores instead of pollen. To identify genes required for maturation of anthers in S. latifolia, we performed a cDNA subtraction approach with healthy male buds and female buds infected with M. violaceum. We isolated five cDNA clones, which were preferentially expressed in healthy male buds during stages associated with a burst in tapetal activity. These five cDNAs are predicted to encode a mandelonitrile lyase protein (SlMDL1), a strictosidine synthase protein (SlSs), a glycosyl hydrolase 17 protein (SlGh17), a proline-rich protein APG precursor (SlAPG), and a chalcone-synthase-like protein (SlChs). All five genes showed expression in both healthy and fungus-infected male buds, but not expressed in either healthy or infected female buds. The first three genes were highly expressed in both tapetum and pollen grains while the last two genes were expressed only inside the tapetum of male flower buds. Phylogenetic analysis results showed that SlChs and SlGh17 belong to anther-specific subgroups of chalcone-synthase-like genes and glycosyl hydrolase 17 family genes, respectively. Our results suggest that the isolated five genes are related to the fertility of the anther leading to the development of fertile pollen. The smut fungus was not able to induce the expression of the five genes in the infected female buds. This raises the possibility that these genes are under the control of master gene(s) on the Y chromosome.     

青葙花药发育的结构和组织化学观察

对苋科植物青葙Celosia argentea花药发育的结构和组织化学（多糖和脂滴）特征进行观察。青葙小孢子发生为同时型,四分体为四面体型。药壁为典型四层,绒毡层属于同型绒毡层。成熟花粉为二胞型。早期花药中的淀粉粒和脂滴均较少,绒毡层细胞至小孢子晚期退化为体积较大的脂块。二胞花粉时期的中层细胞退化为脂滴。早期二胞花粉中先出现多糖颗粒,晚期的成熟花粉中积累大量淀粉粒和较少的脂滴为营养储存物。     

Male-sterility of thermosensitive genic male-sterile rice is associated with premature programmed cell death of the tapetum

The tapetum plays a crucial role in pollen development. This secretory tissue produces numerous nutritive proteins necessary for pollen maturation. The tapetum, whose cells undergo programmed cell death (PCD), is completely diminished by the time the pollen is fully mature. Our previous studies on a thermosensitive genic male-sterile (TGMS) rice (Oryza sativa L.) suggested that male-sterility was due to failure in pollen development. In this paper we describe how further analysis of the TGMS rice revealed that male-sterility is associated with premature PCD of the tapetum. Cytological observations of TGMS rice anthers at various developmental stages indicated that PCD initiates at an early stage of pollen development and continues until the tapetal cells are completely degraded, resulting in pollen collapse. Transmission electron microscopy showed the morphologically distinct hallmarks of apoptosis, including cytoplasmic shrinkage, membrane blebbing, and vacuolation. Identification of DNA fragmentation using the TUNEL assay supports the hypothesis that premature PCD is associated with male-sterility in the rice. The tissue-specific feature of the thermosensitive genic male-sterile phenotype is discussed with regard to PCD during anther development.     

Barley anther culture: The effect of position on pollen development in vivo and in vitro

Locule structure and organization were studied in vivo and in vitro to determine whether the disposition of pollen within barley anthers affected the response of pollen in culture. Following release from the meiotic tetrads, juvenile barley microspores become peripherally organized around the locule, with the single pollen pore oriented towards the tapetum. Scanning electron micrographs of transverse sections from freeze fractured anthers showed that some microspores failed to locate the tapetal surface and occupied a position in the centre of the locule where they continued to develop as small, abnormal pollen grains (dimorphic pollen). Previous evidence has suggested that in some species dimorphic pollen could be the source of embryonic pollen in vitro. Cultured anthers frequently dehisced to reveal a mass of dividing pollen grains, however those anthers that remained intact retained the original locule structure and could be freeze fractured permitting examination of the developing pollen in situ. This showed that pollen embryogenesis was not restricted to dimorphic pollen, and that any grain could become Embryogenic irrespective of position.     

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.     

Tapetosomes in Brassica tapetum accumulate endoplasmic reticulum-derived flavonoids and alkanes for delivery to the pollen surface

Tapetosomes are abundant organelles in tapetum cells during the active stage of pollen maturation in Brassicaceae species. They possess endoplasmic reticulum (ER)-derived vesicles and oleosin-coated lipid droplets, but their overall composition and function have not been established. In situ localization analyses of developing Brassica napus anthers revealed flavonoids present exclusively in tapetum cells, first in an ER network along with flavonoid-3'-hydroxylase and then in ER-derived tapetosomes. Flavonoids were absent in the cytosol, elaioplasts, vacuoles, and nuclei. Subcellular fractionation of developing anthers localized both flavonoids and alkanes in tapetosomes. Subtapetosome fractionation localized flavonoids in ER-derived vesicles, and alkanes and oleosins in lipid droplets. After tapetum cell death, flavonoids, alkanes, and oleosins were located on mature pollen. In the Arabidopsis thaliana mutants tt12 and tt19 devoid of a flavonoid transporter, flavonoids were present in the cytosol in reduced amounts but absent in tapetosomes and were subsequently located on mature pollen. tt4, tt12, and tt19 pollen was more susceptible than wild-type pollen to UV-B irradiation on subsequent germination. Thus, tapetosomes accumulate ER-derived flavonoids, alkanes, and oleosins for discharge to the pollen surface upon cell death. This tapetosome-originated pollen coat protects the haploidic pollen from UV light damage and water loss and aids water uptake.