Microsporogenesis,microgametogenesis, and pollen morphology of <Emphasis Type="Italic">Ambrosia artemisiifolia</Emphasis> L. in China

Ambrosia artemisiifolia L. from Ambrosia of the Heliantheae of the Asteraceae family is a recognized harmful weed worldwide and one of the major invasive foreign plants in China. In this study, we investigated its reproductive features, focusing on its microsporogenesis, microgametogenesis, and pollen morphology. The results show that (1) Ambrosia artemisiifolia L. is a dicotyledonous plant and has spherical, tricolpate pollen grains with spiny outer wall; (2) its anther wall comprises four layers, namely epidermis, endothecium, middle layers, and amoeboid tapetum; (3) cytokinesis of microspore mother cells is successive; (4) most of tetrads are tetrahedral; and (5) mature pollen grains are three-celled. In conclusion, although Ambrosia artemisiifolia L. is a dicotyledonous plant with tricolpate pollen, its microsporogenesis is successive, which is different from typical dicots.     

Pre-zygotic embryological characters ofPlatycrater arguta, a rare and endangered species endemic to East Asia

Platycrater arguta Sieb. et Zucc. is a rare and endangered species endemic to East Asia. It produces two floral morphs viz. bisexual and male flowers. For bisexual flowers, simultaneous cytokinesis in the microsporocyte meiosis leads to a tetrahedral tetrad. The mature pollen grain is shed at 2-cell stage. The young anther wall is composed of epidermis, endothecium that develops fibrous thickenings at maturity, 1–2 middle layers and tapetum. The tapetum with uninucleate to binucleate cells, disintegrates in situ (glandular tapetum), yet in a small percentage of the anthers (about 37.6%), the tapetum does not disintegrate, causing complete male sterility. The ovules are anatropous, unitegmic, tenuinucellar and the formation of the embryo sac follows the monosporic, Polygonum type. Antipodal cells are lacking in the mature embryo sacs. Before fertilization, two polar nuclei fuse into a secondary nucleus. The formation of microsporangial wall, microsporogenesis and male gametogenesis in male flowers are analogous to those in the bisexual. Prezygotic embryological characters ofP. arguta were reported for the first time, revealing that its endangerment is correlated with the abortion of pollen of a part but not to the female development that is normal.     

A transient accumulation of poly(A)-containing RNA in the tapetum of Hyoscyamus niger during microsporogenesis

The distribution of poly(A)-containing RNA in the tapetal cells of Hyoscyamus niger during microsporogenesis was followed by in situ hybridization with [³H]poly(U) as a probe. Although no poly(A)-containing RNA accumulated in the premeiotic tapetum, [³H]poly(U) binding sites were detected in the tapetum as meiosis was completed in the microsporocytes. Accumulation of poly(A)-containing RNA in the tapetal cells reached a peak before the first haploid mitosis in the pollen grains. With the onset of tapetal senescence at the late uninucleate stage of the pollen grain, [³H]poly(U) binding sites gradually decreased and they completely disappeared in the tapetum at the binucleate pollen stage. The significance of the results is discussed, particularly with regard to the possible role of tapetum in the synthesis of informational macromolecules during microsporogenesis.     

Embryological Studies on Narcissus tazetta var. chinensis

Chinese narcissus (Narcissus tazetta var. chinensis Roem) blooms but has no seeds. Embryological studies on the species were conducted to discover the causes of its sterility. Its anther wall is composed of four layers of cells, and its tapetum is of the secretory type. The cytokinesis of microspore mother cells is of the successive type, and the tetrad is tetrahedral. During meiosis of microspore mother cells, some chromosomes lagged, and several micronuclei were found in tetrads. Only 27.7% of the pollen grains contained full cytoplasm, and 1.3% of them germinated in culture medium. No pollen grain, however, could germinate on the stigma. The ovary is trilocular with axile placenta, and the ovules are bitegmic, tenuinucellate, and anatropous. Its embryo sac is of the polygonum type. Most embryo sacs degenerated, and only about 4.5% of the ovules contained a normal embryo sac with an egg cell, two synergids, three antipodal, and a central cell containing two polar nuclei. One reason for the sterility of Chinese narcissus is the abnormality of microsporogenesis and megasporogenesis, in which only a few functional pollen grains and embryo sacs are produced. The other reason is that the pollen grains cannot germinate on the stigma. This paper was translated from Journal of Xiamen University (Natural Science), 2005, 44(1) (in Chinese)     

Microsporogenesis of the feathers (fertile branches derived from annual buds) in Vitis vinifera,cv Picolit giallo

Abstract

Using light and electron microscopy, we have studied the microsporogenesis and tapetal development of the feathers in two different low producing clones of Picolit giallo (sp. Vitis vinifera). In these clones while the productivity of the main branches (fertile branches originated from buds, formed in the previous year, that remained silent during the winter) is very low, that of the feathers (fertile branches derived from annual buds) is always normal.

The microsporogenesis and tapetal development proceed normally in almost all the examined anthers; it is remarkable that at the tetrad stage the tapetal cells appear well structured without any degeneration symptom, unlike what observed for the main branches. Moreover in most of the mature anthers the pollen grains are numerous, pleinty of organelles and show sometimes thickenings in the callose layer under their wall. The tapetal cells of these anthers have disappeared. Only in few anthers we observed the presence of collapsed pollen grains and tapetal cells with anomalous development, that are still present when the pollen grains are mature. This rare situation for the feathers is on the contrary frequent for the main branches.     

New acritarch species from Holocene sediments in central West Greenland

Anther development, microsporogenesis, and microgametogenesis were studied using both light and TEM microscopy in the six accessible subdioecious/cryptically dioecious species of Consolea (Cactaceae). Anther wall development, microsporogenesis, and microgametogenesis are uniform in staminate flowers of all six species, and are typical for Cactaceae. Breakdown of microsporogenesis in male‐sterile anthers occurs early, at the onset of meiosis, and results in anthers bearing no pollen grains. The abortive process follows a common pattern in all investigated species. The tapetum is the first layer to deviate from normal male‐fertile anther development. Tapetal cells in male‐sterile anthers elongate at an early stage and have abundant rER with atypical configurations. Ultimately, the tapetum becomes hypertrophied and non‐functional. Male‐sterility in pistillate flowers appears to be directly related to these anomalies. In addition, other anther layers and tissues are affected, and normal patterns of programmed cell death (PCD) are disrupted. The relationship between these patterns and the pattern of PCD in normal male‐fertile anthers is discussed. We hypothesize a single origin for the cryptically dioecious/subdioecious breeding system of Consolea based on the uniformity of the anther's abortive processes in pistillate flowers.     

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.     

Pollen-connecting threads inHeliconia (Heliconiaceae)

InHeliconia thread-like structures connecting the pollen grains are described. These threads are decay products of the walls separating the pollen chambers, and products of the rupture of the mature anthers in the stomium region. The pliable cell threads mix with the pollen and entangle individual grains to form aggregates. This ensures that the pollen becomes embedded in the feathers or attached to the smooth, unsculptured beak of pollinating hummingbirds (Trochilidae).—Structure and origin of theHeliconia threads differ from those of the related genusStrelitzia (Strelitziaceae).     

Embryology ofKyllinga monocephala (Cyperaceae) and its systematic position

Aspects of the life history ofKyllinga monocephala are described. Anther wall development corresponds to the Monocot type. The endothecium shows spiral thickenings. The tapetum is glandular and has uninucleate cells. Ubisch granules are present. Mature pollen grains (pseudomonads) are 3-celled at maturity. Ovules are bitegmic, crassinucellate and develop a funicular obturator. The embryo development conforms to theJuncus-variation of the Onagrad type. Endosperm, seed coat and pericarp are described.     

Embryology ofEriocaulon setaceum (Eriocaulaceae)

Eriocaulon setaceum can be characterized by: young microsporangium wall with epidermis, endothecium (with fibrous thickenings), and glandular tapetum (uninucleate cells); pollen grains 3-celled, spiraperturate; embryo sac development according to the Polygonum type and with antipodal cyst; endosperm nuclear; embryo small, with incipient differentiation into cotyledonary and epicotylary loci; seed coat mainly from the inner layers of the integuments; pericarp 2-layered and membranous. Embryologically, theEriocaulaceae are nearer to theXyridaceae than to otherFarinosae. Their elevation to the rank of an order,Eriocaulales, therefore appears justified.     

鹅毛竹大小孢子及雌雄配子体发育

利用扫描电镜、透射电镜、石蜡切片,对鹅毛竹的花芽分化、大、小孢子及雌、雄配子体的发育进行了详细观察.结果发现:鹅毛竹花药具4个药室,花药壁由表皮、药室内壁、中层、绒毡层4层结构组成,花药壁发育为单子叶型,绒毡层为腺质型,小孢子母细胞减数分裂中的胞质分裂为连续型,产生左右对称型小孢子.鹅毛竹成熟花粉大多2细胞型,都具1个萌发孔.鹅毛竹子房为单子房,子房1室,侧膜胎座,一个倒生胚珠,双珠被,薄珠心.大孢子母细胞由一个雌性孢原细胞直接发育而成,大孢子四分体呈线型,合点端一个大孢子分化为功能大孢子,由功能大孢子经过3次有丝分裂形成8核胚囊,发育类型为蓼型,位于核点端的3个细胞核进行多次分裂形成多个反足细胞.至此,成熟胚囊形成.并就鹅毛竹不结实的原因进行了探讨.     

开口箭大小孢子发生及雌雄配子体发育

利用石蜡切片技术,对百合科植物开口箭(Tupistra chinensis Baker)大小孢子发生及雌雄配子体发育进程进行胚胎学观察分析,以明确开口箭胚胎发育的特征,为百合科植物的研究提供生殖生物学依据。结果表明:(1)开口箭花药具有4个药室,花药壁的发育方式为基本型,由表皮、药室内壁、中层及绒毡层组成;绒毡层发育类型为分泌型,到四分体花药阶段绒毡层细胞开始解体退化,花药成熟时完全消失。(2)花粉母细胞减数分裂为连续型,依次形成二分体、四分体,四分体为左右对称形;成熟花粉为2-细胞花粉,具单萌发沟。(3)子房3室,倒生型胚珠6枚,双珠被,薄珠心;在花部的分化早期,由珠心顶端表皮下方分化出雌性孢原细胞,孢原细胞经过一次平周分裂形成周缘细胞和造孢细胞,造孢细胞发育为大孢子母细胞;大孢子母细胞第一次减数分裂后形成二分体,珠孔端的二分体孢子退化,合点端的二分体孢子继续第二次分裂,形成两个子细胞依次发育为二核胚囊、四核胚囊和八核胚囊;开口箭的胚囊发育类型为葱型。     

琼榄小孢子发生、雄配子体发育及花粉粒形态

利用光学显微技术和电镜扫描技术研究了琼榄的小孢子发生、雄配子体发育和花粉粒形态以增加广义心翼果科的胚胎学和孢粉学资料。主要结果如下：（1）花药四孢囊;（2）花药壁四层,从外到内分别为表皮、具纤维性加厚的药室内壁、退化早的中层和细胞具2~4核的分泌型绒毡层;（3）小孢子母细胞胞质分裂同时型,形成四面体型排列的小孢子四分体;（4）成熟花粉粒为二细胞型;（5）花粉粒具3个隐形萌发孔,外壁为网状纹饰。琼榄与心翼果属的小孢子发生和雄配子体发育特征非常相似,稍有不同。琼榄的花粉粒形态特征与同属其它种基本相同。     

POLLEN PORE DEVELOPMENT AND ITS SPATIAL ORIENTATION DURING MICROSPOROGENESIS IN THE GRASS SORGHUM BICOLOR

The spatial relationships observed during microsporogenesis and pollen development in Sorghum bicolor indicate that a strong polarization exists in the anther locule and within individual microspores and pollen grains. During all developmental stages, each sporogenous cell and its derivatives lie continuously adjacent to the tapetum. The microspores and pollen grains form depressions in the tapetal orbicular wall. When the single pore of each microspore is initiated, as a gap in the primexine, it too lies adjacent to the tapetum and remains tightly appressed there until pollen maturity. A sequence of polar phenomena in microspores and pollen grains centers on an axis through the pore and perpendicular to the tapetal surface. These events include migrations of the microspore and vegetative nuclei, initial placement of the generative cell opposite the pore and its later migration, and a polar engorgement process whereby the pore end of the pollen grain (adjacent to the tapetum) fills with starch grains first. The tapetal cytoplasm completely degenerates at precisely the time of pollen engorgement, and its degradation products are believed to be available for pollen uptake at this time. The continuous association of the sporogenous cells or their cellular derivatives and their pores with the tapetum is thought to play an indispensible role in pollen development in sorghum and probably in all other grasses as well. The consistent position of the pore adjacent to the tapetum should be considered another common feature of microsporogenesis in the Gramineae. The characteristic exine pattern forms over the operculum and annulus of the pore, but the lamellae, which underlie the annulus, form a highly modified multilayered nexine. Membrane-like cores are observed in these lamellae and are believed to be involved in the initiation of sporopollenin deposition, but they are obliterated by pollen maturity. Neither the cores nor the lamellae are found in other parts of the pore or in the nonapertured wall.     

车桑子小孢子发生与雄配子体发育

为了解干热河谷区车桑子(Dodonaea viscosa)胚胎学特征及其结籽率低的原因,采用常规石蜡切片法和电镜扫描技术对车桑子小孢子发生、雄配子体发育和花粉的形态特征进行了观察。结果表明,车桑子花药具有4个花粉囊。完整的花药壁从外到内依次为表皮、药室内壁、2～3层中层细胞和绒毡层;绒毡层类型是腺质绒毡层。花药成熟期,中层、绒毡层均退化消失。小孢子母细胞进行同时型胞质分裂;四分体为四面体型结构。成熟的花粉为二细胞型。花粉近球形,外壁密布颗粒状纹饰,具有3条不构成合沟的萌发沟。雄性生殖发育过程出现的异常现象可能是干热河谷地区车桑子结籽率低的原因之一。     

Floral micromorphology and microsporogenesis of the gynodioecious herb Glechoma longituba (Lamiaceae)

Gynodioecy, the phenomenon of having both hermaphrodite and female (i.e. male‐sterile) individuals within the same population, is an important intermediate step in the evolution of separate sexes in flowering plants. In this study, we investigated the floral micromorphology and microsporogenesis of the gynodioecious herb Glechoma longituba from four natural populations in Korea. The floral micromorphological characters of the different sex morphs were examined and compared using scanning electron microscopy (SEM), and the ultrastructure of microspores during microsporogenesis was studied. We also examined the development of anthers and pollen grains in the three sexual morphs (i.e. hermaphrodites, females, and gynomonoecious, i.e. individuals with a mixture of female and hermaphroditic flowers) by embryological investigation. The major difference in anther development between the three phenotypes was the early disintegration of the tapetal cells in the anthers of female flowers. While mature fertile pollen grains were found in both hermaphrodite and gynomonoecious phenotypes, females did not produce any pollen grains. In addition, both fertile and sterile pollen grains in gynomonoecious phenotypes were frequently observed. The results of the present study indicate that floral micromorphological characters were not distinct between sexual morphs of G. longituba, except for the structure of the inner cell surfaces of the anther. The observed tapetum abnormalities and degeneration of pollen grains in both gynomonoecious phenotypes and females may be the consequence of inbreeding depression in hermaphrodites.     

Ontogenesis of monad pollen inPterostylis plumosa (Orchidaceae,Neottioideae)

Pterostylis plumosa (Neottioideae) is an orchid with monosulcate monad pollen. Tetrads may be isobilateral, decussate, tetrahedral, rhomboid or T-shaped, but all pollen grains have a similar shape. Those belonging to the same tetrads are contiguous from microspore release to opening of the anther, with the furrow oriented inwards. Sporophytic proteins are present outside the furrow. The tapetum is of the parietal type without orbicles. The increase in pollen grain size between meiosis and maturity is only three-fold. The generative cell is spherical when the pollen is mature. These features are discussed in relation to the primitive nature of the species.     

Ultrastructural study of pollen and anther development in Luehea divaricata (Malvaceae,Grewioideae) and its systematic implications: Role of tapetal transfer cells,orbicules and male germ unit

Developmental processes of microsporogenesis and microgametogenesis in Luehea divaricata (Malvaceae, Grewioideae) were analyzed with transmission electron microscopy. The species studied has perfect flowers. The young anthers are bithecal and tetrasporangiate; microspore mother cells undergo simultaneous meiosis, forming tetrads with a tetrahedral arrangement. The development of the anther wall conforms to the basic type and the tapetum is secretory. The results highlight the presence of multinucleate tapetal cells, which acquire ultrastructural features characteristic of transfer cells at the young pollen grain stage, and which are associated with the presence of orbicules. Tapetal transfer cells have not been previously investigated in detail for other species of angiosperms; their function during pollen development is discussed. The present work is the first contribution to the knowledge of ultrastructural pollen development in the genus Luehea, as well as in the subfamily Grewioideae.     

The common occurrence of incompletely developed pollen of Eupatorium (Compositae: Eupatorieae)

Mature anthers of Eupatorium serotinum Michx., E. coelestinum L. and E. purpureum L. (Compositae: Eupatorieae) contain both loose mature pollen grains and acetolysis-resistant extratapetal sacs enclosing clusters of immature pollen. Many sacs contain incompletely developed pollen grains that differ in size diameter, with spines of varying lengths and degrees of acuity and with colpal areas having narrow to markedly protracted margins. We presume that all nutrients for pollen development within sacs come from plasmodial tapetum included therein. Thus, pollen in portions of the sac or in isolated sacs with inadequate plasmodial tapetum may be incompletely developed. Such partial development may result from stress, e.g. insufficient nutrients and water. While our data are from three species of Eupatorium, we have long noted the syndrome in other Eupatorieae and other tribes in the Compositae. Curtailing supplies for development of some portions of an anther could be an evolutionary strategy for survival of the species through periods of stress.