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1.
在甜椒(Capsicum annuum L.)中,靠近花粉中部的绒毡层自药隔产生,由较大的细胞组成,而花药外部区域的其余的绒毡层细胞较小,来自于初生壁层,前者的细胞具有大液泡和较大的细胞核,甲基绿-派罗宁和汞-溴酚蓝染色反应较后者弱,在造孢组织时期,二者液泡内都含有较大的球形的酸性磷酸酶颗粒,在以后的发育中,这种颗粒消失,在减数分裂时期,两种绒毡层的DNA,RNA和蛋白质合成活动增强,来自药隔的绒毡层积累了更多的DNA,绒毡层在解体时酸性磷本酶活性很高,两种不同的绒毡层退化过程相似,在全部发育过程中绒毡层内无淀粉粒。 相似文献
2.
R. J. Bino 《Protoplasma》1985,127(3):230-240
Summary Anther development of isogenic male fertile and cytoplasmic male sterile types ofPetunia hybrida cv. Blue Bedder is studied by electron microscopy. First deviation in sporogenesis of the sterile type, is observed during leptotene stage of the meiocytes. Initial aberration is represented by the presence of large vacuoles in the cytoplasm of the tapetal cells. These vacuoles reveal the first aspects of degeneration; no other ultrastructural differences are observed. Vacuolation is accompanied by the condensation of cytoplasmic organelles. The tapetal cells become distorted and ultrastructural aberrations in mitochondria do occur. The mitochondria elongate and contain several tubular cristae.Substantial evidence suggests, that cytoplasmic male sterility in petunia is encoded by the mitochondrial genome (Boeshore
el al. 1983). However, before degeneration becomes manifest, no consistent ultrastructural differences in mitochondrial organization are observed.Abortion of the tapetum and the sporogenous tissue in cytoplasmic male sterile plants, generally follows a corresponding pattern. Ultimately, the cells are highly distorted, the nucleus is disrupted and the cytoplasm disorganized. Mitochondria and plastids degenerate and many lipid droplets are present. 相似文献
3.
The tapetal development ofCichorium intybus L. is investigated using LM and TEM and discussed in relation to the development in other species. During the second meiotic division the tapetal cells become binucleate and lose their cell walls. They intrude the loculus at the time of microspore release from the meiotic callose walls, which means that a locular cavity is never present in this species. During pollen development they tightly junct the exine, especially near the tips of the spines. During the two-celled pollen grain stage they degenerate and most of their content turns into pollenkitt. Until anther dehiscence they keep their individuality, which means that these intruding tapetal cells never fuse to form a periplasmodium. The ultrastructural cytoplasmatic changes during this development are discussed in relation to possible functions. 相似文献
4.
The ultrastructure and chemical composition of reflective organelles in the anterior pigment epithelium of the iris of the European starling Sturnus vulgaris were examined. The reflective organelles produced a diffuse white reflectance at the iris mid-section which was visible only when the stroma was removed. The pigment granules were clear, angular, and birefringent under the light microscope. In electron micrographs the granules were irregular in shape and density, sometimes crystalline in appearance, but more often they were lost during sectioning or staining. Guanine was abundant in the modified pigment epithelium of the starling, but not in the pigment epithelia of other birds that lacked birefringent granules. Pteridines, such as xanthopterin and leucopterin, were present in small amounts. Pteridines were also present in the iris stroma which had no reflective organelles. The reflective organelles in the starling pigment epithelium resemble both the reflecting platelets of lower vertebrate chromatophores and the reflective granules in the tapeta of various vertebrates. Possible derivation of the organelles from these sources is discussed. 相似文献
5.
Summary In this report we show that large cytoplasmic channels form between the tapetal cells ofZea mays (maize) during the period of tapetal cell differentiation. Tapetal cells are connected by plasmodesmata through their cellulosic cell walls prior to the first meiotic division of the meiocytes. As the tapetal cellulose wall is degraded at the onset of meiosis, both plasmodesmata and cytoplasmic channels measuring 50–200 nm are detectable between tapetal cells. By the time the meiotic tetrad is formed, the cytoplasmic channels are well-established and vary in size from 100–400 nm. The channels, with an average diameter of 200–300 nm, persist after the microspores are released from the callose wall and throughout the period of exine development in microsporogenesis. The channels could potentially allow for free exchange of cytoplasm and organelles. As the tapetal cells begin to pull apart and become vacuolate prior to microspore mitosis, the connecting channels are no longer detectable. 相似文献
6.
Biogenesis and function of the lipidic structures of pollen grains 总被引:31,自引:0,他引:31
Pollen grains contain several lipidic structures, which play a key role in their development as male gametophytes. The elaborate
extracellular pollen wall, the exine, is largely formed from acyl lipid and phenylpropanoid precursors, which together form
the exceptionally stable biopolymer sporopollenin. An additional extracellular lipidic matrix, the pollen coat, which is particularly
prominent in entomophilous plants, covers the interstices of the exine and has many important functions in pollen dispersal
and pollen-stigma recognition. The sporopollenin and pollen coat precursors are both synthesised in the tapetum under the
control of the sporophytic genome, but at different stages of development. Pollen grains also contain two major intracellular
lipidic structures, namely storage oil bodies and an extensive membrane network. These intracellular lipids are synthesised
in the vegetative cell of the pollen grain under the control of the gametophytic genome. Over the past few years there has
been significant progress in elucidating the composition, biogenesis and function of these important pollen structures. The
purpose of this review is to describe these recent advances within the historical context of research into pollen development.
Received: 1 November 1997 / Revision accepted: 3 February 1998 相似文献
7.
The Men-10 gene is expressed specifically in the tapetum tissue that surrounds and nourishes the developing microspores in the dioecious
plant species, Silene latifolia. Men-10 encodes a proline-rich protein that contains a predicted signal region, indicating that it may be secreted from the tapetal
cells and function in the extracellular domain of the tapetum or be translocated to the developing microspores. Here we report
the sequence and precise expression pattern of the Men-10 cDNA and demonstrate a high level of restriction fragment length polymorphism associated with the Men-10 locus. The possible classification of Men-10 amongst known groups of proline- and hydroxyproline-rich glycoproteins, such
as the arabinogalactan proteins, is discussed.
Received: 20 December 1997 / Revision accepted: 2 July 1998 相似文献
8.
The superior performance of F1 hybrids has a significant impact on agricultural productivity. For commercial application, the availability of an efficient
system for obtaining male-sterile lines of crops is an essential prerequisite. Here we have investigated the use of RNA interference
(RNAi) technology to silence a male-specific gene in the model host tobacco. TA29 is expressed exclusively in anthers at the time of microspore development. About 10 out of 13 tobacco lines transformed with
a hairpin RNAi construct containing TA29 sequences were male sterile. Transgenic plants were phenotypically indistinguishable from non-transgenic plants. At the anthesis
stage, pollen grains from transgenic, male-sterile plants were aborted and lysed in comparison to the round and fully developed
pollen in non-transgenic plants. Microscopic analysis of anthers showed selective degradation of tapetum in transgenic plants
with no microspore development. One week after self-pollination, the ovules of non-transgenic plants were double the size
of those in transgenic plants, due to successful self-fertilization. Male sterile transgenic plants set seed normally, when
cross-pollinated with pollen from non-transgenic plants, confirming no adverse effect on the female parts of the flower. These
results show that silencing of male-specific genes by RNAi is potentially a useful tool for generating male-sterile lines
for producing hybrid seed. 相似文献
9.
C. Conicella G. Genualdo R. Lucia K. S. Ramulu T. Cardi 《TAG. Theoretical and applied genetics. Theoretische und angewandte Genetik》1997,95(4):609-617
Somatic hybridization between Solanum commersonii and S. tuberosum resulted in the production of male-sterile hybrid plants, except for one fully male-fertile hybrid. The male-sterile hybrids
exhibited a“pollen-less” phenotype, with rare pollen grains which were abnormal in shape and exine sculpture. Microsporogenesis
and tapetal development were investigated both in male-sterile and male-fertile somatic hybrids to assess the cytological
events that were involved in male sterility. The pattern of male sterility was complex, arising through mechanisms expressed
at both sporophytic and gametophytic levels. Various abnormalities occurred first in the tapetum, and later during meiosis-II
and cytokinesis. These caused the degeneration of the sporads and of the microspores when they were released. In the male-fertile
hybrid, normal development of the tapetum and pollen mother cells was restored. The hypothesis that tapetal breakdown, meiosis-II
and cytokinesis defects are related to each other, and depend on nuclear-mitochondrial interactions, is discussed. Because
of the formation of multivalent chromosome configurations, it is likely that gene exchange between S. commersonii and S. tuberosum can occur in somatic hybrids, offering potential perspectives for the introgression of useful traits from S. commersonii into S. tuberosum.
Received: 10 December 1996/Accepted: 21 March 1997 相似文献
10.
Pollenkitt – its composition, forms and functions 总被引:1,自引:1,他引:0
Two types of sticky pollen coat material exist in angiosperms, both produced by the anther tapetum. Pollenkitt is the most common adhesive material present around pollen grains of almost all angiosperms pollinated by animals, whereas tryphine seems to be restricted only to Brassicaceae. Tapetal cell protoplasts have different patterns of development according to the products formed during their development and degeneration. If tryphine is formed, the tapetal cell protoplasts lose their individuality at the microspore stage. If pollenkitt is formed, their contents degenerate at later stages. Cell content is totally reabsorbed, when ripe pollen is not surrounded by any gluing material. Current knowledge of pollenkitt formation, deposition on pollen grains and chemical composition are reviewed and discussed. Methods for detecting this viscous fluid are also presented. The many functions of pollenkitt, deduced from personal observations and the literature, act in the period between anther opening and pollen hydration on the stigma; they are: (1) to hold pollen in the anther until dispersal; (2) to enable secondary pollen presentation; (3) to facilitate pollen dispersal; (4) to protect pollen from water loss; (5) to protect pollen from ultra-violet radiation; (6) to maintain sporophytic proteins responsible for pollen–stigma recognition inside exine cavities; (7) to protect pollen protoplasts from fungi and bacteria; (8) to keep together pollen grains during transport; (9) to protect pollen from hydrolysis and exocellular enzymes; (10) to render pollen attractive to animals; (11) to render pollen visible to animal eyes; (12) to hide pollen from animal eyes; (13) to avoid predation of pollen through smell; (14) to enable adhesion to insect bodies; (15) to enable pollen packaging by bees and to form corbicules; (16) to provide a digestible reward for pollinators; (17) to enable pollen clumps to reach the stigma; (18) to allow self-pollination; (19) to facilitate adhesion to the stigma; (20) to facilitate pollen rehydration. Depending on the developmental program of the species, these functions may act during pollen presentation, in relation to pollinators, during pollen dispersal and when pollen reaches the stigma. 相似文献