黄瓜雌花发育过程中柱头的腺特征(英文)

利用透射电镜技术研究了黄瓜（Ｃｕｃｕｍｉｓ　ｓａｔｉｖｕｓ　Ｌ．）雌花柱头发育过程中传递组织、分泌组织和乳突细胞的超微结构。在整个发育过程中,乳突细胞和分泌组织细胞的细胞质内密布很多管状及槽库膨大的内质网,产生很多分泌囊泡;在成熟柱头的传递组织和分泌组织细胞间观察到大量的胞间连丝;乳突细胞和分泌细胞高度液泡化,质膜内折;在柱头发育过程中分泌组织细胞的核周腔扩大形成裂瓣状核,到柱头成熟阶段裂瓣状核更加明显。进一步的研究显示,在成熟柱头的不同组织细胞中,　ＡＴＰａｓｅ的活性呈现在质膜和液泡膜上,随着柱头的发育,ＰＭ－Ｈ＋－ＡＴＰａｓｅ的比活性明显增强。结果表明,黄瓜雌花柱头的腺特征随发育进程而趋于显著。     

荔枝雌蕊发育过程中钙分布变化与细胞程序性死亡

应用焦锑酸钾沉淀法研究了荔枝雌花和雄花雌蕊发育过程中钙的分布变化。在大孢子母细胞阶段,雌花近珠孔内珠被细胞和花柱细胞的钙沉淀颗粒主要分布在细胞壁和细胞间隙,少部分在液泡;雌花花柱维管细胞中含有很多的钙沉淀颗粒;在雄花的近珠孔内珠被细胞钙沉淀颗粒大多在液泡中;雄花花柱细胞和维管细胞中钙沉淀颗粒很少。大孢子母细胞减数分裂后,雌花雌蕊继续发育,雄花雌蕊败育。雌花维管中的钙沉淀颗粒数量减少,可能被转运到将要发生花粉萌发和受精的部位。雌花近珠孔内珠被细胞壁的钙沉淀颗粒分布增加,花柱细胞从上（近柱头）到下（近子房）钙沉淀颗粒量递增。雄花近珠孔内珠被细胞发生程序性死亡：液泡中的钙进入细胞核启动细胞程序性死亡,核周隙与质膜腔形成连续的通道,钙在核与细胞质之间的流动不受限制;在特定的时间段,钙沉淀颗粒出现在线粒体、过氧化物体和线型内质网的外膜上。钙在细胞中重新分布可能触发和调节细胞程序性死亡的进程。缺乏钙沉淀颗粒的雄花花柱细胞迅速解体。     

西瓜柱头乳突细胞分泌活动期间ATP酶活性超微结构定位

研究了西瓜柱头乳突细胞ＡＴＰ酶活性的超微结构定位。分泌活动旺盛的细胞中,质膜、内质网、质体的内部片层、胞间连丝以及多数大液泡的膜上面都有大量ＡＴＰ酶活性反应产物,线粒体和小泡上只有少量酶活性反应产物。分泌活动停止后处于解体状态的细胞内,反应产物主要定位于液泡膜上。分泌旺盛的乳突细胞质膜具有高的ＡＴＰ酶活性表明分泌物运出需要大量能量,内质网ＡＴＰ酶活性强可能意味着该细胞参与分泌物合成。     

西瓜柱头乳突细胞分泌活动期间ATP酶活性超微结构定位

研究了西瓜柱头乳突细胞ATP酶活性的超微结构定位。分泌活动旺盛的细胞中,质膜、内质网、质体的内部片层、胞间连丝以及多数大液泡的膜上面都有大量ATP 酶活性反应产物,线粒体和小泡上只有少量酶活性反应产物。分泌活动停止后处于解体状态的细胞内,反应产物主要定位于液泡膜上。分泌旺盛的乳突细胞质膜具有高的ATP酶活性表明分泌物运出需要大量能量,内质网 ATP 酶活性强可能意味着该细胞器参与分泌物合成。     

甜菊愈伤组织中的质膜内陷:超微结构和酸性磷酸酶细胞化学定位

对在分化条件下的甜菊 (Stevia rebaudiana)愈伤组织分生区域细胞的质膜内陷进行了超微结构和酸性磷酸酶细胞化学研究。结果表明 ,在不同液泡化状态的细胞中均有质膜内陷存在。在原生质浓密的细胞中 ,质膜呈起伏的波纹状 ,某些部位发生明显内陷 ,大小不等 ,多呈圆球状。在部分液泡化细胞中 ,质膜内陷体积增大 ,内含物增多且结构复杂。在液泡化细胞中 ,质膜内陷嵌入中央液泡 ,但彼此间以一膜间隙隔开。质膜内陷中的内含物以小泡和卷绕的膜结构形式存在。酸性磷酸酶活性定位结果显示 ,质膜及其内陷含高的酶活性。推测质膜内陷在功能上与液泡相似 ,构成了这些细胞水解空间的一部分。     

芫荽花蜜腺的发育解剖学研究

芫荽的花蜜腺位于子房上部盘状结构上,属于下位子房上部的花盘蜜腺。蜜腺由分泌表皮和产蜜组织构成。分泌表皮具厚的呈波纹状皱折的角质层,层皮上分布有下陷的变态气孔。产蜜组织细胞４－５层,其下有３－４层大型薄壁细胞与来自子房壁的维管束相毗邻。芫荽花蜜腺发育较晚,在子房发育后期由花盘表面的１－２层细胞恢复分裂能力形成蜜腺组织。产蜜组织细胞在发育过程中,液泡、淀粉粒都呈现一定的消第长规律。根据其结构及泌蜜前后     

荞麦柱头、花柱的结构及ATP酶的超微细胞化学定位

利用超薄切片结合ATP酶定位技术,研究了荞科柱头及花柱的结构。结果表明,成熟的荞麦柱头表面无乳突细胞,柱头细胞的细胞壁存在发达的壁内突,花柱为实心型无引导组织,柱头表面的细胞壁根据电子密度的不同可划分为3层,最外一层电子密度最大,最内一层电子近透明,并形成壁内突的结构,柱头表面和花柱细胞的质膜上ATP酶的活性较高,表明成熟的柱头和花柱细胞物质代谢和运输十分活跃,成熟的柱头和花柱细胞中有丰富的蛋白质和多糖类物质。     

拟南芥根原生韧皮部筛管分子的超微结构

运用高压冷冻替代方法固定处理材料,在透射电镜下观察了拟南芥(Arabidopsis thaliana L.)根原生韧皮部筛管分子在发育过程中的超微结构变化.结果表明:在筛管分子发育过程中,细胞核具有细胞程序化死亡的典型特征,出现核膜内陷、核质聚集并边缘化、核膜破毁以及最后核消失.核膜在破毁前一直呈饱满状态,未出现核膜皱缩、核裂瓣和核周腔明显膨大等现象.在成熟筛管分子的细胞质内,具单层膜的淀粉状颗粒.这些淀粉状颗粒常与线粒体在一起,可能为线粒体的产能活动提供基质.小液泡发生于内质网,未见大液泡的形成.     

葡萄果实发育过程中果肉细胞超微结构的观察

用透射电镜观察了“巨峰”葡萄(Vitis vinifera×V.labrusca)果实3个发育时期中果肉细胞超微结构的变化。果实第一次快速生长期的果肉细胞超微结构表现出物质和能量代谢旺盛的特点。缓慢生长期的果实虽外部形态平静少变,但果肉细胞超微结构表现出深刻的变化:细胞核形状特化为裂瓣状是最显著的特点;线粒体数目丰富;粗面内质网槽库膨大形成的囊泡富集,出现向液泡汇融和向质膜靠近的现象;质膜内陷;液泡膜完整。另外,原生质也出现一些降解的现象。但总体结构特点表明果肉细胞在此期处于十分活跃的物质周转代谢和信息交换过程中。果实第二次快速生长期果肉细胞超微结构表现出衰老降解的特点,但线粒体结构依然完整,数量仍然丰富,原生质膜也保持了很好的完整性,这似乎与维持第二次快速生长或成熟有关。     

鹅掌楸属植物引导组织和花粉管生长

应用光学显微镜和常规石蜡切片技术研究了鹅掌楸属（ＬｉｒｉｏｄｅｎｄｒｏｎＬ．）两种植物雌蕊引导组织的分布和个体发育,引导组织是由心皮边缘或内表面的表皮细胞层或亚细胞层发育形成,是由一层细胞组成的连续层,覆盖干柱头、花柱道和珠柄的表面,引导组织的细胞形态学因其所在部位不同而有差异。在电境水平上研究了柱头和花柱引导组织的超微结构,引导组织细胞是分泌型的传递细胞,其分泌面发育了明显的壁内突,细胞质中富含内质网、多聚核糖体、各种小泡、高尔基体和线粒体,大液泡通常远离分泌面。文中还探讨了花粉管生长后引导组织的变化。     

The transmitting tract in Trimezia fosteriana (Iridaceae). 1. Ultrastructure in the stigma, style and ovary

An ultrastructural investigation of the entire transmitting tract in Trimezia fosteriana (Iridaceae) was undertaken. The transmitting tissue is secretory but transfer cells do not occur at any level. With exception for the stigma papillae, the cells are covered with large amounts of secretory products. The papillae have a thick and ridged cuticle. The cuticle in the rest of the transmitting tract is thin and detached from the cell wall by the secretory products. It is more or less ruptured in the secretory parts of the stigma and ovary. In the stylar canal the major part of the cuticle is continuous and covers the secretory products. The occurence of a large amount of vesicles in the stigma transmitting tissue cells is interpreted as a result of high dictyosome activity. An electron opaque material is produced in the dictyosomes and appears in vesicles and vacuoles but also between the plasma membrane and the cell walls in the stigma. A small amount of such material is present in the cell walls. Corresponding material is also present in the style and the ovary but declines basipetally. Plastids with strongly electron opaque plastoglobules are present at all levels in the transmitting tract.     

Developmental Aspects of Ultrastructure, Histochemistry and Receptivity of the Stigma of Nicotiana sylvestris

The bilobed papillate stigma of Nicotiana sylvestris Speg. andComes, is covered at maturity with a copious exudate containinglipid, protein and carbohydrate. The stigma is receptive fromthe very early stage of development and it also stains positivelyfor esterase activity. The stigma has three distinct zones:an epidermis with papillae; a subepidermal secretory zone; anda parenchymatous ground tissue. The behaviour of the cells ofthese three zones has been followed from 6 d before anthesisto one day after anthesis and pollination. The cells of theepidermis and the secretory zone stain intensively for lipids,proteins and carbohydrates in the initial stages. The secretoryzone develops large intercellular spaces containing heterogenoussecretory products which also stain positively for the aforesaidthree compounds. At maturity the secretory products are releasedto the surface through gaps formed in the epidermis by cellseparation. The main secretion of the stigma is produced bythe cells of the secretory zone. Less secretion is derived fromthe stigmatic papillae. Some amount of secretion is also releasedfrom the stylar transmitting tissue adjoining the stigma. Theglandular cells of the stigma contain numerous plastids, mitochondria,ribosomes, ER, cytoplasmic lipid droplets and some dictyosomes.The plastids and the vacuoles in the secretory cells of thestigma have a lot of electron dense (osmiophilic) inclusionsrespectively in the initial and later stages of development.The former are probably involved in the production of thesematerials. It is suggested that the proteins are directly secretedby rough ER compartments whereas smooth ER is involved in thesynthesis of lipidic materials. The carbohydrate moiety of theexudate is released by the eccrine mode (sugar mono- and dimers)with some addition of polymers by disintegration of the middlelamellae. The means by which the lipidic and osmiophilic materialis extruded remains unclear. Nicotiana sylvestris, stigma receptivity, organization, stigmatic secretory system, stigmatic exudate     

山茱萸花柱和柱头的发育解剖学及组织化学

山茱萸成熟雌蕊的柱头为干型,具表皮起源的单细胞乳突。在开花后授粉前乳突细胞的顶部发生凹陷,授粉后乳突细胞迅速萎缩。花柱在发育初期为开放型,发育后期花柱道消失,成为一种具特殊结构的闭合型。成熟花柱由表皮、皮层和特殊的引导组织等部分构成,在皮层中贯穿有3条维管束,引导组织的中央则有二列类似腺质的内表皮细胞,该细胞富含蛋白质、核酸和多糖类物质。     

STRUCTURE AND DEVELOPMENT OF SIEVE ELEMENTS IN THE LEAF OF ISOETES MURICATA

Leaf tissue of Isoetes muricata Dur. was fixed in glutaraldehyde and postfixed in osmium tetroxide for electron microscopy. The very young sieve elements can be distinguished from contiguous parenchyma cells by their distinctive plastids and the presence of crystalline and fibrillar proteinaceous material in dilated cisternae of the rough ER. During differentiation, the portions of ER enclosing this proteinaceous substance become smooth surfaced and migrate to the cell wall. Along the way they apparently form multivesicular bodies which then fuse with the plasmalemma, discharging their contents to the outside. At maturity, the sieve element contains an elongate nucleus, which consists of dense chromatin material, and remnants of the nuclear envelope. In addition, the mature sieve element is lined by a plasmalemma and a parietal, anastomosing network of smooth ER. Both plastids and mitochondria are present. P-protein is lacking at all stages of development. Tonoplasts are. not discernible in mature sieve elements. The end walls of mature sieve elements contain either plasmodesmata or sieve pores or both, but only plasmodesmata occur in the lateral walls.     

Structural analysis of stigma development in relation with pollen–stigma interaction in sunflower

Structural analysis of stigma development in sunflower highlights the secretory role of papillae due to its semi-dry nature. Production of lipid-rich secretions is initiated at the staminate stage of the flowers in stigma development and increases at the receptive stage, coinciding with an extensive development of elaioplasts and endoplasmic reticulum network in the basal region of the papillae. Transfer cells, earlier identified only in the wet type of stigma, are also present in the transmitting tissue of the sunflower stigma. Attainment of physiological maturity by the stigmatic tissue, accompanying development from bud to pistillate stage, appears to affect the initial steps of pollen–stigma interaction. The nature of self-incompatibility in Helianthus has also been investigated in relation with pollen adhesion, hydration and germination. Pollen adhesion to the stigma is a rapid process in sunflower and stigma papillae exhibit greater affinity for pollen during cross pollination as compared to self-pollination. Components of the pollen coat and the pellicle on the surface of stigmatic papillae are critical for the initial phase of pollen–stigma interaction (adhesion and hydration). The lipidic components of pollen coat and the proteinaceous and lipidic components from the surface of the papillae coalesce during adhesion, leading to the movement of water from stigma to the pollen, thereby causing pollen hydration and its subsequent germination. Pollen germination (both in self-and cross-pollen) on the stigma surface and the growth of the pollen tube characterize the flexibility of self-incompatibility in sunflower. Compatible pollen grains germinate and the pollen tube penetrates the stigma surface to enter the nutrient-rich transmitting tissue. The pollen tube from incompatible pollen germination, however, fails to penetrate the stigmatic tissue and it grows parallel to the papillae. Present findings provide new insights into structural and functional relationships during stigma development and pollen–stigma interaction.     

The transmitting tract in Trimezia fosteriana (Iridaceae).

Observations of the transmitting tract cells in Trimezia fosteriana were made from the pre-secretory stage until anthesis. Secretory products appear about 14 days before anthesis in all parts of the pistil. Simultaneously starch disappears from the plastids and the dictyosomes are surrounded by more and larger vesicles than before. In the beginning of the secretory stage multivesicular bodies may be in contact with ER profiles and an ER origin is therefore presumed. Later during the secretory stage the multivesicular bodies are larger and more abundant. Their envelope is often partly fused with the plasma membrane and vesicle swarms are common on the outside of it. Close to flower opening many organelles change in appearence. RER becomes more abundant and the mitochondrial matrix highly electron dense and the cristae expanded. Starch grains reappear and large ones are common in the stigma and ovary plastids. The dictyosomes are numerous and surrounded by the largest vesicles observed during the secretory stage. Osmiophilic granules are common in the dictyo-some vesicles and under the cell walls abutting the transmitting tract. In the ovary they are present one week before anthesis. In the stigma and style corresponding granules of high electron density appears at the day of flower opening. The extracellular secretory product contains fibrillar and granular substances consisting of carbohydrates, including pectic substances, and proteins.     

The Extrafloral Nectaries of Cotton: II. CYTOCHEMICAL LOCALIZATION OF ATPASE ACTIVITY AND CA2+ -BINDING SITES, AND SELECTIVE OSMIUM IMPREGNATION

Localization of ATPase activity in the extrafloral nectariesof cotton (Gossypium hirsutum) shows most pronounced granularstaining at the plasmalemma of the sieve tube companion cellsbelow the nectaries and at the plasmalemma of cells in the secretorypapillae, particularly in the apical cell. Staining was muchmore intense in mature, secreting nectaries than in young, non-secretingones. When CaCl₂ is included in the fixation and washing solutionswith the aim of localizing calcium binding sites, prominentamorphous electron dense globules are seen at the plasmalemmaof the cells in the papillae, but also associated with othermembranes. Both granular and amorphous deposits are seen whenstaining for Ca²⁺-ATPase activity. Selective osmium impregnationshows pronounced staining of the ER and nuclear envelope insecreting nectaries but not in young non-secreting ones. Key words: Adenosine triphosphatase, Gossypium hirsutum, Nectary, Secretion     

The Structure and Cytochemistry of the Pistil of Hypericum calycinum: The Stigma

The pistil of Hypericum calycinum has a pentacarpellary, syncarpousovary with five slender styles, each terminating in a smallstigma. The stigma is dry and papillate with a thin lining ofpellicle. The cuticle is thin and continuous around the papillae.A large vacuole filled with tannins occupies the major partof the papillae and the cytoplasm forms a thin lining aroundthe vacuole. The cell wall of the mature papillae show two distinctlayers - an outer layer of loosely woven fibrils and an innerdenser layer with compact fibrils. A large number of small lipoidalbodies accumulate just below the cuticle. The papillae havefewer organelles than those typical of glandular cells. Dictyosomesobserved occasionally are without associated vesicles. The cytoplasmis rich in ribosomes. The basal portions of the papillae mergeinto the transmitting tissue made up of loosely arranged cells.The intercellular matrix of the transmitting tissue is richin lipids. Pollen grains are deposited between the papillae.Upon pollen germination, pollen tubes enter the stigma throughthe interstices between the papillae Hypericum calycinum, cytochemistry, pistil, pollen-pistil interaction, stigma, ultrastructure