荇菜腺毛的发育及其分泌过程的超微结构研究

荇菜 (Nymphoides peltatum (Gmel.) O.Kuntz)腺毛由具分泌功能的单列圆筒状细胞组成。它们起源于苗端倒数第二叶原基近轴面 ,由原表皮细胞发育而来。处于分泌期的腺毛细胞其胞质浓厚 ,液泡化程度小。细胞内具丰富的线粒体、高尔基体和内质网等细胞器 ,还具发达的胞间连丝。粘液物质由高尔基体分泌小泡、内质网分泌小泡及多膜体共同携带至细胞边缘 ,经胞吐和渗透相结合的方式分泌至细胞外。腺毛细胞侧壁因积有大量分泌物而呈膨胀状态。经检测 ,粘液由多糖和蛋白质组成 ,对营养芽的生长发育起保护作用。     

羽叶薰衣草表皮毛的发育解剖学研究

对羽叶薰衣草(LavandulapinnataL.)茎和叶上两种表皮毛(腺毛和非腺毛)发育的解剖学观察表明,两者的发生都源于茎或叶的原表皮细胞,但外部形态、发育过程及功能明显不同。腺毛有头状腺毛和盾状腺毛两种类型,均由1个基细胞、1个柄细胞和头部细胞构成。头状腺毛的头部只有1个或2个分泌细胞,盾状腺毛由8个分泌细胞构成头部。非腺毛由3-20个细胞组成,可分为三种类型:单列不分枝、二叉分枝和三叉及三叉以上多分枝的树状分枝。非腺毛的顶部细胞由基部到顶部逐渐变细,先端成尖形。腺毛发育由原表皮细胞经两次平周分裂形成,由于柄细胞和头部细胞所处的分化状态不同而发育成两类腺毛。非腺毛由非腺毛原始细胞经二次或多次平周分裂和不均等分裂,再发育成数个至二十多个子细胞。     

线纹香茶菜叶上腺毛发育的细胞学研究

为进行中药溪黄草基原植物的品种鉴定,采用光镜和电镜对线纹香茶菜(原变种)[Isodon lophanthoides var.lophanthoides]叶上腺毛的发育进行细胞学研究。结果表明,线纹香茶菜具有头状腺毛和盾状腺毛2种类型。头状腺毛无色透明,由1个基细胞、1个柄细胞和1或2个头部分泌细胞构成;盾状腺毛为红色,由1或2个基细胞、1个柄细胞和4~8个分泌细胞构成头部。2种腺毛均由原表皮细胞经两次平周分裂形成,后因柄细胞和头部细胞所处的分化状态不同而形成两类腺毛。2种腺毛超微结构表明,质体、高尔基体和粗面内质网为主要分泌物产生和运输的细胞器。当盾状腺毛成熟时,角质层下间隙充满了分泌物,其分泌物的性质很可能决定了线纹香茶菜腺毛的颜色。     

龙葵腺毛发育的细胞学研究

利用光学显微镜、扫描电镜和透射电镜技术,观察了龙葵“四叶一心”期时叶片及茎表皮的腺毛的种类、分布,探究了不同类型腺毛的起源、生长、成熟、分泌、衰老等发育过程的细胞学特征;通过组织化学染色和荧光显微技术,观察了龙葵腺毛成分、分布,为龙葵的进一步开发利用提供参考。结果表明：（1）龙葵腺毛分为单细胞头腺毛和多细胞头腺毛两类,前者主要分布于茎表面和叶上下表皮,后者主要分布于茎表面的单细胞头腺毛之间、叶脉及叶边缘;（2）龙葵腺毛发育起始于表皮细胞突起,单细胞头腺毛行顶端生长,具1-4个柄细胞,四种类型;多细胞头腺毛可再分为一层、两层与三层多细胞头腺毛,另具三种特殊类型;（3）龙葵成熟腺毛具分泌能力,通过皮下空间的物质积累导致腺毛头细胞表面形成突起、包块、破口,最终释放分泌物;而头细胞与柄细胞随即皱缩、衰老。（4）超微结构显示,腺毛头细胞中内质网与高尔基体极为丰富,合成代谢及分泌活动活跃,产生大量包裹嗜锇物质的囊泡,囊泡与细胞壁融合,进而将嗜锇物质转移至细胞壁并积累,随后储存在角质层下的皮下空间直至分泌释放;（5）组织化学染色结果表明,腺毛含有萜类、生物碱、脂类、蛋白质、酚类和多糖。头细胞中主要含有萜类、生物碱、脂类、蛋白质、酚类和中性多糖;柄细胞中主要含有萜类、生物碱、脂类。     

火炬树腺毛的形态结构和发育的研究

研究了火炬树（RhustyphinaTorner．）叶柄腺毛的形态结构和发育过程,结果表明,其腺毛起源于叶柄的表皮细胞,每个腺毛都由1个基细胞、3个柄细胞和分泌细胞组成的头部3部分组成。     

慈姑腋生小鳞片的发育及其超微结构的研究

慈姑叶腋内有许多１－２层细胞厚、无维管束的小鳞片,它们由叶鞘基部背腹面及叶腋部的表皮细胞分裂形成;小鳞片的发生与顶端分生组织无直接关系。靠近生长锥的幼叶叶腋内的小鳞片能覆盖生长锥;由于小鳞片细胞具有分泌粘液的功能,使生长锥和叶原基片于粘液的包裹之中,从而有效地防止了水流的侵袭。小鳞片进入分泌期后,细胞内高尔基体数量明显增多,并活跃地溢出囊泡;内质网膨大成囊泡状;线粒体由近质膜,且出现变形。小鳞片发     

紫苏腺毛的形态发生研究

紫苏叶上有两种腺毛：质状腺毛和头状腺毛。两者都具１个基细胞、１个柄细胞和头部。前者的头部可由１、２、４或８个分泌细胞组成,扩展成质状;后者的头部由１、２或４个分泌细胞组成,聚成圆球状。两种腺毛的原始细胞都来源于原表皮细胞,经两次平周分裂产生基细胞、柄细胞和顶细胞。在腺毛后期的形态发生中,柄细胞的分化状态决定腺毛的类型。若柄细胞保持扁平关且处于分生状态时,其顶细胞将发育成质状腺毛的头部;若柄细胞纵向     

木香薷腺毛形态结构发生发育规律的研究

采用常规石蜡切片法及扫描电镜技术对木香薷(Elsholtzia stauntoni Benth)腺毛发生发育及其规律进行了研究。结果表明：木香薷表皮上主要有两种表皮毛：无分泌细胞的表皮毛与有分泌细胞的腺毛。前者包括单细胞乳头状毛、2~3细胞管状毛、分枝状毛及多细胞管状毛;后者包括头状腺毛与盾状腺毛。成熟头状腺毛头部由1、2或4个分泌细胞构成,头部呈圆球形或半圆球形;成熟盾状腺毛头部由8~12个分泌细胞构成,分泌细胞横向扩展形成盾状头部。木香薷腺毛主要在茎端幼叶处大量发生,从茎端第一对幼叶处开始产生;从幼叶期到成熟期均有腺毛发生,大部分腺毛在幼叶期发生发育,只有极少部分在叶的成熟期进行发生发育。     

紫苏腺毛的形态发生研究

紫苏叶上有两种腺毛:盾状腺毛和头状腺毛。两者都具1个基细胞、1个柄细胞和头部。前者的头部可由1、2、4或8个分泌细胞组成,扩展成盾状;后者的头部由1、2或4个分泌细胞组成,聚成圆球状。两种腺毛的原始细胞都来源于原表皮细胞,经两次平周分裂产生基细胞、柄细胞和顶细胞。在腺毛后期的形态发生中,柄细胞的分化状态决定腺毛的类型。若柄细胞保持扁平状且处于分生状态时,其顶细胞将发育成盾状腺毛的头部;若柄细胞纵向引长并迅速液泡化时,其顶细胞将发育成头状腺毛的头部。     

高尔基体的结构与功能(二)

二、高尔基体的功能高尔基体的主要功能是参与细胞的分泌活动。近年来用细胞化学和放射自显影等技术对此作了深入的研究,阐明了高尔基体在分泌活动中的作用,主要是将由糙面内质网合成的蛋白质作进一步加工、浓缩和运输,形成各种分     

Studies on the Development of Glandular Hairs in Nymphoides peltatum and the Ultrastructure During Their Secretory P

Each glandular hair of Nyrnphoides peltaturn (Gmel.) O. Kuntz consisted of only one row of cylindar cells with secretory function. The hairs originated from the protoderm cells on the adaxial surface of the second leaf primordium from the shoot apex. Cells of the glandular hairs prossessed dense cytoplast during the secretory period, but the vacuoles were very small. There were not only abundant mitochondria, Golgi bodies and endoplasmic reticulum in the glandular hair cells, but also many plasmodesmata. The authors' research indicated that the mucilage was carried to the edge of the cells by the membranous multilamellar bodies and the vesicles from both Golgi bodies and endoplasmic reticulum. The mucilage was secreted extracellularly by either exocytosis or ecrine secretion. The side walls of the glandular hairs swelled because of mucilage mass accumulation in the walls. The mucilage, being tested to be composed of polysaccharides and a trace of protein, played an important role in protecting the development of the vegetative buds of N. peltatum.     

薄荷头状腺毛分泌过程的超微结构研究

电镜观察表明,刚形成的薄荷头状腺毛的头部细胞,细胞核较大细胞质浓,有一些小液泡,质体和线粒体最显著,分泌前期,内质网及高尔基体数量明显     

The fine structure of the tarsal glands of the honeybee Apis mellifera L. (Hymenoptera)

Summary Tarsal glands are located in the 6th tarsomere of adult honeybee queens, workers and drones. Their structural features are not cast or sex specific. The glandular epithelium is lined by a thin endocuticular layer. A cuticular pocket is formed from a postimaginal delamination of the cuticle secreted by the glandular epithelium. The apical plasma membrane of the glandular cells shows numerous cristae and microvilli lining large crypts that communicate with the subcuticular space. Pinocytotic vesicles, multivesicular bodies and residual dense bodies are present in the apical part of the glandular cells. The RER is well developed in perinuclear and basal parts of the glandular cells, but the Golgi apparatus is a discrete organelle without secretory granules. No exocytotic secretory structures were observed. To reach the glandular pocket, the non-proteinaceous secretory product must pass across the subcuticular space, the cuticular intima, the space between the intima and the cuticular wall, and the cuticular wall of the glandular pocket.     

Secretion of cell wall polysaccharides in Vicia root hairs

Root hairs of hairy winter vetch ( Vicia villosa Roth) synthesize and secrete abundant cell wall matrix polysaccharides, making this an excellent system for the study of secretion during tip growth. Roots with newly formed hairs were preserved by cryofixation and freeze substitution. Cryofixed root hairs showed excellent structural and antigenic preservation. Ultrastructural analyses showed numerous vesicles near the tip and a concentration of Golgi bodies in the subapical region of the hair. The distribution of polygalacturonic acid and xyloglucan in the endomembrane system and cell wall were revealed by immunolabeling, using previously characterized monoclonal antibodies. De-esterified polygalacturonic acid was present on the external surface of the cell wall, but was not detected within the cell, although chemical de-esterification revealed abundant antigen in Golgi bodies and secretory vesicles. Methyl-esterified polygalacturonic acid epitopes were detected within the medial and trans cisternae of Golgi bodies, in secretory vesicles, and throughout the wall, indicating that pectin is secreted in a neutral form and may then be de-esterified in muro . Xyloglucan was also detected within the trans cisternae of Golgi bodies, secretory vesicles and throughout the cell wall. Double labeling experiments demonstrated that both polysaccharides occur simultaneously in the same Golgi bodies, and that secretory vesicles containing both polygalacturonic acid and xyloglucan deliver the polysaccharides to the cell wall at the growing tip.     

Structures, Components and Functions of Secretory Tissues in Houttuynia cordata

Houttuynia cordata Thunb., traditionally used as a therapeutic plant in folk medicine, has shown antioxidant and anticancer activities. The species, as a core component of paleoherbs, is normally characterized based on the presence of different types of secretory tissue： oil cells, three types of secretory cells and glandular hairs. The aim of this work was to study the structural, componential, and the functional characteristics of the secretory tissues in both the floral and vegetative parts. The results indicate that oil cells and secretory cells are distributed in all organs of the plant, while glandular hairs are situated on the aerial stems and leaves. Both oil cells and glandular hairs initiate from the protoderm, but their developmental processes are different. Although three types of secretory cells initiate from different primary meristems, the developmental patterns of different secretory cells are the same. Also, although the origins of secretory cells are different from oil cells, their early developmental processes are the same. Histochemical results show that oil cells, secretory cells and glandular hairs produce flavonoids, phenolic compounds, tannins, lipids, aldehyde and ketone-compounds. In addition, there are terpenoids and pectic-like substances in oil cells, alkaloids in secretory cells of aerial stems, and terpenoids and alkaloids in glandular hairs. These compounds play very important roles in protecting plants from being eaten by herbivores （herbivory） and infected by microbial pathogens. The oil cell and secretory cell, as unicellular secretory tissues, are intermediates between the primitive surface glandular and secretory cavity and canal during the evolution of secretory structures.     

Developmental and comparative ultrastructure of glandular hairs in the two Urticaceae. I. Urtica dioica

Secretion produced by glandular hairs is deposited mainly in the periplasmic space of the head cells. It stains intensely for both proteins and polysaccharides. The ultrastructure of meristematic, differentiating, mature and senescent head cells as well as the stalk and basal cells has been described in comparison to that in other cell types of the leaf. The specific features of the head cells are the proliferation of the granular endoplasmic reticulum as well as the multiplication of the dictyosomes and mitochondria during transition to the secretion stage. However, the frequency of dictyosomes varies among secreting hairs. The ER produces neither secretory nor transition vesicles and does not anastomose with the plasmalemma. In the absence of transition vesicles, the transport of secretory proteins and enzymes of polysaccharide synthesis from the ER to dictyosomes apparently includes the cytosolic step. Dictyosomes, though not appearing hypersecretory, produce two types of smooth secretory vesicles generated by the trans Golgi reticulum. The vectorial transfer of prosecretion and membranes across the dictyosome stack proceeds via the transport (shuttle) vesicles. It is, therefore, concluded that exocytosis of smooth secretory Golgi vesicles is the sole mechanism of release of both proteins and polysaccharides. Coated vesicles occasionally seen near the plasmalemma are likely to be involved in the endocytotic membrane retrieval. The secretion product disappears during senescence of the hairs and the secretory cells undergo vacuolation by means of local autophagy.     

Disruption of the Golgi apparatus and secretory mechanism in the desmid, Closterium acerosum by brefeldin A

The mucilage-secreting desmid, Closterium acerosum, is sensitive to the secretory inhibiting drug, brefeldin A (BFA). After 5 min of treatment with 5 g ml^-1 of BFA, the Golgi body displays the following alterations: the number of cisternae decreases from 12-15 to 6-7; peripheries of cisternae from the same Golgi body often fuse to yield unique profiles; secretory vesicles still merge from the Golgi body; the cisternal stack dissociates to form irregular masses in the alleys of cytoplasm created by the lobes of the chloroplast. Fluoresbrite bead labelling shows that mucilage production ceases in cells treated with BFA even after only 5 min of treatment. Immunogold labelling using anti-mucilage antibody reveals that mucilage production still occurs in the Golgi body and associated vesicles. Helix pomatia lectin-gold labelling shows that wall synthesis still occurs in BFA-treated Golgi bodies and wall precursors accumulate in the perforate cisternal/vesicular masses seen in the TGN region of the Golgi stack.