中国芸香科植物叶分泌囊比较解剖学研究

利用整体透明、石腊和薄切片方法对芸香科22属,40种和2变种植物叶分泌囊的形态结构和分 布进行了比较研究。成熟分泌囊都由鞘细胞和一层上皮细胞围绕圆形腔隙构成,上皮细胞扁平,细胞壁 薄、完整,故分泌囊属裂生方式发生。鞘细胞1～5层,不同种类的层数有变化,个别种缺乏。内层鞘细 胞为扁平的薄壁细胞,外层的细胞壁较厚。分泌囊的形态结构、着生位置和分布密度等在不同属或不同 种间存在一定差异。根据分泌囊在叶中的分布位置和形态结构特点,可将其划分为:叶缘齿缝分泌囊, 叶肉分泌囊和两者混合型。叶肉分泌囊又可分海绵组织分泌囊和栅栏组织分泌囊。在此基础上对该科各类型分泌囊的形态演化关系以及各亚科或各属间的亲缘关系进行了探讨。     

贯叶连翘分泌结构的发育及其内含物积累的研究

应用半薄切片和组织化学观察结果表明,贯叶连翘植物内具有分泌囊和分泌细胞团,叶片,萼片,花瓣中都存在2种分泌结构,分泌囊尚存在于果壁内,而分泌细胞团还在花药和茎棱中 ,2种分泌结构均起源于幼叶的基本分生组织内,其原始细胞形态相似,都垂周分裂为2子细胞,接着分别以不同分裂方式形成原始细胞群,并分化出鞘细胞,以后分 囊原始细胞群以裂生方式发育成由1层鞘细胞,1层上皮细胞包围着分泌腔组成的分泌囊,而分泌细胞团原始细胞群则继续增加细胞数目和体积发育成2－4层鞘细胞包围紧密排列的分泌细胞组成的分泌细胞团,其中给终未出现分泌腔,组织[化学试验表明,前者产生和贮存油类物质,而后者产生和贮存金丝桃素类物质。     

吴茱萸果实中分泌囊的发生和发育研究

吴茱萸果皮内分布有许多分泌囊。我们作了发育解剖学方面的研究。在花蕾期,雌蕊的子房中分泌囊原始细胞即开始发生,它起源于单个表皮细胞和其内的1—4层薄壁细胞。分泌囊最初为裂生,后期由于上皮细胞的破毁,其腔隙逐渐扩大,因此,腔隙发生方式应属裂溶生型。成熟分泌囊是由多层鞘细胞和上皮细胞包围圆形腔隙构成。     

金丝桃属植物分泌结构的类型和金丝桃素含量的相关性

利用整体透明,石蜡制片和半薄切片法,对金丝桃属（Hypericum L.)8组20种1变种植物的分泌结构进行了比较解剖研究,结果表明：该属植物的分泌结构可分泌细胞团和分泌囊两种类型,但在不同植物种和不同器官内,分泌结构的类型和分布密度存在差异,对上述植物的提取物进行薄层层析和高效液相层析检测,结果表明,具有分泌细胞团的植物器官含有金丝桃素,而无分泌细胞团的植物器官,则不含金丝桃素,从而证明金丝桃素由分泌细胞团合成和贮藏,在前中,其金丝桃素的含量与其分泌细胞团密度成正相关。     

金丝桃属植物叶中分泌结构的比较解剖学研究

利用整体透明法、石蜡制片法和半薄切片法,对金丝桃属9组43种l亚种1变种的植物叶分泌 结构的类型、形态、结构和分布进行了比较研究。结果表明,分泌结构是金丝桃属植物叶片普遍的结构特征,根据其分泌结构的特征,可划分为分泌细胞团、分泌囊(道)和韧皮部中分泌小管道等3种分泌结构。其中,分泌细胞团按其在叶片的分布可分为叶缘型和散生型;分泌囊按其在叶横切面中的位置可分为栅栏组织型、海绵组织型、居中型(位于栅栏组织型与海绵组织型之间)和横跨叶肉组织型。根据分泌囊和分泌细胞团在该属植物叶中的分布可划分为3种类型：(1)只有分泌囊的类型;(2)只有分泌细胞团的类型;(3)具分泌囊和分泌细胞团的类型。两种主要分泌结构的类型、分布密度、分布位置及其形态等方面在组间和种间均存在—定的差异,对金丝桃属属以下等级的区分具有一定意义。在此基础上,对该属分泌结构的形态演化以及金丝桃属各组间的亲缘关系进行了探讨。     

臭椿茎中分泌道的发育及其组织化学研究

利用植物解剖学方法研究臭椿茎和叶柄中分泌道的结构、分布和发育过程.结果表明:臭椿茎和叶柄中的分泌道分布于髓的周缘,次生木质部中无分泌道.分泌道是由一层分泌细胞围绕分泌腔而构成,分泌细胞外有1～2层鞘细胞.分泌道以裂生方式形成,其发育过程可分为3个阶段:原始细胞阶段、形成阶段和成熟阶段.在原始细胞阶段,一群原始细胞具浓厚细胞质,细胞核清晰可见;形成阶段,原始细胞的中央细胞间细胞壁中层降解,细胞壁分离,形成腔隙,随着分泌细胞数量的增加,分泌腔体积扩大;成熟阶段的分泌道具有12～16个分泌细胞,1～2层鞘细胞,分泌腔直径为30～50μm.组织化学研究表明,分泌细胞及分泌道内含物中含大量的萜类、多糖和脂类物质.机械创伤能够诱导次生木质部中产生创伤分泌道.臭椿茎中的分泌道和创伤性分泌道在抵御生物和非生物胁迫中起重要作用.     

斑衣蜡蝉雌性生殖系统超微结构

【目的】明确斑衣蜡蝉Lycorma delicatula雌成虫生殖系统整体形态及超微结构特征,为蜡蝉总科昆虫分类及系统发育探讨提供更多形态学证据。【方法】采用光学显微镜与透射电子显微镜,观察斑衣蜡蝉雌成虫生殖系统整体形态和各主要器官的超微结构。【结果】斑衣蜡蝉雌成虫生殖系统主要包括1对卵巢、1个中输卵管、1个交配囊、1个交配囊管、1个前阴道、1个后阴道、1个受精囊、1个受精管和2根受精囊附腺。卵巢为端滋式,由14根卵巢小管组成,卵室由固有膜、滤泡细胞和卵细胞组成,卵巢小管中的滋养细胞清晰可见;中输卵管位于前阴道基部,由中输卵管腔、上皮细胞、肌肉鞘和基膜组成;交配囊膨大呈圆球状,囊壁由上皮细胞、肌肉层和基膜组成;交配囊管呈圆柱状,连接交配囊和后阴道,由肌肉鞘、上皮细胞层和管腔组成;前、后阴道超微结构相似,主要由肌肉鞘、基膜、上皮细胞和管腔组成,但后阴道上皮细胞细胞核周围存在分泌颗粒,且管腔内有大量微绒毛,而前阴道壁内包含有大量囊泡结构;受精管从中输卵管末端延伸至受精囊,由基膜、厚层肌肉鞘和管腔组成;受精囊为受精管近末端略膨大的囊状结构,由肌肉鞘、基膜、上皮细胞和囊腔构成;雌性受精囊附腺着生于受精囊末端,为均匀的螺旋管状,主要由肌肉层、上皮细胞层和附腺中心管腔组成。【结论】斑衣蜡蝉雌性生殖系统与已报道的蜡蝉总科其他类群的雌性生殖系统结构相似,但卵巢小管数目有差异;蝉亚目中不同总科雌成虫雌性附腺与受精囊附腺的形态特征存在明显区别;斑衣蜡蝉雌性生殖系统超微结构与叶蝉总科和沫蝉总科昆虫也存在部分差异。这些差异是否可以作为头喙亚目高级阶元的划分依据仍有待于进一步研究。     

慈菇匍匐茎中分泌道的初步研究

慈茹匍蔔茎的分泌道是裂生的胞间道,分布于匍匐茎的基本组织中。单个分泌道原始细胞起始于离茎端约1毫米处的基本分生组织中,原始细胞经分裂形成5—7个上皮细胞包围着中央的裂生腔隙,成为管道系统。上皮细胞无鞘细胞包围。上皮细胞中高尔基体和内质网发达,并溢出小囊泡向着分泌道腔隙面壁的质膜附近迁移,乳汁中亦存在大量完整的小囊泡。上皮细胞和外围薄壁细胞之间的壁层具有大量胞间连丝,小囊泡和内质网的膜结构与胞间连丝末端相接,同时可见上皮细胞的质膜在数处反折内陷,形成袋状结构,在与上皮细胞相对的薄壁细胞内也有同样现象出现,袋状结构内含小形颗粒或囊泡,并在结构上显示出上皮细胞与相邻薄壁细胞间存在着活跃的物质交流。由此认为。代谢物质以整体小囊泡的形式经胞间连丝或内陷的质膜向分泌道迁移是物质运输和分泌的可能方式之一。在电镜下观察,液泡中的积聚物与乳汁十分相似,液泡可能是乳汁的贮存场所之一。     

贯叶连翘的分泌结构及其与金线桃素积累的关系

贯叶连翘地上器官分布着分泌细胞球（黑色腺点）、分泌囊（半透明腺点）和分泌道（半透明腺条）３类内部分泌细胞,分泌细胞球在茎,叶和花器官中均有分布,由２层鞘细胞包围多个分泌细胞的构成实心的分泌细胞团。     

花椒果实分泌囊发育过程的超微结构研究

电镜观察结果表明,花椒(Zanthoxylum bungeanum Maxim.)果实分泌囊是由裂生方式形成,由鞘细胞、上皮细胞和油腔构成。对分泌囊的原始细胞、油腔发生和扩大以及发育成熟3个时期的超微结构研究表明,其精油是在分泌囊油腔发生时开始积累,以油滴形态存在于上皮细胞的质体内及其周围的细胞质中。根据各细胞器的变化规律分析,质体是精油合成的主要场所,内质网参与精油的合成和转运,线粒体为上述活动提供能量。上皮细胞内积累的精油可能通过两种途径排出细胞,分泌至油腔内贮存。鞘细胞内也积累精油,其主要合成场所也与质体有关,以后转运至上皮细胞内。成熟分泌囊的质体由于功能改变,其内出现蛋白质结晶和淀粉粒。     

贯叶连翘的分泌结构及其与金丝桃素积累的关系

贯叶连翘（ＨｙｐｅｒｉｃｕｍｐｅｒｆｏｒａｔｕｍＬ．）地上器官分布着分泌细胞球（黑色腺点）、分泌囊（半透明腺点）和分泌道（半透明腺条）３类内部分泌结构。分泌细胞球在茎、叶和花器官中均有分布,由２层鞘细胞包围多个分泌细胞构成实心的分泌细胞团。分泌囊主要分布于叶片中,分泌道则分布于花器官中,它们都是由１～２层切向扁平细胞围绕圆形或长形腔道构成,腔道的贮存物为精油。利用组织化学方法,结合荧光显微镜观察,证实金丝桃素类物质是由分泌细胞球（黑色腺点）所合成和积累的。通过用戊二醛和锇酸固定样品的显微和超微结构观察,发现金丝桃素类物质积累在成熟腺体分泌细胞的中央大液泡中,细胞周围浓厚的细胞质中分布着大量小液泡和高尔基体、内质网等细胞器。在此基础上对金丝桃素类物质的积累过程进行了初步探讨     

The Secretory Structure of Hypericum perforatum and Its Relation to Hypericin Accumulation

Three different kinds of internal secretory structures, secretory cell globules (black dots), secretory cavities (translucent dots) and secretory ducts (translucent streaks) were observed in Hypericum perforatum L. The secretory cell globule, which occurred in flower, leaf and stem, consisted of a core of large secretory cells surrounded by two layers of flattened sheath cells. The secretory cavities were present throughout the lamina and the secretory ducts throughout the flower, both consisted of one or two layers of flattened cells walling an oil chamber or duct. Histochemical and fluorescence microscopy revealed that hypericin was accumulated in the secretory cell globules. Microscopic and ultrastmctural observation further demonstrated that hypericin was accumulated in the large central vacuole of the mature secretory cells. Numerous dictyosome, endoplasmic reticulum and small vacuoles were observed in the dense cytoplasm surrounded the large central vacuole. The process of hypericin accumulation in the secretory cells was preliminarily discussed.     

Studies on the Structure and Development of Secretory Cavities in Poncirus Trifoliata

Light microscopical observation of thin sections revealed that the initials of secretory cavities in Poncirus trifoliata (L.) Raf. originated from parenchyma cells below the epidermis in early stages of development. The cavity lumen appeared in the center of the initials and gradually enlarged during subsequent development. Concurrently the ceils surrounding the central space differentiated into secretory cells and sheath cells. The developed cavities of fruit ,stem and leaf consisted of 2–5 layers of sheath cells and 2–3 layers of secretory cells surrounding a spherical space. The secretory cells lining the space were observed to remain intact throughout the plantt s life. On the basis of comparative studies with the aid of different kinds of fixatives, embedding media and sectionings,it was suggested that the ,manner of formation of the lacunao of secretory cavities in fruit peels of P. trifoliata, Citrus reticulata and C. sinensis were different. However,as seen in thin sections the secretory cavities of all the 3 species developed schizogenously. Our result with reference to views of other authers concluded the existance of a common schizogenous cavity formation in Rutaceae.     

COMPARATIVE DEVELOPMENT OF SECRETORY CAVITIES IN THE TRIBES AMORPHEAE AND PSORALEEAE (LEGUMINOSAE: PAPILIONOIDEAE)

The tribes Amorpheae and Psoraleeae of the Leguminosae (Papilionoidae) share the characteristics of one-seeded fruits and gland-dotted foliage. Because of this, they traditionally have been considered closely related (either a single tribe or two closely related tribes). However, Barneby (1977) has suggested that the Amorpheae and Psoraleeae are not close but previously had been combined on the basis of a superficial resemblance. This paper describes the structure of the secretory cavities responsible for the gland dots. Approximately 50% of the species of each tribe were surveyed for cavity structure with leaflet clearings. Eight species were then chosen for developmental studies of their glands. Several distinct kinds of secretory cavities are present in these plants. Trabeculate cavities (found only in the Psoraleeae) are traversed by many elongated cells. This type of cavity and nontrabeculate cavities of the Psoraleeae initiate with localized dorsiventral elongation of protodermal cells to form a hemispherical protuberance on the leaf primordium surface. Development proceeds with separation of the cells of a protuberance along their lateral walls facing the protuberance center. As the leaf expands, the protuberance sinks until its apex is flush with the leaf surface. The result is a cavity lined by an epithelium of modified epidermal cells. Trabeculate cavities have more cells in the initial protodermal bump than nontrabeculate “epidermal” cavities, and the central cells of the protuberance are not involved in epithelium formation, but become separated from other cells on all lateral sides, transversing the cavity as trabeculae. Cavities of the Amorpheae are all nontrabeculate and subepidermal. They initiate with periclinal divisions of protodermal cells that result in two cell layers. The exterior layer differentiates into epidermis, while the interior layer divides to produce a small spherical group of cells (“epithelial initials”). Schizogeny occurs in the center of these cells to produce an epithelium-lined cavity. Previous studies of cavity development in the Amorpheae described lysigenous and schizo-lysigenous cavities for most species. These early reports are reviewed, and the possible role of preparation artifacts in producing images of lysigenous development in general is discussed.     

The role of the parenchyma sheath and PCD during the development of oil cavities in Pterodon pubescens (Leguminosae-Papilionoideae)

Pterodon pubescens cavities are constituted by lumen and uniseriated epithelium surrounded by multiseriate parenchyma sheath. We studied the development of secretory cavities, including the role of parenchyma sheath, using light and transmission electron microscopy. A Tunel assay was performed to verify whether programmed cell death (PCD) occurs during the process. The lumen is formed by schizogeny and lysigeny occur in later developmental stages of the secretory cavities. Ultrastructurally, epithelial cells in later developmental stages become dark and with sinuous walls; the protoplast becomes retracted and the cytoplasm shows low organelle definition. Degenerated cells are released toward the lumen. Our results showed that PCD occurs during later developmental stages of cavities and plays a critical role in functioning of these glands. New cells originated from the parenchyma sheath differentiate into secretory cells and replace those degenerated ones. This fact associated to PCD guarantees epithelium renovation during the secretory cycle and the maintenance of secretory activity of cavities.