侵染细胞质膜附近小泡的来源及其作用

箭舌豌豆根瘤幼龄侵染细胞的壁和质膜比较光滑,成熟侵染细胞与此不同,不仅细胞壁厚薄均,有较多的胞间连丝,而且质膜常常内陷形成各种突起,然后离质膜形成小泡。这些位于质膜附近的小泡体积较小,多呈圆形,既可单独存在,也可多个聚在一起。在向细胞中央移动中,有的小泡靠近细胞质膜,甚至与细菌周期融合,有的小泡不民附近的小液泡融合变为较大液泡,并常用降解程度不同的细菌位于其中,在衰老侵染细胞中,细胞壁附近有小泡,     

在分化条件下甜菊愈伤组织分生区细胞超微结构研究

对甜菊（Ｓｔｅｖｉａｒｅｂａｕｄｉａｎａ）愈伤组织中尚未发生器官分化的分生细胞团进行了超微结构研究．结果表明,在器官分化条件下,愈伤组织中形成的分生区域的细胞体积小,细胞核大,核仁明显,且具核仁泡,部分细胞核中含有核内含物．大量小液泡分布在细胞的边周或散布于整个细胞中．液泡中通常含有陷入的细胞质成分和膜状物．部分液泡的形成与内质网膨大有密切关系．同时也观察到由内质网形成的多圈膜和双层膜包围细胞质成分的同心环结构．高尔基体及其小泡丰富,有时聚集分布在细胞某一区域．核糖体密集,有的聚集成多聚核糖体．因此,愈伤组织中分生区的细胞与分生组织中的液泡化和分裂的细胞类似．分生区细胞的另一明显特征是出现质膜内陷．推测这些超微结构特征可能反映了甜菊愈伤组织器官分化前的某些形态变化。     

知母绒毡层和乌氏体细微结构的研究

从个体发育来看,知母绒毡层具有3个明显的特点;（1）在小孢子母细胞阶段,绒毡层细胞中有丰富的细胞器,如粗糙内质网,脂体,造粉体和小泡等,粗糙内质网－脂体－小泡常常联系在一起,形成细胞器复合体。（2）在单核花粉阶段,绒毡层细胞质中出现大量小泡,它们可以融合成小泡,而且在小泡或大泡中开始沉积与脂体电子密度相似的亲锇物质,这些物质或者充满整个小泡,或者沉积在小泡周缘,此刻,也是乌氏体形成并达到高峰的阶段。（3）在成熟花粉阶段,绒毯层细胞几乎被具膜束缚的小型脂粒和巨型脂体所占据,这些亲锇物质是质体起源的,也许它们是花粉鞘的先质。     

知母绒毡层和乌氏体细微结构的研究

从个体发育来看,知母绒毡层具有3个明显的特点;（1）在小孢子母细胞阶段,绒毡层细胞中有丰富的细胞器,如粗糙内质网,脂体,造粉体和小泡等,粗糙内质网－脂体－小泡常常联系在一起,形成细胞器复合体。（2）在单核花粉阶段,绒毡层细胞质中出现大量小泡,它们可以融合成小泡,而且在小泡或大泡中开始沉积与脂体电子密度相似的亲锇物质,这些物质或者充满整个小泡,或者沉积在小泡周缘,此刻,也是乌氏体形成并达到高峰的阶段。（3）在成熟花粉阶段,绒毯层细胞几乎被具膜束缚的小型脂粒和巨型脂体所占据,这些亲锇物质是质体起源的,也许它们是花粉鞘的先质。     

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。     

鹅掌楸属植物的多糖壁前体和花粉管的生长

本文观察描述了中国鹅掌楸（Ｌｉｒｉｏｄｅｎｄｒｏｎｃｈｉｎｅｎｓｅ）和北美鹅掌楸（Ｌ．ｔｕｌｉｐｉｆｅｒａ）花粉在异已柱头萌发和花粉管生长期间多糖壁前体的发生、形态结构和生理功能．１、多糖壁前体在形态上有Ｐ－粒子（Ｐｏｌｙｓａｃｃｈａｒｉｄｅｐａｒｔｉｃｌｅｓ）,被膜小泡（ｃｏａｔｅｄｖｅｓｉｃｌｅ）和小泡（ｖｅｓｉｃｌｅ）三种。２、Ｐ－粒子于单核花粉期已经发生,至花粉管延伸期为发生高峰。多糖壁前体是在高尔基体,内质网和线粒体的相继、连续作用下,由淀粉质体、蛋白体和脂滴降解形成．３、Ｐ－粒子的形态随不同发育时期而变化,早期为成群的电子透明小泡,或为蛋白质束缚的挤压成多面体形,后期为内含颗粒或微纤丝的无被膜粒子或具刺被膜粒子。４、Ｐ－粒子移至管端．或融合或单个通过周质内质网（ＣＥＲ）,释放内容物参与管端壁的形成,被膜小池和小泡移至花粉管次顶端区向质膜外分泌,参与花粉管壁内层的形成,或移至管端,提供膜片。最后讨论了亲和性与超微结构特征的关系．     

天麻大型细胞消化蜜环菌过程中溶酶体小泡的作用

蜜环菌(Armillaria mellea Fr.)菌丝由天麻(Gastrodia elata Bl.)皮层细胞经纹孔侵入大型细胞。初期大型细胞的原生质膜凹陷,同时细胞壁产生乳突状加厚阻止菌丝侵入。当菌丝侵入大型细胞以后,凹陷的质膜将菌丝紧密包围,大量由单位膜围成的小泡聚集在其周围。随后这些小泡的膜与质膜融合并将其内含物释放到菌丝周围的空间中,凹陷质膜逐渐膨大成为一个包围菌丝的消化泡。小泡和消化泡中均具酸性磷酸酶活性反应产物,证实其分别相当于植物溶酶体系统中的初级和次级溶酶体。菌丝在消化泡中被彻底消化。     

墨兰菌根的结构及酸性磷酸酶定位研究

利用光学显微镜、电子显微镜及细胞化学方法,对墨兰菌根的结构和酸性磷酸酶定位进行了初步研究。结果表明墨兰具有典型的兰科植物根结构,发现该兰花的根的外皮层不具薄壁通道细胞,菌根真菌通过破坏部分根被和外皮层细胞而侵入根的皮层细胞并在细胞内形成菌丝结,侵入的菌丝被染菌皮层细胞质膜和电子透明物质包围,进一步被消化并聚集成衰败菌丝团块。酸性磷酸酶在染菌皮层细胞及包围菌丝的皮层细胞质膜和衰败菌丝细胞壁上有强烈的酶反应,衰败菌丝周围分布有许多单层膜的含酶小泡,它们可相互愈合形成大的含酶泡或与包围菌丝的质膜融合,类似于兰科植物共生原球茎中观察到的现象。说明皮层细胞可主动释放水解酶参与对菌丝的消化     

冬季沙冬青叶肉细胞液泡中泡状内含物的研究

用透射电镜观察了沙冬青叶肉细胞液泡中泡状内含物的形成。在早期,这种泡状内含物位于细胞质中,它由大小不等、形态各异的小泡组成,后经液泡膜内吞进入液泡。液泡中的泡状内含物主要位于两个正常叶绿体之间,附近的细胞质较多,内有丰富的内质网、高尔基体、质膜管状突起和由它们产生的小泡。也有一些液泡泡状内含物出现在解体叶绿体附近。前者主要来自内质网、高尔基体和质膜,后者则主要起源于解体的叶绿体。这种泡状内含物的形成可能与增强植物的抗冻性有关。     

木立芦荟叶内芦荟素的超微细胞化学研究

使用醋酸铅溶液对木立芦荟叶的药用成分芦荟素进行细胞化学定位,在透射电镜下探讨芦荟素产生、转运和贮藏的过程。结果表明:芦荟素由同化薄壁组织产生,质体的类囊体为其合成部位。通过质体膜形成的小泡转移到周围的内质网,以后内质网小泡与质膜融合:或质体小泡直接与质膜融合。通过胞吐作用将芦荟素释放到质膜外,经质外体途径到达维管束的鞘细胞。在鞘细胞中, 芦荟素经内质网小泡转移至内切向壁,由胞间连丝运输到芦荟素细胞的细胞质,最终贮藏在芦荟素细胞的液泡中。     

Ultrastructure of Aerial Hyphae in Linderina pennispora

Ultrathin sections of the aerial hyphae of Linderina pennispora,fixed in glutaraldehyde, show the wall to be composed of anouter electron-dense layer and an inner less-dense one. Thefully developed septum is plugged by electrondense material.A similar septum exists at the base of the pseudophialide. Cytoplasmiccontinuity on both sides of the septum is maintained by theplasmalemma which passes through the septal pore around theperiphery of the plug. Membrane-lined vesicles may occur inthe wall, between the wall and the plasmalemma and internalto the plasmalemma. Ribosome-like particles are numerous inthe cytoplasm and endoplasmic reticulum is virtually absent.     

Plasmalemmasomes and lomasomes in Candida albicans

Candida albicans possesses plasmalemmasomes and lomasomes whose origin, structure and distribution are described. It is suggested that plasmalemmasomes become lomasomes during cell wall synthesis. The endoplasmic reticulum and lomasomes may be regarded as the functional equivalent to the Golgi apparatus in C. albicans and this view is discussed.     

毛竹茎纤维次生壁形成过程的超微结构观察

利用透射电镜观察了毛竹（Ｐｈｙｌｌｏｓｔａｃｈｙｓ ｐｕｂｅｓｃｅｎｓ Ｍａｚｅｌ）茎纤维发育过程中次生壁的形成过程。纤维发育早期,细胞具有较大的细胞核和核仁;细胞质浓稠,具有核糖体、线粒体和高尔基体等细胞器。随着纤维次生壁的形成,细胞壁加厚,细胞质变得稀薄,内质网和高尔基体的数量明显增加,并且两者共同参与了运输小泡的形成;在质膜内侧可观察到大量周质微管分布。随着次生壁的进一步加厚及木质化,细胞壁     

Ultrastructural Study of Secondary Wall Formation in the Stem Fiber of Phyllostachys pubescens

Ultrastructural changes in secondary wall formation of Phyllostachys pubescens Mazel fiber were investigated with transmission electron microscopy. Fiber developed initially with the elongation of cells containing ribosomes, mitochondria and Golgi bodies in the dense cytoplasm. During the wall thickening, the number of rough endoplasmic reticulum and Golgi bodies increased apparently. There were two kinds of Golgi vesicles, together with the ones from endoplasmic reticulum formed transport vesicles. Many microtubules were arranged parallel to the long axis of the cell adjacent to the plasmalemma. Along with the further development of fiber, polylamellate structure of the secondary wall appeared, with concurrent agglutination of chromatin in the nucleus, swelling and disintegration of organelles, while cortical microtubules were still arranged neatly against the inner side of plasmalemma. Lomasomes could be observed between the wall and plasmalemma. The results indicated that the organelles, such as Golgi bodies together with small vesicles, rough endoplasmic reticulum and lomasomes, played the key role in the thickening and lignification of the secondary wall of bamboo fiber, though cortical microtubules were correlative with the process as well.     

蜜环菌成熟菌索的超微结构

用光学和电子显徽镜研究了生长在木材上的蜜环菌成熟菌索的超微结构。拟薄壁组织中有线粒体、内质网、核、液泡、质膜体、核糖体和典型的桶孔隔膜等。在菌索腔中疏松组织由薄壁菌丝、厚壁菌丝和非细胞衬质物质所组成,这些菌丝除了无隔孔帽的隔孔器和分散的核仁以外,见不到其它普通的细胞器,其最明显的特征是质壁分离和质膜断裂而卷曲,似乎是处在脱水状态。一旦它们进入新的寄主,一些普通细胞器就可出现。所以,可认为这些菌丝是处于休眠状态。对蜜环菌菌索的结构和功能的关系也进行了讨论。     

ONTOGENY AND CYTOCHEMISTRY OF ALKALOIDAL VESICLES IN LATICIFERS OF PAPAVER SOMNIFERUM L. (PAPAVERACEAE)

Development of alkaloidal vesicles in laticifers of opium poppy, Papaver somniferum L., was investigated at the ultrastructural level. Laticifer initials possessed abundant endoplasmic reticulum throughout their dense cytoplasm. During differentiation the endoplasmic reticulum organized into long, folded sheets that were parallel to the longitudinal walls along the periphery of the cell. Vesicles appeared to be derived from dilation of endoplasmic reticulum. This relationship was confirmed through cytochemical data obtained with zinc iodide-osmium tetroxide and osmium tetroxide impregnation. Alkaloidal vesicles had electron-dense regions or caps that occurred early in laticifer differentiation, but these caps became less conspicuous in mature cells. Caps appeared to be derived from small particles which condensed along the inner surface of the vesicle membrane and subsequently accumulated at one or two positions along the membrane of the vesicle.     

Lomasomes and plasmalemmasomes in fungi

Summary Electron microscope observations of fungal hyphae and yeast-like cells, using conventional fixation methods and freeze-etching, demonstrate that plasmalemmasomes are not fixation artifacts. The small invaginations of the plasmalemma observed in aldehyde-fixed preparations are also present in frozen-etched samples. The morphology of plasmalemmasomes in the species examined is variable and ranges from vesicles or tubules within the plasmalemma invagination to parallel arrays of membrane lamellae. Plasmalemmasomes thus appear to be primarily excess plasma membrane that has accumulated, perforce, endocellularly. Lomasomes, in contrast, appear to be accumulations of ejected material between the plasmalemma and cell wall that have become sequestered by the deposition of wall material.     

Ultrastructure ofAspergillus nidulans conidia and conidial lomasomes

Summary Lomasomes in the conidia ofAspergillus nidulans can be divided into at least two distinct structures. The first is a twice double membrane bound core of cytoplasmic origin. The outermost membrane of the lomasome becomes incorporated into the plasmalemma as it migrates to rest next to the cell wall. The second lomasome structure appears to be a triangle shaped series of tubules arranged in a parallel fashion. The wide end next to the cell wall connected to the plasmalemma and the opposite end to an element of the endoplasmic reticulum. The term membranosome has been coined to designate this lomasome structure with its function of plasmalemma extension. Various structures of the conidium such as wall, endoplasmic reticulum and the cytoplasmic matrix undergo changes from the conidial chain stage to the free or resting conidial stage. This suggests that after conidiation and before the resting stage, the conidium continues to mature.     

ENZYMO-CYTOCHEMICAL OBSERVATIONS ON THE CORTICAL CHANGE IN THE EGGS OF CYPRINUS CARPIO AND CARASSIUS AURATUS

Acid phosphatase (AcPase) and cholinesterase (ChE) activities were examined by ultracytochemical techniques in the mature unfertilized and the fertilized eggs of Cyprinus carpio and Carassitus auratus , to reveal the differences among three kinds of structures, cortical alveoli, CA- and CB-granules, which discharge their contents on fertilization into the perivitelline space. Deposits of the reaction product for AcPase activity are localized on the plasmalemma of unfertilized eggs, in the cortical alveoli, cytoplasmic matrix, lamellae of the Golgi apparatus and sometimes in multivesicular bodies but not in CA- and CB-granules, mitochondria, rough endoplasmic reticulum or on the plasmalemma of fertilized eggs. Deposits of the reaction product for ChE activity are localized on the inner surface of the plasmalemma, in the cytoplasmic matrix, in mitochondria and on a small number of tubular or cisternal membranes of the endoplasmic reticulum in mature unfertilized eggs, and on the outer surface of the limiting membrane of CB-granules and on membranous structures (possibly Golgi lamellae) associated with their formation, in fertilized eggs. The deposits on the plasmalemma rapidly disappear almost completely, with discharge of the cortical alveoli soon after fertilization, but they are again seen on the inner surface of the plasmalemma when emiocytotic discharge of the CB-granules begins about 10 min after fertilization.