大豆根瘤侵染细胞中一种细胞质内含物的电镜观察

在中国丰收11号大豆根瘤侵染细胞中,我们发现了一种电子密度很高,体积很大,形状为圆形或近似圆形,外面没有界膜,常位于胞间隙附近的特殊的细胞质内含物。高尔基体及其小泡,丰富的粗糙型内质网和核糖体常在它的附近,其中一些核糖体正沉积在它的表面。它主要是由核糖体凝聚而成,高尔基体和内质网在它的形成中也起了一定作用。它的内部含有颗粒状,纤维状,泡状和管状物质。它的出现似乎与侵染细胞固氮有关。     

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。     

沙冬青叶肉细胞中一种特殊内含物的发育

用透射电镜观察了沙冬青（Ａｍ ｍ ｏｐｉｐｔａｎｔｈｕｓｍ ｏｎｇｏｌｉｃｕｓ）叶肉细胞中一种电子密度很高的近似椭圆形的特殊内含物的发育． 它始于中央液泡外侧,起初只是少量的泡状成分和电子密度很高的物质,然后两种成分逐渐增多,并随液泡膜内吞形成突起,不断伸向液泡中央,有的突起占据了液泡很大一部分体积． 接着突起中的泡状成分开始解体,电子密度很高的物质越来越多,直至充满整个突起． 当突起继续内伸时,它的尾部不断收缩变小,最后完全脱离液泡膜而游离在中央液泡里面． 这种内含物一般只出现在严冬季节,里面含有大量的脂．     

多泡体形成过程的细胞化学研究

本实验用酶细胞化学和示踪细胞化学方法观察了睾丸间质细胞中多泡体的形成过程及其与溶酶体的关系。实验结果表明,睾丸间质细胞中多泡体的形成可分三个阶段:首先,一些含内吞物质的泡状结构进入高尔基体区域,与那里的小泡融合,形成内含少量小泡的前多泡体;然后,前多泡体互相融合,形成体积较大、基质电子密度低、内含小泡排列稀疏的低电子密度多泡体;最后,低电子密度多泡体通过表面长出微绒毛样结构并不断断裂的方式去除多余的界膜,形成体积较小、基质电子密度高、内含小泡排列紧密的高电子密度多泡体。因此,多泡体的形成既与内吞活动有关,又与高尔基体区域小泡有关。前多泡体和低电子密度多泡体不含溶酶体酶。在多泡体形成过程中,只有到高电子密度多泡体阶段,才与溶酶体发生关系,从溶酶体中获取溶酶体酶。多泡体形成后,常与自体吞噬泡靠近,可能参与睾丸间质细胞的自体吞噬活动。     

缺氧状态下绿豆(Phaseolus radiatus L.)根部细胞内高尔基体的形态变化(英文)

用铀—铅—铜浸染技术处理样品后,通过透射电子显微镜观察绿豆根部细胞内高尔基体。在缺氧3d,5d和5d后转入供氧条件3d后根部细胞的超微结构变化表明,缺氧3d高尔基体的内质网的液泡仍能生成分泌泡,这种分泌泡不能排出到细胞外,而滞留于细胞质中;缺氧5d的高尔基体则不能形成分泌泡,而分泌物积累于内质网的液泡,使内质网的液泡膨大。当缺氧条件解除3d后,高尔基体的形态和功能基本恢复到正常状态。Russell(1973)证明,培养液缺氧能阻碍植株根部生长。Mollenhauer和Morre(1980)观察到细胞壁和膜的增殖有赖于高尔基体形成的分泌泡。本试验表明:由于缺氧引起高尔基体分泌泡形成和转运受阻,看来可能是它阻碍植株根部生长的主要原因之一。     

受体介导式入胞的分子机理(2)

早期内体除了接受来自细胞膜的囊泡之外,还接受来自高尔基体和晚期内体的囊泡,并且将内体中的物质以囊泡的形式重新分配到细胞膜、高尔基体和晚期内体(如图1,见本刊第11期第13页),这种重新分配也称分选。例如,细胞膜上的脂质和膜蛋白能够被早期内体分选,一部分回到胞膜重新利用,另一部分被转运到溶酶体降解。     

高尔基体的结构与功能(一)

1898年,意火利人 Camillo Golgi 用银盐浸染法在神经细胞内看到一种网状结构,命名为内网器。后来发现很多细胞都具有这种结构,就称它为高尔基体或高尔基器(Golgiapparatus)。由于高尔基体的折射率与周围细胞基质相近,因此在活细胞中不易看到这种结构,在普通染色的片子上也很难看到它,导至有人认为高尔基体不是一种真实结构,而是人为假象。直至电子显微镜的出现才证实了高尔基体是普遍存在于细胞中的一种细胞器。随着对     

受体介导式入胞的分子机理(1)

受体介导式入胞是一种与细胞膜受体有关的入胞过程。这一过程可概括为：1)膜受体识别介质中的特异性配体并与之结合,形成受体一配体复合物;2)该复合物在细胞膜中横向移动．逐渐向膜表面的衣被凹陷处集中,衣被凹陷是细胞膜上一个特殊的区域,其胞质侧富含网格蛋白;3)衣被凹陷进一步向胞质侧凹入,并最终与细胞膜脱离,在胞内形成一个囊泡,称衣被囊泡。衣被囊泡的形成过程称内移(internalization)：4)衣被囊泡与胞浆中的内体融合,内体可以发出和接受囊泡,与细胞膜、高尔基体和溶酶体有着广泛的交通往来．并通过内体的周转实现膜受体的循环利用和胞内物质的转运(如图1);5)内体与溶酶体融合,内容物被降解,受体与配体分离,配体进入胞内．膜受体回到胞膜。对于这样一个复杂的过程,人们的认识水平正不断深入,仅就受体介导式入胞各个环节的分子机理作一综述。     

日本鬼鲉背鳍棘毒腺中Ⅰ、Ⅱ型毒腺细胞关系的探讨

日本鬼背鳍棘毒腺中有两种类型毒腺细胞———Ⅰ型细胞和Ⅱ型细胞。两种细胞结构明显不同。本文用形态学方法探讨Ⅰ型与Ⅱ型细胞的关系。结果表明 :毒腺组织中Ⅰ型细胞光镜下有的胞质内可见浅染点样结构 ,并且在不同的细胞内其浅染点状结构的多少有差异 ;电镜下Ⅰ型细胞膜结构差异较大 ,有的Ⅰ型细胞的脂质双层膜性结构清楚 ;有的细胞膜外侧可见膜包小泡 ;有的细胞内侧面也见小泡形成、融合 ,使脂质双层膜间隙变宽 ,其内可见膜包样物质 ,其电子密度中等或较高 ,结构类似于Ⅱ型细胞的囊泡样物质。不同的Ⅱ型细胞其胞质内颗粒大小及电子密度不一 ,囊泡状物多少也不一。含较小而密集颗粒的Ⅱ型细胞胞膜的脂质双层膜的外侧面较规则 ,与Ⅰ型细胞相似 ;脂质双层膜的内侧面出现许多扩张的大囊泡 ,其内含物电子密度高或中等 ,与胞质内含的颗粒状物质相同 ;位于扩张的囊泡与胞膜之间的胞质结构有的与I型细胞的胞质内的某些结构相似。含大而稀疏颗粒的Ⅱ型细胞其颗粒数量少、电子密度差异大 ,并且囊泡样物质增多。推测Ⅱ型细胞可能由Ⅰ型细胞转化而来     

细鳞鱼卵子发生过程中细胞器的形态变化与作用

通过组织学方法和透射电镜技术对细鳞鱼(Brachymystax lenok)卵子发生过程中细胞器的变化与作用进行了研究.结果表明,从刚分化的卵原细胞至成熟卵母细胞时期(Ⅰ～Ⅴ时相)胞质内均能观察到线粒体,其形态最初为圆形,随着其大量增殖,形态变为棒状、弯曲状或长形(Ⅱ时相),并导致线粒体簇形成,其嵴也由单个变为多个,电子密度呈由低到高的规律变化;但到Ⅲ时相末期线粒体又退化为圆形,个别线粒体还通过对分或牙分进行裂变,线粒体嵴被不断释放,形成空泡,其基质电子密度呈降低的规律变化;在此过程中线粒体主要参与各种囊泡的形成,为后期卵黄前体物质进入、积累创造条件.在Ⅱ时相卵母细胞早期的细胞核附近开始出现内质网和高尔基体,但数量少,结构简单,随着它们的大量增殖(Ⅲ～Ⅳ时相),这两种细胞器将对卵黄物质的合成与加工起到关键作用.内质网主要呈弓形,少数呈圆形或杯形,早期与高尔基体相伴出现,但随着内质网大量增殖,其合成功能也随之增强.早期高尔基体也呈弓形,但随着其高度发育,几个分散的高尔基体聚集形成高度发育的高尔基体复合体,其加工与修饰功能也不断增强,同时其周围伴有大量潴泡或电子密度不同的囊泡体(多层结构)出现,且这些多泡体常常与环形片层(annulate lamellae,AL)一同出现.AL与核膜结构相似,早期呈弧形排列,本研究推测环形片层起源于核膜,其主要作用可能是膜的储藏地.     

ELECTRON MICROSCOPIC RADIOAUTOGRAPHY OF THIN SECTIONS: THE GOLGI ZONE AS A SITE OF PROTEIN CONCENTRATION IN PANCREATIC ACINAR CELLS

Electron microscopic radioautographs of guinea pig pancreatic exocrine cells were obtained by covering thin sections (~ 600 A) of OsO₄-fixed, methacrylate-embedded tissue with thin layers of Ilford K-5 nuclear research emulsion. After an exposure of 13 days at 4°C., the preparations were photographically processed, stained with uranyl acetate, and examined in an electron microscope. The label used was leucine-H³ injected intravenously 20 minutes before collection of the specimens. Conventional radioautographs of thicker sections (0.4 micron) were also examined in a phase contrast microscope. The advantages obtained from electron microscopic radioautography are: the higher radioautographic resolution (of the order of 0.3 micron) due to the thinness of the emulsion and the specimen, and a high optical resolution permitting a clear identification of the labeled structure. In the guinea pig pancreas this technique demonstrated that, at the time studied, newly synthesized proteins were concentrated in the structures of the Golgi complex and especially in large vacuoles partially filled with a dense material. The vacuoles are probably a precursor to the secretion granules (zymogen granules) in which the label becomes segregated at a later time. These observations demonstrate directly the role of the Golgi complex in the secretion process. They also illustrate the possibilities of this method for radioautography at the intracellular level.     

The classic Golgi apparatus and vacuoles

The dense vacuoles, considered to be the classic Golgi apparatus in the root meristem ofFagopyrum, were studied by the following methods: 1. Impregnation methods for the demonstration of the Golgi apparatus, 2. cytochemical methods, 3. electron microscopic methods in the light microscope and 4. the electron microscope. A comparison was made with the classic Golgi apparatus in animal cells in the light and electron microscope. Dense vacuoles inFagopyrum and also evidently in other plants, were taken for the classic Golgi apparatus on account of their morphological similarity to the Golgi apparatus in animal cells on impregnation with silver and osmium and their staining preperties with lipoid methods. Dense vacuoles differ from the classic Golgi apparatus in other chemical properties, such as content of phenol substances, etc. No formations were found in animal cells which were similar to dense vacuoles on investigating by electron microscopy. In the electron microscope dense vacuoles have the appearance of derivatives of the normal light vacuoles known in plant cells. They therefore belong to vacuome of plant cell and cannot be analogous to the classic Golgi apparatus in animal cells. Thus the use of the term Golgi apparatus for dense vacuoles is not well founded. A comparison was made of fixation and impregnation used in the light microscope with fixation in the electron microscope. After fixation with permanganate, dense vacuoles have the same shape as after impregnation. After fixation with permanganate, they stain an intense black in the same way as after impregnation with silver and osmium. The form of the vacuoles is dependent on the fixation used. The comparison was made in the light microscope.     

LYSOSOMES AND GERL IN NORMAL AND CHROMATOLYTIC NEURONS OF THE RAT GANGLION NODOSUM

The rat ganglion nodosum was used to study chromatolysis following axon section. After fixation by aldehyde perfusion, frozen sections were incubated for enzyme activities used as markers for cytoplasmic organelles as follows: acid phosphatase for lysosomes and GERL (a Golgi-related region of smooth endoplasmic reticulum from which lysosomes appear to develop) (31–33); inosine diphosphatase for endoplasmic reticulum and Golgi apparatus; thiamine pyrophosphatase for Golgi apparatus; acetycholinesterase for Nissl substance (endoplasmic reticulum); NADH-tetra-Nitro BT reductase for mitochondria. All but the mitochondrial enzyme were studied by electron microscopy as well as light microscopy. In chromatolytic perikarya there occur disruption of the rough endoplasmic reticulum in the center of the cell and segregation of the remainder to the cell periphery. Golgi apparatus, GERL, mitochondria and lysosomes accumulate in the central region of the cell. GERL is prominent in both normal and operated perikarya. Electron microscopic images suggest that its smooth endoplasmic reticulum produces a variety of lysosomes in several ways: (a) coated vesicles that separate from the reticulum; (b) dense bodies that arise from focal areas dilated with granular or membranous material; (c) "multivesicular bodies" in which vesicles and other material are sequestered; (d) autophagic vacuoles containing endoplasmic reticulum and ribosomes, presumably derived from the Nissl material, and mitochondria. The number of autophagic vacuoles increases following operation.     

THE GOLGI APPARATUS IN NEURONS AND EPITHELIAL CELLS OF THE COMMON LIMPET PATELLA VULGATA

1. In view of widely diverse views held about the identity and structure of the Golgi apparatus in neurons of Mollusca, particularly gastropods, a study has been made on neurons of the common limpet, Patella vulgata, both by light and electron microscopy. A report is given also of observations made on epithelial cells of Patella by electron microscopy. 2. As revealed by Kolatchev's method, the Golgi apparatus in neurons consists basically of black filaments lying to one side of the nucleus. The filaments generally anastomose to form networks of various complexity. Rarely some cells contain only discrete filaments. Associated with some of the filaments is a weakly osmiophilic substance identified as archoplasm. Kolatchev's method also revealed spheroidal bodies (neutral red bodies, "lipochondria," etc.). 3. It has not been possible to demonstrate the Golgi apparatus using either iron-haematoxylin or Sudan black. 4. Examination of Kolatchev's preparations by electron microscopy has revealed that some of the Golgi filaments consist of chromophilic and chromophobic components. The chromophilic component consists of dense lamellae. 5. After fixation in buffered osmium tetroxide solution and examination by electron microscopy, it has been concluded that (a) the chromophilic component of the Golgi apparatus corresponds to a system of paired membranes (which usually enclose an inner dense substance), (b) the chromophobic component corresponds to a substance lying within small dilations of the paired membrane, and (c) the archoplasm corresponds to numerous small vesicles. 6. The paired membranes branch, anastomose, and can often be traced back to a common source. They are interpreted as lamelliform folds, and occasionally tubular processes, of essentially a single Golgi membrane. In cells containing a Golgi network it is suggested that the membrane extends through the whole of the apparatus in such a way that the substance it encloses may be regarded as being in a continuous phase. 7. Epithelial cells of Patella contain a juxtanuclear Golgi apparatus with an ultrastructure similar to that described for neurons.     

OSMIUM STAINING OF ENDOPLASMIC RETICULUM AND MITOCHONDRIA IN THE RAT ADRENAL CORTEX

The zona fasciculata of the rat adrenal cortex synthesizes and secretes glucocorticoids. As observed after aldehyde fixation, the cells in this zone contain an extensive endoplasmic reticulum (ER), a small Golgi apparatus, a moderate number of lipid droplets, and abundant mitochondria with tubulovesicular cristae. Numerous areas within the endoplasmic reticulum and mitochondrial cristae appear clear. In addition, a small percentage of mitochondria encompasses large, clear areas. After immersion of finely minced adrenal cortex in unbuffered 2% OsO₄ (40–48 hr at 40°C), deposits of osmium are seen within the Golgi apparatus, the entirety of the ER, and occasionally within mitochondria. In some mitochondria, the deposits are within cristae; in others, within vacuoles; in still others, in both cristae and vacuoles. These localizations correspond best to the clear areas found in aldehyde-fixed tissue. Osmium is not deposited in lipid droplets, in bar-containing inclusions, in mitochondrial matrix inclusions, or in the peripheral, outer mitochondrial spaces. Addition of zinc-iodide to OsO₄ increases the amount of Golgi apparatus and mitochondrial staining. Adrenocorticotropin (ACTH) does not affect the localization of deposits; hypophysectomy decreases mitochondrial staining. This study (a) emphasizes the necessity for electron microscopic confirmation of osmium localization when this technique is used as a Golgi apparatus stain; and (b) suggests that the ER-staining pattern may be consistent in cells actively synthesizing steroids or steroid-like compounds.     

STUDIES ON THE FINE STRUCTURE OF THE MAMMALIAN TESTIS : I. DIFFERENTIATION OF THE SPERMATIDS IN THE CAT (FELIS DOMESTICA)

The differentiation of cat spermatids was studied in thin sections examined with the electron microscope. The Golgi complex of the spermatid consists of a central aggregation of minute vacuoles, partially surrounded by a lamellar arrangement of flattened vesicles. In the formation of the acrosome, one or more moderately dense homogeneous granules arise within vacuoles of the Golgi complex. The coalescence of these vacuoles and their contained granules gives rise to a single acrosomal granule within a sizable membrane-limited vacuole, termed the acrosomal vesicle. This adheres to the nuclear membrane and later becomes closely applied to the anterior two-thirds of the elongating nucleus to form a closed bilaminar head cap. The substance of the acrosomal granule occupies the narrow cleft between the membranous layers of the cap. The caudal sheath is comprised of many straight filaments extending backward from a ring which encircles the nucleus at the posterior margin of the head cap. Attention is directed to the frequent occurrence of pairs of spermatids joined by a protoplasmic bridge and the origin and possible significance of this relationship are discussed.     

LOCALIZATION OF ACID PHOSPHATASE IN LIPOFUSCIN GRANULES AND POSSIBLE AUTOPHAGIC VACUOLES IN INTERSTITIAL CELLS OF THE GUINEA PIG TESTIS

The intracellular localization of acid phosphatase in guinea pig testicular interstitial cells was investigated by incubating nonfrozen thick sections of glutaraldehyde-perfused testis in a modified Gomori medium and preparing the tissue for electron microscopy. Lipofuscin pigment granules in these cells contain dense pigment, granular matrix, and often a lipid droplet. Reaction product is seen in the matrix of the pigment granules, and they may therefore be called residual bodies. At least some of the dense pigment appears to be derived from myelin figures and membrane whorls, since suitable intermediates can be seen. Lipid droplets found free in the cytoplasm are another possible source of pigment. In both cases the chemical mechanism is presumed to be autoxidation of unsaturated lipid. Acid phosphatase is present in the inner cisterna of Golgi elements. Enzyme activity also appears in possible autophagic vacuoles bounded by double membranes; the reaction product lies between the membranes. Consideration of the enzyme as a tracer suggests that the autophagic vacuoles are derived from the Golgi complex. Possible stages in the formation of these vacuoles by the inner Golgi cisternae are observed.     

ON THE SITE OF SULFATION IN THE CHONDROCYTE

As observed autoradiographically in the cartilage of embryonic rats, radiosulfate is bound and concentrated only in vesicles of the juxtanuclear Golgi apparatus of secreting chondrocytes within 3 minutes of its presentation. From this area, vacuoles migrate peripherally and lodge in the subcortex; their sulfated contents are thence discharged via stomata to the extracellular matrix. The label, apparently often associated with microvesicles at 10 and 20 minutes, is subsequently localized in the dense contents of the larger vacuoles. Bound radiosulfate is not detectable in other organelles. It is concluded that the vesicular component of the Golgi apparatus is the actual site of sulfation. Intracellular hyaluronidase-sensitive metachromatic granules are found chiefly at the cell periphery or mantle, rarely juxtanuclear in the main Golgi zone.     

The electron microscopic and classic Golgi apparatus

The relationship of the membrane structure, designated in electron microscopy as the Golgi apparatus, to the classic Golgi apparatus in the light microscope were studied withFagopyrum. Comparison of these structures in plant cells with the same or similar structures in animal cells led to the following conclusions: there exist two groups of formations, impregnable with osmium or silver, considered as the classic Golgi apparatus. The first group contains the active membrane structures. These are the dictyosomes and the anastomosing form of the electron microscopic Golgi apparatus. To this group belongs also the endoplasmatic reticulum, which in plant cells forms dense vacuoles, having the appearance of the classic Golgi apparatus, and in animal cells occasionally has a similar arrangement as the anastomosing form of the Golgi apparatus. The second group comprises formation containing reserve and secretion material, i.e. predominantly products of the activity of the electron microscopic Golgi apparatus and of the endoplasmic reticulum (matter of the dense vacuoles, lipochondria, secretory granula etc.). In the plant cells, especially ofFygopyrum, the dictyosomes contained in the structures of the first group are separated from the formations of a reserve character in the second group, formed in the lumen of the endoplasmic reticulum (dense vacuoles). The identity of the dictyosomes with the osmiophilic platelets, considered by some authors in the light microscope as the classic Golgi apparatus, has not been proved up to present, because of the one-sidedness of the methods used nowadays. WithFagopyrum no foundation has been observed for the assumed formation of net-form structures by grouping of the dictyosomes. Structures similar to the net-form of the classic Golgi apparatus in the animal cell form only dense vacuoles. On the basis of the differentiation of both types of formations in the plant cell, the foundations were laid for the characterization of the classic Golgi apparatus in the animal cell. The net-form of the classic Golgi apparatus in the animal cell is obviously not artificial, but reflects the ultrastructural arrangement of the electron microscopic Golgi apparatus or of the endoplasmic reticulum. The problem of the suitability and specification of the name Golgi apparatus in the animal and plant cell was also discussed. In contrast to the opinion of some authors, it does not appear useful to remove the name golgi apparatus, designating the dictyosomes and the anastomosing forms of the smooth membranes.     

The distribution of oxidizable mucosubstances and polysaccharides in the planarian Polycelis tenuis iijima

A chromic acid oxidation-silver technique was used to localize polysaccharide material in Polycelis tenuis at the electron microscope level. In the epithelium, staining was observed within apical vacuoles and on the free surfaces of the cells. A similar staining was observed in relation to the glycocalyx of the pharyngeal epithelia and that of the flame cells. Silver was deposited in the basement membrane. In the parenchyma, the major components giving a positive reaction were the cyanophil and mucous gland cells. Particularly strong silver staining (confirmed by X-ray microanalysis) was observed in the granules and Golgi apparatus of the cyanophil cells. IDPase activity was also found in relation to the Golgi apparatus and its secretory products. The overall distribution of mucopolysaccharide material was confirmed with the PAS and Alcian blue techniques. The fine structural localization of the Alcian blue was also determined using electron microscopy and X-ray microanalysis.