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。     

大鼠睾丸间质细胞的自体吞噬活动

本文结合超微结构和细胞化学观察,研究大鼠睾丸间质细胞(Leydig细胞)中溶酶体的结??构与功能。观察结果表明,大鼠睾丸间质细胞中高尔基体非常发达,在高尔基体的成熟面存在着CMP酶阳性反应的GERL系统,说明这种细胞有不断产生溶酶体的能力。细胞化学结果也证实在睾丸间质细胞有较多的初级和次级溶酶体。睾丸间质细胞不仅有较多的溶酶体,而且还有相当数量的自噬小体,存在着活跃的自体吞噬活动。自噬小体的界膜来源于特化的光面内质网或高尔基体膜囊,包围的内容物主要是光面内质网和少量线粒体。当自噬小体与溶酶体融合后即成为自体吞噬泡,由于酶的消化作用,自体吞噬泡内的细胞器有一系列形态变化。根据CMP酶细胞化学反应,可以区分自噬小体和自体吞噬泡,后者是一种次级溶酶体,呈CMP酶阳性反应。睾丸间质细胞是分泌雄性激素的内分泌细胞,其光面内质网和线粒体在类固醇激素分泌中起重要作用,自体吞噬活动的结果是去除部分内质网和线粒体,可能在细胞水平上起着对雄性激素分泌的调节作用。     

STUDIES ON THE INTRACELLULAR DIGESTIVE PROCESS IN MAMMALIAN TISSUE CULTURE CELLS

DNA-protein coacervates containing colloidal gold particles were readily phagocytized by strain L fibroblasts. During the subsequent digestion process, the gold particles served as markers which permitted the demonstration of the evolution of digestive vacuoles to multivesicular bodies and finally to dense bodies. Acid phosphatase and esterolytic activity was present in these structures. The hydrolytic enzymes were apparently brought to the phagocytotic vacuoles in small vesicles originating in the Golgi region. These vesicles entered the vacuoles prior to the digestion of the coacervates and the appearance of positive cytochemical reactions. The cytoplasmic dense bodies frequently merged with the phagocytotic vacuoles. This was demonstrated by prelabeling the dense bodies with colloidal iron prior to phagocytosis of the coacervates. In addition, evidence is presented for the interrelationship of the phagocytotic and autophagic pathways.     

睾丸间质细胞—研究自体吞噬的一种正常细胞模型

In the present study, we tried to estimate, in a semiquantitative way, the relative frequency of the autophagic activity in various cell types under physiological condition. The results indicated that the highest activity appeared to be in the Leydig cells of rat testes. Autophagosomes were frequently observed in electron microscope photographs of Leydig cells, which provide a good model to study the autophagocytosis in normal cells. The autophagic process in Leydig cells was observed with the electron microscope in preparations treated to show CMPase activity. The mode of formation of autophagosomes in Leydig cells can be divided into three steps. Step 1, flattened membranous elements expand to enclose a small cytoplasmic territory to form pre-autophagosome. Step 2, The double membrane profile of the pre-autophagosome then completely encloses the cytoplasmic territory to form early autophagosome in which structurally normal organelles are contained. Step 3, the transformation of an early autophagosome into a late one is accompanied by the loss of one of the two delimiting membranes, the partial disintegration of the enclosed content and simultaneous acquisition of acid phosphatase activity. The enzymatic reactivity is acquired following a close association with the lysosomes. The late autophagosome then reaches the cell surface and appear to exocytose their residual content.     

Ultrastructural localization of acid phosphatase in cultured cells ofDaucus carota

Summary Acid phosphatase localization has been studied, using the lead salt method, in suspension-cultured cells of the wild carrot. Enzyme activity in most of the cells was restricted to the walls and vacuoles. However, in some senescent cells activity was also seen in the nucleus, at one face of the dictyosomes, and in nearby dictyosome-derived vesciles.The activity in the walls was closely associated with the central portion of the wall which ultimately disintegrates in auxin-containing media. However, the large vesicles which accumulate in this portion of the wall as it breaks down never showed acid phosphatase activity, nor did the multivesicular bodies which appear to transfer vesicular material into the wall space. Although multivesicular bodies in plant cells resemble the multivesicular lysosomes of animal cells, no evidence could be obtained in this study for the presence in such bodies of hydrolytic enzymes.     

Ultrastructure of Thraustochytrium sp. zoospores

Summary Acid phosphatase distribution in the biflagellate zoospores of a marine fungus Thraustochytrium, resembling T. motivum Goldstein, was examined utilizing ultrastructural cytochemistry. Acid phosphatase activity was found in the Golgi saccules, Golgi vesicles, multivesicular bodies, endoplasmic reticulum, and autophagic vacuoles.Extensive autolysis of cellular structures occurs in the zoospores. Organelles or portions of the cytoplasm are segregated from the rest of the cytoplasm by acid phosphatase-positive vesicles and lamellae. These vesicles and lamellae coalesce around a portion of cytoplasm forming an enclosing double membraned sac. One of the membranes, probably the inner, is disrupted, releasing the hydrolytic enzymes which initiate digestion of the enclosed cytoplasm. These cytolysomes eventually fuse with larger cytolysomes where digestion is presumably completed. The final fate of the digestive residues and the large cytolysomes has not been determined.Contribution No. 501, Virginia Institute of Marine Science, Gloucester Point, Virginia 23062, U.S.A.Supported in part by the Oceanographic Section, National Science Foundation, Grant # GA-31014, to Dr. Frank O. Perkins.     

睾丸间质细胞——研究自体吞噬的一种正常细胞模型

细胞在生理状态下自体吞噬出现的频率很低,很难用正常细胞来研究自体吞噬活动,一般都通过诱导自体吞噬来获得有关自体吞噬活动的资料。本实验观察了肝、肾、睾丸等组织的32种细胞,发现睾丸间质细胞中自体吞噬出现频率远远高于其他细胞,平均每100个细胞切面中可以看到25个自噬小体,从而为研究自体吞噬的过程和机理提供了一个正常细胞模型。本实验还观察到睾丸间质细胞的自体吞噬活动可分为前自噬小体、早期自噬小体和晚期自噬小体三个阶段,是一个连续的过程。前自噬小体和早期自噬小体不含溶酶体酶,只有在自噬小体与溶酶体接触后,才从后者获取溶酶体酶并将其内容物消化分解,成为晚期自噬小体。由自体吞噬所产生的残余体并不在睾丸间质细胞内积聚,而是通过胞吐作用排出细胞外。     

FUNCTIONS OF COATED VESICLES DURING PROTEIN ABSORPTION IN THE RAT VAS DEFERENS

The role of coated vesicles during the absorption of horseradish peroxidase was investigated in the epithelium of the rat vas deferens by electron microscopy and cytochemistry. Peroxidase was introduced into the vas lumen in vivo. Tissue was excised at selected intervals, fixed in formaldehyde-glutaraldehyde, sectioned without freezing, incubated in Karnovsky's medium, postfixed in OsO₄, and processed for electron microscopy. Some controls and peroxidase-perfused specimens were incubated with TPP,¹ GP, and CMP. Attention was focused on the Golgi complex, apical multivesicular bodies, and two populations of coated vesicles; large (> 1000 A) ones concentrated in the apical cytoplasm and small (<750 A) ones found primarily in the Golgi region. 10 min after peroxidase injection, the tracer is found adhering to the surface plasmalemma, concentrated in bristle-coated invaginations, and within large coated vesicles. After 20–45 min, it is present in large smooth vesicles, apical multivesicular bodies, and dense bodies. Peroxidase is not seen in small coated vesicles at any interval. Counts of small coated vesicles reveal that during peroxidase absorption they first increase in number in the Golgi region and later, in the apical cytoplasm. In both control and peroxidase-perfused specimens incubated with TPP, reaction product is seen in several Golgi cisternae and in small coated vesicles in the Golgi region. With GP, reaction product is seen in one to two Golgi cisternae, multivesicular bodies, dense bodies, and small coated vesicles present in the Golgi region or near multivesicular bodies. The results demonstrate that (a) this epithelium functions in the absorption of protein from the duct lumen, (b) large coated vesicles serve as heterophagosomes to transport absorbed protein to lysosomes, and (c) some small coated vesicles serve as primary lysosomes to transport hydrolytic enzymes from the Golgi complex to multivesicular bodies.     

Exosomes: A Bubble Ride for Prions?

In certain cell types, endosomal multivesicular bodies may fuse with the cell surface in an exocytic manner. During this process, the small 50-90-nm-diameter vesicles contained in their lumen are released into the extracellular environment. The released vesicles are called exosomes. Exosome secretion can be used by cells to eject molecules targeted to intraluminal vesicles of multivesicular bodies, but particular cell types exploit exosomes as intercellular communication devices for transfer of proteins and lipids between cells. The molecular composition of exosomes is determined by sorting events within endosomes that occur concomitantly with the generation of intraluminal vesicles. As other raft-associated components, the glycosylphosphatidylinositol-linked prion protein transits through multivesicular bodies. Recent findings in non-neuronal cell models indicate prion protein association with secreted exosomes. Thus, exosomes could constitute vehicles for transmission of the infectious prion protein, bypassing cell-cell contact in the dissemination of prions.     

DISTRIBUTION OF PHOSPHATASES IN THE GOLGI REGION AND ASSOCIATED STRUCTURES OF THE THORACIC GANGLIONIC NEURONS IN THE GRASSHOPPER, MELANOPLUS DIFFERENTIALIS

The neuronal perikarya of the grasshopper contain sudanophilic lipochondria which exhibit an affinity for vital dyes. These lipochondria are membrane-delimited and display acid phosphatase activity; hence they correspond to lysosomes. Unlike those of most vertebrates, these lysosomes also hydrolyze thiamine pyrophosphate and adenosine triphosphate. Like vertebrate lysosomal "dense bodies," they are electron-opaque and contain granular, vesicular, or lamellar material. Along with several types of smaller dense bodies, they are found in close spatial association with the Golgi apparatus. The Golgi complexes are frequently arranged in concentric configurations within which these dense bodies lie. Some of the smaller dense bodies often lie close to or in association with the periphery of dense multivesicular bodies. Further, bodies occur that display gradations in structure between these multivesicular bodies and the dense lysosomes. Acid phosphatase activity is present in the small as well as the larger dense bodies, in the multivesicular bodies, and in some of the Golgi saccules, associated vesicles, and fenestrated membranes; thiamine pyrophosphatase is found in both the dense bodies and parts of the Golgi complex. The close spatial association of these organelles, together with their enzymatic similarities, suggests the existence of a functional or developmental relationship between them.