Active movements of the chromatoid body. A possible transport mechanism for haploid gene products

Recent data indicate that the chromatoid body typical of rat spermatogenesis may contain RNA synthesized in early spermatids by the haploid genome. Analyses of living step-1 and step-3 spermatids by time-lapse cinephotomicrography have shown that the chromatoid body moves in relation to the nuclear envelope in two different ways. Predominantly in step 1, the chromatoid body moves along the nuclear envelope on a wide area surrounding the Golgi complex and has frequent transient contacts with the latter organelle. In step 3, the chromatoid body was shown to move perpendicular to the nuclear envelope. It was seen located very transiently at the top of prominent outpocketings of the nuclear envelope with apparent material continuities through nuclear pore complexes to intranuclear particles. The rapid movements of the chromatoid body are suggested to play a role in the transport of haploid gene products in the early spermatids, including probably nucleocytoplasmic RNA transport.     

Computer analysis of living cells: movements of the chromatoid body in early spermatids compared with its ultrastructure in snap-frozen preparations

 Quantitative analyses of cytoplasmic and nuclear organelle movements in living interphase cells at defined stages of differentiation are few. By phase contrast videomicroscopy and digital imaging techniques, we have traced the path of the chromatoid body (CB) and analysed its rapidly changing positions in relation to the nuclear envelope, Golgi complex and nuclear pale chromatin areas in living early spermatids of the rat. The CB had intimate interactions with the nuclear envelope and moved both in parallel and perpendicular fashion in relation to it. It had successive short contacts with the Golgi complex and nuclear pale chromatin areas. It was also seen to scan between two pale chromatin areas and it had pinocytosis-like transient engulfments during interactions with the pale chromatin. In ultrastructural analysis of snap-frozen preparations, the CB had a large contact area with the nuclear envelope with several intermediate organelles that may be involved in nucleocytoplasmic material transport. It is evident that quantitative image analysis of living cells is a powerful guide for ultrastructural analyses. The snap-freezing technique gives new possibilities for studies of structures that are sensitive to conventional fixation procedures. Accepted: 23 January 1997     

Actin and RNA are components of the chromatoid bodies in spermatids of the rat

Chromatoid bodies present in spermatocytes and spermatids of the rat show directed movements around spermatid nuclei during differentiation. This transient organelle contains RNA and establishes contact to intranuclear material and to the acrosomal complex. In order to determine possible components of motility and to verify the presence of RNA, we used a recently developed low-temperature embedding resin combined with protein A-gold and enzyme-gold techniques for studies at the ultrastructural level. All chromatoid bodies analyzed display high concentrations of gold particles over the electron-dense regions when labeled with antiactin. In contrast, RNase-gold particles were localized mainly in the electron-translucent areas. Corresponding controls were always negative. The results suggest a relationship between the impressive motility of the chromatoid body and actin present in the organelle. In addition, specific localization of RNA supports earlier findings that consider the chromatoid body an essential element for differentiation during spermiogenesis.     

Morphogenesis and fate of the residual body in human spermiogenesis

Summary In the human testis the formation of the residual body of the spermatid and its morphological changes during and after spermiation were studied by means of electron microscopy. The caudal cytoplasmic mass of the late spermatid contains a Golgi complex, mitochondria, annulate lamellae, a chromatoid body, flower-like structures, ribosomes, a few large vacuoles, myelin-like membrane profiles and sporadic lipid droplets. When, by detachment of the caudal cytoplasm from the free spermatozoon, the residual body is formed, the chromatoid body has disappeared; the mitochondria are clustered peripherally; the ribosomes appear as a single complex in contact with a large vacuole containing granular material; in place of the Golgi complex aggregations of vesicles are present. The lipid droplets remain unchanged. The residual bodies or their fragments are either extruded via the seminiferous tubular lumen into the excurrent ducts or they are engulfed by Sertoli cells where in the supranuclear region the successive steps of decomposition can be observed. The participation of the various constituents in the disintegration of the residual body is discussed. In contrast to other mammalian species, in man the sporadic lipid droplets seem to be of minor importance in the fate of the residual body.     

Intercellular organelle traffic through cytoplasmic bridges in early spermatids of the rat: mechanisms of haploid gene product sharing

Stable cytoplasmic bridges (or ring canals) connecting the clone of spermatids are assumed to facilitate the sharing of haploid gene products and synchronous development of the cells. We have visualized these cytoplasmic bridges under phase-contrast optics and recorded the sharing of cytoplasmic material between the spermatids by a digital time-lapse imaging system ex vivo. A multitude of small (ca. 0.5 microm) granules were seen to move continuously over the bridges, but only 28% of those entering the bridge were actually transported into other cell. The average speed of the granules decreased significantly during the passage. Immunocytochemistry revealed that some of the shared granules contained haploid cell-specific gene product TRA54. We also demonstrate the novel function for the Golgi complex in acrosome system formation by showing that TRA54 is processed in Golgi complex and is transported into acrosome system of neighboring spermatid. In addition, we propose an intercellular transport function for the male germ cell-specific organelle chromatoid body. This mRNA containing organelle, ca. 1.8 microm in diameter, was demonstrated to go over the cytoplasmic bridge from one spermatid to another. Microtubule inhibitors prevented all organelle movements through the bridges and caused a disintegration of the chromatoid body. This is the first direct demonstration of an organelle traffic through cytoplasmic bridges in mammalian spermatogenesis. Golgi-derived haploid gene products are shared between spermatids, and an active involvement of the chromatoid body in intercellular material transport between round spermatids is proposed.     

黑脊倒刺Ba生精细胞拟染色体的形成过程

用电子显微镜观察了黑脊倒刺Ba生精细胞中拟染色体的形成过程。拟染色体在初级精原细胞中形成。在初级精原细胞的细胞核中,拟染色体前体物质先附着于核膜内侧,该处核膜崩溃。并在拟染色体前体物质的内侧,新核膜形成。新核膜将拟染色体前体物质分隔出细胞核之外。新核膜呈凹陷状。拟染色体前体物质集中于该凹陷中,并聚集成拟染色体。新核膜上有较大的空隙。核内还有少量拟染色体前体物质通过该空隙进入核表面的凹陷中,并结合到拟染色体上。黑脊倒刺Ba生精细胞拟染色 体的形成方式与通常认为的核内物质通过核孔排出核外的方式不同,似可表明核内物质向外运输存在着另一种机制。拟染色体形成后不久就与线粒体结合,并离开核凹。在以后的发育过程中,拟染色体又与线粒体分离。     

Incorporation of (3H)uridine by the chromatoid body during rat spermatogenesis

The in vitro incorporation of tritiated uridine into RNA by the spermatogenic cells of the rat has been analyzed by high-resolution autoradiography. Special attention has been focused on the unique cytoplasmic organelle, the chromatoid body. After a short labeling time (2 h), this organelle remains unlabeled in the vast majority of the early spermatids although the nuclei are labeled. When the 2-h incubation with (3H)uridine is followed by a 14-h chase, the chromatoid body is seen distinctly labeled in all spermatids during early spermiogenesis from step 1 to step 8. Very few grains are seen elsewhere in the cytoplasm of these cells. When RNA synthesis in the spermatid ceases, the chromatoid body also remains unlabeled. It is likely that the chromatoid body contains RNA which is synthesized in the nuclei of the spermatids. The function of this RNA as a stable messenger RNA needed for the regulation of late spermiogenesis is discussed.     

Fine structure of the chromatoid body during spermatogenesis in the water-strider,Gerris remigis (SAY)

Summary During spermatogenesis in Gerris remigis, chromatoid bodies appear in the spermatocytes and persist to the-mid-spermatid stage. These structures consist of numerous, parallel tubules, which measure approximately 500 Å in diameter. The tubules are arranged in hexagonal array, and contain dense granules that resemble ribosomes. The chromatoid body may be secretory in function, or may be involved in intracellular transport.The technical assistance of Mr. Roy R. Keppie and Mrs. Mona Brandreth is gratefully acknowledged.     

Formation of the acrosome and basal body during spermiogenesis in a marine snail,Nerita picea (Mollusca: Archaeogastropoda)

In Nerita picea the proacrosomal granule is formed basally in the early spermatid from one large cisterna of the Golgi body, with which the other Golgi-derived vesicles fuse. After the proacrosomal granule has attached to the plasma membrane and invaginated to form a cup shape, one cisterna of endoplasmic reticulum inserts into the open end and deposits a granular secretion on the inner surface. Subsequently, the proacrosome migrates along the plasma membrane to the apex of the nucleus, but the Golgi body remains basal, as occurs in other archaeogastropods and also many polychaete annelids. However, the final shape and structure of the acrosome is similar to that of mesogastropods. The annulus attaches the distal centriole to the plasma membrane early in spermiogenesis. The production of the flagellum by the distal centriole not only expands the plasma membrane posteriorly but moves the centriolar complex to the nucleus, causing an invagination of the plasma membrane where it is bound by the annulus. During proacrosome migration, the Golgi body secretes a dense tube around the flagellum, and the mitochondria fuse into two spheres at the base of the nucleus. The nuclear plug that closes off the intranuclear canal until this stage rapidly reorganizes itself into two tubes of material inside the canal. The centrioles continue flagellar production, break away from the annulus, and move deep into the intranuclear canal where they fuse together to form the basal body of the sperm. In the maturing spermatid, the two mitochondria fuse into a single sheath that spirals around the flagellum. The annulus does not migrate posteriorly but remains anterior to the midpiece, which is unusual for a filiform sperm. Spermiogenesis in Nerita picea has features in common with both archaeogastropods and mesogastropods but also has some unique features. These observations lend credence to the idea that the Neritidae are a transitional group between Archaeogastropoda and Mesogastropoda.     

黑脊倒刺鲃生精细胞拟染色体的形成过程

电子显微镜观察了黑脊倒刺把生精细胞中拟染色体的形成过程。拟染色体在初级精原细胞中形成。在初级精原细胞的细胞核中,拟染色体前体物质先附着于核膜内侧,该处核膜崩溃并在拟染色体前体物质的内侧,新核膜形成。新核膜将拟染色体前体物质分隔出细胞核之外新核膜呈凹陷状。拟染色体前体物质集中于该凹陷中,并聚集成拟染色体。新核膜上有较大的空隙核内还有少量拟染色体前体物质通过该空隙进入核表面的凹陷中,并结合到拟染色体上黑脊倒刺鲃生精细胞拟染色体的形成方式与通常认为的核内物质通过核孔排出核外的方式不同,似可表明核内物质向外运输存在着另一种机制。拟染色体形成后不久就与线粒体结合,并离开核凹在以后的发育过程中,拟染色体又与线粒体分离。     

Ultrastructural labeling of the chromatoid body and the centriole-associated body using the DNase-gold colloidal complex in monkey spermatids

In Monkey spermatids at different steps of spermiogenesis, the use of DNase-gold complex showed, at the ultrastructural level, a labeling over the chromatin and concomitantly over the chromatoid body, centriole associated body and annular chromatoid body. The results obtained with the DNase-gold complex containing either DNA or actin led to discuss the nature of the substances revealed by the labeling in the cytoplasmic structures.     

A cytochemical study of the Golgi apparatus of the spermatid during spermiogenesis in the rat

The reactivity of the various components of the Golgi apparatus of rat spermatids for three phosphatase activities (nicotinamide adenine dinucleotide phosphatase, NADPase; thiamine pyrophosphatase, TPPase; cytidine monophosphatase, CMPase) and the incorporation of 3H-fucose by the spermatids was analyzed at the 19 steps of spermiogenesis, i.e., during and after this organelle elaborated the glycoprotein-rich acrosomic system. During steps 1-3, the Golgi apparatus produced, in addition to the proacrosomic granules, multivesicular bodies that became associated with the chromatoid body. NADPase was located within the four of five intermediate saccules of Golgi stacks, and TPPase was found in the last one or two saccules on the trans aspect of the stacks from steps 1 to 17 of spermiogenesis. CMPase was located within the thick saccular GERL elements found in the trans region of the Golgi apparatus from steps 1 to 7 of spermiogenesis, but the CMPase-positive GERL disappeared from the Golgi apparatus after its detachment from the acrosomic system at step 8. Th acrosomic system itself was reactive from CMPase and TPPase but was negative for NADPase, while the multivesicular bodies were CMPase and NADPase positive but unreactive for TPPase. Tritiated-fucose was readily incorporated within the Golgi apparatus of steps 1-17 spermatids; in steps 1-7 it was subsequently incorporated within the acrosomic system and multivesicular bodies. These various data indicated (1) that the Golgi apparatus of spermatids, although it loses its CMPase-positive GERL element in step 8, retains evidence of functional capacity until it degenerates in step 17; (2) that in early spermatids the various saccular components of the Golgi are specialized with respect to enzymatic activities; and (3) that each Golgi region may contribute in a coordinated fashion to the formation of the acrosomic system and multivesicular bodies.     

Inhibitor induced alterations of chromatoid bodies in male germ line cells of Xenopus laevis

The action of inhibitors of protein synthesis on the structure of cytoplasmic inclusions found in the male germ cell line of the anuran, Xenopus laevis, has been studied by light and electron microscopy. Results indicate that one such inclusion, the chromatoid body, is sensitive to treatment with either chloramphenicol or puromycin. These drugs administered in vivo or in vitro cause up to a thirty-fold increase in the volume of the chromatoid body in all stages where it is normally present. Maximum size increase obtainable is the same for either drug, but is different and characteristic for each germ cell stage. Drug action is dose dependent, with "chromatoid body syndrome" occurring over a relatively narrow concentration range. Cyclohexamide, in contrast to chloramphenicol or puromycin, does not produce a clear increase in the size of chromatoid bodies, and is capable of blocking the action of the other drugs at normally effective concentrations. Results obtained in this investigation suggest that primary spermatogonia contain enough chromatoid body material to account for the total amount present in all subsequent germ cell stages. This fact, coupled with other studies where chromatoid-like bodies have been observed, suggests the hypothesis that the chromatoid body represents at least in part an aggregation stage of materials associated with the microtubule population of the germ cell line. Alternately, or in addition, ribonucleoprotein may contribute to the structure of the chromatoid body.     

Polysome-like structures in the chromatoid body of rat spermatids

A procedure for isolating the chromatoid body from the testis of 40-day-old rats was developed. Electron-microscopical analysis indicated that about 70% of the isolated organelles were chromatoid bodies, while the remaining structures corresponded to dense bodies and probably to satellites. Negative staining of the isolated organelles revealed the presence of polysome-like structures in about 20% of the chromatoid bodies suggesting that the polysomes were not due to contamination with cytoplasmic polysomes. Moreover, the presence of RNA in the stroma of the chromatoid body was confirmed by RNAse-gold staining. Preliminary electrophoretic analysis of the RNA extracted from the organelles revealed the presence of a complex population of RNAs including 5.8 and 5 S ribosomal RNAs but no tRNA.     

Ultrastructural observations on the germ line of Xenopus laevis

Summary The development of the male germ line in Xenopus laevis has been examined by electron microscopy. Findings have been compared to the parallel process in the female. Three structures unique to the germ line were found in both male and female cells: a fibrillar nuclear region free of DNA; largely proteinaceous masses of nuage material; and a chromatoid body. Germ plasm bodies of the egg and early embryo appear to represent a form of nuage material. The finding of a structure which can be identified as a chromatoid body in the female germ line is unique, as is its presence in sexually undifferentiated primordial germ cells. The chromatoid body in Xenopus, unlike that in mammals, does not persist in the spermatozoon. Instead, it dissociates into a series of coated vesicles during spermatogenesis. The chromosomal ultrastructure of meiotic prophase stages in Xenopus is similar in both sexes until diplotene, when male bivalents condense and enter meiotic metaphase instead of entering the extended lampbrush stage characteristic of the female. The multiple nucleoli present in gonia are lost at the onset of meiotic prophase, but no obvious mechanism for this process was observed.The author would like to thank Drs. Joseph Gall and Bernard Tandler for their helpful suggestions during the course of this investigation. The author is a postdoctoral fellow of the National Institutes of Health, U.S.A. This research was supported by N.I.H. Grants 51823 and 12427.     

Reaction of the chromatoid body with a monoclonal antibody to a rat histocompatibility antigen

The monoclonal antibody OX3 against a polymorphic class II antigen encoded by the major histocompatibility locus of the rat has been shown to cross-react with the chromatoid body during spermatogenesis. Using an indirect immunofluorescence assay on frozen, fixed testis sections, the antibody revealed a pattern of fluorescent speckling that correlated with specific stages of spermatogenesis. The positive material first appeared in late pachytene spermatocytes as multiple small spots. Larger dots appeared in all regions containing round spermatids, but, as the spermatids matured, only fine dots were seen. Mature spermatids were negative, as were all early cells (spermatogonia to early pachytene spermatocytes). When suspension of fixed testicular cells were tested, the activity was clearly associated with the chromatoid body adjacent to the nucleus in round spermatids and with multiple smaller structures encircling the nucleus in primary spermatocytes. These associations were confirmed in observations on immature testes at various ages. No reactivity was seen in testes of animals whose testes had previously been irradiated to render them aspermatogenic, nor in grc/grc rats in which spermatogenesis is arrested at the primary spermatocyte stage. Because the expression of this reactivity was seen even in rats that do not express the OX3 antigen on their somatic cells, this antibody should prove useful in determining the structure of this body, its origin and fate, and any possible role it may have in spermiogenesis.     

Ultrastructural and cytochemical studies of the female gonad of Prorhynchus sp. (Platyhelminthes,Lecithoepitheliata)

The female gonad of Prorhynchus is heterocellular (neoophoran organization) and consists of an unpaired, elongate germovitellarium enveloped by a finely granular extracellular lamina. It is composed of a posterior germinative area where early oocytes are randomly associated with differentiating vitellocytes and a growth area with follicular organization. In each follicle a single oocyte is surrounded by a layer of vitellocytes. By electron microscopy, the oocytes showed features typical of non-vitellogenic germ cells; they had chromatoid bodies, annulate lamellae, lipid droplets and R.E.R. and Golgi complexes producing small granules with a multilamellar pattern. Vitellocytes showed features typical of secretory cells with the R.E.R. and Golgi complex developed to a great extent and involved in the production of type A and type B globules, respectively. We speculate that type A globules are shell-globules and type B globules are yolk. The structure, composition and role of vitellocyte globules of Prorhynchus are compared with those of homologous inclusions from other Platyhelminthes.Abbreviations A type A globule - B type B globule - ECL extracellular lamina - GC Golgi complex - L lipid - RER rough endoplasmic reticulum - O oocyte - V vitellocyte     

The relationship between the nuage and the chromatoid body during spermatogenesis in the Rat

Summary Cytoplasmic structures ultrastructurally similar to the nuage are present in the cytoplasm of all spermatogenic cells in adult rats. The nuage is a discrete organelle which should not be confused with the chromatoid body. In step 7–8 spermatids transient contact is established between the nuage and the chromatoid body. This indicates a very specific recognition of the nuage by the chromatoid body. It is suggested that the nuage and the chromatoid body are separate cell organelles the functions of which are somehow related to each other.