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.     

Further study of the chromatoid body in rat spermatocytes and spermatids

Ultrastructure of the chromatoid body in rat spermatocytes and spermatids was studied by transmission electron microscopy. The following was found: 1. electron dense granules, 72.1 +/- 14.73 (SD) nm, that appeared to be both primary (assembling) and end (disassembling) structural subunits in the biogenesis of the chromatoid body, 2. relationship between chromatoid body and cytoplasmic microtubules, 3. ribbon-like structures and aggregates of 25 nm granules. The discussion focuses on a) a probable sequence of formation and breakdown of the chromatoid body, and b) the chromatoid body as an example of a common cellular design involving an interrelationship of dense material-smooth membranes-microtubules.     

Motile components in early rat spermatids

In early rat spermatids, two distinctly different kinds of movements of cell components were detected by video-analysis. The primary flagellum, a typical 9 + 2 axonema, is capable of inducing wave-like movements in three dimensions, unlike late spermatid forms, which display motility of the now thickened flagellum only by repeated bending of its extreme part. Additionally, at the apical regions of spermatids of the same early stage, cytoplasmic protrusions executed rhythmic movements at a frequency of almost three times per second.The two kinds of motility of the different components in the same cell type are thought to be involved in normal orientation and transfer of spermatids in the tubulus seminiferus during their differentiation to sperm.     

The role of chromatoid bodies and cytoskeleton in differentiation of rat spermatozoids

An ultrastructural and immunocytochemical study of rat male germ cells at different stages of development has been carried out. Investigation of morphological changes of spermatogenic cells showed the presence of close associations between chromatoid bodies (CBs) and other cell organelles, particularly with the nucleus and Golgi apparatus. In addition, a connection of manchette noncentosomal microtubules (MTs) with spermatid perinuclear ring plasma membrane (PM) in the zone of adhesion intercellular contact, zonula adhaerens (ZA), was revealed. These results, as well as the available literary data, make it possible to analyze expected pathways of noncentrosomal MT nucleation in the late spermatids. It is possible to suggest that noncentorosomal MT are nucleated on the sites of perinuclear ring ZA. The immunocytochemical analysis revealed two novel proteins for these cells: BASP1 and MARCKS. It was shown that these proteins were present in CBs in early spermatids. During spermatozoid differentiation, these proteins are located along the outer dense fibers (ODFs) of the sperm tail. BASP1 and MARCKS are believed to be involved in the processes of calcium accumulation in CBs and ODFs. Calcium ions seem to play a significant role in RNA processing and protein synthesis in spermatids. Calcium is also necessary for sperm mobility defined mainly by ODFs.     

Immunoelectron microscopical visualization of ribonucleoproteins in the chromatoid body of mouse spermatids

The chromatoid body (CB), a cytoplasmic organelle present only in germ cell line, was studied at the electron microscopic level in mouse spermatids using cytochemical techniques and specific antibodies directed against sn-RNPs, hnRNPs, and ribosomal proteins. We found that specific staining for DNA as well as the use of monoclonal anti-DNA antibodies show a complete absence of DNA in the CB. The CB remains stained, however, after the application of the ethidium bromide-PTA technique, suggesting the presence of RNA within this organelle. snRNP as well as hnRNP proteins are demonstrated within the CB by means of specific monoclonal or polyclonal antibodies, especially during earlier spermiogenic stages. Monoclonal antibodies directed against the large ribosomal subunit proteins P1/P2 detect these antigens on the CB essentially along the internal threads of dense fibrillar material. Our findings suggest that the CB may function as a source of mRNA and/or of its partially processed precursors during the late stages of spermiogenesis, when the spermatid nucleus becomes gradually inactive.     

Localization of mitochondrial ribosomal RNA on the chromatoid bodies of marine planarian polyclad embryos

Electron-dense cytoplasmic structures, referred to as chromatoid bodies, are observed in the somatic stem cells, called neoblasts, and germline cells in adult planarians. Although it has been revealed that the chromatoid bodies morphologically resemble germline granules in Drosophila and Xenopus embryos, what essential role it plays in the planarian has remained unclear. In the present study, to examine whether chromatoid bodies in planarian embryos are responsible for germline formation, the presence and behavior of chromatoid bodies during embryogenesis were examined. Mitochondrial large ribosomal RNA and mitochondrial small ribosomal RNA were used as candidate markers for components of the chromatoid body. Starting from the fertilized egg, extramitochondrial signals of both RNA (mtrRNA) were observed. At the ultrastructural level, mtrRNA were localized on the surface of the chromatoid bodies. At subsequent stages, the signals of mtrRNA were observed in certain restricted blastomeres that contribute to the formation of larval structures. The signals gradually decreased from the gastrula stage. These results suggest that the chromatoid bodies associated with mtrRNA in embryogenesis are not germline granules. The chromatoid bodies of blastomeres may be concerned with the toti- or pluripotency and cell differentiation as proposed in adult planarian neoblasts.     

The role of chromatoid bodies and cytoskeleton for differentiation of rat spermatozoids

The ultrastructural and immunocytochemical study of rat male germ cells on different developing stages has been made. The investigation of morphological changes of spermatogenic cells has demonstrated the presence of tight connections between chromatoid bodies (CBs) and other cell organelles, particularly with the nucleus and Golgi apparatus; has revealed the association of manchette noncentrosomal microtubules (MT) with spermatid perinuclear ring plasma membrane (PM) in the zone of the adhesion intercellular contact--zonula adhaerens (ZA). The comparison of the results obtained in this work with available literary data has given possibility to analyze expected pathways of noncentrosomal MT nucleation in the late spermatids. This paper puts the supposition that noncentrosomal MTs are nucleated on the sites of perinuclear ring ZA. The immunocytochemical analysis discovered two novel proteins for these cells--BASP1 and MARCKS. It has been shown that these proteins present in the CBs in the early spermatids. During the spermatozoid differentiation these proteins are revealed along the outer dense fibers (ODFs) of the sperm tail. BASP1 and MARCKS are supposed to involve in the processes of calcium accumulation in the CBs and ODFs. Calcium ions seem to play the significant role in RNA processing and protein synthesis in spermatids. Calcium is also necessary for the mobility of sperms which is mainly determined by ODFs.     

Transport of material between the nucleus,the chromatoid body and the golgi complex in the early spermatids of the rat

Summary The movement and transport of material between intranuclear dense particles, the chromatoid body and the Golgi complex have been studied in early spermatids of the rat. The analyses involved observation of living accurately identified cells, time-lapse cinemicrography and electron microscopy.The chromatoid body establishes transient contacts with intranuclear material during early spermiogenesis. The chromatoid body also makes contacts with the Golgi complex. It is suggested that the chromatoid body receives material from the nucleus during the postmeiotic period and participates in the early formation of the acrosomic system.This work was supported by the Finnish National Research Council for Medical Sciences. The authors are grateful to Mrs. Marita Aaltonen and Mrs. Raija Andersen for their skilful technical assistance     

Relationship between the chromatoid body and the acrosomal system in early spermatids of Myxine glutinosa L.

Summary A transient close relationship between the chromatoid body and the developing acrosome is demonstrated in early spermatids of Myxine glutinosa.This work was supported by the Norwegian Research Council for Science and Humanities (NAVF, Grant Nr. D 61.44) and the Austrian Fonds zur Förderung der wissenschaftlichen Forschung, Projekt 2183     

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.     

Accumulation of piRNAs in the chromatoid bodies purified by a novel isolation protocol

Haploid male germ cells are featured by an intriguing cytoplasmic cloud-like structure that has been named as chromatoid body (CB) on the basis of its staining properties and appearance under a microscope. Notwithstanding its early discovery in the late 19th century, the function of the CB is still largely obscure. Emerging evidence suggests a role for the CB and other similar RNA-containing granules, such as germ plasm in lower organism and processing bodies in somatic cells, in the control and organization of RNA processing and/or storage. Despite the increasing scientific demand, the lack of CB purification protocols has still been the main obstacle in the functional characterization of this structure. We have successfully isolated CBs from mouse testis by a novel immunoaffinity purification procedure and validated by several different methods that pure CB fractions are obtained. Analysis of the CB RNA content reveals enrichment of PIWI-interacting RNAs (piRNAs), further emphasizing the role of CB as the RNA processing body.     

Actin and major sperm protein in spermatids and spermatozoa of the parasitic nematode Heligmosomoides polygyrus

Nematode spermatozoa are amoeboid cells. In Caernorhabditis elegans and Ascaris suum, previous studies have reported that sperm motility does not involve actin, but, instead, requires a specific cytoskeletal protein, name y major-sperm-protein (MSP). In Heligmosomoides polygyrus, a species with large and elongate spermatids and spermatozoa, cell organelles are easily identified even with light microscopy. Electrophoresis of Heligmosomoides sperm proteins indicates that the main protein band has a molecular weight of about 15 kDa, as MSP in other nematodes, and is specifically labelled by an anti-MSP antibody raised against C. elegans MSP. A minor band at 43 kDa was specifically labelled by an anti-actin antibody. Reaction of anti-actin and anti-MSP antibodies is specific to, and restricted to, their respective targets. Actin and MSP localisation, studied by indirect immunofluorescence in male germ cells of Heligmosomoides polygyrus, are similar: spermatids show rows of dots, corresponding to the fibrous bodies, around an unlabelled central longitudinal core; spermatozoa are labelled strictly in an anterior crescent-shaped cap, at the opposite pole to the nucleus, which contains fibres of the MSP cytoskeleton. Phalloidin labelling shows that F-actin is present in spermatids, but absent in spermatozoa. Tropomyosin shows a distinct pattern in spermatids, but is located in the MSP and actin-containing cap in spermatozoa. It is hypothesized that actin plays a role in the shaping of the cell and in the arrangement of its organelles during nematode spermiogenesis, when MSP is present, in an inactive state, in the fibrous bodies. The concentration of actin and tropomyosin in the anterior cap is not compatible with previous theories about the MSP cytoskeleton which is supposed to act in the absence of actin. © 1996 Wiley-Liss, Inc.     

Ultrastructural localization of RNA in the chromatoid bodies of undifferentiated cells (neoblasts) in planarians by the RNase–gold complex technique

Undifferentiated cells of planarians (Platyhelminthes, Turbellaria), also called neoblasts, are totipotent stem cells, which give rise to all differentiated cell types, while maintaining their own density by cell proliferation. Neoblasts are the only somatic cells of planarians bearing chromatoid bodies in their cytoplasm; these organelles disappear as differentiation takes place. Studies on germinal cells of several groups of organisms have shown that chromatoid bodies contain substantial amounts of RNA. To test its presence in neoblasts, we have used an RNase–gold technique. We found chromatoid bodies labeled with RNase–gold particles. Heterogeneity in the density of the label, may be correlated with the functionality and complexity of these organelles. The gold marker was also present over the nucleus and rough endoplasmic reticulum, but mitochondria, secretory granules, and the extracellular space were devoid of label. This specific localization of RNA in planarian chromatoid bodies supports earlier findings on germ cells and embryonic cells in a variety of organisms, indicating that chromatoid bodies are information-storage structures, essential during the process of cell differentiation. © 1993 Wiley-Liss, Inc.