Sperm development in the teleost Oryzias latipes

Summary In Oryzias latipes the processes of spermatogenesis and spermiogenesis occur within testicular or germinal cysts which are delimited by a single layer of lobule boundary cells. These cells, in addition to comprising the structural component of the cyst wall, ingest residual bodies cast off by developing spermatids. Therefore, they are deemed to be the homologue of mammalian Sertoli cells. The germ cells within a cyst develop synchronously owing to the presence of intercellular bridges connecting adjacent cells. Since bridges also connect spermatogonia, it seems probable that all of the germ cells within a cyst may form a single syncytium and do not exist as individual cells until the completion of spermiogenesis when the residual bodies are cast off. Significant differences between spermiogenesis in O. latipes and in the related poeciliid teleosts are discussed.     

Ultrastuctural and cytochemical study of spermatogenesis in Scrobicularia plana (Mollusca,Bivalvia)

The ultrastructure of the mature spermatozoa and spermatogenesis of the bivalve Scrobicularia plana are described. Support cells extend from the basal lamina to the lumen of the testis and are laterally connected to the germinal epithelium. Germ cells present intercellular bridges and flagella since the spermatogonial stage. While spermatogonia and spermatocytes appear connected to support cells by desmosome-like junctions, elongated spermatids are held at the acrosomal region by support cell finger-like processes. During spermiogenesis, the acrosomal vesicle differentiates from a golgian saccule and then migrates to the nuclear apex. A microtubular manchette arising from centrioles surrounds the acrosomal vesicle, the nucleus, and the mitochondria at the time these three organelles start their elongation, disappearing after that. The mature spermatozoon of S. plana lacks a distinct midpiece because the mitochondria extend from the region of the pericentriolar complex along the nucleus anteriorly for approximately 1.4 μm. The features of this bivalve type of modified spermatozoon are compared with those of other animal groups having similar modifications.     

Gap junctions between germ and somatic cells in the testis of the moth,Anagasta küehniella (Insecta: Lepidoptera)

Summary Heterocellular gap junctions were demonstrated in germ cysts of the moth Anagasta küehniella (Lepidoptera). They conjoin peripheral germ cells of a cyst and cells of their envelope. Their morphology differs according to the developmental stage of the germ cell involved. While gap junctional profiles are flat in cysts of gonia, in cysts of early spermatocytes they appear as button-like structures, the germ cell indenting the corresponding cyst cell. In cysts of late spermatocytes and of young spermatids, they are very numerous and often located at the extremity of conical protrusions of the germ cell. On the germ cell side, cytoplasmic microfilaments are associated with the junctional differentiation. Gap junctions are observed as being pinched off from the surface of the spermatids and, correspondingly, gap vesicles are found in the cyst cells. This, together with the fact that gap junctions are not found at later stages of development, suggests that internalization of the gap junctions might take place before elongation of the spermatids. The potential importance of these germsomatic cell gap junctions is evaluated in light of recent physiological findings obtained by other authors on the oocyte-cumulus system and also in relation with some particularities in the development of the male germ cells in Lepidoptera.     

Ultrastructural investigation of spermatogenesis in Spongilla lacustris and Ephydatia fluviatilis (Porifera,Spongillidae)

Summary Spermatogenesis of the spongillids investigated here is similar in Spongilla lacustris and Ephydatia fluviatilis and proceeds, on the whole, as in other Eumetazoa. Sponges however lack true sex organs, the germ cells developing from somatic cells. The male germ cells originate in spongillids from choanocytes and the female ones from archaeocytes. In Spongilla lacustris single choanocytes leave the flagellated chambers and transform into spermatogonia; in Ephydatia fluviatilis they result from differential cell division. The spermatogonia gather in distinct mesenchyme regions and are surrounded by cyst-building cells. Thus spermatocysts are built in which spermatogenesis proceeds. The spermatogonia in the spermatocysts differentiate into flagellated spermatocytes of I. order. In this process, the early appearance of the flagellum and its mode of formation are uncommon. The following meiotic divisions generate spermatocytes of II. order in the first step and spermatids in the second. In both developmental stages the cells remain connected by cytoplasmic bridges. In the subsequent spermiocytogenesis the cytoplasm of the spermatids is reduced. The reduced parts of the cytoplasm appear as cell fragments in the lumen of the spermatocysts and are eventually ingested by the cystwall cells. The mature spermatozoa arrange in the spermatocysts in a characteristic pattern. Later the spermatocysts open into the excurrent canal system and the spermatozoa leave the sponge with the egestive water stream.     

Trout sertoli cells and germ cells in primary culture: I. Morphological and ultrastructural study

In order to characterize trout Sertoli cells and germ cells obtained after testis dissociation and cell separation, we have studied their morphology, ultrastructure, survival, and ability to express differentiated activities in primary cultures. After dissociation, the fine structure of Sertoli cells does not differ from that observed in situ and only minor changes are shown for at least 13 days. Until they are flattened in a monolayer, they keep the ability to retain germ cells on their surface. When flattened, some of them are able to divide. At the opposite of meiotic germ cells, spermatogonia can develop independently of Sertoli cells. They are able to proliferate during at least 10 days. Spermatocytes and spermatids are obtained as single cells and multinucleated giant cells (symplasts). In the absence of somatic cells, their maximal viability is approximately 5 days, whereas spermatocytes adhering to Sertoli cells can survive at least 10–12 days, provided trout lipoproteins are present. Spermatocytes are able to differentiate to spermatids, although this process is impaired for some ceils. The adhesion of spermatogonia and spermatocytes to Sertoli cells is specific, mediated by desmosome-like junctions and favored by lipoproteins. These data are compared to what is known in mammals and in amphibians.     

Fine structural reconstruction on the testicular cyst of the furrow orb weaver,Larinioides cornutus by 3D volume rendering

Morphological study on spermatids and spermatozoa have long been performed regarding various changes of cell organelles during spermiogenesis as a potential phylogenetic inference. Based on the fact that the number of germ cells per cyst increases according to a geometric series, knowing the exact number of germ cells in a certain stage may lead to the total number of sperms produced per cyst. In spiders, however, the entire process takes place in a cyst represented by a spermatogonium, producing sperms in spherical shape. It is very difficult to count the exact number of germ cells produced per cyst through a 2D image analysis. Therefore, we applied a 3D image of testicular cyst of an orb-weaving spider to visualize the exact number of germ cells produced from a cyst. In this study, 2D images obtained from serially sectioned micrographs were scanned precisely and reconstructed using a 3D-rendering technique. Finally, this research reveals that the exact number of spermatozoa produced each cyst in Larinioides cornutus appeared to be 128 (2⁷), which indicates that a single spermatogonium undergoes five mitotic divisions and two maturing divisions (meiosis) to produce final spermatozoa.     

Ultrastructural changes of the intercellular relationship in impaired human spermatogenesis

Summary In seven hypo- or aspermic patients, electron microscopic investigations of the intercellular connections of the seminiferous tubule were performed. The analysis of cell junctions of Sertoli cells and germ cells revealed irregularities of the Sertoli-cell junctions, hypoplasias of occluding junctions, hypo- and hyperplasias of the Sertoli-spermatid cell junctions and abnormal formation of Sertoli cell junctions with early spermatids, spermatocytes, and spermatogonia. Gap junction-like cell membrane specializations were very rare. Intercellular cytoplasmic bridges of germ cells were always present together with these cells. One hypoplastic bridge connecting two spermatogonia was found.The results allow a preliminary classification of impaired spermatogenesia. The changes of intercellular connections might disturb the blood-testis barrier as well as the intercellular communication in the seminiferous tubule. Evidence is available to support the suggestion that genetic causes play a considerable role in the etiology of the germ cell aplasia and the spermatogenic maturation arrest.     

Cell to cell relationships in the seminiferous epithelium in the mouse embryo

Summary Germ cells and Sertoli cells in embryonic mouse testes (day 14 to 20 of gestation) were examined by sectioning and freeze-fracture. Intercellular cytoplasmic bridges between the germ cells are observed in day 14 and older embryos. Membrane specializations with dense fuzzy material similar to the socalled desmosome-like structures are found between Sertoli cells and germ cells. A cell contact area with dense opposed membranes is also found between adjacent germ cells. Asymmetrical dense fuzzy lining of both Sertoli and germ cell membranes is noted. Pinocytotic pits or caveolae are frequently found in the Sertoli cell membrane. Between adjacent Sertoli cells, gap junctions of various sizes and focal meshworks of the occluding junctions are found. Most of the occluding junctional particles are located in the center of the grooves in the E face, and are similar to those in postnatal and adult Sertoli cell junctions. In addition, on both fractured faces there are ridges and grooves devoid of particles which are continuous with occluding junctions with particles, suggesting an initial stage in the formation of occluding junctions of the Sertoli cells. Particles gathered at the site of desmosome-like structures are present on the P face of the Sertoli cell.This work is supported by the Japanese Ministry of Education     

The ultrastructure of Sorubim lima (Teleostei, Siluriformes, Pimelodidae) spermatogenesis: premeiotic and meiotic periods

The ultrastructure of Sorubim lima spermatogenesis during the premeiotic and meiotic periods was studied. Our observations showed that the germ cells in the cysts are connected by cytoplasmic bridges and the mitotic and meiotic divisions are slightly asynchronous. The first and the last spermatogonial generations differ in the cellular and nuclear volume, nucleolus, chromatin condensation, distribution, size, density, and shape of the mitochondria, presence of 'lamellae anulata', amount and dimension of the 'nuages', and movement of the centrioles. In addition to the nuclear prophase structures, the spermatocyte I shows changes in all other cellular organelles and elongated vesicles appear in the cytoplasm. The accentuated cytoplasmic density and thickened walled vesicles are morphological characteristics that differentiate spermatocytes II from the other germ cells in the cysts of Sorubim lima testis.     

Restauration de la fertilité masculine par la spermatogenèsein vitro

Anin-vitro culture technique, previously tested with germ cells from men with complete spermatogenesis, was applied in assisted reproduction treatment for cases of meiotic and postmeiotic maturation arrest. Some primary spermatocytes from men with maturation arrest at the pachytene stage developed up to the late elongated spermatid stages and were capable of fertilizing the spouse’s oocytes and of giving rise to embryos that were transferred into the spouse’s uterus and subsequently developed to term. In other cases, round spermatids blocked in vivo before the process of spermiogenesis developed to elongated spermatidsin vitro; with the use of suchin-vitro formed spermatids, the first term pregnancies in cases of complete spermiogenesis arrest were achieved. These findings show that certain in-vivo developmental blocks in male germ cells from patients with severe testiculopathies can be overcome byin-vitro culture, probably by modifying control mechanisms acting at developmental checkpoints.     

Ovary cord structure and oogenesis in Hirudo medicinalis and Haemopis sanguisuga (Clitellata, Annelida): remarks on different ovaries organization in Hirudinea

In Hirudo medicinalis and Haemopis sanguisuga, two convoluted ovary cords are found within each ovary. Each ovary cord is a polarized structure composed of germ cells (oogonia, developing oocytes, nurse cells) and somatic cells (apical cell, follicular cells). One end of the ovary cord is club-shaped and comprises one huge apical cell, numerous oogonia, and small cysts (clusters) of interconnected germ cells. The main part of the cord contains fully developed cysts composed of numerous nurse cells connected via intercellular bridges with the cytophore, which in turn is connected by a cytoplasmic bridge with the growing oocyte. The opposite end of the cord degenerates. Cord integrity is ensured by flattened follicular cells enveloping the cord; moreover, inside the cord, some follicular cells (internal follicular cells) are distributed among germ cells. As oogenesis progresses, the growing oocytes gradually protrude into the ovary lumen; as a result, fully developed oocytes arrested in meiotic metaphase I float freely in the ovary lumen. This paper describes the successive stages of oogenesis of H. medicinalis in detail. Ovary organization in Hirudinea was classified within four different types: non-polarized ovary cords were found in glossiphoniids, egg follicles were described in piscicolids, ovarian bodies were found characteristic for erpobdellids, and polarized ovary cords in hirudiniforms. Ovaries with polarized structures equipped with apical cell (i.e. polarized ovary cords and ovarian bodies) (as found in arhynchobdellids) are considered as primary for Hirudinea while non-polarized ovary cords and the occurrence of egg follicles (rhynchobdellids) represent derived condition.     

Spermatogenesis and sperm ultrastructure in the polychaete genusOphryotrocha (Dorvilleidae)

The details of spermatogenesis and spermiogenesis are described forOphryotrocha puerilis. The ultrastructure of mature sperm is shown forO. puerilis, O. hartmanni, O. gracilis, O. diadema, O. labronica, andO. notoglandulata. Clusters of sixteen cells each are proliferated by two stem cells in each setigerous segment ofO. puerilis representing the very early stages of both oogenesis and spermatogenesis. In each spermatocyte-I cluster, the cells are interconnected by cytoplasmic bridges. Early, clusters are enveloped by peritoneal sheath cells. These transient gonad walls break down prior to meiosis. The meiotic processes may start in the clusters with the cells still interconnected, or during breakdown of the original cluster, giving rise to smaller subclusters of both spermatocytes I and spermatocytes II with various numbers of cells. Finally, spermatid tetrads are present. As spermiogenesis progresses, the tetrads disintegrate. Golgi vesicles in both spermatocytes and spermatids contain electron-dense material, presumably preacrosomal. The acrosome is formed by such vesicles. In the six species studied here, the acrosomes appear to be of a similar overall structure but are of different shape. Centrioles are usually located beneath the acrosome. The distal centriole forms the basal body of a flagellum-like cytoplasmic process. The microtubules of these flagellar equivalents do not show a normal ciliar arrangement. The flagellar equivalent appears to be non-motile. InO. hartmanni and inO. notoglandulata, a flagellar equivalent is missing. Microtubules originating from the proximal end of the distal centriole stretch to the nuclear envelope. This feature appears to be especially conspicuous inO. puerilis and inO. labronica. InO. labronica and inO. notoglandulata, bundles of microtubules paralleling the cell perimeter appear to stabilise the sperm. Various numbers of mitochondria are either randomly distributed around the nucleus or accumulate on one side, often directly under the acrosome. Parts of the present paper were presented at the 2^nd International Polychaete Conference, Copenhagen 1986 and at the 3^rd International Polychaete Conference, Long Beach, Ca. 1989.     

Ultrastructure of spermiogenesis in Plagioscion squamosissimus (Teleostei, Perciformes, Sciaenidae)

Spermiogenesis in Plagioscion squamosissimus occurs in cysts. It involves a gradual differentiation process of spermatids that is characterized mainly by chromatin compaction in the nucleus and formation of the flagellum, resulting in the spermatozoa, the smallest germ cells. At the end of spermiogenesis, the cysts open and release the newly formed spermatozoa into the lumen of the seminiferous tubules. The spermatozoa do not have an acrosome and are divided into head, midpiece, and tail or flagellum. The spermatozoa of P. squamosissimus are of perciform type with the flagellum parallel to the nucleus and the centrioles located outside the nuclear notch.     

Pycnotic cycle of the sex chromosome of Pyrgomorpha conica (Orthoptera) and development of spermiogenesis.

We have analyzed the anomalous pycnotic cycle of the X sex chromosome of the grasshopper Pyrgomorpha conica throughout both meiotic divisions and its possible influence on spermiogenesis. During diplotene the sex chromosome shows two differentiated pycnotic regions: (i) the centromeric region, which is negatively heteropycnotic, and (ii) the noncentromeric region, which shows alternating negatively and positively heteropycnotic zones in all standard individuals. The variation in size and location of the negative heteropycnotic zones, their smooth appearance, and their lack of effect on spermiogenesis lead us to suggest that condensation differences and not euchromatinization are responsible for their presence. In two individuals the sex chromosome appeared partially isopycnotic at metaphase I, and high levels of abnormal spermatids (macrospermatids and microspermatids) were found. We suggest that the possible activity of this chromosome during the second meiotic division may promote the disruption of spermiogenesis by affecting the mechanism that maintains intercellular bridges between normal spermatids.     

Microstructural Reconstruction for the Testicular Cysts of Wolf Spider Using 3D Volume Rendering Technique

In insects, the alignment of neighboring spermatid in the late stages is nearly perfect, so that a transverse section of a cyst containing late spermatids transects all the spermatids at approximately the same level. However, the testicular cysts of spiders are spherical, most cysts are arranged in order of increasing maturity from the periphery to the center of the testis. For this reason, it is difficult to observe the whole spermatids within a single microscopic slide and count them. Therefore, we demonstrate microstructural reconstruction technique enabling to count exact number of sperm cells per cyst with aid of 3D volume rendering. For image processing and reconstruction, serially sectioned histologic specimens were scanned with microscopy and 3D images were reconstructed using Amira 5.3.2 software from the image stacks of the germ cells and surrounding testicular cysts subsequentially. With the information gathered by 3D reconstruction, it has finally been counted that exactly 32 (2⁵) cells of the secondary spermatocytes per cyst. This means that most cysts in P. laura contain exactly 64 (2⁶) spermatids or spermatozoa, which presumably arose from four synchronous mitotic and two meiotic divisions. In addition, the number of divisions occurring in a cyst appears to be constant for this spider because it has been known that the number of spermatids per cyst is characteristic for each species.     

An ultrastructural investigation of the testes and spermiogenesis in Myobia murismusculi (Schrank) (Acari,Actinedida: Myobiidae)

Summary

The stages of spermiogenesis in Myobia murismusculi were investigated on the basis of ultrastructural analysis of both the testes and the female organs: receptaculum seminis and seminal duct. The walls of the testes consist of a thin epithelial layer. Germ and secretory cells lie free in the lumen of the testes. In the early stages of differentiation, both cell types represent clusters of sister cells joined by intercellular bridges. Each secretory cell contains prominent RER and Golgi complex, which produce single dense granule. Growing gradually the granule fills the whole volume of the cell's cytoplasm. Mature secretory cells disintegrate and the secretory product discharges into the testicular lumen. The germ cells are represented by the early, the intermediate and the late spermatids as well as the immature sperm (prospermia). Neither spermatogonia nor meiotic figures were observed in adult males. As spermiogenesis starts, numerous narrow invaginations of the outer membrane (peripheral channels) develop on the cell surface. They form a wide circumferential network connected to pinocytotic vesicles. Owing to the secretory activity of the Golgi complex, a large acrosomal granule is formed in the early spermatids. A long acrosomal filament runs along the intranuclear canal. Nuclear material condenses and forms two spherical bodies of different electron density. The lighter one can be observed until the stage of the late spermatids, when the nuclear envelope almost completely disappears. The electron-dense nuclear body transforms into a definite chromatin body, which is observed in the mature sperm as a cup-shaped structure. The late spermatids are characterized by the presence of a large electronlucent vacuole, which seems to be unique for the process of spermiogenesis in Actinedida. After the spermia enter the female genital tract, the peripheral channels disappear as well as the vacuole. The cells form long amoeboid arms with a special microtubular layer underneath the plasma membrane. The chromatin body is encircled by a large acrosomal granule of complex shape provided by long extensions running deep into the cytoplasm. The cytoplasm contains no organelles except for a group of unmodified mitochondria in the post-nuclear region. The main characteristics of the Myobia spermiogenesis are discussed with regard to other actinedid mites.     

Cytological study on Sertoli cells and their interactions with germ cells during annual reproductive cycle in turtle

Sertoli cells (SCs) play a central role in the development of germ cells within functional testes and exhibit varying morphology during spermatogenesis. This present study investigated the seasonal morphological changes in SCs in the reproductive cycle of Pelodiscus sinensis by light microscopy, transmission electron microscopy (TEM), and immunohistochemistry. During hibernation period with the quiescent of spermatogenesis, several autophagosomes were observed inside the SCs, the processes of which retracted. In early spermatogenesis, when the germ cells started to proliferate, the SCs contained numerous lipid droplets instead of autophagosomes. In late spermatogenesis, the SCs processes became very thin and contacted several round/elongated spermatids in pockets. At this time, abundant endoplasmic reticulum and numerous mitochondria were present in the SCs. The organization of the tight junctions and the adherens junctions between the SCs and germ cells also changed during the reproductive cycle. Moreover, SCs were involved in the formation of cytoplasmic bridges, phagophores, and exosome secretions during spermatogenesis. Tubulobulbar complexes (TBC) were also developed by SCs around the nucleus of the spermatid at the time of spermiation. Strong, positive expression of vimentin was noted on the SCs during late spermatogenesis compared with the hibernation stage and the early stage of spermatogenesis. These data provide clear cytological evidence about the seasonal changes in SCs, corresponding with their different roles in germ cells within the Chinese soft‐shelled turtle Pelodiscus sinensis.     

F-Actin and Tubulin During Spermatogenesis in Gamasid Mites (Acari: Parasitina)

Abstract F-actin and tubulin behaviour was investigated using fluorescence probes and electron microscopy in the course of spermatogenesis in two gamasid mites, Porrhostaspis lunulata Müller (Parasitidae) and Pergamasus truatellus Athias-Henriot (Pergamasidae). In spermatogonia and primary spermatocytes of both species, the proteins were localized mainly in the intercellular bridges and, in lesser quantities, in the cytoplasm. Overall, actin was present along the plasma-lemmal contact sites of the gonial cells. At the beginning of spermatid elongation, actin could be detected in two regions: in perinuclear cytoplasm and under the plasmalemma. Subplasmalemmal actin, visible as threads running along acrosome-adhering protrusions of the nuclear envelope, is supposedly located within the electron-dense material filling the subacrosomal gap. Tubulin was found on both sides of each actin thread; its location was consistent with two sets of microtubules adhering to the inner acrosomal membrane. Their involvement in acrosome shaping is suggested. As spermatid elongation terminated, the previous pattern of proteins disappeared. In Pergamasus, however, actin emerged briefly near the centrifugal ends of spermatids (granular bodies zone). In spermatocyte-containing cysts, actin and tubulin fluorescence (more pronounced in Porrhostaspis) was associated with intercellular junctions between the cyst cells. In both species, diffuse actin fluorescence was also detected in the cytoplasm of cyst cells assembling elongated spermatids; the reaction was intensified at the end of the elongation process, when the cytoplasm of cyst cells aggregated around the centripetal ends of spermatids.