Functional morphology of the male reproductive system in Callichirus major (Crustacea: Decapoda: Axiidea): Evidence of oocytes in the gonad

Callichirus major inhabits the intertidal region of marine ecosystems and it is frequently used as live bait for fishing. This study aimed to describe the functional anatomy of the male reproductive system by microscopic techniques. The animals were collected along the Corujão beach, Piuma—ES, Brazil, and, in laboratory, the males were classified into two phases: immature (IM) and developed (DE) based on the macroscopic characteristics of the gonads. The gonad and vas deferens were dissected for histological routine and histochemical tests. Histologically, it was noted that in both phases, the more distal region of gonads has ovarian characteristics, showing developing oocytes. Also, different male germ cells were identified: spermatogonium (SPG), spermatocytes I and II (SPTCI, SPTCII), initial and final spermatid (IS, FS) and sperm (SPZ). Accessory cells with spherical or pyramidal nuclei were also present inside the testicular lobules. According to the vas deferens structure, three regions can be characterized: proximal (PVD), middle (MVD) and distal (DVD). In the lumen of the vas deferens, a spermatophoric matrix highly reactive for histochemical tests was observed. The presence of female germ cells in males suggests the occurrence of intersexuality or hermaphroditism in this species.     

Spermatogenesis and related plasma androgen levels in Atlantic halibut (Hippoglossus hippoglossus L.)

Spermatogenesis in male Atlantic halibut (Hippoglossus hippoglossus L.) was investigated by sampling blood plasma and testicular tissue from 15-39-month-old fish. The experiment covered a period in which all fish reached puberty and completed sexual maturation at least once. The germinal compartment in Atlantic halibut testis appears to be organized in branching lobules of the unrestricted spermatogonial type, because spermatocysts with spermatogonia were found throughout the testis. Spermatogenesis was characterized histologically, and staged according to the most advanced type of germ cell present: spermatogonia (Stage I), spermatogonia and spermatocytes (Stage II), spermatogonia, spermatocytes and spermatids (Stage III), spermatogonia, spermatocytes, spermatids and spermatozoa (Stage IV), and regressing testis (Stage V). Three phases could be distinguished: first, an initial phase with low levels of circulating testosterone (T; quantified by RIA) and 11-ketotestosterone (11-KT; quantified by ELISA), spermatogonial proliferation, and subsequently the initiation of meiosis marked by the formation of spermatocytes (Stage I and II). Secondly, a phase with increasing T and 11-KT levels and with haploid germ cells including spermatozoa present in the testis (Stage III and IV). Thirdly, a phase with low T and 11-KT levels and a regressing testis with Sertoli cells displaying signs of phagocytotic activity (Stage V). Circulating levels of 11-KT were at least four-fold higher than those of T during all stages of spermatogenesis. Increasing plasma levels of T and 11-KT were associated with increasing testicular mass throughout the reproductive cycle. The absolute level of, or the relation between, testis growth and circulating androgens were not significantly different in first time spawners compared to fish that underwent their second spawning season. These results provide reference levels for Atlantic halibut spermatogenesis.     

Activité aromatase dans les cellules germinales mâles: quelle signification fonctionnelle?

The ability of the male gonad to convert androgens into estrogens is well known. According to age, aromatase activity has been already measured in immature and mature rat Leydig cells as well as in Sertoli cells. Recently, in different studies, a cytochrome P450_arom has even been immunolocalized not only in Leydig cells but also in germ cells of mouse, brown bear and rooster whereas in pig, ram and human the aromatase is mainly present in Leydig cells. Our purpose was to investigate the testicular cell distribution of cytochrome P450_arom mRNA in adult rat using RT-PCR. With 2 highly specific primers located on exons 8 and 9, we have been able to amplify a 289 bp aromatase fragment not only in Leydig cells and Sertoli cells but more importantly in highlyenriched preparations of pachytene spermatocytes, round spermatids and testicular spermatozoa. These amplified products showed 100% homology with the corresponding fragment of the rat ovary cDNA. In parallel, using an anti-human cytochrome P450_arom antibody we have demonstrated the presence of a 55 kDa protein in seminiferous tubules and crude germ cell (pachytene spermatocytes and round spermatids) preparation of the mature rat. After incubation with tritiated androstenedione, the aromatase activities in the microsomal fractions were 3.12±0.19 pmoles/mg/h in the testis, 1.25±0.13 in the seminiferous tubules and 1.53±0.15 in the crude germ cells. In purified testicular spermatozoa the aromatase activity was 2.96±0.69 pmoles/mg/h and found to be 5-fold higher when compared to that of either purified pachytene spermatocytes or round spermatids. Using a quantitative RT-PCR method with a standard cDNA 29 bp shorter, we have compared the amount of cytochrome P450_arom mRNA in mature rat Leydig cells and Sertoli cells. In purified Leydig cells from 90 day-old rats the P450_arom mRNA level was: 36.2±3.4×10^?3 amoles/μg RNA whereas in Sertoli cells the mRNA level was 10 fold lower. In pachytene spermatocytes, round spermatids and testicular spermatozoa the P450_arom mRNA levels were re pectively 367.2±76.6, 117.6±22.0 and <1×10^?3 amole/μg RNA. In conclusion we have demonstrated that the P450 aromatase is present not only in Sertoli cells and Leydig cells from mature rat testis but a biologically active aromatase exists also in germ cells (pachytene spermatocytes, round spermatids and spermatozoa). The existence of an additional source of estrogens within the genital tract of the male is now well documented and that suggests a putative role for these hormones during the male germ cell development.     

Histology of salmonid testes during maturation

The commonly applied classification systems of fish gonad maturity divide the maturation process into certain stages. However, the scales do not entirely reflect the continuity of the maturation process. Based on light microscope observations, the paper describes a comprehensive pattern of testicular transformations during maturation. The study was carried out on precocious underyearling and 1-year-old males of sea trout (Salmo trutta m. trutta L.), 1-year-old males of salmon (Salmo salar L.), and males of brown trout (Salmo trutta m. fario L.) aged from 7 months to 4 years. A total of 821 gonads collected during all seasons of the year were examined. The fish were fixed in Bouin's fluid. Histological slides of the mid-part of the gonad were made using the standard paraffin technique. The 3-6 microm sections were stained with Heidenhain haematoxylin. Histological changes of testes during maturation were similar in the three species studied. Immature and resting gonads contained type A spermatogonia in lobules only. The appearance of cystic structures containing type B spermatogonia in the lobules signalled the beginning of the sexual cycle in male gonads. Type B spermatogonia underwent synchronous mitotic divisions resulting in an increase in the total number of spermatogonia. As the spermatogenesis continued, the gonads showed a gradual increase in the number of cysts containing cells at all the spermatogenetic stages: type B spermatogonia, primary and secondary spermatocytes, spermatids, and spermatozoa. The well-formed spermatozoa were released to the lobule lumen once the Sertoli cells and spermatozoa connections broke up and the cyst disappeared. This was a continuous process observed throughout the spawning season. The spermatozoa were moved to the efferent duct. While some of the germ cells were completing spermatogenesis, the lobules contained less and less cysts with type B spermatogonia, primary and secondary spermatocytes, and spermatids; eventually all the cells completed spermatogenesis. At the end of maturation, vacuoles, up to 18.9 microm in final diameter (brown trout), appeared in the Sertoli cells. The vacuoles were visible in the lobule wall epithelium for a prolonged period of time. In most salmonid individuals examined, the reproductive cycles were observed to overlap. In some fish, the preparation for another cycle began very early, i.e., at the and of preceding spermatogenesis, which had not been observed before. Gonad maturation in some males was incomplete.     

The histological changes in the testis, epididymis and prostate gland of the red-bellied tree squirrel, Callosciurus erythraeus, during the growth and reproductive cycle

The male reproductive glands of the red-bellied tree squirrel, Callosciurus erythraeus, in the infantile, and prepubertal males, as well as sexually functional, degenerating and redeveloping adults were studied histologically. In the infant, testes are characterized with solid seminiferous tubules filled with primordial germ cells and Sertoli cells. Interstitial cells are sparse. The prostate is composed of condensed cell cords grouped into lobules dispersed with interlobular tissues rich in fibroblasts. In the epididymis the highly convoluted tubule is lined with a simple cuboidal or columnar epithelium and thin smooth musculature without. In the prepubertal male, germ cells are engaged actively in mitosis. Primary spermatocytes are readily recognized. Leydig cells appear in groups in the interstitial tissue. In the prostate, cell cords become highly branched and collecting tubules make their appearance. The tubules in the epididymis are enlarged in diameter but their peripheral musculature becomes thinner. In functional males, meiosis is active and bundles of spermatozoa are scattered along the central lumen. Leydig cells have their cytoplasm highly enriched. The prostate is in the secretory phase. The tubule in the epididymis is filled with sperm. In the degenerating adult, meiosis is interrupted and necrotic germ cells are detached from germinal epithelium. In the prostate, secretory and collecting ducts are eventually reduced to condensed lobules separated by interlobular fibrous tissue. The tubule in the epididymis often fills with necrotic germ cells but no sperm. In the redeveloping adult, the histology of the testes, prostate and epididymis is similar to that of the prepubertal male. However, there is more fibrous tissue in the interlobular septa in the prostate gland and thick musculature at the periphery of the tubule in the epididymis.     

Histomorphological studies of the testis and male genital ducts of Supachai's caecilian,Ichthyophis supachaii Taylor, 1960 (Amphibia: Gymnophiona)

We investigated the structure of the male reproductive system in Ichthyophis supachaii. The testis comprises a series of mulberry‐like lobes, each of which contains testis lobules occupied by germ cysts. A single cyst consists of synchronously developing germ cells. Six spermatogenic cell types, viz. primary spermatogonia, secondary spermatogonia, primary spermatocytes, secondary spermatocytes, spermatids and spermatozoa, have been identified and described. Notably, the testis of I. supachaii encompasses specific organization patterns of spermatids and spermatozoa during spermiogenesis. Spermiating cysts rupture and release spermatozoa to the collecting ducts, which are subsequently transported to the sperm duct, Wolffian duct and cloaca. We report for the first time ciliated cells in the epithelium of the caecilian Wolffian duct. The cloaca is divided into the urodeum and phallodeum. The urodeum has ciliated and glandular epithelia at its dorsolateral and ventral regions, respectively, as the lining of its internal surface. The muscular phallodeum is lined by ciliated epithelium. Paired Mullerian ducts lie parallel to the intestine and join the cloaca. The posterior portion of the duct is modified as the Mullerian gland. The most posterior region is non‐glandular and lined by ciliated epithelium. Our findings contribute further to information on the reproductive biology of caecilians in Thailand.     

DNA methyltransferase is developmentally expressed in replicating and non-replicating male germ cells.

Genomic methylation patterns are established during maturation of primordial germ cells and during gametogenesis. While methylation is linked to DNA replication in somatic cells, active de novo methylation and demethylation occur in post-replicative spermatocytes during meiotic prophase (1). We have examined differentiating male germ cells for alternative forms of DNA (cytosine-5)-methyltransferase (DNA MTase) and have found a 6.2 kb DNA MTase mRNA that is present in appreciable quantities only in testis; in post-replicative pachytene spermatocytes it is the predominant form of DNA MTase mRNA. The 5.2 kb DNA MTase mRNA, characteristic of all somatic cells, was detected in isolated type A and B spermatogonia and haploid round spermatids. Immunobolt analysis detected a protein in spermatogenic cells with a relative mass of 180,000-200,000, which is close to the known size of the somatic form of mammalian DNA MTase. The demonstration of the differential developmental expression of DNA MTase in male germ cells argues for a role for testicular DNA methylation events, not only during replication in premeiotic cells, but also during meiotic prophase and postmeiotic development.     

Conservation de tissu testiculaire et maturation in vitro de la lignée germinale pour préservation du potentiel de reproduction avant traitement anticancéreux chez le garçon pré-pubère

Sperm auto-conservation before chimioradiotherapy allows preservation of future reproductive possibilities in case of malignancy in young adult male. Because of the lack of mature spermatozoa, such possibilities cannot be offered for boys before puberty, even though the rate of cure of childhood malignancies is high. This paper reviewed recent advances in reproductive technology, which open the field of withdrawal of immature germ cells in prepubertal boys for in vitro maturation and cryopreservation for future paternity. It has been shown that the main steps of male meiosis have been driven in vitro, allowing to obtain round spermatids from pachytene spermatocytes in the rat. In mice, cryopreserved round spermatids have been used for oocyte fertilization and gave rise to normal living pups. In humans pregnancies and living babies have been reported after microinjection of round spermatids in cases of azoospermia. One pregnancy has been obtained with a cryopreserved spermatid. Thus the project of withdrawal of testicular tissues before sterilizing treatment, in vitro maturation of spermatogonia into round spermatids and cryopreservation of immature germ cells for future use for assisted fertilization does not seem unrealistic since each step has been done individually. However developing animal models is necessary to study not only the efficiency of the whole procedure but also to check its harmlessness before clinical trials.     

Developmental expression of the translocator protein 18 kDa (TSPO) in testicular germ cells

Translocator protein (TSPO) is a high affinity 18 kDa drug- and cholesterol-binding protein strongly expressed in steroidogenic tissues where it mediates cholesterol transport into mitochondria and steroid formation. Testosterone formation by Leydig cells in the testis is critical for the regulation of spermatogenesis and male fertility. Male germ cell development comprises two main phases, the pre-spermatogenesis phase occurring from fetal life to infancy and leading to spermatogonial stem cell (SSC) formation, and spermatogenesis, which consists of repetitive cycles of germ cell mitosis, meiosis and differentiation, starting with SSC differentiation and ending with spermiogenesis and spermatozoa formation. Little is known about the molecular mechanisms controlling the progression from one germ cell phenotype to the next. Here, we report that testicular germ cells express TSPO from neonatal to adult phases, although at lower levels than Leydig cells. TSPO mRNA and protein were found at specific steps of germ cell development. In fetal and neonatal gonocytes, the precursors of SSCs, TSPO appears to be mainly nuclear. In the prepubertal testis, TSPO is present in pachytene spermatocytes and dividing spermatogonia. In adult testes, it is found in a stage-dependent manner in pachytene spermatocyte and round spermatid nuclei, and in mitotic spermatogonia. In search of TSPO function, the TSPO drug ligand PK 11195 was added to isolated gonocytes with or without the proliferative factors PDGF and 17β-estradiol, and was found to have no effect on gonocyte proliferation. However, TSPO strong expression in dividing spermatogonia suggests that it might play a role in spermatogonial mitosis. Taken together, these results suggest that TSPO plays a role in specific phases of germ cell development.     

Investigation of detoxification capacity of rat testicular germ cells and Sertoli cells

Isolated pachytene spermatocytes liver longer than round spermatids in vitro. Indigenous formation of oxygen-derived free radicals and hydrogen peroxide can cause damage to germ cells. The germ cell antioxidant capacity may play an important role in this respect. In view of this, we have examined the activity and cellular localization of superoxide dismutase (SOD) and glutathione S-transferases (GST) in rat testicular cells. We have found significant differences in the distribution of these enzymatic activities in the germ cells. In addition, this study shows that alpha-tocopherol is found in various amounts in rat testicular cells in the order of: Sertoli cells greater than pachytene spermatocytes greater than round spermatids, with a factor of 4 in the alpha-tocopherol content between Sertoli cells and round spermatids.     

Morphology of the male reproductive system of freshwater prawn Macrobrachium carcinus (Decapoda,Caridea): Functional and comparative aspects

Testes and vasa deferentia are parts of the male reproductive system of decapod crustaceans. Both organs show morphological differences among decapod species in terms of anatomical and histological patterns reflecting the diversity of this group. Describing these features may assist in systematics, phylogenetics, and studies of reproductive behavior, especially for species of commercial interest, such as Macrobrachium carcinus, a native American species that, unusually for this genus, has no precopulation courting behavior. This study aims to describe the reproductive morphology and spermatogenesis of the male freshwater prawn M. carcinus. The male reproductive system of this species consisted of lobed testes connected to the vasa deferentia. The testis of M. carcinus was divided into several lobules. Each lobule was formed by a cluster of germ cells surrounded by connective tissue and nurse cells. This microscopic anatomy and histology of the testicular histoarchitecture has been described for many species of Decapoda and may represent a derived design of the testes. Unlike that in other decapod species, spermatogenesis proceeds in short transitory phases that produce spermatozoa at high concentrations and frequencies, corroborating the uncommon male reproductive behavior of this species. In the spermatic pathway, the lobules develop and fuse before releasing spermatozoa from the testes; however, this process has not been observed in decapods, yet. The neutral compounds secreted by the vas deferens are important for sperm nutrition as females secrete a substance for spermatophore adhesion during reproduction. This study presents different features and dynamics of the spermatogenic process in the male reproductive system of M. carcinus that have not yet been presented in the literature for decapods.     

Tcp10 promoter-directed expression of the Nek2 gene in mouse meiotic spermatocytes

Nek2 is a cell cycle regulator that is involved in diverse cell cycle events. The expression pattern and biochemical properties of Nek2 in mammalian male germ cells suggested its involvement on regulation of the meiotic cell cycle. To further investigate specific roles of Nek2 in meiosis, we generated transgenic mice in which the Nek2 transgenes were expressed specifically in spermatocytes using the Tcp10 promoter. The Nek2 transgenic mice did not reveal any significant defect in gross testicular anatomy as well as in fertility. However, we observed significant increases in defective spermatogenic cells, such as apoptotic cells and giant degenerating cells, in the Tcp10/Nek2 transgenic mice. These results revealed that even only slightly elevated production of the Nek2 protein disturbed the normal development of male germ cells, possibly in meiosis.     

Specific expression of VCY2 in human male germ cells and its involvement in the pathogenesis of male infertility

Abnormal spermatogenesis in men with Y-chromosome microdeletions suggests that genes important for spermatogenesis have been removed from these individuals. VCY2 is a testis-specific gene that locates in the most frequently deleted azoospermia factor c region in the Y chromosome. We have raised an antiserum to VCY2 and used it to characterize the localization of VCY2 in human testis. Using Western blot analysis, the affinity-purified polyclonal VCY2 antibody gave a single specific band of approximately 14 kDa in size, corresponding to the expected size of VCY2 in all the collected human testicular biopsy specimens with normal spermatogenesis. Immunohistochemical analyses showed that VCY2 localized to the nuclei of spermatogonia, spermatocytes, and round spermatids, except elongated spermatids. At the ultrastructural level, VCY2 expression was found in the nucleus of human ejaculated spermatozoa. To determine the possible relationship of VCY2 with the pathogenesis of male infertility, we examined a group of infertile men with and without Y-chromosome microdeletions and with known testicular pathology using VCY2 antibody. VCY2 was weakly expressed at the spermatogonia and immunonegative in spermatocytes and round spermatids in testicular biopsy specimens with maturation arrest or hypospermatogenesis. The specific localization of the protein in germ cell nuclei indicates that VCY2 is likely to function in male germ cell development. The impaired expression of VCY2 in infertile men suggests its involvement in the pathogenesis of male infertility.