Testis-testicular gland complex of two Tripterygion species (Blennioidei, Teleostei): differences between territorial and non-territorial males

The morphological differences between the testis and testicular gland of territorial and nonterritorial males of Tripterygion tripteronotus and T. delaisi were examined and correlated with differences in reproductive behaviour. In territorial males of both species the testicular gland is much more developed than in non-territorial males. Larger cellular and nuclear sizes in the territorial males indicate that the activity of the gland cells is enhanced. These cells contain SER, numerous lipid droplets and mitochondria with lamellar cristae. Absence of 3β-HSD activity at these sites points to lack of a steroidogenic potency. In both territorial and non-territorial fish, steroid-producing Leydig cells have been demonstrated in the connective tissue betweeen the testis and the testicular gland, and around the collecting sperm duct. In addition, 3β-HSD activity has been found in the scarce interstitial Leydig cells of territorial fish. Morphometric data indicate an enhanced activity of the Leydig cells in territorial fish.     

PROCESS OF FUNCTIONAL SEX REVERSAL OF THE GONAD IN THE FEMALE GUPPY, POECILIA RETICULATA, TREATED WITH ANDROGEN BEFORE BIRTH

In the guppy, Poecilia reticulata , ovarian differentiation occurs during the embryonal life by 14 days after the preceding parturition. Testicular differentiation begins with the appearance of prominent aggregations of stroma cells in the gonadal hilus occurring by 18 days following the last parturition.
Oral administration of methyltestosterone (400 μ/g diet) to gravid guppies, begun 13–15 days after the preceding parturition and continued until the end of gestation, induced a male-type aggregation of somatic cells in the hilus of ovaries of female embryos. Gonads of newly born, androgenized females still had developing oocytes but were always provided with atypical clusters of stroma cells in their hilus. The gonads of affected female offspring developed successively into definite testes within 20 days after birth, displaying a precocious differentiation of the hilar stroma into sperm ducts and testicular interstitium, a concomitant initiation of spermatogenesis, and a conspicuous degeneration of oocytes. A successful masculinization of the somatic element, which may occur prior to that of the germ cells, in androgen-affected embryonic ovaries seems to be essential for the functional sex reversal of genetic females in the guppy.     

Occurrence of an accessory cavity in the testis of the topmouth gudgeon,Pseudorashora parva,and its relation to juvenile intersexuality

The structure of the testis-sperm duct system of the topmouth gudgeon,Pseudorasbora parva, was examined histologically. In almost all of the young and adult males examined, a cavity was found to exist between the dorsomedian side of the testis and the opposed peritoneal wall. The testicular cavity was generally flat in shape and ran along the entire length of the testis, with a blind end at the level of the common sperm duct. It appeared that the testicular cavity was not implicated in the transport and storage of spermatozoa in the fish. By studying the process of differentiation and development of gonads in juvenile fish, it was confirmed that some germ cells in differentiating testes underwent oogenesis in many cases, and that the cavity was formed by fusion of the distal edge of the testes with the peritoneal wall in quite the same manner as the ovarian cavity. Thus, the testicular cavity of the topmouth gudgeon is homologous with the ovarian cavity and is apparently a preserved vestige of juvenile intersexuality occurring in this species of cyprinid teleosts.     

Histology and histochemistry of the testis and ovary of the platyfish,Xiphophorus maculatus,from birth to sexual maturity

Summary The gonads of 3-day- to 7-month-old male and female platyfish (Xiphophorus maculatus) were examined for the presence of 5-3-hydroxysteroid dehydrogenase (3-HSD) and glucose-6-phosphate dehydrogenase (G6PD) by histochemical means. In 3-day-old males a positive response for both enzymes is localized in the Leydig cells. With subsequent testicular development, these cells increase in number and display greater activity at the periphery of the testis and around the efferent ducts. In 3-day-old females 3-HSD and G6PD are localized in the stromal cells of the ovary. These cells increase in number and activity as the animals become sexually mature. Sertoli cells, efferent duct epithelium, and ovarian granulosa cells are negative at all stages of development examined. Our findings suggest that the gonads of neonatal fish possess the potential for steroidogenesis. The role played by sexsteroid hormones in the maturation of the brain-pituitary-gonad axis is discussed.     

Immunolocalization of steroidogenic enzymes in gonads of European eel, Anguilla anguilla (L.)

The localization of cytochrome P450 cholesterol side-chain cleavage (P450scc), 3β-hydroxysteroid dehydrogenase (3β-HSD) and aromatase (P450arom) was investigated using polyclonal antibodies during gonad development in wild European eels, Anguilla anguilla (L.), from the River Po Delta (Ferrara, Italy). The first steroidogenic cells, observed in undifferentiated gonads of 14–16 cm yellow eels, showed no P450scc, 3β-HSD or P450arom activity, but positive regions appeared in head kidney insulae from this stage until the silver eel stage. In undifferentiated gonads of 16–20 cm yellow eels the steroidogenic cells were positive to all enzymes. Pre-Leydig steroidogenic cells, identified in Syrski organs of yellow eels of 22–26 cm evolving into testes, were positive to 3β-HSD and P450scc, but negative to P450arom. However, steroidogenic cells in Syrski organs evolving towards ovaries and in small but fully differentiated ovaries were positive to all enzymes. Immature testes of yellow and silver eels had Leydig cells positive to P450scc and 3β-HSD; the same reactions were also observed in some Sertoli cells of silver eel testes containing meiotic cells. Sex differentiation in A. anguilla apparently occurs through an initial female stage controlled by P450arom activity. Leydig and Sertoli cells appear involved in different steps of hormonal control of spermatogenesis: Leydig cells begin their steroidogenic activity before meiosis, while Sertoli cells begin their activity during meiosis.     

Histological, fine-structural and histochemical differences in the testicular glands of gobiid and blenniid fishes

The testicular gland (t.g.) is a glandular tissue situated adjacent to the testis of blenniid and several gobiid species. In the present study the t.g. of Blennius pavo Risso and Gobius niger L. were compared by histological and histochemical methods. In B. pavo the spermatozoa have to cross the t.g. to reach the vas deferens and thus they come into contact with the gland cells, whereas in G. niger the vas deferens is situated between the testis and the t.g. The fine structure and histo-chemistry of the t.g. cells reveal that in B.pavo the cells of the t.g. have exocrine as well as endocrine functions. The t.g. cells of B. pavo contain large amounts of lipids, form a secretion containing acid mucopolysaccharides, show positive reaction for acid phosphatase, and some cells stain for 3β-HSD and G6PD. The function of the t.g. of G. niger is exclusively endocrine. Characteristics of the gland cells of this species are well developed smooth ER and tubulovesicular or paracristal-line mitochondria. The stainings for 3β-HSD, G6PD and UDPGD give strong positive results in the whole t.g., indicating the presence of steroids and steroid glucuronides.     

Differentiation-related changes in the distribution of glycoconjugates in rat testis.

The distribution of glycoconjugates in differentiating rat testis was investigated by fluorescein labeled lectins during embryogenesis and postnatal development. Double immunofluorescence with rhodamine coupled laminin antibodies was used to delineate testicular cords from the interstitium in embryonic testes. Rat testis was found to be rich in various glycoconjugates, with distinct differentiation-related changes in their distribution. All types of germ cells contained carbohydrate rich compounds in their cytoplasm. Glycosylation in the embryonic testis was different from that in the adult rat. At an early stage of testicular differentiation, the labeling of germ cells and other testicular cells was almost identical. The lectin binding patterns of embryonic germ cells and somatic cells were related to the developmental age of the animal, with a graded disappearance of galactose containing glycoconjugates in embryonal spermatogonia. Spermatogenic cell differentiation was characterized by striking changes in lectin binding patterns of germ cells, particularly in the acrosomes of developing spermatids, in relation to their functional activation and the emergence of adult type of glycosylation during the postnatal maturation of the testis. As the knowledge of regular glycosylation throughout tissue differentiation is of significance for the analysis of aberrant glycosylations occurring in pathologic disorders, our findings suggest the usefulness of lectin histochemistry for the studies on germ cell differentiation.     

Differentiation-related changes in the distribution of glycoconjugates in rat testis

Summary The distribution of glycoconjugates in differentiating rat testis was investigated by fluorescein labeled lectins during embryogenesis and postnatal development. Double immunofluorescence with rhodamine coupled laminin antibodies was used to delineate testicular cords from the interstitium in embryonic testes. Rat testis was found to be rich in various glycoconjugates, with distinct differentiation-related changes in their distribution. All types of germ cells contained carbohydrate rich compounds in their cytoplasm. Glycosylation in the embryonic testis was different from that in the adult rat. At an early stage of testicular differentiation, the labeling of germ cells and other testicular cells was almost identical. The lectin binding patterns of embryonic germ cells and somatic cells were related to the developmental age of the animal, with a graded disappearance of galactose containing glycoconjugates in embryonal spermatogonia. Spermatogenic cell differentiation was characterized by striking changes in lectin binding patterns of germ cells, particularly in the acrosomes of developing spermatids, in relation to their functional activation and the emergence of adult type of glycosylation during the postnatal maturation of the testis. As the knowledge of regular glycosylation throughout tissue differentiation is of significance for the analysis of aberrant glycosylations occurring in pathologic disorders, our findings suggest the usefulness of lectin histochemistry for the studies on germ cell differentiation.     

Germ cell deficiency causes testis cord differentiation in reconstituted mouse fetal ovaries

Sex-reversal in fetal ovaries was studied by using a dissociation-reconstitution technique. Gonads of 12.5 gestation-day male and female mouse fetuses were dissociated into single cells. To eliminate germ cells, the dissociated cells were cultured for 14 h, and then somatic cells attached to culture dishes were harvested and aggregated by gyratory culture for 24 h. The aggregates were then transplanted into ovarian bursa in ovary-ectomized nude mice. The recovered explants were examined histologically. Male somatic cells developed into testes containing Sertoli cells, Leidig cells, and tunica albuginea. Female somatic cells formed testis cords and differentiated into Sertoli cells, but they did not differentiate into other testis components or ovarian tissues. However, aggregates consisting of both female and male somatic cells differentiated into well-developed testes containing Leidig cells and tunica albuginea as well as Sertoli cells. Enzyme marker analysis showed significant contributions of female cells in these organized testes. In contrast, aggregates containing both female germ cells and somatic cells developed into ovaries and did not differentiate into any testicular tissues. The results indicate that female somatic cells in fetal gonads at 12.5 gestation day have the potency to form testis cords and differentiate into Sertoli cells. The subsequent steps in testis development require the contributions of male cells. The present study also suggests that testicular differentiation is independent of germ cells but ovarian development involves the interaction between germ cells and somatic cells.     

Trout sertoli and leydig cells: Isolation,separation, and culture

Trout testes at various stages of maturation were dissociated by perfusion at 12°C with collagenase plus pronase and then with collagenase alone, followed by slight shaking overnight in 1% bovine albumin. This step provided a suspension of isolated somatic and germ cells, clusters of interstitial cells, and either intact spermatogenetic cysts (meiotic testes) or clusters of Sertoli cells (other testes). Most of the spermatozoa were removed from the testis cell suspension by centrifugation in Percoll (density 1.065 g/ml). Sertoli and Leydig cells were prepared by a two-step separation method: (1) the testis cell suspension was separated by sedimentation at unit gravity into “isolated cell” and “cell cluster” populations; (2) these populations were fractionated by isopyknic centrifugation in Percoll gradients. In terms of somatic cell composition, a nearly pure Sertoli cell (clusters) population was obtained between 1.017 and 1.033 g/ml and a Leydig cell (clusters) enriched population of between 1.033 and 1.048 g/ml (testes resuming spermatogenesis) or 1.048 and 1.062 g/ml (other testes). These various cell populations were cultured in modified Leibovitz L15 medium for 10–15 days. When seeded, the Sertoli cells had a normal ultrastructure that remained unchanged for at least 10 days, and the steroidogenic activity of Leydig cells could be stimulated by salmon gonadotropin. Leydig cells remained 3β-HSD positive and produced progesterone and 17α, 20β-OH progesterone for at least 11 days. This study points out that viable and differentiated trout somatic testicular cells can be prepared and cultured for several days.     

A study on the 3β- and 17β-hydroxysteroid dehydrogenase activities in the gonads of Monopterus albus (Pisces: Teleostei) at various sexual phases during natural sex reversal

Activities of 3β-hydroxysteroid dehydrogenase (3β-HSD) and 17β-hydroxysteroid dehydrogenase (17β-HSD) in Monopterus gonads were studied at different sexual phases during natural sex reversal. Before sexual transformation, positive reactions for 3β-HSD in the follicular epithelium were found in the granulosa cells of some large, maturing follicles in some females during the breeding season. Weak reaction for this enzyme was also detected in some scattered interstitial cells found occasionally in some ovaries. At the intersexual and the male phases, intense 3β-HSD activities were demonstrated exclusively in the interstitial Leydig cells. No 17β-HSD activities were observable in the gonads at any stage of development. The reaction intensity of 3β-HSD in the interstitial cells exhibited a marked increase during the process of sex change from female to the intersexual and the male phases and there is a definite correlation with the density and nuclear size of these cells. It is concluded that in Monopterus , the granulosa cells in the ovary and the interstitial cells of the intersexual and male gonads are the major sites for the biosynthesis of oestrogens and androgens, respectively, and that the intensive development of interstitial tissue with increasing steroidogenic enzyme activities at the intersexual and male phases was directly related to the increase in androgen production in vitro reported previously. The occasional presence of some 3β-HSD positive interstitial cells in the ovary suggests that interstitial cell development might precede testicular lobule formation during natural sex reversal.     

Immunocytochemical localization of 17β-hydroxysteroid dehydrogenase in porcine testis

Summary The immunocytochemical localization of 17-hydroxysteroid dehydrogenase (17-HSD) in porcine testes was examined by applying an indirect-immunofluorescence method using an antiporcine testicular 17-HSD antibody. Only the Leydig cells located in the interstitial tissue exhibited a positive immunoreaction for 17-HSD: the germ cells and Sertoli cells located in the seminiferous tubules were entirely negative. These results suggest that, in porcine testis, the biosynthesis of testicular testosterone, the final step of which is the conversion of androstenedione to testosterone, takes place in the Leydig cells.Supported by grants from the Ministry of Education, Science, and Culture, Japan     

Efficacy of exemestane,a new generation of aromatase inhibitor,on sex differentiation in a gonochoristic fish

We report the first use of exemestane (EM), a steroidal aromatase inhibitor (AI) commercially known as aromasin, in studies of sex differentiation in fish. The effectiveness of EM was examined in two different age groups of the gonochoristic fish, Nile tilapia (Oreochromis niloticus). Untreated control fish (all female) showed normal ovarian differentiation through 120 days after hatching (dah), whereas fish treated with EM at 1000 and 2000 µg/g of feed from 9 dah through 35 dah, the critical period for sex differentiation, exhibited complete testicular differentiation; all stages of spermatogenic germ cells were evident and well developed efferent ducts were present. Fish treated with EM at 1000 µg/g of feed from 70 dah through 100 dah significantly suppressed plasma estradiol-17β level and increased level of 11-ketotestosterone. Furthermore, untreated control fish showed strong gonadal expression of the steroidogenic enzymes P450 cholesterol-side chain-cleavage enzyme (P450scc), 3β-hydroxysteroid dehydrogenase (3β-HSD), and cytochrome P450 aromatase (P450arom). In contrast, EM-treated fish showed immunopositive reactions against P450scc and 3β-HSD but not against P450arom in interstitial Leydig cells. These results indicate that treatment of tilapia juveniles with EM during sex differentiation leads to the development of testes, apparently by a complete suppression of aromatase activity.     

A sex cord‐like structure and some remarkable features in early gonadal sex differentiation in the marine teleost Siganus guttatus(Bloch)

Several notable features of early gonadal sex differentiation in the golden rabbitfish Siganus guttatus are described including the first report among teleosts of a distinctive dual structure, consisting of somatic cells directly enclosing germ cells (sex cord‐like structure, SCS) and outer somatic tissue surrounding the SCS, in both undifferentiated and early differentiated gonads. Germ cells occurred and proliferated exclusively in the SCS during the process of ovarian and testicular differentiation. A second remarkable characteristic was the delayed germinal cell proliferation for oogenesis in the ovary, that commenced simultaneously with that in the testis, a relatively long time after the onset of somatic development. These observations suggest the possibility that sex differentiation of germ cells is preceded by some sex specific changes in somatic components of the SCS that are light‐microscopically indistinguishable between the sexes. The third unique feature was the detachment of gonadal tissue, including both somatic and germ cells, into the ovarian cavity in the ovary and into the seminiferous lobules and main seminal duct in the testis. This phenomenon occurred in the testis, forming the efferent duct network after 73 days post‐hatch (DPH), and in the ovaries, forming the ovigerous lamellae and regulating the number of oocytes attaining full maturation at c . 129 DPH.     

Characterization and inducibility of hsp 70 proteins in the male mouse germ line

The properties and inducibility of the heat shock protein 70 (hsp 70) gene products were examined during differentiation of mouse testicular cells by one and two-dimensional gel electrophoresis and immunoblotting. Low levels of the 72- and 73-kD heat shock proteins normally found in mouse cell lines were detected in the mouse testis. A novel isoform with a relative molecular mass of 73 kD (called 73T) was also observed, in the presence or absence of heat shock. 73T was shown to be produced by germ cells since it was not detected in testes from mutant mice devoid of germ cells. Furthermore, 73T was found only in adult mouse testicular cells, not in testes from animals that lack meiotic germ cells. 73T was synthesized in enriched cell populations of both meiotic prophase and postmeiotic cells, but was not inducible by in vitro heat shock. In the adult testis, low levels of the bona fide 72-kD heat-inducible (hsp72) were induced in response to elevated temperatures. In contrast, in testes from animals in which only somatic cells and premeiotic germ cells were present, there was a substantial induction of hsp 72. It is suggested that hsp 72 is inducible in the somatic compartment and possibly in the premeiotic germ cells, but not in germ cells which have entered meiosis and which are expressing members of the hsp 70 gene family in a developmentally regulated fashion.     

Histochemical detection of steroid synthesizing cells in the testes of goldfish,Carassius auratus,during the annual reproductive cycle

We investigated the sites of Δ⁵-3β-hydroxysteroid dehydrogenase (3 β-HSD) and glucose-6-phosphate dehydrogenase (G-6-PD) synthesis in the testes of goldfish, Carassius auratus, during the annual reproductive cycle. The histochemistry of fish gonads has been investigated previously in many species other than goldfish. The reproductive cycle of goldfish, is divided into five stages and the steroid synthesizing cells of the testes were studied during these stages, using histochemical techniques. We found that interstitial cells and seminiferous tubules are the main steroid synthesizing sites in testes of goldfish, and that enzyme activity was more intense in the interstitial cells than in the seminiferous tubules. During the pre-spawning months, 3 β-HSD and G-6-PD activities were weak compared to the spawning months.     

Functions of the testicular gland in two blenniid fishes, Salaria (=Blennius) pavo and Lipophrys (= Blennius) dalmatinus (Blenniidae, Teleostei) as revealed by electron microscopy and enzyme histochemistry

The functions of the testicular gland in two different blenniid fishes, Salaria pavo and Lipophrys dulmutinus , are described by fine structural and enzyme histochemical methods. In the testes of the two fishes no mature spermatozoa are found. Sperrniogenesis occurs only until the spermatidal stage. Spermatids are released into the testicular gland. During the spawning period the testicular gland functions in differentiation of spermatids, nutrition of spermatids, and secretion of sialomucins. After spawning, the testicular gland has phagocytotic functions in resorbtion of remaining spermatids, which are transformed into lipids in the gland cells. During the interspawning period the testicular gland is a storage reservoir for lipids and phospholipids which are re-transformed into testicular gland secretion in the next reproductive season. Testicular gland cells themselves do not have steroidogenetic functions, but steroids are synthesized by interstitial cells homologous to Leydig cells in other fish. Possible explanations for the reduction of the testis in L. dalmatinus and implications of the testicular gland in taking over testicular functions are discussed.     

Influence of adenosine 3':5'-cyclic monophosphate analogues on testicular organization of fetal mouse gonads in vitro

Gonadal primordia, isolated from fetal mice on the 11th or 12th day of gestation, differentiated in vitro into morphologically distinct testes or ovaries after 7 days in culture. The addition of cAMP analogues into culture media prevented the differentiation of testis cords. Histological examination indicated that the basement membranes of testis cords disintegrated after treatment with cAMP analogues, while development of germ cells and Leydig cells appeared to be unaffected. Fetal testes in culture secreted testosterone which increased following addition of dibutyryl-cAMP (Bt2 c-AMP). Primordial germ cells reached prespermatogonial stage in the presence or absence of Bt2 cAMP, suggesting that progressive differentiation of primordial germ cells is independent of testis cord organization. The Bt2 cAMP-treated explants resumed testicular development after transplantation into a site beneath the kidney capsules of adult mice, although the inhibitory effect appeared irreversible in vitro. The testicular organization-preventing effect of cAMP analogues was mimicked by prostaglandins or forskolin, which are known to stimulate adenylate cyclase. The inhibitory effect of either cAMP analogues or prostaglandins was potentiated when added in combination with phosphodiesterase inhibitors. The present results suggest that increase of intracellular cAMP prevents the development of basement membrane and the assembly of cells to form testicular structures.     

Differentiation of adult Leydig cells

Adult Leydig cells originate within the testis postnatally. Their formation is a continuous process involving gradual transformation of progenitors into the mature cell type. Despite the gradual nature of these changes, studies of proliferation, differentiation and steroidogenic function in the rat Leydig cell led to the recognition of three distinct developmental stages in the adult Leydig cell lineage: Leydig cell progenitors, immature Leydig cells and adult Leydig cells. In the first stage, Leydig cell progenitors arise from active proliferation of mesenchymal-like stem cells in the testicular interstitium during the third week of postnatal life and are recognizable by the presence of Leydig cell markers such as histochemical staining for 3β-hydroxysteroid dehydrogenase (3β-HSD) and the present of luteinizing hormone (LH) receptors. They proliferate actively and by day 28 postpartum differentiate into immature Leydig cells. In the second stage, immature Leydig cells are morphologically recognizable as Leydig cells. They have an abundant smooth endoplasmic reticulum and are steroidogenically active, but primarily produce 5-reduced androgens rather than testosterone. Immature Leydig cells divide only once, giving rise to the total adult Leydig cell population. In the third and final stage, adult Leydig cells are fully differentiated, primarily produce testosterone and rarely divide. LH and androgen act together to stimulate differentiation of Leydig cell progenitors into immature Leydig cells. Preliminary data indicate that insulin like growth factor-1 (IGF-1) acts subsequently in the transformation of immature Leydig cells into adult Leydig cells.     

Establishment and characterization of a testicular cell line from the half-smooth tongue sole, Cynoglossus semilaevis

Spermatogenesis within the adult testis is an excellent system for studying stem cell renewal and differentiation, which is under the control of testicular somatic cells. In order to understanding spermatogenesis in the half-smooth tongue sole (Cynoglossus semilaevis) as a marine fish model of aquaculture importance, we established a cell line called CSGC from a juvenile gonad of this organism. CSGC is composed of fibroblast-like cells, retains a diploid karyotype of 42 chromosomes, lacks the heterogametic W chromosome, lacks a female specific marker and expresses the dmrt, a marker for testicular somatic cells. Therefore, CSGC appears to consist of testicular somatic cell cells. We show that this cell line is effective for infection by the turbot reddish body iridovirus and flounder lymphocystis disease virus as evidenced by the appearance of cytopathic effect and virus propagation in the virus-infected cells, and most convincingly, the observation of viral particles by electon microscopy, demonstrateing that CSGC is suitable to study interactions between virus and host cells. As a first fish testicular somatic cell line of the ZZ-ZW genetic sex determination system, CSGC will be a useful tool to study sex-related events and interactions between somatic cells and germ cells during spermatogenesis.