Trout Sertoli and Leydig cells: isolation, separation, and culture

The role of the maturation-inducing steroid, 17,20beta-dihydroxypregn-4-en-3-one, in male fishes: a review

The major progestin in teleosts is not progesterone, as in tetrapods, but 17,20beta-dihydroxypregn-4-en-3-one (17,20beta-P) or, in certain species, 17,20beta,21-trihydroxy-pregn-4-en-3-one (17,20beta,21-P). Several functions for 17,20beta-P and 17,20beta,21-P have been proposed (and in some cases proved). These include induction of oocyte final maturation and spermiation (milt production), enhancement of sperm motility (by alteration of the pH and fluidity of the seminal fluid) and acting as a pheromone in male cyprinids. Another important function, initiation of meiosis (the first step in both spermatogenesis and oogenesis), has only very recently been proposed. This is a process that takes place at puberty in all fishes and once a year in repeat spawners. The present review critically examines the evidence to support the proposed functions of 17,20beta-P in males, including listing of the evidence for the presence of 17,20beta-P in the blood plasma of male fishes and discussion of why, in many species, it appears to be absent (or present at low and, in some cases, unvarying concentrations); consideration of the evidence, obtained mainly from in vitro studies, for this steroid being predominantly produced by the testis, for its production being under the control of luteinizing hormone (gonadotrophin II) and, at least in salmonids, for two cell types (Leydig cells and sperm cells) being involved in its synthesis; discussion of the factors involved in the regulation of the switch from androgen to 17,20beta-P production that seems to occur in many species just at the time of spermiation; discussion of the effects of in vivo injection and application of 17,20beta-P (and closely related compounds) in males; a listing of previously published evidence that supports the proposed new function of 17,20beta-P as an initiator of meiosis; finally, discussion of the evidence for environmental endocrine disruption by progestins in fishes.

Nitric oxide: An autocrine regulator of Leydig cell steroidogenesis in the Asian catfish, Clarias batrachus

Nitric oxide has been recognized as an important inter- and intra-cellular modulator of testicular steroidogenesis in higher vertebrates with conflicting results. Moreover, its role in regulation of testicular steroidogenesis in ectothermic vertebrates is non-existent. The present study was, therefore, undertaken to examine whether Leydig cells of a freshwater catfish, Clarias batrachus produce nitric oxide (NO), if so, does it regulate its steroidogenic activity? The purified Leydig cells were stained histochemically for NADPH-diaphorase (NADPH-d) activity, and immunocytochemically for neuronal and inducible nitric oxide synthase (nNOS and iNOS) like molecules. Leydig cells were also incubated with NOS inhibitor, N-nitro-l-arginine methyl ester (l-NAME), and NO donor, sodium nitroprusside (SNP). NO and testosterone released in incubation medium were analyzed. A distinct positive NAPDH-d staining was observed in Leydig cells. These cells also exhibited immunoprecipitation of variable intensity with nNOS and iNOS antibodies. Further, l-NAME treatment caused significant suppression in NO production and elevation in testosterone secretion by Leydig cells. On the contrary, exposure of Leydig cells to SNP resulted in increased NO production with concomitant decline in testosterone level. Thus, the present study reports NO production by Leydig cells in fish for the first time, which appears to inhibit its own androgen production.

In vivo and in vitro effects of prochloraz and nonylphenol ethoxylates on trout spermatogenesis

We investigated the effects of in vivo exposure to non-lethal concentrations of two chemicals commonly discharged into the aquatic environment, prochloraz and nonylphenol diethoxylate (NP2EO - Igepal(R) 210), on the development of spermatogenesis in trout. The in vitro effects on basal and insulin-like growth factor-1 (IGF-I) stimulated DNA synthesis by early germ cells were also studied. In vivo, rainbow trout were exposed for 2 or 3 weeks to waterborne prochloraz (21 and 175 nmol/l) and/or NP2EO (68-970 nmol/l) renewed continuously, or periodically. Only the highest concentrations of NP2EO (225-970 nmol/l) induced a significant increase in blood plasma vitellogenin in juvenile or maturing male trout. When prepubertal fish were exposed for 15 days to prochloraz, the spermatogenetic process was significantly inhibited as shown by the stage of gonadal development reached 3 weeks after exposure. This effect was, to a great extent, reversible within 9 weeks post-exposure. When fish in the initial stage of spermatogenesis were exposed for 21-27 days to 580 nmol/l NP2EO, a 20-40% reduction of the gonadosomatic index was observed 4.5 weeks post-exposure, and the spermatogenetic process was partly inhibited. In vitro, testicular cells obtained at different stages of spermatogenesis were cultured for 4.5 days in the presence or not of the tested molecules and with IGF-I or not. 3H-thymidine (3H-Tdr) incorporation was measured according to Loir (Mol. Reprod. Dev. 53 (1999) 424) and 125I-IGF-I specific binding was determined according to Le Gac et al. (Mol. Reprod. Dev. 44 (1996) 35). Irrespective of the spermatogenetic stage, basal 3H-Tdr incorporation was decreased by prochloraz concentrations > or =10 micromol/l. The presence of IGF-I (10-100 ng/ml) stimulated 3H-Tdr incorporation; this response to IGF-I began to decrease at 25-50 micromol/l prochloraz. In parallel, a dose-dependent increase of IGF-I specific binding was induced by prochloraz 1-100 micromol/l. Similarly, basal and IGF-I-stimulated 3H-Tdr incorporation was decreased by nonylphenol polyethoxylate (NpnEO; starting at 10 micromol/l), NP2EO and NP (30 micromol/l); a dose-dependent increase of IGF-I specific binding was also induced by NP and NPnEO. While 1-100 nmol/l 17beta-estradiol had no effect in our in vitro system, Triton(R) X-100 acted as NPnEO on 3H-Tdr incorporation. Beside their known endocrine disrupting effects on sex steroid production or action, these lipophilic molecules could act on germ cells by disrupting cell membrane receptivity to peptide hormones like growth factors.

Spermatogonia of rainbow trout: III. In vitro study of the proliferative response to extracellular ATP and adenosine

Unlike in higher vertebrates, in fish it is not known whether the nerve supply of the testis can influence testicular functions or not. In addition to neurotransmitters, nerve terminals may release ATP and adenosine in the extracellular medium. On the assumption that these molecules might be released by fibers innervating the teleost testis, it is possible that they participate in the control of testicular function and, maybe, in the control of spermatogonia (Go) proliferation. This study addresses this issue. We have investigated the ability for extracellular ATP and adenosine to influence the in vitro incorporation, either basal or GTH-, IGF-I- and suramin-stimulated, of 3H-thymidine (3H-Tdr) by trout Go. Mixed suspensions of somatic and germ cells prepared from testes, which were immature or spermatogenetic, were cultured usually for 4.5 days in the presence or not of the tested molecules; 3H-Tdr was added during the last day in culture. In our cell culture conditions, 25 to 250 microM adenosine, ATP, ADP, and AMP stimulated the 3H-Tdr incorporation by Go from prespermatogenetic testes and from testes starting spermatogenesis, in a dose-dependent way. The effect of these molecules decreased when the testes were more advanced in spermatogenesis and it became inhibiting when the testes were in mid-spermatogenesis. Five'-N-ethylcarboxamidoadenosine (NECA) was as potent as adenosine in stimulating or inhibiting 3H-Tdr incorporation, while R-N6-(2-phenylisopropyl)adenosine (R-PIA) always had a marked inhibiting effect. Adenosine 5'-O-(3-thiotriphosphate) (ATPgammaS; 25-200 microM), a non-hydrolysable analogue of ATP, which had no effect on Go from prespermatogenetic testes (collected October-February) and from testes in advanced spermatogenesis, stimulated 3H-Tdr incorporation by Go from testes at the beginning of spermatogenesis very efficiently. The order of potency of the different ATP analogues was as follows: ATPgammaS > ATP congruent with alpha,beta-methylene-ATP > UTP > 2-methylthio-ATP. These data suggest that A2 adenosine receptors and P2 receptors would be present on unidentified testicular cells. The stimulating effect of adenosine/ATP was additive with that of either GTH-I or IGF-I or suramin when the cells were from testes at the beginning of spermatogenesis, but adenosine suppressed their effect when the cells were from testes in mid-spermatogenesis. In conclusion, our results suggest that in the trout extracellular adenosine and ATP are able to influence the in vitro proliferation of Go, and are potential candidates for mediating the possible influence of the nervous system on the induction, speeding up, then slowing down of spermatogenesis.

Spermatogonia of rainbow trout: II. in vitro study of the influence of pituitary hormones, growth factors and steroids on mitotic activity

At the present time, in spite of recent advances, knowledge about the factors regulating germ cell proliferation in the teleost testis is limited. This study was designed to investigate, in vitro, the ability of various hormones, growth factors, and steroids to influence the proliferation of trout spermatogonia (Go) present in mixed cultures of somatic and germ cells prepared from testes, either prespermatogenetic or spermatogenetic. The tested molecules were usually present for the duration of culture (4.5 days) and 3H-thymidine (3H-Tdr) for the last day in culture. In our cell culture conditions, homologous gonadotropin I (tGTH-I) and growth hormone (tGH) moderately stimulated 3H-Tdr incorporation by Go, with ED50 equal to 5.5 +/- 3.0 and 1.8 +/- 0.4 ng/ml respectively. Insulin growth factor I (rhIGF-I) and fibroblast growth factor (rhFGF-2) stimulated 3H-Tdr incorporation by Go from spermatogenetic testes only, with ED50 equal to 16.2 +/- 9.3 and 2.4 +/- 0.3 ng/ml respectively. The effects of the most efficient concentrations of rhIGF-I combined with those of either tGTH-I or tGH were additive. Seventy to one hundred microM suramin stimulated 3H-Tdr incorporation by Go from testes at all maturation stages and this effect was additive with that of tGTH-I. We assume that this effect of suramin could result from the inhibition of an unidentified antimitogenic factor. No effect was observed with homologous prolactin, human epidermal growth factor, activin A and B, transforming growth factor-beta1, testosterone, 11-ketotestosterone, 17beta-estradiol, pregnenolone, 11beta-hydroxyprogesterone, and 22-hydroxycholesterol. In conclusion, our in vitro results suggest that GTH-I, GH, IGF-I, and FGF-2, are potent in situ modulators of the proliferative activity of trout Go at the time of induction, speeding up, then slowing down spermatogenesis, through direct or indirect additive and/or antagonistic influences.

Spermatogonia of rainbow trout: I. Morphological characterization, mitotic activity, and survival in primary cultures of testicular cells

Prerequisites of developing in vitro studies for a better understanding of the control mechanisms underlying the proliferation and differentiation of spermatogonia (Go) in the teleost testis are: (1) to be able to identify the different types of Go; (2) to maintain in culture the structural relationships occurring in situ between the various testicular cell types, as intact as possible; and (3) to know how the Go survive and proliferate in culture for several days. After very gentle homogenization of trout testes treated with collagenase, a cell suspension containing mainly spermatocysts (one or several Sertoli cells enclosing one Go or a clone of germ cells) and clusters of myoid cells and Leydig cells was seeded in culture onto a laminin plus fibronectin coating. After 4.5-6 days in culture, then staining with May-Grünwald and Giemsa reagents, the determination of the nuclear and cellular size of the various Go and of the number of Go present in clones has enabled the identification of two types of large Go, in pairs or alone (Go A) and six successive types of smaller Go (Go B). Cell viability determination by staining with Rhodamine 123/propidium iodide (PI)/Hoechst 33342 and with FITC-Annexin V/PI indicated that after 5-7 days in culture, all the somatic cells and most of the Go were viable. Only some of the Go, mainly among the most differentiated ones, underwent apoptosis, as it was the case for a number of spermatocytes and spermatids increasing with the time in culture. Brdu labelling and 3H-Thymidine (3H-Tdr) incorporation indicated that the proliferative activity of Go was at a maximum after 4.5 days in culture and that the response to at least two molecules (QAYL-IGF-I and GTH-I) remained unchanged between 3 and 6 days. As only very scarce somatic cells from immature/spermatogenetic testes synthesized DNA up to 6 days in culture, the measurement of 3H-Tdr incorporation by cells from such testes reliably reflected synthesis of DNA by only the Go (and eventually also by primary spermatocytes when they are present). In conclusion, this study provides information allowing a detailed analysis of the events related with the mitotic phase of spermatogenesis in the trout and it establishes that primary cultures of testicular cells carried out in the reported conditions represent a useful tool to develop an analysis of the mechanisms participating in the control of this phase.

Cell-cell interactions in the testis of teleosts and elasmobranchs

In this paper we present the state of knowledge on cell-cell interactions in the testis of two groups of anamniote vertebrates--teleosts and elasmobranchs--which include most fish. In these fish, the structural organization of the testis differs fundamentally from that which characterizes amniotes in which the germinal tissue is located in tubules open at both ends and consists of a permanent population of Sertoli cells associated with successive stages of germ cell development. In fish, the spermatogenic unit of testis is the spermatocyst, which corresponds to one germ cell or to a clone of isogenetic germ cells, enclosed by one or several Sertoli cells, which form the wall of the cyst. In fish testis, the Sertoli cells do not represent a permanent population of cells. Although both are of the cystic type, the teleost and elasmobranch testes are differently organized. In elasmobranchs, primary spermatogonia and Sertoli cells lie initially free within the interstitial tissue, before becoming sequestered by a basement membrane; the testis is then composed of a mass of spermatocysts which contain many Sertoli cells, each being associated with a clone of germ cells. In contrast, in teleosts, the cysts are confined to large elongated structures limited by a basement membrane. These structures are either lobules originating under the albuginea or tubules which, in contrast to those of mammals, are anastomosed. In the lobules, the spermatocysts start to develop at the blind end of the lobules and migrate towards the efferent system, whereas in the tubules, the spermatocysts are located against the basement membrane, all along the tubules and do not migrate. In elasmobranchs, unlike teleosts, Leydig cells are either absent from the interstitial tissue or rare and undifferentiated and their role in steroid production is at best marginal. While many studies have focused on topographical and functional interactions between the diverse cell types present in mammalian testis, only a few studies have brought particular attention to these aspects in fish. In fish, like in mammals, testicular cell-cell interactions are based on structural elements and chemical factors. Occasionally, various adhering junctions have been observed, essentially in teleosts, between Sertoli cells, between Sertoli cells and germ cells, between germ cells themselves, and interstitial cells. Furthermore, in some teleost species, using horseradish peroxidase or lanthanum salts, the presence of tight junctions between Sertoli cells has been correlated to the occurrence of a Sertoli barrier. In these species, the barrier develops after meiosis so that only haploid germ cells are shielded from the vascular system. In fish, recent development of techniques which enable the preparation and in vitro culture of enriched populations of testicular cells and of spermatocysts, has allowed investigations on functional aspects of cell-cell interactions. In particular, data have been obtained, in the trout, on the control of spermatogonia proliferation by Sertoli cell-conditioned media and, in the dogfish, on the steroidogenic activity of Sertoli cells, in relation to the differentiation stage of the associated germ cells. Furthermore information exists, in the trout, showing that intratubular macrophages may participate in the re-initiation of spermatogonial proliferation. In conclusion, the cytoarchitecture of fish testis, as compared to that of mammals, presents original features which provide unique opportunities to develop fruitful studies for a better understanding of the complex control mechanisms underlying testicular function in vertebrates.

Synthesis and regulation of 17α-hydroxy-20β-dihydroprogesterone in immature males of Oncorhynchus mykiss

Three experimental approaches were chosen to study the question if the progestin 17α-hydroxy-20β-dihydroprogesterone (17α20βOHP) is synthesised in testes of young Oncorhynchus mykiss, in which the absence of spermatozoa was verified histologically: first, in order to detect 20β-hydroxysteroid dehydrogenase activity (20βHSD), testes homogenates were incubated with (3)H-labeled 17αOHP.Metabolites were analysed by TLC, HPLC, and repeated crystallization to constant isotope ratios. One of the metabolites was identified as 17α20βOHP-(3)H, indicating that already immature testes contain 20βHSD activity and are able to produce 20β-reduced steroids. Second, 17α20βOHP was quantified by radioimmunoassay in incubates of testes fragments. The sensitivity of the gonads to gonadotropin II (GtH II) became evident when comparing incubations in the absence and presence of GtH II. Third, plasma levels of 17α20βOHP were significantly higher in animals injected with partially purified salmon gonadotropin, compared to controls. Thus, for the first time, it could be shown that 20βHSD is present in testicular cells other than spermatozoa. Furthermore, 17α20βOHP is indeed secreted at a very early stage of testicular development; 17α20βOHP secretion is also responsive to GtH II. Future studies will have to show if the functions of this progestin include the stimulation of spermatogenesis.

In vitro approach to the control of spermatogonia proliferation in the trout

When spermatogonia and primary spermatocytes (G(o) + CI), uncontaminated by somatic testicular cells, were prepared from trout testes at various maturation stages and cultured alone, basal tritiated thymidine (3H-Tdr) incorporation decreased throughout the reproductive cycle. It was unchanged by salmon gonadotropin (sGtH II), trout growth hormone (rhGH), testosterone, estradiol and 17 alpha, 20 beta-dihydroprogesterone. Conversely, it was dose-dependently stimulated by rhIGF-I, with a mean ED50 of 5.2 ng/ml and a mean maximum stimulation of 3.2-fold above control. When Go + CI were cultured either in the presence of Sertoli cells or in Sertoli cell-conditioned medium (SCCM), basal 3H-Tdr incorporation was always decreased when the Sertoli cells were from spermatogenetic testes, but it was stimulated when they were from testes which were to resume spermatogenesis soon. Whatever the origin of the Sertoli cells, they always partly inhibited IGF-I stimulation. When present during either the co-cultures or the preparation of SCCM, sGtH II and rtGH had no effect when Sertoli cells were from spermatogenetic testes. In conclusion, IGF-I is a direct efficient stimulator of the proliferation of trout male germ cells, the effect of which is partly counteracted by Sertoli cells. sGtH II, rtGH and the 3 tested steroids are not directly active. While sGtH II has no Sertoli cell-mediated activity, further investigation is necessary to clarify whether the other tested molecules have such an activity.

Trout steroidogenic testicular cells in primary culture. II. Steroidogenic activity of interstitial cells, Sertoli cells, and spermatozoa

Somatic cells (interstitial cells and Sertoli cells) were prepared either as single cells or in clusters, from spermatogenic and mature trout testes, according to Loir (1988), and cultured for 10-14 days. Sertoli cells are 3 beta-HSD negative when prepared from testes resuming spermatogenesis and from mature testes, but they are 3 beta-HSD positive in spermatogenic testes. Progesterone, 17 alpha-hydroxyprogesterone (17 alpha-OH-P), and free androgens are secreted by interstitial cells, 11-ketotestosterone (11KT) being the predominating steroid produced immediately after seeding. These cells also produce high levels of glucuronated androgens. At least in mature spermiating testes they do not secrete estradiol. After isolation, interstitial cells would lose most of their ability to secrete 17 alpha-hydroxy,20 beta-dihydroprogesterone (17 alpha 20 beta-OH-P) but they would recover it later. Testicular spermatozoa, which convert 17 alpha-OH-P independently of s-GtH, constitute a second source of this progestagen. In addition, our results suggest that Sertoli cells could be able to secrete 17 alpha-OH-P and also progesterone. A possible participation of the intralobular production of the former progestagen to the local regulation of germ cell maturation is evoked.

Trout steroidogenic testicular cells in primary culture. I. Changes in free and conjugated androgen and progestagen secretions: effects of gonadotropin, serum, and lipoproteins

Isolated trout steroidogenic testicular cells were cultured for 10-15 days, either mixed with other round cells or after enrichment in interstitial cells. Free and conjugated progestagen and androgen secretions were assayed using specific radioimmunoassays (RIA). Free progesterone, 17 alpha-hydroxyprogesterone (17 alpha-OH-P), 17 alpha-hydroxy,20 beta-dihydroprogesterone (17 alpha,20 beta-OH-P), androstenedione, testosterone (T), and 11-ketotestosterone (11KT) were produced by testicular cells prepared from testes in spermatogenesis and mature testes. Discrete amounts of dehydroepiandrosterone (DHA) and of estradiol were secreted by mixed testicular cells prepared from mature testes, but no estradiol was detected in interstitial cell media. Conjugated androgens were produced by interstitial cells. While the production of progestagens by cells from spermatogenetic and mature testes either remained constant or increased throughout culture duration, those of free and conjugated androgens progressively decreased to low values whatever the components added to the medium. When salmon gonadotropin (s-GtH) was present permanently, androgen (free and conjugated) and progestagen secretions were stimulated for 3 to 4 days. When GtH was present discontinuously (1 day in every 3 days), the sensitivity of the cells was maintained for at least 7 days. While the GtH-stimulated/basal ratio was high for androgens, it was rather low for 17 alpha 20 beta-OH-P as compared to the values obtained with testis fragments. Trout serum (5%) stimulated the secretion of free and conjugated T and 11KT when testes were mature, but not when they were in spermatogenesis, while it stimulated 17 alpha 20 beta-OH-P secretion at the two stages. Total trout lipoproteins (125-500 micrograms/ml) stimulated 17 alpha 20 beta-OH-P secretion by cells from spermatogenetic testes, but not 11KT secretion.

Surface location and stage-specificity of differentiation antigens on germ cells in the common carp (Cyprinus carpio), as revealed with monoclonal antibodies and immunogold staining

During development of juvenile and young adult carp (Cyprinus carpio, L., Teleostei) three differentiation stages were distinguished in the testis: the prespermatogenic, the early spermatogenic and the advanced spermatogenic testis. Carp testis tissue of these stages was dissociated by enzymatic digestion and viable testis cells with well preserved morphological features were obtained. The surface location and stage-specificity of differentiation antigens on these germ cells was investigated using monoclonal antibodies (MAbs) raised against carp spermatozoa. Binding of MAbs to cells was visualized with immunofluorescence as well as in the immunogold staining assay. Both methods revealed that antigenic determinants defined by seven MAbs were located on the outer surface of testis cells. Four MAbs, i.e. WCS 3, 17, 28 and 29, reacted with germ cells from both pre-spermatogenic testes (WCS 28 weakly) and spermatogenic testes. The antigenic determinants defined by three other MAbs, i.e. WCS 7, 11 and 12, appeared only after the onset of spermatogenesis. In the immunogold staining assay a post-fixation and nuclear staining procedure was developed which allowed identification of isolated germ cells, revealing clearly, for all seven MAbs, that the determinants were expressed on germ cells but not on somatic cells and, for WCS 7, 11 and 12 only, that the determinants first appeared on small spermatogonia prior to meiosis. A survey of the immunogold assay on the binding of the seven MAbs with isolated germ cells from ovaries, is included.

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 cells. 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.

Evidence for an androgen binding protein in the testis of a teleost fish (Salmo gairdneri R.): a potential marker of Sertoli cell function

A factor binding tritiated testosterone was detected using "steady-state" polyacrylamide-gel electrophoresis, in rainbow trout genital tract. It migrated with a Rf identical to that of rat ABP. This binding was thermolabile, and was competitively inhibited by unlabelled testosterone. The steroid binding protein was found in cytosols from trout testes which had been previously perfused to avoid blood contamination, trout seminal plasma and in testicular explants incubation media. Using a quantitative assay and a Scatchard analysis, 25-50 pmol binding sites per gram gonad were found in testis cytosol. Binding affinity constant for testosterone in the various samples was close to 4 x 10(8) M(-1). The dissociation of steroid-protein complex was rapid (t 1/2 approximately 1.5 min). Hormonal specificity was studied by the competition of 3H-T binding with several concentrations of unlabelled competitors and the following order for affinities was obtained: dihydrotestosterone approximately androstenedione greater than testosterone greater than oestradiol greater than 17 alpha, 20 beta DHP greater than 11KT greater than cyproterone acetate greater than cortisol. High testicular cytosol and seminal plasma concentrations and apparent in vitro production indicate that the testis may synthesize an ABP-like protein in the trout. Such a factor would provide a unique marker of Sertoli cell activity and regulation in various physiological or experimental situations.