In vitro transformation of steroids by the head kidney, the body kidney, and the corpuscles of Stannius of the rainbow trout (Salmo gairdneri)

Star1 gene mutation reveals the essentiality of 11-ketotestosterone and glucocorticoids for male fertility in Nile Tilapia (Oreochromis niloticus)

Steroidogenic acute regulatory protein (Star) plays an essential role in the biosynthesis of corticosteroids and sex steroids by mediating the transport of cholesterol from the outer to the inner membrane of mitochondria. Two duplicated Star genes, namely star1 and star2, have been identified in non-mammalian vertebrates. To investigate the roles of star genes in fish steriodogenesis, we generated two mutation lines of star1-/- and star1-/-/star2-/- in Nile tilapia (Oreochromis niloticus). Previous studies revealed that deficiency of star2 gene caused delayed spermatogenesis, sperm apoptosis and sterility in male tilapia. Our present data revealed that mutation of star genes impaired male fertility. Disordered seminiferous lobules and spermatic duct obstruction were found in the testis of both types of mutants. Moreover, significant decline in semen volume, sperm abnormality and impaired fertility were also detected in star1-/- and star1-/-/star2-/- males. In star1-/- male fish, lipid accumulation, up-regulation of steroidogenic enzymes, and significant decline of androgens were found. Additionally, hyperplasic interrenal cells, elevated steroidogenic gene expression level and decline of serum glucocorticoids were detected in star1 mutants. Intriguingly, either 11-KT or cortisol supplementation successfully rescued the impaired fertility of the star1-/- mutants. Taken together, these results further indicate that Star1 might play critical roles in the production of both 11-KT and glucocorticoids, which are indispensable for the maintenance of male fertility in fish.

Effects of cortisol on female-to-male sex change in a wrasse

Sex change occurs as a usual part of the life cycle for many teleost fish and the modifications involved (behavioural, gonadal, morphological) are well studied. However, the mechanism that transduces environmental cues into the molecular cascade that underlies this transformation remains unknown. Cortisol, the main stress hormone in fish, is hypothesised to be a key factor linking environmental stimuli with sex change by initiating gene expression changes that shift steroidogenesis from oestrogens to androgens but this notion remains to be rigorously tested. Therefore, this study aimed to experimentally test the role of cortisol as an initiator of sex change in a protogynous (female-to-male) hermaphrodite, the New Zealand spotty wrasse (Notolabrus celidotus). We also sought to identify potential key regulatory factors within the head kidney that may contribute to the initiation and progression of gonadal sex change. Cortisol pellets were implanted into female spotty wrasses under inhibitory conditions (presence of a male), and outside of the optimal season for natural sex change. Histological analysis of the gonads and sex hormone analyses found no evidence of sex change after 71 days of cortisol treatment. However, expression analyses of sex and stress-associated genes in gonad and head kidney suggested that cortisol administration did have a physiological effect. In the gonad, this included upregulation of amh, a potent masculinising factor, and nr3c1, a glucocorticoid receptor. In the head kidney, hsd11b2, which converts cortisol to inactive cortisone to maintain cortisol balance, was upregulated. Overall, our results suggest cortisol administration outside of the optimal sex change window is unable to initiate gonadal restructuring. However, our expression data imply key sex and stress genes are sensitive to cortisol. This includes genes expressed in both gonad and head kidney that have been previously implicated in early sex change in several sex-changing species.

Special features of neuroendocrine interactions between stress and reproduction in teleosts

Stress and reproduction are both essential functions for vertebrate survival, ensuring on one side adaptative responses to environmental changes and potential life threats, and on the other side production of progeny. With more than 25,000 species, teleosts constitute the largest group of extant vertebrates, and exhibit a large diversity of life cycles, environmental conditions and regulatory processes. Interactions between stress and reproduction are a growing concern both for conservation of fish biodiversity in the frame of global changes and for the development of sustainability of aquaculture including fish welfare. In teleosts, as in other vertebrates, adverse effects of stress on reproduction have been largely documented and will be shortly overviewed. Unexpectedly, stress notably via cortisol, may also facilitate reproductive function in some teleost species in relation to their peculiar life cyles and this review will provide some examples. Our review will then mainly address the neuroendocrine axes involved in the control of stress and reproduction, namely the corticotropic and gonadotropic axes, as well as their interactions. After reporting some anatomo-functional specificities of the neuroendocrine systems in teleosts, we will describe the major actors of the corticotropic and gonadotropic axes at the brain-pituitary-peripheral glands (interrenals and gonads) levels, with a special focus on the impact of teleost-specific whole genome duplication (3R) on the number of paralogs and their potential differential functions. We will finally review the current knowledge on the neuroendocrine mechanisms of the various interactions between stress and reproduction at different levels of the two axes in teleosts in a comparative and evolutionary perspective.

Survey of the Adrenal Homolog in Teleosts

The adrenal homolog of teleosts is not a compact organ as the adrenal glands of most vertebrates but is composed by aminergic chromaffin and interrenal steroidogenic cells located mostly inside the head kidney that, in this taxon, generally has a hematopoietic function. The two tissues can be mixed, adjacent, or completely separated and line the endothelium of the venous vessels or are located in close proximity. The chromaffin cells in some species are also present in the posterior kidney. Histological and ultrastructural work revealed cytological peculiarities of both types of cells as compared to those of other vertebrate species. In particular, the interrenal ones can show some variations in ultrastructure depending on sex, time of the year, and relation to stress events. A periodic renewal of the whole gland tissue is also sustained by some studies. Research regarding development is scanty as compared to mammals and most studies go back to the early years of the past century. The adrenal homolog of teleosts is under hormonal and neuronal control. Moreover, local paracrine interactions may play an important role in modulating a system involved in stress response and osmoregulation. Most previous studies involved a few species with the object of intensive rearing for commercial purposes; in fact cortisol, the main hormone secreted by the interrenal cells, can also influence reproduction and growth. This review summarizes data from morphocytological work and refers to other excellent reviews regarding physiology. Some of the results are compared to data available from other fishes and vertebrate classes with the aim of including them in an evolutionary and environmental framework.

Expression of cytochrome P450(11beta) (11beta-hydroxylase) gene during gonadal sex differentiation and spermatogenesis in rainbow trout, Oncorhynchus mykiss

Androgens and especially 11-oxygenated androgens are known to be potent masculinizing steroids in fish. As a first step to study their physiological implication in gonadal sex differentiation in fish, we cloned a testicular cytochrome P450(11beta) (11beta-hydroxylase) cDNA in the rainbow trout, Oncorhynchus mykiss. We isolated a 1882 bp P450(11beta) cDNA (rt11betaH2, AF217273) which contains an open reading frame encoding a 552 putative amino acids protein. This sequence was highly homologous (98% in nucleotides and 96.5% in amino acids) to another rainbow trout P450(11beta) sequence (AF179894) and also to a Japanese eel P450(11beta) (68% in amino acids). Northern blot analysis detected a single transcript of 2 kb which was highly expressed in the testis (stage II) and to a lesser degree in the anterior kidney (containing the interrenal tissue). No signal was detected in the posterior kidney, brain, liver, skin, intestine and heart. In the testis this transcript was highly expressed at the beginning of spermatogenesis (stages I and II), followed by a decrease during late spermatogenesis (stages III to V). By semi-quantitative reverse transcription polymerase chain reaction, P450(11beta) expression during gonadal differentiation was estimated to be at least 100 times higher in male than in female gonads. This difference was first detected at 55 days post-fertilization (dpf), i.e. 3 weeks before the first sign of histological sex differentiation, and was sustained long after differentiation (127 dpf). Specific P450(11beta) gene expression was also demonstrated before testis differentiation (around 50 dpf) using virtual Northern blot, with no expression detected in female differentiating gonads. From these results, and also based on the already known actions of 11-oxygenated androgens in testicular differentiation in fish, it is now suggested that P450(11beta) gene expression is a key factor for the testicular differentiation in rainbow trout.

Effects of 17alpha,20beta-dihydroxy-4-pregnen-3-one on cortisol production by rainbow trout interrenal tissue in vitro

Physiological levels of 17alpha,20beta-dihydroxy-4-pregnen-3-one (17, 20-P) stimulated time- and dose-dependent increases in cortisol production by rainbow trout (Oncorhynchus mykiss) interrenal tissue cultured in vitro. Significant stimulation occurred in response to 100, 300, and 1000 ng/ml of 17,20-P. Lower doses were ineffective. Elevated cortisol levels were observed 1 hr after addition of 300 ng/ml 17,20-P. No additive or synergistic interaction was evident between human adrenocorticotropin fragment 1-24 (ACTH1-24) and 17, 20-P in stimulating cortisol secretion, although 300 ng/ml 17,20-P could further enhance cortisol production above levels already stimulated by 300 ng/ml ACTH. 17alpha, 20alpha-dihydroxy-4-pregnen-3-one also stimulated cortisol secretion, but was only half as effective as 17,20-P. Estradiol-17beta, testosterone, and 11-ketotestosterone had no effect on cortisol secretion. Inhibitors of mRNA and protein synthesis had no effect on 17,20-P-stimulated cortisol production. Radiotracer studies demonstrated that the bioconversion of 17,20-P to cortisol could fully account for the cortisol produced by the interrenal in response to 17,20-P and demonstrated that rainbow trout interrenal cells contain an active 20beta-hydroxysteroid dehydrogenase. These data suggest that 17,20-P may be a regulator of cortisol production during the periovulatory period in salmonid fishes.

Metabolism of androstenedione and 11-ketotestosterone in the kidney of the three-spined stickleback, Gasterosteus aculeatus

Stickleback kidneys were incubated with tritiated androstenedione (A4) or 11-ketotestosterone (OT). After the A4 incubations the following steroids were found, testosterone (T), 5 beta-androstane-3,17-dione (5 beta Ad), etiocholanolone (Et), 5 beta-dihydrotestosterone (5 beta DHT), 5 beta-androstane-3 alpha,17 beta-diol (5 beta A3 alpha 17 beta diol), androsterone, 5 alpha-androstane-3,17-dione, 5 alpha-androstane-3 alpha,17 beta-diol (5 alpha A3 alpha 17 beta diol), as well as glucuronides of T, Et, 5 beta DHT, 5 beta A3 alpha 17 beta diol, and 5 alpha A3 alpha 17 beta diol. The metabolites found in the largest amounts were usually T, 5 beta Ad, Et, and the glucuronides of T, Et, and especially of 5 beta A3 alpha 17 beta diol. These results suggest the main pathway to be A4-5 beta Ad-Et-5 beta A3 alpha 17 beta diol-5 beta A3 alpha 17 beta diol-glucuronide or Et-Et-glucuronide-5 beta A3 alpha 17 beta diol-glucuronide. The formation of 5 beta-reduced compounds was larger in postbreeding males and females than in breeding males. The opposite was the case for 5 alpha-reduced compounds. The total formation of glucuronides was lower in the breeding males than in the other groups. After the OT incubations 11-ketoandrostenedione, 17 beta-hydroxy-5 beta-androstane-3,11-dione (tentatively identified), and OT-glucuronide were found. 17 beta-Hydroxy-5 alpha-androstane-3,11-dione was not present.

Progesterone metabolism in the microsomal fraction of the testis, head kidney, and trunk kidney from the rainbow trout

In the present study on male rainbow trout, well-defined microsomal fractions from gonad, trunk kidney, and head kidney were used to study enzymes active on progesterone. The metabolites produced were identified by mass spectrometric analysis. In the testis the main metabolite was 17 alpha-hydroxyprogesterone which is an intermediate in the steroid biosynthetic pathway. 17 alpha-Hydroxyprogesterone was also identified in incubations from head and trunk kidney. The 17 alpha-hydroxylase activity was higher in the head kidney than in the trunk kidney which probably reflects the presence of steroid producing interrenal cells in this part of the kidney. The conversion of progesterone to 17 alpha-hydroxylated products in the testis and head kidney was NADPH dependent and inhibited by carbon monoxide, indicating the participation of cytochrome P450 monooxygenase in this reaction. NADH supported the reaction to some extent (27% of the NADPH-dependent activity) in the testis but not in the head kidney. In addition to 17 alpha-hydroxyprogesterone the head and trunk kidney microsomes gave rise to 16 alpha- and 6 beta-hydroxyprogesterone. These activities were low or absent in testis microsomes. Progesterone 5 alpha-reductase activity was only detected in trunk kidney microsomes.

Regional distribution of microsomal xenobiotic and steroid metabolism in kidney microsomes from rainbow trout

The regional distribution of microsomal cytochrome P-450-mediated reactions with exogenous and endogenous substrates in the kidney of rainbow trout was studied. The cytochrome P-450-dependent 7-ethoxyresorufin- and 7-ethoxycoumarin-0-deethylase activities were significantly higher (3-4 and 10-14 fold, respectively) in the trunk kidney than in the head kidney, whereas ethylmorphine-N-demethylase activity was evenly distributed along the kidney. The microsomal cytochrome P-450-dependent steroid hydroxylases and steroid reducing enzymes when using androstenedione as substrate also exhibited a regional distribution in trout kidney. The 6β- and 16-hydroxylase activities as well as the 5α-reductase and 17 hydroxysteroid oxidoreductase activities were higher in the anterior part of the trunk kidney than in the head kidney and posterior trunk kidney.

Corticosteroid biosynthesis in the interrenal cells of the teleost fish, Oreochromis mossambicus

Applying high-performance liquid chromatography and thin-layer chromatography to separate corticosteroids, we studied the biosynthesis of steroids by the interrenal cells of the head kidneys (the adrenocortical homolog) of Oreochromis mossambicus. Intact head kidneys converted exogenous 17 alpha-hydroxyprogesterone into mainly cortisol, but 11-deoxycortisol, cortisone, and androstenedione were also recovered from the medium. Incubation of intact tissue with pregnenolone in addition resulted in the formation of large amounts of an unidentified product, which was absent in incubations of tissue homogenates with pregnenolone.

The corticosteroid receptor and the action of various steroids in rainbow trout fibroblasts

Corticosteroid binding sites with the characteristics of steroid receptors were detected with the synthetic corticosteroid, [3H]triamcinolone acetonide (TA), in monolayers of the rainbow trout fibroblast cell line, RTG-2. The sites had low capacity as saturation was achieved at approximately 5 nM. Scatchard plots of the data suggested a single population of high-affinity binding sites. The number of receptors per cell was approximately 20,000; the dissociation constant, 1 nM. Changes in [3H]thymidine incorporation and cellular morphology were monitored as potential corticosteroid-sensitive metabolic responses. Only cortisol and 11-deoxycortisol among 14 naturally occurring steroids and TA, fluocinolone acetonide, dexamethasone, and prednisolone among 6 synthetic corticosteroids inhibited [3H]thymidine incorporation and altered the morphology in RTG-2 cells. Two observations suggested that the corticosteroid receptor mediated these responses. The synthetic steroid, RU 38486, which is an antiglucocorticoid in mammals, did not elicit these responses, had a high affinity for the receptor, and blocked the ability of cortisol and TA to change [3H]thymidine incorporation and cellular morphology. Second, the affinity of various natural steroids for the receptor correlated with their ability to elicit a cellular response. Cortisol, and to lesser extent 11-deoxycortisol, showed strong affinity for the receptor. Cortisone, aldosterone, and the sex steroids had no affinity and did not elicit cellular responses.

Gonadotropin stimulated androgen secretion of rainbow trout (Salmo gairdneri Richardson) testis in vitro

1. The secretion of five androgens was quantified from trout testes under GTH-stimulation in vitro before and after the onset of milt production, and a general increase of basal and GTH stimulated androgen secretion was recorded during this period. 2. 11-Ketotestosterone, testosterone, and in spermiating males, 11 beta-hydroxytestosterone as well showed GTH dependent concentration increases, while androstenetrione and 11 beta-hydroxyandrostendione were found in highly variable amounts. 3. 17 beta-Hydroxyandrogen glucuronides in the medium (with the exception of testosterone) and tissue androgens were by far exceeded by the free androgens in the medium.

Cortisol secretion in vitro by the interrenal of coho salmon (Oncorhynchus kisutch) during smoltification: relationship with plasma thyroxine and plasma cortisol

An in vitro system for the incubation of interrenal tissue (head kidney fragments) from coho salmon, Oncorhynchus kisutch, was developed in order to examine changes in interrenal sensitivity to ACTH1-24 during smoltification, using cortisol secretion as the endpoint. Time-course studies indicated that maximal cortisol accumulation in incubation media was achieved after 3 hr exposure to ACTH. There was no correlation between head kidney weight, body weight, or sex and the response of the interrenal to ACTH1-24 in vitro. Approximately monthly or bi-weekly experiments were performed during the smoltification period (February-July): tissue was preincubated in hormone-free media for 3 hr, washed twice, and then challenged with 5 X 10(-10)-5 X 10(-7) M (1.5-1500 ng/ml) ACTH1-24 for 3 hr. The pattern of cortisol secretion was similar in February, early March, and late March in the dose range of 5 X 10(-10)-5 X 10(-8) M ACTH1-24. A marked, significant increase in sensitivity to ACTH and in the steroidogenic capacity of the tissue occurred in April, but by May the response was similar to that in the pre-April period. Enhanced sensitivity and steroidogenic capacity were found in interrenal tissue taken from coho salmon in June and July. Maximal in vitro responsiveness of interrenal tissue to ACTH in April was correlated with peak plasma thyroxine titers and enhanced hypoosmoregulatory ability, but not with peak plasma cortisol titers, which occurred in May.

Effects of natural androgens and corticosteroids on gonad differentiation in the rainbow trout, Salmo gairdneri

Rainbow trout fry were treated with equimolar quantities of cortisol, cortisone, androstenedione, and 11 beta-hydroxyandrostenedione, added to the aquarium water during a 4-week period. All four steroids inhibited ovarian growth. Androstenedione did not influence gonadal sex differentiation; the other steroids pushed the sex ratio in the male direction. However, a near to normal sex ratio was observed 300 days after the 11 beta-hydroxyandrostenedione treatment. When added to the food in two different doses during 8 weeks, 11 beta-hydroxyandrostenedione had a pronounced masculinizing effect, and androstenedione did not modify the gonads at all. It is suggested that the two exogenous corticosteroids were probably converted into 11-oxygenated androstenedione derivatives, and that these 11-oxygenated androstenedione derivatives are particularly important in sustaining the differentiation and early development of the testes in rainbow trout. Testosterone does not seem to be indispensable for these processes, because two different doses of testosterone-blocking cyproterone acetate, added to the food for 8 weeks, failed to affect early gonad development.

Increase of steroid-producing cells in interrenal tissue and masculinization of gonads after long-term treatment of juvenile rainbow trout with cyanoketone

Cyanoketone administered via the food (0.1, 0.2 and 2 mg/g) for 8 weeks from the first feeding (day 46 after fertilization) or via the aquarium water (3 and 30 mg/100 l) for 4 weeks from day 41 does not influence the activity of 3 beta-hydroxysteroid dehydrogenase (3 beta-HSD) in the interstitial cells of the gonads or interrenal cells of juvenile trout in vivo. However, the number of 3 beta-HSD-positive interrenal cells was strongly increased by administration of the highest dose of cyanoketone via both routes. These high doses furthermore affect the sex ratio in favor of males. It is concluded that interrenal tissue is responsible for the masculinizing effect of cyanoketone via increased production of androgens and/or corticosteroids. Cyanoketone at concentrations of 0.01 to 100 micrograms/ml causes a dose-response inhibition of 3 beta-HSD activity in the interrenal cells, when the substance is administered to an incubation medium for demonstration of this enzyme in tissue sections. The controversial in-vivo and in-vitro effects of cyanoketone on 3 beta-HSD activity are discussed.