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OPINION article

Front. Endocrinol., 18 February 2022
Sec. Experimental Endocrinology
This article is part of the Research Topic New Vistas in Fish Reproduction and Molecular Endocrinology: Mechanisms and Applications View all 3 articles

Sex Specific Transcriptional Regulation of Gonadal Steroidogenesis in Teleost Fishes

  • Department of Zoology, Hemvati Nandan Bahuguna (HNB) Garhwal University, Pauri Garhwal, India

Introduction

Fishes are developmentally diverse and economically essential organisms (1). Teleost fishes show remarkable gonadal plasticity by representing both gonochorism (one sex at a time) and hermaphroditism (more than one sex) (13). Gonochoristic teleosts mature as either males or females and remain in such sexual identity throughout adulthood, whereas hermaphroditic species are plastic in terms of sex-reversal signals, i) protogynous (female to male e.g. gilt-head sea bream Sparus auratus, bluehead wrasse Thalassoma bifasciatum), ii) protandrous (male to female e.g. clown fish Amphiprion sp, Premnas sp, Rice filed eel Monopterus albus and black porgy Acanthopagrus schlegeli) or iii) in both directions for multiple times (e.g. Okinawa goby Trimma okinawae, cleaner wrasse Labroides dimidiatus and monogamous coral-dwelling gobies Paragobiodon and Gobiodon) (1, 4). Sexual identity is controlled by social cues and environmental stimuli that operate via the cross-talk between hypothalamus–pituitary–gonadal (HPG) and hypothalamus–pituitary– inter-renal (HPI) axes involving neuro-endocrine factors like kisspeptin, dopamine, gonadotropin- releasing hormone (GnRH), gonadotropins (FSH and LH) and gonadal steroids like 17β-estradiol (E2) and testosterone (T) (57). Gonadal cells initiate the steroidogenic cascade under the influence of FSH and LH by transporting cholesterol from cytosolic lipid droplet to mitochondrial inner membrane via Steroidogenic acute regulatory protein (StAR) followed by its rate limited conversion to pregnenolone via P450scc enzyme (Cholesterol side chain cleavage enzyme) coded by Cyp11a1 gene (8). Pregnenolone then gets converted to T through multiple steps prior to the synthesis of bio-active male androgen i.e. 11-Keto-Testosterone (11-KT) or female specific E2. The production of E2 from T depends on P450- aromatase enzyme coded by Cyp19a1a gene in ovaries whereas, T gets converted to 11- hydroxy-androstenedione (11-OHA) by 11β-hydroxylase enzyme coded by Cyp11b gene and subsequently 11-OHA acts as a substrate for 11β-hydroxysteroid dehydrogenase (11β-HSD) enzyme coded by Hsd11b2 gene to produce 11-KT in testes (1, 68).

Experimental feminization of XY fries and/or masculinization of XX fries have been successfully achieved by administration of exogenous E2 or T for two months respectively (9, 10) despite having a robust genetic mechanism for sex determination (GSD) in medaka Oryzias latipes (11, 12). Furthermore, long term depletion of endogenous P450 aromatase by fadrozole in adult teleosts like mekada (13), Nile-tilapia Oreochromis niloticus (14) or zebra-fish Danio rerio (15) results into functional female to male sex reversal. Consistently, a dramatic shift in plasma sex steroids also has been reported during gonadal trans-differentiation observed in natural sex changing fishes (3). For example, in protogynous species a severe decline in E2 leads to ovarian regression followed by a gradual elevation in circulatory 11-KT, whereas in protandrous fishes E2 concentration rises with the decline of 11-KT level (2, 16). However, in bidirectional sex change, only E2 (not 11-KT) shows such sexual shift in the circulatory pattern (2, 16). Therefore, the critical balance between the bio-conversion rates of T to either E2 or 11-KT exclusively directs the sexual fate, reproductive maturation and fertility potential in fishes. The seasonal reproductive cyclicity of fishes is broadly categorized into five stages i) Resting Phase ii) Preparatory/Recrudescence Phase iii) Pre-Spawning/Developing Phase iv) Spawning Active/Capable Phase v) Post-Spawning/Regressing/Spent Phase (17). Intriguingly, a drastic steroidogenic shift occurs in post-vitellogenic (Spawning Phase) ovaries during meiotic maturation of oocytes involving an inhibition of FSH signal leading to the suppression of Cyp19a1a promoter and thereby decline in E2 production with subsequent LH mediated activation of 20β-Hsd promoter for the production of maturation inducing steroids [17α,20β-DPs (17α,20β-dihydroxy-4-pregnen-3-one or 17α,20β,21-trihydroxy-4-pregnen-3-one)] (6, 8, 18). Similarly, a dominant upregulation of Hsd11b2 promoter activity has been reported in testes ensuring the rise in 11-KT level in spawning males. Therefore, a complex interplay among the multiple cis acting sequences/elements and respective trans acting factors collectively regulate the sex specific differential promoter activities of the genes coding for key steroidogenic enzymes in teleost gonads (8). Although brain, kidney, liver and adipose tissues are other potential sites of steroidogenesis in fishes, we here briefly highlight the critical contribution of major transcription factors regulating gonadal steroidogenic output to determine fish reproduction.

Glucocorticoid Receptors

Corticosteroid like cortisol produced from adrenal glands acts via glucocorticoid receptor (GR) and critically regulates the promoter function of Cyp19a1a and Cyp11c1/Cyp11b or Hsd11b2 genes thereby fixing the E2: 11-KT concentration (2, 5). Cortisol induced GR blocks the aromatase enzyme in the ovaries of pejerrey Odontesthes bonariensis (19) or Japanese flounder Paralichthys olivaceus (20) and induces the promoter activity of Hsd11b2 in the testes of pejerrey (21) or European eel Anguilla anguilla (22) in male favourable temperatures.

Foxl2

FOXL2 (Forkhead transcription factor 2), member of the winged helix/fork-head group of proteins is known for ovarian differentiation (23). Fox genes like Foxc1, Foxl2, Foxl3(a germ cell intrinsic transcription factor determinant of sexual fate in medaka) have been shown to determine the ovarian function (23). In ovary, FOXL2 suppresses Dmrt1 and upregulates female programming genes like Cyp19a1a, Rspo1 and Wnt4/βcatenin etc and support E2 production (23, 24). The co-localizations of FOXL2 and P450 aromatase enzyme in the ovaries of adult medaka (25), Nile-tilapia (2629) and Japanese flounder (30) suggest the critical involvement of FOXL2 in transcriptional regulation of Cyp19a1a and E2 production. In medaka, FOXL2 protein is initially detected in the germline stem cells and maintained thereafter throughout the meiotic progression (23). In Nile-tilapia, the promoter region of Cyp19a1a possesses the core element ACAAATA from -545 to -538 known for the binding site for FOXL2 (27). Over-expression of Foxl2 dominant negative mutant in XX tilapia triggers female to male reversal (27), whereas the loss of Foxl2 in XX tilapia leads to female to male reversal (27, 3133). In Japanese flounder FOXL2 directly activates the Cyp19a1a gene transcription by binding to the forkhead- responsive site (30).

Ad4BP/SF-1

Ad4 Binding Proteins/Steroidogenic Factor1 (AD4BP/SF-1) or Fushi Tarazu factor 1 (FTZ-F1) is an orphan nuclear receptor under subfamily 5 group A member 1 (NR5A1) that gets co-localized in the interstitial cells of pre-vitellogenic ovary and granulosa cells of the vitellogenic follicles along with FOXL2 and P450 aromatase in medaka (34, 35) and Nile-tilapia (27). Although in TM3 cell lines and granulosa cells of Nile-tilapia, FOXL2 alone can activate the gene transcription of Cyp19a1a as both these cells contain endogenous Ad4BP/SF-1, FOXL2 alone fails to show such impact on the Cyp19a1a promoter in HEK293 cells (27). However, with co-transfection of Ad4BP/SF1 and Foxl2, the P450 aromatase promoter gets pronouncedly activated indicating Foxl2 and Ad4BP/SF1 act synergistically to augment Cyp19a1a transcription (36). On the other hand, Ad4BP/SF-1 binds to two FF1 response elements on the promoter of Cyp11a1 gene and upregulates its transcription in zebra-fish (37).

Dax1

DAX1 (Dosage- sensitive sex reversal adrenal hypoplasia congenital critical region on the X chromosome, gene 1), an orphan receptor is a member of the nuclear receptor superfamily (NR0B1). Dax1 is expressed in adrenal cortex, gonads, ventromedial hypothalamus and pituitary gonadotrophs potentially crucial for testis differentiation (3840). The expression of Dax1 is up-regulated by androgen in rainbow trout Oncorhynchus mykiss during ovary to testis transition (41). In medaka, DAX1 has only one LXXLL- related motif in N-terminal and is involved in repressing E2 synthesis in ovarian follicles (36). In medaka co-transfection of Dax1 along with AD4BP/SF-1 and Foxl2 in a dose dependent manner leads to a significant decline in the activity of Cyp19a1a promoter indicating that DAX1 negatively regulates Cyp19a1a expression by suppressing Ad4BP/SF1 and FOXL2 proteins in ovarian follicles (36).

Dmy/Dmrt 1

In metazoans, double-sex and mab-3 related transcription factor 1 (Dmrt1) is the critical inducer of testicular differentiation (42). Testes restricted expression patterns of Dmrt1 have been found in medaka, Nile-tilapia, Olive flounder, Rainbow trout African catfish Clarias gariepinus, rare minnow Gobiocypris rarus, lake sturgeon Acipenser fulvescens, Atlantic cod Gadus morhua, pejerrey,shovelnose sturgeon Scaphirhynchus platorynchus and southern catfish Silurus meridionals (42). DMRT1 either alone or in synergy with DAX1 represses the female programming genes like Cyp19a1a, Rspo1, Figla, Gdf9 and Wnt4/β catenin and augments the transcription of male specific genes like Gsdf, Cyp11c1, Sox9/3, Amh etc in testes (42). The exposure of E2 downregulates Dmrt1 transcription in medaka (43), African catfish (44), Nile-tilapia (28), rare minnow (45), pejerrey (46), zebra-fish (47) and rainbow trout (48). DMRT1 directly suppresses Cyp19a1a promoter activity in medaka (36) and in Nile-tilapia (28). In XX tilapia, overexpression of Dmrt1 leads to downregulation of Cyp19a1a expression and E2 production (28). However, knock-down of Dmrt1 in XY tilapia (32) and mutation of Dmrt1 in Cynoglossusse milaevis (49) resulted in increased Foxl2 and Cyp19a1a expression without any male to female sex reversal. On the other hand, the loss of Dmrt1 leads to an elevated expression of Foxl2 in zebra-fish (50) whereas an augmentation in both Foxl2 and Cyp19a1a in medaka (51). The duplicated copy of Dmrt1a on the Y chromosome Dmy/Dmrt1bY (DM domain gene on the Y chromosome/doublesex and mab-3 related transcription factor 1b on the Y chromosome) acts as a master of male sex in medaka (12, 52). However, Dmy downregulates itself by binding to the conserved cis-regulatory elements like Izanagi, within its promoter (42). In differentiating testes of medaka, Dmy downregulates the hedgehog pathway by suppressing its receptor Pitch-2 and upregulating its antagonist Hhip (42).

Sox Proteins

The Sry related HMG box (Sox) gene(s) encode variety of transcription factor(s) critical for gonadal morphogenesis (5). Two paralogous forms of Sox9, namely Sox9a and Sox9b are reported in medaka and zebra-fish without any such sexual dimorphic expression pattern (53). In Indian rice-fish Oryzias dancena, Sox3 gene has been shown critical for sex determination by up-regulating expression of Gsdf (Gonadal soma-derived factor) (54). The expressions of Sox3 and Hsd11b2 are found to be associated with the initiation and progression of spermatogenesis in male catfish testis (8). Precisely, SOX3 binds to Hsd11b2 gene promote and transactivates its transcription in males (8). During development of zebra-fish, the transcription factor SOX5, directly downregulates the Dmrt1 transcription (42) whereas SOX5 downregulates Cyp19a1a transcription in the red spotted grouper Epinephelus akaara (55).

Other Transcription Factors

Wilm’s tumor 1 (WT1) is a key transcription factor having critical role in mammalian gonadal morphogenesis (5). In Indian catfish Clarias batrachus, WT1 has been shown to upregulate the promoter activity of Hsd11b2 (56). E2 bound Estrogen Receptor (coded by Esr1 gene) acts as a potential transcriptional inducer for Cyp19a1a in zebra-fish (57, 58). Finally, activated cAMP response element binding protein (CREB-P; phosphorylated at Ser-133 residue) differentially regulate the transcriptional control of Cyp19a1a and 20β-Hsd genes as found in ovaries of Nile-tilapia, rainbow trout and catfishes (8, 18). In pre-spawning vitellogenic ovaries, CREB-P upregulates the transcription of Cyp19a1a in synergy with Ad4BP/SF-1 and FOXL2under the influence of FSH. However, in post-vitellogenic spawning ovaries such dominant transcription of Cyp19a1a gets downregulated due to selective inhibition of FSH signal followed by LH induced upregulation 20β-Hsd transcription by CREB-P alone synthesizing maturation inducing steroids (17α,20β-DPs) critical for the meiotic progression of developing oocytes (8, 18).

Conclusion

In summary, molecular techniques like Electrophoretic mobility shift assay (EMSA) or Chromatin immuno-precipitation (ChIP) assay investigating DNA-protein interactions have revealed the differential promoter activities of the key steroidogenic genes like Cyp19a1a, Cyp11b and Hsd11b2 by various transcription factors to regulate the turnover rate of T for fixing the E2: 11-KT concentration in fish gonads (8). For example, in males, DMRT1 directly suppresses Cyp19a1a transcription, while DAX1 does the same via inhibiting FOXL2 and Ad4BP/SF-1 leading to the testicular differentiation. Conversely, FOXL2 and Ad4BP/SF-1 augment the expression of Cyp19a1a ensuring E2 production and promote the ovarian function. Figure 1 schematically represents the complex antagonistic genetic network that regulates the ovarian estrogenic or testicular androgenic milieu in teleost gonads. Supplementary Table 1 describes the critical role(s) of major transcription factors identified till date in different teleost species in a chronological order directing gonadal development and function. Supplementary Table 2 summarizes the effect of various environmental parameters on fish gonadal development and steroidogenesis.

FIGURE 1
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Figure 1 Sex specific regulation of gonadal steroidogenesis by transcription factors. Images of testis and ovary are representatives of a typical fresh water teleost (Schizothorax plagiostomus, Order: Cypriniformes, Family: Cyprinidae). (A) Regulation of Cyp19a1a promoter: In testis, DMRT1 alone or in synergy with DAX1 represses the Cyp19a1a transcription. In ovaries, FOXL2 either alone or along with Ad4BP/SF-1 activates Cyp19a1a transcription. CREB-P upregulates the transcription of Cyp19a1a in synergy with FOXL2 and Ad4BP/SF1 under the influence of FSH. Cortisol induced Glucocorticoid Receptor (GR) blocks the aromatase enzyme. Estrogen bound Estrogen Receptor (ER) acts as a potential inducer of Cyp19a1a transcription. DAX1 negatively regulates the Cyp19a1a expression by suppressing Ad4BP/SF-1 and FOXL2 (B) Regulation of Cyp11b/Cyp11b2/Cyp11c1 promoters: Cortisol induced GR activates the transcription of Cyp11b/Cyp11b2/Cyp11c1 in males. (C) Regulation of 11β- Hsd promoter: In males, SOX3/WT1 binds to 11β-Hsd and promoters its transcription and Cortisol induced GR activates the transcription of 11β-Hsd. www.frontiersin.org: Repression www.frontiersin.org: Activation www.frontiersin.org: Decline in activity, Nt, Nucleotide sequence.

Future Directions

Notably there is a potential scope for the commercial application of genetically engineered fishes having mutant transcription factors by advanced genome editing technologies like TALEN/CRISPER-CAS9 Transgenesis/RNAi mediated silencing etc. These gain in function (by transgenic over-expression/integration) or loss of function (by knock-out/down) models can be successfully implemented in aquaculture or fishery industry to increase the productivity/yield by manipulating fertility of fishes. However more studies are required in non-model teleost species by employing advanced high throughput next generation sequencing with multi-omics approach to generate gonadal transcriptomic resource datasets. This may further help identify the involvement of new putative factor(s) like chromatin remodelling complexes, DNA-methyl-transferases (DNMTs) and novel micro-RNAs or long-non-coding RNAs which can potentially regulate the sex specific transcriptional switch in gonadal steroidogenesis (59).

Author Contributions

IB conceived the idea. PS wrote the first draft of the Text, Figure, and Table with support from SP, SK and SN. IB generated the final form of the manuscript. All authors contributed to the article and approved the submitted version.

Funidng

IB acknowledges the financial support from University Grants Commission (F.30104/2015BSR) and Department of Science and Technology (ECR/2018/000868). The funder was not involved in the study design, collection, analysis, interpretation of data, the writing of this article or the decision to submit it for publication.

Conflict of Interest

The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.

Publisher’s Note

All claims expressed in this article are solely those of the authors and do not necessarily represent those of their affiliated organizations, or those of the publisher, the editors and the reviewers. Any product that may be evaluated in this article, or claim that may be made by its manufacturer, is not guaranteed or endorsed by the publisher.

Acknowledgments

The authors are sincerely grateful to the Hon’ble Vice Chancellor, HNBGU, Research and Consultancy Coordination cell, HNBGU and past and present Head(s), Dept. of Zoology, HNBGU for valuable support.

Supplementary Material

The Supplementary Material for this article can be found online at: https://www.frontiersin.org/articles/10.3389/fendo.2022.820241/full#supplementary-material

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Keywords: transcription factor, steroidogenesis, testosterone, estrogen, cortisol

Citation: Sharma P, Purohit S, Kothiyal S, Negi S and Bhattacharya I (2022) Sex Specific Transcriptional Regulation of Gonadal Steroidogenesis in Teleost Fishes. Front. Endocrinol. 13:820241. doi: 10.3389/fendo.2022.820241

Received: 22 November 2021; Accepted: 10 January 2022;
Published: 18 February 2022.

Edited by:

Mohd Ashraf Rather, Sher-e-Kashmir University of Agricultural Sciences & Technology of Kashmir, India

Reviewed by:

Aritra Bera, Central Institute of Brackishwater Aquaculture (ICAR), India
Carlos Alfonso Alvarez-González, Universidad Juárez Autónoma de Tabasco, Mexico

Copyright © 2022 Sharma, Purohit, Kothiyal, Negi and Bhattacharya. This is an open-access article distributed under the terms of the Creative Commons Attribution License (CC BY). The use, distribution or reproduction in other forums is permitted, provided the original author(s) and the copyright owner(s) are credited and that the original publication in this journal is cited, in accordance with accepted academic practice. No use, distribution or reproduction is permitted which does not comply with these terms.

*Correspondence: Indrashis Bhattacharya, aW5kcmFzaGlzLmJoYXR0YWNoYXJ5YUBnbWFpbC5jb20=

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