The protandrous black porgy, Acanthopagrus schlegeli, has a striking life cycle, with sex differentiation at the juvenile stage, mono-male development, a bisexual gonad during the first 2 yr of life, and a male-to-female sex change (with vitellogenic oocytes) at 3 yr of age. In the present study, we investigated the possible roles of amh and amhr2 in gonadal development in a nonmammalian model organism (protandrous black porgy), especially in relation to sex differentiation, testicular and ovarian growth, and sex change. Fish of various ages were treated with estradiol or an aromatase inhibitor to induce the fish to become female. Furthermore, a natural sex change (2(+)-yr-old [>2 yr and <3 yr] fish) and a nonchemical method to surgically remove one of the pair of gonads to examine the possible roles of amh in the natural sex change were conducted. We present integrative in situ hybridization, immunohistochemical, cellular, and molecular data describing these phenomena. During gonadal sex differentiation, an increase in amh and amhr2 expression was detected. Higher levels of amh and amhr2 transcripts were observed in the testicular tissue when compared to the ovarian tissue in the bisexual gonad of 1(+)-yr-old (>1 yr and <2 yr) fish. Transcripts of amh reached peak levels in November (prespermatogenesis period) and then declined to the lowest levels in January (spawning period). Chemical-induced ovarian tissue had very low amh transcript levels but high levels of amhr2. Active testes had significantly higher amh and amhr2 expression levels as compared to inactive testes. In contrast, no difference in the expression of amh and amhr2 between active and inactive ovarian tissues was found. Transcripts of amh were expressed in the somatic cells of the spermatogonia and vitellogenic oocytes, and amhr2 was expressed in the somatic cells of the spermatogonia. Transcripts of amh decreased in the testicular tissue 5 mo before occurrence of the sex change into a female. In contrast, testicular amh expression remained high if the fish remained male. Human chorionic gonadotropin regulated amh and amhr2 expression in the testicular tissue but not in the ovarian tissue. The present results suggest that amh plays important roles in early testicular and ovarian development, late ovarian growth (e.g., vitellogenic oocytes), and natural sex change in the protandrous black porgy.
In hermaphroditic fish, the ovotestis can respond to external stimuli so that only one type of gonadal tissue (either ovarian or testicular tissue) will remain reproductively active and the other will recede to a rudimentary stage. However, the molecular mechanism for sexual fate determination is still poorly understood in hermaphroditic fish. In the present study, we examined whether sexual fate determination with respect to testis development is due to differential expression of dmrt1. Expression of dmrt1 was limited to the spermatogonia-surrounding cells (Sertoli cells) throughout testis development. Testicular dmrt1 was differentially expressed in fish (black porgy [Acanthopagrus schlegeli Bleeker]) depending on if fish were destined to be female or male. Expression of dmrt1 in Sertoli cells did not require germ cell factors with busulfan treatment. To examine the role of dmrt1, we used virus-based RNA interference. Deficiency of dmrt1 resulted in a reduced number of germ cells in the testis and stimulated a male-to-female sex change. Higher serum luteinizing hormone levels were detected in 2(+)- to 3-yr-old male fish as compared to sex-changing female fish. Furthermore, we showed that fish treated in vivo with gonadotropin-releasing hormone (Gnrh) and fish treated in vitro with gonadotropin (Gth) had higher dmrt1 expression in the testis, suggesting that these endocrine factors may affect the male-to-female sex change. Therefore, our data suggest that dmrt1 plays a key role in initial testis differentiation and in later maintenance of male development. We show, to our knowledge for the first time, the functions of dmrt1 in hermaphroditic fish, which indicate that male-phase maintenance may be regulated by the brain-pituitary-gonadal axis via the Gnrh-Gth-Dmrt1 axis.
In the present study, we tested the hypothesis that the brain of the black porgy fish, Acanthopagrus schlegeli, has the capacity for de novo steroidogenesis and that these neurosteroids may impact sex differentiation. Gonadal histology and Dmrt1 gene expression revealed that the fish were not sex differentiated until 155 dah (days after hatching). We further demonstrated the developmental expressions of the mRNAs encoding for four key neurosteroidogenic enzymes, namely, the cytochrome P450 side chain cleavage (CYP11A1), 3beta-hydroxysteroid dehydrogenase/Delta(5)-Delta(4) isomerase (3betaHSD), cytochrome P450c17 (CYP17) and aromatase (CYP19b) in the brain at different post-hatching developmental ages. The results indicated that steroidogenic genes are expressed in brain from the earliest sampling time, 60 dah. Quantitative real-time polymerase chain reaction analysis demonstrated significantly higher expression levels of these enzymes at 120 dah compared to 60 dah in all the brain regions. However, the increase for 3betaHSD was significant only in hypothalamus and midbrain, whereas it was significant only in forebrain and hypothalamus for CYP19b. A decline in mRNA levels were observed for all the genes at 155 dah except in midbrain for CYP11A1 and in hindbrain for CYP19b. Analysis of aromatase enzyme activity showed a significant increase in aromatase activity in the forebrain at 120 dah. Thus, the present study demonstrated for the first time an age- and/or region dependent expression of the mRNAs encoding the steroidogenic enzyme genes in the brain of black porgy. The presence of key steroidogenic enzymes as early as 60 dah, before gonadal sex differentiation, demonstrates that steroid biosynthetic capacity in brain precedes histological gonad differentiation. The mRNA transcripts of these genes showed a synchronous peak at 120 dah, suggesting that oestradiol may be locally formed in most parts of the brain. The study suggests an important role for brain aromatase in male black porgy brain sex differentiation, and considers the possibility of a role for this enzyme in neurogenesis.
The protandrous black porgy, Acanthopagrus schlegeli, has a striking life cycle with sex differentiation at the juvenile stage, mono-male development, and male-to-female sex change (with vitellogenic oocytes) at age 3 yr. In the present study, we investigated the possible roles of wnt4 in gonadal development in a nonmammalian model organism (protandrous black porgy), especially in relation to sex differentiation, ovarian growth, and sex change. Fish of various ages were treated with estradiol (E2) or aromatase inhibitor (AI) to determine whether manipulation of the hormonal environment had an effect on these processes. Furthermore, a natural sex change (> or =2-yr-old fish) and a nonchemical method to induce an early sex change (> or =1-yr-old fish) via the removal of testicular tissue were examined in this study. We present herein an integrative immunohistochemical, cellular, and molecular data set describing these phenomena. During gonadal sex differentiation, no increase in wnt4 expression was detected. A profile of increased wnt4 expression and decreased cyp19a1a expression was associated with ovarian growth (proliferation of oogonia and development of ovarian lamellae) in > or =1-yr-old fish. Both E2 and AI induced an increase in wnt4 transcripts and resulted in ovarian development in > or =0-yr-old and > or =1-yr-old fish. Increased wnt4 transcripts were found in ovarian tissue undergoing development from primary oocytes to vitellogenic oocytes during the natural sex change in > or =2-yr-old fish. Removal of testicular tissue in > or =1-yr-old fish resulted in successful early sex change (with vitellogenic oocytes) 6 mo after the excision. During the process of the early sex change (3 mo after testis excision), the fish ovary became active and had increased diameter of the primary oocytes; this was in accord with increased ovarian wnt4 expression but not sf1, foxl2, and genes in the steroidogenic pathway, including cyp19a1a. Wnt4 staining further confirmed the profile of wnt4 expression associated with ovarian development. The results of the present study suggest that wnt4 has important roles in late ovarian growth (e.g., oogonia proliferation and structure of ovarian lamellae) and the natural sex change (vitellogenic oocytes) in the protandrous black porgy.
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