Follistatin is an early player in rainbow trout ovarian differentiation and is both colocalized with aromatase and regulated by the wnt pathway.

In mammals, follistatin (FST) plays an important role in early ovarian differentiation, acting downstream of the Wnt pathway. In teleost fish, fst is implicated in folliculogenesis and oocyte maturation, and an early and specific expression during ovarian differentiation has been described in rainbow trout, Oncorhynchus mykiss. By in situ hybridization, we demonstrated that during rainbow trout gonadal differentiation, fst shares a similar expression pattern with cyp19a1a, the gene encoding ovarian aromatase, a key steroidogenic enzyme needed for ovarian differentiation in fish. Expression of fst and cyp19a1a was first detected in a few scattered cells in the embryonic ovary several days before hatching. Then, after histological differentiation, fst and cyp19a1a expression was localized in clusters of cells lining the future ovarian lamellae. As FST expression is known to be induced by the Wnt/ß-catenin pathway in mammals, the Wnt pathway was inhibited in vivo with the IWR-1 molecule, and we analyzed by qPCR the effects of this treatment on fst expression. We found that IWR-1 decreased fst expression in female gonads, consistent with a regulation of fst expression by the Wnt pathway in rainbow trout. Furthermore, expression of cyp19a1a was also downregulated, suggesting an implication of the Wnt pathway in ovarian differentiation.

Sex differentiation in an all-female (XX) rainbow trout population with a genetically governed masculinization phenotype.

Sex determination is known to be male heterogametic in the rainbow trout, Oncorhynchus mykiss; however, scattered observations that deviate from this rather strict genetic control have been reported. Here, we provide a detailed morphological and histological characterization of the gonadal differentiation and development (from 43 days postfertilization to 11 months of age) in an all-female (XX) population with a genetically governed masculinization phenotype. In comparison with control males and females, the gonadal differentiation in these animals was characterized by many perturbations, including significantly fewer germ cells. This decrease in germ cells was confirmed by the significantly decreased expression of 2 germ cell maker genes (vasa and sycp3) in the masculinized XX populations as compared with the control females and control males. Although only a proportion of the total adult population was partially or fully masculinized, this early differentiating phenotype affected nearly all the sampled animals. This suggests that the adult masculinization phenotype is the consequence of an early functional imbalance in ovarian differentiation in the entire population. We hypothesize that the lower number of germ cells that we observed in this population could be one cause of their masculinization.