Ayaka Yano

Flow-Cytometric Isolation of Testicular Germ Cells from Rainbow Trout (Oncorhynchus mykiss) Carrying the Green Fluorescent Protein Gene Driven by Trout vasa Regulatory Regions

Abstract There is a need to isolate different populations of spermatogenic cells to investigate the molecular events that occur during spermatogenesis. Here we developed a new method to identify and purify testicular germ cells from rainbow trout (Oncorhynchus mykiss) carrying the green fluorescent protein gene driven by trout vasa regulatory regions (pvasa-GFP) at various stages of spermatogenesis. Rainbow trout piwi-like (rtili), rainbow trout scp3 (rt-scp3), and rainbow trout shippo1 (rt-shippo1) were identified as molecular markers for spermatogonia, spermatocytes, and spermatids, respectively. The testicular cells were separated into five fractions (A–E) by flow cytometry (FCM) according to their GFP intensities. Based on the molecular markers, fractions A and B were found to contain spermatogonia, while fractions C and D contained spermatocytes, and fraction E contained spermatids. We also classified the spermatogonia into type A, which contained spermatogonial stem cells (SSCs), and type B, which did not. As none of the molecular markers tested could distinguish between the two types of spermatogonia, we subjected them to a transplantation assay. The results indicated that cells with strong GFP fluorescence (fraction A) colonized the recipient gonads, while cells with weaker GFP fluorescence (fraction B) did not. As only SSCs could colonize the recipient gonads, this indicated that fraction A and fraction B contained mainly type A and type B spermatogonia, respectively. These findings confirmed that our system could identify and isolate various populations of testicular cells from rainbow trout using a combination of GFP-dependent FCM and a transplantation assay.

Identification of a molecular marker for type A spermatogonia by microarray analysis using gonadal cells from pvasa-GFP transgenic rainbow trout (Oncorhynchus mykiss)

The spermatogonia of fish can be classified as being either undifferentiated type A spermatogonia or differentiated type B spermatogonia. Although type A spermatogonia, which contain spermatogonial stem cells, have been demonstrated to be a suitable material for germ cell transplantation, no molecular markers for distinguishing between type A and type B spermatogonia in fish have been developed to date. We therefore sought to develop a molecular marker for type A spermatogonia in rainbow trout. Using GFP‐dependent flow cytometry (FCM), enriched fractions of type A and type B spermatogonia, testicular somatic cells, and primordial germ cells were prepared from rainbow trout possessing the green fluorescent protein (GFP) gene driven by trout vasa regulatory regions (pvasa‐GFP rainbow trout). The gene‐expression profiles of each cell fraction were then compared with a microarray containing cDNAs representing 16,006 genes from several salmonid species. Genes exhibiting high expression for type A spermatogonia relative to above‐mentioned other types of gonadal cells were identified and subjected to RT‐PCR and quatitative PCR analysis. Since only the rainbow trout notch1 homologue showed significantly high expression in the type A spermatogonia‐enriched fraction, we propose that notch1 may be a useful molecular marker for type A spermatogonia. The combination of GFP‐dependent FCM and microarray analysis of pvasa‐GFP rainbow trout can therefore be applied to the identification of potentially useful molecular markers of germ cells in fish. Mol. Reprod. Dev. 76: 246–254, 2009.

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/β-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 hormone‐binding globulins characterization and gonadal gene expression during sex differentiation in the rainbow trout, Oncorhynchus mykiss

Sex hormone‐binding globulin (SHBG) binds androgens and estrogens in the blood of many vertebrates, including teleost fish. In mammals, SHBG is synthetized in the liver and secreted into the blood. In fish, shbga also exhibits a hepatic expression. In salmonids, in which the gene has been duplicated, the recently discovered shbgb gene exhibits a predominantly ovarian expression. The present work aimed at gaining new insight into shbgb gene structure and expression during gonadal sex differentiation, a steroid‐sensitive process, and Shbgb protein structure and binding characteristics; specifically, rainbow trout (Oncorhynchus mykiss) shbgb was analyzed. shbgb structure was analyzed in silico while expression was characterized during gonadal sex differentiation using all‐male and all‐female populations. We observed that shbgb gene and cognate‐protein structures are similar to homologs previously described in zebrafish and mammals. The shbgb gene is predominantly expressed in differentiating female gonads, with increased expression around the end of ovarian differentiation. In the ovary, shbgb mRNA was detected in a subset of somatic cells surrounding the ovarian lamellae. Furthermore, Shbgb binds steroids with a higher selectivity than Shbga, exhibiting a higher affinity for estradiol compared to Shbga. In conclusion, Shbgb binding characteristics are clearly different from those of Shbga. Shbgb is expressed in the differentiating ovary during a period when the synthesis and action of testosterone and estradiol must be tightly regulated. This strongly suggests that Shbgb participates in the regulation of steroid metabolism and/or mediation, that is, needed during early gonadal development in rainbow trout. Mol. Reprod. Dev. 81: 757–765, 2014.

No early gender effects on energetic status and life history in a salmonid

Throughout an organisms early development, variations in physiology and behaviours may have long lasting consequences on individual life histories. While a large part of variation in critical life-history transitions remains unexplained, a significant proportion may be caused by early gender effects as part of gender-specific life histories shaped by sexual selection. In this study, we investigated the presence of early gender effects on the timing of emergence from gravel and the energetic status of brown trout (Salmo trutta) early stages. To investigate this question, individual measures of emergence timing, metabolic rate and energetic content were coupled for the first time with the use of a recent genetic marker for sdY (sexually dimorphic on the Y-chromosome), a master sex-determining gene. Our results show that gender does not influence the energetic content of emerging juveniles or their emergence timing. These findings suggest that gender differences may appear later throughout salmonid life history and that selective pressures associated with the critical period of emergence from gravel may shape early life-history traits similarly in both males and females.