The cellular expression patterns of gdnfa and gdnfb in the gonads of Nile tilapia and their differential response to retinoic acid.

In mammals, glial cell derived neurotrophic factor (GDNF) plays a critical role in the self-renewal and maintenance of spermatogonial stem cells (SSCs) in testis and oogenesis in ovary, whilst retinoic acid (RA), the key factor of meiosis initiation, can downregulate its expression. Unlike mammals, two Gdnf replication genes are widely present in teleost fishes, however, our understanding of them is still poor. In the present study, two paralogous gdnf from Nile tilapia (Oreochromis niloticus), namely as Ongdnfa and Ongdnfb, were characterized, and then their cellular expression profiles in testis and ovary and responsiveness to RA treatment at the tissue and cellular levels were investigated. In phylogenetic tree, the Gdnfa and Gdnfb from teleost fishes were clustered into two different subclasses, respectively, and then clustered with the homologs from cartilaginous fish and tetrapods, suggesting that OnGdnfa and OnGdnfb are orthologous to GDNF and paralogous to each other. Ongdnfa is expressed in Sertoli cells and Leydig cells in testis and oocytes in ovary. The expression pattern of Ongdnfb is similar to Ongdnfa. In the ex vivo testicular organ culture, RA down-regulated the expression of Ongdnfa, whereas up-regulated the expression of Ongdnfb (P < 0.05), suggesting that they have differential responsiveness to RA signaling. RA treatment of the cultured cells derived from adult Nile tilapia testis which have the expression of RA receptors (RAR), Ongdnfa and Ongdnfb further confirmed the above result. Collectively, our study suggests that Ongdnfa and Ongdnfb have non-germline expression patterns in testis and germline expression patterns in ovary; furthermore, they have differential responsiveness to RA signaling, implying that they might have differential biological functions. This study broadens and enriches our understanding of fish GDNF homologs and lays foundation for the study of their biological functions in the future.

Nile tilapia (Oreochromis niloticus) Nanog co-expression with Pou5f3, transcriptional regulation and biological activity in embyonic development and embryonic cells.

Mammalian Nanog is critical in pluripotency acquisition and maintenance. Nonetheless, a recent report from zebrafish (Danio rerio) suggests that Nanog is not required for embryonic cells which is not like the mammalian homologs, but is necessary for the proper formation of the extra-embryonic yolk syncytial layer (YSL). However, whether its biological function in other fishes is conservative remains to be investigated. Our previous work shows that Nanog from Nile tilapia (Oreochromis niloticus) (termed as Ong thereafter) displays differential spatiotemporal expression patterns from the other teleost fishes including zebrafish. In this study, Ong co-expression with Pou5f3 (another core pluripotent transcription factor), transcriptional regulation and its biological functions during embryonic development and in the survival and proliferation of embryonic cells were investigated. At the blastula stage, both Ong and Pou5f3 were highly expressed in embryonic cells and co-located in the nucleus. After that, the expression of both Ong and Pou5f3 began to decrease at the gastrula stage (24 haf) and then exhibited a differential expression profile at the segmentation stage (28-36 haf). Ong disappeared in embryonic cells and was limited to YSL, whilst Pou5f3 was highly expressed in embryonic cells even some with obvious cytoplasmic distribution. Luciferase assay indicated that Ong was negatively regulated by Pou5f3 and positively regulated by androgen and itself. Ong depletion in fertilized one-cell embryos through CRISPR/Cas9 led to blastula blockage or death, and the survival and proliferation of blastula-derived embryonic cells in vitro failed. Collectively, Ong has similar expression and biological function to Pou5f3 at the blastula stage, which is similar to mammalian homolog but different from zebrafish homolog. These data suggest that the expression patterns and functions of Nanog are not conservative in fishes and vary from species to species. This study enriches our understanding about Nanog and its evolution.

Desert hedgehog mediates the proliferation of medaka spermatogonia through Smoothened signaling.

Desert hedgehog (DHH) signaling has been reported to be involved in spermatogenesis and the self-renewal of spermatogonial stem cells (SSCs). However, the role of DHH in proliferation of spermatogonia including SSCs remains to be elucidated. Here, we report that Dhh from medaka (Oryizas latipes) (named as OlDhh) could directly mediate the proliferation of spermatogonia via Smoothened (Smo) signaling. Oldhh is 1362 bp in length and encodes 453 amino acid (aa) residues with more than 50% identity with the homologs in other species. It has expression predominantly restricted to testis. The soluble and tag-free 176-aa mature OlDhh (named as mOlDhh) were successfully obtained by fusing with the N-terminal tag of cleavable 6-histidine and small ubiquitin-related modifier and then removing the tag. Notably, mOlDhh significantly promoted the proliferation of SG3 (a spermatogonial stem cell line from medaka testis) in a dose-dependent manner and spermatogonia in testicular organ culture. Furthermore, the proliferation of SG3 in the presence of mOlDhh could be inhibited by Smo antagonist (cyclopamine) resulting in apoptosis. Additionally, mOlDhh significantly upregulated the expression of smo as well as the pluripotent-related genes bcl6b and sall4. These data suggest that Smo is an indispensable downstream component in the Dhh signaling pathway. In conclusion, our findings unambiguously demonstrate that Dhh could directly mediate the proliferation of spermatogonia through Smo signaling. This study provides new knowledge about the proliferation regulation of spermatogonia.

Characterization of nanog in Nile tilapia (Oreochromis niloticus) and its spatiotemporal expression patterns during embryonic and gonadal development.

Nanog is one of the well-characterized core transcription factors in pluripotency maintenance network. So far, studies on fishes indicate that the Nanog expression occurs from embryonic 1-cell stage to blastula stage, and is restricted to the gonadal germline cells in adult tissues, which is strikingly different from that in mammals. However, whether this expression profile is conservative in fishes remains to be investigated. Here Nile tilapia (Oreochromis niloticus) nanog (named as Ong) was identified and its spatiotemporal expression patterns during embryonic and gonadal development were investigated. The Ong cDNA contains an open reading frame of 678 bp, encoding 226 amino acids. The anti-Ong antibody was prepared through prokaryotic protein expression and its specificity was validated. The Ong expression in embryonic 1-cell stage did not appear until the early stage of blastocyst and continued to the late stage of blastocyst. In adult tissues, its expression was limited to gonads. Its expression patterns during gonadal development were further investigated by in situ hybridization and immunohistochemical staining. In testis, Ong was not expressed at 30 dah (days after hatching), but highly expressed in spermatogonia and spermatocytes at 150 dah; in ovaries at 30 and 150 dah, it was not expressed in germline cells but in all somatic cells. This expression profile is strikingly different from reports in fishes to date. Our study firstly indicates that the Nanog expression profile is not conservative in fishes. This study is valuable for further functional and evolutionary study of this gene.