Project description:Goal of this study is the gene expression analysis of the zebrafish adult germline (ovary, oocyte, testis)

Project description:RNAseq of wild type zebrafish germline (ovary, oocyte, testis)

Project description:The main goal of our study is to identify the molecular events that determine the gonadal identity in mammals. Although testis and ovary arise from a common embryonic primordium, they represent outcomes of opposing fate determination. This decision to differentiate into a testis or an ovary hinges upon the balance between two antagonizing factors, pro-testis SOX9 and pro-ovary β-catenin. This microarray analysis led to the identification of the genes involved in the fate of XX and XY gonads in absence of SOX9 and beta-catenin

Project description:The main goal of our study is to identify the molecular events that determine the gonadal identity in mammals. Although testis and ovary arise from a common embryonic primordium, they represent outcomes of opposing fate determination. This decision to differentiate into a testis or an ovary hinges upon the balance between two antagonizing factors, pro-testis SOX9 and pro-ovary β-catenin. This microarray analysis led to the identification of the genes involved in the fate of XX and XY gonads in absence of SOX9 and beta-catenin We developed mouse genetic models that lack either Sox9, β-catenin, or both specifically in the somatic cells. All embryos used in this study resulted from the crossing between Ctnnb1f/f; Sox9f/f females with Sf1-cre+/Tg ; Ctnnb1+/f; Sox9+/f males. XX and XY fetal gonads were collected at embryonic day E14.5

Project description:The identification of novel cardiomyocyte-intrinsic factors that support ventricular function will expand the number of candidate genes and therapeutic options for heart failure, a leading cause of death worldwide. Here, we demonstrate that a conserved RNA-binding protein RBPMS2 is required for ventricular function in zebrafish and for myofibril organization and the regulation of intracellular calcium dynamics in zebrafish and human cardiomyocytes. A differential expression screen uncovered co-expression of rbpms2a and rbpms2b in zebrafish cardiomyocytes. Double knockout embryos suffer from compromised ventricular filling during the relaxation phase of the cardiac cycle, which significantly reduces cardiac output. Evaluating rbpms2-null embryos with splicing-sensitive differential expression analysis, quantitative PCR, and in situ hybridization revealed differential alternative splicing of cardiomyopathy genes including myosin binding protein C3 (mybpc3) and phospholamban (pln). Cardiomyocytes in double mutant ventricles and those derived from RBPMS2-null human induced pluripotent stem cells exhibit myofibril disarray and calcium handling abnormalities. Taken together, our data suggest that RBPMS2 performs a conserved role in regulating alternative splicing in cardiomyocytes, which is required for sarcomere organization, optimal calcium handling, and cardiac function.

Project description:The identification of novel cardiomyocyte-intrinsic factors that support ventricular function will expand the number of candidate genes and therapeutic options for heart failure, a leading cause of death worldwide. Here, we demonstrate that a conserved RNA-binding protein RBPMS2 is required for ventricular function in zebrafish and for myofibril organization and the regulation of intracellular calcium dynamics in zebrafish and human cardiomyocytes. A differential expression screen uncovered co-expression of rbpms2a and rbpms2b in zebrafish cardiomyocytes. Double knockout embryos suffer from compromised ventricular filling during the relaxation phase of the cardiac cycle, which significantly reduces cardiac output. Evaluating rbpms2-null embryos with splicing-sensitive differential expression analysis, quantitative PCR, and in situ hybridization revealed differential alternative splicing of cardiomyopathy genes including myosin binding protein C3 (mybpc3) and phospholamban (pln). Cardiomyocytes in double mutant ventricles and those derived from RBPMS2-null human induced pluripotent stem cells exhibit myofibril disarray and calcium handling abnormalities. Taken together, our data suggest that RBPMS2 performs a conserved role in regulating alternative splicing in cardiomyocytes, which is required for sarcomere organization, optimal calcium handling, and cardiac function.

Project description:In this study, we explored the biological process of zebrafish gonad differentiation through Poly(A)-enriched RNA sequencing，and found that the differences in the gonads differentiating towards testis or ovary were represented through types and expression levels of different genes. Using the GO enrichment classification, it is found that, in the differentiating ovary, the differentially expressed genes are enriched in processes of material synthesis and metabolic pathway, indicating that oocyte requires the accumulation of maternal RNA, protein, sugar, lipids, vitamins and other substances, which is consistent with its basic function of providing primary materials for early development of fertilized embryo. In addition, during ovarian differentiation, the biological processes associated with the nucleus, mitochondria, and cytoplasmic particles are more active, and the genes associated with sperm egg recognition are also expressed during this period. Unlike the differentiating ovary, when the gonad differentiates into testis, the differentially expressed genes are more enriched in biological regulation and development processes, including morphogenesis, cell proliferation, etc.The cytometers adapted to these biological processes are associated with cell membrane, such as membrane receptors, extra-cellular regions, extra-cellular matrix, and cell connections, and also associated with nuclear chromatin. In addition, we enriched 14 signaling pathways involved in testis differentiation, and showed the expression heat map of every differentially expressed gene of each pathway. Overall, the study reveals the different biological processes existing in the differentiation of the zebrafish gonads into ovary or testis, helping us to get a comprehensive understanding of the basis on biological events and molecules during this process.

Project description:: Sex determination triggers the differentiation of the bi-potential gonad into either an ovary or testis. In non-mammalian vertebrates, the presence or absence of oestrogen dictates gonad differ-entiation, while in mammals, this mechanism has been supplanted by the testis determining SRY gene. Exogenous oestrogen can override this genetic trigger to shift somatic cell fate in the gonad towards ovarian developmental pathways by limiting the bioavailability of the key testis factor SOX9 within somatic cells. Our previous work has implicated the MAPK pathway in mediating the rapid cellular response to oestrogen. We performed proteomic and phosphoproteomic anal-yses to investigate the precise mechanism through which oestrogen impacts these pathways to ac-tivate -catenin—a factor essential for ovarian development. We show that oestrogen can activate -catenin within 30 minutes, concomitant with the cytoplasmic retention of SOX9. This occurs through changes to the MAP3K1 cascade, suggesting this pathway is a mechanism through which oestrogen influences gonad somatic cell fate. We demonstrate that oestrogen can promote the shift from SOX9 pro-testis activity to -catenin pro-ovary activity through activation of MAP3K1. Our findings define a previously unknown mechanism through which oestrogen can promote a switch in gonad somatic cell fate and provided novel insights into the impacts of exogenous oestrogen exposure on the testis.

Project description:Zebrafish males undergo a juvenile ovary to testis type gonadal transformation process. To understand how juvenile ovary-to-testis transformation in zebrafish is genetically regulated, we compared the transcriptomes of juvenile ovary (JO) and juvenile ovotestis (JOT) samples at 35 dpf using the Gonad Uniclone Microarray v1 (ArrayExpress ID: A-MEXP-838). We also analyzed the transcriptomes of the 32 dpf JO, 32 dpf JOT, 34 dpf JOT, and 36 dpf JOT gonads using the slightly modified Gonad Uniclone Microarray v2 and together with the 35 dpf JO and 35 dpf JOT samples, compared the JO samples against the JOT samples to identify genes that could be potentially involved in the gonad transformation process.

Project description:The role of microRNAs in gene regulation has been well established. The extent of miRNA regulation also increases with increasing genome complexity. Though the number of genes appear to be equal between human and zebrafish, substantially less microRNAs have been discovered in zebrafish compared to human (Release 19). It appears that most of the miRNAs in zebrafish are yet to be discovered. We sequenced small RNAs from brain, gut, liver, ovary, testis, eye, heart and embryo of zebrafish. In brain, gut and liver sequencing was done in male and female separately. Majority of the sequenced reads (16-62%) mapped to known miRNAs, with the exception of ovary (5.7%) and testis (7.8%). Using the miRNA discovery tool (miRDeep2), we discovered novel miRNAs from the un-annotated reads that ranged from 7.6 to 23.0%, with exceptions of ovary (51.4%) and testis (55.2%). The prediction tool identified a total of 459 novel pre-miRNAs. We compared expression of miRNAs between different tissues and between males and females to identify tissue associated and sex associated miRNAs respectively. These miRNAs could serve as putative biomarkers for these tissues. The brain and liver had highest number of tissue associated (22) and sex associated (34) miRNAs, respectively. This study comprehensively identifies tissue and sex associated miRNAs in zebrafish. Further, we have discovered 459 novel pre-miRNAs (~30% seed homology to human miRNA) as a genomic resource which can facilitate further investigations to understand miRNA-mRNA gene regulatory networks in zebrafish which will have implications in understanding the function of human homologs. Known miRNA profiling, novel miRNA discovery and identification of tissue associated and sex associated miRNAs from sRNA deep sequencing data of different tissues and embryo of zebrafish (in triplicate) was carried out using the Illumina HiSeq 2000 platform.