Project description:Both transcription and post-transcriptional processes, such as alternative splicing, play crucial roles in controlling developmental programs in metazoans. Recently emerged RNA-seq method has brought our understanding of eukaryotic transcriptomes to a new level, because it can resolve both gene expression level and alternative splicing events simultaneously. To gain a better understanding of cellular differentiation in gonads, we analyzed mRNA profiles from Drosophila testes and ovaries using RNA-seq. We identified a set of genes that have sex-specific isoforms in wild-type (WT) gonads, including several transcription factors. We found that differentiation of sperms from undifferentiated germ cells induced a dramatic downregulation of RNA splicing factors. Our data confirmed that RNA splicing events are significantly more frequent in the undifferentiated cell-enriched bag of marbles (bam) mutant testis, but downregulated upon differentiation in WT testis. Consistent with this, we showed that genes required for meiosis and terminal differentiation in WT testis were mainly regulated at the transcriptional level, but not by alternative splicing. Unexpectedly, we observed an increase in expression of all families of chromatin remodeling factors and histone modifying enzymes in the undifferentiated cell-enriched bam testis. More interestingly, chromatin regulators and histone modifying enzymes with opposite enzymatic activities are coenriched in undifferentiated cells in testis, suggesting that these cells may possess dynamic chromatin architecture. Finally, our data revealed many new features of the Drosophila gonadal transcriptomes, and will lead to a more comprehensive understanding of how differential gene expression and splicing regulate gametogenesis in Drosophila. Our data provided a foundation for the systematic study of gene expression and alternative splicing in many interesting areas of germ cell biology in Drosophila, such as the molecular basis for sexual dimorphism and the regulation of the proliferation vs terminal differentiation programs in germline stem cell lineages. RNA-Seq experiments for four Drosophila melanogaster samples: (1) bam mutant testes, (2) wild-type testes, (3) bam mutant ovaries, (4) wild-type ovaries

Project description:We use male gonads isolated from a Drosophila strain that allows us to obtain enough cells at their primitive status as the starting material to study the endogenous chromatin structure of undifferentiated cells using ChIP-seq. We integrate the ChIP-seq data with RNA-seq data that measures the transcriptome in a digital manner. Our genome-wide analyses indicate that the majority of differentiation genes in undifferentiated cells lack an active chromatin mark and paused Pol II; instead, they are associated with either the repressive H3K27me3 mark or no detectable mark. In order to address the possibility that distinct techniques are responsible for such a difference, we also use the Drosophila S2 cells to perform ChIP-seq and RNA-seq and compare the results directly with published work using ChIP-chip and microarray on S2 cells. For the S2 cell ChIP-chip data, we used data from the following paper: Muse GW, Gilchrist DA, Nechaev S, Shah R, Parker JS, Grissom SF, Zeitlinger J, Adelman K: RNA polymerase is poised for activation across the genome. /Nat Genet /2007, 39(12):1507-1511. The accession number for this data is: GSE6714. ChIP-seq: Profiling chromatin modifications using antibodies against 3 histone modifications and RNA Pol II in S2 cells Profiling chromatin structure in bam testis using antibodies against 3 histone modifications and RNA Pol II RNA-seq: Profiling transcriptome of S2 cells using RNA-seq

Project description:To investigate the role of CPES in germ cell differentiation during spermatogenesis in Drosophila testis. We have generated cpes null mutants using ends-out homologus recombination and rescued with Bam-Gal4 and UAS-CPES in cpes mutant background. We then dissected 200 pairs of testes for each of the 3 replicates from wild type, cpes mutant and Rescue (Bam-Gal4 and UAS-CPES) Drosophila males and total RNA was extracted using Trizol and RNA-Clean and concentrater column. About 1ug of RNA in 20ul was submitted for bulk RNAseq using Illumina machine (HWI-ST1276).

Project description:In mammals, gonadal differentiation is the first step of sex determination, and the transcription factor Sox9 promotes testis differentiation. Here we used the XY Sox9flox/flox; Sf1:creTr/+ mouse model and show that the lack of Sox9 expression induces a full sex reversal of E13.5 XY Sox9flox/flox; Sf1:creTr/+ gonads compared to XY Sox9flox/flox. Keywords: gonads gene expression profiling in WT and Sox9flox/flox; Sf1:creTr/+ mice

Project description:In mammals, gonadal differentiation is the first step of sex determination, and the transcription factor Sox9 promotes testis differentiation. Here we used the XY Sox9flox/flox; Sf1:creTr/+ mouse model and show that the lack of Sox9 expression induces a full sex reversal of E13.5 XY Sox9flox/flox; Sf1:creTr/+ gonads compared to XY Sox9flox/flox. Keywords: gonads gene expression profiling in WT and Sox9flox/flox; Sf1:creTr/+ mice 3 WT versus 3 Sox9flox/flox; Sf1:creTr/+ mice.

Project description:Purpose: The goals of this study are to compare transcriptomes using RNA-seq of mouse myoblasts (C2C12 cell line) in undifferentiated and differentiated states and with siRNA-mediated knock down of the RNA binding proteins, Rbfox1 (only expressed in differentiated state) and Rbfox2 (expressed in both undifferentiated and differentiated states). Methods: Differentiated and undifferentiated C2C12 cultures treated with Rbfox1 (differentiated only) or Rbfox2 siRNAs or a mock siRNA transfection were used for RNA-Seq analysis using Illumina HiSeq2000. 101x2 paired-end RNA-seq reads were first uniquely aligned to the mouse genome (mm9) using TopHat 1.4.1. RSEM was used to count the number of reads mapped to genes using UCSC database, followed by edgeR to call differentially expressed genes with false discovery rate less than 0.01. Cufflinks was used to reconstruct isoforms and analyze alternative splicing and percent spliced in (PSI) was calculated. PSI values were validated by RT-PCR. Results: 58-88% of the RNA-seq reads from technical and biological replicates mapped uniquely to the mouse genome. Analysis of gene expression and alternative splicing changes are published in Singh et al. Molecular Cell (2014). Conclusions: Our study has identified gene expression and alternative splicing transitions that occur during myoblast differentiation, demonstrate that 30% of the splicing transitions are regulated by Rbfox2, demonstrated that Rbfox2 is required for a late step of myoblast differentiation and identified two Rbfox2-regulated splicing transitions that are required for differentiation. Undifferentiated and differentiated C2C12 cultures with Rbfox2 depletion or Rbfox1 depletion (differentiated only) in at least duplicate samples analyzed by deep sequencing on Illumina HiSeq2000.

Project description:From fish to human, FOXL2 is considered one of the most conserved markers of ovarian granulosa cell identity. To determine if the sole expression of FOXL2 can determine ovarian differentiation, we created a mouse model that allows the conditional expression of FOXL2. Rosa26-CAG-LSL-Foxl2 mice were crossed to Sf1-Cre mice to induce the expression of FOXL2 in the SF1+ somatic cells of the fetal gonads.When FOXL2 was induced in the somatic cells of the undifferentiated testis, the Sertoli cells and consequently the other cell lineages composing the fetal gonads were feminized, resulting in a partial testis-to-ovary sex reversal We created a mouse genetic model that conditionaly express FOXL2 in the somatic cells of the fetal gonads. All embryos used in this study resulted from the crossing between Rosa26-CAG-LSL-Foxl2+/f and Sf1-cre+/Tg mice. XX and XY fetal gonads were collected at embryonic day E14.5. This microarray analysis led to the identification of the genes misregulated upon ectopic induction of FOXL2 in the fetal testis, and showed that FOXL2 expression resulted in feminization of both somatic and germ cells of the fetal gonad.

Project description:We designed this experiment to investigate the transcriptional changes in gonads as a result of sex transformation. Here we performed transcriptional profiling of the ovary transformed into testis from the tra loss of function (XX_tra_lof), testis transformed into ovary from the tra gain of function (XY_tra_gof) and ovary transformed into testis in dsxM gain of function (XX_DsxM_gof/lof) Drosophila melanogaster third instar larvae in biological quadruplicates. In addition, as controls we sequenced ovaries and testes from the female and male wildtype larvae respectively. We constructed polyA+ libraries of the gonads, cleaned off the fatbody and performed 50 bp, stranded single-end RNA-Seq.

Project description:Purpose: We performed a time-course single-cell RNA-seq of the somatic cells of the XY mouse gonads to study the cell population heterogeneity and the genetic program during their differentiation. Methods: We collected gonads from NR5A1-eGFP transgenic embryos at five embryonic stages: E10.5, E11.5, E12.5, E13.5, E16.5. Cells were captured with the C1 autoprep system and cDNA sequenced with Illumina HiSeq 2000. Results: One cell population was detected at E10.5 and gives rise to both Sertoli and fetal Leydig cells. A precursor cell population remains undifferentiated at E16.5 and are likely to be adult Leydig cell precursors. Conclusion: Our study is, to date, the most granular transcriptomic study of the developing mouse testis and provide a more complete model of somatic cell differentiation during male sex determination.

Project description:One of the earliest morphological changes during testicular differentiation is the establishment of an XY specific vasculature. The testis vascular system is derived from mesonephric endothelial cells that migrate into the gonad. In the XX gonad, mesonephric cell migration and testis vascular development is inhibited by WNT4 signaling. In Wnt4 mutant XX gonads, endothelial cells migrate from the mesonephros and form a male-like coelomic vessel. Consequently, the XX Wnt4 mutant mice presented an opportunity to focus a gene expression screen on the processes of mesonephric cell migration and testicular vascular development. We compared differences in gene expression between XY Wnt4+/+ and XX Wnt4+/+ gonads and between XX Wnt4-/- and XX Wnt4+/+ gonads to identify genes similarly upregulated in wildtype XY gonads and XX mutant gonads that might play important roles in testis-specific vascular development. Keywords: genetic sex and phenotypic comparisons