Project description:Transcriptome analysis of Prdm10 maternal knock out mouse oocytes

Project description:Members of the PR/SET domain-containing (PRDM) family of zinc finger transcriptional regulators play diverse roles in embryonic development and lineage differentiation. PRDM10 is a yet uncharacterized family member, with unknown functions in vivo. Here we report an essential requirement for PRDM10 in the pre-implantation embryo and embryonic stem cells (mESCs), where loss of PRDM10 results in severe cell growth inhibition. Genomic and biochemical analyses reveal that PRDM10 functions as a sequence-specific transcription factor which modulates gene expression by binding to target gene promoters. We identify Eif3b, which encodes a core component of the eukaryotic translation initiation factor 3 (eIF3) complex, as a key downstream target and demonstrate that growth inhibition in PRDM10-deficient mESCs is largely mediated through EIF3B-dependent effects on global translation. This work elucidates the molecular function of PRDM10 in maintaining global translation and establishes its essential role in early embryonic development and mESC homeostasis, offering novel insights into the functional repertoire of PRDMs as well as the transcriptional mechanisms regulating global translation.

Project description:Members of the PR/SET domain-containing (PRDM) family of zinc finger transcriptional regulators play diverse roles in embryonic development and lineage differentiation. PRDM10 is a yet uncharacterized family member, with unknown functions in vivo. Here we report an essential requirement for PRDM10 in the pre-implantation embryo and embryonic stem cells (mESCs), where loss of PRDM10 results in severe cell growth inhibition. Genomic and biochemical analyses reveal that PRDM10 functions as a sequence-specific transcription factor which modulates gene expression by binding to target gene promoters. We identify Eif3b, which encodes a core component of the eukaryotic translation initiation factor 3 (eIF3) complex, as a key downstream target and demonstrate that growth inhibition in PRDM10-deficient mESCs is largely mediated through EIF3B-dependent effects on global translation. This work elucidates the molecular function of PRDM10 in maintaining global translation and establishes its essential role in early embryonic development and mESC homeostasis, offering novel insights into the functional repertoire of PRDMs as well as the transcriptional mechanisms regulating global translation.

Project description:Members of the PR/SET domain-containing (PRDM) family of zinc finger transcriptional regulators play diverse roles in embryonic development and lineage differentiation. PRDM10 is a yet uncharacterized family member, with unknown functions in vivo. Here we report an essential requirement for PRDM10 in the pre-implantation embryo and embryonic stem cells (mESCs), where loss of PRDM10 results in severe cell growth inhibition. Genomic and biochemical analyses reveal that PRDM10 functions as a sequence-specific transcription factor which modulates gene expression by binding to target gene promoters. We identify Eif3b, which encodes a core component of the eukaryotic translation initiation factor 3 (eIF3) complex, as a key downstream target and demonstrate that growth inhibition in PRDM10-deficient mESCs is largely mediated through EIF3B-dependent effects on global translation. This work elucidates the molecular function of PRDM10 in maintaining global translation and establishes its essential role in early embryonic development and mESC homeostasis, offering novel insights into the functional repertoire of PRDMs as well as the transcriptional mechanisms regulating global translation.

Project description:Basonuclin, which is a zinc-finger protein found in abundance only in the keratinocytes of the stratified epithelium, male germ cells and oocytes, qualifies as a maternal-effect gene because the source of pre-implantation embryonic basonuclin is maternal. Using a transgenic-RNAi approach, we knocked-down basonuclin specifically in mouse oocytes, which led to female sub-fertility. Basonuclin deficiency in oocytes perturbed both RNA polymerase I- and II-mediated transcription and oocyte morphology was affected as evidenced by cytoplasmic and cell surface abnormalities. The affected oocytes, however, could still mature to and arrest at metaphase II and be ovulated, suggesting the impaired pathways were not essential for oocyte development and maturation. Nevertheless, an early embryonic failure in pre-implantation development was identified and likely accounted for the sub-fertility phenotype. These results suggest that basonuclin is a new member of the mammalian maternal-effect genes and interestingly, differs from the previously reported mammalian maternal-effect genes in that it also apparently perturbs oogenesis.

Project description:Basonuclin, which is a zinc-finger protein found in abundance only in the keratinocytes of the stratified epithelium, male germ cells and oocytes, qualifies as a maternal-effect gene because the source of pre-implantation embryonic basonuclin is maternal. Using a transgenic-RNAi approach, we knocked-down basonuclin specifically in mouse oocytes, which led to female sub-fertility. Basonuclin deficiency in oocytes perturbed both RNA polymerase I- and II-mediated transcription and oocyte morphology was affected as evidenced by cytoplasmic and cell surface abnormalities. The affected oocytes, however, could still mature to and arrest at metaphase II and be ovulated, suggesting the impaired pathways were not essential for oocyte development and maturation. Nevertheless, an early embryonic failure in pre-implantation development was identified and likely accounted for the sub-fertility phenotype. These results suggest that basonuclin is a new member of the mammalian maternal-effect genes and interestingly, differs from the previously reported mammalian maternal-effect genes in that it also apparently perturbs oogenesis. Keywords: RNAi knockdown

Project description:Primordial germ cells (PGCs), the founder cells of the germline, are specified in pre-gastrulating embryos in mammals, and subsequently migrate towards gonads to mature into functional gametes. Here, we investigated PGC development in rats, by genetically modifying Prdm14, a unique marker and a critical PGC transcriptional regulator. We trace PGC development in rats, for the first time, from specification until sex determination stage in fetal gonads using Prdm14 H2BVenus knock-in rats. We uncover that Prdm14’s crucial role in PGC specification is conserved between rat and mice, by analyzing Prdm14 deficient rat embryos. Notably, loss of Prdm14 completely abrogates the PGC program: failure in maintenance and/or activation of germ cell markers and pluripotency genes. Finally, we profile the transcriptome of the postimplantation epiblast and all PGC stages in rat, to reveal enrichment of distinct gene sets at each transition point, thereby providing an accurate transcriptional time-line for rat PGC development. Thus, the novel genetically modified rats and data sets obtained in this study will advance our knowledge on conserved vs species-specific features for germline development in mammals.

Project description:Gene regulatory networks underlying cellular pluripotency are controlled by a core circuitry of transcription factors, including POU5F1 and NANOG in mammals. However, the evolutionary origin and transformation of pluripotency transcriptional networks have not been elucidated in deuterostomes. PR domain-containing protein 14 (PRDM14) is specifically expressed in pluripotent cells and germ cells, and is required for establishing embryonic stem cells (ESCs) and primordial germ cells (PGCs) in mice. Here, we compared the functions and expression patterns of PRDM14 orthologues within deuterostomes. Amphioxus PRDM14, zebrafish PRDM14, and the combination of sea urchin PRDM14 and CBFA2T compensated for disruption of the mouse Prdm14 gene in terms of maintaining mouse ESC pluripotency. Interestingly, Prdm14 was expressed in motor neurons, but not in germ cells in amphioxus embryos as observed in zebrafish embryos. Therefore, our results suggest that the integration of the PRDM14–CBFA2T complex into the transcriptional network for pluripotency may be essential for stabilizing pluripotency during the early amniote development.

Project description:Germline cells reprogram extensive epigenetic modifications to ensure the cellular totipotency of the next generation and prevent accumulation of epimutations. Primordial germ cells (PGCs)1, the common source of both oocytes and sperm, erase genome-wide DNA methylation and histone H3 lysine 9 dimethylation (H3K9me2), a process called genome-wide epigenetic reprogramming2,3. However, little is known about the molecular mechanism of DNA demethylation by developing PGCs. Here we show that overexpression of PRDM14, a critical regulator for specification and early differentiation of PGCs, promotes global DNA demethylation in embryonic stem cells (ESCs). PRDM14 directly represses transcription of de novo DNA methyltransferase, Dnmt3b, but its repression is not sufficient for global DNA demethylation. Comparison of global gene expression profiles between PRDM14-overexpressing ESCs and Dnmts triple mutant ESCs clearly demonstrates that overexpression of PRDM14 activates about half of the genes silenced by DNA methylation in ESCs. Furthermore, PRDM14 directly interacts with TET1, which converts 5-methylcytosine to 5-hydroxymethylcytosine, and DNA demethylation by overexpression of PRDM14 is strongly disturbed by pharmacological inhibitors of the base excision repair (BER) pathway. We propose that formation of a PRDM14/TET1 complex triggers the activation of BER-dependent active demethylation across the whole genome of developing PGCs.

Project description:PRDM14 is a crucial regulator of mouse primordial germ cells (mPGC), epigenetic reprogramming and pluripotency, but its role in the evolutionarily divergent regulatory network of human PGCs (hPGCs) remains unclear. Besides, a previous knockdown study indicated that PRDM14 might be dispensable for human germ cell fate. Here, we decided to use inducible degrons for a more rapid and comprehensive PRDM14 depletion. We show that PRDM14 loss results in significantly reduced specification efficiency and an aberrant transcriptome of human PGC-like cells (hPGCLCs) obtained in vitro from human embryonic stem cells (hESCs). Chromatin immunoprecipitation and transcriptomic analyses suggest that PRDM14 cooperates with TFAP2C and BLIMP1 to upregulate germ cell and pluripotency genes, while repressing WNT signalling and somatic markers. Notably, PRDM14 targets are not conserved between mouse and human, emphasising the divergent molecular mechanisms of PGC specification. The effectiveness of degrons for acute protein depletion is widely applicable in various developmental contexts.