Project description:Nat10 is required for sculpting the maternal transcriptome through timely degradation of polyA tail mRNAs during the Maternal-to-Zygotic transition(MZT)

Project description:In animals, the maternal-to-embryonic transition (MET) is an important step occurring in the first days of early development. This important transition involves the degradation of maternal transcripts that have been stocked during oogenesis and used until this transition. Moreover, some precise and specific control mechanisms must govern the adequate synchronization of the MET events to promote embryonic genome activation. These mechanisms are not well understood, but microRNAs could be one of the mechanisms involved. MicroRNAs are short non-coding RNAs involved in a growing number of pathways by their post-transcriptional repression of mRNA translation. Thus, we analyzed microRNA expression during oocyte maturation by comparing GV-oocytes with MII-oocytes in cow. Groups of 300 Oocytes_GV and Oocytes_MII were used for miRNA expression analysis. The miRNA expressions were determined using the MiRMammalia_11.0 array from LC Sciences.

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:In animals, the maternal-to-embryonic transition (MET) is an important step occurring in the first days of early development. This important transition involves the degradation of maternal transcripts that have been stocked during oogenesis and used until this transition. Moreover, some precise and specific control mechanisms must govern the adequate synchronization of the MET events to promote embryonic genome activation. These mechanisms are not well understood, but microRNAs could be one of the mechanisms involved. MicroRNAs are short non-coding RNAs involved in a growing number of pathways by their post-transcriptional repression of mRNA translation. Thus, we analyzed microRNA expression during oocyte maturation by comparing GV-oocytes with MII-oocytes in cow.

Project description:In vitro oogenesis is key to elucidating the mechanism of human female germ-cell development and its anomalies. Accordingly, pluripotent stem cells have been induced into primordial germ cell-like cells and into oogonia with epigenetic reprogramming, yet further reconstitutions remain a challenge. Here, we demonstrate ex vivo reconstitution of fetal oocyte development in both humans and cynomolgus monkeys (Macaca fascicularis). With an optimized culture of fetal ovary reaggregates over three months, human and monkey oogonia enter and complete the first meiotic prophase to differentiate into diplotene oocytes that form primordial follicles, the source for oogenesis in adults. The cytological and transcriptomic progressions of fetal oocyte development in vitro closely recapitulate those in vivo. A comparison of single-cell transcriptomes among humans, monkeys, and mice unravels primate-specific and conserved programs driving fetal oocyte development, the former including a distinct transcriptomic transformation upon oogonia-to-oocyte transition and the latter including two active X chromosomes with little X-chromosome upregulation. Our study provides a critical step forward for realizing human in vitro oogenesis and uncovers salient characteristics of fetal oocyte development in primates.

Project description:In vitro oogenesis is key to elucidating the mechanism of human female germ-cell development and its anomalies. Accordingly, pluripotent stem cells have been induced into primordial germ cell-like cells and into oogonia with epigenetic reprogramming, yet further reconstitutions remain a challenge. Here, we demonstrate ex vivo reconstitution of fetal oocyte development in both humans and cynomolgus monkeys (Macaca fascicularis). With an optimized culture of fetal ovary reaggregates over three months, human and monkey oogonia enter and complete the first meiotic prophase to differentiate into diplotene oocytes that form primordial follicles, the source for oogenesis in adults. The cytological and transcriptomic progressions of fetal oocyte development in vitro closely recapitulate those in vivo. A comparison of single-cell transcriptomes among humans, monkeys, and mice unravels primate-specific and conserved programs driving fetal oocyte development, the former including a distinct transcriptomic transformation upon oogonia-to-oocyte transition and the latter including two active X chromosomes with little X-chromosome upregulation. Our study provides a critical step forward for realizing human in vitro oogenesis and uncovers salient characteristics of fetal oocyte development in primates.

Project description:In vitro oogenesis is key to elucidating the mechanism of human female germ-cell development and its anomalies. Accordingly, pluripotent stem cells have been induced into primordial germ cell-like cells and into oogonia with epigenetic reprogramming, yet further reconstitutions remain a challenge. Here, we demonstrate ex vivo reconstitution of fetal oocyte development in both humans and cynomolgus monkeys (Macaca fascicularis). With an optimized culture of fetal ovary reaggregates over three months, human and monkey oogonia enter and complete the first meiotic prophase to differentiate into diplotene oocytes that form primordial follicles, the source for oogenesis in adults. The cytological and transcriptomic progressions of fetal oocyte development in vitro closely recapitulate those in vivo. A comparison of single-cell transcriptomes among humans, monkeys, and mice unravels primate-specific and conserved programs driving fetal oocyte development, the former including a distinct transcriptomic transformation upon oogonia-to-oocyte transition and the latter including two active X chromosomes with little X-chromosome upregulation. Our study provides a critical step forward for realizing human in vitro oogenesis and uncovers salient characteristics of fetal oocyte development in primates.

Project description:In vitro oogenesis is key to elucidating the mechanism of human female germ-cell development and its anomalies. Accordingly, pluripotent stem cells have been induced into primordial germ cell-like cells and into oogonia with epigenetic reprogramming, yet further reconstitutions remain a challenge. Here, we demonstrate ex vivo reconstitution of fetal oocyte development in both humans and cynomolgus monkeys (Macaca fascicularis). With an optimized culture of fetal ovary reaggregates over three months, human and monkey oogonia enter and complete the first meiotic prophase to differentiate into diplotene oocytes that form primordial follicles, the source for oogenesis in adults. The cytological and transcriptomic progressions of fetal oocyte development in vitro closely recapitulate those in vivo. A comparison of single-cell transcriptomes among humans, monkeys, and mice unravels primate-specific and conserved programs driving fetal oocyte development, the former including a distinct transcriptomic transformation upon oogonia-to-oocyte transition and the latter including two active X chromosomes with little X-chromosome upregulation. Our study provides a critical step forward for realizing human in vitro oogenesis and uncovers salient characteristics of fetal oocyte development in primates.

Project description:In vitro oogenesis is key to elucidating the mechanism of human female germ-cell development and its anomalies. Accordingly, pluripotent stem cells have been induced into primordial germ cell-like cells and into oogonia with epigenetic reprogramming, yet further reconstitutions remain a challenge. Here, we demonstrate ex vivo reconstitution of fetal oocyte development in both humans and cynomolgus monkeys (Macaca fascicularis). With an optimized culture of fetal ovary reaggregates over three months, human and monkey oogonia enter and complete the first meiotic prophase to differentiate into diplotene oocytes that form primordial follicles, the source for oogenesis in adults. The cytological and transcriptomic progressions of fetal oocyte development in vitro closely recapitulate those in vivo. A comparison of single-cell transcriptomes among humans, monkeys, and mice unravels primate-specific and conserved programs driving fetal oocyte development, the former including a distinct transcriptomic transformation upon oogonia-to-oocyte transition and the latter including two active X chromosomes with little X-chromosome upregulation. Our study provides a critical step forward for realizing human in vitro oogenesis and uncovers salient characteristics of fetal oocyte development in primates.

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