Project description:Development is often assumed to be a sequential unfolding of genetic programs towards increased complexity and occurring with a very stereotypical timing. However, embryos across all lineages of metazoans can enter reversible states of developmental pausing in response to adverse environmental conditions. In mammals, pausing manifests as a delayed implantation of the blastocyst, the source of embryonic stem cells (ESCs). Paused pluripotency can be induced in mouse blastocysts and ESCs by inhibition of mTOR, a conserved growth-promoting kinase, and is characterized by a drastic global decrease in biosynthetic activity, including gene transcription. The molecular mechanisms by which this remarkable dormant cellular state is achieved remain largely unknown. Here we show that m6A RNA methylation by Mettl3 is essential for transcriptional dormancy and maintenance of the paused pluripotent state in vitro and in vivo. Mass spectrometry and transcriptome-wide sequencing revealed an increase in m6A in paused ESCs. Knockout of the RNA methyltransferase Mettl3 suppresses transcriptional and proliferation dormancy of ESC specifically in the paused state, and leads to loss of paused blastocysts. Integration of several datasets in vitro and in vivo identified the transcriptional amplifier and oncogene Mycn as a key “anti-pausing factor” regulated by m6A mRNA methylation. Mett3-mediated methylation at a specific site of the Mycn mRNA is essential for its destabilization, which in turns mediates suppression of nascent transcription and proliferation in paused conditions. Our results highlight an intricate feedback between signaling, regulation of RNA stability and nascent transcription during pausing, with Mettl3 as an essential integrator and Mycn as a key downstream anti-pausing factor. These findings shed light on the mechanisms that underlie tuning of global transcriptional output during mammalian developmental pausing, and that may be redeployed in adult stem cells or during cancer dormancy.

Project description:Development is often assumed to be a sequential unfolding of genetic programs towards increased complexity and occurring with a very stereotypical timing. However, embryos across all lineages of metazoans can enter reversible states of developmental pausing in response to adverse environmental conditions. In mammals, pausing manifests as a delayed implantation of the blastocyst, the source of embryonic stem cells (ESCs). Paused pluripotency can be induced in mouse blastocysts and ESCs by inhibition of mTOR, a conserved growth-promoting kinase, and is characterized by a drastic global decrease in biosynthetic activity, including gene transcription. The molecular mechanisms by which this remarkable dormant cellular state is achieved remain largely unknown. Here we show that m6A RNA methylation by Mettl3 is essential for transcriptional dormancy and maintenance of the paused pluripotent state in vitro and in vivo. Mass spectrometry and transcriptome-wide sequencing revealed an increase in m6A in paused ESCs. Knockout of the RNA methyltransferase Mettl3 suppresses transcriptional and proliferation dormancy of ESC specifically in the paused state, and leads to loss of paused blastocysts. Integration of several datasets in vitro and in vivo identified the transcriptional amplifier and oncogene Mycn as a key “anti-pausing factor” regulated by m6A mRNA methylation. Mett3-mediated methylation at a specific site of the Mycn mRNA is essential for its destabilization, which in turns mediates suppression of nascent transcription and proliferation in paused conditions. Our results highlight an intricate feedback between signaling, regulation of RNA stability and nascent transcription during pausing, with Mettl3 as an essential integrator and Mycn as a key downstream anti-pausing factor. These findings shed light on the mechanisms that underlie tuning of global transcriptional output during mammalian developmental pausing, and that may be redeployed in adult stem cells or during cancer dormancy.

Project description:Development is often assumed to be a sequential unfolding of genetic programs towards increased complexity and occurring with a very stereotypical timing. However, embryos across all lineages of metazoans can enter reversible states of developmental pausing in response to adverse environmental conditions. In mammals, pausing manifests as a delayed implantation of the blastocyst, the source of embryonic stem cells (ESCs). Paused pluripotency can be induced in mouse blastocysts and ESCs by inhibition of mTOR, a conserved growth-promoting kinase,  and is characterized by a drastic global decrease in biosynthetic activity, including gene transcription. The molecular mechanisms by which this remarkable dormant cellular state is achieved remain largely unknown. Here we show that m6A RNA methylation by Mettl3 is essential for transcriptional dormancy and maintenance of the paused pluripotent state in vitro and in vivo. Mass spectrometry and transcriptome-wide sequencing revealed an increase in m6A in paused ESCs. Knockout of the RNA methyltransferase Mettl3 suppresses transcriptional and proliferation dormancy of ESC specifically in the paused state, and leads to loss of paused blastocysts. Integration of several datasets in vitro and in vivo identified the transcriptional amplifier and oncogene Mycn  as a key “anti-pausing factor” regulated by m6A mRNA methylation. Mett3-mediated methylation at a specific site of the Mycn mRNA is essential for its destabilization, which in turns mediates suppression of nascent transcription and proliferation in paused conditions. Our results highlight an intricate feedback between signaling, regulation of RNA stability and nascent transcription during pausing, with Mettl3 as an essential integrator and Mycn as a key downstream anti-pausing factor. These findings shed light on the mechanisms that underlie tuning of global transcriptional output during mammalian developmental pausing, and that may be redeployed in adult stem cells or during cancer dormancy.

Project description:Development is often assumed to be a sequential unfolding of genetic programs towards increased complexity and occurring with a very stereotypical timing. However, embryos across all lineages of metazoans can enter reversible states of developmental pausing in response to adverse environmental conditions. In mammals, pausing manifests as a delayed implantation of the blastocyst, the source of embryonic stem cells (ESCs). Paused pluripotency can be induced in mouse blastocysts and ESCs by inhibition of mTOR, a conserved growth-promoting kinase,  and is characterized by a drastic global decrease in biosynthetic activity, including gene transcription. The molecular mechanisms by which this remarkable dormant cellular state is achieved remain largely unknown. Here we show that m6A RNA methylation by Mettl3 is essential for transcriptional dormancy and maintenance of the paused pluripotent state in vitro and in vivo. Mass spectrometry and transcriptome-wide sequencing revealed an increase in m6A in paused ESCs. Knockout of the RNA methyltransferase Mettl3 suppresses transcriptional and proliferation dormancy of ESC specifically in the paused state, and leads to loss of paused blastocysts. Integration of several datasets in vitro and in vivo identified the transcriptional amplifier and oncogene Mycn  as a key “anti-pausing factor” regulated by m6A mRNA methylation. Mett3-mediated methylation at a specific site of the Mycn mRNA is essential for its destabilization, which in turns mediates suppression of nascent transcription and proliferation in paused conditions. Our results highlight an intricate feedback between signaling, regulation of RNA stability and nascent transcription during pausing, with Mettl3 as an essential integrator and Mycn as a key downstream anti-pausing factor. These findings shed light on the mechanisms that underlie tuning of global transcriptional output during mammalian developmental pausing, and that may be redeployed in adult stem cells or during cancer dormancy.

Project description:Development is often assumed to be a sequential unfolding of genetic programs towards increased complexity and occurring with a very stereotypical timing. However, embryos across all lineages of metazoans can enter reversible states of developmental pausing in response to adverse environmental conditions. In mammals, pausing manifests as a delayed implantation of the blastocyst, the source of embryonic stem cells (ESCs). Paused pluripotency can be induced in mouse blastocysts and ESCs by inhibition of mTOR, a conserved growth-promoting kinase,  and is characterized by a drastic global decrease in biosynthetic activity, including gene transcription. The molecular mechanisms by which this remarkable dormant cellular state is achieved remain largely unknown. Here we show that m6A RNA methylation by Mettl3 is essential for transcriptional dormancy and maintenance of the paused pluripotent state in vitro and in vivo. Mass spectrometry and transcriptome-wide sequencing revealed an increase in m6A in paused ESCs. Knockout of the RNA methyltransferase Mettl3 suppresses transcriptional and proliferation dormancy of ESC specifically in the paused state, and leads to loss of paused blastocysts. Integration of several datasets in vitro and in vivo identified the transcriptional amplifier and oncogene Mycn  as a key “anti-pausing factor” regulated by m6A mRNA methylation. Mett3-mediated methylation at a specific site of the Mycn mRNA is essential for its destabilization, which in turns mediates suppression of nascent transcription and proliferation in paused conditions. Our results highlight an intricate feedback between signaling, regulation of RNA stability and nascent transcription during pausing, with Mettl3 as an essential integrator and Mycn as a key downstream anti-pausing factor. These findings shed light on the mechanisms that underlie tuning of global transcriptional output during mammalian developmental pausing, and that may be redeployed in adult stem cells or during cancer dormancy.

Project description:Embryonic stem (ES) cells and embryos reversibly pause via chemical mTOR inhibition. In this study, we investigate the tissue-specific response to mTORi-induced pausing in ES and trophoblast stem (TS) cells. To resolve the sequential rewiring of the proteome, we conducted a time-series proteomics experiment at 1, 3, 6, 12, 24, and 48 hours upon induction of pausing, and at 1, 3, 6, 12, 24, and 48 hours upon release of pausing in ES and TS cells. We find that ES, but not TS cells pause reversibly. To optimise developmental pausing conditions, we reasoned that by understanding the difference in pausing response of ES and TS cells, we could identify which pathways are essential for pausing. We found that KEGG pathways related to amino acid degradation, fatty acid degradation, and DNA repair are upregulated in ES cells, but downregulated in TS cells during entry into pausing. Moreover, by targeted metabolomics, we found a depletion of short chain carnitines in the paused ES cells. To extend the length of developmental pausing, we supplemented paused embryos with L-carnitine. The L-carnitine supplementation facilitates lipid usage and prolongs the pausing length by 19 days through the establishment of a more dormant state.

Project description:Embryonic stem (ES) cells and embryos reversibly pause via chemical mTOR inhibition. In this study, we investigate the tissue-specific response to mTORi-induced pausing in ES and trophoblast stem (TS) cells. To resolve the sequential rewiring of the proteome, we conducted a time-series proteomics experiment at 1, 3, 6, 12, 24, and 48 hours upon induction of pausing, and at 1, 3, 6, 12, 24, and 48 hours upon release of pausing in ES and TS cells. We find that ES, but not TS cells pause reversibly. To optimise developmental pausing conditions, we reasoned that by understanding the difference in pausing response of ES and TS cells, we could identify which pathways are essential for pausing. We found that KEGG pathways related to amino acid degradation, fatty acid degradation, and DNA repair are upregulated in ES cells, but downregulated in TS cells during entry into pausing. Moreover, by targeted metabolomics, we found a depletion of short chain carnitines in the paused ES cells. To extend the length of developmental pausing, we supplemented paused embryos with L-carnitine. The L-carnitine supplementation facilitates lipid usage and prolongs the pausing length by 19 days through the establishment of a more dormant state.

Project description:Embryonic stem (ES) cells and embryos reversibly pause via chemical mTOR inhibition. In this study, we investigate the tissue-specific response to mTORi-induced pausing in ES and trophoblast stem (TS) cells. To resolve the sequential rewiring of the proteome, we conducted a time-series proteomics experiment at 1, 3, 6, 12, 24, and 48 hours upon induction of pausing, and at 1, 3, 6, 12, 24, and 48 hours upon release of pausing in ES and TS cells. We find that ES, but not TS cells pause reversibly. To optimise developmental pausing conditions, we reasoned that by understanding the difference in pausing response of ES and TS cells, we could identify which pathways are essential for pausing. We found that KEGG pathways related to amino acid degradation, fatty acid degradation, and DNA repair are upregulated in ES cells, but downregulated in TS cells during entry into pausing. Moreover, by targeted metabolomics, we found a depletion of short chain carnitines in the paused ES cells. To extend the length of developmental pausing, we supplemented paused embryos with L-carnitine. The L-carnitine supplementation facilitates lipid usage and prolongs the pausing length by 19 days through the establishment of a more dormant state.

Project description:The tammar blastocyst remains in embryonic diapause until it receives a signal from the uterine endometrium via its secretions.This study analaysed uterine flushings from diapause, different stages of reactivation upto late gestation.

Project description:In this study we aimed to examine the effect of alternative in vivo and in vitro culture conditions during the time of blastocyst formation on the transcriptome profile of bovine blastocysts. Two different blastocyst groups were produced. The first group (Vitro_morula) was matured, fertilized and cultured in vitro until morula stage then transferred to synchronized recipients and blastocysts were collected at day 7 by uterine flushing. The second group (Vivo_morula) was matured, fertilized and cultured in vivo until morula stage then flushed out and cultured in vitro until day 7. Complete in vitro (IVP) and in vivo blastocysts were produced and used as controls.