Project description:<p>Human embryonic stem cells (hESCs) can self-renew infinitely or differentiate into the 3 germ layer lineages<em> in vitro</em> with certain cues, holding great promise to model early human embryo development <em>ex vivo</em>. It is wildly accepted that hESCs take advantage of both glycolysis and mitochondrial respiration to favor the naïve pluripotency, while prefer glycolysis to support the primed pluripotency. Thus, the function of mitochondrial respiration in primed hESCs has been underestimated for a long time, and has not been fully understood yet. Herein, we report that the adenosine triphosphate (ATP) production rate is comparable between mitochondrial respiration and glycolysis, suggesting that mitoATP may serve as one of the major sources of the ATP pool in primed hESCs. To further reveal the function of mitochondrial respiration, we deployed inducible CRISPRi method to inhibit OGDH expression with high efficiency, resulting in the TCA cycle blockade as well as the diminishment of mitochondrial respiration activity and total ATP level. Of note, OGDH deficiency led to the exit of primed pluripotency accompanied by cell death. Furthermore, the treatment with small molecule inhibitors to block electron transport chain (ETC) can phenocopy the loss-of-function of OGDH in hESCs. Therefore, genetic and pharmacological perturbations on mitochondrial respiration can impair the stemness of primed hESCs. Collectively, the current study unveils that OGDH acts as a key regulator to fine-tune the abundance of TCA cycle metabolites to ensure the mitochondrial respiration activity in primed hESCs, and highlights the pivotal roles of mitochondrial respiration in terms of ATP production and the maintenance of primed pluripotency. Our findings may provide insights into the linkage between pluripotent states and energy metabolism in hESCs.</p>

Project description:<p>Naïve human embryonic stem cells (hESCs) that resemble the pre-implantation epiblasts are fueled by a combination of aerobic glycolysis and oxidative phosphorylation, but their mitochondrial regulators are poorly understood. Here we report that, proline dehydrogenase (PRODH), a mitochondria-localized proline metabolism enzyme, is dramatically upregulated in naïve hESCs compared to their primed counterparts. The upregulation of PRODH is induced by a reduction in c-Myc expression that is dependent on PD0325901, a MEK inhibitor routinely present in naive hESC culture media. PRODH knockdown in naive hESCs significantly promoted mitochondrial oxidative phosphorylation (mtOXPHOS) and reactive oxygen species (ROS) production that triggered autophagy, DNA damage, and apoptosis. Remarkably, MitoQ, a mitochondria-targeted antioxidant, effectively restored the pluripotency and proliferation of PRODH-knockdown naïve hESCs, indicating that PRODH maintains naïve pluripotency by preventing excessive ROS production. Concomitantly, PRODH knockdown significantly slowed down the proteolytic degradation of multiple key mitochondrial electron transport chain complex proteins. Thus, we revealed a crucial role of PRODH in limiting mtOXPHOS and ROS production, and thereby safeguarding naïve pluripotency of hESCs.</p><p><br></p><p><strong>Untargeted metabolomics</strong> - H9N PLKO.1 vs H9P PLKO.1 / H9P shPRODH vs H9P PLKO.1 / H9N shPRODH vs H9N PLKO.1 - is reported in the current study <a href='https://www.ebi.ac.uk/metabolights/MTBLS7840' rel='noopener noreferrer' target='_blank'><strong>MTBLS7840</strong></a>.</p><p><strong>Targeted metabolomics</strong> (amino acids and derivatives) - H9P (Primed) VS H9N (Naïve) - is reported in <a href='https://www.ebi.ac.uk/metabolights/MTBLS7832' rel='noopener noreferrer' target='_blank'><strong>MTBLS7832</strong></a>.</p>

Project description:<p>Naïve human embryonic stem cells (hESCs) that resemble the pre-implantation epiblasts are fueled by a combination of aerobic glycolysis and oxidative phosphorylation, but their mitochondrial regulators are poorly understood. Here we report that, proline dehydrogenase (PRODH), a mitochondria-localized proline metabolism enzyme, is dramatically upregulated in naïve hESCs compared to their primed counterparts. The upregulation of PRODH is induced by a reduction in c-Myc expression that is dependent on PD0325901, a MEK inhibitor routinely present in naive hESC culture media. PRODH knockdown in naive hESCs significantly promoted mitochondrial oxidative phosphorylation (mtOXPHOS) and reactive oxygen species (ROS) production that triggered autophagy, DNA damage, and apoptosis. Remarkably, MitoQ, a mitochondria-targeted antioxidant, effectively restored the pluripotency and proliferation of PRODH-knockdown naïve hESCs, indicating that PRODH maintains naïve pluripotency by preventing excessive ROS production. Concomitantly, PRODH knockdown significantly slowed down the proteolytic degradation of multiple key mitochondrial electron transport chain complex proteins. Thus, we revealed a crucial role of PRODH in limiting mtOXPHOS and ROS production, and thereby safeguarding naïve pluripotency of hESCs.</p><p><br></p><p><strong>Targeted metabolomics</strong> (amino acids and derivatives) - H9P (Primed) VS H9N (Naïve) - is reported in the current study <a href='https://www.ebi.ac.uk/metabolights/MTBLS7832' rel='noopener noreferrer' target='_blank'><strong>MTBLS7832</strong></a>.</p><p><strong>Untargeted metabolomics</strong> - H9N PLKO.1 vs H9P PLKO.1 / H9P shPRODH vs H9P PLKO.1 / H9N shPRODH vs H9N PLKO.1 - is reported in <a href='https://www.ebi.ac.uk/metabolights/MTBLS7840' rel='noopener noreferrer' target='_blank'><strong>MTBLS7840</strong></a>.</p>

Project description:Understanding the molecular underpinnings of pluripotency is a prerequisite for optimal maintenance and application of embryonic stem cells (ESCs). While the protein-protein interactions of core pluripotency factors have been identified in mouse ESCs, their interactome in human ESCs (hESCs) has not to date been explored. Here we mapped the OCT4 interactomes in naïve and primed hESCs, revealing extensive connections to mammalian ATP-dependent nucleosome remodeling complexes.

Project description:The balance between glycolytic and oxidative metabolism shifts during differentiation of human embryonic stem cells (hESCs) and during reprogramming of somatic cells into pluripotent stem cells. However the contribution of glycolytic metabolism to various stages of pluripotency is not well understood. Additionally, few tools have been developed that modulate pluripotent stem cell glycolytic metabolism to influence self-renewal or differentiation. Here we show that the degree of human pluripotency is associated with glycolytic rate, whereby naive hESCs exhibit higher glycolytic flux, increased MYC transcriptional activity, and elevated nuclear N-MYC levels relative to primed hESCs. Consistently, the inner cell mass of human blastocysts also exhibits increased MYC transcriptional activity relative to primed hESCs and elevated nuclear N-MYC levels. Expression of the lactate transporter, monocarboxylate transporter 1 (MCT1), is strongly associated with the pluripotent state, and reduction of glycolysis using a small molecule inhibitor towards MCT1 decreases self-renewal of naïve hESCs and feeder-free cultured primed hESCs, but not that of primed hESCs grown in feeder-supported conditions. Lastly, reduction of glycolytic metabolism via MCT1 inhibition in feeder-free primed hESCs enhances neural lineage specification. These findings validate the association between glycolytic metabolism and pluripotency, reveal differences in the glucose metabolism of feeder- versus feeder-free cultured hESCs, and show that pharmacologic regulation of glycolysis can influence self-renewal and initial cell fate specification of human pluripotent stem cells.

Project description:Functions of OGDH in primed human embryonic stem cells.

Project description:Mouse embryonic stem cells (mESCs) are in naive pluripotency that represents the ground state of development, from which all cells in the mouse embryo are derived. In contrast, human embryonic stem cells (hESCs) are in a primed state of pluripotency with many different properties. Despite intense efforts to generate naive human pluripotent stem cells (hPSCs), it has not been possible to derive naive hPSCs without relying on transgene overexpression or chemicals. Here, we show that a transient treatment with Torin1, a selective inhibitor of mTOR, converted hPSCs from primed to naive pluripotency. The naive hPSCs were maintained in the same condition as mESCs in defined media with 2iLI (MEK inhibitor, GSK3b inhibitor, LIF and Insulin). Like mESCs, they exhibited high clonal efficiency, rapid cell proliferation, active mitochondrial respiration, X chromosome activation, DNA hypomethylation, and transcriptomes similar to those of human blastocysts than primed hESCs. Most importantly, the naive hPSCs significantly contributed to mouse embryos when transferred to mouse blastocysts. mTor inhibition induced nuclear translocation of TFE3, a critical transcription factor at the interplay of autophagy and pluripotency. TFE3 with mutated nuclear localization signal blocked the conversion from primed to naive pluripotency. It appears that by mimicking diapause at the cellular level, naive pluripotency in human can be readily attained from primed hPSCs, thus establishing the unified ground state of pluripotency in mammals.

Project description:Mouse embryonic stem cells (mESCs) are in naive pluripotency that represents the ground state of development, from which all cells in the mouse embryo are derived. In contrast, human embryonic stem cells (hESCs) are in a primed state of pluripotency with many different properties. Despite intense efforts to generate naive human pluripotent stem cells (hPSCs), it has not been possible to derive naive hPSCs without relying on transgene overexpression or chemicals. Here, we show that a transient treatment with Torin1, a selective inhibitor of mTOR, converted hPSCs from primed to naive pluripotency. The naive hPSCs were maintained in the same condition as mESCs in defined media with 2iLI (MEK inhibitor, GSK3b inhibitor, LIF and Insulin). Like mESCs, they exhibited high clonal efficiency, rapid cell proliferation, active mitochondrial respiration, X chromosome activation, DNA hypomethylation, and transcriptomes similar to those of human blastocysts than primed hESCs. Most importantly, the naive hPSCs significantly contributed to mouse embryos when transferred to mouse blastocysts. mTor inhibition induced nuclear translocation of TFE3, a critical transcription factor at the interplay of autophagy and pluripotency. TFE3 with mutated nuclear localization signal blocked the conversion from primed to naive pluripotency. It appears that by mimicking diapause at the cellular level, naive pluripotency in human can be readily attained from primed hPSCs, thus establishing the unified ground state of pluripotency in mammals.

Project description:Understanding the molecular underpinnings of pluripotency is a prerequisite for optimal maintenance and application of embryonic stem cells (ESCs). While the protein-protein interactions of core pluripotency factors have been identified in mouse ESCs, their physical interactome in human ESCs (hESCs) has not been explored thus far. Here we mapped the protein-protein interactions of OCT4 in naive and primed hESCs, revealing extensive connections to ATP-dependent nucleosome remodeling complexes. In naive hESCs, OCT4 is associated with both BRG1 and BRM, the two core ATPases of the BAF complex. Genome-wide location analyses and genetic deletion studies reveal that these two enzymes exert a functionally redundant role in transcriptional regulation of blastocyst-specific genes. In contrast, in primed hESCs OCT4 cooperates with BRG1 and the transcription factor SOX2 to create an open chromatin architecture at neural lineage associted genes. This work offers insight into the regulation of human stem cell identity and reveals how a common transcription factor utilizes differential BAF complex composition to control distinct transcriptional programs in naive and primed hESCs.

Project description:Understanding the molecular underpinnings of pluripotency is a prerequisite for optimal maintenance and application of embryonic stem cells (ESCs). While the protein-protein interactions of core pluripotency factors have been identified in mouse ESCs, their physical interactome in human ESCs (hESCs) has not been explored thus far. Here we mapped the protein-protein interactions of OCT4 in naive and primed hESCs, revealing extensive connections to ATP-dependent nucleosome remodeling complexes. In naive hESCs, OCT4 is associated with both BRG1 and BRM, the two core ATPases of the BAF complex. Genome-wide location analyses and genetic deletion studies reveal that these two enzymes exert a functionally redundant role in transcriptional regulation of blastocyst-specific genes. In contrast, in primed hESCs OCT4 cooperates with BRG1 and the transcription factor SOX2 to create an open chromatin architecture at neural lineage associted genes. This work offers insight into the regulation of human stem cell identity and reveals how a common transcription factor utilizes differential BAF complex composition to control distinct transcriptional programs in naive and primed hESCs.