Project description:During peri-implantation development, the pluripotent tissue of the early embryo undergoes profound cellular and biochemical reprogramming. These transformations are essential for subsequent development, yet how they are coordinated with the preservation of genome integrity remains poorly understood. Here, we uncover a telomere length checkpoint that is elicited by metabolic remodeling as mouse embryonic stem cells (ESCs) transition from the naïve to formative pluripotent state. We show that the exit of naïve pluripotency is marked by accelerated mitochondrial respiration and de novo lipogenesis, fueling lipid droplet accumulation required for tissue remodeling. Unexpectedly, these acute metabolic shifts trigger transient telomere shortening and activate ZSCAN4, a pluripotency-associated regulator of telomeres, followed by telomere re-elongation as cells adopt a more glycolytic metabolic profile. Our findings reveal a feedback mechanism in which metabolism-induced telomere stress engages ZSCAN4 as a protective response, thereby linking metabolic state to telomere homeostasis during early developmental progression.

Project description:During peri-implantation development, the pluripotent tissue of the early embryo undergoes profound cellular and biochemical reprogramming. These transformations are essential for subsequent development, yet how they are coordinated with the preservation of genome integrity remains poorly understood. Here, we uncover a telomere length checkpoint that is elicited by metabolic remodeling as mouse embryonic stem cells (ESCs) transition from the naïve to formative pluripotent state. We show that the exit of naïve pluripotency is marked by accelerated mitochondrial respiration and de novo lipogenesis, fueling lipid droplet accumulation required for tissue remodeling. Unexpectedly, these acute metabolic shifts trigger transient telomere shortening and activate ZSCAN4, a pluripotency-associated regulator of telomeres, followed by telomere re-elongation as cells adopt a more glycolytic metabolic profile. Our findings reveal a feedback mechanism in which metabolism-induced telomere stress engages ZSCAN4 as a protective response, thereby linking metabolic state to telomere homeostasis during early developmental progression.

Project description:Naïve and primed pluripotent states represent two different states of pluripotency. Mouse naïve pluripotent stem cells (PSCs) exhibit germline competence as determined by chimera production test and can generate all-PSC mice by tetraploid embryo complementation (TEC) test, the most stringent functional test of developmental potency. By contrast, primed PSCs fail in germline chimeras and TEC test. Unfortunately, these tests cannot be applied to characterization of developmental pluripotency of human PSCs due to ethic issue. Extensive studies demonstrated that naïve and primed pluripotent state exhibits clear epigenome differences. Here we uncover surprising differences in telomere maintenance, retrotransposon activity and genomic stability between these two pluripotent states. Although both states express high telomerase activity, naïve PSCs show robust telomere elongation capacity, associated with higher telomere recombination, consistent with sporadic expression of two-cell (2C) genes including Zscan4. Distinctively, primed PSCs only can maintain their telomere length but without elongation, in association with repression of 2C genes, and increased telomere fragility and telomeric DNA damage with passages. RNA-seq revealed that DNA repair and especially recombination repair pathways are down-regulated in primed state compared to naïve state cells, corroborating the robust DNA repair capacity and genome stability in naïve PSCs. These data suggest that vigorous telomere elongation of naïve state may act to minimize DNA damage to the genome. Furthermore, we identified LINE1 family integrant L1Md_T as naïve-specific retrotransposon and ERVK family integrant IAPEz-int to define primed PSCs, distinguishing the two pluripotent states. Heterochromatin modifications and Dnmt3b differentially regulate transcription of the 2C genes and retrotransposons. Notably, aberrant expression of retrotransposons links to increased genomic stability of primed PSCs. Hence, our data reveals that telomere regulation and retrotransposon activity markedly distinguishes naïve from primed pluripotent state. These new criteria may facilitate induction of high quality and additional characterization of developmental pluripotency and scrutinizing the genomic stability of human naïve PSCs for regenerative medicine

Project description:Naïve and primed pluripotent states represent two different states of pluripotency. Mouse naïve pluripotent stem cells (PSCs) exhibit germline competence as determined by chimera production test and can generate all-PSC mice by tetraploid embryo complementation (TEC) test, the most stringent functional test of developmental potency. By contrast, primed PSCs fail in germline chimeras and TEC test. Unfortunately, these tests cannot be applied to characterization of developmental pluripotency of human PSCs due to ethic issue. Extensive studies demonstrated that naïve and primed pluripotent state exhibits clear epigenome differences. Here we uncover surprising differences in telomere maintenance, retrotransposon activity and genomic stability between these two pluripotent states. Although both states express high telomerase activity, naïve PSCs show robust telomere elongation capacity, associated with higher telomere recombination, consistent with sporadic expression of two-cell (2C) genes including Zscan4. Distinctively, primed PSCs only can maintain their telomere length but without elongation, in association with repression of 2C genes, and increased telomere fragility and telomeric DNA damage with passages. RNA-seq revealed that DNA repair and especially recombination repair pathways are down-regulated in primed state compared to naïve state cells, corroborating the robust DNA repair capacity and genome stability in naïve PSCs. These data suggest that vigorous telomere elongation of naïve state may act to minimize DNA damage to the genome. Furthermore, we identified LINE1 family integrant L1Md_T as naïve-specific retrotransposon and ERVK family integrant IAPEz-int to define primed PSCs, distinguishing the two pluripotent states. Heterochromatin modifications and Dnmt3b differentially regulate transcription of the 2C genes and retrotransposons. Notably, aberrant expression of retrotransposons links to increased genomic stability of primed PSCs. Hence, our data reveals that telomere regulation and retrotransposon activity markedly distinguishes naïve from primed pluripotent state. These new criteria may facilitate induction of high quality and additional characterization of developmental pluripotency and scrutinizing the genomic stability of human naïve PSCs for regenerative medicine

Project description:Chemical induced pluripotent stem cells (CiPSCs) have been successfully achieved and may provide an alternative and attractive source for stem cell-based therapy. Sufficient telomere lengths are critical for unlimited self-renewal and genomic stability of pluripotent stem cells. Dynamics of telomere reprogramming and whether and how telomeres are sufficiently elongated in the CiPSCs have remained to be understood. We show that CiPSCs acquire telomere lengthening with increasing passages after clonal formation. Both telomerase activity and recombination-based mechanisms are involved in the telomere elongation. Telomere lengths strongly indicate the degree of reprogramming, pluripotency and differentiation capacity of CiPSCs. Nevertheless, telomere damage and shortening occur at late stage of lengthy induction, limiting CiPSC formation. Recombination mechanism is not activated during induction until CiPSC clonal formation and passages. We find that histone crotonylation induced by crotonic acid can activate two-cell genes including Zscan4, alleviate telomere damage and shortening during induction and promote CiPSC generation. Moreover, crotonylation decreases abundance of heterochromatic H3K9me3 and HP1a at subtelomeres and Zscan4 loci. Taken together, telomere rejuvenation links to reprogramming and pluripotency of CiPSCs. Crotonylation facilitates telomere maintenance and enhances chemical induced reprogramming to pluripotency.

Project description:The ERK5 MAP kinase signalling pathway was recently discovered as a driver of naïve pluripotency in mouse Embryonic Stem Cells (mESCs). However, the molecular functions of ERK5 in mESCs have not been investigated. Here, we employ combinatorial mESC proteomics to identify ERK5 target genes and substrates. Global proteomic profiling reveals ZSCAN4 and other 2-cell stage genes as transcriptional targets of the ERK5 pathway. ZSCAN4 expression is specifically induced by ERK5-dependent transcription of the core pluripotency factor KLF2. Additionally, ERK5 directly phosphorylates tandem KLF2 Thr-Pro/Ser-Pro motifs identified by phosphoproteomics to recruit the FBXW7-CUL1 E3 ligase, promoting KLF2 ubiquitylation and degradation. ERK5 phosphorylation of KLF2 thereby provides negative-feedback control to restrain transcriptional induction of ZSCAN4. Our data uncover an auto-regulatory module by which ERK5 co-opts KLF2 to pattern ZSCAN4 expression. This study provides the first molecular insight into ERK5 functions in mESCs, and suggests a novel role for ERK5 signalling in stem cell rejuvenation

Project description:Telomere length heterogeneity in various cell types including stem cells and cancer cells has been recognized. Cell heterogeneity also is found in pluripotent stem cells such as embryonic stem cells (ESCs). The implication and mechanisms underlying the heterogeneity remain to be defined. We have optimized a robust method that can simultaneously measure telomere length coupled with RNA-sequencing analysis (scT&R-seq) in the same human ES cell. Using this method, we show that telomere length varies with pluripotency state. Long telomere hESCs highly express TERF1/TRF1 as well as ZFP42/REX1, PRDM14 and NANOG for naïve pluripotency, in contrast to short telomere hESCs. hESCs express high telomerase activity as expected, and ubiquitously express NOP10 and DKC1, stabilizing components of telomerase complexes, regardless of telomere lengths. Moreover, new candidate genes such as MELK, MSH6 and UBQLN1 cluster with long telomeres and pluripotency network. Notably, short telomere hESCs exhibit higher oxidative phosphorylation primed for lineage differentiation, whereas long telomere hESCs show elevated glycolysis, another key feature for naïve pluripotency. Our data further suggest that telomere length is implicated in metabolism activity and pluripotency state of hESCs. Single cell analysis of telomere and RNA-sequencing can be exploited to further understand the molecular mechanisms of telomere heterogeneity.

Project description:The Zinc finger and SCAN domain containing 4 (Zscan4) protein, expressed transiently in pluripotent stem cells as well as in gamete and embryonic development, regulates genome stability in addition to telomere elongation and karyotype correction in mouse ES cells. However, the mechanism underlying Zscan4’s ability to counter the toxic effects of DNA/chromatin remodeling is not fully understood. In this study, we used ChIP-seq technology with Zscan4 antibodies to identify genome-wide binding sites in mouse and human ES cells. We discovered that both mouse and human Zscan4 bind to specific simple sequence repeats, (TG/CA)n, that have a propensity to induce genomic instability through a left-handed helix and stem-loop structure. Furthermore, we found that Zscan4 removes active histone marks from (TG/CA)n regions to maintain the closed/inactive chromatin state. These results demonstrate that Zscan4 protects unstable genomic regions by directing chromatin condensation.

Project description:The Zinc finger and SCAN domain containing 4 (Zscan4) protein, expressed transiently in pluripotent stem cells as well as in gamete and embryonic development, regulates genome stability in addition to telomere elongation and karyotype correction in mouse ES cells. However, the mechanism underlying Zscan4’s ability to counter the toxic effects of DNA/chromatin remodeling is not fully understood. In this study, we used ChIP-seq technology with Zscan4 antibodies to identify genome-wide binding sites in mouse and human ES cells. We discovered that both mouse and human Zscan4 bind to specific simple sequence repeats, (TG/CA)n, that have a propensity to induce genomic instability through a left-handed helix and stem-loop structure. Furthermore, we found that Zscan4 removes active histone marks from (TG/CA)n regions to maintain the closed/inactive chromatin state. These results demonstrate that Zscan4 protects unstable genomic regions by directing chromatin condensation.

Project description:The exit of naïve pluripotency contains a metabolism-induced checkpoint for telomere homeostasis.