Project description:Genome stability relies on epigenetic mechanisms that enforce repression of endogenous retroviruses (ERVs). Current evidence suggests that distinct chromatin-based mechanisms repress ERVs in cells of embryonic origin (histone methylation-dominant) versus more differentiated cells (DNA methylation-dominant). However, the latter aspect of this model has not been tested. Remarkably, and in contrast to the prevailing model, we find that repressive histone methylation catalyzed by the enzyme SETDB1 is critical for suppression of specific ERV families and exogenous retroviruses in committed B-lineage cells from adult mice. The profile of ERV activation in SETDB1-deficient B cells is distinct from that observed in corresponding embryonic tissues, despite the loss of repressive chromatin modifications at all ERVs. We provide evidence that, upon loss of SETDB1, ERVs are activated in a lineage-specific manner depending on the set of transcription factors available to target proviral regulatory elements. These findings have important implications for genome stability in somatic cells, as well as the interface between epigenetic repression and viral latency. Expression profiling and bisulfite PCR sequencing in Setdb1 C/C and Setdb1 D/D pro-B cells

Project description:Genome stability relies on epigenetic mechanisms that enforce repression of endogenous retroviruses (ERVs). Current evidence suggests that distinct chromatin-based mechanisms repress ERVs in cells of embryonic origin (histone methylation-dominant) versus more differentiated cells (DNA methylation-dominant). However, the latter aspect of this model has not been tested. Remarkably, and in contrast to the prevailing model, we find that repressive histone methylation catalyzed by the enzyme SETDB1 is critical for suppression of specific ERV families and exogenous retroviruses in committed B-lineage cells from adult mice. The profile of ERV activation in SETDB1-deficient B cells is distinct from that observed in corresponding embryonic tissues, despite the loss of repressive chromatin modifications at all ERVs. We provide evidence that, upon loss of SETDB1, ERVs are activated in a lineage-specific manner depending on the set of transcription factors available to target proviral regulatory elements. These findings have important implications for genome stability in somatic cells, as well as the interface between epigenetic repression and viral latency.

Project description:Silencing of endogenous retroviruses (ERVs) is largely mediated by repressive chromatin modifications, such as H3K9me3 and DNA methylation. Their impact on ERV silencing differs in various cell types and, no systematic analyses on the interdependence between H3K9me3 and DNA methylation have been performed in differentiated cells. Here we show that deletion of the H3K9me3 HMTase Setdb1 in mouse embryonic endoderm results in ERV de-repression in only a subset of endoderm cells. We found that de-repression is restricted to visceral endoderm descendants and does not occur in definitive endoderm cells. Deletion of Setdb1 in visceral endoderm progenitors resulted in loss of H3K9me3 and reduced DNA methylation of IAPEz, consistent with up-regulation of this ERV family. In definitive endoderm cells, loss of Setdb1 did not affect H3K9me3 nor DNA methylation, suggesting Setdb1-independent pathways for maintaining these modifications. Importantly, Dnmt1 ko resulted in ERV de-repression in both visceral and definitive endoderm cells, while H3K9me3 was unaltered. Thus, our data suggest a dominant role of DNA methylation over H3K9me3 in ERV silencing in endoderm cells. Our findings suggest, that H3K9me3 is not sufficient for ERV silencing, but rather critical for maintaining high DNA methylation.

Project description:Silencing of endogenous retroviruses (ERVs) is largely mediated by repressive chromatin modifications, such as H3K9me3 and DNA methylation. Their impact on ERV silencing differs in various cell types and, no systematic analyses on the interdependence between H3K9me3 and DNA methylation have been performed in differentiated cells. Here we show that deletion of the H3K9me3 HMTase Setdb1 in mouse embryonic endoderm results in ERV de-repression in only a subset of endoderm cells. We found that de-repression is restricted to visceral endoderm descendants and does not occur in definitive endoderm cells. Deletion of Setdb1 in visceral endoderm progenitors resulted in loss of H3K9me3 and reduced DNA methylation of IAPEz, consistent with up-regulation of this ERV family. In definitive endoderm cells, loss of Setdb1 did not affect H3K9me3 nor DNA methylation, suggesting Setdb1-independent pathways for maintaining these modifications. Importantly, Dnmt1 ko resulted in ERV de-repression in both visceral and definitive endoderm cells, while H3K9me3 was unaltered. Thus, our data suggest a dominant role of DNA methylation over H3K9me3 in ERV silencing in endoderm cells. Our findings suggest, that H3K9me3 is not sufficient for ERV silencing, but rather critical for maintaining high DNA methylation.

Project description:Silencing of endogenous retroviruses (ERVs) is largely mediated by repressive chromatin modifications, such as H3K9me3 and DNA methylation. Their impact on ERV silencing differs in various cell types and, no systematic analyses on the interdependence between H3K9me3 and DNA methylation have been performed in differentiated cells. Here we show that deletion of the H3K9me3 HMTase Setdb1 in mouse embryonic endoderm results in ERV de-repression in only a subset of endoderm cells. We found that de-repression is restricted to visceral endoderm descendants and does not occur in definitive endoderm cells. Deletion of Setdb1 in visceral endoderm progenitors resulted in loss of H3K9me3 and reduced DNA methylation of IAPEz, consistent with up-regulation of this ERV family. In definitive endoderm cells, loss of Setdb1 did not affect H3K9me3 nor DNA methylation, suggesting Setdb1-independent pathways for maintaining these modifications. Importantly, Dnmt1 ko resulted in ERV de-repression in both visceral and definitive endoderm cells, while H3K9me3 was unaltered. Thus, our data suggest a dominant role of DNA methylation over H3K9me3 in ERV silencing in endoderm cells. Our findings suggest, that H3K9me3 is not sufficient for ERV silencing, but rather critical for maintaining high DNA methylation.

Project description:Silencing of endogenous retroviruses (ERVs) is largely mediated by repressive chromatin modifications, such as H3K9me3 and DNA methylation. Their impact on ERV silencing differs in various cell types and, no systematic analyses on the interdependence between H3K9me3 and DNA methylation have been performed in differentiated cells. Here we show that deletion of the H3K9me3 HMTase Setdb1 in mouse embryonic endoderm results in ERV de-repression in only a subset of endoderm cells. We found that de-repression is restricted to visceral endoderm descendants and does not occur in definitive endoderm cells. Deletion of Setdb1 in visceral endoderm progenitors resulted in loss of H3K9me3 and reduced DNA methylation of IAPEz, consistent with up-regulation of this ERV family. In definitive endoderm cells, loss of Setdb1 did not affect H3K9me3 nor DNA methylation, suggesting Setdb1-independent pathways for maintaining these modifications. Importantly, Dnmt1 ko resulted in ERV de-repression in both visceral and definitive endoderm cells, while H3K9me3 was unaltered. Thus, our data suggest a dominant role of DNA methylation over H3K9me3 in ERV silencing in endoderm cells. Our findings suggest, that H3K9me3 is not sufficient for ERV silencing, but rather critical for maintaining high DNA methylation.

Project description:Silencing of endogenous retroviruses (ERVs) is largely mediated by repressive chromatin modifications, such as H3K9me3 and DNA methylation. Their impact on ERV silencing differs in various cell types and, no systematic analyses on the interdependence between H3K9me3 and DNA methylation have been performed in differentiated cells. Here we show that deletion of the H3K9me3 HMTase Setdb1 in mouse embryonic endoderm results in ERV de-repression in only a subset of endoderm cells. We found that de-repression is restricted to visceral endoderm descendants and does not occur in definitive endoderm cells. Deletion of Setdb1 in visceral endoderm progenitors resulted in loss of H3K9me3 and reduced DNA methylation of IAPEz, consistent with up-regulation of this ERV family. In definitive endoderm cells, loss of Setdb1 did not affect H3K9me3 nor DNA methylation, suggesting Setdb1-independent pathways for maintaining these modifications. Importantly, Dnmt1 ko resulted in ERV de-repression in both visceral and definitive endoderm cells, while H3K9me3 was unaltered. Thus, our data suggest a dominant role of DNA methylation over H3K9me3 in ERV silencing in endoderm cells. Our findings suggest, that H3K9me3 is not sufficient for ERV silencing, but rather critical for maintaining high DNA methylation.

Project description:Transcription of endogenous retroviruses (ERVs) is inhibited by de novo DNA methylation during gametogenesis, a process initiated after birth in oocytes and at ~E15.5 in prospermatogonia. Earlier in germline development however, the genome, including most retrotransposons, is progressively demethylated, with young ERVK and ERV1 elements retaining intermediate methylation levels. As DNA methylation reaches a low point in E13.5 primordial germ cells (PGCs) of both sexes, we determined whether retrotransposons are marked by H3K9me3 and H3K27me3 using a recently developed low input ChIP-seq method. Although these repressive histone modifications are predominantly found on distinct genomic regions in E13.5 PGCs, they concurrently mark partially methylated LTRs and LINE1 elements. Germline-specific conditional knock-out (KO) of the H3K9 methyltransferase SETDB1 yields a decrease of both histone marks and DNA methylation at H3K9me3 enriched retrotransposon families. Strikingly, Setdb1-KO E13.5 PGCs show concomitant de-repression of many marked ERVs, including IAP, ETn and ERVK10C elements and ERV-proximal genes, a subset in a sex-dependent manner. Furthermore, Setdb1 deficiency is associated with a reduced number of male PGCs and postnatal hypogonadism in both sexes. Taken together, these observations reveal that SETDB1 is an essential guardian against proviral expression prior to the onset of de novo DNA methylation in the germline. H3K9me3, H3K27me3 and expression profiles in Setdb1 WT, Het and KO male and female E13.5 PGCs.

Project description:Endogenous retroviruses (ERVs), which are responsible for 10% of spontaneous mouse mutations, are kept under control via several epigenetic mechanisms. The H3K9 histone methyltransferase SETDB1 is essential for ERV repression in embryonic stem cells (ESCs), with DNA methylation also playing an important role. It has been suggested that SETDB1 protects ERVs from TET-dependent DNA demethylation, but the relevance of this mechanism for ERV expression remains unclear. Moreover, previous studies have been performed in primed ESCs, which are not epigenetically or transcriptionally representative of preimplantation embryos. We used naïve ESCs to investigate the role of SETDB1 in ERV regulation and, in particular, its relationship with TET-mediated DNA demethylation. Naïve ESCs show an increased dependency on SETDB1 for ERV silencing when compared to primed ESCs, including at the highly mutagenic intracisternal A particles (IAPs). We found that, in the absence of SETDB1, TET2 activates IAP elements in a catalytic-dependent manner. Surprisingly, however, TET2 does not drive changes in DNA methylation levels at IAPs, suggesting that it regulates these transposons indirectly.

Project description:Endogenous retroviruses (ERVs), which are responsible for 10% of spontaneous mouse mutations, are kept under control via several epigenetic mechanisms. The H3K9 histone methyltransferase SETDB1 is essential for ERV repression in embryonic stem cells (ESCs), with DNA methylation also playing an important role. It has been suggested that SETDB1 protects ERVs from TET-dependent DNA demethylation, but the relevance of this mechanism for ERV expression remains unclear. Moreover, previous studies have been performed in primed ESCs, which are not epigenetically or transcriptionally representative of preimplantation embryos. We used naïve ESCs to investigate the role of SETDB1 in ERV regulation and, in particular, its relationship with TET-mediated DNA demethylation. Naïve ESCs show an increased dependency on SETDB1 for ERV silencing when compared to primed ESCs, including at the highly mutagenic intracisternal A particles (IAPs). We found that, in the absence of SETDB1, TET2 activates IAP elements in a catalytic-dependent manner. Surprisingly, however, TET2 does not drive changes in DNA methylation levels at IAPs, suggesting that it regulates these transposons indirectly.