Explore the vast range of titles available.

Brown adipocytes share the same developmental origin with skeletal muscle. Here we find that a brown adipocyte-to-myocyte remodeling also exists in mature brown adipocytes, and is induced by prolonged high fat diet (HFD) feeding, leading to brown fat dysfunction. This process is regulated by the interaction of epigenetic pathways involving histone and DNA methylation. In mature brown adipocytes, the histone demethylase UTX maintains persistent demethylation of the repressive mark H3K27me3 at Prdm16 promoter, leading to high Prdm16 expression. PRDM16 then recruits DNA methyltransferase DNMT1 to Myod1 promoter, causing Myod1 promoter hypermethylation and suppressing its expression. The interaction between PRDM16 and DNMT1 coordinately serves to maintain brown adipocyte identity while repressing myogenic remodeling in mature brown adipocytes, thus promoting their active brown adipocyte thermogenic function. Suppressing this interaction by HFD feeding induces brown adipocyte-to-myocyte remodeling, which limits brown adipocyte thermogenic capacity and compromises diet-induced thermogenesis, leading to the development of obesity. Brown adipocytes contribute to energy balance, and adipocyte development and brown adipocyte thermogenesis are in part regulated by epigenetic modifications. Here the authors report that the histone demethylase Utx maintains brown adipocyte identity via demethylation of PRDM16, which in turn represses myogenic remodelling via DNMT1-mediated Myod1 promoter hypermethylation in mice.

Stem cell proviral silencing Endogenous retroviruses are widely dispersed in mammalian genomes, and are silenced in somatic cells by DNA methylation. Here, an endogenous retroviruses silencing pathway independent of DNA methylation is shown to operate in embryonic stem cells. The pathway involves the histone H3K9 methyltransferase ESET/SETDB1 and might be important for endogenous retrovirus silencing during the stages in embryogenesis when DNA methylation is reprogrammed. Endogenous retroviruses (ERVs) are widely dispersed in mammalian genomes, and are silenced in somatic cells by DNA methylation. Here, an ERV silencing pathway independent of DNA methylation is shown to operate in embryonic stem cells. The pathway involves the histone H3K9 methyltransferase ESET and might be important for ERV silencing during the stages in embryogenesis when DNA methylation is reprogrammed. Endogenous retroviruses (ERVs), retrovirus-like elements with long terminal repeats, are widely dispersed in the euchromatic compartment in mammalian cells, comprising ∼10% of the mouse genome 1 . These parasitic elements are responsible for >10% of spontaneous mutations 2 . Whereas DNA methylation has an important role in proviral silencing in somatic and germ-lineage cells 3 , 4 , 5 , an additional DNA-methylation-independent pathway also functions in embryonal carcinoma and embryonic stem (ES) cells to inhibit transcription of the exogenous gammaretrovirus murine leukaemia virus (MLV) 6 , 7 , 8 . Notably, a recent genome-wide study revealed that ERVs are also marked by histone H3 lysine 9 trimethylation (H3K9me3) and H4K20me3 in ES cells but not in mouse embryonic fibroblasts 9 . However, the role that these marks have in proviral silencing remains unexplored. Here we show that the H3K9 methyltransferase ESET (also called SETDB1 or KMT1E) and the Krüppel-associated box (KRAB)-associated protein 1 (KAP1, also called TRIM28) 10 , 11 are required for H3K9me3 and silencing of endogenous and introduced retroviruses specifically in mouse ES cells. Furthermore, whereas ESET enzymatic activity is crucial for HP1 binding and efficient proviral silencing, the H4K20 methyltransferases Suv420h1 and Suv420h2 are dispensable for silencing. Notably, in DNA methyltransferase triple knockout ( Dnmt1 -/- Dnmt3a -/- Dnmt3b -/- ) mouse ES cells, ESET and KAP1 binding and ESET-mediated H3K9me3 are maintained and ERVs are minimally derepressed. We propose that a DNA-methylation-independent pathway involving KAP1 and ESET/ESET-mediated H3K9me3 is required for proviral silencing during the period early in embryogenesis when DNA methylation is dynamically reprogrammed.

Genome-wide localization and activity analysis of the de novo DNA methyltransferases DNMT3A and DNMT3B in mouse embryonic stem cells identifies overlapping and individual targeting preferences to the genome, including a role for DNMT3B in gene body methylation. Mechanism of de novo DNA methylation Genomic patterns of DNA methylation are established by the de novo DNA methyltransferases DNMT3A and DNMT3B. Dirk Schübeler and colleagues determine the genome-wide localization and activity of these two enzymes in mouse embryonic stem cells. Both localize to methylated CpG-rich regions and are excluded from active gene regulatory regions. DNMT3B also binds to the bodies of actively transcribed genes, dependent on its PWWP domain and methylation of Lys36 on histone H3. This leads to de novo methylation of active genes that scales with co-transcriptional deposition of H3K36me3. DNA methylation is an epigenetic modification associated with transcriptional repression of promoters and is essential for mammalian development. Establishment of DNA methylation is mediated by the de novo DNA methyltransferases DNMT3A and DNMT3B, whereas DNMT1 ensures maintenance of methylation through replication 1 . Absence of these enzymes is lethal 2 , and somatic mutations in these genes have been associated with several human diseases 3 , 4 . How genomic DNA methylation patterns are regulated remains poorly understood, as the mechanisms that guide recruitment and activity of DNMTs in vivo are largely unknown. To gain insights into this matter we determined genomic binding and site-specific activity of the mammalian de novo DNA methyltransferases DNMT3A and DNMT3B. We show that both enzymes localize to methylated, CpG-dense regions in mouse stem cells, yet are excluded from active promoters and enhancers. By specifically measuring sites of de novo methylation, we observe that enzymatic activity reflects binding. De novo methylation increases with CpG density, yet is excluded from nucleosomes. Notably, we observed selective binding of DNMT3B to the bodies of transcribed genes, which leads to their preferential methylation. This targeting to transcribed sequences requires SETD2-mediated methylation of lysine 36 on histone H3 and a functional PWWP domain of DNMT3B. Together these findings reveal how sequence and chromatin cues guide de novo methyltransferase activity to ensure methylome integrity.

De novo DNA methylation (DNAme) in mammalian germ cells is dependent on DNMT3A and DNMT3L. However, oocytes and spermatozoa show distinct patterns of DNAme. In mouse oocytes, de novo DNAme requires the lysine methyltransferase (KMTase) SETD2, which deposits H3K36me3. We show here that SETD2 is dispensable for de novo DNAme in the male germline. Instead, the lysine methyltransferase NSD1, which broadly deposits H3K36me2 in euchromatic regions, plays a critical role in de novo DNAme in prospermatogonia, including at imprinted genes. However, males deficient in germline NSD1 show a more severe defect in spermatogenesis than Dnmt3l −/− males. Notably, unlike DNMT3L, NSD1 safeguards a subset of genes against H3K27me3-associated transcriptional silencing. In contrast, H3K36me2 in oocytes is predominantly dependent on SETD2 and coincides with H3K36me3. Furthermore, females with NSD1-deficient oocytes are fertile. Thus, the sexually dimorphic pattern of DNAme in mature mouse gametes is orchestrated by distinct profiles of H3K36 methylation. NSD1, which deposits H3K36me2, is a major regulator of DNA methylation in male but not in female gametogenesis. NSD1 safeguards against H3K27me3-associated transcriptional silencing.

DNA methylation profiling of virus-specific T cells during acute viral infection in mice provides evidence that a fate-permissive subset of effector CD8 T cells dedifferentiates into long-lived memory T cells. A pathogen to remember Memory cells protect against reinfection, or protect against infection after vaccination, but whether they are derived from naive or effector T cells is unknown. Rafi Ahmed and colleagues study the generation, maintenance and characteristics of long-lived memory CD8 T cells in humans after yellow fever vaccination and deuterium labelling. The study demonstrates that long-lived memory CD8 T cells are derived from cells that have divided extensively during the effector phase of the infection. Quiescent memory cells appear to revert to a naive phenotype but maintain an upregulated pattern of gene regulation that resembles effector T cells. In a second paper in this issue, Rafi Ahmed and colleagues examine changes in DNA methylation during effector and memory CD8 T cell differentiation, providing support for a model in which long-lived memory cells arise from a precursor of effector cells. Memory CD8 T cells that circulate in the blood and are present in lymphoid organs are an essential component of long-lived T cell immunity. These memory CD8 T cells remain poised to rapidly elaborate effector functions upon re-exposure to pathogens, but also have many properties in common with naive cells, including pluripotency and the ability to migrate to the lymph nodes and spleen. Thus, memory cells embody features of both naive and effector cells, fuelling a long-standing debate centred on whether memory T cells develop from effector cells or directly from naive cells 1 , 2 , 3 , 4 . Here we show that long-lived memory CD8 T cells are derived from a subset of effector T cells through a process of dedifferentiation. To assess the developmental origin of memory CD8 T cells, we investigated changes in DNA methylation programming at naive and effector cell-associated genes in virus-specific CD8 T cells during acute lymphocytic choriomeningitis virus infection in mice. Methylation profiling of terminal effector versus memory-precursor CD8 T cell subsets showed that, rather than retaining a naive epigenetic state, the subset of cells that gives rise to memory cells acquired de novo DNA methylation programs at naive-associated genes and became demethylated at the loci of classically defined effector molecules. Conditional deletion of the de novo methyltransferase Dnmt3a at an early stage of effector differentiation resulted in reduced methylation and faster re-expression of naive-associated genes, thereby accelerating the development of memory cells. Longitudinal phenotypic and epigenetic characterization of the memory-precursor effector subset of virus-specific CD8 T cells transferred into antigen-free mice revealed that differentiation to memory cells was coupled to erasure of de novo methylation programs and re-expression of naive-associated genes. Thus, epigenetic repression of naive-associated genes in effector CD8 T cells can be reversed in cells that develop into long-lived memory CD8 T cells while key effector genes remain demethylated, demonstrating that memory T cells arise from a subset of fate-permissive effector T cells.

In dividing cells, the epigenetic mechanism of DNA methylation is catalyzed by enzymes that maintain DNA methylation or act as a de novo methyltransferase. In this study, the authors find that DNA methyltransferases Dnmt1 and 3a have an active role in the maintenance of DNA methylation in postmitotic excitatory neurons. Results indicate that there is a redundancy between the two enzymes in neurons and that DNA methylation is essential for normal synaptic plasticity and memory formation. Dnmt1 and Dnmt3a are important DNA methyltransferases that are expressed in postmitotic neurons, but their function in the CNS is unclear. We generated conditional mutant mice that lack Dnmt1 , Dnmt3a or both exclusively in forebrain excitatory neurons and found that only double knockout (DKO) mice showed abnormal long-term plasticity in the hippocampal CA1 region together with deficits in learning and memory. Although we found no neuronal loss, hippocampal neurons in DKO mice were smaller than in the wild type; furthermore, DKO neurons showed deregulated expression of genes, including the class I MHC genes and Stat1 , that are known to contribute to synaptic plasticity. In addition, we observed a significant decrease in DNA methylation in DKO neurons. We conclude that Dnmt1 and Dnmt3a are required for synaptic plasticity, learning and memory through their overlapping roles in maintaining DNA methylation and modulating neuronal gene expression in adult CNS neurons.

During mammalian development, DNA methylation patterns need to be reset in primordial germ cells (PGCs) and preimplantation embryos. However, many LTR retrotransposons and imprinted genes are impervious to such global epigenetic reprogramming via hitherto undefined mechanisms. Here, we report that a subset of such genomic regions are resistant to widespread erasure of DNA methylation in mouse embryonic stem cells (mESCs) lacking the de novo DNA methyltransferases (Dnmts) Dnmt3a and Dnmt3b. Intriguingly, these loci are enriched for H3K9me3 in mESCs, implicating this mark in DNA methylation homeostasis. Indeed, deletion of the H3K9 methyltransferase SET domain bifurcated 1 (Setdb1) results in reduced H3K9me3 and DNA methylation levels at specific loci, concomitant with increased 5-hydroxymethylation (5hmC) and ten-eleven translocation 1 binding. Taken together, these data reveal that Setdb1 promotes the persistence of DNA methylation in mESCs, likely reflecting one mechanism by which DNA methylation is maintained at LTR retrotransposons and imprinted genes during developmental stages when DNA methylation is reprogrammed.

Inactivation of three Tet genes in mice leads to gastrulation phenotypes similar to those in embryos with increased Nodal signalling, revealing a functional redundancy of Tet genes and showing balanced and dynamic DNA methylation and demethylation is crucial to regulate key signalling pathways in early body plan formation. Dnmt and Tet enzymes controls Nodal signalling The importance of DNA methylation and its removal by the TET family enzymes during embryo development have been a much debated area of research. Here, Guo-Liang Xu and colleagues show that inactivation of all three Tet genes in mice leads to gastrulation phenotypes similar to those in embryos with increased Nodal signalling. Expression of inhibitors of Nodal signalling is diminished and can be restored when the Dnmt3a/b genes are inactivated. These alterations do not occur if one of the Tet genes remains intact. These findings reveal a functional redundancy of Tet genes and show that balanced and dynamic DNA methylation and demethylation is crucial in regulation of key signalling pathways in early body plan formation Mammalian genomes undergo epigenetic modifications, including cytosine methylation by DNA methyltransferases (DNMTs). Oxidation of 5-methylcytosine by the Ten-eleven translocation (TET) family of dioxygenases can lead to demethylation 1 , 2 , 3 . Although cytosine methylation has key roles in several processes such as genomic imprinting and X-chromosome inactivation, the functional significance of cytosine methylation and demethylation in mouse embryogenesis remains to be fully determined 4 , 5 , 6 , 7 , 8 , 9 . Here we show that inactivation of all three Tet genes in mice leads to gastrulation phenotypes, including primitive streak patterning defects in association with impaired maturation of axial mesoderm and failed specification of paraxial mesoderm, mimicking phenotypes in embryos with gain-of-function Nodal signalling 10 . Introduction of a single mutant allele of Nodal in the Tet mutant background partially restored patterning, suggesting that hyperactive Nodal signalling contributes to the gastrulation failure of Tet mutants. Increased Nodal signalling is probably due to diminished expression of the Lefty1 and Lefty2 genes, which encode inhibitors of Nodal signalling. Moreover, reduction in Lefty gene expression is linked to elevated DNA methylation, as both Lefty–Nodal signalling and normal morphogenesis are largely restored in Tet -deficient embryos when the Dnmt3a and Dnmt3b genes are disrupted. Additionally, a point mutation in Tet that specifically abolishes the dioxygenase activity causes similar morphological and molecular abnormalities as the null mutation. Taken together, our results show that TET-mediated oxidation of 5-methylcytosine modulates Lefty–Nodal signalling by promoting demethylation in opposition to methylation by DNMT3A and DNMT3B. These findings reveal a fundamental epigenetic mechanism featuring dynamic DNA methylation and demethylation crucial to regulation of key signalling pathways in early body plan formation.

Small cell lung cancer (SCLC) is notorious for its early and frequent metastases, which contribute to it as a recalcitrant malignancy. To understand the molecular mechanisms underlying SCLC metastasis, we generated SCLC mouse models with orthotopically transplanted genome-edited lung organoids and performed multiomics analyses. We found that a deficiency of KMT2C, a histone H3 lysine 4 methyltransferase frequently mutated in extensive-stage SCLC, promoted multiple-organ metastases in mice. Metastatic and KMT2C-deficient SCLC displayed both histone and DNA hypomethylation. Mechanistically, KMT2C directly regulated the expression of DNMT3A, a de novo DNA methyltransferase, through histone methylation. Forced DNMT3A expression restrained metastasis of KMT2C-deficient SCLC through repressing metastasis-promoting MEIS/HOX genes. Further, S-(5'-adenosyl)-L-methionine, the common cofactor of histone and DNA methyltransferases, inhibited SCLC metastasis. Thus, our study revealed a concerted epigenetic reprogramming of KMT2C- and DNMT3A-mediated histone and DNA hypomethylation underlying SCLC metastasis, which suggested a potential epigenetic therapeutic vulnerability.

ABSTRACT Perioperative neurocognitive disorder (PND) is a severe postoperative complication in older patients. Epigenetic changes are hallmarks of senescence and are closely associated with cognitive impairment. However, the effects of anesthesia and surgery on the aging brain's epigenetic regulatory mechanisms and its impact on cognitive impairment remain unclear. Using a laparotomy PND model, we report significant reduction in DNA methyltransferase 3a (DNMT3a) in hippocampal neurons of aged mice, which causes global DNA methylation decrease. Knockdown of DNMT3a leads to synaptic disorder and memory impairment in aged mice. Mechanistically, bisulfite sequencing revealed that DNMT3a deficiency reduces methylation in the LRG1 promoter region and promotes its transcription. We also show that activation of TGF‐β signaling by the increase in LRG1 level, ultimately impacts the synaptic function. In contrast, both overexpressing DNMT3a or knockdown LRG1 in hippocampus can attenuate the synaptic disorders and rescue postoperative cognitive deficits in aged mice. Our results reveal that DNMT3a is a previously undefined mediator in the pathogenesis of PND, which couples epigenetic regulations with anesthesia/surgery‐induced synaptic dysfunction and represents a therapeutic target to tackle PND. DNMT3a downregulation appears to causally contribute to surgery‐induced cognitive impairment, whereas its overexpression effectively alleviated cognitive impairment behaviors. Mechanistically, DNMT3a downregulation induced by anesthesia/surgery could disrupt DNA methylation stability in the hippocampus of aged mice. This decreased the binding of DNMT3a to the Lrg1 promoter and upregulated Lrg1 expression in hippocampal neurons. Furthermore, increased Lrg1 expression activates TGF‐β signaling and promotes synaptic and memory deficits.