Histone Methyltransferase Research Articles

SETDB1 activity is globally directed by H3K14 acetylation via its Triple Tudor Domain.

SETDB1 (SET domain bifurcated histone lysine methyltransferase 1) is a major protein lysine methyltransferasetrimethylating lysine 9 on histone H3 (H3K9) which isinvolved in heterochromatin formation and silencing of repeat elements (REs). It contains a unique Triple Tudor Domain (3TD), which specifically binds the dual modification of H3K14ac in the presence of H3K9me1/2/3. Here, we explored the role of the 3TD H3-tail interaction for the H3K9 methylation activity of SETDB1. We generated a binding reduced 3TD mutant and demonstrate in biochemical methylation assays on peptides and recombinant nucleosomes containing H3K14ac and H3K14ac analogs, respectively, that H3K14 acetylation is crucial for the 3TD mediated recruitment of SETDB1. We also observe this effect in cells where SETDB1 binding and activity is globally correlated with H3K14ac, and knockout of the H3K14 acetyltransferase HBO1 causes a drastic reduction in H3K9me3 levels at SETDB1 dependent sites. Regions with DNA hypomethylation after SETDB1 knockout also show an enrichment in SETDB1-dependent H3K9me3 and H3K14ac. Further analyses revealed that 3TD is particularly important at specific target regions like L1M REs, where H3K9me3 cannot be efficiently reconstituted by the 3TD mutant of SETDB1. In summary, our data demonstrate that the H3K9me3 and H3K14ac are not antagonistic marks but rather the presence of H3K14ac is required for SETDB1 recruitment via 3TD binding to H3K9me1/2/3-K14ac regionsand establishment of H3K9me3.

Abstract B007: Unlocking antiviral immunity against endogenous retroviruses in skin squamous cell carcinomas

Abstract Known as molecular parasites that invaded our genome through ancestors, transposons (mainly retrotransposons) are interspersed genomic repeats that constitute ∼40% of the mammalian genome. Primarily residing in the heterochromatin, retrotransposons exhibit dynamic expressions to orchestrate embryonic development and shape adult functions. Although rare, a cohort of evolutionarily young retrotransposons resisted extinction, whose selfish activities underlie polymorphic variations and genetic diseases including cancer. While the extraordinary molecular and functional heterogeneity of retrotransposons has been long recognized, mechanistic dissection remains challenging. To tackle this challenge, we use murine skin as our model, given its well-characterized, abundant, and highly accessible adult stem cells, not only mediating postnatal remodeling and tissue repair, but also serving as cell of origin for squamous cell carcinomas. By analyzing a genetic model lacking a known retrotransposon suppressor, histone methyltransferase Setdb1, which we found to be essential in the adult skin, we saw hair loss and hair follicle stem cell exhaustion phenotype, accompanied by a robust and selective surge of endogenous retroviruses (ERVs). When combined with squamous cell carcinoma drivers, Setdb1 loss significantly blocked tumor progression in vivo. We detected abundant retroviral peptides originated from its full-length copies through mass spectrometry and viral-like particles through transmission electron microscopy that are immunoreactive to previously reported ERV surface envelope (env) antibody. Similar viral-like particles were broadly evident across several epithelial tissues beyond skin, implicating its conserved function across squamous cancers. Mechanistically, epithelial originated ERVs elicit tissue wide inflammatory response, and can be ameliorated by pharmacological or genetic inhibition of retroviral activity. Moreover, ERV reactivation induced replication stress functionally accounts for stem cell exhaustion, therefore serving as a specific therapeutic vulnerability in squamous cancers. As an evolutionary conundrum, viral-coding ERVs pose a threat to host fitness and yet, they’ve resisted extinction persisting in the mammalian genome. Our findings suggest ERVs wrestle with the host surveillance programs to regulate adult tissue physiology and pathology, thus providing a key target in eliciting innate immunity in squamous cell carcinomas. Citation Format: Ying Lyu, Yejing Ge. Unlocking antiviral immunity against endogenous retroviruses in skin squamous cell carcinomas [abstract]. In: Proceedings of the AACR Special Conference in Cancer Research: RNAs as Drivers, Targets, and Therapeutics in Cancer; 2024 Nov 14-17; Bellevue, Washington. Philadelphia (PA): AACR; Mol Cancer Ther 2024;23(11_Suppl):Abstract nr B007.

Abstract 4137500: The Histone Methyltransferase MLL1 Regulates Notch Signaling and T Cell Phenotype During Pathologic Abdominal Aortic Aneurysm Development

Objective: Abdominal aortic aneurysms (AAA) are characterized by pathological vascular remodeling and an imbalance between anti-inflammatory regulatory T H cells (Tregs) and pro-inflammatory T H 17 cells within the aortic wall. The mechanisms regulating CD4 + T H cell differentiation during AAA development remain unknown. Recently, the histone methyltransferase, mixed lineage leukemia 1 (MLL1), has been shown to influence T H cell phenotype by directly altering key transcription factors for T H 17 (RORγ) and Treg (FOXp3) differentiation in varying disease states. As such the objective of this study was to evaluate the role of MLL1 in promoting T H 17 activity within AAA development and to determine key T H 17 cell signaling pathways that are altered Methods: Single-cell sequencing was conducted on human AAAs and control tissue samples. For our murine model, C57BL/6 mice were injected with an AAV encoding a PCSK9 gain-of-function mutation and fed a saturated fat diet followed by either AngII infusion to induce AAAs (1 µg/kg/min) or saline. Mice with T-cell specific deletion of Notch1 signaling (Notch1 f/f CD4 cre+ ) or MLL1 ( Mll1 f/f CD4 cre+ ) were subjected to the AngII-induced AAA model and AAA diameters quantified. CD4+ T-cells were isolated by MACs and gene expression analyzed by qPCR as well as T-cell phenotype by flow cytometry. ChIP was used to evaluate histone 3 lysine trimethylation (H3K4me3). Results: Single-cell RNA sequencing of human aortic tissue revealed that the epigenetic enzyme MLL1 and Notch1 signaling were profoundly upregulated in human AAA CD4+ cells compared to non-aneurysmal control samples. Congruently, CD4 + T H cells isolated from the murine AngII-induced AAA model displayed a predominance of T H 17 phenotype and elevated expression of MLL1. Histone methylation was evaluated by ChIP in AngII-induced AAA CD4+ cells and demonstrated increased levels of the MLL1-mediated activation histone methylation mark, H3K4me3, on the Notch 1 promoter. Mice deficient in CD4 + T H cell Notch signaling ( Notch1 f/f CD4 cre+ ) or MLL1 ( Mll1 f/f CD4 cre+ ) subjected to the AngII-induced murine model displayed significant reduction AAA development (n=10/group, p<0.05) with decreased CD4+ T H 17 cell activity and reciprocal increase in Treg expression. Conclusions: MLL1, a histone methyltransferase, regulates Notch1 signaling and T-cell differentiation in AAA development, causing pathologic inflammation. This pathway may serve as a potential therapeutic target to prevent aortic dilation.

Abstract 4122717: An Epigenetic Drug, GSK126 Mitigates Endothelial to Mesenchymal Transition Attenuating Atherosclerosis in Diabetes

Background: Endothelial to mesenchymal transition (EndMT) involves transformation of an endothelial to mesenchymal like cellular state. Recent studies implicate EndMT in atherosclerosis development. Diabetes is associated with both EndMT as well as accelerated atherosclerosis. Experimental evidence supports the use of epigenetic drugs that act on relevant epigenetic mechanisms to attenuate atherosclerosis. Recently, inhibition of a histone methyltransferase Enhancer of zest homolog 2 (EZH2) with GSK-126 attenuated atherosclerosis development. However, the role of EZH2 in induction of EndMT in diabetes induced atherosclerosis is not known. Methods: An in-vitro model of EndMT was generated using high glucose (HG) and TNF-α in human aortic endothelial cells (HAECs). EZH2 methyltransferase activity was inhibited using EZH2 specific inhibitor GSK-126. RNA sequencing was performed in this setting. EZH2 genetic knockdown (shRNA) in HAECs was also performed to validate role of EZH2 in EndMT. In addition, EZH2 mediated H3K27me3 and EndMT was assessed in atheroprone diabetic mouse model. Results: In HAECs, morphological changes as well as gene and protein expression confirmed TNF-α+HG induced EndMT, which was blunted by GSK-126. Elevated EZH2 mediated H3K27me3 activity by the TNF-α + HG stimulation was blunted with GSK-126 treatment. Furthermore, RNA sequencing identified several enriched pathways including AGE-RAGE signaling pathway in diabetic complications, focal adhesion, and leukocyte trans-endothelial migration directly relevant to EndMT and commonly deregulated in diabetic complications, which were rescued by EZH2 inhibition. Transcriptomic analysis showed that 242 genes including MMP2, NOS3 linked to EndMT were dysregulated. Interestingly, expression of 76 dysregulated genes in EndMT were rescued by GSK-126. EZH2 knockdown studies in HAECs also validated the role of EZH2 in EndMT. Furthermore, immunofluorescence staining identified elevated levels of H3K27me3 in the aortic endothelial layer of diabetic Apoe -/- mice. Co-localization of EndMT markers was observed in the endothelial layer of aortic sinus of diabetic Apoe -/- mice which was blunted with GSK-126 treatment. Conclusion: The study identified EZH2 inhibition as a novel therapeutic target in diabetes induced EndMT in atherosclerosis. These findings highlighted ongoing efforts to develop targeted therapies for diabetic patients who are at risk to develop cardiovascular disease.

Deficiency of TET2-mediated KMT2D self-transcription confers a targetable vulnerability in hepatocellular carcinoma

Abstract Hepatocellular carcinoma (HCC) has become a leading cause of cancer-related mortality worldwide. Conventional therapies tend to exacerbate comorbidities, liver dysfunction and relapse, rendering an urgent demand for novel strategy for management of HCC. Here we reported that DNA dioxygenase TET2 collaborates with histone methyltransferase KMT2D to enable transcription of KMT2D and ARID1A in HCC. Mechanistically, KMT2D and ARID1A are the major epigenetic targets of TET2 through RNA-seq analysis. Moreover, KMT2D recruits TET2 to facilitate self-transcription via oxidation of 5mC in promoter, thereby maintaining expression of ARID1A. Physiologically, KMT2D was identified as a tumor suppressor and mediates the antitumor effect of vitamin C in HCC. Tumors with depleted KMT2D present growth advantage over control group. Vitamin C is able to impair tumor growth, which is compromised by deficiency of KMT2D. Furthermore, loss of KMT2D sensitizes HCC tumors to cisplatin with reduced tumor weight and high level of DNA damage. Ultimately, TET2-KMT2D axis correlates with prognosis of HCC patients. Patients with high amount of TET2 and KMT2D presents better outcome. Our findings not only put forth a heretofore unrecognized mechanism underlying cross-talk between TET2 and KMT2D in mediating self-transcription of KMT2D, but also propose a targetable vulnerability for HCC therapy on the basis of TET2-KMT2D axis.

EZH1/2 plays critical roles in oocyte meiosis prophase I in mice

Backgroudabnormalities or defects in oocyte meiosis can result in decreased oocyte quality, reduced ovarian reserve, and female diseases. However, the mechanisms of oocyte meiosis remain largely unknown, especially epigenetic regulation. Here, we explored the role of EZH1/2 (histone methyltransferase of H3K27) in mouse oocyte meiosis by inhibiting its activity and deleting its gene.Resultswith embryonic ovary cultured in vitro, EZH1/2 was demonstrated to be essential for oocyte development during meiosis prophase I in mice. Activity inhibition or gene knockout of EZH1/2 resulted in cell apoptosis and a reduction in oocyte numbers within embryonic ovaries. By observing the expression of some meiotic marker protein (γ-H2AX, diplotene stage marker MSY2 and synapsis complex protein SCP1), we found that function deficiency of EZH1/2 resulted in failure of DNA double-strand breaks (DSBs) repair and break of meiotic progression in fetal mouse ovaries. Moreover, Ezh1/2 deficiency led to the suppression of ATM (Ataxia Telangiectasia Mutated kinase) phosphorylation and a decrease in the expression of key DNA repair proteins Hormad1, Mre11, Rad50, and Nbs1 in fetal mouse ovaries, underscoring the enzyme’s pivotal role in initiating DNA repair. RNA-seq analysis revealed that Ezh1/2-deletion induced abnormal expression of multiple genes involved into several function of oocyte development in embryonic ovaries. Knockout of Ezh1/2 in ovaries also affected the levels of H3K9me3 and H4K20me2, as well as the expression of their target genes L3mbtl4 and Fbxo44.Conclusionsour study demonstrated that EZH1/2 plays a role in the DSBs repair in oocyte meiosis prophase I via multiple mechanisms and offers new insights into the physiological regulatory role of histone modification in fetal oocyte guardianship and female fertility.

The function of histone methyltransferase SETDB1 and its roles in liver cancer

The function of histone methyltransferase SETDB1 and its roles in liver cancer

A cytoplasmic form of EHMT1N methylates viral proteins to enable inclusion body maturation and efficient viral replication.

Protein lysine methyltransferases (PKMTs) methylate histone and non-histone proteins to regulate biological outcomes such as development and disease including viral infection. While PKMTs have been extensively studied for modulating the antiviral responses via host gene regulation, their role in methylation of proteins encoded by viruses and its impact on host-pathogen interactions remain poorly understood. In this study, we discovered distinct nucleo-cytoplasmic form of euchromatic histone methyltransferase 1 (EHMT1N/C), a PKMT, that phase separates into viral inclusion bodies (IBs) upon cytoplasmic RNA-virus infection (Sendai Virus). EHMT1N/C interacts with cytoplasmic EHMT2 and methylates SeV-Nucleoprotein upon infection. Elevated nucleoprotein methylation during infection correlated with coalescence of small IBs into large mature platforms for efficient replication. Inhibition of EHMT activity by pharmacological inhibitors or genetic depletion of EHMT1N/C reduced the size of IBs with a concomitant reduction in replication. Additionally, we also found that EHMT1 condensation is not restricted to SeV alone but was also seen upon pathogenic RNA viral infections caused by Chandipura and Dengue virus. Collectively, our work elucidates a new mechanism by which cytoplasmic EHMT1 acts as proviral host factor to regulate host-pathogen interaction.

G9a promotes muscular atrophy in chronic aging and acute denervation

AbstractMuscular atrophy accompanied by neuromuscular junction (NMJ) denervation is often observed after long-term chronic diseases and aging and is associated with substantial morbidity and mortality. Here, we report that histone methyltransferase G9a is elevated in the muscle of muscular atrophy model mice and that muscle-specific deficiency of G9a (Ehmt2Ckmm−KO) alleviates muscular atrophy in both aged and denervated mice. Moreover, increased nerve-to-myofiber ratios and increased Agrin-Lrp4-MuSK signaling, which maintains NMJ, are found in aged Ehmt2Ckmm−KO mice. Together, these data suggest that G9a promotes muscular atrophy and disrupts NMJ; thus, inhibiting the G9a level may be a potential therapy for muscular atrophy.

The HIF2α-dependent Upregulation of SETDB1 Facilitates Hypoxia-induced Functional and Phenotypical Changes of Pulmonary Microvascular Endothelial Cells.

Background: Emerging studies have reported the vital role of histone modification in the dysfunction of pulmonary vascular endothelial cells, which acts as the key reason to drive the hypoxia-induced pulmonary vascular remodeling and pulmonary hypertension (PH). This study aims to investigate the role of a histone 3 lysine 9 (H3K9) methyltransferase, SET domain bifurcated 1 (SETDB1), in hypoxia-induced functional and phenotypical changes of pulmonary vascular endothelial cells. Methods: Primarily cultured rat pulmonary microvascular endothelial cells (PMVECs) were used as cell model. Specific knockdown and overexpression strategies were used to systematically determine the molecular regulation and function of SETDB1 in PMVECs. Results: SETDB1 is highly expressed and significantly upregulated in the pulmonary vascular endothelium of lung tissue isolated from SU5416/hypoxia-induced PH (SuHx-PH) rats, and also in pulmonary arterial endothelial cells (PAECs) from idiopathic pulmonary arterial hypertension (IPAH) patients, comparing to their respective controls. In primarily cultured rat PMVECs, treatment of hypoxia or CoCl2 induces significant upregulation of HIF2α, SETDB1 and H3K9me3. Specific knockdown and overexpression strategies indicate the hypoxia- or CoCl2-induced upregulation of SETDB1 is mediated through a HIF2α-dependent mechanism. Knockdown of SETDB1 significantly inhibits the hypoxia- or CoCl2-induced apoptosis, senescence and endothelial to mesenchymal transition (EndoMT) in rat PMVECs. Moreover, treatment of the specific inhibitor of histone methyltransferase, Chaetocin, effectively attenuates the disease pathogenesis of SuHx-PH in rat. Conclusions: Our results suggest that the HIF2α-dependent upregulation of SETDB1 facilitates hypoxia-induced functional and phenotypical changes of PMVECs, potentially contributing to the hypoxia-induced pulmonary vascular remodeling and PH.

SMYD family in cancer: epigenetic regulation and molecular mechanisms of cancer proliferation, metastasis, and drug resistance.

Epigenetic modifiers (miRNAs, histone methyltransferases (HMTs)/demethylases, and DNA methyltransferases/demethylases) are associated with cancer proliferation, metastasis, angiogenesis, and drug resistance. Among these modifiers, HMTs are frequently overexpressed in various cancers, and recent studies have increasingly identified these proteins as potential therapeutic targets. In this review, we discuss members of the SET and MYND domain-containing protein (SMYD) family that are topics of extensive research on the histone methylation and nonhistone methylation of cancer-related genes. Various members of the SMYD family play significant roles in cancer proliferation, metastasis, and drug resistance by regulating cancer-specific histone methylation and nonhistone methylation. Thus, the development of specific inhibitors that target SMYD family members may lead to the development of cancer treatments, and combination therapy with various anticancer therapeutic agents may increase treatment efficacy.

Combined inhibition of histone methyltransferases EZH2 and DOT1L is an effective therapy for neuroblastoma.

The child cancer, neuroblastoma (NB), is characterised by a low incidence of mutations and strong oncogenic embryonal driver signals. Many new targeted epigenetic modifier drugs have failed in human trials as monotherapy. We performed a high-throughput, combination chromatin-modifier drug screen against NB cells. We screened 13 drug candidates in 78 unique combinations. We found that the combination of two histone methyltransferase (HMT) inhibitors: GSK343, targeting EZH2, and SGC0946, targeting DOT1L, demonstrated the strongest synergy across 8 NB cell lines, with low normal fibroblast toxicity. High mRNA expression of both EZH2 and DOT1L in NB tumour samples correlated with the poorest patient survival. Combination HMT inhibitor treatment caused activation of ATF4-mediated endoplasmic reticulum (ER) stress responses. In addition, glutathione and several amino acids were depleted by HMT inhibitor combination on mass spectrometry analysis. The combination of SGC0946 and GSK343 reduced tumour growth in comparison to single agents. Our results support further investigation of HMT inhibitor combinations as a therapeutic approach in NB.

Chromatin remodeling by the histone methyltransferase SETD2 drives cardiometabolic heart failure with preserved ejection fraction

Abstract Background Cardiometabolic heart failure with preserved ejection fraction (cHFpEF) is highly prevalent and associates with a poor outcome. Pathological gene expression in heart failure is accompanied by changes in active histone marks without major alterations in DNA methylation. Histone 3 trimethylation at lysine 36 (H3k36me3) - a chromatin signature induced by the histone methyltransferase SETD2 – has shown a strong correlation with changes in gene expression in the human failing heart; however its role in cardiac disease is poorly understood. The present study investigates the role of SETD2/ H3k36me3 in cHFpEF. Purpose To investigate the role of chromatin remodelling in obese HFpEF (obHFpEF). Methods Mice with cardiomyocyte-specific deletion of SETD2 (c-SETD2-/-) were generated and subjected to high fat diet feeding and L-NAME treatment for 15 weeks to induce cHFpEF. Cardiac function and exercise tolerance were assessed by echocardiography and Treadmill exhaustion test, respectively. ChIP-Seq datasets were employed to determine the biological pathways regulated by H3k36me3, whereas chromatin immunoprecipitation assays (ChIP) were performed to investigate SETD2/H3k36me3 enrichment on gene promoters. SETD2 gain- and loss-of-function experiments were performed in cultured cardiomyocytes (CMs) exposed to metabolic stress (palmitic acid). SETD2/H3k36me3 axis was also investigated in left ventricular (LV) myocardial specimens from patients with cHFpEF and control donors. Moreover, pharmacological inhibition of SETD2 was performed in skinned CMs from cHFpEF patients. Results Bioinformatic analysis of ChIP-Seq data in mouse CMs showed a strong involvement of SETD2/H3k36me3 in lipid-related pathways. Specifically, SETD2 and H3k36me3 were upregulated in cHFpEF vs. control mouse hearts and were highly enriched on the promoter of sterol regulatory element-binding transcription factor 1 (SREBP1) gene. SETD2 activation in cHFpEF led to SREBP1 upregulation, myocardial triglyceride accumulation and lipotoxic damage. In cHFpEF mice, cardiomyocyte-specific deletion of SETD2 prevented hypertrophic remodeling, diastolic dysfunction and lung congestion while improving exercise tolerance. Mechanistically, SETD2 deletion blunted H3K36me3 enrichment on SREBP1 promoter thus preventing SREBP1-driven lipid accumulation and leading to a significant rewiring of the cardiac lipidome. These findings were associated with restoration of autophagic flux in the cHFpEF myocardium. In CMs exposed to palmitic acid, SETD2 depletion prevented SREBP1 upregulation, whereas SETD2 overexpression recapitulated lipotoxic damage. Finally, SETD2 was upregulated in LV myocardial samples from cHFpEF patients and its pharmacological inhibition attenuated CM stiffness. Conclusions SETD2 is a new molecular target implicated in the pathophysiology of cHFpEF.

Blockade of endothelial to mesenchymal transition (EndMT) by an inhibitor of histone methyltransferase EZH2 attenuates atherosclerosis in diabetes

Abstract Background Atherosclerosis is a major contributor to cardiovascular disease (CVD) related deaths in individuals with diabetes. Persistent endothelial cell activation caused by factors such as hyperglycaemia induces endothelial to mesenchymal transition (EndMT), which promotes both initiation as well as progression of atherosclerosis. Gene expression changes that occur during EndMT, are regulated by multiple factors including epigenetic modifiers such as the histone methyltransferase EZH2 (Enhancer of zest homolog 2). Recent studies have implicated the role of EndMT in cardiovascular complications of diabetes including atherosclerosis. However, the role of EZH2 in induction of EndMT in diabetes associated atherosclerosis is not known. Methods Aortae of atheroprone diabetic Apoe-/- mice were subjected to single cell RNA sequencing (scRNA-seq) analysis using 10X Genomics platform. In vitro model mimicking diabetes-induced EndMT was established in human aortic endothelial cells (HAECs) using high glucose (25mM) and TNF-α containing media for 72 hrs ± a small molecule inhibitor of EZH2, GSK126. RNA and Chromatin Immunoprecipitation (ChIP) sequencing was performed to identify EZH2-mediated epigenomic and corresponding transcriptomic changes in this setting. Complementary in vitro EZH2 knockdown experiments using shRNA were also performed. Moreover, Apoe-/- mice made diabetic with streptozotocin, were treated with GSK126 (50 mg/kg BW daily for 5 weeks) in an intervention study design. Aortic sections from treated and control mice were subjected to immunofluorescent staining specific for the EndMT pathway. Results scRNA-seq analysis identified an EndMT+ve endothelial cell sub-population with a diabetes specific proatherogenic transcriptomic profile. Comparison with the ENCODE dataset for EZH2 target genes using Harmonizome showed that indeed multiple repressed genes in diabetes were targets of EZH2. Methyltransferase activity of EZH2 was elevated in in vitro settings of EndMT. Interestingly, EZH2 inhibition by GSK126 attenuated EndMT. Gene expression analysis showed that GSK126 treatment rescued 76 of 242 differentially expressed genes in HAECs exposed to EndMT conditions. Several differentially expressed genes including COL1A2, MMP2, NOS3, COL4A1, and TGFB2 (FDR <0.05, Log2 fold change (2x)) were targets of EZH2 validating integrated analysis of our scRNA-seq with the ENCODE dataset. EZH2 knockdown experiments validated experimental findings of EZH2 inhibition studies using GSK126 in HAECs. Importantly, GSK126 treatment blocked EndMT resulting in reduced atherosclerosis in diabetic Apoe-/- mice in intervention studies. Conclusion This study showed that the inhibition of EZH2 with GSK126 is a potential vasculoprotective treatment for the diabetes induced EndMT and associated atherosclerosis.

Targeting the histone methyltransferase SETD7 rescues diabetes-induced impairment of angiogenic response by transcriptional repression of semaphorin 3G

Abstract Background Peripheral artery disease (PAD) is highly prevalent in patients with diabetes (DM) and associates with a high rate of limb amputation and poor prognosis. Surgical and catheter-based revascularization have failed to improve outcome in DM patients with PAD. Hence, a need exists to develop new treatment strategies able to promote blood vessel growth in this setting. Mono-methylation of histone 3 at lysine 4 (H3K4me1) - a specific epigenetic signature induced by the histone methyltransferase SETD7 - favours an open chromatin thus enabling gene transcription. Purpose To investigate whether SETD7-dependent epigenetic changes modulate angiogenic response in diabetes. Methodology Primary human aortic endothelial cells (HAECs) were exposed to normal glucose (NG, 5 mM) or high glucose (HG, 25 mM) concentrations for 48 hours. Unbiased gene expression profiling was performed by RNA sequencing (RNA-seq) followed by Ingenuity Pathway Analysis (IPA). In vitro assays, namely cell migration and tube formation were employed to study angiogenic properties in HAECs. SETD7 and H3K4me1 levels were investigated by Western blot and Chromatin immunoprecipitation (ChIP). Pharmacological blockade of SETD7 was achieved by using the highly selective inhibitor (R)-PFI-2. Mice with streptozotocin-induced diabetes were orally treated with (R)-PFI-2 or vehicle and underwent hindlimb ischemia by femoral artery ligation for 14 days. Blood flow recovery was analysed at 30 minutes, 7 and 14 days by laser Doppler imaging. Our experimental findings were also translated in gastrocnemius muscle samples from patients with and without diabetes. Results RNA-seq in HG-treated HAECs revealed a profound upregulation of the methyltransferase SETD7, an enzyme involved in mono-methylation of lysine 4 at histone 3 (H3K4me1). SETD7 upregulation in HG-treated HAECs was associated with increased H3K4me1 levels as well as with impaired endothelial cell migration and tube formation. Both SETD7 gene silencing and pharmacological inhibition by (R)PFI-2 rescued hyperglycemia-induced impairment of HAECs migration and tube formation, while SETD7 overexpression blunted the angiogenic response. RNA-seq and ChIP assays showed that SETD7-dependent H3K4me1 regulates the transcription of the angiogenesis inhibitor semaphorin-3G (SEMA-3G). Moreover, SEMA-3G overexpression blunted migration and tube formation in SETD7-depleted HAECs. In diabetic mice with hindlimb ischemia, treatment with (R)-PFI-2 improved limb vascularization and perfusion as compared to vehicle. Finally, SETD7/SEMA3G axis was upregulated in muscle specimens from T2D patients as compared to controls. Conclusion Targeting SETD7 represents a novel epigenetic-based therapy to boost neovascularization in diabetic patients with PAD.

DOT1L protects against podocyte injury in diabetic kidney disease through phospholipase C-like 1

BackgroundPodocyte injury causes proteinuria and accelerates glomerular sclerosis during diabetic kidney disease (DKD). Disruptor of telomeric silencing 1-like (DOT1L), an evolutionarily conserved histone methyltransferase, has been reported in preventing kidney fibrosis in chronic kidney disease models. However, whether DOT1L exerts beneficial effects in diabetes induced podocyte injury and the underlying molecular mechanisms need further exploration.MethodsThe expression of DOT1L was confirmed by Western blotting in MPC-5 cells and cortex of kidney from db/db mice, as well as immunofluorescence staining in human renal biopsy samples. The effect of DOT1L on podocyte injury was obtained using MPC-5 cells and db/db mice. The potential target genes regulated by DOT1L was measured by RNA-sequencing. Then, a series of molecular biological experiments was performed to investigate the regulation of PLCL1 by DOT1L in MCP-5 cells and db/db mice. Lipid accumulation was assessed by UPLC-MS/MS analysis and Oil Red O staining.ResultsDOT1L expression was significantly declined in high glucose (HG)-treated MPC-5 cells, podocyte regions of kidney tissues from db/db mice and human renal biopsy samples. Subsequent investigations revealed that upregulation of DOT1L ameliorated HG-induced cell apoptosis in MPC-5 cells as well as primary podocytes. Furthermore, podocyte-specific DOT1L overexpression inhibited diabetic podocyte injury in db/db mice. Mechanistically, we revealed that DOT1L upregulated phospholipase C-like 1 (PLCL1) expression by mediating H3K79me2 at its promoter and PLCL1 silencing suppressed the protective role of DOT1L on podocyte injury. Moreover, DOT1L improved diabetes induced abnormal fatty acid metabolism in podocytes and PLCL1 knockdown reversed its protective effects.ConclusionsTaken together, our results indicate that DOT1L protects podocyte injury via PLCL1-mediated fatty acid metabolism and provides new insights into the therapeutic target of DKD.

The Plasmodium falciparum histone methyltransferase SET10 participates in a chromatin modulation network crucial for intraerythrocytic development.

The lifecycle progression of the malaria parasite Plasmodium falciparum requires precise tuning of gene expression including histone methylation. The histone methyltransferase PfSET10 was previously described as an H3K4 methyltransferase involved in var gene regulation, making it a prominent antimalarial target. In this study, we investigated the role of PfSET10 in the blood stages of P. falciparum in more detail, using tagged PfSET10-knockout (KO) and -knockdown (KD) lines. We demonstrate a nuclear localization of PfSET10 with peak protein levels in schizonts. PfSET10 deficiency reduces intraerythrocytic growth but has no effect on gametocyte commitment and maturation. Screening of the PfSET10-KO line for histone methylation variations reveals that lack of PfSET10 renders the parasites unable to mark H3K18me1, while no reduction in the H3K4 methylation status could be observed. Comparative transcriptomic profiling of PfSET10-KO schizonts shows an upregulation of transcripts particularly encoding proteins linked to red blood cell remodeling and antigenic variation, suggesting a repressive function of the histone methylation mark. TurboID coupled with mass spectrometry further highlights an extensive nuclear PfSET10 interaction network with roles in transcriptional regulation and mRNA processing, DNA replication and repair, and chromatin remodeling. The main interactors of PfSET10 include ApiAP2 transcription factors, epigenetic regulators like PfHDAC1, chromatin modulators like PfMORC and PfISWI, mediators of RNA polymerase II, and DNA replication licensing factors. The combined data pinpoint PfSET10 as a histone methyltransferase essential for H3K18 methylation that regulates nucleic acid metabolic processes in the P. falciparum blood stages as part of a comprehensive chromatin modulation network.IMPORTANCEThe fine-tuned regulation of DNA replication and transcription is particularly crucial for the rapidly multiplying blood stages of malaria parasites and proteins involved in these processes represent important drug targets. This study demonstrates that contrary to previous reports the histone methyltransferase PfSET10 of the malaria parasite Plasmodium falciparum promotes the methylation of histone 3 at lysine K18, a histone mark to date not well understood. Deficiency of PfSET10 due to genetic knockout affects genes involved in intraerythrocytic development. Furthermore, in the nuclei of blood-stage parasites, PfSET10 interacts with various protein complexes crucial for DNA replication, remodeling, and repair, as well as for transcriptional regulation and mRNA processing. In summary, this study highlights PfSET10 as a methyltransferase affecting H3K18 methylation with critical functions in chromatin maintenance during the development of P. falciparum in red blood cells.

Histone Methylation-Mediated Reproductive Toxicity to Consumer Product Chemicals in Caenorhabditis elegans: An Epigenetic Adverse Outcome Pathway (AOP).

The significance of histone methylation in epigenetic inheritance underscores its relevance to disease and the chronic effects of environmental chemicals. However, limited evidence of the causal relationships between chemically induced epigenetic changes and organismal-level effects hinders the application of epigenetic markers in ecotoxicological assessments. This study explored the contribution of repressive histone marks to reproductive toxicity induced by chemicals in consumer products in Caenorhabditis elegans, applying the adverse outcome pathway (AOP) framework. Triclosan (TCS) and tetrabromobisphenol A (TBBPA) exposures caused reproductive toxicity and altered histone methyltransferase (HMT) and histone demethylase (HDM) activities, increasing the level of trimethylation of H3K9 and H3K27. Notably, treatment with an H3K27-specific HMT inhibitor alleviated reproductive defects and the transcriptional response of genes related to vitellogenin, xenobiotic metabolism, and oxidative stress. Comparison of points of departure (PODs) based on calculated benchmark concentrations (BMCs) revealed the sensitivity of histone-modifying enzyme activities to these chemicals. Our findings suggest that the 'disturbance of HMT and HDM' can serve as the molecular initiating event (MIE) leading to reproductive toxicity in the epigenetic AOP for TCS and TBBPA. The study extended the biological applicability of these enzymes by identifying model species with analogous protein sequences and functions. This combined approach enhances the essentiality, empirical support, and taxonomic domain of applicability (tDOA), which are crucial considerations for ecotoxicological AOPs. Given the widespread use and environmental distribution of chemicals in consumer products, this study proposes histone-modifying enzyme activity as an effective screening tool for reproductive toxicants and emphasizes the integration of epigenetic mechanisms into a prospective ERA.

The Plasmodium falciparum histone methyltransferase PfSET10 is dispensable for the regulation of antigenic variation and gene expression in blood-stage parasites.

The malaria parasite Plasmodium falciparum employs antigenic variation of the virulence factor P. falciparum erythrocyte membrane protein 1 (PfEMP1) to escape adaptive immune responses during blood infection. Antigenic variation of PfEMP1 occurs through epigenetic switches in the mutually exclusive expression of individual members of the multi-copy var gene family. var genes are located in perinuclear clusters of transcriptionally inactive heterochromatin. Singular var gene activation is linked to locus repositioning into a dedicated zone at the nuclear periphery and deposition of histone 3 lysine 4 di-/trimethylation (H3K4me2/3) and H3K9 acetylation marks in the promoter region. While previous work identified the putative H3K4-specific methyltransferase PfSET10 as an essential enzyme and positive regulator of var gene expression, a recent study reported conflicting data. Here, we used iterative genome editing to engineer a conditional PfSET10 knockout line tailored to study the function of PfSET10 in var gene regulation. We demonstrate that PfSET10 is not required for mutually exclusive var gene expression and switching. We also show that PfSET10 is dispensable not only for asexual parasite proliferation but also for sexual conversion and gametocyte differentiation. Furthermore, comparative RNA-seq experiments revealed that PfSET10 plays no obvious role in regulating gene expression during asexual parasite development and gametocytogenesis. Interestingly, however, PfSET10 shows different subnuclear localization patterns in asexual and sexual stage parasites and female-specific expression in mature gametocytes. In summary, our work confirms in detail that PfSET10 is not involved in regulating var gene expression and is not required for blood-stage parasite viability, indicating PfSET10 may be important for life cycle progression in the mosquito vector or during liver stage development.IMPORTANCEThe malaria parasite Plasmodium falciparum infects hundreds of millions of people every year. To survive and proliferate in the human bloodstream, the parasites need to escape recognition by the host's immune system. To achieve this, P. falciparum can change the expression of surface antigens via a process called antigenic variation. This fascinating survival strategy is based on infrequent switches in the expression of single members of the var multigene family. Previous research reported conflicting results on the role of the epigenetic regulator PfSET10 in controlling mutually exclusive var gene expression and switching. Here, we unequivocally demonstrate that PfSET10 is neither required for antigenic variation nor the expression of any other proteins during blood-stage infection. This information is critical in directing our attention toward exploring alternative molecular mechanisms underlying the control of antigenic variation and investigating the function of PfSET10 in other life cycle stages.

SETDB1 targeting SESN2 regulates mitochondrial damage and oxidative stress in renal ischemia–reperfusion injury

BackgroundThe role of histone methyltransferase SETDB1 in renal ischemia–reperfusion (I/R) injury has not been explored yet. This study aims to investigate the potential mechanism of SETDB1 in regulating renal I/R injury and its impact on mitochondrial damage and oxidative stress.MethodsThe in vivo model of renal I/R in mice and the in vitro model of hypoxia/reoxygenation (H/R) in human renal tubular epithelial cells (HK-2) were constructed to detect the expression of SETDB1. Next, the specific inhibitor (R,R)-59 and knockdown viruses were used to inhibit SETDB1 and verify its effects on mitochondrial damage and oxidative stress. Chromatin immunoprecipitation (ChIP) and coimmunoprecipitation (CoIP) were implemented to explore the in-depth mechanism of SETDB1 regulating renal I/R injury.ResultsThe study found that SETDB1 had a regulatory role in mitochondrial damage and oxidative stress during renal I/R injury. Notably, SESN2 was identified as a target of SETDB1, and its expression was under the influence of SETDB1. Besides, SESN2 mediated the regulation of SETDB1 on renal I/R injury. Through deeper mechanistic studies, we uncovered that SETDB1 collaborates with heterochromatin HP1β, facilitating the labeling of H3K9me3 on the SESN2 promoter and impeding SESN2 expression.ConclusionsThe SETDB1/HP1β-SESN2 axis emerges as a potential therapeutic strategy for mitigating renal I/R injury.