Search Results (331)

Systemic lupus erythematosus (SLE) is a complex autoimmune disease characterized by autoantibody production and the formation of immune complexes (ICs), which lead to widespread inflammation and tissue damage. Neutrophil extracellular traps (NETs), web-like structures composed of DNA, histones, and antimicrobial proteins released by activated neutrophils, play a crucial role in innate immunity by defending against pathogens. However, excessive NET formation and ineffective clearance of these structures contribute to the development of SLE. This review explores the mechanisms behind NET formation in SLE, their relationship with oxidative stress, and the potential role of antioxidants in treatment. Research indicates that SLE patients exhibit two key abnormalities: excessive NET formation and impaired NET clearance. Excessive NET formation is driven by proinflammatory low-density granulocytes (LDGs) and immune complexes (ICs). Impaired NET clearance stems from reduced DNase1/DNase1L3 activity or anti-nuclease autoantibodies. These two abnormalities lead to elevated circulating NETs. These NETs act as autoantigen reservoirs, forming pathogenic NET–ICs that amplify autoimmune responses. Oxidative stress drives NET formation by activating NADPH oxidase. In contrast, various antioxidants, including enzymatic and non-enzymatic types, can inhibit NET formation via scavenging reactive oxygen species (ROS) and blocking NADPH oxidase activation. Preclinical studies show that antioxidants such as curcumin, resveratrol, and mitochondrial-targeted MitoQ reduce NET formation and ameliorate lupus nephritis; clinical trials confirm that curcumin and N-acetylcysteine (NAC) lower SLE disease activity and reduce proteinuria, supporting their role as safe adjuvant therapies. However, high-dose vitamin E may exacerbate autoimmunity, highlighting the need for dose optimization. Future research should aim to clarify the mechanisms underlying NET formation in SLE and to optimize new antioxidant therapies, including assessments of their long-term efficacy and safety. Full article

Microgravity during space travel induces significant regulatory changes in the body, posing health risks for astronauts, including alterations in cell morphology and cytoskeletal integrity. The Small Ubiquitin-like Modifier (SUMO) is crucial for cellular adaptation, regulating DNA repair, cytoskeletal dynamics, cell division, and protein turnover—all processes affected by microgravity. To determine the extent to which SUMO mediates the cellular response to microgravity stress, Saccharomyces cerevisiae cells were cultured under normal gravity and simulated microgravity (SMG) in rotating wall vessels. After 12 h of culture, we investigated changes in SUMO modified proteins and protein expression. We identified 347 SUMOylated proteins, 18 of which demonstrated a 50% change in abundance under SMG. Of 3773 proteins identified, protein expression for 34 proteins decreased and 8 increased by over 50% in SMG (p < 0.05). Differentially expressed proteins represented changes in cellular processes for DNA repair, cell division, histone modification, and cytoskeleton regulation. These findings underscore the pivotal role of SUMOylation in orchestrating cellular adaptation to the unique stress of microgravity, revealing potential targets for mitigating spaceflight-induced health risks. Full article

Stress-induced mental disorders, including depression and anxiety disorders, constitute a global issue in contemporary society due to treatment complexity and the diversity of manifestations. Understanding the molecular mechanisms of these disorders presents a significant challenge for neurobiology. We investigated the effects of social defeat stress (SDS) of varying durations (10 and 30 days) on behavioral patterns and the H3K4me3 (trimethylation at the 4th lysine residue of histone H3) landscape in the prefrontal cortex of C57BL/6 mice. Furthermore, we compared these data with previously published H3K4me3 landscape data obtained after 15 days of SDS and transcriptomic data collected after 10, 15, and 30 days. We discovered that a 30-day period of stress results in more pronounced depressive-like behavior. SDS induces slight alterations in the H3K4me3 density across numerous nucleosomal peaks. The analysis of differential enrichment peaks of H3K4me3 in promoter regions following varying durations of SDS revealed that the aggregation of multiple H3K4me3 nucleosome peaks in the promoter region functions as a QR code, likely affecting the promoter’s state regarding the accessibility of transcription factors. Furthermore, we identified a cluster of genes in the promoter regions exhibiting differential enrichment peaks of H3K4me3 following SDS of any duration. This cluster includes genes encoding transcription factors such as Mef2c and Nr4a3, as well as postsynaptic density proteins (Shank2, Shank1, and Gria2), which are associated with stress sensitivity and the onset of depression; their protein products are involved in synaptic transmission and signal transduction mechanisms. The comparison of ChIP-seq and RNA-seq data following varying durations of SDS enabled a deeper insight in to the dynamics of SDS-induced changes. Together, these findings provide a better understanding of the molecular mechanisms of SDS in the prefrontal cortex. Full article

Antibiotic resistance (AR) has long been interpreted through the lens of genetic mutations and horizontal gene transfer. Yet, mounting evidence suggests that epigenetic regulation, including DNA and RNA methylation, histone-like proteins, and small non-coding RNAs, plays a similarly critical role in bacterial adaptability. These reversible modifications reshape gene expression without altering the DNA sequence, enabling transient resistance, phenotypic heterogeneity, and biofilm persistence under antimicrobial stress. Advances in single-molecule sequencing and methylome mapping have uncovered diverse DNA methyltransferase systems that coordinate virulence, efflux, and stress responses. Such epigenetic circuits allow pathogens to survive antibiotic exposure, then revert to susceptibility once pressure subsides, complicating clinical treatment. Parallel advances in CRISPR-based technologies now enable direct manipulation of these regulatory layers. CRISPR interference (CRISPRi) and catalytically inactive dCas9-fused methyltransferases can silence or reactivate genes in a programmable, non-mutational manner, offering a new route to reverse resistance or sensitize pathogens. Integrating methylomic data with transcriptomic and proteomic profiles further reveals how epigenetic plasticity sustains antimicrobial tolerance across environments. This review traces the continuum from natural bacterial methylomes to engineered CRISPR-mediated epigenetic editing, outlining how this emerging interface could redefine antibiotic stewardship. Understanding and targeting these reversible, heritable mechanisms opens the door to precision antimicrobial strategies that restore the effectiveness of existing drugs while curbing the evolution of resistance. Full article

For decades, 8-oxoguanine (8-oxoG) has been recognized as a pervasive and pro-mutagenic oxidative DNA lesion. In human cells, 8-oxoG is removed from DNA via the base excision repair pathway initiated by 8-oxoguanine–DNA glycosylase (OGG1). However, emerging evidence over the past twenty years suggests a more complex, regulatory role for this DNA modification. Here, we discuss findings that 8-oxoG, particularly when present in gene promoters, can act as a signal to modulate transcription, establishing an 8-oxoG/OGG1 axis in the inflammatory response. Proposed mechanisms include the generation of 8-oxoG during chromatin remodeling processes involving histone demethylases, the recruitment of transcription factors (NF-κB, HIF1α, Myc, SMAD, etc.) by OGG1, and the lesion’s enrichment in guanine-rich sequences prone to forming G-quadruplex structures. The pro-mutagenic nature of 8-oxoG and the lack of dedicated, functionally separate writer and reader proteins challenge its classification as a true epigenetic DNA mark, distinguishing it from canonical epigenetic nucleobases like 5-methylcytosine and 5-hydroxymethylcytosine. On the other hand, 8-oxoG is well suited for the role of a regulatory signal localized to DNA and involved in the cellular response to oxidative stress and the associated physiological stimuli. Full article

Vitamin B12 (B12) is a strong antioxidant and a cofactor for methionine synthase supporting DNA/RNA/protein methylation. We previously demonstrated that oral high-dose B12 supplement mitigates diabetic cardiomyopathy in Akita diabetic mice expressing twice the normal levels of Elmo1 (Engulfment and cell motility 1). To assess how B12 prevents early kidney damage, we treated Elmo1^HH mice and diabetic Elmo1^HH Ins2^Akita/+ mice with or without B12 in drinking water starting at 8 weeks of age. At 16 weeks, markedly reduced mesangial expansion was detected in the B12-treated diabetic kidneys (22% of glomeruli affected vs. 70% in the untreated diabetic kidneys). RNAseq analysis of the kidneys revealed that B12 suppressed expression of genes for adaptive immune response, while it upregulated those for solute carrier transporters and antioxidant genes. Strikingly, B12 treatment suppressed activators of circadian rhythm, Clock and Bmal1, and upregulated repressors like Cry1/2, Per1-3 and Dbp, suggesting a shift in their rhythmicity. B12 also upregulated linker histone H1 variants, and enhanced chromatin stability and cell cycle regulation. In BU.MPT proximal tubular cells in culture, B12 shifted forward the circadian expression phase of Bmal1 and Per1. Taken together, B12 supplement effectively mitigates early development of diabetic nephropathy in diabetic mice, potentially involving regulation of circadian rhythm. Full article

This review presents soybean responses to drought, heat, and salinity within a signal–transcript–chromatin framework. In this framework, calcium/reactive oxygen species and abscisic acid cues converge on abscisic acid-responsive element binding factor (ABF/AREB), dehydration-responsive element binding protein (DREB), NAC, and heat shock factor (HSF) families. These processes are modulated by locus-specific chromatin and non-coding RNA layers. Base-resolved methylomes reveal a high level of CG methylation in the gene body, strong CHG methylation in heterochromatin, and dynamic CHH ‘islands’ at the borders of transposable elements. CHH methylation increases over that of transposable elements during seed development, and GmDMEa editing is associated with seed size. Chromatin studies in soybean and model species implicate the reconfiguration of salt-responsive histone H3 lysine 27 trimethylation (H3K27me3) in G. max and heat-linked H2A.Z dynamics at thermoresponsive promoters characterized in Arabidopsis and other plants, suggesting that a conserved chromatin layer likely operates in soybean. miR169–NF-YA, miR398–Cu/Zn Superoxide Dismutases(CSD)/copper chaperone of CSD(CCS), miR393–transporter inhibitor response1/auxin signaling F-box (TIR1/AFB), and miR396–growth regulating factors (GRF) operate across leaves, roots, and nodules. Overexpression of lncRNA77580 enhances drought tolerance, but with context-dependent trade-offs under salinity. Single-nucleus and spatial atlases anchor these circuits in cell types and microenvironments relevant to stress and symbiosis. We present translational routes, sentinel epimarkers (bisulfite amplicons, CUT&Tag), haplotype-by-epigenotype prediction, and precise cis-regulatory editing to accelerate marker development, genomic prediction and the breeding of resilient soybean varieties with stable yields. Full article

Chronic low-grade systemic inflammation is increasingly recognized as a key mediator linking stress, pain sensitivity, and cognitive decline. Central to this process are the acute-phase reactants interleukin-6 (IL-6) and C-reactive protein (CRP), which serve as biomarkers of systemic inflammation while promoting neuroimmune dysregulation. Emerging evidence implicates the IL-6–CRP axis in the amplification of pain perception, central sensitization, and stress hypersensitivity, ultimately promoting neurodegenerative processes such as those observed in Alzheimer’s disease (AD) and vascular dementia. Monomeric CRP (mCRP), a proinflammatory isoform generated under mechanical or oxidative stress, can trigger histone modifications (e.g., H3 citrullination), activate endothelial and immune cells, and exacerbate inflammatory pain pathways. These mechanisms are further modulated by genetic and epigenetic factors, including IL-6/CRP/NR3C1 gene variant expression; promoter methylation; and stress-responsive microRNAs, which intersect with dysregulation of the hypothalamic–pituitary–adrenal (HPA) axis, impairing immune resolution and neurocognitive resilience. Psychosocial stressors, such as the burden of caregiving or perfectionistic cognitive patterns, amplify IL-6 and CRP levels, particularly when pain is present, suggesting a synergistic interaction between emotional distress and somatic inflammation. Specifically, elevated CRP is associated with increased pain sensitivity, lower pain thresholds, and cognitive decline even in subclinical populations, providing a feedforward model in which chronic stress and pain potentiate systemic inflammation, disrupt neuroendocrine feedback, and accelerate neurodegenerative pathology. However, in this model, the potentially critical mechanistic and pathological role of mCRP remains to be discovered. This review addresses the missing elements of these overlapping pathways and discusses the therapeutic potential of targeting IL-6–CRP signaling, stress regulation, and epigenetic modifiers as strategies to ameliorate inflammation-driven cognitive decline and enhance stress resistance in chronic disease contexts. We propose that plasma mCRP or more likely the isoform-aware metric, the mCRP/CRP ratio, will provide a biologically anchored, potentially more discriminative approach to vascular-neuroimmune risk and capture the propensity for local effector signaling, likely outperforming hs-CRP or IL-6 alone for risk stratification across neurovascular and stress-sensitized pain phenotypes. Full article

KMT2C (histone lysine N-methyltransferase 2C, also known as MML3, myeloid/lymphoid or mixed-lineage leukemia 3) is a causal gene for Kleefstra syndrome 2, a rare neurodevelopmental disorder. Recent human genetic studies have identified it as a high-risk gene for autism spectrum disorder (ASD), with 79% of patients harboring KMT2C variants having ASD. However, the causal link between KMT2C haploinsufficiency and ASD remains unclear. KMT2C/MLL3 encodes a histone methyltransferase, a core protein of the KMT2C/D COMPASS (complex proteins associated with Set1) complex, which plays fundamental roles in chromatin modification, occupancy, and gene expression. The expression of KMT2C/Kmt2c peaks during the developmental period in the human/mouse brain, which indicates the critical roles of KMT2C/Kmt2c in neurodevelopment. Here, we investigated the impact of germline Kmt2c haploinsufficiency on autism-like behavioral deficits in mice, which modeled humans carrying diverse KMT2C variants. Compared with Kmt2c^+/+ controls, Kmt2c haploinsufficiency mice had normal motor function without anxiety-like behaviors. Notably, Kmt2c haploinsufficiency mice exhibited autism-like social deficits and increased self-grooming in both males and females, which recapitulated the core phenotypes of ASD patients. Novel object recognition and spatial memory deficits were observed in male and female Kmt2c haploinsufficiency mice. This study reveals a causal link between Kmt2c haploinsufficiency and ASD-like behavioral deficits. These germline Kmt2c haploinsufficiency mice can be used for further studying the molecular mechanisms and developing therapeutic interventions for KMT2C haploinsufficiency-associated behavioral deficits. Full article

Endothelial cell proliferation, migration, and intercellular interactions for blood vessel formation require coordinated signaling by a myriad of molecules. Following endothelial cell activation by growth factors and cytokines, a variety of signaling molecules are activated on the surface and transported intracellularly by TM4SF1-enriched microdomains (TMEDs), 100–300 nm diameter protein–lipid complexes recruited by the transmembrane protein TM4SF1. TMEDs internalize via microtubules from the cell surface toward the microtubule-organizing center (MTOC) and then enter the nucleus via nuclear pores (see Graphic Illustration). This internalization pathway permits delivery of activated proteins and other signaling molecules from the cell surface to the nucleus, which directly translates extracellular stimuli to modulation of gene expression. Molecules transported by this route include phospholipase C, gamma 1 (PLCγ1), histone deacetylase 6 (HDAC6), and importins. In the absence of TMEDs, endothelial cells lose the ability to divide into cultures in vitro and to support blood vessel formation in mouse embryos in vivo. We liken TMEDs to cable cars, which take in passengers at the cell surface, travel along microtubule cables, and deliver their passengers to various locations, including the “city center”, the nucleus. This commentary aims to elucidate the functions of TMEDs in endothelial cells, to show that cells, like busy cities, need efficient transport systems to deliver molecules to the destinations where they perform their cellular functions. TMEDs offer a novel and curated transport system providing selected molecules with access to the nucleus. Full article

JC virus (JCV) replicates within the nuclei of glial cells in the human brain and causes progressive multifocal leukoencephalopathy. JCV possesses a small, circular, double-stranded DNA genome, divided into early and late protein-coding regions. The non-coding control region (NCCR) functions bidirectionally for both early and late genes, and the agnogene is located downstream of TCR and upstream of three capsid proteins in the late region. Previously, in cell culture systems, we demonstrated that these capsid proteins accumulate in intranuclear domains known as promyelocytic leukemia nuclear bodies (PML-NBs), where they assemble into virus-like particles (VLPs). To investigate the agnogene’s function, VLPs were formed in its presence or absence, and differential gene expression was analyzed using microarray technology. The results revealed altered expression of histone-modifying enzymes, including methyltransferases (EHMT1, PRMT7) and demethylases (KDM2B, KDM5C, KDM6B), as well as various kinases and phosphatases. Notably, CTDP1, which dephosphorylates the C-terminal domain of an RNA polymerase II subunit, was also differentially expressed. The changes were predominant in the presence of the agnogene. These findings indicate that the agnogene and/or its protein product likely influence epigenetic regulation associated with PML-NBs, which may influence cell cycle control. Consistently, in human brain tissue, JCV-infected glial cells displayed maintenance of a diploid chromosomal complement, likely through G2 arrest. The precise mechanism of this, however, remains to be elucidated. Full article

Lysine methylation is a critical post-translational modification catalyzed by lysine methyltransferases (KMTs), originally characterized in the regulation of histones. However, the breadth of non-histone targets remains largely unexplored. Here, we used a systematic peptide array-based approach to define a substrate preference motif for the SET-domain-containing KMT MLL4 (KMT2D), a member of the COMPASS complex and a known H3K4 methyltransferase. Using this motif, we identified CXXC finger protein 1 (CFP1), a core component of Setd1A/B complexes, as a putative MLL4 substrate. In vitro methyltransferase assays confirmed robust methylation of CFP1 by an MLL4-WRAD complex. Surprisingly, while initial predictions implicated K328, array-based methylation profiling revealed multiple lysine residues within CFP1’s lysine-rich basic domain as methylation targets, including K331, K335, K339, and K340. We further demonstrated that CFP1 methylation likely modulates its interaction with MLL4’s PHD cassettes and facilitates binding to Setd1A. Binding preferences of MLL4’s PHD1–3 and PHD4–6 domains varied with methylation state and site, suggesting non-histone methyl mark recognition by these cassettes. Pulldown assays confirmed that methylated, but not unmethylated, CFP1 binds Setd1A, supporting a potential methyl-switch mechanism. Together, our findings propose CFP1 as a potential non-histone substrate of MLL4 and suggest that MLL4 may regulate Setd1A/B function indirectly via CFP1 methylation. This study expands the substrate landscape of MLL4 and lays the groundwork for future investigations into non-histone methylation signaling in chromatin regulation. Full article

Multiple sclerosis (MS) is a chronic autoimmune neurodegenerative disorder characterized by progressive demyelination and axonal degeneration within the central nervous system, driven by complex genomic and epigenomic dysregulation. Its pathogenesis involves aberrant DNA methylation patterns at CpG islands of numbers of genes like OLIG1 and OLIG2 disrupting protein expression at myelin with compromised oligodendrocyte differentiation. Furthermore, histone modifications, particularly H3K4me3 and H3K27ac, alter the promoter regions of genes responsible for myelination, affecting myelin synthesis. MS exhibits chromosomal instability and copy number variations in immune-regulatory gene loci, contributing to the elevated expression of genes for pro-inflammatory cytokines (TNF-α, IL-6) and reductions in anti-inflammatory molecules (IL-10, TGF-β1). Vitamin D deficiency correlates with compromised immune regulation through hypermethylation and reduced chromatin accessibility of vitamin D receptor (VDR) dysfunction and is reported to be associated with dopaminergic neuronal loss. Vitamin D supplementation demonstrates therapeutic potential through binding with VDR, which facilitates nuclear translocation and subsequent transcriptional activation of target genes via vitamin D response elements (VDREs), resulting in suppression of NF-κB signalling, enhancement of regulatory T-cell (T_reg) responses due to upregulation of specific genes like FOXP3, downregulation of pro-inflammatory pathways, and potential restoration of the chromatin accessibility of oligodendrocyte-specific gene promoters, which normalizes oligodendrocyte activity. Identification of differentially methylated regions (DMRs) and differentially expressed genes (DEGs) that are in proximity to VDR-mediated gene regulation supports vitamin D supplementation as a promising, economically viable, and sustainable therapeutic strategy for MS. This systematic review integrates clinical evidence and eventual bioinformatical meta-analyses that reference transcriptome and methylome profiling and identify prospective molecular targets that represent potential genetic and epigenetic biomarkers for personalized therapeutic intervention. Full article

The submandibular glands (SMGs), along with the parotid and sublingual glands, generate the majority of saliva and play critical roles in maintaining oral and systemic health. Despite their physiological importance, long-term therapeutic options for salivary gland dysfunction remain limited, highlighting the need for a deeper molecular understanding of SMG biology, particularly in humans. To address this knowledge gap, we have performed transcriptomic- and epigenomic-based analyses and molecular characterization of the human SMG. Our integrated analysis of multiorgan RNA-sequencing datasets has identified an SMG-enriched gene expression signature comprising 289 protein-coding and 75 long non-coding RNA (lncRNA) genes that include both known regulators of salivary gland function and several novel candidates ripe for future exploration. To complement these transcriptomic studies, we have generated chromatin immunoprecipitation sequencing (ChIP-seq) datasets of key histone modifications on human SMGs. Our epigenomic analyses have allowed us to identify genome-wide enhancers and super-enhancers that are likely to drive genes and regulatory pathways that are important in human SMG biology. Finally, comparative analysis with mouse and human SMG and other tissue datasets reveals evolutionary conserved gene and regulatory networks, underscoring fundamental mechanisms of salivary gland biology. Collectively, this study offers a valuable knowledge-based resource that can facilitate targeted research on salivary gland dysfunction in human patients. Full article

Antinuclear antibodies, especially anti-DNA antibodies, are known to be a hallmark of systemic lupus erythematosus (SLE) and represent a diverse pool of autoantibodies with different origins, antigenic properties, and physicochemical features. Antibodies with catalytic properties have been found among the antibody repertoire in SLE, but the specific features and clinical associations of such antibodies have not been sufficiently studied. This study showed that chromatographically purified IgG from the serum of SLE patients effectively hydrolyzed DNA and DNA-associated proteins such as histones and high-mobility group box 1 (HMGB1) compared to healthy individuals. Remarkably, the level of hydrolysis of DNA and DNA-associated proteins was closely correlated. At the same time, these antibodies did not hydrolyze the control protein, tumor necrosis factor-α (TNFα), which does not possess DNA-binding properties. IgG DNase activity levels varied significantly, so patients were divided into high- and low-activity subgroups using the DBSCAN algorithm, with the difference between median values being greater than 49 times. The subgroup with high IgG DNase activity was characterized by an increase in anti-DNA antibodies (p < 0.04) than the subgroup with low activity, which had a shorter duration of the disease (p = 0.03) and was more often characterized by a subacute rather than a non-chronic course of the disease (p = 0.048). High catalase-like activity of IgG was also detected in SLE. Thus, the antibody pool in SLE contains not only high-affinity antinuclear autoantibodies but also catalytic antibodies capable of hydrolyzing DNA and DNA-associated proteins. These findings expand our understanding of the heterogeneity of the repertoire of catalytic autoantibodies among SLE patients. Full article