Search Results (396)

Chromatin architecture is a central determinant of genomic stability. Effective DNA repair requires dynamic chromatin remodeling to grant repair factors timely access to lesions and to orchestrate repair pathway choice. Disruption of chromatin-regulatory mechanisms or DNA damage response pathways undermines repair fidelity and contributes to a wide spectrum of human disorders, including developmental syndromes, premature aging, and multiple cancers. Here, we review how chromatin state and remodeling complexes shape detection, signaling, and resolution of DNA double-strand breaks, and we examine how their misregulation drives disease and presents opportunities for therapeutic intervention. Specifically, we discuss how post-translational modifications and ATP-dependent chromatin remodeling complexes contribute to DNA damage repair with a particular focus on DNA double-strand breaks, one of the most deleterious DNA lesions. We summarize how chromatin remodeling and histone post-translational modifications regulate DNA repair pathway choice, and how these processes are essential for safeguarding genomic integrity and preventing human disease. Finally, we discuss emerging concepts and major unanswered questions in the context of chromatin function and DNA double-strand break repair, with a focus on exploring the emerging literature on the role of chromatin compartments and topological associated domains for orchestrating DNA repair within chromatin and safeguarding genomic stability. Full article

Erythropoiesis is tightly regulated by lineage-specific transcription factors that govern erythroid commitment, proliferation, and differentiation. A core erythroid transcriptional network, together with non-DNA-binding cofactors, occupies regulatory regions of genes essential for erythroid development. This process is further shaped by epigenetic mechanisms, including histone post-translational modifications and long-range chromatin interactions. CCCTC-binding factor (CTCF) is a multifunctional regulator with a central role in three-dimensional chromatin organization. Although CTCF has been implicated in hematopoietic differentiation and leukemogenesis, its specific function in erythropoiesis remains poorly defined. Here, we investigated the role of CTCF during erythroid differentiation using two complementary models: pluripotent K562 leukemia cells and primary human CD34⁺ hematopoietic stem/progenitor cells, each induced toward the erythroid lineage by distinct stimuli. In both systems, CTCF silencing impaired erythroid differentiation by repression of key erythroid transcription factor genes, including LMO2, KLF1, MYB, and ETS1. This repression was associated with enrichment of repressive histone marks at CTCF-binding sites within their regulatory regions. Moreover, CTCF cooperated with cohesin to establish and stabilize long-range chromatin interactions at these loci. These results provide new insight into how CTCF-dependent chromatin regulation contributes to normal erythroid development and suggest that perturbation of this regulatory axis may have implications for hematopoietic disorders and malignancies. Full article

Background: Gene expression and cellular identity are regulated by epigenetics that occurs through chromatin modifications, RNA changes, chromatin accessibility, and three-dimensional genome organization. Although DNA methylation has been the focus of most epigenetics studies in the past, other non-methyl epigenetic processes, including histone post-translational modifications (PTMs), epitranscriptomic marks, and chromatin remodeling, are dynamic, reversible, and context-dependent, and thus are difficult to accurately interrogate using endpoint sequencing-based assays, especially in heterogeneous tissues, developing systems, and therapeutic response environments. Scope and Approach: The present review discusses epigenetic modifications other than DNA methylation regarding sensor-based technologies that can measure live, dynamic, and spatially resolved measurements. Epigenetic sensors include any genetically encoded sensors (GECs) based on resonance energy transfer, CRISPR/dCas-derived sensors, or aptamer-based sensors, and hybrid biochemical/imaging sensors that can be used in live or semi-live settings. It lays emphasis on the technologies, which have been developed recently, that allow real-time kinetic measurements, working in three-dimensional and organoid models, and being applied to disease-relevant perturbations. On these platforms, performance properties such as specificity, sensitivity, spatial and temporal resolution, ability to perform dynamic versus locus-specific interrogation, and perturbed endogenous chromatin states are compared. Key Conclusions and Outlook: Together, these sensing strategies are complementary to the traditional methods of measuring epigenomics in that they show epigenetic dynamics unobservable with static measurements. We list the important technical issues, including specificity, quantitation, multiplexing, and chromatin perturbation, and report the barriers and solutions in development and design. Lastly, we provide a conceptual map of how live epigenetic sensing and multi-omics and translational models can be integrated, and how the two methodologies can be used to develop functional epigenetics and guide disease modeling and drug development. Full article

Diverse epigenetic regulatory mechanisms ensure and modulate cellular diversity. The histone 3 lysine 9 me3 (H3K9me3) post-translational modification participates in silencing lineage-inappropriate genes by restricting access of transcription factors and other regulatory proteins to genes that control cell fate. Mouse olfactory sensory neurons (OSNs) select one olfactory receptor (OR) gene out of 2600 possibilities. This monoallelic and stochastic OR choice occurs as OSNs differentiate and undergo dramatic changes in nuclear architecture. OR genes from different chromosomes converge into specialized nuclear bodies and chromatin compartments, as H3K9me3 and chromatin binding proteins including heterochromatin protein 1 (HP1) are incorporated. In this work, we have uncovered an unexpected role for HP1β in OR choice and neuronal identity that cannot be rescued by HP1α in vivo. With the use of a conditional knock-in mouse model, that after CRE expression replaces HP1β with HP1α, we observe changes in H3K9me3 levels and DNA accessibility over OR gene clusters. These changes alter the expression patterns that partition the mouse olfactory epithelium into five OR expression zones, which results in a reduced OR repertoire that leads to a loss of olfactory sensory neuron diversity. We propose that HP1β modulates the competition of OR promoters for enhancers to promote receptor diversity by establishing repression gradients in a zonal fashion. Full article

The hypothalamic–pituitary–adrenal (HPA) axis coordinates metabolic, immune, and behavioral responses to a changing environment. Its molecular effectors are the nuclear receptors for glucocorticoids and mineralocorticoids (the GRs/MRs), encoded by nr3c1/nr3c2. The MR serves as the high-affinity sensor of basal hormone concentrations, whereas the GR amplifies the stress response and mediates negative feedback. Despite their shared domain architecture, the receptors have diverged functionally: isoform composition, post-translational modifications, and the complement of co-regulators together determine which genes are activated or repressed in a given tissue at a given time. The regulation of the HPA axis activity is a major determinant of embryonic development. Pregnancy adds a placental control layer that meters maternal signals: 11β-hydroxysteroid dehydrogenase type 2 (11β-HSD2) in the syncytiotrophoblast inactivates cortisol, whereas 11β-hydroxysteroid dehydrogenase type 1 (11β-HSD1) can regenerate it, and systemic buffering by transcortin (cortisol-binding globulin, CBG) limits the free hormone fraction. Under stress, inflammation, or hypoxia, this barrier weakens, exposing the fetus to stronger glucocorticoid pulses during windows of heightened vulnerability for brain and immune development. Such overexposure not only reshapes ongoing transcription but is also epigenetically inscribed: the methylation of alternative nr3c1 promoters, the remodeling of histones, and the shifts in ncRNA profiles recalibrate the axis sensitivity for the long term. At the phenotypic level, this manifests as variability in stress reactivity, cognitive and affective trajectories, and an immune and metabolic risk across later ontogeny. In this review, we integrate evidence on the structure and functions of the GR, the mechanisms of its post-translational and epigenetic regulation, and the role of the placenta, to provide a coherent framework for understanding the multifaceted consequences of prenatal stress and to identify potential targets for early prevention. Full article

Phosphorylation has long been regarded as the principal mechanism governing oncogenic signal transduction. However, it does not fully account for the diversity, persistence, and context dependence of cancer signaling outputs. Protein methylation, historically studied in the context of histone regulation, is now recognized as a widespread modification of non-histone signaling proteins, including transcription factors, DNA damage response mediators, and scaffold components. In this Review, we propose that protein methylation functions as a regulatory logic layer that shapes how oncogenic signals are amplified, stabilized, and interpreted. Rather than serving as a primary trigger of pathway activation, methylation modulates signaling behavior across four interconnected dimensions: activation threshold and signal gain, temporal persistence, network topology and complex assembly, and spatial routing. We examine major signaling axes in which methylation refines genome integrity networks, proliferative pathways, inflammatory circuits, and lineage-specific transcriptional programs. We further discuss the interdependency between methylation and phosphorylation, highlighting sequential, competitive, and feedback-mediated interactions that expand combinatorial signaling states. Finally, we explore how methylation-mediated regulatory logic contributes to signaling plasticity and adaptive resistance under therapeutic pressure, and we outline key measurement and translational challenges. Framing protein methylation within a regulatory logic paradigm provides a structured approach for integrating this modification into contemporary models of oncogenic signaling and therapeutic intervention. Full article

Eukaryotic DNA is wrapped around octamers of four core histones, forming nucleosomes. Histone post-translational modifications (PTMs) influence chromatin structure and the recruitment of regulatory factors, thereby affecting gene expression and DNA repair, including the response to DNA double-strand breaks (DSBs). Here, we describe a robust chromatin immunoprecipitation protocol combined with micrococcal nuclease digestion and DNA sequencing (MNase-ChIP-seq) to map histone modifications and their genome-wide distribution after the induction of a single DSB by the HO endonuclease in Saccharomyces cerevisiae. We validate the method by detecting changes in histone H3 methylation following HO transcriptional activation and DSB induction. This protocol enables reliable analysis of histone PTMs across mutant strains or stress conditions, supporting studies of chromatin dynamics in yeast. Full article

Cell division is a highly regulated process that actively involves dynamic changes to the genetic material within the nucleus. DNA is faithfully replicated in the S-Phase of the cell cycle, being converted from loose, relaxed chromatin into tight, condensed chromosomes to be segregated in mitosis. In addition to scaffolding proteins that shape these mitotic chromosomes, post-translational modifications of histones within nucleosomes modulate chromosome dynamics throughout the cell cycle. In this review, we use a comparative approach to highlight some of the major epigenetic marks affected by the cell cycle during embryogenesis of Caenorhabditis elegans: H4K20me1, H3S10ph, H4S1ph, H2AS1ph, and H3T118ph. These five histone post-translational modifications will be specifically highlighted in the context of the mitotic cell cycle, as they are well documented in the C. elegans literature. Full article

Metabolic reprogramming and epigenetic remodeling are critical features of tumorigenesis. The process of metabolic reprogramming causes metabolites like Succinyl-CoA to accumulate. Succinylation, which depends on succinyl-CoA as the direct donor group, plays a crucial role in regulating cancer metabolism. This involves the transfer of the succinyl group to the lysine residues of substrate proteins resulting in the alteration of the conformation and function of the proteins, modulating several signaling pathways, many of them involved in metabolism. There is growing evidence that succinylation can alter the activity and stability of metabolic enzymes and reshape metabolic networks. Furthermore, it precisely regulates gene expression through the epigenetic modification mechanisms of the histones and non-histone proteins. Lysine succinylation is thus a crucial hub linking tumor metabolic reprogramming and epigenetic remodeling. This review systematically summarizes the dynamic regulatory mechanisms of lysine succinylation and its critical roles in tumor metabolic reprogramming and epigenetic regulation. In the end, we discuss the crosstalk between succinylation and other post-translational modifications (PTMs) as well as recent advances in cancer therapies targeting succinylation. Full article

Chromatin dynamics are usually modulated by histone epigenetic post-translational modifications, which rapidly and reversibly govern accessibility and transcriptional responsiveness. During microbial infection, this regulatory layer becomes a highly contested interface where host defense mechanisms and pathogen-driven subversion strategies converge and compete. Many infectious agents exploit chromatin to reprogram gene expression, creating cellular environments that are conducive to infection, proliferation, and persistence. Diverse strategies have been described for viruses, bacteria, fungi, protozoa and nematodes, including the direct secretion of acetyltransferases and methyltransferases, interference with host chromatin-binding proteins, subcellular localization of transcriptional factors or epigenetic regulators, and metabolic availability manipulation. Concurrently, host cells activate immune and stress-response genes to mount rapid, adaptable antimicrobial responses. Recent advances in genome-wide, single-cell, and spatial omics profiling have begun to reveal the temporal and cell-type-specific dynamics of the host genome at the core of infection. This review synthesizes current insights into how chromatin is rewired by the major categories of pathogens during infection, highlighting representative case studies across infective agents and the functional consequences for immunity and cell fate. In addition, we discuss emerging techniques for epigenomic and transcriptomic data collection, and the potential of targeted host-directed therapeutic strategies. Chromatin regulation is thus a promising field of study and a possible target for next-generation interventions. Full article

Histone lysine acetylation is a widespread posttranslational modification, essential for vital functions in eukaryotic organisms. Histone lysine acetyltransferases (KATs) employ acetyl-coenzyme A as a universal acetyl donor for acetylation of lysine residues in histone and non-histone proteins. Despite the biomedicinal importance of modulation of the KAT activity, application of the acetyl-coenzyme A cosubstrate structure for the design of potent and selective inhibitors has been underexplored. Here, we developed functionalized coenzyme A analogs as inhibitors against human histone lysine acetyltransferases GCN5, KAT8, and HAT1. In contrast to the unmodified coenzyme A, which was found to be a poor inhibitor of GCN5 and KAT8 (IC₅₀ > 150 μM), we showed that a ketone-substituted coenzyme A was the most potent inhibitor of GCN5 and KAT8 (IC₅₀ = 10.9 μΜ and 13.6 μΜ, respectively). Coenzyme A and an acetamide-substituted coenzyme A efficiently inhibited HAT1 (IC₅₀ = 7.3 μΜ and IC₅₀ = 3.9 μΜ, respectively). Our work demonstrates that human KATs can be efficiently and selectively inhibited by S-functionalized coenzyme A, the results exhibiting significant potential towards development of highly active chemical probes for biomedically important KATs. Full article

The Spt-Ada-Gcn5 acetyltransferase (SAGA) complex is a conserved transcriptional coactivator that coordinates histone modifications and transcriptional regulation in eukaryotes. In Cryptococcus neoformans, SAGA governs key virulence traits, yet the roles of several core scaffold subunits remain undefined. Here, we characterize the functional roles of Spt7, a core SAGA component, in C. neoformans. Comparative genomics revealed that C. neoformans Spt7 retains conserved histone fold and bromodomain motifs. Deletion of SPT7 produced pleiotropic phenotypes, including defective melanization and capsule formation, impaired titan cell development, and heightened sensitivity to thermal, metal, antifungal, and cell wall stresses. The spt7Δ mutant exhibited strong sensitivity to the echinocandin micafungin, implicating Spt7 in maintaining cell wall integrity. The spt7Δ mutant was avirulent in a murine inhalation model. At the chromatin level, SPT7 deletion disrupted SAGA-dependent histone post-translational modifications, increasing H2B ubiquitination while reducing H3K14ac and H3K18ac levels. Proteomic profiling revealed reduced abundance of ribosomal, mitochondrial, and translational proteins and upregulation of lipid metabolic and secretory pathway components. Collectively, our findings establish Spt7 as a central integrator of SAGA-mediated chromatin regulation, proteomic balance, and virulence in C. neoformans and highlight the SAGA core as a potential antifungal target. Full article

Mass spectrometry has become an indispensable tool for the identification and quantification of epigenetic modifications, offering both high sensitivity and structural specificity. The two major classes of epigenetic modifications identified—DNA methylation and histone post-translational modifications—play fundamental roles in cancer development, underscoring the relevance of their precise quantification for understanding tumorigenesis and potential therapeutic targeting. In this scoping review, we included 89 studies that met the inclusion criteria for detailed methodological assessment. Among these, we compared pre-treatment workflows, analytical platforms, and acquisition modes employed to characterize epigenetic modifications in human samples and model systems. Our synthesis highlights the predominance of bottom-up strategies combined with Orbitrap-based platforms and data-dependent acquisition for histone post-translational modifications, whereas triple quadrupole mass spectrometers were predominant for DNA methylation quantification. We critically evaluate current limitations, including heterogeneity in validation reporting, insufficient coverage of combinatorial post-translational modifications, and variability in derivatization efficiency. Full article

Egg quality is a critical economic trait in poultry production, influencing consumer preference and production efficiency. The genetic and epigenetic regulation of egg quality involves complex biological pathways across various traits such as shell quality, albumen composition, and yolk biochemistry. This review synthesizes recent advances in the genetic, molecular, and epigenetic mechanisms that determine poultry egg quality. Specifically, it focuses on external traits such as eggshell strength, color, and thickness, and internal traits including albumen height, yolk composition, and the Haugh unit. Through genome-wide association studies (GWAS), quantitative trait loci (QTL) mapping, whole-genome sequencing (WGS), and multi-omics approaches, key candidate genes such as OC-116, CALB1, CA2 (shell formation), OVAL, SPINK5, SERPINB14 (albumen quality), and FGF9, PIAS1, NOX5 (lipid metabolism) have been identified. These genes play a pivotal role in shell biomineralization, albumen protein regulation, and yolk lipid transport. This review also explores the heritability of these traits, emphasizing the challenges posed by polygenic architecture and the influence of environmental factors. Furthermore, it addresses the dynamic spatiotemporal regulation of egg quality traits, including epigenetic layers such as DNA methylation, histone modifications, RNA methylation, and post-translational protein modifications. This paper highlights the application of these findings to breeding programs via genomic selection, marker-assisted breeding, and epigenetic engineering approaches. Future directions for precision breeding and the development of functional eggs with enhanced quality are also discussed. Full article

The peptidylarginine deiminase (PAD) family includes five isozymes (PAD1–4 and PAD6) with unique tissue distributions and substrate specificities. These enzymes facilitate citrullination, a post-translational modification where positively charged arginine residues are converted into neutral citrulline residues in the presence of calcium ions. This process significantly changes protein properties, affecting molecular interactions, structural stability, and biological functions. Over the past six years (2019–2025), there has been significant progress in understanding PAD activity mechanisms and their therapeutic potential. Recent discoveries include the regulated nuclear translocation of PAD2, PAD4’s specific role in forming cancer extracellular chromatin networks (CECNs), and the development of next-generation inhibitors with greatly improved pharmacological profiles. PAD4 is crucial in forming neutrophil extracellular traps (NETs). Citrullination of histones H3 and H4 by PAD4 destabilizes chromatin, helping release DNA-protein networks as an antibacterial defense. However, excessive NET formation can contribute to autoimmune diseases and thrombosis. Similarly, the bacterial peptidylarginine deiminase from Porphyromonas gingivalis (PPAD)—the only known prokaryotic citrullinating enzyme—plays a key role. Working with R-gingipains, PPAD triggers pathological citrullination of host proteins, leading to immune tolerance breakdown and linking periodontal disease with systemic autoimmune disorders such as rheumatoid arthritis, atherosclerosis, and Alzheimer’s disease. Once thought to be a rare post-translational modification, citrullination is now understood as a vital regulatory mechanism in both normal physiology and disease, involving both internal processes of homeostasis and external mechanisms of bacterial pathogenesis. Full article