Role of TET enzymes in DNA methylation, development, and cancer

Epithelial-mesenchymal transition promotes metabolic reprogramming to suppress ferroptosis

Epithelial-mesenchymal transition (EMT) is a cellular de-differentiation process that provides cells with the increased plasticity and stem cell-like traits required during embryonic development, tissue remodeling, wound healing and metastasis. Morphologically, EMT confers tumor cells with fibroblast-like properties that lead to the rearrangement of cytoskeleton (loss of stiffness) and decrease of membrane rigidity by incorporating high level of poly-unsaturated fatty acids (PUFA) in their phospholipid membrane. Although large amounts of PUFA in membrane reduces rigidity and offers capabilities for tumor cells with the unbridled ability to stretch, bend and twist in metastasis, these PUFA are highly susceptible to lipid peroxidation, which leads to the breakdown of membrane integrity and, ultimately results in ferroptosis. To escape the ferroptotic risk, EMT also triggers the rewiring of metabolic program, particularly in lipid metabolism, to enforce the epigenetic regulation of EMT and mitigate the potential damages from ferroptosis. Thus, the interplay among EMT, lipid metabolism, and ferroptosis highlights a new layer of intricated regulation in cancer biology and metastasis. Here we summarize the latest findings and discuss these mutual interactions. Finally, we provide perspectives of how these interplays contribute to cellular plasticity and ferroptosis resistance in metastatic tumor cells that can be explored for innovative therapeutic interventions.

Advancing TET Inhibitor Development: From Structural Insights to Biological Evaluation

Ten-eleven translocation (TET) methylcytosine dioxygenases are part of the epigenetic regulatory machinery that erases DNA methylation. Aberrant TET activities are frequently found in hematopoietic malignancies, where loss of TET2 function leads to DNA hypermethylation. A comprehensive understanding of the biological role of TETs is essential to elucidate disease pathogenesis and identify novel therapeutic strategies. We present a robust pipeline integrating protein X-ray crystallography, molecular modeling, and pharmacophore analysis to advance the current TET inhibitor development. In addition, we have synthesized and evaluated a series of 8-hydroxyquinoline (8-HQ) derivatives, demonstrating their potential as chemical tools to explore TET function further. These findings lay the groundwork for a TET-centered therapeutic approach.

Pathogen-derived glyoxylate inhibits Tet2 DNA dioxygenase to facilitate bacterial persister formation

Pathogenic bacterial persistence enables survival during antibiotic treatment, leading to treatment failure and recurrent infections, yet its underlying mechanisms remain unclear. Here, we reveal that glyoxylate, a metabolite originally evolved for alternative carbon utilization, functions as a signaling molecule to reprogram the host transcriptome and promote persister formation. Glyoxylate inhibits the DNA dioxygenase TET2, suppressing pro-inflammatory gene expression and attenuating host immune defense. Notably, stimulating TET2 activity with vitamin C or blocking glyoxylate production by Salmonella reduces bacterial antibiotic resistance and improves infection treatment outcomes. Beyond its metabolic role, glyoxylate emerges as a regulator of host-pathogen interactions, while TET2 plays a critical role in preventing bacterial persistence. Our findings suggest that targeting glyoxylate production or enhancing TET2 activity offers promising therapeutic strategies to combat bacterial persistence and enhance the efficacy of antibiotic treatments.

Low TET1 Expression Levels in COPD Are Associated with Airway and Blood Neutrophilia

Epigenetic dysregulation, particularly DNA methylation variations, is implicated in the pathogenesis of chronic obstructive pulmonary disease (COPD). Ten-eleven translocation (TET) proteins (TET1, TET2, and TET3) regulate DNA methylation and gene transcription. Impaired TET1 expression was previously associated with airway inflammation and asthma. Here we investigated TET gene associations with COPD severity. We found that reduced TET1 expression in peripheral blood mononuclear cells was associated with higher sputum and blood neutrophil counts, decreased lung function and increased disease severity in patients. These findings support a potential protective role and warrant further mechanistic investigations into the actions of TET1 in COPD.

PRAME Expression in Melanoma is Negatively Regulated by TET2-Mediated DNA Hydroxymethylation

Preferentially expressed Antigen in Melanoma (PRAME) and Ten-Eleven Translocation (TET) dioxygenase-mediated 5-hydroxymethylcytosine (5hmC) are emerging melanoma biomarkers. We observed an inverse correlation between PRAME expression and 5hmC levels in benign nevi, melanoma in situ, primary invasive melanoma, and metastatic melanomas via immunohistochemistry and multiplex immunofluorescence: nevi exhibited high 5hmC and low PRAME, whereas melanomas showed the opposite pattern. Single-cell multiplex imaging of melanoma precursors revealed that diminished 5hmC coincides with PRAME upregulation in premalignant cells. Analysis of The Cancer Genome Atlas and Genotype-Tissue Expression databases confirmed a negative relationship between TET2 and PRAME messenger RNA expression in melanoma. Additionally, 5hmC levels were reduced at the PRAME 5' promoter in melanoma compared with nevi, suggesting a role for 5hmC in PRAME transcription. Restoring 5hmC levels via TET2 overexpression notably reduced PRAME expression in melanoma cell lines. These findings establish a function of TET2-mediated DNA hydroxymethylation in regulating PRAME expression and demonstrate epigenetic reprogramming as pivotal in melanoma tumorigenesis.

Portable, Wireless Potentiostat Sensor for Ultra-Sensitive, Real-Time Detection of 5hmC in Genomic DNA Using Tree-Like Graphene

Aberrant alterations in genomic 5-hydroxymethylcytosine (5hmC), an oxidation product of 5-methylcytosine (5mC) by Ten-eleven translocation (TET) enzymes, are frequently associated with cancers. Quick and precise 5hmC quantification is vital since it is a key biomarker for diagnosis, pathophysiology, and therapy. Here, we present a portable, wireless potentiostat sensor for real-time, ultrasensitive 5hmC-DNA sensing based on a tree-like graphene (teG)-modified screen-printed microelectrode. One-pot electrochemical exfoliation of pencil graphite enabled the cost-effective, eco-friendly, and scalable synthesis of teG, which exhibited high electrical conductivity, excellent electrochemical conductivity, low surface roughness, and high 5hmC-DNA adsorption, surpassing those of pencil graphite (pG) and graphene oxide (GO). The teG-modified gold electrodes exhibited exceptional sensitivity (6.15 × 10-6 mM-1 cm-2), selectivity, and reproducibility, with an ultralow detection limit of 12.6 fM for 5hmC-DNA. The sensor's performance was validated by quantifying 5hmC levels in genomic DNA from various biological specimens, including primary mouse tissues with altered TET function, mouse hepatocellular carcinoma, and human prostate cancer cell lines. To enhance practicality, a flexible, screen-printed microelectrode on mulberry paper was developed and integrated with a portable, wireless potentiostat powered by the Arduino Nano 33 IoT. Open-circuit potential (OCP)-based detection enabled label-free, real-time monitoring with wireless data transmission to an Android mobile application, successfully differentiating 5hmC levels between cancerous and noncancerous cells. These findings highlight teG's high surface area, superior charge transport, and scalability, positioning it as a promising platform for next-generation biosensing. The developed sensor provides a rapid, cost-effective, and highly sensitive tool for 5hmC quantification, with significant implications for early cancer diagnostics and treatment.

Epigenetic Mechanisms of Obesity: Insights from Transgenic Animal Models

Obesity is a chronic disease with prevalence rates that have risen dramatically over the past four decades. This increase is not due to changes in the human genome but rather to environmental factors that promote maladaptive physiological responses. Emerging evidence suggests that external influences, such as high-fat diets, modify the epigenome-the interface between genes and the environment-leading to persistent alterations in energy homeostasis. This review explores the role of epigenetic mechanisms in obesity, emphasizing insights from transgenic animal models and clinical studies. Additionally, we discuss the evolution of obesity research from homeostatic to allostatic frameworks, highlighting key neuroendocrine regulators of energy balance.

TET2 gene mutation status associated with poor prognosis of transition zone prostate cancer: a retrospective cohort study based on whole exome sequencing and machine learning models

Background

Prostate cancer (PCa) in the transition zone (TZ) is uncommon and often poses challenges for early diagnosis, but its genomic determinants and therapeutic vulnerabilities remain poorly characterized.

Methods

Tumor mutational landscape was characterized in nine patients with TZ PCa, identifying somatic variants through whole-exome sequencing (WES). Novel candidate variants relevant to driver gene were selected using rare-variant burden analysis. Kaplan-Meier curves with log-rank testing and Cox regression models were applied to evaluate the prognostic significance of selected mutant driver gene and clinicopathological characteristics in a cohort of 132 patients with TZ PCa. Significant prognostic determinants were integrated into a validated nomogram for individualized prediction of 3-, 4-, and 5-year biochemical recurrence-free survival (BRFS) and overall survival (OS) probabilities. Eight machine learning algorithms were employed to develop BRFS and OS prediction models in a cohort.

Results

A total of 5,036 somatic single nucleotide variants (SNVs) and 587 somatic insertion and deletion (INDELs) were discovered. Among eight driver gene mutations which were verified through Sanger sequencing, TET2 gene, with high mutation frequency and potential targeted drug relevance (bromodomain inhibitors and DOT1L inhibitors) was selected for further validation. Retrospective cohort study demonstrated that TET2 mutant status was significantly associated with Gleason score (p = 0.004) and distant metastasis (p = 0.002). Furthermore, TET2 mutant status was significantly correlated with inferior BRFS and OS and served as an independent predictor. Comparative evaluation of eight algorithms revealed the GBM model achieved superior discriminative ability for BRFS (AUC for 3-year: 0.752, 4-year: 0.786, 5-year: 0.796). The predictive model based on the GBM machine learning algorithm achieved the best predictive performance for OS (AUC for 3-year: 0.838, 4-year: 0.915, 5-year: 0.868). The constructed predictive nomogram provided evidence that TET2 mutant status integration conferred statistically significant improvements in model accuracy and clinical predictive value.

Conclusion

Our study elucidated the distinct genetic basis of prostate cancer in the transition zone and identified TET2 mutation as an independent prognostic determinant in TZ PCa. However, the limited sample size of this study necessitates cautious interpretation of these findings, and further validation in larger cohorts is warranted to confirm their generalizability.

Prognostic implications of DNA methylation machinery (DNMTs and TETs) expression in gliomas: correlations with tumor grading and patient survival

PURPOSE

DNA methylation is a crucial epigenetic modification that regulates gene expression and chromatin structure. Its dysregulation is linked to glioma progression and prognosis, particularly through alterations in methylation machinery. DNMTs and TETs play key roles in these processes, but their involvement in gliomagenesis remains complex, especially in the context of IDH mutations. This study examines the expression patterns of DNMT and TET family genes in gliomas to assess their prognostic significance and therapeutic potential.

MATERIALS AND METHODS

mRNA expression levels of DNMT1, DNMT3A, DNMT3B, DNMT3L, TET1, TET2, TET3, and TDG were analyzed in 75 glioma samples and 10 normal controls using real-time quantitative PCR (qPCR). Statistical analyses and graphical representation were performed using R (v3.3.2) and RStudio (v1.4.1717), with p-values < 0.05 considered significant. Findings were validated using publicly available databases, TCGA and CGGA.

RESULTS

Compared to normal controls, DNMTs and TETs were significantly downregulated in gliomas, with expression levels inversely correlated with histological grade. Survival analysis using the log-rank test demonstrated a significant association between lower TETs and DNMTs expression and an increased risk of mortality. However, multivariate Cox regression analysis indicated that DNMTs and TETs expression were not independent prognostic markers for patient survival, suggesting their impact may be influenced by other clinical and molecular factors. Validation through online databases (TCGA and CGGA) showed that TET family expression across histological grades was consistent with our samples, whereas TDG and DNMT family expression differed.

CONCLUSION

Our findings suggest that DNMTs and TETs may serve as therapeutic targets in glioma due to their downregulation and association with survival, with TET family members (TET1, TET2, and TET3) validated through online databases. However, their prognostic value is limited, as other clinical and molecular factors influence patient outcomes. The downregulation of DNMTs in our samples compared to online databases can be attributed to distinct epigenetic mechanisms: in IDH-mutant gliomas, DNMT suppression results from global hypermethylation (G-CIMP) due to 2-HG accumulation, which inhibits TET enzymes and disrupts DNA methylation homeostasis. In contrast, IDH-wildtype high-grade gliomas exhibit global hypomethylation, genomic instability, oncogenic signaling, and dedifferentiation, reducing the demand for active DNA methylation maintenance. These findings underscore the complex regulation of DNMTs and TETs in gliomas and their potential therapeutic implications.

Epigenetic-modification associated hnRNPA3 acts as a prognostic biomarker and promotes malignant progression of HCC

OBJECTIVE

hnRNPA3 is highly expressed in numerous malignancies, including hepatocellular carcinoma (HCC), but its function and mechanism has not been elucidated. In this study, we performed a comprehensive bioinformatics analysis of hnRNPA3 in the TCGA-LIHC dataset and several experiments in vitro to investigate the function and potential mechanisms of hnRNPA3 in HCC.

METHODS

Pan-cancer expression including hnRNPA3 levels as well as DNA methylation, associated ceRNA, immune infiltration, and immune checkpoint genes of hnRNPA3 in TCGA-LIHC dataset were assessed. Logistic regression, receiver operating characteristic curve (ROC), Kaplan-Meier analysis, and nomogram modeling were used to evaluate prognostic values of hnRNPA3 in HCC. hnRNPA3 level in cell subtypes in HCC tumor microenvironment was analysed through spatial transcriptomic. "pRRophetic" package was used to predict potential chemotherapeutic drugs sensitivity. hnRNPA3 level in HCC patients and cell lines were detected by qRT-PCR or WB. hnRNPA3's impact on proliferation, migration were studied in SNU449 and HuH7 cell lines. RNA-seq showed hnRNPA3 controled different important singaling passways in HCC.

RESULTS

hnRNPA3 was significantly elevated in HCC tumors compared to controls. hnRNPA3 levels correlated with Age, HCC stage, histologic grade, and tumor status, and may independently predict the overall and disease-specific survival. Significant associations were found between hnRNPA3 levels and DNA methylation. hsa-miR-22-3p may act as a regulatory factor for hnRNPA3 and form a ceRNA network with multiple lncRNAs.Analysis of immune infiltration and immune checkpoint genes revealed a correlation between hnRNPA3 expression and macrophages. The similar conclusion also occurred in the spatial transcriptomic detection. 5-Fluorouracil, Doxorubicin, Etoposide, et al., may be potential sensitive drugs in therapy of high-hnRNPA3 HCC patients. Silencing hnRNPA3 expression in SNU449 and HuH7 cells resulted in reducing proliferation and migration. RNA-seq showed hnRNPA3 played an important regulatory role in the malignant progression of HCC.

CONCLUSION

hnRNPA3 was found to represent a promising biomarker within HCC diagnosis and prognosis and maybe a potential drug-target in HCC therapy.

Treating Hematological Malignancies With OR-2100, an Orally Bioavailable Prodrug of Decitabine

DNA methylation is an enzyme-driven epigenetic modification that must be precisely regulated to maintain cellular homeostasis. Aberrant methylation status, especially hypermethylation of the promoter sites of tumor-suppressor genes, is observed in human malignancies and is a proven target for cancer therapy. The first-generation DNA demethylating agents, azacitidine and decitabine, are widely used for treating several hematological malignancies. In addition, orally bioavailable prodrugs of azacitidine and decitabine have recently been approved by the FDA. We have developed a silylated derivative of decitabine, OR-2100, which is resistant to degradation by cytidine deaminase and orally bioavailable. It has efficacy against several human hematological malignancies in xenograft mouse models with less hematotoxicity than decitabine. Since DNA demethylating agents are combined with molecularly targeted drugs in clinical use and trials, we think that the less hematotoxic profile of OR-2100 makes it suitable for use as a combination therapy. In this article, we review the therapeutic approach in hematological malignancies with the DNA demethylating agent OR-2100.

Epigenetic and epitranscriptomic role of lncRNA in carcinogenesis (Review)

Long non‑coding RNAs (lncRNAs) are key players in the regulation of gene expression by mediating epigenetic and epitranscriptomic modification. Dysregulation of lncRNAs is implicated in tumor initiation, progression and metastasis. lncRNAs modulate chromatin structure and gene transcription by recruiting epigenetic regulators, including DNA‑ or histone‑modifying enzymes. Additionally, lncRNAs mediate chromatin remodeling and enhancer‑promoter long‑range chromatin interactions to control oncogene expression by recruiting chromatin organization‑associated proteins, thereby promoting carcinogenesis. Furthermore, lncRNAs aberrantly induce oncogene expression by mediating epitranscriptomic modifications, including RNA methylation and RNA editing. The present study aimed to summarize the regulatory mechanisms of lncRNAs in cancer to unravel the complex interplay between lncRNAs and epigenetic/epitranscriptomic regulators in carcinogenesis. The present review aimed to provide a novel perspective on the epigenetic and epitranscriptomic roles of lncRNAs in carcinogenesis to facilitate identification of potential biomarkers and therapeutic targets for cancer diagnosis and treatment.

The physiological functions of ascorbate in the development of cancer

The metabolite ascorbate (vitamin C) is synthesized endogenously in most animals or, in humans and some other species, obtained from the diet. Its role in cancer development is controversial. Addition of ascorbate to cultured cells or high-dose administration in animals can inhibit growth of many cancers, but most of these effects are caused by non-physiological biochemical activities. Few experiments have tested the physiological roles of ascorbate in cancer development by depleting it in physiological settings. Ascorbate depletion inhibits the activity of ten-eleven translocation (TET) enzymes in hematopoietic and leukemia cells and accelerates myeloid leukemia development. Many clinical trials have tested ascorbate supplementation in cancers and shown little or no evidence that it has a beneficial role. I propose that depletion experiments are needed to define the cancers in which ascorbate has a physiological role, establish its cellular and molecular targets, and provide a rationale for clinical trials.

Identification of clinicopathological-specific driver gene and genetic subtyping of colorectal cancer

This study analyzed targeted sequencing data from 6530 tissue samples from patients with metastatic Chinese colorectal cancer (CRC) to identify low mutation frequency and subgroup-specific driver genes, using three algorithms for overall CRC as well as across different clinicopathological subgroups. We analyzed 425 cancer-related genes, identifying 101 potential driver genes, including 36 novel to CRC. Notably, some genes demonstrated subgroup specificity; for instance, ERBB4 was found as a male-specific driver gene and mutations of ERBB4 only influenced the prognosis of male patients with CRC. This sex disparity of ERBB4 was validated in an independent large-scale Memorial Sloan Kettering Cancer Center CRC cohort with 2444 samples. Furthermore, using network-based stratification based on protein-protein interaction, we classified the microsatellite stable (MSS) and unstable (MSI) CRCs into six and three major subtypes, respectively, each showing unique phenotypes and prognoses. In MSS CRC, cluster 5 (APCAMER1-KRAS) and cluster 2 (RNF43-BRAF-PIK3CA) were predominant, and cluster 5 showed a superior overall survival compared with cluster 2. This extensive heterogeneity in driver gene mutations underscores the complexity of CRC and suggests significant implications for treatment and prognostic assessments.

DNA Methylation in Periodontal Disease: A Focus on Folate, Folic Acid, Mitochondria, and Dietary Intervention

Although periodontal disease (PD) is reported to be associated with changes in various genes and proteins in both invading bacteria and the host, its molecular mechanism of pathogenesis remains unclear. Changes in immune and inflammatory genes play a significant role in PD pathogenesis. Some reports relate alterations in cellular epigenetic patterns to PD characteristics, while several high-throughput analyses indicate thousands of differentially methylated genes in both PD patients and controls. Furthermore, changes in DNA methylation patterns in inflammation-related genes have been linked to the efficacy of periodontal therapy, as demonstrated by findings related to the cytochrome C oxidase II gene. Distinct DNA methylation patterns in mesenchymal stem cells from PD patients and controls persisted despite the reversal of phenotypic PD. Methyl groups for DNA methylation are supplied by S-adenosylmethionine, which is synthesized with the involvement of folate, an essential nutrient known to play a role in maintaining mitochondrial homeostasis, reported to be compromised in PD. Folate may benefit PD through its antioxidant action against reactive oxygen and nitrogen species that are overproduced by dysfunctional mitochondria. As such, DNA methylation, dietary folate, and mitochondrial quality control may interact in PD pathogenesis. In this narrative/hypothesis review, we demonstrate how PD is associated with changes in mitochondrial homeostasis, which may, in turn, be improved by folate, potentially altering the epigenetic patterns of immune and inflammatory genes in both the nucleus and mitochondria. Therefore, a folate-based dietary intervention is recommended for PD prevention and as an adjunct therapy. At the same time, further research is needed on the involvement of epigenetic mechanisms in the beneficial effects of folate on PD studies.

Decoding the epigenetic and transcriptional basis of direct cardiac reprogramming

Heart disease, particularly resulting from myocardial infarction (MI), continues to be a leading cause of mortality, largely due to the limited regenerative capacity of the human heart. Current therapeutic approaches seek to generate new cardiomyocytes from alternative sources. Direct cardiac reprogramming, which converts fibroblasts into induced cardiomyocytes (iCMs), offers a promising alternative by enabling in situ cardiac regeneration and minimizing tumorigenesis concerns. Here we review recent advancements in the understanding of transcriptional and epigenetic mechanisms underlying cardiac reprogramming, with a focus on key early-stage molecular events, including epigenetic barriers and regulatory mechanisms that facilitate reprogramming. Despite substantial progress, human cardiac fibroblast reprogramming and iCM maturation remain areas for further exploration. We also discuss the combinatorial roles of reprogramming factors in governing transcriptional and epigenetic changes. This review consolidates current knowledge and proposes future directions for promoting the translational potential of cardiac reprogramming techniques.

The pharmacology of vitamin C

Ascorbic acid, the reduced form of vitamin C, is a ubiquitous small carbohydrate. Despite decades of focused research, new metabolic functions of this universal electron donor are still being discovered and add to the complexity of our view of vitamin C in human health. Although praised as an unsurpassed water-soluble antioxidant in plasma and cells, the most interesting functions of vitamin C seem to be its roles as specific electron donor in numerous biological reactions ranging from the well-known hydroxylation of proline to cofactor for the epigenetic master regulators ten-eleven translocation enzymes and Jumonji domain-containing histone-lysine demethylases. Some of these functions may have important implications for disease prevention and treatment and have spiked renewed interest in, eg, vitamin C's potential in cancer therapy. Moreover, some fundamental pharmacokinetic properties of vitamin C remain to be established including if other mechanisms than passive diffusion governs the efflux of ascorbate anions from the cell. Taken together, there still seems to be much to learn about the pharmacology of vitamin C and its role in health and disease. This review explores new avenues of vitamin C and integrates our present knowledge of its pharmacology. SIGNIFICANCE STATEMENT: Vitamin C is involved in multiple biological reactions of which most are essential to human health. Hundreds of millions of people are considered deficient in vitamin C according to accepted guidelines, but little is known about the long-term consequences. Although the complexity of vitamin C's physiology and pharmacology has been widely disregarded in clinical studies for decades, it seems clear that a deeper understanding of particularly its pharmacology holds the key to unravel and possibly exploit the potential of vitamin C in disease prevention and therapy.

Redox imbalance driven epigenetic reprogramming and cardiovascular dysfunctions: phytocompounds for prospective epidrugs

BACKGROUND

Cardiovascular diseases (CVDs) are the major contributor to global mortality and are gaining incremental attention following the COVID-19 outbreak. Epigenetic events such as DNA methylation, histone modifications, and non-coding RNAs have a significant impact on the incidence and onset of CVDs. Altered redox status is one of the major causative factors that regulate epigenetic pathways linked to CVDs. Various bioactive phytocompounds used in alternative therapies including Traditional Chinese Medicines (TCM) regulate redox balance and epigenetic phenomena linked to CVDs. Phytocompound-based medications are in the limelight for the development of cost-effective drugs with the least side effects, which will have immense therapeutic applications.

PURPOSE

This review comprehends certain risk factors associated with CVDs and triggered by oxidative stress-driven epigenetic remodelling. Further, it critically evaluates the pharmacological efficacy of phytocompounds as inhibitors of HAT/HDAC and DNMTs as well as miRNAs regulator that lowers the incidence of CVDs, aiming for new candidates as prospective epidrugs.

METHODS

PRISMA flow approach has been adopted for systematic literature review. Different Journals, computational databases, search engines such as Google Scholar, PubMed, Science Direct, Scopus, and ResearchGate were used to collect online information for literature survey. Statistical information collected from the World Health Organization (WHO) site (https://www.who.int/news-room/fact-sheets/detail/cardiovascular-diseases-(cvds)) and the American Heart Association of Heart Disease and Stroke reported the international and national status of CVDs.

RESULTS

The meta-analysis of various studies is elucidated in the literature, shedding light on major risk factors such as socioeconomic parameters, which contribute highly to redox imbalance, epigenetic modulations, and CVDs. Going forward, redox imbalance driven epigenetic regulations include changes in DNA methylation status, histone modifications and non-coding RNAs expression pattern which further regulates global as well as promoter modification of various transcription factors leading to the onset of CVDs. Further, the role of various bioactive compounds used in herbal medicine, including TCM for redox regulation and epigenetic modifications are discussed. Pharmacological safety doses and different phases of clinical trials of these phytocompounds are elaborated on, which shed light on the acceptance of these phytocompounds as prospective drugs.

CONCLUSION

This review suggests a strong linkage between therapeutic and preventive measures against CVDs by targeting redox imbalance-driven epigenetic reprogramming using phytocompounds as prospective epidrugs. Future in-depth research is required to evaluate the possible molecular mechanisms behind the phytocompound-mediated epigenetic reprogramming and oxidative stress management during CVD progression.

Cytometry at the Intersection of Metabolism and Epigenetics in Lymphocyte Dynamics

Landmark studies at the turn of the century revealed metabolic reprogramming as a driving force for lymphocyte differentiation and function. In addition to metabolic changes, differentiating lymphocytes must remodel their epigenetic landscape to properly rewire their gene expression. Recent discoveries have shown that metabolic shifts can shape the fate of lymphocytes by altering their epigenetic state, bringing together these two areas of inquiry. The ongoing evolution of high-dimensional cytometry has enabled increasingly comprehensive analyses of metabolic and epigenetic landscapes in lymphocytes that transcend the technical limitations of the past. Here, we review recent insights into the interplay between metabolism and epigenetics in lymphocytes and how its dysregulation can lead to immunological dysfunction and disease. We also discuss the latest technical advances in cytometry that have enabled these discoveries and that we anticipate will advance future work in this area.

RNA methylation: where to from here for hematologic malignancies?

RNA methylation and the machinery that regulates or "reads" its expression has recently been implicated in the pathogenesis of acute myeloid leukemia (AML) and other hematologic malignancies. Modulation of these epigenetic marks has started to become a reality as several companies around the world seek to leverage this knowledge therapeutically in the clinic. Although the bases of observed activity in AML have been described by numerous groups, the exact context in which these therapies will ultimately be used remains to be properly determined. While context is likely to be of great importance here, a more "global" mechanism of action might allow for more widespread applicability to multiple disease subtypes. In other areas such as the myelodysplastic and other preleukemic syndromes, data remain sparse. Ongoing work is needed to determine whether therapeutic modulation of RNA modifications is a viable and biologically plausible approach in these cases. Regardless of the outcomes, this is an exciting era for "epitranscriptomics" as we navigate a pathway forward. Here, I describe the current knowledge around RNA methylation and hematologic malignancies at the end of 2024 including some of the relevant questions that are yet to be answered.

Interplay between pioneer transcription factors and epigenetic modifiers in cell reprogramming

The generation of induced pluripotent stem cells (iPSCs) from differentiated somatic cells by Yamanaka factors, including pioneer transcription factors (TFs), has greatly reshaped our traditional understanding of cell plasticity and demonstrated the remarkable potential of pioneer TFs. In addition to iPSC reprogramming, pioneer TFs are pivotal in direct reprogramming or transdifferentiation where somatic cells are converted into different cell types without passing through a pluripotent state. Pioneer TFs initiate a reprogramming process through chromatin opening, thereby establishing competence for new gene regulatory programs. The action of pioneer TFs is both influenced by and exerts influence on epigenetic regulation. Despite significant advances, many direct reprogramming processes remain inefficient, which limits their reliability for clinical applications. In this review, we discuss the molecular mechanisms underlying pioneer TF-driven reprogramming, with a focus on their interactions with epigenetic modifiers, including Polycomb repressive complexes (PRCs), nucleosome remodeling and deacetylase (NuRD) complexes, and the DNA methylation machinery. A deeper understanding of the dynamic interplay between pioneer TFs and epigenetic modifiers will be essential for advancing reprogramming technologies and unlocking their full clinical potential.

Aberrant DNA methylation as a key modulator of cell death pathways: insights into cancer progression and other diseases

Cell death plays a significant role in the physiology of all living organisms, and its disruption is the underlying cause of various diseases. Previously, it was assumed that apoptosis and necrosis were the only means of cell death. Recent discoveries of alternative cell death pathways highlighted a complicated interplay between cell death regulation and its role in numerous human pathologies. DNA methylation is a universal epigenetic mechanism characterized by the covalent addition of a methyl group to cytosine in CpG dinucleotides. Alterations in DNA methylation patterns lead to the dysregulation of multiple cell death pathways. DNA methylome studies on cell death pathways have improved our understanding of the mechanism of various types of cell death, such as apoptosis, pyroptosis, necroptosis, ferroptosis, anoikis, autophagy, and cuproptosis. The irregular DNA methylation patterns of genes encoding proteins linked to multiple cell death pathways could underlie resistance to cell death. Dysregulation of cell death is linked to ailments in humans, such as cancer. However, unlike genetic alterations, DNA methylation is reversible, making it extremely interesting for therapeutics considering the potential use of DNA methyltransferase inhibitors. Furthermore, tumor microenvironment and genetic heterogeneity of cancers may influence the methylation-dependent regulation of cell death, contributing to tumor progression and therapeutic resistance. Understanding how DNA methylation influences cell death pathways may illuminate the underlying causes of cancer. This review explores the significance of the DNA methylation patterns of key genes involved in cell death pathways, emphasizing their connections and identifying potential gaps that could be exploited for developing epigenetic therapies targeting cancer.

DNA methylation alterations in prostate cancer: from diagnosis to treatment

Epigenetics, particularly DNA methylation, plays a crucial role in gene activation and deactivation. Indeed, modification of this pathway has been well described as promoter of cancer development in many settings. Hypermethylation of CpG islands has also been described as a significant epigenetic alteration in prostate cancer (PCa), being associated with gene silencing and tumour progression. Key studies have shown that specific genes, such as GSTP1, APC, and RARb2, exhibit significant epigenetic alterations in PCa, with their methylation profiles showing potential utility as biomarkers in the diagnostic setting. Furthermore, comprehensive methylation analyses have identified numerous differentially methylated CpGs and relative molecular pathways associated with PCa carcinogenesis and progression, thus enhancing the understanding of its molecular underpinnings. Finally, therapies targeting DNA methylation, such as DNA methyltransferases (DNMTs) inhibitors, show potential in overcoming drug resistance in advanced PCa treatment. Consequently, dissecting epigenetic mechanisms, and in particular DNA methylation, is fundamental for understanding PCa carcinogenesis, providing valuable insights for clinical decisions and development of targeted therapies. Given the above premises, this review aims to provide an overview of the role of DNA methylation aberrations in PCa, highlighting current and future directions for exploring the epigenetic landscape to better understand the origins and progression of this disease.

Effects of Environmental Non-Essential Toxic Heavy Metals on Epigenetics During Development

We are exposed to a variety of environmental chemicals in our daily lives. It is possible that the effects of this daily chemical exposure could accumulate in the organism in some form and influence health and disease development. The exposure effects extend throughout the human lifetime, not only after birth, but also during the embryonic period. Epigenetics is an important target for the molecular mechanisms of daily environmental chemical effects. Epigenetics is a mechanism of gene transcription regulation that does not involve changes in DNA sequence. The Developmental Origins of Health and Disease (DOHaD) theory has also been proposed, in which effects such as exposure to environmental chemicals during embryonic period are mediated by epigenetic changes, which may lead to risk for disease development and adverse health effects after maturity. This review summarizes the association between embryonic exposure and the epigenetics of well-known non-essential toxic heavy metals (methylmercury, cadmium, arsenic, and lead), a representative group of environmental chemicals. In the future, it will be important to predict the epigenetic mechanisms of unknown chemical and combined exposures. In addition, further experimental investigations using experimental animals and the accumulation of knowledge are needed to study the transgenerational effects of environmental chemicals in the future.

Optogenetics with Atomic Precision─A Comprehensive Review of Optical Control of Protein Function through Genetic Code Expansion

Conditional control of protein activity is important in order to elucidate the particular functions and interactions of proteins, their regulators, and their substrates, as well as their impact on the behavior of a cell or organism. Optical control provides a perhaps optimal means of introducing spatiotemporal control over protein function as it allows for tunable, rapid, and noninvasive activation of protein activity in its native environment. One method of introducing optical control over protein activity is through the introduction of photocaged and photoswitchable noncanonical amino acids (ncAAs) through genetic code expansion in cells and animals. Genetic incorporation of photoactive ncAAs at key residues in a protein provides a tool for optical activation, or sometimes deactivation, of protein activity. Importantly, the incorporation site can typically be rationally selected based on structural, mechanistic, or computational information. In this review, we comprehensively summarize the applications of photocaged lysine, tyrosine, cysteine, serine, histidine, glutamate, and aspartate derivatives, as well as photoswitchable phenylalanine analogues. The extensive and diverse list of proteins that have been placed under optical control demonstrates the broad applicability of this methodology.

Epigenetic drugs in cancer therapy

Genetic and epigenetic modifications of DNA are involved in cancer initiation and progression. Epigenetic modifications change chromatin structure and DNA accessibility and thus affect DNA replication, DNA repair and transcription. Epigenetic modifications are reversible and include DNA methylation, histone acetylation and histone methylation. DNA methylation is catalysed by DNA methyltransferases, histone acetylation and deacetylation are catalysed by histone acetylases and deacetylases, while histone methylation is catalysed by histone methyltransferases. Epigenetic modifications are dysregulated in several cancers, making them cancer therapeutic targets. Epigenetic drugs (epi-drugs) which are inhibitors of epigenetic modifications and include DNA methyltransferase inhibitors (DNMTi), histone deacetylase inhibitors (HDACi), histone methyltransferase inhibitors (HMTi) and bromodomain and extra-terminal motif protein inhibitors (BETi), have demonstrated clinical success as anti-cancer agents. Furthermore, the combination of epi-drugs with standard chemotherapeutic agents has demonstrated promising anti-cancer effects in pre-clinical and clinical settings. In this review, we discuss the role of epi-drugs in cancer therapy and explore their current and future use in combination with other anti-cancer agents used in the clinic. We further highlight the side effects and limitations of epi-drugs. We additionally discuss novel delivery methods and novel tumour epigenetic biomarkers for the screening, diagnosis and development of personalised cancer treatments, in order to reduce off-target toxicity and improve the specificity and anti-tumour efficacy of epi-drugs.

Epigenetic marvels: exploring the landscape of colorectal cancer treatment through cutting-edge epigenetic-based drug strategies

Epigenetics is currently considered the investigation of inheritable changes in gene expression that do not rely on DNA sequence alteration. Significant epigenetic procedures are involved, such as DNA methylations, histone modifications, and non-coding RNA actions. It is confirmed through several investigations that epigenetic changes are associated with the formation, development, and metastasis of various cancers, such as colorectal cancer (CRC). The difference between epigenetic changes and genetic mutations is that the former could be reversed or prevented; therefore, cancer treatment and prevention could be achieved by restoring abnormal epigenetic events within the neoplastic cells. These treatments, consequently, cause the anti-tumour effects augmentation, drug resistance reduction, and host immune response stimulation. In this article, we begin our survey by exploring basic epigenetic mechanisms to understand epigenetic tools and strategies for treating colorectal cancer in monotherapy and combination with chemotherapy or immunotherapy.

Epigenetic control of cell identities from epiblast to gastrulation

Epigenetic modifications of chromatin are essential for the establishment of cell identities during embryogenesis. Between embryonic days 3.5-7.5 of murine development, major cell lineage decisions are made that discriminate extraembryonic and embryonic tissues, and the embryonic primary germ layers are formed, thereby laying down the basic body plan. In this review, we cover the contribution of dynamic chromatin modifications by DNA methylation, changes of chromatin accessibility, and histone modifications, that in combination with transcription factors control gene expression programs of different cell types. We highlight the differences in regulation of enhancer and promoter marks and discuss their requirement in cell lineage specification. Importantly, in many cases, lineage-specific targeting of epigenetic modifiers is carried out by pioneer or master transcription factors, that in sum mediate the chromatin landscape and thereby control the transcription of cell-type-specific gene programs and thus, cell identities.

Nitric oxide inhibits ten-eleven translocation DNA demethylases to regulate 5mC and 5hmC across the genome

DNA methylation at cytosine bases (5-methylcytosine, 5mC) is a heritable epigenetic mark regulating gene expression. While enzymes that metabolize 5mC are well-characterized, endogenous signaling molecules that regulate DNA methylation machinery have not been described. We report that physiological nitric oxide (NO) concentrations reversibly inhibit the DNA demethylases TET and ALKBH2 by binding to the mononuclear non-heme iron atom forming a dinitrosyliron complex (DNIC) and preventing cosubstrates from binding. In cancer cells treated with exogenous NO, or endogenously synthesizing NO, 5mC and 5-hydroxymethylcytosine (5hmC) increase, with no changes in DNA methyltransferase activity. 5mC is also significantly increased in NO-producing patient-derived xenograft tumors from mice. Genome-wide methylome analysis of cells chronically treated with NO (10 days) shows enrichment of 5mC and 5hmC at gene-regulatory loci, correlating with altered expression of NO-regulated tumor-associated genes. Regulation of DNA methylation is distinctly different from canonical NO signaling and represents a unique epigenetic role for NO.

Double and single stranded detection of 5-methylcytosine and 5-hydroxymethylcytosine with nanopore sequencing

5-methylcytosine (5mC) and 5-hydroxymethylcytosine (5hmC) are modified versions of cytosine in DNA with roles in regulating gene expression. Using whole genomic DNA from mouse cerebellum, we benchmark 5mC and 5hmC detection by Oxford Nanopore Technologies sequencing against other standard techniques. In addition, we assess the ability of duplex base-calling to study strand asymmetric modification. Nanopore detection of 5mC and 5hmC is accurate relative to compared techniques and opens means of studying these modifications. Strand asymmetric modification is widespread across the genome but reduced at imprinting control regions and CTCF binding sites in mouse cerebellum. Here we demonstrate the unique ability of nanopore sequencing to improve the resolution and detail of cytosine modification mapping.

Novel Epigenetics Control (EpC) Nanocarrier for Cancer Therapy Through Dual-Targeting Approach to DNA Methyltransferase and Ten-Eleven Translocation Enzymes

BACKGROUND/OBJECTIVES

Aberrant hypermethylation in the promoter regions of tumor suppressor genes facilitates the pathogenesis and progression of cancer. Therefore, inhibitors targeting DNA methyltransferase (DNMT) have been tested in clinical studies. However, the current monotherapy of DNMT inhibitors shows limited efficacy. Furthermore, the mechanism of action of DNMT inhibitors is DNA replication-dependent. To address these limitations, we developed a novel core-shell-type "epigenetics control (EpC) nanocarrier" that encapsulated decitabine (5-aza-dC) in the PLGA core nanoparticle and hybridized TET1 gene-encoding pDNA on the lipid shell surface. This study aimed to evaluate whether the dual delivery of DNMT inhibitors and pDNA of TET1 could synergistically enhance tumor suppressor gene expression and induce cell cycle arrest and/or apoptosis in cancer cells. Herein, we demonstrate the potential of the EpC carrier in HCT116 human colon cancer cells to upregulate tumor suppressor gene expression and rapidly achieve cell cycle arrest.

METHODS

PLGA core nanoparticles were prepared by the W/O/W double emulsion method. The formation of core-shell nanoparticles and complexation with pDNA were investigated and optimized by dynamic light scattering, zeta potential measurement, and agarose gel electrophoresis. The cellular uptake and transfection efficiency were measured by confocal laser scanning microscopy and a luciferase assay, respectively. The expression of p53 protein was detected by Western blotting. The anti-tumor effects of the EpC nanocarrier were evaluated by cell cycle analysis and an apoptosis assay.

RESULTS

The EpC nanocarrier delivered the DNMT inhibitor and TET gene-encoding pDNA into HCT116 cells. It promoted the expression of the tumor suppressor protein p53 and induced rapid cell cycle arrest in the G2/M phase in HCT116 cells.

CONCLUSIONS

Our findings suggest that the dual-targeting of DNMT and TET enzymes effectively repairs aberrant DNA methylation and induces growth arrest in cancer cells, and the dual-targeting strategy may contribute to the advancement of epigenetic cancer therapy.

Unveiling the Therapeutic Promise of Epigenetics in Vascular Cognitive Impairment and Vascular Dementia

Vascular dementia (VaD) is a progressive neurodegenerative disease characterized by cognitive decline and memory deficits. Despite its significant prevalence and impact, the pathophysiology of VaD remains poorly understood, and current treatments are limited to symptom management. Emerging evidence highlights the importance of lifestyle-associated risk factors in VaD, emphasizing the role of gene-environment interactions, particularly in the realm of epigenetics. While preclinical studies using animal models have provided valuable insights into epigenetic mechanisms, the translatability of these findings to human clinical settings remains limited, and research into VaD-specific epigenetics is still in its infancy. This review aims to elucidate the intricate interplay between epigenetics and VaD, shedding light on potential therapeutic interventions rooted in epigenetic mechanisms. By synthesizing insights from existing literature, we also discuss the challenges and opportunities in translating preclinical findings into clinically viable treatments, underscoring the need for further research to bridge the gap between animal models and human applications.

Active DNA demethylation is upstream of rod-photoreceptor fate determination and required for retinal development

Retinal cell fate specification from multipotent retinal progenitors is governed by dynamic changes in chromatin structure and gene expression. Methylation at cytosines in DNA (5mC) is actively regulated for proper control of gene expression and chromatin architecture. Numerous genes display active DNA demethylation across retinal development; a process that requires oxidation of 5mC to 5-hydroxymethylcytosine (5hmC) and is controlled by the ten-eleven translocation methylcytosine dioxygenase (TET) enzymes. Using an allelic series of conditional TET enzyme mutants, we determine that DNA demethylation is required upstream of NRL and NR2E3 expression for the establishment of rod-photoreceptor fate. Using histological, behavioral, transcriptomic, and base-pair resolution DNA methylation analyses, we establish that inhibition of active DNA demethylation results in global changes in gene expression and methylation patterns that prevent photoreceptor precursors from adopting a rod-photoreceptor fate, instead producing a retina in which all photoreceptors specify as cones. Our results establish the TET enzymes and DNA demethylation as critical regulators of retinal development and cell fate specification, elucidating a novel mechanism required for the specification of rod-photoreceptors.

Hallmarks of aging: A user's guide for comparative biologists

Since the first description of a set of characteristics of aging as so-called hallmarks or pillars in 2013/2014, these characteristics have served as guideposts for the research in aging biology. They have been examined in a range of contexts, across tissues, in response to disease conditions or environmental factors, and served as a benchmark for various anti-aging interventions. While the hallmarks of aging were intended to capture generalizable characteristics of aging, they are derived mostly from studies of rodents and humans. Comparative studies of aging including species from across the animal tree of life have great promise to reveal new insights into the mechanistic foundations of aging, as there is a great diversity in lifespan and age-associated physiological changes. However, it is unclear how well the defined hallmarks of aging apply across diverse species. Here, we review each of the twelve hallmarks of aging defined by Lopez-Otin in 2023 with respect to the availability of data from diverse species. We evaluate the current methods used to assess these hallmarks for their potential to be adapted for comparative studies. Not unexpectedly, we find that the data supporting the described hallmarks of aging are restricted mostly to humans and a few model systems and that no data are available for many animal clades. Similarly, not all hallmarks can be easily assessed in diverse species. However, for at least half of the hallmarks, there are methods available today that can be employed to fill this gap in knowledge, suggesting that these studies can be prioritized while methods are developed for comparative study of the remaining hallmarks.

The role of lncRNAs in the interplay of signaling pathways and epigenetic mechanisms in glioma

Gliomas, highly aggressive tumors of the central nervous system, present overwhelming challenges due to their heterogeneity and therapeutic resistance. Glioblastoma multiforme (GBM), the most malignant form, underscores this clinical urgency due to dismal prognosis despite aggressive treatment regimens. Recent advances in cancer research revealed signaling pathways and epigenetic mechanisms that intricately govern glioma progression, offering multifaceted targets for therapeutic intervention. This review explores the dynamic interplay between signaling events and epigenetic regulation in the context of glioma, with a particular focus on the crucial roles played by non-coding RNAs (ncRNAs). Through direct and indirect epigenetic targeting, ncRNAs emerge as key regulators shaping the molecular landscape of glioblastoma across its various stages. By dissecting these intricate regulatory networks, novel and patient-tailored therapeutic strategies could be devised to improve patient outcomes with this devastating disease.

The Role of DNA Methylation in Gastrointestinal Disease: An Expanded Review of Malignant and Nonmalignant Gastrointestinal Diseases

Esophageal, colorectal, pancreatic, hepatocellular, and gastric cancer together impact millions of patients worldwide each year, with high overall mortality rates, and are increasing in incidence. Additionally, premalignant gastrointestinal diseases, such as Barrett's esophagus and inflammatory bowel disease, are also increasing in incidence. However, involvement of aberrant DNA methylation in these diseases is incompletely understood, especially given recent research advancements in this field. Here, we review knowledge of this epigenetic mechanism in gastrointestinal preneoplasia and neoplasia, considering mechanisms of action, genetic and environmental factors, and 5'-C-phosphate-G-3' island methylator phenotype. We also highlight developments in translational research, focusing on genomic-wide data, methylation-based biomarkers and diagnostic tests, machine learning, and therapeutic epigenetic strategies.

Diagnostic Challenges in the Pathological Approach to Pleural Mesothelioma

Malignant pleural mesothelioma (MPM) still represents a complex diagnostic challenge for pathologists in routine practice. This diagnosis requires a multidisciplinary approach, and pathological evaluation is mandatory. The histopathological diagnosis is stepwise and should be based on morphological and immunohistochemical assessment, sometimes associated with molecular tests, and supported by clinical and radiological findings. A correct morphological approach aims to exclude pleural metastasis or benign mesothelial proliferations, which are the main differential diagnoses. While certain histological features are diagnostic of MPM, others are highly suggestive but not definitive. Immunohistochemistry plays a pivotal role, with a panel of both traditional and newer markers being used to assess mesothelial differentiation and to differentiate malignant from benign proliferations. In more challenging cases, molecular tests, such as fluorescent in situ hybridization (FISH) to detect CDKN2A deletion, can be helpful in distinguishing malignant from benign pleural lesions. This review summarizes the key morphological, immunohistochemical, and molecular features that should be considered when pleural biopsy samples are examined, with the aim of improving diagnostic accuracy in this complex area.

Exploring the Characters of Non-Coding RNAs in Spermatogenesis and Male Infertility

Infertility is a widespread clinical problem that affects human reproduction and species persistence worldwide. Around 40-70% of cases are due to male reproductive defects. Functional spermatogenesis (sperm production through several coordinated events) is at the heart of male fertility. Non-coding RNAs (ncRNAs) are the primary regulators of gene expression, controlling extensive critical cellular processes, for example proliferation, differentiation, apoptosis, and reproduction. Due to advancements in high-throughput sequencing tools, many studies have revealed that ncRNAs are widely expressed in germ cells, meiosis, spermatogenesis, sperm fertility, early post-fertilization development, and male infertility. The present review examines the biology and function of ncRNAs, including microRNAs, circular RNAs, and long ncRNAs, in spermatogenesis, their correlation with infertility, and their potential as biomarkers for sperm quality and fertility. The function of ncRNA in Sertoli cells (SCs) and Leydig cells (LCs) is also outlined throughout this study, because spermatogenesis requires testicular somatic cells to be involved in testicular development and male fertility. Meanwhile, the future development of ncRNAs for the clinical treatment of male infertility is also anticipated and discussed.

Oxidative-Stress-Mediated Epigenetic Dysregulation in Spermatogenesis: Implications for Male Infertility and Offspring Health

Male reproductive health is governed by an intricate interplay of genetic, epigenetic, and environmental factors. Epigenetic mechanisms-encompassing DNA methylation, histone modifications, and non-coding RNA activity-are crucial both for spermatogenesis and sperm maturation. However, oxidative stress, driven by excessive reactive oxygen species, disrupts these processes, leading to impaired sperm function and male infertility. This disruption extends to epigenetic modifications, resulting in abnormal gene expression and chromatin remodeling that compromise genomic integrity and fertilization potential. Importantly, oxidative-stress-induced epigenetic alterations can be inherited, affecting the health and fertility of offspring and future generations. This review investigates how oxidative stress influences epigenetic regulation in male reproduction by modifying DNA methylation, histone modifications, and non-coding RNAs, ultimately compromising spermatogenesis. Additionally, it discusses the transgenerational implications of these epigenetic disruptions and their potential role in hereditary infertility and disease predisposition. Understanding these mechanisms is vital for developing therapeutic strategies that mitigate oxidative damage and restore epigenetic homeostasis in the male germline. By integrating insights from molecular, clinical, and transgenerational research, this work emphasizes the need for targeted interventions to enhance male reproductive health and prevent adverse outcomes in progeny. Furthermore, elucidating the dose-response relationships between oxidative stress and epigenetic changes remains a critical research priority, informing personalized diagnostics and therapeutic interventions. In this context, future studies should adopt standardized markers of oxidative damage, robust clinical trials, and multi-omic approaches to capture the complexity of epigenetic regulation in spermatogenesis. Such rigorous investigations will ultimately reduce the risk of transgenerational disorders and optimize reproductive health outcomes.

Epigenetic Control of Redox Pathways in Cancer Progression

Significance: Growing evidence indicates the importance of redox reactions homeostasis, mediated predominantly by reactive oxygen species (ROS) in influencing the development, differentiation, progression, metastasis, programmed cell death, tumor microenvironment, and therapeutic resistance of cancer. Therefore, reviewing the ROS-linked epigenetic changes in cancer is fundamental to understanding the progression and prevention of cancer. Recent Advances: We review in depth the molecular mechanisms involved in ROS-mediated epigenetic changes that lead to alteration of gene expression by altering DNA, modifying histones, and remodeling chromatin and noncoding RNA. Critical Issues: In cancerous cells, alterations of the gene-expression regulatory elements could be generated by the virtue of imbalance in tumor microenvironment. Various oxidizing agents and mitochondrial electron transport chain are the major pathways that generate ROS. ROS plays a key role in carcinogenesis by activating pro-inflammatory signaling pathways and DNA damage. This loss of ROS-mediated epigenetic regulation of the signaling pathways may promote tumorigenesis. We address all such aspects in this review. Future Directions: Developments in this growing field of epigenetics are expected to contribute to further our understanding of human health and diseases such as cancer and to test the clinical applications of redox-based therapy. Recent studies of the cancer-epigenetic landscape have revealed pervasive deregulation of the epigenetic factors in cancer. Thus, the study of interaction between ROS and epigenetic factors in cancer holds a great promise in the development of effective and targeted treatment modalities. Antioxid. Redox Signal. 00, 000-000.

miR-143-3p/TET1 Axis Regulates GPC1 Through DNA Methylation and Impairs the Malignant Biological Behaviour of HCC via the Hippo Signalling Pathway

Hepatocellular carcinoma (HCC) is a malignant tumour that poses a serious threat to human health and places a heavy burden on individuals and society. However, the role of GPC1 in the malignant progression of HCC is unknown. In this study, we analysed the expression of GPC1 in HCC, and its association with poor patient prognosis. The effects of GPC1 on the proliferation, invasion and migration of HCC were analysed through cellular functional experiments in vitro and in vivo. Mechanistically, DNA methylation of GPC1 was analysed by DNA extraction, methylation-specific PCR and bisulfite Sanger sequencing (BSP), and the target genes TET1 and miRNA regulating DNA methylation of GPC1 were found through the bioinformatics database. The results revealed that GPC1 was highly expressed in HCC, and its high expression was significantly associated with poor prognosis of HCC patients. Inhibiting the expression of GPC1 can inhibit the proliferation, invasion and migration of HCC cells. GPC1 was hypomethylated in HCC, and its methylation level was regulated by TET1. miR-143-3p can significantly regulated the expression of TET1 and affect the methylation level and protein expression of GPC1. Furthermore, GPC1 also affects the malignant biological behaviour of HCC by regulating the expression of Hippo signalling pathway. In summary, miR-143-3p regulates the expression of TET1, affects the expression of GPC1 through DNA methylation and regulates the malignant progression of HCC via Hippo signalling pathway.

DNA Methylation in Prostate Cancer: Clinical Implications and Potential Applications

BACKGROUND

Prostate cancer is a common cancer with a variable prognosis. Its management is currently guided by histological and biological markers such as the Gleason score and PSA. Developments in molecular biology are now making it possible to identify new targets for better classification of prostate cancer. Among emerging biomarker, DNA methylation, an epigenetic process, is increasingly being studied in carcinogenesis. Techniques for analyzing DNA methylation are constantly improving, and digital PCR now allows absolute methylation quantification with high sensitivity. These techniques can be performed on circulating tumor DNA.

MATERIALS & METHODS

We conducted a literature review of scientific articles addressing the topic of DNA methylation in prostate cancer.

RESULTS & DISCUSSION

This review summarizes the different genes whose methylation is involved in carcinogenesis and their clinical implications, both diagnostic and prognostic. Methylation monitoring could also be useful for the prediction of treatment response. However, most studies are retrospective, and prospective studies are needed to validate these data.

Bridging tissue repair and epithelial carcinogenesis: epigenetic memory and field cancerization

The epigenome coordinates spatial-temporal specific gene expression during development and in adulthood, for the maintenance of homeostasis and upon tissue repair. The upheaval of the epigenetic landscape is a key event in the onset of many pathologies including tumours, where epigenetic changes cooperate with genetic aberrations to establish the neoplastic phenotype and to drive cell plasticity during its evolution. DNA methylation, histone modifiers and readers or other chromatin components are indeed often altered in cancers, such as carcinomas that develop in epithelia. Lining the surfaces and the cavities of our body and acting as a barrier from the environment, epithelia are frequently subjected to acute or chronic tissue damages, such as mechanical injuries or inflammatory episodes. These events can activate plasticity mechanisms, with a deep impact on cells' epigenome. Despite being very effective, tissue repair mechanisms are closely associated with tumour onset. Here we review the similarities between tissue repair and carcinogenesis, with a special focus on the epigenetic mechanisms activated by cells during repair and opted by carcinoma cells in multiple epithelia. Moreover, we discuss the recent findings on inflammatory and wound memory in epithelia and describe the epigenetic modifications that characterise them. Finally, as wound memory in epithelial cells promotes carcinogenesis, we highlight how it represents an early step for the establishment of field cancerization.

Prognostic and functional role of the nuclear export receptor 1 (XPO1) in gastrointestinal cancers: a potential novel target?

In the last decades the survival of metastatic gastrointestinal (GI) cancer patients could have been significantly extended due to the introduction of targeted- and immunotherapy. However, only the minority of patients will experience long-lasting survival. Hence, novel therapeutics are clearly necessary for GI cancer patients. Molecular high-throughput profiling techniques have revealed potential novel targetable molecular alterations, emphasizing the necessity for tailored therapeutic approaches. Nuclear export proteins, particularly Exportin-1 (XPO1), have emerged as promising targets in cancer therapy due to their crucial role in cellular homeostasis and regulation of key cellular functions. Dysregulation of XPO1-mediated nuclear export leads to the functional loss of tumor suppressors and pro-apoptotic factors, facilitating cancer progression. Selinexor, a XPO1 inhibitor, has shown promising activity in preclinical and clinical studies, particularly in hematological malignancies. However, its efficacy in GI cancers remains underexplored. This review aims to elucidate the functional and pathophysiological role of XPO1 in GI cancers. Despite the potential of XPO1 inhibitors in suppressing cell proliferation and inducing apoptosis, comprehensive molecular landscape data and validation of selective inhibitors in GI cancers are lacking. Targeting XPO1 presents a significant therapeutic potential for the treatment of GI cancer patients. Further research is necessary to fully elucidate the molecular landscape according to XPO1 expression in GI tumors and to validate the efficacy of selective XPO1 inhibitors. These efforts are expected to contribute to the development of more effective and personalized therapeutic strategies for GI cancer patients.

Vitamin C and MEK Inhibitor PD0325901 Synergistically Promote Oligodendrocytes Generation by Promoting DNA Demethylation

DNA methylation and demethylation are key epigenetic events that regulate gene expression and cell fate. DNA demethylation via oxidation of 5-methylcytosine (5mC) to 5-hydroxymethylcytosine (5hmC) is typically mediated by TET (ten-eleven translocation) enzymes. The 5hmC modification is considered an intermediate state of DNA demethylation; it is particularly prevalent in the brain and is believed to play a role in the development of many cell types in the brain. Our previous studies have identified that vitamin C (Vc) and MEK inhibitor PD0325901 could significantly promote OPC (oligodendrocyte progenitor cell)-to-OL (oligodendrocyte) differentiation. Here we discovered that Vc and PD0325901 may promote OPC-to-OL differentiation by inducing DNA demethylation via hydroxymethylation. Blocking 5hmC formation almost totally blocked Vc- and PD0325901-stimulated OPC-to-OL differentiation. In addition, TET1 is not involved in Vc,- and PD0325901-promoted OL generation. We also found a synergistic effect between the two compounds in inducing OL generation, suggesting the possibility of a combination therapy for demyelination diseases in the future.

Epigenetic-modifying agents: The potential game changers in the treatment of hematologic malignancies

Hematologic malignancies are lethal diseases arising from accumulated leukemic cells with substantial genetic or epigenetic defects in their natural development. Epigenetic modifications, including DNA methylation and histone modifications, are critical in hematologic malignancy formation, propagation, and treatment response. Both mutations and aberrant recruitment of epigenetic modifiers are reported in different hematologic malignancies, which regarding the reversible nature of epigenetic regulations, make them a potential target for cancer treatment. Here, we have first outlined a comprehensive overview of current knowledge related to epigenetic regulation's impact on the development and prognosis of hematologic malignancies. Furthermore, we have presented an updated overview regarding the current status of epigenetic-based drugs in hematologic malignancies treatment. And finally, discuss current challenges and ongoing clinical trials based on the manipulation of epigenetic modifies in hematologic malignancies.

The analgesic effect of acupuncture in neuropathic pain: regulatory mechanisms of DNA methylation in the brain

Recent research has demonstrated that chronic pain, resulting from peripheral nerve injury, leads to various symptoms, including not only allodynia and hyperalgesia but also anxiety, depression, and cognitive impairment. These symptoms are believed to arise due to alterations in gene expression and neural function, mediated by epigenetic changes in chromatin structure. Emerging evidence suggests that acupuncture can modulate DNA methylation within the central nervous system, contributing to pain relief and the mitigation of comorbidities. Specifically, acupuncture has been shown to adjust the DNA methylation of genes related to mitochondrial dysfunction, oxidative phosphorylation, and inflammation pathways within cortical regions, such as the prefrontal cortex, anterior cingulate cortex, and primary somatosensory cortex. In addition, it influences the DNA methylation of genes associated with neurogenesis in hippocampal neurons. This evidence indicates that acupuncture, a treatment with fewer side effects compared with conventional medications, could offer an effective strategy for pain management.

[Epigenetics and cancer: the role of DNA methylation]

Alterations in DNA methylation profiles are typically found in cancer cells, combining genome-wide hypomethylation with hypermethylation of specific regions, such as CpG islands, which are normally unmethylated. Driving effects in cancer development have been associated with alteration of DNA methylation in certain regions, inducing, for example, the repression of tumor suppressor genes or the activation of oncogenes and retrotransposons. These alterations represent prime candidates for the development of specific markers for the detection, diagnosis and prognosis of cancer. In particular, these markers, distributed along the genome, provide a wealth of information that offers potential for innovation in the field of liquid biopsy, in particular thanks to the emergence of artificial intelligence for diagnostic purposes. This could overcome the limitations related to sensitivities and specificities, which remain too low for the most difficult applications in oncology: the detection of cancers at an early stage, the monitoring of residual disease and the analysis of brain tumors. In addition, targeting the enzymatic processes that control the epigenome offers new therapeutic strategies that could reverse the regulatory anomalies of these altered epigenomes.

LncRNAs and the cancer epigenome: Mechanisms and therapeutic potential

Long non-coding RNAs (lncRNAs) have emerged as critical regulators of epigenome, modulating gene expression through DNA methylation, histone modification, and/or chromosome remodeling. Dysregulated lncRNAs act as oncogenes or tumor suppressors, driving tumor progression by shaping the cancer epigenome. By interacting with the writers, readers, and erasers of the epigenetic script, lncRNAs induce epigenetic modifications that bring about changes in cancer cell proliferation, apoptosis, epithelial-mesenchymal transition, migration, invasion, metastasis, cancer stemness and chemoresistance. This review analyzes and discusses the multifaceted role of lncRNAs in cancer pathobiology, from cancer genesis and progression through metastasis and therapy resistance. It also explores the therapeutic potential of targeting lncRNAs through innovative diagnostic, prognostic, and therapeutic strategies. Understanding the dynamic interplay between lncRNAs and epigenome is crucial for developing personalized therapeutic strategies, offering new avenues for precision cancer medicine.

Opportunities for Therapeutic Modulation of O-GlcNAc

O-Linked β-N-acetylglucosamine (O-GlcNAc) is an essential, dynamic monosaccharide post-translational modification (PTM) found on serine and threonine residues of thousands of nucleocytoplasmic proteins. The installation and removal of O-GlcNAc is controlled by a single pair of enzymes, O-GlcNAc transferase (OGT) and O-GlcNAcase (OGA), respectively. Since its discovery four decades ago, O-GlcNAc has been found on diverse classes of proteins, playing important functional roles in many cellular processes. Dysregulation of O-GlcNAc homeostasis has been implicated in the pathogenesis of disease, including neurodegeneration, X-linked intellectual disability (XLID), cancer, diabetes, and immunological disorders. These foundational studies of O-GlcNAc in disease biology have motivated efforts to target O-GlcNAc therapeutically, with multiple clinical candidates under evaluation. In this review, we describe the characterization and biochemistry of OGT and OGA, cellular O-GlcNAc regulation, development of OGT and OGA inhibitors, O-GlcNAc in pathophysiology, clinical progress of O-GlcNAc modulators, and emerging opportunities for targeting O-GlcNAc. This comprehensive resource should motivate further study into O-GlcNAc function and inspire strategies for therapeutic modulation of O-GlcNAc.