DNA Methylation Modifications Research Articles

DNA Methylation and Transcriptome Profiling Reveal the Role of the Antioxidant Pathway and Lipid Metabolism in Plectropomus leopardus Skin Color Formation

Leopard coral grouper (Plectropomus leopardus), possessing a distinct red body color, is an important species in commercial markets; however, the high ratio of black individuals under intensive cultivation has limited the commercial value of the species. To dissect the regulatory mechanisms underlying the red skin trait in P. leopardus, gene expression and DNA methylation modifications were compared between red and black skin tissues after astaxanthin treatment. Astaxanthin effectively increased the redness value a* and body weight. Multi-omics analyses revealed the crucial roles of pathways related to antioxidants and lipid metabolism, particularly “Tyrosine metabolism”, “Melanogenesis”, “Fatty acid metabolism”, “Fatty acid elongation”, and “Biosynthesis of unsaturated acids”, in red skin coloration. A molecular network for the regulation of red skin coloration in P. leopardus was constructed, and pmel, tyr, tyrp1a, tyrp1b, dct, slc24a5, wnt1, acsl4, elovl1, elovl6l.1, elovl6l.2, and elovl7 were identified as key genes. Notably, pmel, acsl4, and elovl7 were negatively regulated by differential DNA methylation. Our results provide new insight into the molecular and epigenetic mechanisms of body color variation, representing a significant step towards breeding for the red skin trait in P. leopardus.

Glyphosate-Based Herbicide Stress During Pregnancy Impairs Intestinal Development in Newborn Piglets by Modifying DNA Methylation.

Glyphosate-based herbicide (GBH), a feed contaminant, has been proven to impair the growth and development of humans and animals. Previous research has revealed that maternal toxin exposure during pregnancy could cause permanent fetal changes by epigenetic modulation. However, there was insufficient evidence of the involvement of DNA methylation in maternal GBH exposure-induced intestinal health of offspring. Here, we established pregnant sow exposure models to investigate the effects of GBH on the intestinal DNA methylation of newborn piglets. The results showed gestational exposure to GBH compromises the intestinal function of newborn piglets as well as decreases the mRNA expression of Dnmt1 and Dnmt3b jejunum. Further RRBS DNA methylation analysis revealed genomic hypomethylation in jejunum, and the differentially methylated regions were enriched in the pathways of intestinal development and food digestion and the related GO terms. Additionally, integrative analysis of methylome and transcriptome identified 23 genes showing inverse correlations and indicated the underlying injury mechanisms upon maternal GBH. These findings provide new insights and fundamental knowledge into the possible involvement of DNA methylation in the intestinal injury of offspring induced by maternal GBH exposure during pregnancy, which drives manufacturers to develop low-toxicity herbicide to ensure food safety and human health.

Paternal inheritance mediated by epigenetic changes in sperms

Epigenetics is the link between the genome and environment, which can respond to physiological (such as age) or environmental factors (such as diet, stress, and pollution) and induce changes in epigenetic modifications (such as DNA methylation, non-coding RNA, and histone modifications). It can also serve as cellular memory transmitted from generation to generation. Sperm is highly responsive to such environmental changes and has unique epigenetic profiles. The paternal inter-/trans-generational inheritance mediated by sperm epigenetic changes is closely related to the health of offspring, which is an issue of great concern. This review has summarized the epigenetic mechanisms of paternal inter-/trans-generational inheritance and recent studies on the paternal inheritance mediated by sperm epigenetic changes in human and mice, which may facilitate understanding of the relationship between paternal epigenetic changes and the health of offspring caused by physiological or environmental changes and provide a basis for genetic counseling and clinical intervention.

The effect of exercise and physical activity on skeletal muscle epigenetics and metabolic adaptations.

Physical activity (PA) and exercise elicit adaptations and physiological responses in skeletal muscle, which are advantageous for preserving health and minimizing chronic illnesses. The complicated atmosphere of the exercise response can be attributed to hereditary and environmental variables. The primary cause of these adaptations and physiological responses is the transcriptional reactions that follow exercise, whether endurance- (ET) or resistance- training (RT). As a result, the essential metabolic and regulatory pathways and myogenic genes associated with skeletal muscle alter in response to acute and chronic exercise. Epigenetics is the study of the relationship between genetics and the environment. Exercise evokes signaling pathways that strongly alter myofiber metabolism and skeletal muscle physiological and contractile properties. Epigenetic modifications have recently come to light as essential regulators of exercise adaptations. Research has shown various epigenetic markers linked to PA and exercise. The most critical epigenetic alterations in gene transcription identified are DNA methylation and histone modifications, which are associated with the transcriptional response of skeletal muscle to exercise and facilitate the modification to exercise. Other changes in the epigenetic markers are starting to emerge as essential processes for gene transcription, including acetylation as a new epigenetic modification, mediated changes by methylation, phosphorylation, and micro-RNA (miRNA). This review briefly introduces PA and exercise and associated benefits, provides a summary of epigenetic modifications, and a fundamental review of skeletal muscle physiology. The objectives of this review are 1) to discuss exercise-induced adaptations related to epigenetics and 2) to examine the interaction between exercise metabolism and epigenetics.

Epigenetic therapeutics attenuate kidney injury and fibrosis by restoring the expression of epigenetically reprogrammed fibrogenic genes and signaling pathways

Kidney fibrosis is a commonly observed pathological condition during development of chronic kidney disease. Therapeutic options currently available are effective only in slowing the progression of kidney fibrosis and there is no cure for this disease. Aberrant expression and excessive accumulation of extracellular matrix (ECM) proteins in the peritubular space is a characteristic pathological feature of fibrotic kidney. However, the molecular basis of aberrant regulation of fibrotic genes in kidneys is not clear. In this context, this study aimed to evaluate the role of epigenetic reprogramming in kidney fibrosis. Folic acid (FA)-induced acute kidney injury (AKI) and kidney fibrosis in mice as an in vivo model and long-term arsenic or FA-exposed fibrogenic HK-2 cells as an in vitro model were used to evaluate the role of DNA methylation and histone modifications in fibrosis. DNA demethylating agent 5aza2 deoxycytidine (5-aza-2-dC) and histone deacetylase inhibitor Trichostatin A (TSA) were used to treat FA-injected mice. Results of histopathological and immunofluorescence staining of kidney tissue, serum albumin- creatinine levels, body weight, and gene expression analysis revealed significant protective effects of 5-aza-2-dC and TSA in FA-induced AKI and fibrosis. Insignificant change in the expression of N-cadherin whereas a significant decrease in E-cadherin as well as an increase in the expression of Vimentin and α-SMA suggest partial EMT associated with fibrosis. Aberrant expression of epithelial-mesenchymal-transition (EMT) and ECM-regulators (MMP2, Smad7, and TIMP3) as well as fibrogenic signaling pathways (Notch, TGF-beta, and Wnt signaling), and their restoration by 5-aza-2-dC and TSA treatments suggest epigenetic reprogramming of these genes and signaling pathways during FA-induced fibrosis. In summary, this study provides new information on the role of epigenetic reprogramming of fibrogenic genes and signaling pathways during the development of kidney fibrosis. Attenuation of fibrosis after 5-aza-2-dC and TSA treatments suggest the promise of these epigenetic-based therapeutics in the clinical management of this disease.

Using Callus as an Ex Vivo System for Chromatin Analysis.

Next-generation sequencing has revolutionized epigenetics research, enabling a comprehensive analysis of DNA methylation and histone modification profiles to explore complex biological systems at unprecedented depth. Deciphering the intricate epigenetic mechanisms that regulate gene activity presents significant challenges, including the issue of analyzing heterogeneous cell populations in bulk. Bulk analysis introduces bias and can obscure crucial information by averaging readouts from distinct cells. Various approaches have been developed to address this issue, such as cell-type-specific enrichment or single-cell sequencing techniques. However, the need for transgenic lines with fluorescent markers, along with technical challenges such as efficient protoplast isolation and low yield, limits their widespread adoption and use in multi-omic studies. This review discusses the pros and cons of these approaches, providing a valuable basis for selecting the most suitable strategy to minimize heterogeneity. We will also highlight the use of cotyledon-derived callus as an ex vivo system as a simple, accessible, and robust platform for enabling high-throughput multi-omic analyses.

Methylome analysis in long-lived men deciphers DNA methylation modifications associated with male longevity in humans.

Men, despite having a lower likelihood of longevity compared to women, generally exhibit better health status when they achieve longevity. The role of DNA methylation in this paradox remains unclear. We performed whole-genome bisulfite sequencing on long-lived men (LLMs), long-lived women (LLWs), younger men (YMs) and younger women (YWs) to explore specific methylation characteristics in LLMs. Despite an accelerated methylation aging rate in LLMs compared to LLWs, we identify thousands of differentially methylated genomic units (DMUs) in LLMs independent of age and sex. These DMUs, validated by an elastic net classifier, can serve as methylation markers for discriminating longevity potential in men. Many are located near health-related genes. Genes like PIWIL1 and EXT1, with promoters featuring DMUs, exemplify the potential role of LLM-specific methylation patterns in suppressing age-related diseases by regulating gene transcription. Our findings provide evidence of a distinct methylation feature contributing to healthy aging and longevity of LLMs.

Epigenetic Mechanisms of Endocrine-Disrupting Chemicals in Breast Cancer and Their Impact on Dietary Intake

Addressing the consequences of exposure to endocrine-disrupting chemicals (EDCs) demands thorough research and elucidation of the mechanism by which EDCs negatively impact women and lead to breast cancer (BC). Endocrine disruptors can affect major pathways through various means, including histone modifications, the erroneous expression of microRNA (miRNA), DNA methylation, and epigenetic modifications. However, it is still uncertain if the epigenetic modifications triggered by EDCs can help predict negative outcomes. Consequently, it is important to understand how different endocrine disrupters or signals interact with epigenetic modifications and regulate signalling mechanisms. This study proposes that the epigenome may be negatively impacted by several EDCs, such as cadmium, arsenic, lead, bisphenol A, phthalates, polychlorinated biphenyls and parabens, organochlorine, and dioxins. Further, this study also examines the impact of EDCs on lifestyle variables. In breast cancer research, it is essential to consider the potential impacts of EDC exposure and comprehend how EDCs function in tissues.

Gut microbiome-gut brain axis-depression: interconnection.

The relationship between the gut microbiome and mental health, particularly depression, has gained significant attention. This review explores the connection between microbial metabolites, dysbiosis, and depression. The gut microbiome, comprising diverse microorganisms, maintains physiological balance and influences health through the gut-brain axis, a communication pathway between the gut and the central nervous system. Dysbiosis, an imbalance in the gut microbiome, disrupts this axis and worsens depressive symptoms. Factors like diet, antibiotics, and lifestyle can cause this imbalance, leading to changes in microbial composition, metabolism, and immune responses. This imbalance can induce inflammation, disrupt neurotransmitter regulation, and affect hormonal and epigenetic processes, all linked to depression. Microbial metabolites, such as short-chain fatty acids and neurotransmitters, are key to gut-brain communication, influencing immune regulation and mood. The altered production of these metabolites is associated with depression. While progress has been made in understanding the gut-brain axis, more research is needed to clarify causative relationships and develop new treatments. The emerging field of psychobiotics and microbiome-targeted therapies shows promise for innovative depression treatments by harnessing the gut microbiome's potential. Epigenetic mechanisms, including DNA methylation and histone modifications, are crucial in how the gut microbiota impacts mental health. Understanding these mechanisms offers new prospects for preventing and treating depression through the gut-brain axis.

The Development of Prenatal Muscle Satellite Cells (MuSCs) and Their Epigenetic Modifications During Skeletal Muscle Development in Yak Fetus.

To investigate prenatal muscle satellite cell (MuSC) development and the associated epigenetic modifications in yak. Here, we conducted morphological and protein co-localization analyses of fetal longissimus dorsi muscle at various developmental stages using histology and immunofluorescence staining methods. Our study observed that primary muscle fibers began forming at 40 days of gestation, fully developed by 11 weeks, and secondary muscle fibers were predominantly formed by around 105 days. Throughout development, MuSCs were mainly located between the muscle fiber membrane and the basement membrane, acting as a reserve for the stem cell pool. MuSCs appeared within myotubes only during critical phases of primary and secondary muscle fiber formation. The proliferation of MuSCs gradually decreases until birth. MuSCs with 5mC modification show a trend of increasing first and then decreasing. MuSCs with 5hmC modification also present a dynamic change trend. The 41st day and 11th week are the critical periods for the changes of both. From the 11th week to around the 110th day of gestation, the modification effect of histone H3K4me3 is crucial for MuSCs during the development of the fetal longissimus dorsi muscle. Combined, our data identify key time points for yak fetal skeletal muscle growth and development and demonstrate that DNA methylation and histone modifications in MuSCs are closely related to this process, offering a valuable basis for future research into the molecular mechanisms underlying yak muscle development.

The epigenetic impact of fatty acids as DNA methylation modulators.

DNA methylation is a key epigenetic mechanism that regulates gene expression. Fatty acids, the building blocks of many essential lipids, play a crucial role in various biological events. Aberrant acetylation and methylation profiles are linked to a number of non-communicable diseases. Various fatty acids have been identified as potential 'epi-drugs' because of their ability to correct aberrant acetylation and methylation profiles in a number of non-communicable diseases, enhancing the value of their biochemical properties. This review summarizes the effects of selected saturated and unsaturated fatty acids and fatty-acid-rich food items on disease-associated DNA methylation profiles, aiming to justify the classification of fatty acids as DNA methylation modulators.

Targeting Epigenetic Dysregulations in Head and Neck Squamous Cell Carcinoma.

Head and neck squamous cell carcinoma (HNSCC) is one of the deadliest human cancers, with the overall 5-year survival rate stagnating in recent decades due to the lack of innovative treatment approaches. Apart from the recently Food and Drug Administration-approved epidermal growth factor receptor inhibitor and immune checkpoint inhibitor, alternative therapeutic strategies that target epigenetic abnormalities, an emerging cancer hallmark, remain to be fully explored. A pathological epigenetic landscape, characterized by widespread reprogramming of chromatin modifications such as DNA methylation and histone modifications, which drives transcription deregulation and genome reorganization, has been extensively documented in numerous cancers, including HNSCC. Growing evidence indicates that these frequent epigenomic alterations play pivotal roles in regulating malignant transformation, promoting metastasis and invasion, and reshaping the tumor microenvironment. Furthermore, these epigenetic changes also present unique vulnerabilities that open new avenues for identifying novel prognostic biomarkers and developing targeted antitumor therapies. In this review, we summarize recent discoveries of epigenetic dysregulations in HNSCC, with a focus on deregulated chromatin modifications, which include aberrant DNA methylation, oncohistone H3 lysine 36 to methionine (H3K36M) mutation, as well as recurrent mutations or altered expression of chromatin-modifying enzymes such as NSD1, EZH2, and KMT2C/D. Importantly, we discuss the various molecular mechanisms underlying the contributions of these epigenetic alterations to HNSCC development, particularly their involvement in deregulated cell proliferation and cell death, metabolic reprogramming, tumor immune evasion, and phenotypic plasticity. Finally, we conclude by highlighting the translational and clinical implications of targeting the epigenetic machinery, which offers promising prospects for overcoming resistance to conventional radiotherapy/chemotherapy and enhancing the response to immunotherapy in HNSCC.

Angiotensin receptor blockers modulate the lupus CD4+ T cell epigenome characterized by TNF family-linked signaling.

In systemic lupus erythematosus (lupus), environmental effects acting within a permissive genetic background lead to autoimmune dysregulation. Dysfunction of CD4+ T cells contributes to pathology by providing help to autoreactive B and T cells, and CD4+ T cell dysfunction coincides with altered DNA methylation and histone modifications of select gene loci. However, chromatin accessibility states of distinct T cell subsets and mechanisms driving heterogeneous chromatin states across patients remain poorly understood. We defined the transcriptome and epigenome of multiple CD4+ T cell populations from lupus patients and healthy individuals. Most lupus patients, regardless of disease activity, had enhanced chromatin accessibility bearing hallmarks of inflammatory cytokine signals. Single cell approaches revealed that chromatin changes extended to naive CD4+ T cells; uniformly affecting naive subpopulations. Transcriptional data and cellular and protein analyses suggested that the TNF family members, TNFɑ, LIGHT, and TWEAK, were linked to observed molecular changes and the altered lupus chromatin state. However, we identified a patient subgroup prescribed angiotensin receptor blockers (ARBs) which lacked TNF-linked lupus chromatin accessibility features. These data raise questions about the role of lupus-associated chromatin changes in naive CD4+ T cell activation and differentiation and implicate ARBs in the regulation of disease-driven epigenetic states.

Epigenetic Mechanisms in Aging: Extrinsic Factors and Gut Microbiome.

Aging is a natural physiological process involving biological and genetic pathways. Growing evidence suggests that alterations in the epigenome during aging result in transcriptional changes, which play a significant role in the onset of age-related diseases, including cancer, cardiovascular disease, diabetes, and neurodegenerative disorders. For this reason, the epigenetic alterations in aging and age-related diseases have been reviewed, and the major extrinsic factors influencing these epigenetic alterations have been identified. In addition, the role of the gut microbiome and its metabolites as epigenetic modifiers has been addressed. Long-term exposure to extrinsic factors such as air pollution, diet, drug use, environmental chemicals, microbial infections, physical activity, radiation, and stress provoke epigenetic changes in the host through several endocrine and immune pathways, potentially accelerating the aging process. Diverse studies have reported that the gut microbiome plays a critical role in regulating brain cell functions through DNA methylation and histone modifications. The interaction between genes and the gut microbiome serves as a source of adaptive variation, contributing to phenotypic plasticity. However, the molecular mechanisms and signaling pathways driving this process are still not fully understood. Extrinsic factors are potential inducers of epigenetic alterations, which may have important implications for longevity. The gut microbiome serves as an epigenetic effector influencing host gene expression through histone and DNA modifications, while bidirectional interactions with the host and the underexplored roles of microbial metabolites and non-bacterial microorganisms such as fungi and viruses highlight the need for further research.

Progress Toward Epigenetic Targeted Therapies for Childhood Cancer.

Among the most significant discoveries from cancer genomics efforts has been the critical role of epigenetic dysregulation in cancer development and progression. Studies across diverse cancer types have revealed frequent mutations in genes encoding epigenetic regulators, alterations in DNA methylation and histone modifications, and a dramatic reorganization of chromatin structure. Epigenetic changes are especially relevant to pediatric cancers, which are often characterized by a low rate of genetic mutations. The inherent reversibility of epigenetic lesions has led to an intense interest in the development of epigenetic targeted therapies. Additionally, the recent appreciation of the interplay between the epigenome and immune regulation has sparked interest in combination therapies and synergistic immunotherapy approaches. Further, the recent appreciation of epigenetic variability as a driving force in cancer evolution has suggested new roles for epigenetic therapies in limiting plasticity and resistance. Here, we review recent progress and emerging directions in the development of epigenetic targeted therapeutics and their promise across the landscape of childhood cancers.

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

Abstract 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.

Epigenetic reprogramming, germline and genomic imprinting

The memory of cellular identity is crucial for the correct development of an individual and is maintained throughout life by the epigenome. Chromatin marks, such as DNA methylation and histone modifications, ensure the stability of gene expression programmes over time and through cell division. Loss of these marks can lead to severe pathologies, including cancer and developmental syndromes. However, reprogramming of cellular identity is also a natural phenomenon that occurs early in mammalian development, particularly in the germ line, which enables the production of mature and functional gametes. The germ line transmits genetic and epigenetic information to the next generation, contributing to the survival of the species. Primordial germ cells (PGCs) undergo extensive chromatin remodelling, including global DNA demethylation and erasure of the parental imprints. This review introduces the concept of epigenetic reprogramming, its discovery and key steps, as well as the transcriptional and chromatin changes that accompany germ cell formation in mice. Finally, we discuss the epigenetic mechanisms of genomic imprinting, its discovery, regulation and relevance to human disease.

Methylation of SHOX-2, DAPK1, RAR-beta, and Mir-375 genes in hydrothorax in patients with nephrotic syndrome

Nephrotic syndrome is characterized by clinical manifestations, including proteinuria, hypoalbuminemia, hyperlipidemia, and edema. Hydrothorax is a rare but serious complication caused by enhanced fluid exudation due to hypoalbuminemia and changes in capillary permeability. In this study, the methylation of the SHOX-2, DAPK1, RAR-beta, and mir-37 genes was assessed in 35 patients with nephrotic syndrome and hydrothorax using DNA extracted from pleural fluid and urine. Methylation was determined using real-time PCR. The PCR results showed no methylation of SHOX-2, RAR-beta, DAPK1, or Mir-375. The amplification curves show an exponential increase in the signal and a stable plateau, indicating successful DNA amplification. The absence of methylation confirmed the high specificity of the method for detecting unmethylated sequences. These results highlight the need for further research to understand the epigenetic mechanisms of gene expression and to develop new therapeutic approaches aimed at modulating DNA methylation and restoring normal gene regulation.

LINE-1 hypomethylation characterizes the inflammatory response in coeliac disease associated-intestinal mucosa and small bowel adenocarcinomas.

Long interspersed nuclear elements 1 (LINE-1) are the most abundant and the only autonomous mobile elements in the human genome. When their epigenetic repression is removed, it can lead to disease, such as autoimmune diseases and cancer. Coeliac disease (CeD) is an immune-mediated disease triggered by an abnormal T-cell response to dietary gluten and a predisposing condition of small bowel adenocarcinoma (SBA), frequently characterized by epigenetic alterations. The aim of this work was to assess LINE-1 methylation by bisulphite pyrosequencing and NanoString® gene transcription analysis in 38 CeD-SBAs compared with 25 SBAs associated with Crohn's disease (CrD-SBAs) and 25 sporadic SBAs (S-SBA). Both analyses were also performed in duodenal mucosae from 12 untreated CeD patients (UCD) and 19 treated CeD patients (TCD), and in 11 samples of normal intestinal mucosa to better investigate the role of LINE-1 deregulation in CeD and in CeD-SBA. A significant loss of LINE-1 methylation was observed in CeD-SBAs and in mucosae from UCD patients (with very similar methylation levels) compared with controls. By contrast, a restoration of normal LINE-1 methylation levels was found in TCD mucosae after a strict gluten-free diet. LINE-1 hypomethylation does not lead to expression of ORF1 and ORF2, with the only exception being for one CeD-SBA. The expression analysis of enzymes modulating DNA methylation and inflammatory genes confirmed that CeD-SBA shared a very similar expression profile of UCD mucosae showing a strong upregulation of genes involved in inflammation, immune response, and T-cell activity compared with TCD mucosae. For the first time, this work demonstrates that loss of DNA methylation is an intrinsic epigenetic feature of CeD, accompanying the immune response as a reversible mechanism in patients following a strict gluten-free diet, and suggests the possible role of LINE-1 hypomethylation in promoting cell adaptability during the gliadin-related inflammatory process. © 2024 The Author(s). The Journal of Pathology published by John Wiley & Sons Ltd on behalf of The Pathological Society of Great Britain and Ireland.

Epigenetic regulation and memories

This article summarizes the current understanding of epigenetic regulation in grapevines, emphasising their significance in a clonally propagated plant with limited genetic diversity. Key epigenetic processes, including DNA methylation and histone modifications, shape chromatin structure, influencing gene expression. The grapevine leaf methylome reveals similarities with other clonally propagated plants, emphasizing low methylation levels in specific contexts. Epigenetic regulation contributes to grapevine phenotypic plasticity, clonal diversity, and an intriguing dialogue between grafted partners. These mechanisms form a vital part of plant memory, especially in the face of climate change. Despite the potential resetting during plant regeneration, recent evidence suggests the persistence of parental epigenetic imprints in progeny. Understanding how environmental conditions affect epigenetic imprints in grapevine clones is crucial. In Uruguay, where the wine industry faces climate challenges, Tannat stands as an emblematic variety adapted for our environmental production systems. However, climate change predictions in the region include rising temperatures, altered precipitation patterns, and increased extreme events, which could impact some aspects of its adaptation (yields, berry quality and typicity, among others). Vineyard management strategies, along with plant breeding, are essential for adaptation. Adding epigenetic diversity for breeding strategies enhances adaptability, contributing to sustainable viticulture in the face of climate change. The article calls for urgently developing innovative strategies utilizing heritable epigenetic variations, presenting a faster and more efficient approach to grapevine breeding for stress tolerance in the era of climate change.