geneimprint : Hot off the Press

'; ?> geneimprint : Hot off the Press http://www.geneimprint.com/site/hot-off-the-press Daily listing of the most recent articles in epigenetics and imprinting, collected from the PubMed database. en-us Sat, 21 Mar 2026 07:57:57 EDT Sat, 21 Mar 2026 07:57:57 EDT jirtle@radonc.duke.edu james001@jirtle.com Emerging multi-omics biomarkers in glioblastoma: Integrative insights from genomics to metabolomics. Kakde GS, Dakal TC, Maurya PK
Biochim Biophys Acta Rev Cancer (Apr 2026)

Glioblastoma (GBM) is the most malignant form of primary brain tumor in adults, described by profound molecular heterogeneity, rapid progression, and limited therapeutic response. Despite advances in chemotherapy (TMZ), radiotherapy, and surgery, patient outcomes remain poor, with a median survival of 12-15Â months. Traditional single-omics studies have identified critical biomarkers such as IDH mutations, MGMT promoter methylation, and EGFR alterations; however, these provide only partial insight into the disease's complexity. Recent integrative multi-omics approaches encompassing genomics, transcriptomics, epigenomics, proteomics, metabolomics, and non-coding RNAs have transformed the landscape of biomarker discovery in GBM. Genomic profiling has revealed recurrent mutations and subtype-specific aberrations, while transcriptomic analyses refine molecular classification and uncover alternative splicing and fusion events. Epigenomic markers, particularly MGMT methylation and G-CIMP status, are now central to prognosis and therapy stratification. Proteomic and metabolomic studies highlight dysregulated pathways, metabolic vulnerabilities, and non-invasive biomarkers in cerebrospinal fluid and plasma. Integrating multi-omics data not only improves diagnostic and prognostic accuracy but also unveils therapeutic targets, offering opportunities for precision oncology. Furthermore, liquid biopsy and single-cell/spatial omics enhance real-time monitoring of disease progression and treatment response, addressing challenges posed by intratumoral heterogeneity. This review synthesizes recent advances in GBM biomarker research across multiple omics layers, emphasizing their complementary roles in unravelling tumor biology, guiding personalized treatment, and shaping future therapeutic strategies.]]> Wed, 31 Dec 1969 19:00:00 EST Rising Star: Single Cell Omics Technologies: When Whole Omics Analysis Meets Single Cell Resolution. Tang F
J Mol Biol (Apr 2026)

I got my PhD degree under the supervision of Prof. Kegang Shang in 2003. And I did my postdoc research in Azim Surani's lab. Then I set up my own lab in Biomedical Pioneering Innovation Center at Peking University in 2010. My research has focused on developing single-cell omics sequencing technologies and employing these powerful tools to dissect the gene regulation networks in human germline cell development under both physiological and pathological conditions. My lab systematically developed a serial of single-cell omics sequencing technologies, including the first single-cell DNA methylome sequencing technology in 2013, which was considered to pioneer the single-cell epigenome field. In recent years, my lab has focused on developing single-cell omics long-read sequencing technologies based on single-molecule sequencing platforms, which can reveal critical features of the repetitive elements. The repetitive elements are considered as 'dark matter', which account for over half of our genome and play important roles for both normal development and numerous diseases. The research in my lab revealed critical features of the epigenetic reprogramming of human germline cells, deepening our understanding of these cells, which are fundamental to the transgenerational immortality of the human species.]]> Wed, 31 Dec 1969 19:00:00 EST Interactions between nutrition and the epigenome: how can it be harnessed for public health? Anastasopoulou M, Dereki I, Sgourou A, Lagoumintzis G
Future Sci OA (Dec 2026)

A substantial body of evidence shows that dietary habits influence gene expression and epigenetic processes, holding significant implications for public health policies. Epigenetic modifications are increasingly associated with metabolic state, disease risk, and biological aging. Translating mechanistic results into scalable, efficient nutritional epigenetics treatments is difficult.]]> Wed, 31 Dec 1969 19:00:00 EST Molecular Interplay of Gene Network Dynamics, Epigenetic Regulation, and Therapeutic Mapping in Cardiovascular Disease. Akanda MR, Sabuj MSS, Salam SMA, Jahan E
Cardiovasc Drugs Ther (Apr 2026)

Cardiovascular diseases (CVDs) continue to be the leading cause of death globally, driven by a complex interplay of genetic, epigenetic, and environmental factors. Traditional risk factors alone fail to explain the individual variability in disease susceptibility and progression. Recent advances in genomics and epigenomics have revealed key molecular mechanisms that regulate cardiovascular function, highlighting the importance of gene network dynamics and epigenetic regulation.]]> Wed, 31 Dec 1969 19:00:00 EST Melatonin-enabled omics: understanding plant responses to single and combined abiotic stresses for climate-smart agriculture. Raza A, Li Y, Charagh S, Guo C, Zhao M, Hu Z
GM Crops Food (Dec 2026)

Climate change-driven single and combined abiotic stresses pose escalating threats to sustainable, climate-smart agriculture and global food security. Melatonin (MLT, a powerful plant biostimulant) has established noteworthy potential in improving stress tolerance by regulating diverse physiological, biochemical, and molecular responses. Therefore, this review delivers a comprehensive synopsis of MLT-enabled omics responses across genomics, transcriptomics, proteomics, metabolomics, miRNAomics, epigenomics, phenomics, ionomics, and microbiomics levels that collectively regulate plant adaptation to multiple abiotic stresses. We also highlight the crosstalk between these omics layers and the power of integrated multi-omics (panomics) approaches to harness the complex regulatory networks underlying MLT-enabled stress tolerance. Lastly, we argue for translating these omics insights into actionable strategies through advanced genetic engineering and synthetic biology platforms to develop MLT-enabled, stress-smart crop plants.]]> Wed, 31 Dec 1969 19:00:00 EST Artificial intelligence and multi-omics convergence in breast cancer: Revolutionizing diagnosis, prognostication, and precision oncology. Jiang B, Wu Y, Chen X, Jian C, Wang W
Crit Rev Oncol Hematol (Apr 2026)

Breast cancer (BC) is a highly heterogeneous malignancy and remains a major cause of cancer-related mortality among women worldwide. Advances in multi-omics profiling spanning genomics, transcriptomics, epigenomics, proteomics, and metabolomics have enabled finer subtype stratification and more comprehensive characterisation of tumour biology, thereby accelerating the discovery of diagnostic and prognostic biomarkers and actionable therapeutic targets. Nonetheless, translating multi-layer molecular signals into clinically robust decision support remains challenging because of the high dimensionality and heterogeneity of omics data, cross-cohort and cross-platform variability, and the fragmentation inherent to single-modality analyses. This review summarises how multi-omics studies have refined BC subtype definitions and advanced biomarker and target identification, and then synthesises recent progress in artificial intelligence, particularly deep learning, for integrating multi-omics with imaging, pathology, and clinical variables to improve diagnosis, risk stratification, prognosis prediction, and treatment response assessment. We critically examine representative multimodal integration frameworks and emerging deep learning architectures that learn both shared and modality-specific representations, which in many settings enable more accurate patient-level prediction than unimodal baselines. We further delineate key barriers to clinical translation, including cross-centre heterogeneity and inconsistent endpoint definitions, structural missingness of modalities in real-world workflows, inadequate cross-platform normalisation, limited interpretability and auditability, and a lack of prospective validation. Finally, we propose realistic next steps, including standardised and auditable preprocessing pipelines, missingness-aware fusion strategies, explainable and uncertainty-aware modelling, privacy-preserving multi-centre learning, and prospective, workflow-based evaluation. Collectively, these perspectives provide a roadmap for advancing multimodal AI-multi-omics integration toward reliable clinical deployment in BC management.]]> Wed, 31 Dec 1969 19:00:00 EST A cell type enrichment analysis tool for brain DNA methylation data (CEAM). MÃ¼ller J, Laroche VT, Imm J, Weymouth L, Harvey J, Reijnders RA, Smith AR, van den Hove D, Lunnon K, Cavill R, Pishva E
Epigenetics (Dec 2026)

DNA methylation (DNAm) signatures are highly cell type-specific, yet most epigenome-wide association studies (EWAS) are performed on bulk tissue, potentially obscuring critical cell type-specific patterns. Existing computational tools for detecting cell type-specific DNAm changes are often limited by the accuracy of cell type deconvolution algorithms. Here, we introduce CEAM (Cell-type Enrichment Analysis for Methylation), a robust and interpretable framework for cell type enrichment analysis in DNA methylation data. CEAM applies over-representation analysis with cell type-specific CpG panels from Illumina EPIC arrays derived from nuclei-sorted cortical post-mortem brains from neurologically healthy aged individuals. The constructed CpG panels were systematically evaluated using both simulated datasets and published EWAS results from Alzheimer's disease, Lewy body disease, and multiple sclerosis. CEAM demonstrated resilience to shifts in cell type composition, a common confounder in EWAS, and remained robust across a wide range of differentially methylated positions, when upstream modeling of cell type composition was modeled with sufficient accuracy. Application to existing EWAS findings generated in neurodegenerative diseases revealed enrichment patterns concordant with established disease biology, confirming CEAM's biological relevance. The workflow is publicly available as an interactive Shiny app (https://um-dementia-systems-biology.shinyapps.io/CEAM/) enabling rapid, interpretable analysis of cell type-specific DNAm changes from bulk EWAS.]]> Wed, 31 Dec 1969 19:00:00 EST Portrait of a Spectrum: Clinical and Genetic Characterization of a Large Cohort of Chromatinopathies-30âYears' Experience From a Third Level Center. Marchetti GB, Rosina E, Meossi C, Mura M, Pezzani L, Selicorni A, Bedeschi MF, Tenconi R, Agostoni C, Finelli P, De Matteis S, Di Fede E, Massa V, Pezzoli L, Gervasini C, Iascone M, Milani D
Clin Genet (Apr 2026)

Chromatinopathies (CPs) are an expanding group of rare genetic disorders affecting epigenetic machinery. Besides an intricate genotypic spectrum, these conditions share overlapping phenotypes characterized by neurocognitive impairment, growth defects and distinctive, but often convergent, facial features. Although individually rare, the landscape of CPs is increasingly growing and represents an emerging and possibly underestimated cause of disability. Due to their complexity and rarity, accurate diagnosis and management pose significant difficulties. To address these challenges and gain a deeper overview of these diseases' spectrum, we retrospectively collected clinical characteristics of 239 patients diagnosed with CPs and critically analyzed their diagnostic journey, growth charts, neurological and gestaltic features. Starting from the largest collection of CPs to date, our data point to wide sequencing analyses as the best shortcut to diagnosis. We have also demonstrated the importance of growth defects in this group of disorders that require dedicated growth tables, and we have delved into the great variability of neurological and clinical burden in these conditions. This retrospective study provides a significant advance in our understanding of these rare diseases and will help to improve diagnostic, therapeutic, and clinical approaches to CPs and to develop personalized multidisciplinary care plans for affected patients.]]> Wed, 31 Dec 1969 19:00:00 EST Long noncoding RNA H19 in liver development and disease. Montoya-Durango DE, Gobejishvili L
Cell Signal (Jun 2026)

Liver disease is a global health problem responsible for more than two million deaths annually. Metabolic dysfunction-associated steatotic liver disease (MASLD) and alcohol-associated liver disease (ALD) are major contributors to chronic liver disease-related morbidity and mortality. Factors like diet and alcohol consumption have become key drivers of liver pathologies including steatosis, fibrosis/cirrhosis, and hepatocellular carcinoma. To date very few treatments are available, hence there is a critical need for the development of novel therapies to slow down the development/progression of liver damage. The long non-coding RNA H19 gene, H19, is an imprinted gene normally expressed from the maternally inherited chromosome and epigenetically silenced in the paternal chromosome. At the embryo stage H19 controls genome-wide methylation, directs the methylation of the imprinted gene network, and regulates organ size. In the livers of neonates, H19 is important for organ maturation but remains silent in the mature organ. H19 re-expression in the adult liver drives de novo lipogenesis and fibrosis and maintains a proliferative state in tumor cells. The complexity of H19 functions in the liver is reflected in its interaction and regulation of a growing number of proteins, and coding and non-coding RNAs involved in metabolism, pro-fibrotic gene networks, cell cycle progression, and chromatin regulation. This review summarizes the findings related to the role of H19 in liver development and in diseases such as fatty liver, fibrosis, and hepatocellular carcinoma.]]> Wed, 31 Dec 1969 19:00:00 EST Global analyses of genomic and epigenomic influences on gene expression reveal as a major regulator of cardiac gene expression in response to catecholamine challenge during heart failure. Lahue C, Ravindran S, Dalal A, Avetisyan R, Rau CD
Epigenetics (Dec 2026)

Heart failure arises from maladaptive remodelling driven by genetic and epigenetic networks. Using a systems genetics framework, we mapped how DNA variants and CpG methylation shape cardiac transcriptomes during beta adrenergic stress in the Hybrid Mouse Diversity Panel, a cohort of over 100 fully inbred mouse strains. Expression QTLs (eQTLs), methylation QTLs (mQTLs) and methylation-driven eQTLs (emQTLs) were generated from over 13k expressed genes and 200k hypervariable CpGs in left ventricles. We discovered hundreds of regulatory 'hotspots' that control large portions of the genome, including several that regulate over 10% of the transcriptome and/or methylome. Approximately 16% of these hotspots overlapped with prior GWAS or EWAS signals. We focus on a hotspot on chromosome 12 and identify the serpine peptidase inhibitor , as the most likely driver gene in this hotspot. Experimental knockdown of in neonatal rat ventricular cardiomyocytes blunted hypertrophy induced by a variety of hypertrophic signals, while altering predicted target expression and modulating the activity of and . Together, these findings position as a major regulator of stress-responsive cardiac gene programs, highlighting how integration of genetic and epigenetic signals can pinpoint key drivers of heart failure.]]> Wed, 31 Dec 1969 19:00:00 EST Limitations and opportunities in multi-omics integration for neurodevelopmental, neurodegenerative and psychiatric disorders: A systematic review. Behrens LMP, Fernandes GDS, GonÃ§alves GF, Nunes FVM, Weimer RD, Moreira JCF, Dorn M
Neuroscience (Apr 2026)

Recent advances in high-throughput technologies have led to an increased generation of biological data across genomics, transcriptomics, proteomics, epigenomics, and metabolomics. However, a major challenge remains: effectively integrating these multi-omics datasets to allow a more holistic understanding of the complex, interconnected mechanisms underlying human diseases. Neurodevelopmental, neurodegenerative, and psychiatric disorders are particularly multifactorial and heterogeneous, making them candidates for multi-omics approaches. In this context, this systematic review assesses the current state of multi-omics integration in neurological research. Records retrieved from five major databases were processed, and 156 studies were included for further analysis. The most frequently studied conditions were Alzheimer's Disease, Depressive Disorder and Parkinson's Disease, with epigenomics-transcriptomics and metagenomics-metabolomics emerging as the most common omics pairings. The field remains dominated by studies integrating pairs of omics layers. Only a limited number of computational tools are currently being applied to the integration of more than two omics layers, highlighting a gap in comprehensive multi-omics modeling. Despite progress, key challenges persist, including data accessibility and the need for standardized frameworks to allow cross-study comparisons. Moreover, most computational findings lack experimental validation in wet-laboratory settings. Future research should address these challenges, develop scalable algorithms for integrating multi-omics data, and leverage large, open-access datasets. Integrating computational predictions with experimental validation could help researchers prioritize high-confidence biomarkers relevant to clinical applications. Collaborative efforts among bioinformaticians, clinicians, and experimentalists will be essential to translating these advances into clinically actionable solutions.]]> Wed, 31 Dec 1969 19:00:00 EST DNA methylation-mediated alterations in Copper(I/II) redox equilibrium underlie lead-induced neurotoxicity. Hu J, Wang WX
Environ Pollut (Apr 2026)

Lead (Pb), a ubiquitous environmental toxin, poses significant risks to central nervous system health, primarily by disrupting essential metal homeostasis in the brain. While epigenetic regulation and proteomic expression are significantly affected by Pb, its specific molecular impact on copper (Cu) redox states remains poorly understood. This study systematically investigated the molecular mechanisms underlying Pb-induced neurotoxicity in SH-SY5Y cells through integrated epigenomics and proteomics analysis. DNA methylation analysis revealed 141,357 differentially methylated regions (DMRs), primarily in CpG sites, with 62.6Â % hypermethylated and 37.4Â % hypomethylated. These DMRs were enriched in genes associated with critical processes such as metal ion binding, cell cycle regulation, and nervous system development. Promoter-specific methylation changes were notably pronounced, impacting pathways linked to neurodegenerative diseases, including Alzheimer's disease. Proteomic analysis identified 740 differentially expressed proteins (DEPs), with 366 upregulated and 374 downregulated in Pb-treated cells. Functional annotation revealed significant enrichment of DEPs in mitochondria, where Pb exposure disrupted processes related to oxidative phosphorylation, ion transport, and transmembrane processes. These proteomic changes aligned with the observed epigenetic modifications, reinforcing the role of Pb in impairing neuronal function via its effects on cellular energy metabolism and metal ion dynamics. Notably, Pb exposure disrupted Cu redox transitions between Cu(I) and Cu(II) as well as glutathione (GSH) activity, underscoring its impact on cellular metal homeostasis regulation and oxidative imbalance. In summary, this study provides a comprehensive view of how Pb exposure alters epigenetic and proteomic landscapes, disrupting key biological processes and pathways essential for neuronal health.]]> Wed, 31 Dec 1969 19:00:00 EST An Epigenetic Clock for Accurate Age Prediction in Atlantic Cod Populations for Improved Fisheries Management. Anastasiadi D, Kasmi Y, Stransky C, Casas L, Eschbach E, Piferrer F
Mol Ecol Resour (Apr 2026)

Fisheries management relies on accurate stock assessments, which in turn depend on precise age information. Recent molecular tools called 'epigenetic clocks' harness age-related DNA methylation changes to build accurate and precise age-prediction models. However, the influences of intrinsic and extrinsic factors on clock performance remain uncertain. In this study, we examined Atlantic cod aged 0 to 7âyears, sampled from various locations across the North Sea, and developed an epigenetic clock using DNA methylation data of 73 CpG sites from fin clips obtained by bisulfite restriction-site associated DNA sequencing (bis-RAD-seq). This clock predicted age with 97.5% accuracy and a precision of 2.8âmonths and generalised well in unseen data. Further, we addressed critical variables such as sex and maturity status, which are often overlooked, and we showed that clock performance was unaffected by sex-specific differences in growth, and it was lower in advanced sexually mature individuals, reflecting a slight bias towards younger fish. A key finding of our study is the discovery of a latitudinal cline in global DNA methylation patterns. We found that DNA methylation varied with latitude, despite the absence of genetic differences, while our clock maintained consistent performance across geographic locations. This resolves a major question regarding how generalizable epigenetic clocks are within the distribution of a species. Our clock demonstrates extensive applicability and enhanced practicality for real-world fisheries management. It provides accurate and precise age prediction for Atlantic cod irrespective of intrinsic differences or environmental influences associated with geographic locations.]]> Wed, 31 Dec 1969 19:00:00 EST : a computational suite for DNA methylation sequencing data analysis. Loyfer N, Rosenski J, Kaplan T
Life Sci Alliance (Apr 2026)

Next-generation methylation-aware sequencing of DNA sheds light on the fundamental role of methylation in cellular function in health and disease, increasing the number of covered CpG sites from hundreds of thousands in previous array-based approaches to tens of millions across the whole genome. While array-based approaches are limited to single-CpG resolution, next-generation sequencing allows for a more detailed, single-molecule fragment-level analysis; however, existing tools to fully use this capability are not yet well developed. Here, we present , an extensive computational suite tailored for methylation sequencing data. allows fast access and ultracompact anonymized representation of high-throughput methylome data, obtained through various library preparation and sequencing methods, with a custom epiread file format achieving a compression factor of over 100x from the input BAM file. In addition, contains state-of-the-art algorithms for genomic segmentation, biomarker identification, genetic and epigenetic data integration, and more. offers fragment-level analysis and informative visualizations, across multiple genomic regions and samples.]]> Wed, 31 Dec 1969 19:00:00 EST Introduction to the special issue on epigenetic regulation of chronic pain. Nackley AG
Pain Rep (Apr 2026)

This Special Issue features 6 articles from leaders in the field that elucidate novel epigenetic mechanisms regulating nociception, inflammation, responses to pharmacologic and integrative therapies, and pain disparities among racial/ethnic groups. Together, they highlight the expanding potential of epigenomics to inform mechanistic discovery, guide personalized pain therapeutics, and advance pain equity.]]> Wed, 31 Dec 1969 19:00:00 EST Synergistic integration of clinical and multi-omics data for early MCI diagnosis using an attention-based graph fusion network. Yu S, Zhao J, Ouyang J, Wang X, Kou P, Zhu K, Liu P
J Neurosci Methods (Apr 2026)

Mild cognitive impairment (MCI), a precursor to Alzheimer's disease (AD), requires precise early diagnosis. Single-omics approaches often miss disease complexity, motivating integrative and interpretable solutions.]]> Wed, 31 Dec 1969 19:00:00 EST Hyperglycaemia-induced metabolic stress and epigenetic imprinting in the inflammatory pathogenesis of diabetic neuropathy. Razi FB, Ashraf H, Singhal S, Qamar Z, Moin S
Diabetes Res Clin Pract (Apr 2026)

Diabetic neuropathy (DN), a major microvascular complication of diabetes mellitus, results from a complex interplay among oxidative stress, inflammation, and persistent epigenetic modifications. Hyperglycemia-induced mitochondrial dysfunction increases reactive oxygen species (ROS), which activate redox-sensitive inflammatory cascades, including NF-ÎºB, JAK/STAT, and the NLRP3 inflammasome. These pathways amplify cytokine release and neuronal sensitisation, while reciprocal feedback between ROS and inflammation mediated by Nrf2 suppression further perpetuates nerve damage. Damage-associated molecular patterns (DAMPs), including HMGB1, S100A8/A9, mitochondrial DNA, and extracellular ATP, act as key amplifiers of neuroinflammation. By engaging receptors such as RAGE, Toll-like receptors (TLRs), and NOD-like receptors (NLRs), particularly NLRP3, these DAMPs trigger glial activation and nociceptive signalling, contributing to axonal degeneration and pain hypersensitivity in DN. Epigenetic dysregulation, including DNA methylation drift, histone modification imbalance, and aberrant non-coding RNA expression, constitutes a critical mechanism underlying metabolic memory, wherein prior hyperglycemic exposure leaves lasting molecular imprints. Persistent histone acetylation (H3K9ac), altered methylation (H3K4me1/Set7, H3K9me3/SUV39H1), and stable 5-methylcytosine patterns sustain inflammatory and oxidative pathways, even after glucose normalisation. Therapeutically, DNMT and HDAC inhibitors, miRNA modulators, and agents targeting RAGE/TLR4/NLRP3 pathways show promise in reversing these molecular imprints. Antioxidants and anti-inflammatory compounds with epigenetic effects further represent potential disease-modifying strategies. Future research must focus on longitudinal human studies, nerve-specific epigenomics, and multi-omics integration to enable personalised, mechanism-based therapy for DN. Understanding the interdependence of ROS, DAMPs, and epigenetic memory is key to breaking the cycle of chronic neuroinflammation and neuronal injury.]]> Wed, 31 Dec 1969 19:00:00 EST EnsembleAge: enhancing epigenetic age assessment with a multi-clock framework. Haghani A, Lu AT, Yan Q, Belmonte JCI, Reddy P, Cheng V, Yang XW, Wang N, Mozhui K, Murach K, Ocampo A, Williams RW, Jucker M, Bergmann C, Poganik JR, Zhang B, Gladyshev VN, Horvath S
Geroscience (Apr 2026)

Several widely used epigenetic clocks have been developed for mice and other species, but a persistent challenge remains: different mouse clocks often yield inconsistent results. To address this limitation in robustness, we present EnsembleAge, a suite of ensemble-based epigenetic clocks. Leveraging data from over 200 perturbation experiments across multiple tissues, EnsembleAge integrates predictions from multiple penalized models. Empirical evaluations demonstrate that EnsembleAge outperforms existing clocks in detecting both pro-aging and rejuvenating interventions. Furthermore, we introduce EnsembleAge HumanMouse, an extension that enables cross-species analyses, facilitating translational research between mouse models and human studies. Together, these advances underscore the potential of EnsembleAge as a robust tool for identifying and validating interventions that modulate biological aging.]]> Wed, 31 Dec 1969 19:00:00 EST Multi-omics biomarkers in psychiatric disorders diagnosis and stratification. Khatami SH, Anoosheh S, Khodaparast M, Maghsoudloonejad A, Dadgostar E, Asadi A, Kaveh M, Haghighi MM
Clin Chim Acta (Apr 2026)

The precise diagnosis and stratification of psychiatric disorders remain formidable challenges in modern medicine, hindered by the absence of objective biomarkers and reliance on subjective clinical criteria. Recent advances in multi-omics technologies, including genomics, transcriptomics, proteomics, metabolomics, and epigenomics, have revolutionized our understanding of complex neuropsychiatric conditions such as schizophrenia, bipolar disorder, major depressive disorder, and autism spectrum disorder. This review critically evaluates the current landscape of multi-omics research in psychiatry, highlighting methodological innovations, integrative strategies, and translational potential for biomarker discovery and clinical implementation. By synthesizing data across diverse molecular layers, multi-omics approaches enable a systems-level view of psychiatric disorders as multifactorial entities shaped by molecular, cellular, environmental, and neurocircuitry interactions. Despite promising advances in diagnostic accuracy and personalized treatment, significant barriers persist, including data heterogeneity, analytical complexity, and the translational gap between molecular signatures and clinical phenotypes. This review systematically explores the contributions of individual omics domains, emerging frameworks for multimodal data integration, the role of systems biology and network-based models, and the impact of large-scale consortia in driving clinical translation.]]> Wed, 31 Dec 1969 19:00:00 EST Polycomb repressive-deubiquitinase complex safeguards oocyte epigenome and female fertility by restraining Polycomb activity. Kang J, Liu P, Ichimura S, Cook L, Hu M, Namekawa SH, Chen Z
Nat Commun (Mar 2026)

Mouse oocytes exhibit a unique chromatin landscape characterized by broad H3K27ac and H3K27me3 domains, demarcating euchromatin and facultative heterochromatin, respectively. However, the mechanisms underlying this non-canonical landscape remain elusive. Here we report BAP1, a core component of the Polycomb Repressive-Deubiquitinase (PR-DUB) complex, as a key negative regulator of Polycomb activity during oogenesis. BAP1 restricts pervasive H2AK119ub1 accumulation and protects oocyte-specific broad H3K27ac, particularly within gene-poor regions, from ectopic H3K27me3 deposition. While PR-DUB has been linked to gene repression, in oocytes BAP1 primarily promotes transcription and contributes minimally to Polycomb-mediated silencing. BAP1-dependent transcriptional activation during oogenesis is essential for oocyte developmental competence, maternal-to-zygotic transition, and female fertility. Notably, ectopic H3K27me3 domains established in BAP1-deficient oocytes persist in preimplantation embryos but are resolved after implantation, and loss of maternal BAP1 does not impair either canonical or non-canonical genomic imprinting. Together, these findings reveal a critical role for PR-DUB in safeguarding the oocyte epigenome by protecting euchromatin from ectopic Polycomb activity, rather than enforcing transcriptional repression.]]> Wed, 31 Dec 1969 19:00:00 EST