Epigenetic Interactions Research Articles

Epigenetic regulation of macrophage function in kidney disease: New perspective on the interaction between epigenetics and immune modulation.

The interaction between renal intrinsic cells and macrophages plays a crucial role in the onset and progression of kidney diseases. In recent years, epigenetic mechanisms such as DNA methylation, histone modification, and non-coding RNA regulation have become essential windows for understanding these processes. This review focuses on how renal intrinsic cells (including tubular epithelial cells, podocytes, and endothelial cells), renal cancer cells, and mesenchymal stem cells influence the function and polarization status of macrophages through their own epigenetic alterations, and how the epigenetic regulation of macrophages themselves responds to kidney damage, thus participating in renal inflammation, fibrosis, and repair. Moreover, therapeutic studies targeting these epigenetic interaction mechanisms have found that the application of histone deacetylase inhibitors, histone methyltransferase inhibitors, various nanomaterials, and locked nucleic acids against non-coding RNA have positive effects on the treatment of multiple kidney diseases. This review summarizes the latest research advancements in these epigenetic regulatory mechanisms and therapies, providing a theoretical foundation for further elucidating the pathogenesis of kidney diseases and the development of novel therapeutic strategies.

MiR-204-5p and miR-130a-3p in Focus: Computational Breakthroughs in Understanding Hypertension Pathogenesis

Hypertension is a multifactorial disorder influenced by complex genetic and epigenetic interactions. Recent advancements in understanding the role of microRNAs (miRNAs) in regulating gene expression have provided new insights into the molecular mechanisms underlying hypertension. This study investigates the involvement of miRNAs in the pathophysiology of hypertension by analyzing gene expression profiles derived from multiple datasets obtained from NCBI and analyzed with GEOR. miR-DEGs were identified and subjected to the DAVID online tool for gene ontology study. BiBiServ2 was queried for miRNA/mRNA homology study. A total of 1,014 overlapping differentially expressed genes (DEGs) were identified across three datasets, revealing a significant dysregulation of the hypertensive transcriptome. The study further highlights the role of miRNAs, such as miR-29a-3p, miR-204-5p, miR-130a-3p, and miR-145-5p, in targeting these DEGs, with a predominant suppression of gene expression observed in hypertensive conditions. Functional enrichment analysis of miRNA-targeted DEGs revealed significant associations with key pathways involved in vascular remodeling, inflammation, and aldosterone regulation, including MAPK signaling, PI3K-Akt signaling, and the renin-angiotensin-aldosterone system (RAAS). Additionally, miRNA/gene homology studies demonstrated strong binding affinities between these miRNAs and genes involved in aldosterone synthesis, suggesting their pivotal role in modulating blood pressure regulation. The findings underscore the critical involvement of miRNAs in hypertension, proposing their potential as biomarkers and therapeutic targets for hypertension management. Future research should focus on validating these miRNA-targeted pathways and exploring miRNA-based therapeutics to restore homeostasis in hypertension.

Harnessing Demethylase-Regulated Catalytic DNA Circuit for In-Situ Investigation of the Regulatory Connection with MicroRNA.

Insight into the epigenetic modulation-correlated molecule interactions has significant implications for the in-depth understanding of intracellular intricate biological networks. However, there is currently a lack of reliable biological tools for elucidating the potential correlation between epigenetic regulators and relevant genes, e.g., microRNAs (miRNAs). Herein, an alkB homologue 5 (ALKBH5, a key epigenetic regulator)-modulated catalytic DNA circuit (ACD) was constructed by grafting a N6-methyladenosine (m6A)-caged I-R3 DNAzyme into the circuitry components for achieving the on-site miRNA imaging in living cells. Specifically, the catalytic activity of I-R3 DNAzyme could be effectively suppressed by the m6A modification situated at its highly sequence-conserved core region and then be selectively restored through the ALKBH5-mediated demethylation pathway. And the ALKBH5-activated I-R3 DNAzyme allowed the highly efficient DNA cleaving reaction in the presence of DNAzyme cofactors, resulting in the liberation of catalytic hairpin assembly (CHA) reactants. Subsequently, target miRNA triggered the CHA circuit to produce a duplex DNA product while releasing the miRNA analyte. The liberated miRNA could autonomously trigger the next round of the CHA assembly cycle for generating the amplified fluorescence readout. By virtue of the stimuli-responsive activation and the CHA amplification circuit, the ACD system achieved highly specific and sensitive imaging of miRNA in tumor cells. Moreover, this efficiently and reliably ALKBH5-activated DNA circuit is demonstrated to reveal the underlying relationship between activator ALKBH5 and miRNA. Overall, the developed ACD system provides a promising tool for the robust on-site profiling of epigenetic-involved signal pathways, thus displaying great potential in bioanalytical applications.

Dysbiosis-epigenetics-immune system interaction and ageing health problems.

Background. The growing interest in microbiota-epigenetics-immune system research stems from the understanding that microbiota, a group of micro-organisms colonized in the human body, can influence the gene expression through epigenetic mechanisms and interaction with the immune system. Epigenetics refers to changes in gene activity that are not caused by the alteration in the DNA sequence itself.Discussion. The clinical significance of this research lies in the potential to develop new therapies for diseases linked to the imbalance of these microbial species (dysbiosis), such as cancer and neurodegenerative diseases. The intricate interaction between microbiota and epigenetics involves the production of metabolites and signalling molecules that can impact our health by influencing immune responses, metabolism and inflammation. Understanding these interactions could lead to novel therapeutic strategies targeting microbiota-epigenetic pathways to improve health outcomes.Conclusion. In this context, we aim to review and emphasize the current knowledge and key concepts that link the microbiota to epigenetics and immune system function, exploring their relevance to the development and maintenance of homeostasis and susceptibility to different diseases later in life. We aim to elucidate key concepts concerning the interactions and potential effects among the human gut microbiota, epigenetics, the immune system and ageing diseases linked to dysbiosis.

Psoriasis and Seasonality: Exploring the Genetic and Epigenetic Interactions.

Psoriasis is a multifactorial, chronic, and inflammatory disease that severely impacts patients' quality of life. The disease is caused by genetic irregularities affected by epigenetic and environmental factors. Some of these factors may include seasonal changes, such as solar radiation, air pollution, and humidity, and changes in circadian rhythm, especially in the temporal and polar zones. Thus, some psoriasis patients report seasonal variability of symptoms. Through a comprehensive review, we aim to delve deeper into the intricate interplay between seasonality, environmental factors, and the genetic and epigenetic landscape of psoriasis. By elucidating these complex relationships, we strive to provide insights that may inform targeted interventions and personalized management strategies for individuals living with psoriasis.

High-throughput optimized prime editing mediated endogenous protein tagging for pooled imaging of protein localization.

The subcellular organization of proteins carries important information on cellular state and gene function, yet currently there are no technologies that enable accurate measurement of subcellular protein localizations at scale. Here we develop an approach for pooled endogenous protein tagging using prime editing, which coupled with an optical readout and sequencing, provides a snapshot of proteome organization in a manner akin to perturbation-based CRISPR screens. We constructed a pooled library of 17,280 pegRNAs designed to exhaustively tag 60 endogenous proteins spanning diverse localization patterns and explore a large space of genomic and pegRNA design parameters. Pooled measurements of tagging efficiency uncovered both genomic and pegRNA features associated with increased efficiency, including epigenetic states and interactions with transcription. We integrate pegRNA features into a computational model with predictive value for tagging efficiency to constrain the design space of pegRNAs for large-scale peptide knock-in. Lastly, we show that combining in-situ pegRNA sequencing with high-throughput deep learning image analysis, enables exploration of subcellular protein localization patterns for many proteins in parallel following a single pooled lentiviral transduction, setting the stage for scalable studies of proteome dynamics across cell types and environmental perturbations.

Genetic and Epigenetic Interactions Involved in Senescence of Stem Cells.

Cellular senescence is a permanent condition of cell cycle arrest caused by a progressive shortening of telomeres defined as replicative senescence. Stem cells may also undergo an accelerated senescence response known as premature senescence, distinct from telomere shortening, as a response to different stress agents. Various treatment protocols have been developed based on epigenetic changes in cells throughout senescence, using different drugs and antioxidants, senolytic vaccines, or the reprogramming of somatic senescent cells using Yamanaka factors. Even with all the recent advancements, it is still unknown how different epigenetic modifications interact with genetic profiles and how other factors such as microbiota physiological conditions, psychological states, and diet influence the interaction between genetic and epigenetic pathways. The aim of this review is to highlight the new epigenetic modifications that are involved in stem cell senescence. Here, we review recent senescence-related epigenetic alterations such as DNA methylation, chromatin remodeling, histone modification, RNA modification, and non-coding RNA regulation outlining new possible targets for the therapy of aging-related diseases. The advantages and disadvantages of the animal models used in the study of cellular senescence are also briefly presented.

Deciphering the role of oxidative stress genes in idiopathic pulmonary fibrosis: a multi-omics mendelian randomization approach.

Oxidative stress (OS) is crucial in idiopathic pulmonary fibrosis (IPF) pathogenesis, with its genes potentially acting as both causes and consequences of the disease. We identified OS-related genes from GeneCards and performed a meta-analysis on pulmonary transcriptome datasets to discover differentially expressed genes (DEGs) related to OS in IPF. We integrated this data with the largest available IPF GWAS summaries, expression quantitative trait loci (eQTLs), and DNA methylation QTLs (mQTLs) from blood. This approach aimed to identify blood OS genes and regulatory elements linked to IPF risk, incorporating the latest pulmonary eQTLs and bronchoalveolar lavage fluid microbial QTLs (bmQTLs) for a comprehensive view of gene-lung microbiota interactions through SMR and colocalization analyses. Sensitivity analyses were conducted using two additional mendelian randomization (MR) methods. Meta-analysis revealed 1090 differentially expressed OS genes between IPF patients and controls. Integration with IPF GWAS, eQTL, and mQTL data identified key genes and regulatory elements involved in IPF pathogenesis, highlighting the role of specific genes such as KCNMA1 and SLC22A5 in modulating IPF risk through epigenetic mechanisms. Colocalization analysis further identified potential interactions between gene expression and lung microbiota. Our findings elucidate the complex interplay between OS genes and IPF, suggesting potential therapeutic targets and highlighting the importance of considering epigenetic and microbial interactions in the disease's etiology and progression.

Changes in the Transcriptome and Long Non-Coding RNAs but Not the Methylome Occur in Human Cells Exposed to Borrelia burgdorferi.

Lyme disease, caused by infection with members of the Lyme borreliosis group of Borrelia spirochete bacteria, is increasing in frequency and distribution worldwide. Epigenetic interactions between the mammalian host, tick, and bacterial pathogen are poorly understood. In this study, high-throughput next-generation sequencing (NGS) allowed for the in vitro study of the transcriptome, non-coding RNAs, and methylome in human host cells in response to Borrelia burgdorferi infection. We tested the effect of the Borrelia burgdorferi strain B31 on a human primary cell line (HUVEC) and an immortalized cell line (HEK-293) for 72 h, a long-duration time that might allow for epigenetic responses in the exposed human host cells. Differential gene expression was detected in both cell models in response to B. burgdorferi. More differentially expressed genes were found in HUVECs compared to HEK-293 cells. Borrelia burgdorferi exposure significantly induced genes in the interferon, in addition to cytokine and other immune response signaling in HUVECs. In HEK-293 cells, pre-NOTCH processing in Golgi was significantly downregulated in Borrelia-exposed cells. Other significantly altered gene expressions were found in genes involved in the extracellular matrix. No significant global methylation changes were detected in HUVECs or HEK-293 cells exposed to B. burgdorferi; however, two long non-coding RNAs and a pseudogene were deregulated in response to B. burgdorferi in HUVECs, suggesting that other epigenetic mechanisms may be initiated by infection.

Epigenetics Regulation in Responses to Abiotic Factors in Plant Species: A Systematic Review.

Plants have several mechanisms to adapt or acclimate to environmental stress. Morphological, physiological, or genetic changes are examples of complex plant responses. In recent years, our understanding of the role of epigenetic regulation, which encompasses changes that do not alter the DNA sequence, as an adaptive mechanism in response to stressful conditions has advanced significantly. Some studies elucidated and synthesized epigenetic mechanisms and their relationships with environmental change, while others explored the interplay between epigenetic modifications and environmental shifts, aiming to deepen our understanding of these complex processes. In this study, we performed a systematic review of the literature to analyze the progression of epigenetics studies on plant species' responses to abiotic factors. We also aimed to identify the most studied species, the type of abiotic factor studied, and the epigenetic technique most used in the scientific literature. For this, a search for articles in databases was carried out, and after analyzing them using pre-established inclusion criteria, a total of 401 studies were found. The most studied species were Arabidopsis thaliana and Oryza sativa, highlighting the gap in studies of non-economic and tropical plant species. Methylome DNA sequencing is the main technique used for the detection of epigenetic interactions in published studies. Furthermore, most studies sought to understand the plant responses to abiotic changes in temperature, water, and salinity. It is worth emphasizing further research is necessary to establish a correlation between epigenetic responses and abiotic factors, such as extreme temperatures and light, associated with climate change.

Synthesis and Regulation of miRNA, Its Role in Oncogenesis, and Its Association with Colorectal Cancer Progression, Diagnosis, and Prognosis.

The dysfunction of several types of regulators, including miRNAs, has recently attracted scientific attention for their role in cancer-associated changes in gene expression. MiRNAs are small RNAs of ~22 nt in length that do not encode protein information but play an important role in post-transcriptional mRNA regulation. Studies have shown that miRNAs are involved in tumour progression, including cell proliferation, cell cycle, apoptosis, and tumour angiogenesis and invasion, and play a complex and important role in the regulation of tumourigenesis. The detection of selected miRNAs may help in the early detection of cancer cells, and monitoring changes in their expression profile may serve as a prognostic factor in the course of the disease or its treatment. MiRNAs may serve as diagnostic and prognostic biomarkers, as well as potential therapeutic targets for colorectal cancer. In recent years, there has been increasing evidence for an epigenetic interaction between DNA methylation and miRNA expression in tumours. This article provides an overview of selected miRNAs, which are more frequently expressed in colorectal cancer cells, suggesting an oncogenic nature.

Elucidating the Epigenetic and Protein Interaction Landscapes in Amyotrophic Lateral Sclerosis: An Integrated Bioinformatics Analysis

Background: Amyotrophic Lateral Sclerosis (ALS) is a debilitating neurodegenerative disorder characterized by the progressive degeneration of motor neurons, leading to muscle weakness and paralysis. Understanding the molecular basis of ALS is crucial for the development of effective therapies. Objective: This study aims to explore the genetic and epigenetic underpinnings of ALS, focusing on the interplay between gene mutations, protein interactions, and epigenetic factors. Methods: We conducted an extensive analysis of key ALS-associated genes including TARDBP, SOD1, ANG, VAPB, and CHMP2B. We used computational tools to assess the functional consequences of identified mutations on neuronal health and explored DNA methylation patterns in gene promoters to investigate epigenetic regulation. Results: Our findings reveal that mutations in ALS-associated genes disrupt critical processes such as amyloid fibril formation and autophagy. We also identified altered DNA methylation patterns, suggesting a mechanism for changes in gene expression linked to ALS. Molecular docking studies highlighted Humulene and Buddledin C as compounds with high binding affinities to the SOD1 enzyme, suggesting their potential to mitigate hallmark features of ALS pathology such as SOD1 aggregation and oxidative stress. Conclusions: Our comprehensive analysis underscores the complexity of ALS pathogenesis, combining genetic, epigenetic, and proteomic approaches. The insights gained not only enhance our understanding of ALS but also pave the way for novel therapeutic strategies, highlighting the importance of integrated approaches in tackling this challenging neurodegenerative disease.

A Common OXTR Risk Variant Alters Regulation of Gene Expression by DNA Hydroxymethylation in Pregnant Human Myometrium

Postpartum hemorrhage, or excessive bleeding after birth, is a leading cause of maternal morbidity. A major cause of postpartum hemorrhage is uterine atony, tiring of the uterus which leads to ineffective contractions. Uterine contractions depend on oxytocin signaling in the myometrium, which in turn depends on expression of the oxytocin receptor (OXTR). Both genetic and epigenetic factors related to the oxytocin receptor are associated with risk of postpartum hemorrhage, but a mechanism relating these factors to oxytocin receptor activity in myometrium remains unclear. We report a genetic by epigenetic interaction whereby the relationship between DNA hydroxymethylation and OXTR gene expression depends on a common OXTR gene variant (rs53576). We also provide evidence that a similar genetic by epigenetic interaction using blood-derived DNA methylation is associated with relevant clinical outcomes: quantity of oxytocin administration and odds for postpartum hemorrhage. These results provide new avenues for predicting how women will respond to pharmacological agents in the prevention and treatment of postpartum hemorrhage.

LINC00152: Potential driver oncogene in pan-cancer.

Long noncoding RNAs (lncRNA) are a class of non-coding RNAs greater than 200 bp in length with limited peptide-coding function. The transcription of LINC00152 is derived from chromosome 2p11.2. Many studies prove that LINC00152 influences the progression of various tumors via promoting the tumor cells malignant phenotype, chemoresistance, and immune escape. LINC00152 is regulated by multiple transcription factors and DNA hypomethylation. In addition, LINC00152 participates in the regulation of complex molecular signaling networks through epigenetic regulation, protein interactions, and competitive endogenous RNA (ceRNA). Here, we provide a systematic review of the upstream regulatory factors of LINC00152 expression level in different types of tumors. In addition, we revisit the main functions and mechanisms of LINC00152 as driver oncogene and biomarker in pan-cancer. This article is categorized under: RNA in Disease and Development > RNA in Disease RNA Methods > RNA Analyses in Cells RNA Interactions with Proteins and Other Molecules > RNA-Protein Complexes.

Imputation of 3D genome structure by genetic–epigenetic interaction modeling in mice

Gene expression is known to be affected by interactions between local genetic variation and DNA accessibility, with the latter organized into three-dimensional chromatin structures. Analyses of these interactions have previously been limited, obscuring their regulatory context, and the extent to which they occur throughout the genome. Here, we undertake a genome-scale analysis of these interactions in a genetically diverse population to systematically identify global genetic–epigenetic interaction, and reveal constraints imposed by chromatin structure. We establish the extent and structure of genotype-by-epigenotype interaction using embryonic stem cells derived from Diversity Outbred mice. This mouse population segregates millions of variants from eight inbred founders, enabling precision genetic mapping with extensive genotypic and phenotypic diversity. With 176 samples profiled for genotype, gene expression, and open chromatin, we used regression modeling to infer genetic–epigenetic interactions on a genome-wide scale. Our results demonstrate that statistical interactions between genetic variants and chromatin accessibility are common throughout the genome. We found that these interactions occur within the local area of the affected gene, and that this locality corresponds to topologically associated domains (TADs). The likelihood of interaction was most strongly defined by the three-dimensional (3D) domain structure rather than linear DNA sequence. We show that stable 3D genome structure is an effective tool to guide searches for regulatory elements and, conversely, that regulatory elements in genetically diverse populations provide a means to infer 3D genome structure. We confirmed this finding with CTCF ChIP-seq that revealed strain-specific binding in the inbred founder mice. In stem cells, open chromatin participating in the most significant regression models demonstrated an enrichment for developmental genes and the TAD-forming CTCF-binding complex, providing an opportunity for statistical inference of shifting TAD boundaries operating during early development. These findings provide evidence that genetic and epigenetic factors operate within the context of 3D chromatin structure.

Cellotype–phenotype associations using ‘organoid villages’

En masse phenotyping technology, using massively mosaic donor-derived cells and organoids, can offer enriched insights for cellotype–phenotype association in a cell-type-specific regulatory context. This emerging approach will help to discover biomarkers, inform genetic–epigenetic interactions and identify personalized therapeutic targets, offering hope for precision medicine against highly heterogeneous metabolic diseases.

Abstract 1707: YAP-driven epigenetic reprogramming in head and neck cancer

Abstract The ability to measure tumor evolution is difficult due to a lack of model systems able to capture tumor initiation, development, and invasion. We have developed a Dox-inducible spatiotemporally controlled HPV- and YAP-driven model of head and neck squamous cell carcinoma (HNSCC) with a well-defined cancer stem cell population. In order to better understand the epigenetic reprogramming associated with tumorigenesis we have systematically characterized the chromatin accessibility, histone landscape and YAP binding sites in this model. Cell lines were generated from tongue epithelia of normal and Dox-induced tumor-containing mice. Gene expression was measured using RNA-seq and chromatin accessibility was measured using ATAC-seq. CUT&Tag for H3K27me3, H3K27ac, and YAP was used to measure epigenetic reprogramming and YAP-DNA interactions. Differential gene expression shows that genes involved in hormone signaling, glutathione-related metabolism, fatty acid metabolism and p53 signaling were highly enriched in the normal tongue suggesting a change in metabolism upon tumorigenesis.Differential ATAC-seq peaks with higher binding levels in the normal tongue showed enrichment for p53 motifs as well as homebox motifs including Otx2, GSC and CRX suggesting p53 signaling is lost upon carcinogenesis and lineage determination is altered. Motifs for TEAD, AP-1, and KLF5 were enriched in the tumor-specific ATAC-seq peaks showing that YAP is involved in chromatin accessibility changes. CUT&Tag for YAP shows clear YAP binding near canonical YAP target genes including Axl, Ccn1, Ccn2 and Birc3. YAP peaks with higher binding in the normal tongue cell line were enriched for RUNX2 and p63 motifs and peaks higher in the tumor contained KLF5 motifs showing YAP is directly involved in the reprogramming of lineage determination. Multi-omics integration shows YAP-driven chromatin remodeling is associated with differential expression of genes involved in keratin production, EGFR and ER signaling. Direct epigenetic characterization of YAP involvement in tumor initiation is key to understanding the mechanisms of tumorigenesis in head and neck cancer. This work shows that YAP directly binds and affects the expression of genes involved in lineage determination and growth factor signaling to induce cancer progression and generate a cancer stem cell population. Citation Format: Adam Officer, Farhoud Faraji, Sydney Ramirez, Alon Goren, Pablo Tamayo, J. Silvio Gutkind. YAP-driven epigenetic reprogramming in head and neck cancer [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2024; Part 1 (Regular Abstracts); 2024 Apr 5-10; San Diego, CA. Philadelphia (PA): AACR; Cancer Res 2024;84(6_Suppl):Abstract nr 1707.

Words of caution regarding T-DNA-associated mutagenesis in plant reproduction research.

T-DNA transformation is prevalent in Arabidopsis research and has expanded to a broad range of crops and model plants. While major progress has been made in optimizing the Agrobacterium-transformation process for various species, a variety of pitfalls associated with the T-DNA insertion may lead to the misinterpretation of T-DNA mutant analysis. Indeed, secondary mutagenesis either on the integration site or elsewhere in the genome, together with epigenetic interactions between T-DNA inserts or frequent genomic rearrangements can be tricky to differentiate from the effect of the knockout of the gene of interest. Mainly the case of genomic rearrangements that become balanced in filial generations without consequential phenotypical defects may be confusing particularly for studies that aim to investigate fertility and gametogenesis. As a cautionary note to the plant research community studying gametogenesis, we here report an overview of the consequences of T-DNA-induced secondary mutagenesis with emphasis on the genomic imbalance on gametogenesis. Additionally, we present a simple guideline to evaluate the T-DNA mutagenized transgenic lines to decrease the risk of faulty analysis with minimal experimental effort.

Atopic dermatitis - itchy problem of children and adults

Atopic dermatitis is a chronic inflammatory disease with recurrent exacerbations, persistent itching, erythema, dry skin due to damage to the epidermal barrier, and staphylococcal infections. The causative factors are mutations in the gene encoding filaggrin, dysregulation of the immune system, changes in the skin microbiome and lipids in the stratum corneum and deficiency of antimicrobial peptides AMPs. The disease mainly affects children, causing a significant deterioration in the quality of life, and its first symptoms occur in approximately 90% before the age of 5. Lesions most often appear on the bends of elbows and knees, on the face and neck, but may also affect the skin of the entire body (erythroderma). The location of the eruptions depends on age. Atopic dermatitis is the result of complex genetic, epigenetic, environmental and immunological interactions with a coexisting epidermal barrier defect. The disease is diagnosed based on the Hanifin and Rajka criteria. Treatment of atopic dermatitis is symptomatic and selected individually. They include the elimination of provoking factors, care of the epidermal barrier, and anti-inflammatory and anti-pruritic therapy.

Spatial chromatin accessibility sequencing resolves high-order spatial interactions of epigenomic markers.

As the genome is organized into a three-dimensional structure in intracellular space, epigenomic information also has a complex spatial arrangement. However, most epigenetic studies describe locations of methylation marks, chromatin accessibility regions, and histone modifications in the horizontal dimension. Proper spatial epigenomic information has rarely been obtained. In this study, we designed spatial chromatin accessibility sequencing (SCA-seq) to resolve the genome conformation by capturing the epigenetic information in single-molecular resolution while simultaneously resolving the genome conformation. Using SCA-seq, we are able to examine the spatial interaction of chromatin accessibility (e.g. enhancer-promoter contacts), CpG island methylation, and spatial insulating functions of the CCCTC-binding factor. We demonstrate that SCA-seq paves the way to explore the mechanism of epigenetic interactions and extends our knowledge in 3D packaging of DNA in the nucleus.