Histone H3 Tail Research Articles

Acetylation-Dependent Compaction of the Histone H4 Tail Ensemble.

Acetylation of the histone H4 tail (H4Kac) has been established as a significant regulator of chromatin architecture and accessibility; however, the molecular mechanisms that underlie these observations remain elusive. Here, we characterize the ensemble features of the histone H4 tail and determine how they change following acetylation on specific sets of lysine residues. Our comprehensive account is enabled by a robust combination of experimental and computational biophysical methods that converge on molecular details including conformer size, intramolecular contacts, and secondary structure propensity. We find that acetylation significantly alters the chemical environment of basic patch residues (16-20) and leads to tail compaction that is partially mediated by transient intramolecular contacts established between the basic patch and N-terminal amino acids. Beyond acetylation, we identify that the protonation state of H18, which is affected by the acetylation state, is a critical regulator of ensemble characteristics, highlighting the potential for interplay between the sequence context and post-translational modifications to define the ensemble features of intrinsically disordered regions. This study elucidates molecular details that could link H4Kac with the regulation of chromatin architecture, illuminating a small piece of the complex network of molecular mechanisms underlying the histone code hypothesis.

Structural mechanisms of SLF1 interactions with Histone H4 and RAD18 at the stalled replication fork.

DNA damage that obstructs the replication machinery poses a significant threat to genome stability. Replication-coupled repair mechanisms safeguard stalled replication forks by coordinating proteins involved in the DNA damage response (DDR) and replication. SLF1 (SMC5-SMC6 complex localization factor 1) is crucial for facilitating the recruitment of the SMC5/6 complex to damage sites through interactions with SLF2, RAD18,and nucleosomes. However, the structural mechanisms of SLF1's interactions are unclear. In this study, we determined the crystal structure of SLF1's ankyrin repeat domain bound to an unmethylated histone H4 tail, illustrating how SLF1 reads nascent nucleosomes. Using structure-based mutagenesis, we confirmed a phosphorylation-dependent interaction necessary for a stable complex between SLF1's tandem BRCA1 C-Terminal domain (tBRCT) and the phosphorylated C-terminal region (S442 and S444) of RAD18. We validated a functional role of conserved phosphate-binding residues inSLF1, and hydrophobic residues in RAD18 that areadjacent to phosphorylation sites, both of whichcontribute to the strong interaction. Interestingly, we discovered a DNA-binding property of this RAD18-binding interface, providing an additional domain of SLF1 to enhance binding to nucleosomes. Our results provide critical structural insights into SLF1's interactions with post-replicative chromatin and phosphorylation-dependent DDR signalling, enhancing our understanding of SMC5/6 recruitment and/or activity during replication-coupled DNA repair.

A circular engineered sortase for interrogating histone H3 in chromatin.

Reversible modification of the histone H3 N-terminal tail is critical in regulating chromatin structure, gene expression, and cell states, while its dysregulation contributes to disease pathogenesis. Understanding the crosstalk between H3 tail modifications in nucleosomes constitutes a central challenge in epigenetics. Here we describe an engineered sortase transpeptidase, cW11, that displays highly favorable properties for introducing scarless H3 tails onto nucleosomes. This approach significantly accelerates the production of both symmetrically and asymmetrically modified nucleosomes. We demonstrate the utility of asymmetrically modified nucleosomes produced in this way in dissecting the impact of multiple modifications on eraser enzyme processing and molecular recognition by a reader protein. Moreover, we show that cW11 sortase is very effective at cutting and tagging histone H3 tails from endogenous histones, facilitating multiplex "cut-and-paste" middle down proteomics with tandem mass tags. This cut-and- paste proteomics approach permits the quantitative analysis of histone H3 modification crosstalk after treatment with different histone deacetylase inhibitors. We propose that these chemoenzymatic tail isolation and modification strategies made possible with cW11 sortase will broadly power epigenetics discovery and therapeutic development.

A Live-Cell Epigenome Manipulation by Photo-Stimuli-Responsive Histone Methyltransferase Inhibitor.

Post-translational modifications on the histone H3 tail regulate chromatin structure, impact epigenetics, and hence the gene expressions. Current chemical modulation tools, such as unnatural amino acid incorporation, protein splicing, and sortase-based editing, have allowed for the modification of histones with various PTMs in cellular contexts, but are not applicable for editing native chromatin. The use of small organic molecules to manipulate histone-modifying enzymes alters endogenous histone PTMs but lacks precise temporal and spatial control. To date, there has been no achievement in modulating histone methylation in living cells with spatiotemporal resolution. In this study, a new method is presented for temporally manipulating histone dimethylation H3K9me2 using a photo-responsive inhibitor that specifically targets the methyltransferase G9a on demand. The photo-caged molecule is stable under physiological conditions and cellular environments, but rapidly activated upon exposure to light, releasing the bioactive component that can immediately inhibit the catalytic ability of the G9a in vitro. Besides, this masked compound could also efficiently reactivate the inhibition of methyltransferase activity in living cells, subsequently suppress H3K9me2, a mark that regulates various chromatin functions. Therefore, the chemical system will be a valuable tool for manipulating the epigenome for therapeutic purposes and furthering the understanding of epigenetic mechanisms.

How does CHD4 slide nucleosomes?

Chromatin remodelling enzymes reposition nucleosomes throughout the genome to regulate the rate of transcription and other processes. These enzymes have been studied intensively since the 1990s, and yet the mechanism by which they operate has only very recently come into focus, following advances in cryoelectron microscopy and single-molecule biophysics. CHD4 is an essential and ubiquitous chromatin remodelling enzyme that until recently has received less attention than remodellers such as Snf2 and CHD1. Here we review what recent work in the field has taught us about how CHD4 reshapes the genome. Cryoelectron microscopy and single-molecule studies demonstrate that CHD4 shares a central remodelling mechanism with most other chromatin remodellers. At the same time, differences between CHD4 and other chromatin remodellers result from the actions of auxiliary domains that regulate remodeller activity by for example: (1) making differential interactions with nucleosomal epitopes such as the acidic patch and the N-terminal tail of histone H4, and (2) inducing the formation of distinct multi-protein remodelling complexes (e.g. NuRD vs ChAHP). Thus, although we have learned much about remodeller activity, there is still clearly much more waiting to be revealed.

Single-cell multi-modal chromatin profiles revealing epigenetic regulations of cells in hepatocellular carcinoma.

Various epigenetic regulations systematically govern gene expression in cells involving various biological processes. Dysregulation of the epigenome leads to aberrant transcriptional programs and subsequently results in diseases, such as cancer. Therefore, comprehensive profiling epigenomics is essential for exploring the mechanisms underlying gene expression regulation during development and disease. In this study, we developed single-cell chromatin proteins and accessibility tagmentation (scCPA-Tag), a multi-modal single-cell epigenetic profile capturing technique based on barcoded Tn5 transposases and a droplet microfluidics platform. scCPA-Tag enables the simultaneous capture of DNA profiles of histone modification and chromatin accessibility in the same cell. By applying scCPA-Tag to K562 cells and a hepatocellular carcinoma (HCC) sample, we found that the silence of several chromatin-accessible genes can be attributed to lysine-27-trimethylation of the histone H3 tail (H3K27me3) modification. We characterized the epigenetic features of the tumour cells and different immune cell types in the HCC tumour tissue by scCPA-Tag. Besides, a tumour cell subtype (C2) with more aggressive features was identified and characterized by high chromatin accessibility and a lower abundance of H3K27me3 on tumour-promoting genes. Our multi-modal scCPA-Tag provides a comprehensive approach for exploring the epigenetic landscapes of heterogeneous cell types and revealing the mechanisms of gene expression regulation during developmental and pathological processes at the single-cell level. scCPA-Tag offers a highly efficient and high throughput technique to simultaneously profile histone modification and chromatin accessibility within a single cell. scCPA-Tag enables to uncover multiple epigenetic modification features of cellular compositions within tumor tissues. scCPA-Tag facilitates the exploration of the epigenetic landscapes of heterogeneous cell types and provides the mechanisms governing gene expression regulation.

Autoregulatory mechanism of enzyme activity by the nuclear localization signal of lysine-specific demethylase 1

The N-terminal region of the human Lysine Specific Demethylase 1 (LSD1) has no predicted structural elements, contains a nuclear localization signal (NLS), undergoes multiple post-translational modifications (PTMs), and acts as a protein-protein interaction hub. This intrinsically disordered region (IDR) extends from core LSD1 structure, resides atop the catalytic active site, and is known to be dispensable for catalysis. Here, we show differential nucleosome binding between the full-length and an N-terminus deleted LSD1 and identify that a conserved NLS and PTM containing element of the N-terminus contains an alpha helical structure, and that this conserved element impacts demethylation. Enzyme assays reveal that LSD1’s own electropositive NLS amino acids 107-120 inhibit demethylation activity on a model Histone 3 lysine 4 di-methyl (H3K4me2) peptide (Kiapp ∼ 3.3 μM) and H3K4me2 nucleosome substrates (IC50 ∼ 30.4 μM), likely mimicking the histone H3 tail. Further, when the identical, inhibitory NLS region contains phosphomimetic modifications, inhibition is partially relieved. Based upon these results and biophysical data, a regulatory mechanism for the LSD1-catalyzed demethylation reaction is proposed whereby NLS-mediated autoinhibition can occur through electrostatic interactions, and be partially relieved through phosphorylation that occurs proximal to the NLS. Taken together, the results highlight a dynamic and synergistic role for PTMs, IDRs, and structured regions near LSD1 active site and introduces the notion that phosphorylated mediated NLS regions can function to fine-tune chromatin modifying enzyme activity.

H3K27-Altered Diffuse Midline Glioma of the Brainstem: From Molecular Mechanisms to Targeted Interventions.

Pediatric high-grade gliomas are a devastating subset of brain tumors, characterized by their aggressive pathophysiology and limited treatment options. Among them, H3 K27-altered diffuse midline gliomas (DMG) of the brainstem stand out due to their distinct molecular features and dismal prognosis. Recent advances in molecular profiling techniques have unveiled the critical role of H3 K27 alterations, particularly a lysine-to-methionine mutation on position 27 (K27M) of the histone H3 tail, in the pathogenesis of DMG. These mutations result in epigenetic dysregulation, which leads to altered chromatin structure and gene expression patterns in DMG tumor cells, ultimately contributing to the aggressive phenotype of DMG. The exploration of targeted therapeutic avenues for DMG has gained momentum in recent years. Therapies, including epigenetic modifiers, kinase inhibitors, and immunotherapies, are under active investigation; these approaches aim to disrupt aberrant signaling cascades and overcome the various mechanisms of therapeutic resistance in DMG. Challenges, including blood-brain barrier penetration and DMG tumor heterogeneity, require innovative approaches to improve drug delivery and personalized treatment strategies. This review aims to provide a comprehensive overview of the evolving understanding of DMG, focusing on the intricate molecular mechanisms driving tumorigenesis/tumor progression and the current landscape of emerging targeted interventions.

Expression Proteomics and Histone Analysis Reveal Extensive Chromatin Network Changes and a Role for Histone Tail Trimming during Cellular Differentiation.

In order to understand the coordinated proteome changes associated with differentiation of a cultured cell pluripotency model, protein expression changes induced by treatment of NT2 embryonal carcinoma cells with retinoic acid were monitored by mass spectrometry. The relative levels of over 5000 proteins were mapped across distinct cell fractions. Analysis of the chromatin fraction revealed major abundance changes among chromatin proteins and epigenetic pathways between the pluripotent and differentiated states. Protein complexes associated with epigenetic regulation of gene expression, chromatin remodelling (e.g., SWI/SNF, NuRD) and histone-modifying enzymes (e.g., Polycomb, MLL) were found to be extensively regulated. We therefore investigated histone modifications before and after differentiation, observing changes in the global levels of lysine acetylation and methylation across the four canonical histone protein families, as well as among variant histones. We identified the set of proteins with affinity to peptides housing the histone marks H3K4me3 and H3K27me3, and found increased levels of chromatin-associated histone H3 tail trimming following differentiation that correlated with increased expression levels of cathepsin proteases. We further found that inhibition of cathepsins B and D reduces histone H3 clipping. Overall, the work reveals a global reorganization of the cell proteome congruent with differentiation, highlighting the key role of multiple epigenetic pathways, and demonstrating a direct link between cathepsin B and D activity and histone modification.

Mechanism of heterochromatin remodeling revealed by the DDM1 bound nucleosome structures

The SWI/SNF2 chromatin remodeling factor decreased DNA methylation 1 (DDM1) is essential for the silencing of transposable elements (TEs) in both euchromatic and heterochromatic regions. Here, we determined the cryo-EM structures of DDM1-nucleosomeH2A and DDM1-nucleosomeH2A.W complexes at near-atomic resolution in the presence of the ATP analog ADP-BeFx. The structures show that nucleosomal DNA is unwrapped more on the surface of the histone octamer containing histone H2A than that containing histone H2A.W. DDM1 embraces one DNA gyre of the nucleosome and interacts with the N-terminal tails of histone H4. Although we did not observe DDM1-H2A.W interactions in our structures, the results of the pull-down experiments suggest a direct interaction between DDM1 and the core region of histone H2A.W. Our work provides mechanistic insights into the heterochromatin remodeling process driven by DDM1 in plants.

Combined and differential roles of ADD domains of DNMT3A and DNMT3L on DNA methylation landscapes in mouse germ cells

DNA methyltransferase 3A (DNMT3A) and its catalytically inactive cofactor DNA methyltransferase 3-Like (DNMT3L) proteins form functional heterotetramers to deposit DNA methylation in mammalian germ cells. While both proteins have an ATRX-DNMT3-DNMT3L (ADD) domain that recognizes histone H3 tail unmethylated at lysine-4 (H3K4me0), the combined and differential roles of the domains in the two proteins have not been fully defined in vivo. Here we investigate DNA methylation landscapes in female and male germ cells derived from mice with loss-of-function amino acid substitutions in the ADD domains of DNMT3A and/or DNMT3L. Mutations in either the DNMT3A-ADD or the DNMT3L-ADD domain moderately decrease global CG methylation levels, but to different degrees, in both germ cells. Furthermore, when the ADD domains of both DNMT3A and DNMT3L lose their functions, the CG methylation levels are much more reduced, especially in oocytes, comparable to the impact of the Dnmt3a/3L knockout. In contrast, aberrant accumulation of non-CG methylation occurs at thousands of genomic regions in the double mutant oocytes and spermatozoa. These results highlight the critical role of the ADD-H3K4me0 binding in proper CG and non-CG methylation in germ cells and the various impacts of the ADD domains of the two proteins.

MLL4 binds TET3

Human mixed lineage leukemia 4 (MLL4), also known as KMT2D, regulates cell type specific transcriptional programs through enhancer activation. Along with the catalytic methyltransferase domain, MLL4 contains seven less characterized plant homeodomain (PHD) fingers. Here, we report that the sixth PHD finger of MLL4 (MLL4PHD6) binds to the hydrophobic motif of ten-eleven translocation 3 (TET3), a dioxygenase that converts methylated cytosine into oxidized derivatives. The solution NMR structure of the TET3-MLL4PHD6 complex and binding assays show that, like histone H4 tail, TET3 occupies the hydrophobic site of MLL4PHD6, and that this interaction is conserved in the seventh PHD finger of homologous MLL3 (MLL3PHD7). Analysis of genomic localization of endogenous MLL4 and ectopically expressed TET3 in mouse embryonic stem cells reveals a high degree overlap on active enhancers and suggests a potential functional relationship of MLL4 and TET3.

Binding to nucleosome poises human SIRT6 for histone H3 deacetylation.

Sirtuin 6 (SIRT6) is an NAD+-dependent histone H3 deacetylase that is prominently found associated with chromatin, attenuates transcriptionally active promoters and regulates DNA repair, metabolic homeostasis and lifespan. Unlike other sirtuins, it has low affinity to free histone tails but demonstrates strong binding to nucleosomes. It is poorly understood how SIRT6 docking on nucleosomes stimulates its histone deacetylation activity. Here, we present the structure of human SIRT6 bound to a nucleosome determined by cryogenic electron microscopy. The zinc finger domain of SIRT6 associates tightly with the acidic patch of the nucleosome through multiple arginine anchors. The Rossmann fold domain binds to the terminus of the looser DNA half of the nucleosome, detaching two turns of the DNA from the histone octamer and placing the NAD+ binding pocket close to the DNA exit site. This domain shows flexibility with respect to the fixed zinc finger and moves with, but also relative to, the unwrapped DNA terminus. We apply molecular dynamics simulations of the histone tails in the nucleosome to show that in this mode of interaction, the active site of SIRT6 is perfectly poised to catalyze deacetylation of the H3 histone tail and that the partial unwrapping of the DNA allows even lysines close to the H3 core to reach the enzyme.

Binding to nucleosome poises human SIRT6 for histone H3 deacetylation

Sirtuin 6 (SIRT6) is an NAD+-dependent histone H3 deacetylase that is prominently found associated with chromatin, attenuates transcriptionally active promoters and regulates DNA repair, metabolic homeostasis and lifespan. Unlike other sirtuins, it has low affinity to free histone tails but demonstrates strong binding to nucleosomes. It is poorly understood how SIRT6 docking on nucleosomes stimulates its histone deacetylation activity. Here, we present the structure of human SIRT6 bound to a nucleosome determined by cryogenic electron microscopy. The zinc finger domain of SIRT6 associates tightly with the acidic patch of the nucleosome through multiple arginine anchors. The Rossmann fold domain binds to the terminus of the looser DNA half of the nucleosome, detaching two turns of the DNA from the histone octamer and placing the NAD+ binding pocket close to the DNA exit site. This domain shows flexibility with respect to the fixed zinc finger and moves with, but also relative to, the unwrapped DNA terminus. We apply molecular dynamics simulations of the histone tails in the nucleosome to show that in this mode of interaction, the active site of SIRT6 is perfectly poised to catalyze deacetylation of the H3 histone tail and that the partial unwrapping of the DNA allows even lysines close to the H3 core to reach the enzyme.

A DNA Force Circuit for Exploring Protein‐Protein Interactions at the Single‐Molecule Level†

Comprehensive SummaryProtein‐protein interactions (PPIs) play a crucial role in drug discovery and disease treatment. However, the development of effective drugs targeting PPIs remains challenging due to limited methodologies for probing their spatiotemporal anisotropy. Here, we propose a single‐molecule approach using a unique force circuit to investigate PPI dynamics and anisotropy under mechanical forces. Unlike conventional techniques, this approach enables the manipulation and real‐time monitoring of individual proteins at specific amino acids with defined geometry, offering insights into molecular mechanisms at the single‐molecule level. The DNA force circuit was constructed using click chemistry conjugation methods and genetic code expansion techniques, facilitating orthogonal conjugation between proteins and nucleic acids. The SET domain of the MLL1 protein and the tail of histone H3 were used as a model system to demonstrate the application of the DNA force circuit. With the use of atomic force microscopy and magnetic tweezers, optimized assembly procedures were developed. The DNA force circuit provides an exceptional platform for studying the anisotropy of PPIs and holds promise for advancing drug discovery research targeted at PPIs.

Disentangling the effects of the N-terminal tails of histone H3 and CENP-A from the histone core on nucleosome stability

Disentangling the effects of the N-terminal tails of histone H3 and CENP-A from the histone core on nucleosome stability

Abstract B008: KDM4C histone demethylase connects redox balance to chromatin remodeling via histone H3 tail clipping

Abstract Triple-negative breast cancer (TNBC) is a breast cancer subtype with inferior prognosis necessitating the discovery of novel therapeutic targets. In this study, we describe that KDM4C, a histone demethylase amplified and overexpressed in a subset of TNBC is a driver of TNBC tumor growth. Integrative multi-omic analysis using RNA-seq, ChIP-seq and ATAC-seq demonstrated that KDM4C inhibition triggers chromatin and transcriptomic remodeling without substantial changes of its canonical substrates H3K9me3 and H3K36me3 in TNBC breast cancer cells. Rather KDM4C loss surprisingly caused proteolytic cleavage at histone 3 N terminus (A21 site) identified by histone mass spectrometry. Protease inhibitor array pointed out cathepsin L (CTSL) as the endopeptidase mediating this procedure and CTSL proteomic interactome profiling further uncovered that grainyhead like transcription factor 2 (GRHL2) recruited CTSL to the chromatin. Metabolomic profiling showed reduced glutathione levels following KDM4C inhibition partly due to a decrease in glutamate-cysteine ligase (GCLC) triggered by CTSL-mediated histone H3 cleavage and subsequent increase in reactive oxygen species (ROS). Knockout of CTSL rescued KDM4C blockade-associated metabolic dysfunction and tumor suppression in vivo. The expression of KDM4C and GCLC correlated in TNBC and combined targeting of KDM4C and the GSH axis improved response to cisplatin in cell culture and xenograft models. Our study reveals a novel role for KDM4C in TNBC that links cellular redox regulation and epigenetics. Citation Format: Zheqi Li, Guillermo Peluffo, Laura Stevens, Xintao Qiu, Marco Seehawer, Xiao-Yun Huang, Shawn Egri, Malvina Papanastasiou, Natalie Kingston, Clive D'Santos, Eva Papachristou, Jun Nishida, Kyle Evans, Ji-Heui Seo, Kendell Clement, Daniel Temko, Muhammad Ekram, Matthew Rees, Melissa Ronan, Jennifer Roth, Anton Simeonov, Stephen Kales, Ganesha Rai, Madhu Lal-Nag, David Maloney, Ajit Jadhav, Franziska Michor, Alex Meissner, Justin Balko, Jason Carroll, Matthew Freedman, Henry Long, Jacob Jaffe, Kornelia Polyak. KDM4C histone demethylase connects redox balance to chromatin remodeling via histone H3 tail clipping [abstract]. In: Proceedings of the AACR Special Conference in Cancer Research: Advances in Breast Cancer Research; 2023 Oct 19-22; San Diego, California. Philadelphia (PA): AACR; Cancer Res 2024;84(3 Suppl_1):Abstract nr B008.

ECCO Grant Serotonin gets into your genes: the role of histone serotonylation in inflammatory response and visceral hypersensitivity in Crohn’s Disease

Abstract Background and Aims More than 70% of CD patients experience visceral hypersensitivity (VH) despite reaching remission. VH treatment is difficult because the mechanism of its complication is unknown. Serotonin is mainly produced in the gut and regulates several physiological processes, such as intestinal immunity and pain. Disturbances in serotonin levels are associated with CD severity and VH. Intriguingly, we have recently observed that serotonin can covalently bind to glutamine at position 5 on histone H3 tail, leading to histone serotonylation (H3Q5ser) in peripheral blood mononuclear cells (PBMCs). Another study has demonstrated that H3Q5ser can also occur in cultured neuronal cells. Our objective is to investigate the role of this newly discovered epigenetic signature (H3Q5ser) in immune cells and enteric neurons in CD and its potential impact on the transcriptional programs of the inflammatory response and VH. Methods To accomplish this goal, we will first determine the concentrations of serotonin in the mucosa and serum of active CD patients compared to healthy controls and establish how these levels relate to the enhancement of H3Q5ser in immune cells and enteric neurons. To study the functional role of H3Q5ser in cell activation, we will use site-directed or oligonucleotide- mediated mutagenesis to induce a point mutation in cultured enteric neuron cell lines and PBMCs to remove the binding site for serotonin on histone. Both wild-type and mutant cells will be incubated with or without serotonin and subjected to chromatin immunoprecipitation sequencing and RNA sequencing profiling to investigate the effect of H3Q5ser on the transcriptional programs associated with inflammation and VH. Anticipated Impact This project will provide a comprehensive understanding of the impact of the changes in serotonin concentrations on H3Q5ser-related gene expression in CD- associated VH and the inflammatory response. Our anticipated impact is subsequent studies that monitor H3Q5ser in VH in CD patients during treatment.

Genomic analysis of oesophageal carcinoma (EC) to identify recurrent mutations in histone methyltransferases as a distinctive subset.

379 Background: Histone-lysine N-methyltransferase 2 (KMT2) family proteins methylate lysine 4 on the histone H3 tail at important regulatory regions in the genome and thereby impart crucial functions through modulating chromatin structures and DNA accessibility, which is associated with tumorigenesis and immune tolerance, indicating its possible correlation with the efficacy of immunotherapy. Recurrent mutations of KMT2 have been identified in EC, but data addressing the molecular features of KMT2 mutated (MT) EC are lacking. We aimed to understand the molecular profile of KMT2 -MT EC. Methods: A total of 787 oesophageal carcinoma [adenocarcinoma (EAC), N=604; squamous cell carcinoma (ESCC), N=183] were analyzed using next-generation sequencing (NGS) and immunohistochemistry (Caris Life Sciences, Phoenix, AZ). Tumor mutational burden (TMB) was calculated based on somatic nonsynonymous mutations, and mismatch repair deficiency (dMMR)/microsatellite instability-high (MSI-H) status was evaluated by a combination of IHC, Fragment analysis and NGS. Results: The mutation spectrum of KMT2A/C/D was significantly different between ESCC and EAC ( KMT2A, 2.7% vs. 1.2%; KMT2C, 3.8% vs. 1.2%; KMT2D, 14.2% vs. 2.0%, P <0.05). KMT2-MT EAC tumors showed significantly higher mutation rates in CIC (13% vs 1.1%), NF1 (12.5% vs 2.2%), FBXW7 (12% vs 3.4%), ATM (11.5% vs 2.6%) and BRCA1 (11.5% vs 1%, all q<0.05), compared to KMT2-WT tumors. However, in ESCC there were no significant differences in gene mutations between the KMT2-MT and WT groups. Significantly higher rates of dMMR/MSI-H (19.2% vs 1.0% in EAC, 5.4% vs. 0% in ESCC, both p<0.01) were seen in both KMT2-MT ESCC and EAC, compared to KMT2-WT cohorts, respectively. TMB was significantly higher in both KMT2-MT ESCC (median: 10 vs 8.6 mut/Mb, P=0.042) and EAC (23.9 vs 8.0 mut/Mb, P<0.0001), compared to KMT2-WT cohorts, respectively. A numerically longer immune-related overall survival was observed in KMT2 -MT EC patients, compared to KMT2 -WT EC patients (9.05 vs 6.98 months, HR=0.744, 95%CI: 0.52-1.07, P =0.11). Conclusions: This is the largest study to investigate the distinct genomic landscapes between KMT2 -MT and WT EC to date. Our data showed the KMT2 -MT EC has a distinctive genetic profile, indicated by higher TMB, and higher frequency of dMMR/MSI-H and gene mutations involved in DDR and epigenetic regulation. Understanding these molecular characteristics may be informative in the development of effective treatment strategies in KMT2 -MT EC.

Poly(ADP-ribosyl)ation enhances nucleosome dynamics and organizes DNA damage repair components within biomolecular condensates

Nucleosomes, the basic structural units of chromatin, hinder recruitment and activity of various DNA repair proteins, necessitating modifications that enhance DNA accessibility. Poly(ADP-ribosyl)ation (PARylation) of proteins near damage sites is an essential initiation step in several DNA-repair pathways; however, its effects on nucleosome structural dynamics and organization are unclear. Using NMR, cryoelectron microscopy (cryo-EM), and biochemical assays, we show that PARylation enhances motions of the histone H3 tail and DNA, leaving the configuration of the core intact while also stimulating nuclease digestion and ligation of nicked nucleosomal DNA by LIG3. PARylation disrupted interactions between nucleosomes, preventing self-association. Addition of LIG3 and XRCC1 to PARylated nucleosomes generated condensates that selectively partition DNA repair-associated proteins in a PAR- and phosphorylation-dependent manner invitro. Our results establish that PARylation influences nucleosomes across different length scales, extending from the atom-level motions of histone tails to the mesoscale formation of condensates with selective compositions.