Histone Tail Modifications Research Articles

Epigenetic Mechanisms Underlying Sex Differences in Neurodegenerative Diseases.

Neurodegenerative diseases are characterized by profound differences between females and males in terms of incidence, clinical presentation, and disease progression. Furthermore, there is evidence suggesting that differences in sensitivity to medical treatments may exist between the two sexes. Although the role of sex hormones and sex chromosomes in driving differential susceptibility to these diseases is well-established, the molecular alterations underlying these differences remain poorly understood. Epigenetic mechanisms, including DNA methylation, histone tail modifications, and the activity of non-coding RNAs, are strongly implicated in the pathogenesis of neurodegenerative diseases. While it is known that epigenetic mechanisms play a crucial role in sexual differentiation and that distinct epigenetic patterns characterize females and males, sex-specific epigenetic patterns have been largely overlooked in studies aiming to identify epigenetic alterations associated with neurodegenerative diseases. This review aims to provide an overview of sex differences in epigenetic mechanisms, the role of sex-specific epigenetic processes in the central nervous system, and the main evidence of sex-specific epigenetic alterations in three neurodegenerative diseases, including Alzheimer's disease, Parkinson's disease, and amyotrophic lateral sclerosis. Understanding the sex-related differences of these diseases is essential for developing personalized treatments and interventions that account for the unique epigenetic landscapes of each sex.

P-115 GATAD2B is required for pre-implantation embryo development by delaying zygotic genome activation

Abstract Study question Major zygotic genome activation (ZGA) involving the activation of thousands of genes occurs at the late-2cell stage, but the regulatory mechanisms governing ZGA remain unclear. Summary answer Our results demonstrate that GATAD2B is essential for early embryonic development, in part through facilitating zygotic genome activation (ZGA). What is known already Acetylation modifications of histone tails promote transcriptional activation, and the maternal deletion of H4K16ac leads to failure in ZGA. GATAD2B is one of the core subunits of the Nucleosome remodeling and histone deacetylation complex(NuRD). Study design, size, duration Using mouse embryos as the research model, the study was conducted over a period of approximately two years to ensure a relatively small-scale investigation. Participants/materials, setting, methods We examined the dynamic expression of NURD complex components, including GATAD2B, during pre-implantation embryonic stages. GATAD2B expression was specifically reduced via microinjection of GATAD2B-siRNA during the zygote stage, revealing its impact on early embryonic development in mice. Zygotic genome activation (ZGA), morula compaction, and blastocyst lineage differentiation were investigated using immunofluorescence, western blot, and other techniques. Additionally, we employed RNA-seq, protein immunoprecipitation, and mass spectrometry to uncover underlying molecular mechanisms. Main results and the role of chance Our research has shown that GATAD2B exhibits specific nucleus localization and high protein expression from the late-2-cell to 8-cell. This intriguing phenomenon prompted us to investigate the relationship between GATAD2B and the ZGA. We discovered a distinctive pattern of GATAD2B, starting from the late 2-cell stage with nuclear localization. GATAD2B depletion resulted in defective embryonic development, including increased DNA damage at morula, decreased blastocyst formation rate and abnormal differentiation of ICM/TE lineages. Consistent with the delay during the cleavage stage, the transcriptome analysis of the 2-cell revealed inhibition of the cell cycle G2/M phase transition pathway. Furthermore, the GATAD2B proteomics data provided clear evidence of a certain association between GATAD2B and molecules involved in the cell cycle pathway. As hypothesized, GATAD2B-deficient 2-cell embryos exhibited abnormalities in ZGA during the maternal-to-embryonic transition, with lower expression of the major ZGA mark MERVL. Limitations, reasons for caution Given the limitations of antibody effectiveness and specificity required for the experiments, the exploration of molecular mechanisms is still ongoing. Wider implications of the findings Our findings have elucidated the impact of GATAD2B on early embryonic development through the regulation of zygotic genome activation (ZGA), providing a novel genetic explanation for clinical defects in early embryonic development. Trial registration number not applicable

Liver-specific deletion of de novo DNA methyltransferases protects against glucose intolerance in high-fat diet-fed male mice.

Alterations to gene transcription and DNA methylation are a feature of many liver diseases including fatty liver disease and liver cancer. However, it is unclear whether the DNA methylation changes are a cause or a consequence of the transcriptional changes. It is even possible that the methylation changes are not required for the transcriptional changes. If DNA methylation is just a minor player in, or a consequence of liver transcriptional change, then future studies in this area should focus on other systems such as histone tail modifications. To interrogate the importance of de novo DNA methylation, we generated mice that are homozygous mutants for both Dnmt3a and Dnmt3b in post-natal liver. These mice are viable and fertile with normal sized livers. Males, but not females, showed increased adipose depots, yet paradoxically, improved glucose tolerance on both control diet and high-fat diets (HFD). Comparison of the transcriptome and methylome with RNA sequencing and whole-genome bisulfite sequencing in adult hepatocytes revealed that widespread loss of methylation in CpG-rich regions in the mutant did not induce loss of homeostatic transcriptional regulation. Similarly, extensive transcriptional changes induced by HFD did not require de novo DNA methylation. The improved metabolic phenotype of the Dnmt3a/3b mutant mice may be mediated through the dysregulation of a subset of glucose and fat metabolism genes which increase both glucose uptake and lipid export by the liver. However, further work is needed to confirm this.

Additional Sex Combs-like Family Associated with Epigenetic Regulation.

The additional sex combs-like (ASXL) family, a mammalian homolog of the additional sex combs (Asx) of Drosophila, has been implicated in transcriptional regulation via chromatin modifications. Abnormal expression of ASXL family genes leads to myelodysplastic syndromes and various types of leukemia. De novo mutation of these genes also causes developmental disorders. Genes in this family and their neighbor genes are evolutionary conserved in humans and mice. This review provides a comprehensive summary of epigenetic regulations associated with ASXL family genes. Their expression is commonly regulated by DNA methylation at CpG islands preceding transcription starting sites. Their proteins primarily engage in histone tail modifications through interactions with chromatin regulators (PRC2, TrxG, PR-DUB, SRC1, HP1α, and BET proteins) and with transcription factors, including nuclear hormone receptors (RAR, PPAR, ER, and LXR). Histone modifications associated with these factors include histone H3K9 acetylation and methylation, H3K4 methylation, H3K27 methylation, and H2AK119 deubiquitination. Recently, non-coding RNAs have been identified following mutations in the ASXL1 or ASXL3 gene, along with circular ASXLs and microRNAs that regulate ASXL1 expression. The diverse epigenetic regulations linked to ASXL family genes collectively contribute to tumor suppression and developmental processes. Our understanding of ASXL-regulated epigenetics may provide insights into the development of therapeutic epigenetic drugs.

GATAD2B is required for pre-implantation embryonic development by regulating zygotic genome activation.

Major zygotic genome activation (ZGA) occurs at the late 2-cell stage and involves the activation of thousands of genes, supporting early embryonic development. The reasons underlying the regulation of ZGA are not clear. Acetylation modifications of histone tails promote transcriptional activation, and the maternal deletion of H4K16ac leads to failure in ZGA. GATAD2B is one of the core subunits of the nucleosome remodelling and histone deacetylation (NuRD) complex. Our research has shown that GATAD2B exhibits specific nucleus localization and high protein expression from the late 2-cell stage to the 8-cell stage. This intriguing phenomenon prompted us to investigate the relationship between GATAD2B and the ZGA. We discovered a distinctive pattern of GATAD2B, starting from the late 2-cell stage with nuclear localization. GATAD2B depletion resulted in defective embryonic development, including increased DNA damage at morula, decreased blastocyst formation rate, and abnormal differentiation of ICM/TE lineages. Consistent with the delay during the cleavage stage, the transcriptome analysis of the 2-cell embryo revealed inhibition of the cell cycle G2/M phase transition pathway. Furthermore, the GATAD2B proteomic data provided clear evidence of a certain association between GATAD2B and molecules involved in the cell cycle pathway. As hypothesized, GATAD2B-deficient 2-cell embryos exhibited abnormalities in ZGA during the maternal-to-embryonic transition, with lower expression of the major ZGA marker MERVL. Overall, our results demonstrate that GATAD2B is essential for early embryonic development, in part through facilitating ZGA.

Molecular mechanisms in regulation of autophagy and apoptosis in view of epigenetic regulation of genes and involvement of liquid-liquid phase separation

Cellular physiology is critically regulated by multiple signaling nexuses, among which cell death mechanisms play crucial roles in controlling the homeostatic landscape at the tissue level within an organism. Apoptosis, also known as programmed cell death, can be induced by external and internal stimuli directing the cells to commit suicide in unfavourable conditions. In contrast, stress conditions like nutrient deprivation, infection and hypoxia trigger autophagy, which is lysosome-mediated processing of damaged cellular organelle for recycling of the degraded products, including amino acids. Apparently, apoptosis and autophagy both are catabolic and tumor-suppressive pathways; apoptosis is essential during development and cancer cell death, while autophagy promotes cell survival under stress. Moreover, autophagy plays dual role during cancer development and progression by facilitating the survival of cancer cells under stressed conditions and inducing death in extreme adversity. Despite having two different molecular mechanisms, both apoptosis and autophagy are interconnected by several crosslinking intermediates. Epigenetic modifications, such as DNA methylation, post-translational modification of histone tails, and miRNA play a pivotal role in regulating genes involved in both autophagy and apoptosis. Both autophagic and apoptotic genes can undergo various epigenetic modifications and promote or inhibit these processes under normal and cancerous conditions. Epigenetic modifiers are uniquely important in controlling the signaling pathways regulating autophagy and apoptosis. Therefore, these epigenetic modifiers of both autophagic and apoptotic genes can act as novel therapeutic targets against cancers. Additionally, liquid-liquid phase separation (LLPS) also modulates the aggregation of misfolded proteins and provokes autophagy in the cytosolic environment. This review deals with the molecular mechanisms of both autophagy and apoptosis including crosstalk between them; emphasizing epigenetic regulation, involvement of LLPS therein, and possible therapeutic approaches against cancers.

KMT2D preferentially binds mRNAs of the genes it regulates, suggesting a role in RNA processing.

Histone lysine methyltransferases (HKMTs) perform vital roles in cellular life by controlling gene expression programs through the posttranslational modification of histone tails. Since many of them are intimately involved in the development of different diseases, including several cancers, understanding the molecular mechanisms that control their target recognition and activity is vital for the treatment and prevention of such conditions. RNA binding has been shown to be an important regulatory factor in the function of several HKMTs, such as the yeast Set1 and the human Ezh2. Moreover, many HKMTs are capable of RNA binding in the absence of a canonical RNA binding domain. Here, we explored the RNA binding capacity of KMT2D, one of the major H3K4 monomethyl transferases in enhancers, using RNA immunoprecipitation followed by sequencing. We identified a broad range of coding and non-coding RNAs associated with KMT2D and confirmed their binding through RNA immunoprecipitation and quantitative PCR. We also showed that a separated RNA binding region within KMT2D is capable of binding a similar RNA pool, but differences in the binding specificity indicate the existence of other regulatory elements in the sequence of KMT2D. Analysis of the bound mRNAs revealed that KMT2D preferentially binds co-transcriptionally to the mRNAs of the genes under its control, while also interacting with super enhancer- and splicing-related non-coding RNAs. These observations, together with the nuclear colocalization of KMT2D with differentially phosphorylated forms of RNA Polymerase II suggest a so far unexplored role of KMT2D in the RNA processing of the nascent transcripts.

The role of epigenetic and epitranscriptomic modifications in plants exposed to non-essential metals.

Contamination of the soil with non-essential metals and metalloids is a serious problem in many regions of the world. These non-essential metals and metalloids are toxic to all organisms impacting crop yields and human health. Crop plants exposed to high concentrations of these metals leads to perturbed mineral homeostasis, decreased photosynthesis efficiency, inhibited cell division, oxidative stress, genotoxic effects and subsequently hampered growth. Plants can activate epigenetic and epitranscriptomic mechanisms to maintain cellular and organism homeostasis. Epigenetic modifications include changes in the patterns of cytosine and adenine DNA base modifications, changes in cellular non-coding RNAs, and remodeling histone variants and covalent histone tail modifications. Some of these epigenetic changes have been shown to be long-lasting and may therefore contribute to stress memory and modulated stress tolerance in the progeny. In the emerging field of epitranscriptomics, defined as chemical, covalent modifications of ribonucleotides in cellular transcripts, epitranscriptomic modifications are postulated as more rapid modulators of gene expression. Although significant progress has been made in understanding the plant's epigenetic changes in response to biotic and abiotic stresses, a comprehensive review of the plant's epigenetic responses to metals is lacking. While the role of epitranscriptomics during plant developmental processes and stress responses are emerging, epitranscriptomic modifications in response to metals has not been reviewed. This article describes the impact of non-essential metals and metalloids (Cd, Pb, Hg, Al and As) on global and site-specific DNA methylation, histone tail modifications and epitranscriptomic modifications in plants.

Post-Translational Modifications in Histones and Their Role in Abiotic Stress Tolerance in Plants.

Abiotic stresses profoundly alter plant growth and development, resulting in yield losses. Plants have evolved adaptive mechanisms to combat these challenges, triggering intricate molecular responses to maintain tissue hydration and temperature stability during stress. A pivotal player in this defense is histone modification, governing gene expression in response to diverse environmental cues. Post-translational modifications (PTMs) of histone tails, including acetylation, phosphorylation, methylation, ubiquitination, and sumoylation, regulate transcription, DNA processes, and stress-related traits. This review comprehensively explores the world of PTMs of histones in plants and their vital role in imparting various abiotic stress tolerance in plants. Techniques, like chromatin immune precipitation (ChIP), ChIP-qPCR, mass spectrometry, and Cleavage Under Targets and Tag mentation, have unveiled the dynamic histone modification landscape within plant cells. The significance of PTMs in enhancing the plants' ability to cope with abiotic stresses has also been discussed. Recent advances in PTM research shed light on the molecular basis of stress tolerance in plants. Understanding the intricate proteome complexity due to various proteoforms/protein variants is a challenging task, but emerging single-cell resolution techniques may help to address such challenges. The review provides the future prospects aimed at harnessing the full potential of PTMs for improved plant responses under changing climate change.

177 Functional Annotation of an Array of Immune Cells and Various Tissues in the Chicken

Abstract Infection and disease negatively affect performance, growth, and health in production animals and has major economic impacts on commercial poultry production. Regulatory elements control the expression of genes and consequently phenotype. Epigenetic modifications such as histone tail modifications and DNA methylation are not only key to the regulation of unique transcriptome patterns, these modifications are indispensable as genome annotators to uncover cell- and tissue-specific regulatory elements. The objectives of our current projects are to leverage transcriptomic and epigenomic methods to annotate transcripts, coding and noncoding, and cis-regulatory elements in the chicken genome, including promoters, enhancers and insulators. In addition, we are employing single-cell sequencing to characterize new or rare cell populations in tissues relevant to production and investigate underlying mechanisms of disease resistance to pathogens. The transcriptome of a number of important cells and tissues has been analyzed, including immune, intestinal and reproductive. The animal procedure was approved and conducted according to guidelines established by the Western University of Health Sciences, Pomona, California (WesternU) Institutional Animal Care and Use Committee. Cell and tissue collection, processing and bioinformatic analysis for transcriptome studies were performed as described in Overbey et al. (2021; Frontiers Genetics). Single-cell studies were performed as described in Sparling et al. (2022; Journal of Immunology) using the 10x Genomics platform. Results for the transcriptome studies show that in the immune cells, many DEGs were mostly involved in cellular processes relating to differentiation and cell metabolism as well as basic functions of immune cells such as cell adhesion and signal transduction. This was to be expected, as there was no explicit immunological stimulus involved. Nevertheless, it was notable that DEGs in the comparison between bursa and thymus that were upregulated in the thymus were related to T cell differentiation and maturation. On the other hand, genes differentially upregulated in B cell vs Bursa or Bursa vs Thymus, are mostly involved in B cell development and differentiation, or activation. Genes differentially regulated in B cells and monocytes are involved in specific functions of the cell types. In the intestinal tissues, we were able to correlate most of the differential expressed genes to metabolic processes related to nutrient digestion and absorption. Several genes in the distal part of the intestine were particularly implicated in vitamin metabolism. Genes involved in energy metabolism are also abundant in the cecum, which suggests that microbial contribution of energy production in the intestine is especially important. Finally, single cell studies on the chicken shell gland are ongoing, but we found differences in cellular populations and gene expression dependent on the chicken haplotype profiled and differences in expression of Ig-like receptors that need to be further explored.

Mass Cytometry as a Tool for Investigating Senescence in Multiple Model Systems.

Cellular senescence is a durable cell cycle arrest as a result of the finite proliferative capacity of cells. Senescence responds to both intrinsic and extrinsic cellular stresses, such as aging, mitochondrial dysfunction, irradiation, and chemotherapy. Here, we report on the use of mass cytometry (MC) to analyze multiple model systems and demonstrate MC as a platform for senescence analysis at the single-cell level. We demonstrate changes to p16 expression, cell cycling fraction, and histone tail modifications in several established senescent model systems and using isolated human T cells. In bone marrow mesenchymal stromal cells (BMSCs), we show increased p16 expression with subsequent passage as well as a reduction in cycling cells and open chromatin marks. In WI-38 cells, we demonstrate increased p16 expression with both culture-induced senescence and oxidative stress-induced senescence (OSIS). We also use Wanderlust, a trajectory analysis tool, to demonstrate how p16 expression changes with histone tail modifications and cell cycle proteins. Finally, we demonstrate that repetitive stimulation of human T cells with CD3/CD28 beads induces an exhausted phenotype with increased p16 expression. This p16-expressing population exhibited higher expression of exhaustion markers such as EOMES and TOX. This work demonstrates that MC is a useful platform for studying senescence at a single-cell protein level, and is capable of measuring multiple markers of senescence at once with high confidence, thereby improving our understanding of senescent pathways.

The SETD2 Methyltransferase Supports Productive HPV31 Replication through the LEDGF/CtIP/Rad51 Pathway.

The human papillomavirus (HPV) life cycle takes place in the stratified epithelium, with the productive phase being activated by epithelial differentiation. The HPV genome is histone-associated, and the life cycle is epigenetically regulated, in part, by histone tail modifications that facilitate the recruitment of DNA repair factors that are required for viral replication. We previously showed that the SETD2 methyltransferase facilitates the productive replication of HPV31 through the trimethylation of H3K36 on viral chromatin. SETD2 regulates numerous cellular processes, including DNA repair via homologous recombination (HR) and alternative splicing, through the recruitment of various effectors to histone H3 lysine 36 trimethylation (H3K36me3). We previously demonstrated that the HR factor Rad51 is recruited to HPV31 genomes and is required for productive replication; however, the mechanism of Rad51 recruitment has not been defined. SET domain containing 2 (SETD2) promotes the HR repair of double-strand breaks (DSBs) in actively transcribed genes through the recruitment of carboxy-terminal binding protein (CtBP)-interacting protein (CtIP) to lens epithelium-derived growth factor (LEDGF)-bound H3K36me3, which promotes DNA end resection and thereby allows for the recruitment of Rad51 to damaged sites. In this study, we found that reducing H3K36me3 through the depletion of SETD2 or the overexpression of an H3.3K36M mutant leads to an increase in γH2AX, which is a marker of damage, on viral DNA upon epithelial differentiation. This is coincident with decreased Rad51 binding. Additionally, LEDGF and CtIP are bound to HPV DNA in a SETD2-dependent and H3K36me3-dependent manner, and they are required for productive replication. Furthermore, CtIP depletion increases DNA damage on viral DNA and blocks Rad51 recruitment upon differentiation. Overall, these studies indicate that H3K36me3 enrichment on transcriptionally active viral genes promotes the rapid repair of viral DNA upon differentiation through the LEDGF-CtIP-Rad51 axis. IMPORTANCE The productive phase of the HPV life cycle is restricted to the differentiating cells of the stratified epithelium. The HPV genome is histone-associated and subject to epigenetic regulation, though the manner in which epigenetic modifications contribute to productive replication is largely undefined. In this study, we demonstrate that SETD2-mediated H3K36me3 on HPV31 chromatin promotes productive replication through the repair of damaged DNA. We show that SETD2 facilitates the recruitment of the homologous recombination repair factors CtIP and Rad51 to viral DNA through LEDGF binding to H3K36me3. CtIP is recruited to damaged viral DNA upon differentiation, and, in turn, recruits Rad51. This likely occurs through the end resection of double-strand breaks. SETD2 trimethylates H3K36me3 during transcription, and active transcription is necessary for Rad51 recruitment to viral DNA. We propose that the enrichment of SETD2-mediated H3K36me3 on transcriptionally active viral genes upon differentiation facilitates the repair of damaged viral DNA during the productive phase of the viral life cycle.

Physical basis of the cell size scaling laws.

Cellular growth is the result of passive physical constraints and active biological processes. Their interplay leads to the appearance of robust and ubiquitous scaling laws relating linearly cell size, dry mass, and nuclear size. Despite accumulating experimental evidence, their origin is still unclear. Here, we show that these laws can be explained quantitatively by a single model of size regulation based on three simple, yet generic, physical constraints defining altogether the Pump-Leak model. Based on quantitative estimates, we clearly map the Pump-Leak model coarse-grained parameters with the dominant cellular components. We propose that dry mass density homeostasis arises from the scaling between proteins and small osmolytes, mainly amino acids and ions. Our model predicts this scaling to naturally fail, both at senescence when DNA and RNAs are saturated by RNA polymerases and ribosomes, respectively, and at mitotic entry due to the counterion release following histone tail modifications. Based on the same physical laws, we further show that nuclear scaling results from a osmotic balance at the nuclear envelope and a large pool of metabolites, which dilutes chromatin counterions that do not scale during growth.

Plant mobile domain proteins ensure Microrchidia 1 expression to fulfill transposon silencing.

Silencing of transposable elements (TEs) is an essential process to maintain genomic integrity within the cell. In Arabidopsis, together with canonical epigenetic pathways such as DNA methylation and modifications of histone tails, the plant mobile domain (PMD) proteins MAINTENANCE OF MERISTEMS (MAIN) and MAIN-LIKE 1 (MAIL1) are involved in TE silencing. In addition, the MICRORCHIDIA (MORC) ATPases, including MORC1, are important cellular factors repressing TEs. Here, we describe the genetic interaction and connection between the PMD and MORC pathways by showing that MORC1 expression is impaired in main and mail1 mutants. Transcriptomic analyses of higher order mutant plants combining pmd and morc1 mutations, and pmd mutants in which MORC1 expression is restored, show that the silencing defects of a subset of TEs in pmd mutants are most likely the consequence of MORC1 down-regulation. Besides, a significant fraction of up-regulated TEs in pmd mutants are not targeted by the MORC1 pathway.

Targeting chromatin mediated cellular plasticity in vivo.

Advances in cancer treatment, including precision oncology, are significantly hindered by cancer cell plasticity. The ability to adapt to various external stressors is due to two attributes of highly plastic cells: transcriptional malleability, which is the ability of a cell to quickly upregulate survival pathways, and transcriptional heterogeneity, or the variance in the pathways utilized by cells to evade cell death. Both aspects of phenotypic plasticity have been directly linked to a measure of statistical chromatin organization, the chromatin packing scaling D, which facilitates changes in gene expression. To study the role of chromatin in plasticity-mediated survival, we performed time-course imaging of chemotherapy-treated cancer cells using label-free Partial Wave Spectroscopic (PWS) microscopy. The population distribution of D shifted over the course of treatment such that all surviving cells exhibited high D values. Accordingly, cell cluster tracking demonstrated a negative correlation between the initial D and the increase in D induced by treatment. We developed a computational model of cell fate based on changes in transcription due to D, which could recapitulate experimental results. We predicted that pharmacologically lowering D would reduce plasticity and improve chemotherapeutic efficacy. Specifically, we screened compounds that would lower D by facilitating chromatin-nucleoplasm interactions through either histone tail modifications or changes in the nuclear ionic environment. Adding a D-lowering agent to chemotherapy treatment increased the probability of cell death compared to chemotherapy alone, which matched model predictions. We next tested these treatments in vivo in a PDX model where our model predicted that although tumors would still be able to adapt to chemotherapy treatment, the combination treatment would exhibit a higher cell growth inhibition rate and stunt tumor adaptation. Significantly, our results demonstrated that lowering D improves treatment outcomes even in a conservative treatment with low-dose chemotherapy.

Mesoscale chromatin organization is regulated by active transcription and epigenetic regulation.

Epigenetically regulated post-translational modifications of histone tails via acetylation or methylation have been established to play a role in determining the transcriptional status of genes. Beyond epigenetic regulation, chromatin loop extrusion through cohesin rings, driven by transcription-generated DNA supercoiling, can also alter spatial chromatin organization. Here, we present a mesoscale phase-field model to explain the underlying physics of chromatin reorganization in the presence of transcriptionally driven chromatin loop extrusion. The model incorporates energetic considerations of chromatin-chromatin and chromatin-lamina interactions leading to phase separation in the interior and periphery of the nucleus. We incorporate the kinetics of the diffusion of nucleoplasm and epigenetic marks. In addition, a non-conservative interconversion of euchromatin and heterochromatin is captured by incorporating first-order reaction kinetics of histone methylation and acetylation. Lastly, and vitally, the extrusion of genetically expressive chromatin enhancer-promoter loops is included via a kinetic conversion of heterochromatin into euchromatin in the presence of RNAPII-mediated transcriptional activity. Our theoretical analysis predicts that the size of the stable heterochromatin domains is determined solely by the kinetics of acetylation, methylation, and chromatin loop extrusion. Our numerical simulations, in conjunction with the super-resolution in-vitro nucleus imaging techniques, reveal that the absence of transcription increases chromatin compaction and heterochromatin domain sizes in the nucleus's interior and periphery. We also predict that enhanced chromatin loop extrusion would result in reduced sizes of heterochromatin domains - which is validated by super-resolution imaging of WAPL-deficient nuclei. Lastly, we reveal the synergistic effects of WAPL deficiency and transcriptional abrogation such that chromatin decompaction in WAPL-deficient nuclei is blocked by inhibiting transcription. By uncovering the physical mechanisms of mesoscale chromatin organization in the nucleus, our model presents a new step in understanding how cell fate is affected by its chemo-mechanical environment.

Architecture and function of the meiotic metazoan HORMAD chromatin binding region (CBR).

During early meiotic prophase, the chromosome axis is formed by DNA-binding cohesin proteins, filamentous axis core proteins, and meiotic HORMA domain (HORMAD) proteins. HORMADs are master regulators of meiotic recombination, recruiting Spo11 and associated proteins to create DNA double-strand breaks (DSBs) and promoting their repair as interhomolog crossovers (COs). In earlier work, we discovered a central chromatin binding region (CBR) domain in the S. cerevisiae HORMAD protein Hop1 (SNU, unpublished), and further found that diverse eukaryotes including many plants and metazoans within the opisthokonta family also possess a central CBR with variable architecture. In fungi such as Vanderwaltozyma polyspora and Saccharomyces cerevisiae, Hop1 has an internal CBR domain containing a variant plant homeodomain (PHD) zinc finger domain and a DNA-binding winged helix-turn-helix domain (wHTH), plus a conserved C-terminal extension (HTH-C). Similarly, metazoan HORMAD CBR domains are predicted to contain a canonical PHD domain and a wHTH domain. Here we show two x-ray crystal structures of metazoan HORMAD CBRs from Schistosoma mansoni (blood fluke) and Patiria miniata (starfish). Both structures contain PHD and wHTH domains like the fungal Hop1 CBR, but do not contain a C-terminal extension (HTH-C). The PHD domain contains two beta strands with a conserved pocket that we propose binds a histone tail. We are currently pursuing both biochemical and cell-based approaches to determine the molecular basis for the HORMAD CBR-chromatin interaction and identify any specificity for histone tail modifications. This work will define how the HORMAD CBR modulates chromosome axis architecture and localization in diverse eukaryotes.

A direct nuclear magnetic resonance method to investigate lysine acetylation of intrinsically disordered proteins.

Intrinsically disordered proteins are frequent targets for functional regulation through post-translational modification due to their high accessibility to modifying enzymes and the strong influence of changes in primary structure on their chemical properties. While lysine Nε-acetylation was first observed as a common modification of histone tails, proteomic data suggest that lysine acetylation is ubiquitous among both nuclear and cytosolic proteins. However, compared with our biophysical understanding of the other common post-translational modifications, mechanistic studies to document how lysine Nε-acetyl marks are placed, utilized to transduce signals, and eliminated when signals need to be turned off, have not kept pace with proteomic discoveries. Herein we report a nuclear magnetic resonance method to monitor Nε-lysine acetylation through enzymatic installation of a13C-acetyl probe on a protein substrate, followed by detection through 13C direct-detect spectroscopy. We demonstrate the ease and utility of this method using histone H3 tail acetylation as a model. The clearest advantage to this method is that it requires no exogenous tags that would otherwise add steric bulk, change the chemical properties of the modified lysine, or generally interfere with downstream biochemical processes. The non-perturbing nature of this tagging method is beneficial for application in any system where changes to local structure and chemical properties beyond those imparted by lysine modification are unacceptable, including intrinsically disordered proteins, bromodomain containing protein complexes, and lysine deacetylase enzyme assays.

DNA methylation in the pathogenesis of type 2 diabetes.

Type 2 diabetes (T2D) is a metabolic disease characterized by the development of β-cell dysfunction with hepatic, muscular and adipose tissue insulin resistance. Although the molecular mechanisms leading to its development are not entirely known, investigations of its causes reveal a multifactorial contribution to its development and progression in most cases. In addition, regulatory interactions mediated by epigenetic modifications such as DNA methylation, histone tail modifications and regulatory RNAs have been found to play a significant role in the etiology of T2D. In this chapter, we discuss the role of DNA methylation and its dynamics in the development of the pathological features of T2D.

Dynamic play between human N-α-acetyltransferase D and H4-mutant histones: Molecular dynamics study.

Many N-terminal acetyltransferases (NATs) enzymes play important role in the post-translational modification of histone tails. Research showed that these enzymes have been reported upregulated in many cancers. NatD is known to acetylate H4/H2A at the N-terminal. During lung cancer, this enzyme competes with the protein kinase CK2α and blocks the phosphorylation of H4 and, acetylates. Also, we observed that H4 has various mutations at the N-terminal and we considered only four mutations (S1C, R3C, G4D and G4S) to study the impacts of these mutations on H4 binding with NatD using MD simulation. Our main objective in this study was to understand the structure and dynamics of hNatD under the influence of WT and MT H4 histones bindings. The previous experimental study reported that mutations on H4 N-terminus reduce the catalytic efficiency of N-Terminal acetylation. But here, we performed a molecular-level study thus, we can understand how these mutations (S1C, R3C, G4D and G4S) cause significant depletion in catalytic efficiency of hNatD. Purely computational approaches were employed to investigate the impacts of four mutations in human histone H4 on its binding with the N-α-acetyltransferase D. Initially, molecular docking was used to dock the histone H4 peptide with the N-α-acetyltransferase. Next, all-atom molecular dynamics simulations were performed to probe the structural deviation and dynamics of N-α-acetyltransferase D under the binding of WT and MT H4 histones. Our results show that R3C stabilizes the NatD whereas the remaining mutations destabilize the NatD. Thus, mutations have significant impacts on NatD structure. Our finding supports the previous analysis also. Another interesting observation is that the enzymatic activity of hNatD is altered due to the considerably large deviation of acetyl-CoA from its original position (G4D). Further, simulation and correlation data suggest which regions of the hNatD are highly flexible and rigid and, which domains or residues have the correlation and anticorrelation. As hNatD is overexpressed in lung cancer, it is an important drug target for cancer hence, our study provides structural information to target hNatD. In this study, we examined the impacts of WT and MTs (S1C, R3C, G4D and G4S) histone H4 decapeptides on their bindings with hNatD by using 100 ns all-atom MD simulation. Our results support the previous finding that the mutant H4 histones reduce the catalytic efficiency of hNatD. The MD post-trajectory analyses revealed that S1C, G4S and G4D mutants remarkably alter the residue network in hNatD. The intramolecular hydrogen bond analysis suggested that there is a considerable number of losses of hydrogen bonds in hNatD of hNatD-H4_G4D and hNatD-H4_G4S complexes whereas a large number of hydrogen bonds were increased in hNatD of hNatD-H4_R3C complex during the entire simulations. This implies that R3C mutant binding to hNatD brings stability in hNatD in comparison with WT and other MTs complexes. The linear mutual information (LMI) and Betweenness centrality (BC) suggests that S1C, G4D and G4S significantly disrupt the catalytic site residue network as compared to R3C mutation in H4 histone. Thus, this might be the cause of a notable reduction in the catalytic efficiency of hNatD in these three mutant complexes. Further, interaction analysis supports that E126 is the important residue for the acetyltransferase mechanisms as it is dominantly found to have interactions with numerous residues of MTs histones in MD frames. Additionally, intermolecular hydrogen bond and RMSD analyses of acetyl-CoA predict the higher stability of acetyl-CoA inside the WT complex of hNatD and R3C complex. Also, we report here the structural and dynamic aspects and residue interactions network (RIN) of hNatD to target it to control cell proliferation in lung cancer conditions.