Histone Deacetylation Research Articles

Integration of CRISPR/dCas9-Based methylation editing with guide positioning sequencing identifies dynamic changes of mrDEGs in breast cancer progression

Dynamic changes in DNA methylation are prevalent during the progression of breast cancer. However, critical alterations in aberrant methylation and gene expression patterns have not been thoroughly characterized. Here, we utilized guide positioning sequencing (GPS) to conduct whole-genome DNA methylation analysis in a unique human breast cancer progression model: MCF10 series of cell lines (representing benign/normal, atypical hyperplasia, and metastatic carcinoma). By integrating with mRNA-seq and matched clinical expression data from The Cancer Genome Atlas (TCGA) and the Gene Expression Omnibus (GEO), six representative methylation-related differentially expressed genes (mrDEGs) were identified, including CAVIN2, ARL4D, DUSP1, TENT5B, P3H2, and MMP28. To validate our findings, we independently developed and optimized the dCas9-DNMT3L-DNMT3A system, achieving a high efficiency with a 98% increase in methylation at specific sites. DNA methylation levels significantly increased for the six genes, with CAVIN2 at 67.75 ± 1.05%, ARL4D at 53.29 ± 6.32%, DUSP1 at 57.63 ± 8.46%, TENT5B at 44.00 ± 5.09%, P3H2 at 58.50 ± 3.90%, and MMP28 at 49.60 ± 5.84%. RT-qPCR confirmed an inverse correlation between increased DNA methylation and gene expression. Most importantly, we mimicked tumor progression in vitro, demonstrating that transcriptional silencing of the TENT5B promotes cell proliferation in MCF10A cells owing to the crosstalk between hypermethylation and histone deacetylation. This study unveils the practical implications of DNA methylation dynamics of mrDEGs in reshaping epigenomic features during breast cancer malignant progression through integrated data analysis of the methylome and transcriptome. The application of the CRISPR/dCas9-based methylation editing technique elucidates the regulatory mechanisms and functional roles of individual genes within the DNA methylation signature, providing valuable insights for understanding breast cancer pathogenesis and facilitating potential therapeutic approaches in epigenome editing for patients with breast cancer.

TEC-mediated tRF-31R9J regulates histone lactylation and acetylation by HDAC1 to suppress hepatocyte ferroptosis and improve non-alcoholic steatohepatitis

BackgroundTectorigenin (TEC) is a monomer of anthocyanin, which we found exhibits hepatoprotective effects. tRNA-derived fragments (tRFs) and ferroptosis play important roles in the pathogenesis of non-alcoholic steatohepatitis (NASH). Recent discoveries have revealed that histone lactylation and acetylation play a crucial role in connecting cellular metabolism and epigenetic regulation through post-translational modification of histones. However, it is unclear whether TEC improves NASH by regulating histone lactylation, acetylation and hepatocyte ferroptosis through tRFs.ResultsIn this study, we demonstrated that TEC significantly inhibits free fatty acids-induced hepatocyte ferroptosis both in vitro and in vivo. We identified tRF-31R9J (tRF-31-R9JP9P9NH5HYD) involved in TEC regulation of ferroptosis in steatosis hepatocytes. Overexpression of tRF-31R9J suppressed hepatocyte ferroptosis and enhanced cell viability in steatosis HepG2 cells. Knockdown of tRF-31R9J partially counteracted the inhibitory effect of TEC on ferroptosis in hepatocytes. Mechanistically, tRF-31R9J recruited HDAC1 to reduce the levels of histone lactylation and acetylation modifications of the pro-ferroptosis genes ATF3, ATF4, and CHAC1, thereby inhibiting their gene expression.ConclusionsThis study demonstrates that TEC-mediated tRF-31R9J inhibits hepatocyte ferroptosis through HDAC1-regulated histone delactylation and deacetylation, thereby improving NASH. These discoveries offer a theoretical foundation and new strategies for the medical management of NASH.

Histone Deacetylation in Alzheimer's Diseases (AD); Hope or Hype.

Histone acetylation is the process by which histone acetyltransferases (HATs) add an acetyl group to the N-terminal lysine residues of histones, resulting in a more open chromatin structure. Histone acetylation tends to increase gene expression more than methylation does. In the central nervous system (CNS), histone acetylation is essential for controlling the expression of genes linked to cognition and learning. Histone deacetylases (HDACs), "writing" enzymes (HATs), and "reading" enzymes with bromodomains that identify and localize to acetylated lysine residues are responsible for maintaining histone acetylation. By giving animals HDAC inhibitors (HDACis), it is possible to intentionally control the ratios of "writer" and "eraser" activity, which will change the acetylation of histones. In addition to making the chromatin more accessible, these histone acetylation alterations re-allocate the targeting of "readers," including the transcriptional co-activators, cAMP response element-binding protein (CBP), and bromodomain-containing protein 4 (Brd4) in the CNS. Conclusive evidence has shown that HDACs slow down the progression of Alzheimer's disease (AD) by reducing the amount of histone acetylation, decreasing the activity of genes linked to memory, supporting cognitive decline and Amyloid beta (Aβ) protein accumulation, influencing aberrant tau phosphorylation, and promoting the emergence of neurofibrillary tangles (NFTs). In this review, we have covered the therapeutic targets and functions of HDACs that might be useful in treating AD.

HDC1 Promotes Primary Root Elongation by Regulating Auxin and K+ Homeostasis in Response to Low-K+ Stress.

Plants frequently encounter relatively low and fluctuating potassium (K+) concentrations in soil, with roots serving as primary responders to this stress. Histone modifications, such as de-/acetylation, can function as epigenetic markers of stress-inducible genes. However, the signaling network between histone modifications and low-K+ (LK) response pathways remains unclear. This study investigated the regulatory role of Histone Deacetylase Complex 1 (HDC1) in primary root growth of Arabidopsis thaliana under K+ deficiency stress. Using a hdc1-2 mutant line, we observed that HDC1 positively regulated root growth under LK conditions. Compared to wild-type (WT) plants, the hdc1-2 mutant exhibited significantly inhibited primary root growth under LK conditions, whereas HDC1-overexpression lines displayed opposite phenotypes. No significant differences were observed under HK conditions. Further analysis revealed that the inhibition of hdc1-2 on root growth was due to reduced apical meristem cell proliferation rather than cell elongation. Notably, the root growth of hdc1-2 showed reduced sensitivity compared to WT after auxin treatment under LK conditions. HDC1 may regulate root growth by affecting auxin polar transport and subsequent auxin signaling, as evidenced by the altered expression of auxin transport genes. Moreover, the organ-specific RT-qPCR analyses unraveled that HDC1 negatively regulates the expression of CBL-CIPK-K+ channel-related genes such as CBL1, CBL2, CBL3, AKT1, and TPK1, thereby establishing a molecular link between histone deacetylation, auxin signaling, and CBLs-CIPKs pathway in response to K+ deficiency.

HDAC6: Tumor Progression and Beyond.

Histone Deacetylase 6 (HDAC6) is an intriguing therapeutic target in cancer re-search, distinguished as the only HDAC family member predominantly located in the cyto-plasm. HDAC6 features two catalytic domains and a unique ubiquitin-binding domain, which sets it apart from other HDACs. Beyond its role in histone deacetylation, HDAC6 targets vari-ous nonhistone substrates, such as α-tubulin, cortactin, Heat Shock Protein 90 (HSP90), and Heat Shock Factor 1 (HSF1). Its involvement spans critical aspects of tumor progression, in-cluding invasion, metastasis, angiogenesis, drug resistance, stemness, and the reduction of tu-mor cell immunogenicity. Given these functions, HDAC6 inhibitors are emerging as valuable tools in the treatment of both solid and hematological tumors. Recent advancements have seen several HDAC6 inhibitors to enter clinical trials, with promising outcomes reported. This re-view covers the structural features of HDAC6, its biological roles, and its impact on tumor development, particularly focusing on progression-related events. Additionally, a detailed dis-cussion of preclinical and clinical trials involving selective HDAC6 inhibitors is provided.

CTSG is a prognostic marker involved in immune infiltration and inhibits tumor progression though the MAPK signaling pathway in non-small cell lung cancer

PurposeThis study aims to investigate the biological roles and molecular mechanisms of Cathepsin G (CTSG) in the progression of non-small cell lung cancer (NSCLC).MethodsWestern blotting and immunohistochemistry analyses of clinical samples were performed to determine the expression levels of CTSG in patients with NSCLC. Bioinformatic analysis of clinical datasets was conducted to evaluate the correlation between CTSG and lymph node metastasis, tumor stage, and immune cell infiltration. Gain-of-function assays and tumor implantation experiments were employed to determine the effects of CTSG on malignant behaviors of NSCLC cells. Transcriptome sequencing and subsequent bioinformatic analysis were performed to explore the signaling pathways regulated by CTSG. Western blotting and qPCR were utilized to assess the influence of CTSG on the MAPK and EMT signaling pathways.ResultsCTSG is expressed at low levels and serves as a prognostic marker in NSCLC. The downregulation of CTSG expression was associated with lymph node metastasis, tumor stage, and immune cell infiltration. CTSG inhibits NSCLC cell proliferation, migration, and invasion as well as tumor growth in nude mice. There exists a significant correlation between CTSG expression and endoplasmic reticulum function, cell cycling, and the IL-17 signaling pathway. CTSG suppresses the MAPK and EMT signaling pathways in NSCLC cells. Moreover, DNA methylation and histone deacetylation have been identified as crucial mechanisms contributing to the decreased expression of CTSG.ConclusionCTSG inhibits NSCLC development by suppressing the MAPK signaling pathway and is also associated with tumor immunity.

Histone Modification-Dependent Transcriptional Regulation of Defence Genes in Early Response of Arabidopsis to Spodoptera litura Attack.

Histone modification is a cellular process for transcriptional regulation. In herbivore-damaged plants, activation of genes involved in defence responses is required for antiherbivore properties, but little is known about how the chromatin remodelling system is involved. In Arabidopsis (Arabidopsis thaliana) plants responding to Spodoptera litura larvae, HAC1 and HDA6, a histone acetyltransferase and a histone deacetylase, respectively, were found here to be involved in histone H3 (Lys9; H3K9) acetylation/deacetylation at the promoter region of the plant defensin gene PDF1.2 and the gene body of ethylene response factor 13 (ERF13) as early as 2 h after the onset of herbivore attack. The H3K9 acetylation was responsible for the robust upregulation of PDF1.2 later, at 24 h, and ERF13 even earlier, at 1 h. TOPLESS (TPL) and TOPLESS-related (TPR) corepressors interacted with HDA6 to deacetylate H3K9 at PDF1.2 and ERF13, while negatively regulating the expression of PDF1.2 but not ERF13. Furthermore, TPL also interacted with ERF13, resulting in ERF13-mediated regulation of PDF1.2. Taken together, these data suggest a model of promoter-restricted, TPL/TPR-directed histone deacetylation and transcription factor repression in healthyArabidopsis plants for the feedback regulation of the antiherbivore response.

Radiomic Consensus Clustering in Glioblastoma and Association with Gene Expression Profiles.

Glioblastoma (GBM) is the most common malignant primary central nervous system tumor with extremely poor prognosis and survival outcomes. Non-invasive methods like radiomic feature extraction, which assess sub-visual imaging features, provide a potentially powerful tool for distinguishing molecular profiles across groups of patients with GBM. Using consensus clustering of MRI-based radiomic features, this study aims to investigate differential gene expression profiles based on radiomic clusters. Patients from the TCGA and CPTAC datasets (n = 114) were included in this study. Radiomic features including T1, T1 with contrast, T2, and FLAIR MRI sequences were extracted using PyRadiomics. Selected radiomic features were then clustered using ConsensusClusterPlus (k-means base algorithm and Euclidean distance), which iteratively subsamples and clusters 80% of the data to identify stable clusters by calculating the frequency in which each patient is a member of a cluster across iterations. Gene expression data (available for n = 69 patients) was analyzed using differential gene expression (DEG) and gene set enrichment (GSEA) approaches, after batch correction using ComBat-seq. Three distinct clusters were identified based on the relative consensus matrix and cumulative distribution plots (Cluster 1, n = 25; Cluster 2, n = 46; Cluster 3, n = 43). No significant differences in patient demographic characteristics, MGMT methylation status, tumor location, or overall survival were identified across clusters. Differentially expressed genes were identified in Cluster 1, which have been previously associated with GBM prognosis, recurrence, and treatment sensitivity. GSEA of Cluster 1 showed an enrichment of genes upregulated for immune-related and DNA metabolism pathways and genes downregulated in pathways associated with protein and histone deacetylation. Clusters 2 and 3 exhibited fewer DEGs which failed to reach significance after multiple testing corrections. Consensus clustering of radiomic features revealed unique gene expression profiles in the GBM cohort which likely represent subtle differences in tumor biology and radiosensitivity that are not visually discernible, underscoring the potential of radiomics to serve as a non-invasive alternative for identifying GBM molecular heterogeneity. Further investigation is still required to validate these findings and their clinical implications.

Rapid degradation of histone deacetylase 1 (HDAC1) reveals essential roles in both gene repression and active transcription.

Histone Deacetylase 1 (HDAC1) removes acetyl groups from lysine residues on core histones, a critical step in regulating chromatin accessibility. Despite histone deacetylation being an apparently repressive activity, suppression of HDACs causes both up- and downregulation of gene expression. Here we exploited the degradation tag (dTAG) system to rapidly degrade HDAC1 in mouse embryonic stem cells (ESCs) lacking its paralog, HDAC2. The dTAG system allowed specific degradation and removal of HDAC1 in<1 h (100x faster than genetic knockouts). This rapid degradation caused increased histone acetylation in as little as 2 h, with H2BK5 and H2BK11 being the most sensitive. The majority of differentially expressed genes following 2 h of HDAC1 degradation were upregulated (275 genes up versus 15 down) with increased proportions of downregulated genes observed at 6 h (1153 up versus 443 down) and 24 h (1146 up versus 967 down), respectively. Upregulated genes showed increased H2BK5ac and H3K27ac around their transcriptional start site (TSS). In contrast, decreased acetylation and chromatin accessibility of super-enhancers was linked to the most strongly downregulated genes. These findings suggest a paradoxical role for HDAC1 in the maintenance of histone acetylation levels at critical enhancer regions required for the pluripotency-associated gene network.

The SIRT6 allosteric activator MDL-800 suppresses calcium oxalate nephrocalcinosis by alleviating inflammatory and renal damage.

Kidney stones consist largely of calcium oxalate (CaOx), and induce inflammation and damage to renal tubular epithelial (RTE) cells, leading to CaOx nephrocalcinosis. Sirtuin 6 (SIRT6), a sirtuin family member, is an NAD-dependent deacetylase that has been associated with cell damage and inflammation in various diseases. This study evaluated the efficacy of the novel SIRT6 allosteric agonist MDL-800 in treating CaOx nephrocalcinosis. The data revealed that MDL-800 preconditioning alleviated CaOx crystal-mediated damage in RTE cells by suppressing inflammation, as shown in both cell and animal studies. Furthermore, MDL-800 enhanced SIRT6 deacetylation at H3K9AC. However, MDL-800 pretreatment of SIRT6-knockdown (KD) RTE cells did not protect against CaOx crystal-induced cell damage and inflammation. Mechanistically, MDL-800 markedly downregulated the expression of IL-1β, TNF-α, MCP-1, and IL-6 in mouse kidneys via the TRL4/NF-κB pathway. These data indicated that MDL-800 reduces inflammation and inhibits the TLR4/NF-κB axis by increasing SIRT6-modulated histone deacetylation, thus inhibiting and protecting against inflammatory responses. In summary, MDL-800 modulation of SIRT6-mediated inflammation and renal damage represents a novel strategy for treating CaOx-mediated nephrocalcinosis.

Epigenetics of oogenesis.

Epigenetic changes include all modifications affecting the expression of genes without changing the nucleotide sequence of the genome. Most studied epigenetic changes include DNA methylation, histone alterations and non-coding RNAs. DNA methylation is an important epigenetic mark, protecting the genome during gametogenesis and early embryo development. Demethylation process is a genome-wide event, taking place in two distinct waves during gametogenesis. The first event helps restore naïve pluripotency of the zygote, while the second event aids in the loss of parental epigenetic memory and facilitates specification of gametes. Histone modifications were recognized in murine and human primordial germ cells where their subsets condense chromatin, protecting it from dynamic changes taking place during gamete maturation. Deacetylation of histones was recognized as an important prerequisite of chromosomal segregation during metaphase II. Germline-specific ncRNAs and piRNAs are important in inhibiting transposon activity during gametogenesis, protecting overall genome stability. All epigenetic changes are prone to disruption, especially by exogenous factors. In recent years, with the increase in infertility, the association between assisted reproductive technology (ART) and its effects on epigenome remodeling of gametes have gained importance. The aim of this review is to summarize the epigenetic modifications crucial for oocyte development, while highlighting their role in reproductive disorders and ART.

Gain of pancreatic beta cell-specific SCD1 improves glucose homeostasis by maintaining functional beta cell mass under metabolic stress.

The key pancreatic beta cell transcription factor v-maf musculoaponeurotic fibrosarcoma oncogene homologue A (MafA) is critical for the maintenance of mature beta cell function and phenotype. The expression levels and/or activities of MafA are reduced when beta cells are chronically exposed to diabetogenic stress, such as hyperglycaemia (i.e. glucotoxicity). Interventional targets and adjuvant therapies to abate MafA loss in beta cells may provide evidence to support the effective treatment of diabetes. In this study, we aimed to investigate the function of stearoyl-CoA desaturase 1 (SCD1) in the stabilisation of MafA expression and activity in order to maintain functional beta cell mass, with a view to suppressing the development of type 2 diabetes. SCD1 expression levels were analysed in islets obtained from humans with type 2 diabetes, hyperglycaemic db/db mice, and a high-fat diet (HFD)-induced mouse model of diabetes. Pancreatic beta cell-specific Scd1 knockin (βSCD1KI) mice were generated to study the role of SCD1 in beta cell function and identity. The protein-to-protein interactions between SCD1 and MafA were detected in MIN6 and HEK293A cells. We used experiments including chromatin immunoprecipitation, cell-based ubiquitination assay and fatty acid composition analysis to investigate the specific molecular mechanism underlying the effect of SCD1 on the restoration of MafA and beta cell function under glucotoxic conditions. SCD1 expression was reduced in beta cells of humans with type 2 diabetes and in HFD-fed and db/db mice compared with healthy controls, which was attributed to glucotoxicity-induced Scd1 promoter histone deacetylation. Gain-of-function of SCD1 in beta cells improved insulin deficiency, glucose intolerance and beta cell dedifferentiation/transdifferentiation in the HFD-induced mouse model of diabetes. Mechanistically, SCD1 directly bound to the E3 ubiquitin ligase HMG-CoA reductase degradation 1 (HRD1) and stabilised nuclear MafA through interrupting MafA-HRD1 interactions in mouse islets and MIN6 cells, which inhibited the ubiquitination-mediated degradation of MafA. Moreover, the products of SCD enzyme reactions (mainly oleic acid) also alleviated glucotoxicity-mediated oxidative stress in MIN6 cells. Our findings indicate that SCD1 stabilises beta cell MafA both in desaturase-dependent and -independent manners, thus improving glucose homeostasis under metabolic stress. This provides a potential novel target for precision medicine for the treatment of diabetes.

Transcriptional Cofactors for Thyroid Hormone Receptors.

Thyroid hormone (TH) is essential throughout life. It's actions are mediated primarily by the thyroid hormone receptor (THR), which is a nuclear receptor. Classically, the THRs act as inducible transcription factors. In the absence of TH, a corepressor complex is recruited to the THR to limit TH-related gene expression. In the presence of TH, the corepressor complex is dismissed and a coactivator complex is recruited to facilitate TH-related gene expression. These coregulators can interact with multiple nuclear receptors and are also key in maintaining normal physiologic function. The nuclear receptor corepressor 1 (NCOR1) and the nuclear receptor corepressor 2 (NCOR2) have been the most extensively studied corepressors of the THR involved in histone deacetylation. The steroid receptor coactivator/p160 (SRC) family and in particular, SRC-1, plays a key role in histone acetylation associated with the THR. The Mediator Complex is also required for pretranscription machinery assembly. This mini-review focuses on how these transcriptional cofactors influence TH-action and signaling, primarily via histone modifications.

The OsNL1-OsTOPLESS2-OsMOC1/3 pathway regulates high-order tiller outgrowth in rice.

Tiller is an important factor in determining rice yield. Currently, researches mainly focus on the outgrowth of low-order tiller (LOT), while the regulation mechanism of high-order tiller (HOT) outgrowth has remained unknown. In this study, we detected one OsNL1 mutant, nl1, exhibiting HOT numbers increase, and found that OsNL1 interacts with OsTOPLESS2, which was mediated by the core motif of nine amino acids VDCTLSLGT within the HAN domain of OsNL1. The topless2 mutant exhibits similar HOT number increase as in the nl1. Through ChIP-seq analysis, we revealed that OsNL1 recruits OsTOPLESS2 to conduct histone deacetylation in the promoters of OsMOC1 and OsMOC3 to regulate HOT outgrowth. Moreover, we showed that the HAN domain is essential for OsNL1 function as a repressor. In summary, our study reveals partial mechanism of HOT outgrowth in rice and deciphers the molecular biology function of the HAN domain. This will contribute to the comprehensive understanding of tiller outgrowth and the role of HAN-domain-containing genes.

Nzf2 promotes oligodendrocyte differentiation and regeneration via repressing HDAC1-mediated histone deacetylation.

Proper axonal myelination and function of the vertebrate central nervous system rely largely on the timely differentiation of oligodendrocytes (OLs), yet key regulatory factors remain enigmatic. Our study reveals neural zinc finger (Nzf2) as a crucial orchestrator that controls the timing of OL differentiation both during development and myelin repair, contrasting with its previously suggested role in direct myelin gene regulation. Nzf2 ablation delays the onset of OL differentiation, while hyperactivation stimulates OL differentiation both during development and remyelination. Using RNA-seq and ChIP-seq, we pinpoint Nkx2.2 as a critical downstream target of Nzf2. Specific binding of Nzf2 in the Nkx2.2 gene locus inhibits histone deacetylation by disrupting the HDAC1 repressor complex and reducing deacetylase activity. Furthermore, Nzf2 overrides the inhibitory Notch signaling to initiate OL differentiation. Thus, we propose that the Notch-Nzf2-Nkx2.2 axis is a vital component of OL differentiation timing mechanism, suggesting Nzf2 as a potential therapeutic target for stimulating OL differentiation and boosting myelin repair in demyelinating diseases.

HDAC6-Mediated FoxO1 Acetylation And Phosphorylation Control Periodontal Inflammatory Responses.

Post-translational modifications (PTMs) are critical regulators of protein function and cellular signaling. While histone deacetylation by histone deacetylases (HDACs) is well established, the role of specific HDACs in modulating non-histone protein PTMs, particularly in an infectious context, is poorly understood. Here, we reveal a pivotal role for HDAC6 in orchestrating periodontal inflammation through its dual regulatory effects on FoxO1 acetylation and phosphorylation. Using Porphyromonas gingivalis , a key periodontal pathogen, as a model pathogen, we observed that infection induces HDAC6 activation, driving inflammatory responses via modulating FoxO1 activity. HDAC6 depletion increased FoxO1 acetylation and phosphorylation, leading to its cytoplasmic sequestration and subsequent suppression of FoxO1- mediated pro-inflammatory cytokine production in macrophages. Mechanistically, HDAC6 deficiency not only directly enhances the acetylation of FoxO1 but also upregulates the expression of Rictor, a critical component of the mTORC2 complex, thereby promoting Akt phosphorylation and subsequently FoxO1 phosphorylation. This results in its cytoplasmic retention and attenuated inflammatory transcriptional activity. Functional studies demonstrated that HDAC6 depletion suppressed the production of key inflammatory mediators, including TNFα, IL-6, IL-12p40, and MIP-2, while promoting macrophage polarization toward anti-inflammatory M2 phenotypes. In vivo , using oral gavage infection and ligature-induced mouse periodontitis models, HDAC6 deficiency significantly reduced inflammatory cell infiltration in gingival tissues and protected against alveolar bone loss. These findings establish HDAC6 as a central regulator of periodontal inflammation, acting through the coordinated modulation of FoxO1 acetylation and phosphorylation. Beyond its role in oral pathology, HDAC6 may serve as a promising therapeutic target for managing inflammatory diseases linked to immune dysregulation.

BRD8 Guards the Pluripotent State by Sensing and Maintaining Histone Acetylation.

Epigenetic control of cell fates is a critical determinant to maintain cell type stability and permit differentiation during embryonic development. However, the epigenetic control mechanisms are not well understood. Here, it is shown that the histone acetyltransferase reader protein BRD8 impairs the conversion of primed mouse EpiSCs (epiblast stem cells) to naive mouse ESCs (embryonic stem cells). BRD8 works by maintaining histone acetylation on promoters and transcribed gene bodies. BRD8 is responsible for maintaining open chromatin at somatic genes, and histone acetylation at naive-specific genes. When Brd8 expression is reduced, chromatin accessibility is unchanged at primed-specific genes, but histone acetylation is reduced. Conversely, naive-specific genes has reduced repressive chromatin marks and acquired accessible chromatin more rapidly during the cell type conversion. It is shown that this process requires active histone deacetylation to promote the conversion of primed to naive. This data supports a model for BRD8 reading histone acetylation to accurately localize the genome-wide binding of the histone acetyltransferase KAT5. Overall, this study shows how the reading of the histone acetylation state by BRD8 maintains cell type stability and both enables and impairs stem cell differentiation.

ALFIN-like proteins link histone H3K4me3 to H2A ubiquitination and coordinate diverse chromatin modifications in Arabidopsis.

Trimethylation of histone H3K4 (H3K4me3) is widely distributed at numerous actively transcribed protein-coding genes throughout the genome. However, the interplay between H3K4me3 and other chromatin modifications in plants remains poorly understood. In this study, we find that the Arabidopsis thaliana ALFIN-LIKE (AL) proteins contain a C-terminal PHD finger capable of binding to H3K4me3, along with a PHD-associated AL (PAL) domain that interacts with components of the Polycomb repressive complex 1 (PRC1), thereby facilitating H2A ubiquitination (H2Aub) at H3K4me3-enriched genes throughout the genome. Furthermore, we demonstrate that the loss of SDG2, a key histone H3K4 methyltransferase, leads to a reduction in H3K4me3 level, which subsequently causes a decrease in H2Aub on a genome-wide scale, revealing a strong association between H3K4me3 and H2Aub. Additionally, we show that the PAL domain interacts with various other chromatin-related proteins or complexes, including those involved in regulating H2A.Z deposition, H3K27me3 demethylation, histone deacetylation, and chromatin accessibility. Our genome-wide analysis suggests that the AL proteins play a crucial role in coordinating H3K4me3 with multiple other chromatin modifications across the genome.

Histone Modifications in the Anoxic Northern Crayfish, Faxonius virilis.

Northern Crayfish, Faxonius virilis, displays various strategies that allow them to survive extended periods of oxygen deprivation. However, certain epigenetic adaptations that these crayfish use have not been studied in detail, and the role of specific mechanisms used such as histone modifications remain unknown. Epigenetic studies offer a new perspective on how crayfish can regulate gene expression to redirect energy to essential functions needed for survival. This study investigates the regulation of histone modifications of proteins including acetylation and deacetylation in F. virilis in response to 20-h anoxia exposure. These histone modifications were studied via analysis of writer, reader, and eraser proteins such as lysine acetyltransferases (KATs), bromodomain proteins (BRDs), histone deacetylases (HDAC), and sirtuin proteins (SIRTs). Significant upregulation was seen in one histone protein and one lysine acetyltransferase: H3K14Ac and KAT2A. These proteins are known to be regulated by BRD2; a protein that specifically reads and targets H3K14Ac. In response to anoxia, a larger number of histone deacetylases and sirtuin proteins were upregulated in comparison to lysine acetyltransferases suggesting a focus on suppression of gene expression. The histone deacetylases and sirtuin proteins with significant upregulation were HDAC2, HDAC3, SIRT2, SIRT3, and SIRT6. These proteins have also all been implicated in DNA damage regulation which further suggests that crayfish focus limited energy on ensuring cell survival. This study provides an understanding of how histone acetylation and deacetylation are regulated in crayfish as a component of metabolic rate suppression under anoxia.

Design, synthesis, and biological evaluation of novel AAK1/HDACs dual inhibitors against SARS-CoV-2 entry

AP2-associated protein kinase 1 (AAK1) is a crucial regulator of clathrin-mediated endocytosis, involved in various cellular processes, including viral infection. Histone deacetylases (HDACs) are essential in regulating gene transcription through the process of histone deacetylation and have become promising therapeutic targets for the treatment of cancer and viral infections. In this study, several AAK1/HDACs dual inhibitors based on our previous reported compounds were designed and synthesized, and the antiviral activity of these dual inhibitors were evaluated. Among them, compound 12 showed remarkable dual inhibitory activity against both AAK1 and HDACs, with IC50 values of 15.9 nM for AAK1, 148.7 nM for HDAC1, and 5.2 nM for HDAC6. Notably, this compound exhibited superior efficacy in suppressing SARS-CoV-2 entry into host cells compared to its close analogs 4, 13a, and 13b. Mechanistically, compound 12 attenuated AAK1-induced phosphorylation of adaptor protein-2 μ subunit (AP2M1) threonine 156, disrupting the direct interaction between AP2M1 and ACE2, thus inhibiting the CME-mediated SARS-CoV-2 endocytosis. Additionally, compound 12 increased the acetylation levels of H3K27 and α-tubulin, suggesting its potential as an epigenetic modulator. Overall, our findings propose compound 12 as a promising dual inhibitor against AAK1 and HDACs, highlighting its therapeutic potential in antiviral infections.