Project description:HDAC3 and HDAC8 are members of class I deacetylases involved in several biological mechanisms and represent a highly sought-after therapeutic target for drug development. It is historically challenging to develop selective deacetylase inhibitors due to their conserved catalytic domains. HDAC3 also has deacetylase-independent activity, which cannot be blocked by conventional enzymatic inhibitors. Recent advances in proteolysis-targeting chimeras (PROTACs) provide an opportunity to eliminate the whole protein selectively, abolishing both enzymatic and scaffolding functions. Here, we report a novel HDAC3/8 dual degrader YX968 that induces highly potent, rapid and selective degradation of both HDAC3 and HDAC8 without trigging pan-HDAC inhibitory effects. Unbiased quantitative proteomics experiments further confirmed its high selectivity. This dual-specific degrader specifically ablates cellular pathways attributed to HDAC3 and HDAC8 and exhibits high potency in killing cancer cells. YX968 represents a new probe for dissecting the complex biological functions of HDAC3 and HDAC8.

Project description:HDAC3 and HDAC8 are members of class I deacetylases involved in several biological mechanisms and represent a highly sought-after therapeutic target for drug development. It is historically challenging to develop selective deacetylase inhibitors due to their conserved catalytic domains. HDAC3 also has deacetylase-independent activity, which cannot be blocked by conventional enzymatic inhibitors. Recent advances in proteolysis-targeting chimeras (PROTACs) provides an opportunity to eliminate the whole protein selectively, abolishing both enzymatic and scaffolding functions. Here, we report a novel HDAC3/8 dual degrader YX968 that induces highly potent, rapid and selective degradation of both HDAC3 and HDAC8 without trigging pan-HDAC inhibitory effects. Unbiased quantitative proteomics experiments further confirmed its high selectivity. This dual-specific degrader specifically ablates cellular pathways attributed to HDAC3 and HDAC8 and exhibits high potency in killing cancer cells. YX968 represents a new probe for dissecting the complex biological functions of HDAC3 and HDAC8.

Project description:HDAC3 and HDAC8 are members of class I deacetylases involved in several biological mechanisms and represent a highly sought-after therapeutic target for drug development. It is historically challenging to develop selective deacetylase inhibitors due to their conserved catalytic domains. HDAC3 also has deacetylase-independent activity, which cannot be blocked by conventional enzymatic inhibitors. Recent advance in proteolysis-targeting chimeras (PROTACs) provides an opportunity to eliminate the whole protein selectively, abolishing both enzymatic and scaffolding function. Here, we report a novel HDAC3/8 dual degrader YX968 that induces highly potent, rapid, and selective degradation of both HDAC3 and HDAC8 without trigging pan-HDAC inhibitory effects. Unbiased quantitative proteomics experiments further confirmed its high selectivity. This dual-specific degrader specifically ablates cellular pathways attributed to HDAC3 and HDAC8 and exhibits high potency in killing cancer cells. YX968 represents a new probe for dissecting the complex biological functions of HDAC3 and HDAC8.

Project description:RNA-seq experiments were performed to assess effects of degradation of HDAC3 and HDAC8 on transcriptome

Project description:Human histone deacetylase 3 (HDAC3) plays an important role in gene transcription in diseased human cells, such as leukemia. The t(8;21) chromosomal translocation is one of the most commonly observed genetic abnormalities associated with acute myeloid leukemia. This translocation generates the AML1-ETO fusion protein between the wild-type RUNX1 transcription factor and wild-type ETO transcriptional corepressor. To better understand the role of HDAC3 in t(8;21) leukemogenesis, the human HDAC3-containing complexes were isolated from stably-transfected HeLa cells by using anti-FLAG immunoprecipitation. The resulting complexes were resolved in SDS-PAGE. The components of the complexes were identified using LC-MS/MS. We report here that the human RUNX1 transcription is a component of the HDAC3 complexes. We demonstrate that HDAC3 and RUNX1 collaboratively repress AML1-ETO-mediated transcription. These results reveal new insight into how AML1-ETO, RUNX1, and HDAC3 crosstalk to deregulate gene transcription in t(8;21) leukemia cells.

Project description:Lysine alkylation and acylation serve as crucial links between cellular metabolism and a wide range of biological functions. However, hybrid modifications that combine features of both alkylation and acylation remain largely unexplored. Here, we report the discovery and in-depth characterization of lysine methylpropionylation (Kpm), a hybrid post-translational modification (PTM) defined by the propionylation of monomethyllysine residues. Genome-wide chromatin immunoprecipitation coupled with transcriptomic profiling revealed that Kpm exhibits distinct genomic distribution compared to canonical Kac and Kpr, with preferential enrichment at promoters of genes involved in metabolic pathways. Together, our findings establish Kpm as a dual-feature PTM that integrates metabolic cues with both chromatin regulation and non-histone protein function, offering a mechanistic framework for understanding metabolism-proteome crosstalk.

Project description:Ischemic stroke induces pathological glycogen deposition in astrocytes, but its role in post-injury neural dysfunction remains undefined. We reveal that glycogen-laden astrocytes in the ischemic penumbra undergo HDAC3-dependent mitochondrial fragmentation via a stress granule-mediated mechanism, exacerbating neuronal injury and hindering functional recovery. Mechanistic studies demonstrate that glycogen aggregates sequester cytoplasmic HDAC3, enabling its translocation to mitochondria. There, HDAC3 deacetylates outer mitochondrial membrane protein ATAD3A, promoting oligomerization-driven mitochondrial fission. Astrocyte-specific ATAD3A ablation prevents stroke-induced synaptic disorganization, neural circuit disruption, and cognitive deficits. Therapeutically, combined administration of cotadutide (a glycogen-depleting GLP-1/GCGR agonist) and HDAC3 inhibitor RGFP966 reverses glycogen accumulation, rescues mitochondrial architecture/function, and restores synaptic plasticity and circuit reorganization, thereby accelerating sensorimotor recovery. Our work identifies glycogen stress granules as pathogenic signaling hubs linking astrocytic metabolic stress to mitochondrial failure through compartmentalized HDAC3-ATAD3A crosstalk, and proposes a dual-target paradigm addressing both substrate overload and protein acetylation dynamics for stroke neurorestoration.

Project description:The model predicts the inhibitory potential of small molecules against Histone deacetylase 3 (HDAC3), a relevant human target for cancer, inflammation, neurodegenerative diseases and diabetes. The authors have used a dataset of 1098 compounds from ChEMBL and validated the model using the benchmark MUBD-HDAC3. Model Type: Predictive machine learning model. Model Relevance: Probability that the molecule is a HDAC3 inhibitor Model Encoded by: Sarima Chiorlu (Ersilia) Metadata Submitted in BioModels by: Zainab Ashimiyu-Abdusalam Implementation of this model code by Ersilia is available here: https://github.com/ersilia-os/eos1n4b

Project description:Post-translational modifications (PTMs) are under significant focus in molecular biomedicine due to their importance in signal transduction in most cellular and organismal processes. Identification of PTMs, determination of PTM location sites, discrimination between functional and inert PTMs, and quantification of their occupancies are demanding tasks, especially in the light of PTM crosstalk in each biosystem. On top of that, the study of each PTM often necessitates a particular experimental design. Computational approaches can identify the relevant PTMs in a biosystem and help to design follow-up experiments involving specific PTM enrichment. Here, we present a PTM-centric proteome informatic pipeline for prediction of most probable and relevant PTMs in mass spectrometry-based proteomics data and refining raw data search parameters based on the acquired knowledge. Using expression profiling, we identified cellular proteins that are differentially regulated in response to multikinase inhibitors dasatinib and staurosporine at four different concentrations. Computational enrichment analysis was employed to determine the potential PTMs of protein targets for both drugs. Finally, we conducted an additional round of database search with these predicted chemical modifications. Our pipeline helped analyze the enriched PTMs and even detected proteins that were not picked up in the initial search. Our findings support the idea of PTM-oriented searching of MS data in proteomics based on computational enrichment analysis.

Project description:Post-translational modifications (PTMs) are under significant focus in molecular biomedicine due to their importance in signal transduction in most cellular and organismal processes. Identification of PTMs, determination of PTM location sites, discrimination between functional and inert PTMs, and quantification of their occupancies are demanding tasks, especially in the light of PTM crosstalk in each biosystem. On top of that, the study of each PTM often necessitates a particular experimental design in majority of cases. Computational approaches can identify the relevant PTMs in a biosystem and help to design follow-up experiments involving specific PTM enrichment. Here, we present a PTM-centric proteome informatic pipeline for prediction of most probable and relevant PTMs in mass spectrometry-based proteomics data and refining raw data search parameters based on the acquired knowledge. Using expression profiling, we identified cellular proteins that are differentially regulated in response to multikinase inhibitors dasatinib and staurosporine at four different concentrations. Computational enrichment analysis was employed to determine the potential PTMs of protein targets for both drugs. Finally, we conducted an additional round of database search with these predicted chemical modifications. Our pipeline helped analyze the enriched PTMs and even detected proteins that were not picked up in the initial search. Our findings support the idea of PTM-oriented searching of MS data in proteomics based on computational enrichment analysis.