Abstract 4582: HDAC6 inhibition reshapes the epigenome of cancer via P300 stabilization

Introduction: Histone deacetylases (HDACs)are crucial in regulating gene expression, DNA synthesis, and metabolic processes, including cancer, in various cellular environments. The unique structural and functional attributes of class IIb HDAC6 position it as a key player in influencing protein stability and chromatin dynamics. While its role in cancer progression and immunomodulation is well-recognized, the in-depth mechanisms following HDAC6 inactivation, particularly its influence on chromatin remodeling and gene regulation, are not thoroughly understood. This knowledge gap represents a critical area of investigation, given the potential of HDAC6 as a therapeutic target in oncology. This study aims to elucidate HDAC6 inactivation-dependent epigenetic effects of, exploring the possibility to exploit these latter for therapeutic purposes in cancer. This aim includes an examination of the stabilization of the lysine acetyltransferase P300 and its implications for chromatin structure and function. Methods & Results: In this study, ITF3756 and CRISPR/Cas9 were employed to inactivate HDAC6 across a variety of cancer cell lines (Jurkat, MDA 231, HCC1806, 4T1, and B16F10 melanoma). ATAC-seq and H3K27Ac ChIP-seq were used to investigate changes in chromatin accessibility, revealing significant alterations, particularly in introns and distal intergenic regions. Gene Ontology (GO) analysis further supported this alteration in the chromatin landscape, which indicated a differential expression of genes involved in critical cellular processes like cell proliferation, adhesion, migration, and apoptosis. A notable outcome of this study was the stabilization of P300 following ITF3756 treatment, an effect that was paralleled by changes in the expression of critical genes, including AKT1, ITGB3, GAS6, SOX9, NF1, TGFB2, and CASP7. These genes are integral to cellular survival mechanisms, and their modulation emphasizes the role of HDAC6 in cancer cell physiology. Conclusions: This research shows that the chemical or genetic inactivation of HDAC6 impacts cancer cell proliferation and chromatin architecture, underscoring the potential of HDAC6 as a target in cancer therapeutics.. A critical finding of this study is the stabilization of P300, which offers new perspectives on HDAC6's functionality and its role as an epigenetic modifier in cancer cells. This study contributes to the field by suggesting therapeutic strategies focusing on HDAC/HAT pharmacological targeting, thereby advancing our understanding of the role of HDAC6 in regulating cancer cell behavior and epigenetic landscape.