Uncovering Robust Delactoylase and Depyruvoylase Activities of HDAC Isoforms.

Zinc-dependent histone deacetylases (HDACs) and sirtuins (SIRT) represent two different classes of enzymes which are responsible for deacylation of modified lysine side chains. The repertoire of acyl residues on lysine side chains identified in vivo is rapidly growing, and very recently lysine lactoylation was described to be involved in metabolic reprogramming. Additionally, lysine pyruvoylation represents a marker for aging and liver cirrhosis. Here, we report a systematic analysis of acyl-specificity of human zinc-dependent HDAC and sirtuin isoforms. We identified HDAC3 as a robust delactoylase with several-thousand-fold higher activity as compared to SIRT2, which was claimed to be the major in vivo delactoylase. Additionally, we systematically searched for enzymes, capable of removing pyruvoyl residues from lysine side chains. Using model peptides, we uncovered high depyruvoylase activity for HDAC6 and HDAC8. Interestingly, such substrates have extremely low KM values for both HDAC isoforms, pointing to possible in vivo functions.

Strategies To Design Selective Histone Deacetylase Inhibitors.

This review classifies drug-design strategies successfully implemented in the development of histone deacetylase (HDAC) inhibitors, which have many applications including cancer treatment. Our focus is on especially demanded selective HDAC inhibitors and their structure-activity relationships in relation to corresponding protein structures. The main part of the paper is divided into six subsections each narrating how optimization of one of six structural features can influence inhibitor selectivity. It starts with the impact of the zinc binding group on selectivity, continues with the optimization of the linker placed in the substrate binding tunnel as well as the adjustment of the cap group interacting with the surface of the protein, and ends with the addition of groups targeting class-specific sub-pockets: the side-pocket-, lower-pocket- and foot-pocket-targeting groups. The review is rounded off with a conclusion and an outlook on the future of HDAC inhibitor design.

Design of selective histone deacetylase inhibitors: rethinking classical pharmacophore.

For two decades, a classical pharmacophore model comprising a zinc binding group, a linker and a cap group, has been used for the development of histone deacetylase (HDAC) inhibitors. However, some of the recently reported selective HDAC inhibitors targeting additional, usually subtype specific, cavities in the binding pocket show supplementary features which do not fit this classical pharmacophore. We, therefore, propose an extended pharmacophore model, which can describe almost all currently known HDAC inhibitors. This pharmacophore consists of six pharmacophoric features and should be helpful for the classification and design of selective HDAC inhibitors.

Structure-Activity Relationship of Propargylamine-Based HDAC Inhibitors.

As histone deacetylases (HDACs) play an important role in the treatment of cancer, their selective inhibition has been the subject of various studies. These continuous investigations have given rise to a large collection of pan- and selective HDAC inhibitors, containing diverse US Food and Drug Administration (FDA)-approved representatives. In previous studies, a class of alkyne-based HDAC inhibitors was presented. We modified this scaffold in two previously neglected regions and compared their cytotoxicity and affinity toward HDAC1, HDAC6, and HDAC8. We were able to show that R-configured propargylamines contribute to increased selectivity for HDAC6. Docking studies on available HDAC crystal structures were carried out to rationalize the observed selectivity of the compounds. Substitution of the aromatic portion by a thiophene derivative results in high affinity and low cytotoxicity, indicating an improved drug tolerance.