Opening the Selectivity Pocket in the Human Lysine Deacetylase Sirtuin2 - New Opportunities, New Questions.

Reversible lysine deacetylation is exerted by both zinc and NAD+ -dependent deacetylases. It is an important factor in epigenetic regulation and more generally in the posttranslational regulation of protein stability, association and activity. Some of these enzymes can also cleave off fatty acids or dicarboxylic acids from lysines in proteins. The NAD+ -dependent deacetylases are termed Sirtuins and are implicated in the pathogenesis of different diseases. For the isotype Sirt2 highly selective inhibitors have been identified in the last few years. Many of those Sirt2 selective compounds, like the Sirtuin rearranging ligands (SirReals) discovered in our group, have been shown or are postulated to bind to the so-called selectivity pocket. This binding site is not observed in crystal structures of the apo-enzyme but can be opened up by long chain fatty acid substrates respectively suitable inhibitors. Recently, this unique feature of Sirt2 was exploited to provide highly potent and selective tools for the chemical biology of Sirtuins. Here, we shortly review Sirtuin biology, present inhibitors that have either been confirmed or postulated to bind to the selectivity pocket, their applications and an outlook regarding mechanistic investigations.

Structure-Reactivity Relationships on Substrates and Inhibitors of the Lysine Deacylase Sirtuin 2 from Schistosoma mansoni (SmSirt2).

The only drug currently available for treatment of the neglected disease Schistosomiasis is Praziquantel, and the possible emergence of resistance makes research on novel therapeutic agents necessary and urgent. To this end, the targeting of Schistosoma mansoni epigenetic enzymes, which regulate the parasitic life cycle, emerged as a promising approach. Due to the strong effects of human sirtuin inhibitors on parasite survival and reproduction, Schistosoma sirtuins were postulated as potential therapeutic targets. In vitro testing of synthetic substrates of S. mansoni sirtuin 2 (SmSirt2) and kinetic experiments on a myristoylated peptide demonstrated lysine long-chain deacylation as an intrinsic SmSirt2 activity in addition to its known deacetylase activity for the first time. Focused in vitro screening of the GSK Kinetobox library and structure-activity relationships of identified hits led to the first SmSirt2 inhibitors with activity in the low micromolar range. Several SmSirt2 inhibitors showed potency against both larval schistosomes (viability) and adult worms (pairing, egg laying) in culture without general toxicity to human cancer cells.

New chemical tools for probing activity and inhibition of the NAD+-dependent lysine deacylase sirtuin 2.

Sirtuins are NAD+-dependent protein deacylases capable of cleaving off acetyl as well as other acyl groups from the ɛ-amino group of lysines in histones and other substrate proteins. They have been reported as promising drug targets, and thus modulators of their activity are needed as molecular tools to uncover their biological function and as potential therapeutics. Here, we present new assay formats that complement existing assays for sirtuin biochemistry and cellular target engagement. Firstly, we report the development of a homogeneous fluorescence-based activity assay using unlabelled acylated peptides. Upon deacylation, the free lysine residue reacts with fluorescamine to form a fluorophore. Secondly, using click chemistry with a TAMRA-azide on a propargylated sirtuin inhibitor, we prepared the first fluorescently labelled small-molecule inhibitor of Sirt2. This is used in a binding assay, which is based on fluorescence polarization. We used it successfully to map potential inhibitor-binding sites and also to show cellular Sirt2 engagement. By means of these new assays, we were able to identify and characterize novel Sirt2 inhibitors out of a focused library screen. The binding of the identified Sirt2 inhibitors was rationalized by molecular docking studies. These new chemical tools thus can enhance further sirtuin research.This article is part of a discussion meeting issue 'Frontiers in epigenetic chemical biology'.

Pure enantiomers of benzoylamino-tranylcypromine: LSD1 inhibition, gene modulation in human leukemia cells and effects on clonogenic potential of murine promyelocytic blasts.

The pure enantiomers of the N-(2-, 3-, and 4-(2-aminocyclopropyl)phenyl)benzamides hydrochlorides 11a-j were prepared and tested against LSD1 and MAO enzymes. The evaluation of the regioisomers 11a-j highlighted a net increase of the anti-LSD1 potency by shifting the benzamide moiety from ortho to meta and mainly to para position of tranylcypromine phenyl ring, independently from their trans or cis stereochemistry. In particular, the para-substituted 11a,b (trans) and 11g,h (cis) compounds displayed LSD1 and MAO-A inhibition at low nanomolar levels, while were less potent against MAO-B. The meta analogs 11c,d (trans) and 11i,j (cis) were in general less potent, but more efficient against MAO-A than against LSD1. In cellular assays, all the para and meta enantiomers were able to inhibit LSD1 by inducing Gfi-1b and ITGAM gene expression, with 11b,c and 11g-i giving the highest effects. Moreover, 11b and 11g,h strongly inhibited the clonogenic potential of murine promyelocytic blasts.