A kinetic study of thiol addition to N-phenylchloroacetamide.

Irreversible enzyme inhibitors bind covalently to their target and permanently limit its function. The redox-sensitive thiol group on the side chain of cysteine (Cys) residues is often the nucleophilic group that is targeted for reaction with the electrophilic warhead of irreversible inhibitors. While the acrylamide group is the warhead applied most frequently currently in the design of inhibitors with therapeutic potential, the chloroacetamide group offers a comparable reactivity profile. In that context, we have studied the details of the mechanism of thiol addition to N-phenylchloroacetamide (NPC). A kinetic assay was developed to accurately monitor the reaction progress between NPC and a small library of thiols with varying pKa values. From these data, a Brønsted-type plot was constructed, from which a ßnucRS- value of 0.22 ± 0.07 was derived, indicative of a relatively early transition state with respect to attack by the thiolate. The halide leaving group was also varied, for the reaction with one thiol, providing rate constants consistent with a transition state that is early with respect to leaving group departure. The effects of temperature and ionic strength were also studied, and all data are consistent with an early transition state for a concerted SN2 mechanism of addition. Molecular modelling was also performed, and these calculations confirm the concerted transition state and relative reactivity of the haloacetamides. Finally, this study allows a detailed comparison of the reactivity and reaction mechanisms of the chloroacetamide group with the benchmark acrylamides used in many irreversible inhibitor drugs.

The war on hTG2: warhead optimization in small molecule human tissue transglutaminase inhibitors.

Human tissue transglutaminase (hTG2) is a multifunctional enzyme with protein cross-linking and G-protein activity, both of which have been implicated in the progression of diseases such as fibrosis and cancer stem cell propagation when dysregulated, prompting the development of small molecule targeted covalent inhibitors (TCIs) possessing a crucial electrophilic 'warhead'. In recent years there have been significant advances in the library of warheads available for the design of TCIs; however, the exploration of warhead functionality in hTG2 inhibitors has remained relatively stagnant. Herein, we describe a structure-activity relationship study entailing rational design and synthesis for systematic variation of the warhead on a previously reported small molecule inhibitor scaffold, and rigorous kinetic evaluation of inhibitory efficiency, selectivity, and pharmacokinetic stability. This study reveals a strong influence on the kinetic parameters k inact and K I with even subtle variation in warhead structure, suggesting that the warhead plays a significant role in not only reactivity, but also binding affinity, which consequently extends to isozyme selectivity. Warhead structure also influences in vivo stability, which we model by measuring intrinsic reactivity with glutathione, as well as stability in hepatocytes and in whole blood, giving insight into degradation pathways and relative therapeutic potential of different functional groups. This work provides fundamental structural and reactivity information highlighting the importance of strategic warhead design for the development of potent hTG2 inhibitors.

A mechanistic study of thiol addition to N-acryloylpiperidine.

Nucleophilic cysteine (Cys) residues are present in many enzyme active sites and represent the target of many different irreversible enzyme inhibitors. Given its fine balance between aqueous stability and thiolate reactivity, the acrylamide group is a particularly popular warhead pharmacophore among inhibitors designed for biological and therapeutic application. The acrylamide group is well known to undergo thiol addition, but the precise mechanism of this addition reaction has not been studied in as much detail. In this work we have focussed on the reaction of N-acryloylpiperidine (AcrPip), which represents a motif found in many targeted covalent inhibitor drugs. Using a precise HPLC-based assay, we measured the second order rate constants for the reaction of AcrPip with a panel of thiols possessing different pKa values. This allowed construction of a Brønsted-type plot that reveals the relative insensitivity of the reaction to the nucleophilicity of the thiolate. By studying temperature effects, we were able to construct an Eyring plot from which the enthalpy and entropy of activation were calculated. Ionic strength and solvent kinetic isotope effects were also studied, informing on charge dispersal and proton transfer in the transition state. DFT calculations were also performed, providing information on the potential structure of the activated complex. Taken together, these data strongly support one cohesive addition mechanism that is the microscopic reverse of the E1cb elimination, and highly relevant to the intrinsic thiol selectivity of AcrPip inhibitors and their subsequent design.

A mechanistic study of thiol addition to N-phenylacrylamide.

Cysteine (Cys) residues contain a redox-sensitive thiol and are commonly found in enzyme active sites. In recent years, the presence of a reactive thiolate group on a protein has been exploited in the development of irreversible enzyme inhibitors as therapeutic agents. Many targeted covalent inhibitors (TCIs) are designed to covalently react with a specific Cys residue on a target protein active site, irreversibly modifying the target and inhibiting its normal function. The electrophilic warhead most commonly used in this way is the acrylamide functional group. Although the acrylamide group is well known for its ability to undergo thiol-addition reactions, very few studies have been conducted to elucidate the detailed mechanism of this reaction, which inspired us to conduct a thorough kinetic investigation. First, we developed a robust kinetic assay to accurately monitor reaction progress between N-phenylacrylamide (NPA) and a small library of alkyl thiols having widely varying pKa values. This allowed us to construct a Brønsted-type plot for the thiol addition reaction, revealing a ßnucRS- value of 0.07 ± 0.04. We also studied the solvent kinetic isotope effects (SKIEs), pH dependence, and temperature dependence of the reaction, which showed that reaction has a relatively large negative ΔS‡, and a small ΔH‡. Computational studies provided a structure for the transition state that is consistent with the experimental data. All of these data are consistent with rate-limiting nucleophilic attack, followed by rapid protonation of the enolate, corresponding to the microscopic reverse of the E1revcb elimination mechanism.

Structure-activity relationships of hydrophobic alkyl acrylamides as tissue transglutaminase inhibitors.

Tissue transglutaminase (TG2) is a multifunctional protein that plays biological roles based on its ability to catalyse protein cross-linking and to function as a non-canonical G-protein known as Ghα. The non-regulated activity of TG2 has been implicated in fibrosis, celiac disease and the survival of cancer stem cells, underpinning the therapeutic potential of cell permeable small molecule inhibitors of TG2. In the current study, we designed a small library of inhibitors to explore the importance of a terminal hydrophobic moiety, as well as the length of the tether to the irreversible acrylamide warhead. Subsequent kinetic evaluation using an in vitro activity assay provided values for the k inact and K I parameters for each of these irreversible inhibitors. The resulting structure-activity relationship (SAR) clearly indicated the affinity conferred by dansyl and adamantyl moieties, as well as the efficiency provided by the shortest warhead tether. We also provide the first direct evidence of the capability of these inhibitors to suppress the GTP binding ability of TG2, at least partially. However, it is intriguing to note that the SAR trends observed herein are opposite to those predicted by molecular modelling - namely that longer tether groups should improve binding affinity by allowing for deeper insertion of the hydrophobic moiety into a hydrophobic pocket on the enzyme. This discrepancy leads us to question whether the existing crystallographic structures of TG2 are appropriate for docking non-peptidic inhibitors. In the absence of a more relevant crystallographic structure, the data from rigorous kinetic studies, such as those provided herein, are critically important for the development of future small molecule TG2 inhibitors.