Three-Dimensional Structure of Chymotrypsin Inactivated with (2S)-N-Acetyl-L-alanyl-L-phenylalanyl .alpha.-chloroethane: Implications for the Mechanism of Inactivation of Serine Proteases by Chloroketones

Kreutter, K. D.; Steinmetz, Anke; Liang, Tzyy-Chyau; Prorok, Maryfrances; Abeles, Robert H.; Ringe, Dagmar

doi:10.1021/bi00250a033

Cited by 26 publications

(18 citation statements)

References 43 publications

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“…For example, chloromethyl ketone inhibitors usually form two covalent attachments each to one of the His57:Ser195 catalytic pair in their native conformation, possibly through a double displacement mechanism. 21 Interestingly, in the crystal structure of elastase complexed with the non-covalent inhibitor, trifluoroacetal-leucyl-alanyl-p-trifluoromethylphenylanilide (TFLA), the C β -O γ bond of Ser195 does undergo a similar rotation to avoid steric clashes with the trifluoro function of the inhibitor (PDB code 7EST). 22 This rotation in the side-chain of the catalytic serine/ cysteine residue not only increases slightly the distance between N ε2 of the assisting general base (His57 of elastase/His41 of 3CL pro ) and the nucleophilic atom, but also places the nucleophilic O γ /S γ atom in a position less coplanar with the imidazole ring of the histidine residue.…”

Section: The Interactions Between the Peptidyl Portions Of The Inhibimentioning

confidence: 99%

A Mechanistic View of Enzyme Inhibition and Peptide Hydrolysis in the Active Site of the SARS-CoV 3C-like Peptidase

Jiang

Niu

Cherney

et al. 2007

Journal of Molecular Biology

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The 3C-like main peptidase 3CL pro is a viral polyprotein processing enzyme essential for the viability of the Severe Acute Respiratory Syndrome coronavirus (SARS-CoV). While it is generalized that 3CL pro and the structurally related 3C pro viral peptidases cleave their substrates via a mechanism similar to that underlying the peptide hydrolysis by chymotrypsin-like serine proteinases (CLSPs), some of the hypothesized key intermediates have not been structurally characterized. Here, we present three crystal structures of SARS 3CL pro in complex with each of two members of a new class of peptide-based phthalhydrazide inhibitors. Both inhibitors form an unusual thiiranium ring with the nucleophilic sulfur atom of Cys145, trapping the enzyme's catalytic residues in configurations similar to the intermediate states proposed to exist during the hydrolysis of native substrates. Most significantly, our crystallographic data are consistent with a scenario in which a water molecule, possibly via indirect coordination from the carbonyl oxygen of Thr26, has initiated nucleophilic attack on the enzyme-bound inhibitor. Our data suggest that this structure resembles that of the proposed tetrahedral intermediate during the deacylation step of normal peptidyl cleavage.

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Section: The Interactions Between the Peptidyl Portions Of The Inhibimentioning

confidence: 99%

A Mechanistic View of Enzyme Inhibition and Peptide Hydrolysis in the Active Site of the SARS-CoV 3C-like Peptidase

Jiang

Niu

Cherney

et al. 2007

Journal of Molecular Biology

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“…The mechanism of inactivation is however, different for the proteases. In concert with other cysteine proteases calpain inhibition by peptidyl chloromethyl ketones is due to alkylation of the active site thiolate [104] while inactivation of serine proteases involves alkylation of the active site histidine [105]. In attempts to generate selective protease inhibitors, peptidyl fluoromethyl ketones were investigated as enzyme inhibitors [106].…”

Section: Calpain Inhibitor Warheadsmentioning

confidence: 99%

A Survey of Calpain Inhibitors

Donkor¹

2000

CMC

136

153

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Calpain is unique among the cysteine protease family of enzymes in that it combines thiol protease activity with calmodulin-like activity. Despite its wide spread distribution the exact physiological function(s) of calpain is yet to be deciphered. The enzyme is however, implicated in a number of pathophysiological conditions. Due to the potential of calpain as a therapeutic target a number of inhibitors have been described for the enzyme. In this article we have grouped calpain inhibitors into those derived from natural sources, and those derived from chemical synthesis. Additionally, an overview of functional groups that have been used as warheads of calpain inhibitors is presented along with a discussion of the structure activity relationship studies of the address region of peptidyl calpain inhibitors. Recent work in this area has led to a better understanding of the structural requirements for tight binding of inhibitors to the active site of calpain. A discussion of peptidomimetic calpain inhibitors, nonpeptide calpain inhibitors, and selectivity of some calpain inhibitors are also presented. The recent disclosure of the crystal structure of a nonpeptide calpain inhibitor bound to a hydrophobic pocket on the calcium-binding domain of calpain has opened the door to future development of potent cell permeable nonpeptide calpain inhibitors.

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“…[5] While this finding conclusively demonstrated the mode of inactivation-alkylation of the thiolate, the precise mechanism of inactivation has yet to be established.Although unclear, the mechanism of inactivation presumably proceeds through one of at least two routes: direct displacement of the halogen through an S N 2 mechanism or initial attack on the iminium carbon, followed by displacement of the halide to form a sulfonium ring, and ending with concomitant re-formation of the imine and opening of the sulfonium ring (Scheme 1). While the former possibility is the more intuitive, the latter is analogous to the mechanism by which the fluoromethylketones inactivate the cysteine proteases, [10][11][12] and therefore warranted further investigation.We began our investigations by examining the influence of pH on k inact /K I , that is, the second-order rate constant of enzyme inactivation. These studies were pursued because pH rate profiles can suggest the identity of catalytically important functional groups, in the inactivator or free enzyme, up to and including the first irreversible step of the reaction.…”

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confidence: 99%

Haloacetamidine‐Based Inactivators of Protein Arginine Deiminase 4 (PAD4): Evidence that General Acid Catalysis Promotes Efficient Inactivation

et al. 2010

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Dysregulated Protein Arginine Deiminase (PAD) activity, particularly PAD4, has been suggested to play a role in the onset and progression of numerous human diseases, including Rheumatoid Arthritis (RA). Given the potential role of PAD4 in RA, we set out to develop inhibitors/ inactivators that could be used to modulate PAD activity and disease progression. This effort led to the discovery of two mechanism-based inactivators, denoted F-and Cl-amidine, that inactivate PAD4 via the covalent modification of an active site cysteine that is critical for catalysis. To gain further insights into the mechanism of inactivation by these compounds, the effect of pH on the rates of inactivation were determined. These results, combined with the results of solvent isotope effect and proton inventory studies, strongly suggest that the inactivation of PAD4 by F-and Clamidine proceeds via a multi-step mechanism that involves the protonation and stabilization of the tetrahedral intermediate formed upon nucleophilic attack by the active site cysteine, i.e. Cys645. Stabilization of this intermediate would help to drive the halide-displacement reaction, which results in the formation of a three-membered sulfonium ring that ultimately collapses to form the inactivated enzyme. This finding -that protonation of the tetrahedral intermediate is important for enzyme inactivation -may also suggest that during catalysis, protonation of the analogous intermediate is required for efficient substrate turnover. KeywordsDeiminase; Citrulline; Cl-amidine; rheumatoid arthritis; inactivator In nature, a myriad of posttranslational modifications are found in proteins. These modifications, and the requisite modifying enzymes, can have far-reaching effects on living systems. Within the family of protein modifying enzymes are the Protein Arginine Deiminases (PADs). These enzymes catalyze the hydrolysis of arginine residues to form citrulline.[1-3] Much effort from our lab has been focused on gaining insight into the mechanism of the PADs, and, in particular, PAD4. [3-5] Our interest in PAD4, and the

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Three-Dimensional Structure of Chymotrypsin Inactivated with (2S)-N-Acetyl-L-alanyl-L-phenylalanyl .alpha.-chloroethane: Implications for the Mechanism of Inactivation of Serine Proteases by Chloroketones

Cited by 26 publications

References 43 publications

A Mechanistic View of Enzyme Inhibition and Peptide Hydrolysis in the Active Site of the SARS-CoV 3C-like Peptidase

A Mechanistic View of Enzyme Inhibition and Peptide Hydrolysis in the Active Site of the SARS-CoV 3C-like Peptidase

A Survey of Calpain Inhibitors

Haloacetamidine‐Based Inactivators of Protein Arginine Deiminase 4 (PAD4): Evidence that General Acid Catalysis Promotes Efficient Inactivation

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