Robert Ménard

Human cathepsin X: A novel cysteine protease of the papain family with a very short proregion and unique insertions1

A novel cDNA encoding a cysteine protease of the papain family named cathepsin X was obtained by PCR amplification from a human ovary cDNA library. The cathepsin X cDNA is ubiquitously expressed in human tissues and contains an open reading frame of 912 nucleotides encoding a predicted protein of 303 amino acids. All highly conserved regions in papain‐like cysteine proteases including the catalytic residues are present in cathepsin X. The mature part of cathepsin X is 26–32% identical to human cathepsins B, C, H, K, L, O, S and W. The cathepsin X sequence contains several unique features: (i) a very short proregion; (ii) a three amino acid residue insertion in a highly conserved region between the glutamine of the putative oxyanion hole and the active site cysteine; and (iii) a second insertion of 15 amino acid residues that can be aligned with the occluding loop region in cathepsin B.

Selectivity in ISG15 and ubiquitin recognition by the SARS coronavirus papain-like protease

Abstract The severe acute respiratory syndrome coronavirus papain-like protease (SARS-CoV PLpro) carries out N-terminal processing of the viral replicase polyprotein, and also exhibits Lys48-linked polyubiquitin chain debranching and ISG15 precursor processing activities in vitro. Here, we used SDS–PAGE and fluorescence-based assays to demonstrate that ISG15 derivatives are the preferred substrates for the deubiquitinating activity of the PLpro. With k cat/K M of 602,000M−1 s−1, PLpro hydrolyzes ISG15-AMC 30- and 60-fold more efficiently than Ub-AMC and Nedd8-AMC, respectively. Data obtained with truncated ISG15 and hybrid Ub/ISG15 substrates indicate that both the N- and C-terminal Ub-like domains of ISG15 contribute to this preference. The enzyme also displays a preference for debranching Lys48- over Lys63-linked polyubiquitin chains. Our results demonstrate that SARS-CoV PLpro can differentiate between ubiquitin-like modifiers sharing a common C-terminal sequence, and that the debranching activity of the PLpro is linkage type selective. The potential structural basis for the demonstrated specificity of SARS-CoV PLpro is discussed.

3-Acylamino-azetidin-2-one as a novel class of cysteine proteases inhibitors

A new class of inhibitors for cysteine proteases cathepsin B, L, K and S is described. These inhibitors are based on the beta-lactam ring designed to interact with the nucleophilic thiol of the cysteine in the active site of cysteine proteases. Some 3-acylamino-azetidin-2-one derivatives showed very potent inhibition activities for cathepsins L, K and S at the nanomolar or subnanomolar IC(50) values.

High incidence of ubiquitin‐like domains in human ubiquitin‐specific proteases

Ubiquitin‐specific proteases (USPs) emerge as key regulators of numerous cellular processes and account for the bulk of human deubiquitinating enzymes (DUBs). Their modular structure, mostly annotated by sequence homology, is believed to determine substrate recognition and subcellular localization. Currently, a large proportion of known human USP sequences are not annotated either structurally or functionally, including regions both within and flanking their catalytic cores. To extend the current understanding of human USPs, we applied consensus fold recognition to the unannotated content of the human USP family. The most interesting discovery was the marked presence of reliably predicted ubiquitin‐like (UBL) domains in this family of enzymes. The UBL domain thus appears to be the most frequently occurring domain in the human USP family, after the characteristic catalytic domain. The presence of multiple UBL domains per USP protein, as well as of UBL domains embedded in the USP catalytic core, add to the structural complexity currently recognized for many DUBs. Possible functional roles of the newly uncovered UBL domains of human USPs, including proteasome binding, and substrate and protein target specificities, are discussed. Proteins 2007.

Family C1 cysteine proteases: Biological diversity or redundancy?

Abstract Recent progress in the identification and partial characterization of novel genes encoding cysteine proteases of the papain family has considerably increased our knowledge of this family of enzymes. Kinetic data available to date for this large family indicate relatively broad, overlapping specificities for most enzymes, thus inspiring a growing conviction that they may exhibit functional redundancy. This is also supported in part by phenotypes of cathepsin knockout mice and suggests that several proteases can substitute for each other to degrade or process a given substrate. On the other hand, specific functions of one particular protease have also been documented. In addition, differences in cellular distribution and intracellular localization may contribute to defining specific functional roles for some of these proteases.

Recent insights into cysteine protease specificity : Lessons for drug design

Cysteine proteases of the papain superfamily are usually considered to possess a relatively broad substrate specificity. However, despite a number of similarities between cysteine proteases, unique and/or restricted preferences for substrates have been served in a few cases and differences do exist that can form the basis for the design of more specific inhibitors. Recent crystallographic measurements coupled to mutational analysis have allowed the molecular basis behind several of these specificity determinants to be uncovered.

Nature of papain products resulting from inactivation by a peptidyl O-acyl hydroxamate.

Mass spectrometry has been used to provide insights into the mechanism of inhibition of cysteine proteases by a hydroxylamine derivative, CBZ‐Phe‐Gly‐NH‐O‐CO‐(2,4,6‐Me3)Ph. An oxidized form of papain resulting from the incubation of the enzyme with the peptidyl hydroxamate in the absence of a reducing agent has been identified as a sulfinic acid. The presence of a covalent enzyme‐inhibitor complex of molecular mass consistent with a sulfenamide adduct of papain could also be detected by this method. Implications on the mechanism of inactivation of cysteine proteases by peptidyl hydroxamates are discussed.

Binding site-based classification of coronaviral papain-like proteases

The coronavirus replicase gene encodes one or two papain‐like proteases (termed PL1pro and PL2pro) implicated in the N‐terminal processing of the replicase polyprotein and thus contributing to the formation of the viral replicase complex that mediates genome replication. Using consensus fold recognition with the 3D‐JURY meta‐predictor followed by model building and refinement, we developed a structural model for the single PLpro present in the severe acute respiratory syndrome coronavirus (SCoV) genome, based on significant structural relationships to the catalytic core domain of HAUSP, a ubiquitin‐specific protease (USP). By combining the SCoV PLpro model with comparative sequence analyses we show that all currently known coronaviral PLpros can be classified into two groups according to their binding site architectures. One group includes all PL2pros and some of the PL1pros, which are characterized by a restricted USP‐like binding site. This group is designated the R‐group. The remaining PL1pros from some of the coronaviruses form the other group, featuring a more open papain‐like binding site, and is referred to as the O‐group. This two‐group, binding site‐based classification is consistent with experimental data accumulated to date for the specificity of PLpro‐mediated polyprotein processing and PLpro inhibition. It also provides an independent evaluation of the similarity‐based annotation of PLpro‐mediated cleavage sites, as well as a basis for comparison with previous groupings based on phylogenetic analyses. Proteins 2006.

Delineating functionally important regions and residues in the cathepsin B propeptide for inhibitory activity.

Synthetic peptides derived from the proregion of rat cathepsin B were used to identify functionally important regions and residues for cathepsin B inhibition. Successive 5 amino acid deletions of a 56 amino acid propeptide from both the N‐ and C‐termini has allowed the identification of two regions important for inhibitory activity: the NTTWQ (residues 21p–25p) and CGTVL (42p–46p) regions. Alanine scanning of residues within these two regions indicates that Trp‐24p and Cys‐42p contribute strongly to inhibition, their replacement by Ala resulting in 160‐ and 140‐fold increases in K i , respectively.

SYNTHESIS OF AMIDRAZONES USING AN ENGINEERED PAPAIN NITRILE HYDRATASE

To demonstrate the usefulness of an engineered papain nitrile hydratase as a biocatalyst, a peptide amidrazone was prepared by incubation of the nitrile MeOCO‐Phe‐Ala‐nitrile with the Gln19Glu papain mutant in the presence of salicylic hydrazide as a nucleophile. The amidrazone results from nucleophilic attack by salicylic hydrazide at the imino carbon of the thioimidate adduct formed between the enzyme and the peptide nitrile substrate. Compared to wild‐type enzyme, the engineered nitrile hydratase causes a better than 4000‐fold increase in the rate of amidrazone formation and yields a product of much higher purity. The advantages over other nitrile‐hydrolyzing enzymes and current limitations of the papain nitrile hydratase are discussed.