Anchoring of surface proteins to the cell wall of Staphylococcus aureus. Cysteine 184 and histidine 120 of sortase form a thiolate-imidazolium ion pair for catalysis.

Surface proteins of Staphylococcus aureus are anchored to the cell wall peptidoglycan by a mechanism requiring a C-terminal sorting signal with a LPXTG motif. Sortase cleaves polypeptides between the threonine and the glycine of the LPXTG motif. The carboxyl group of threonine is subsequently amide-linked to the amino group of peptidoglycan cross-bridges. The three-dimensional structure of sortase revealed the close proximity of the catalytic site residue cysteine 184 with histidine 120; however, no structural evidence for a thiolate-imidazolium ion pair could be detected. We report that alanine substitution of either cysteine 184 or histidine 120 abolishes in vivo and in vitro sorting reactions. Further, alanine substitution of tryptophan 194, a residue that is in close proximity of histidine 120, reduces the transpeptidase activity of sortase. These results suggest a model whereby sortase forms a thiolate-imidazolium ion pair for the catalysis of its transpeptidation reaction and that the position of tryptophan 194 assists in the formation of this ion pair.     

Staphylococcus aureus sortase A contributes to the Trojan horse mechanism of immune defense evasion with its intrinsic resistance to Cys184 oxidation

Staphylococcus aureus is a Gram-positive bacterial pathogen that causes serious infections which have become increasingly difficult to treat due to antimicrobial resistance and natural virulence strategies. Bacterial sortase enzymes are important virulence factors and good targets for future antibiotic development. It has recently been shown that sortase enzymes are integral to bacterial survival of phagocytosis, an underappreciated, but vital, step in S. aureus pathogenesis. Of note, the reaction mechanism of sortases relies on a solvent-accessible cysteine for transpeptidation. Because of the common strategy of oxidative damage employed by professional phagocytes to kill pathogens, it is possible that this cysteine may be oxidized inside the phagosome, thereby inhibiting the enzyme. This study addresses this apparent paradox by assessing the ability of physiological reactive oxygen species, hydrogen peroxide and hypochlorite, to inhibit sortase A (SrtA) from S. aureus. Surprisingly, we found that SrtA is highly resistant to oxidative inhibition, both in vitro and in vivo. The mechanism of resistance to oxidative damage is likely mediated by maintaining a high reduction potential of the catalytic cysteine residue, Cys184. This is due to the unusual active site utilized by S. aureus SrtA, which employs a reverse protonation mechanism for transpeptidation, resulting in a high pK(a) as well as reduction potential for Cys184. The results of this study suggest that S. aureus SrtA is able to withstand the extreme conditions encountered in the phagosome and maintain function, contributing to survival of phagocytotic killing.     

Crystal structures of Staphylococcus aureus sortase A and its substrate complex

The cell wall envelope of staphylococci and other Gram-positive pathogens is coated with surface proteins that interact with human host tissues. Surface proteins of Staphylococcus aureus are covalently linked to the cell wall envelope by a mechanism requiring C-terminal sorting signals with an LPXTG motif. Sortase (SrtA) cleaves surface proteins between the threonine (T) and the glycine (G) of the LPXTG motif and catalyzes the formation of an amide bond between threonine at the C-terminal end of polypeptides and cell wall cross-bridges. The active site architecture and catalytic mechanism of sortase A has hitherto not been revealed. Here we present the crystal structures of native SrtA, of an active site mutant of SrtA, and of the mutant SrtA complexed with its substrate LPETG peptide and describe the substrate binding pocket of the enzyme. Highly conserved proline (P) and threonine (T) residues of the LPXTG motif are held in position by hydrophobic contacts, whereas the glutamic acid residue (E) at the X position points out into the solvent. The scissile T-G peptide bond is positioned between the active site Cys(184) and Arg(197) residues and at a greater distance from the imidazolium side chain of His(120). All three residues, His(120), Cys(184), and Arg(197), are conserved in sortase enzymes from Gram-positive bacteria. Comparison of the active sites of S. aureus sortase A and sortase B provides insight into substrate specificity and suggests a universal sortase-catalyzed mechanism of bacterial surface protein anchoring in Gram-positive bacteria.     

Anchoring of surface proteins to the cell wall of Staphylococcus aureus. A conserved arginine residue is required for efficient catalysis of sortase A

Surface proteins of Staphylococcus aureus are anchored to the cell wall envelope by a mechanism requiring a C-terminal sorting signal with an LPXTG motif. Sortase A cleaves surface proteins between the threonine (T) and the glycine (G) residues of the LPXTG motif and catalyzes the formation of an amide bond between the carboxyl group of threonine at the C-terminal end of polypeptides and the amino group of pentaglycine cross-bridges of cell wall peptidoglycan. Previous work showed that Cys(184) and His(120) of sortase A are absolutely essential for catalysis; however an active site thiolateimidazolium ion pair may not be formed. The three-dimensional crystal structure of sortase A revealed that Arg(197) is located in close proximity to both the active site Cys(184) and the scissile peptide bond between threonine and glycine. We show here that substitution of Arg(197) with alanine, lysine, or histidine severely reduced sortase A function both in vivo and in vitro, whereas Asn(98), which had earlier been implicated in hydrogen bonding to His(120), was found to be dispensable for catalysis. As the structural proximity of Arg(197) and Cys(184) is conserved in sortase enzymes and as ionization of the Cys(184) sulfhydryl group seems required for sortase activity, we propose that Arg(197) may function as a base, facilitating thiolate formation during sortase-mediated cleavage and transpeptidation reactions.     

Anchoring of surface proteins to the cell wall of Staphylococcus aureus. Sortase catalyzed in vitro transpeptidation reaction using LPXTG peptide and NH(2)-Gly(3) substrates

Staphylococcus aureus sortase anchors surface proteins to the cell wall envelope by cleaving polypeptides at the LPXTG motif. Surface proteins are linked to the peptidoglycan by an amide bond between the C-terminal carboxyl and the amino group of the pentaglycine cross-bridge. We find that purified recombinant sortase hydrolyzed peptides bearing an LPXTG motif at the peptide bond between threonine and glycine. In the presence of NH(2)-Gly(3), sortase catalyzed exclusively a transpeptidation reaction, linking the carboxyl group of threonine to the amino group of NH(2)-Gly(3). In the presence of amino group donors the rate of sortase mediated cleavage at the LPXTG motif was increased. Hydrolysis and transpeptidation required the sulfhydryl of cysteine 184, suggesting that sortase catalyzed the transpeptidation reaction of surface protein anchoring via the formation of a thioester acyl-enzyme intermediate.     

一种抗革兰氏阳性致病菌新型靶酶——分选酶

许多革兰氏阳性菌的表面蛋白是经过一种被称为分选酶的半胱氨酸转肽酶的作用而锚定到细胞壁上,由于表面蛋白在病原菌的致病性方面起关键作用,分选酶有可能成为降低革兰氏阳性菌致病性的药物靶点.目前,通过对金黄色葡萄球菌中分选酶A(SrtA)的研究,已初步阐明分选酶的作用机制及其活性位点,与此同时,一些SrtA抑制剂的初步鉴定为今后抑制剂更深层次的筛选提供了基础.     

Cell surface display of minor pilin adhesins in the form of a simple heterodimeric assembly in Corynebacterium diphtheriae

Pilus assembly in Gram-positive bacteria occurs by a two-step mechanism, whereby pilins are polymerized and then covalently anchored to the cell wall. In Corynebacterium diphtheriae, the pilin-specific sortase SrtA catalyses polymerization of the SpaA-type pilus, consisting of the shaft pilin SpaA, tip pilin SpaC and minor pilin SpaB. Cell wall anchoring of the SpaA polymers is triggered when SrtA incorporates SpaB into the pilus base via lysine-mediated transpeptidation; anchoring to the cell wall peptidoglycan is subsequently catalysed by the housekeeping sortase SrtF. Here we show that SpaB and SpaC formed a heterodimer independent of SpaA polymerization. SrtA was absolutely required for the formation of the SpaBC heterodimer, while SrtF facilitated the optimal cell wall anchoring of this heterodimer. Alanine substitution of the SpaB lysine residue K139 or truncation of the SpaB cell wall-sorting signal (CWSS) abolished assembly of the SpaBC heterodimer, hence underscoring SpaB function in transpeptidation and cell wall linkage. Importantly, sortase specificity for the cell wall-anchoring step was found to be dependent on the LAFTG motif within the SpaB CWSS. Thus, C. diphtheriae employs a common sortase-catalysed mechanism involving lysine-mediated transpeptidation to generate both adhesive pilus and simple heterodimeric structures on the bacterial the cell wall.     

Sortase A substrate specificity in GBS pilus 2a cell wall anchoring

Streptococcus agalactiae, also referred to as Group B Streptococcus (GBS), is one of the most common causes of life-threatening bacterial infections in infants. In recent years cell surface pili have been identified in several Gram-positive bacteria, including GBS, as important virulence factors and promising vaccine candidates. In GBS, three structurally distinct types of pili have been discovered (pilus 1, 2a and 2b), whose structural subunits are assembled in high-molecular weight polymers by specific class C sortases. In addition, the highly conserved housekeeping sortase A (SrtA), whose main role is to link surface proteins to bacterial cell wall peptidoglycan by a transpeptidation reaction, is also involved in pili cell wall anchoring in many bacteria. Through in vivo mutagenesis, we demonstrate that the LPXTG sorting signal of the minor ancillary protein (AP2) is essential for pilus 2a anchoring. We successfully produced a highly purified recombinant SrtA (SrtA(ΔN40)) able to specifically hydrolyze the sorting signal of pilus 2a minor ancillary protein (AP2-2a) and catalyze in vitro the transpeptidation reaction between peptidoglycan analogues and the LPXTG motif, using both synthetic fluorescent peptides and recombinant proteins. By contrast, SrtA(ΔN40) does not catalyze the transpeptidation reaction with substrate-peptides mimicking sorting signals of the other pilus 2a subunits (the backbone protein and the major ancillary protein). Thus, our results add further insight into the proposed model of GBS pilus 2a assembly, in which SrtA is required for pili cell wall covalent attachment, acting exclusively on the minor accessory pilin, representing the terminal subunit located at the base of the pilus.     

Kinetic mechanism of Staphylococcus aureus sortase SrtA

Staphylococcus aureus sortase (SrtA) is a thiol transpeptidase. The enzyme catalyzes a cell wall sorting reaction in which a surface protein with a sorting signal containing a LPXTG motif is cleaved between the threonine and glycine residues. The resulting threonine carboxyl end of this protein is covalently attached to a pentaglycine cross-bridge of peptidoglycan. The transpeptidase activity of sortase has been demonstrated in in vitro reactions between a LPETG-containing peptide and triglycine. When a nucleophile is not available, sortase slowly hydrolyzes the LPETG peptide at the same site. In this study, we have analyzed the steady-state kinetics of these two types of reactions catalyzed by sortase. The kinetic results fully support a ping-pong mechanism in which a common acyl-enzyme intermediate is formed in transpeptidation and hydrolysis. However, each reaction has a distinct rate-limiting step: the formation of the acyl-enzyme in transpeptidation and the hydrolysis of the same acyl-enzyme in the hydrolysis reaction. We have also demonstrated in this study that the nucleophile binding site of S. aureus sortase SrtA is specific for diglycine. While S1' and S2' sites of the enzyme both prefer a glycine residue, the S1' site is exclusively selective for glycine. Lengthening of the polyglycine acceptor nucleophile beyond diglycine does not further enhance the binding and catalysis.     

The binding mechanism,multiple binding modes,and allosteric regulation of Staphylococcus aureus Sortase A probed by molecular dynamics simulations

Sortase enzymes are vitally important for the virulence of gram‐positive bacteria as they play a key role in the attachment of surface proteins to the cell wall. These enzymes recognize a specific sorting sequence in proteins destined to be displayed on the surface of the bacteria and catalyze the transpeptidation reaction that links it to a cell wall precursor molecule. Because of their role in establishing pathogenicity, and in light of the recent rise of antibiotic‐resistant bacterial strains, sortase enzymes are novel drug targets. Here, we present a study of the prototypical sortase protein Staphylococcus aureus Sortase A (SrtA). Both conventional and accelerated molecular dynamics simulations of S. aureus SrtA in its apo state and when bound to an LPATG sorting signal (SS) were performed. Results support a binding mechanism that may be characterized as conformational selection followed by induced fit. Additionally, the SS was found to adopt multiple metastable states, thus resolving discrepancies between binding conformations in previously reported experimental structures. Finally, correlation analysis reveals that the SS actively affects allosteric pathways throughout the protein that connect the first and the second substrate binding sites, which are proposed to be located on opposing faces of the protein. Overall, these calculations shed new light on the role of dynamics in the binding mechanism and function of sortase enzymes.     

Bacillus anthracis sortase A (SrtA) anchors LPXTG motif-containing surface proteins to the cell wall envelope

Cell wall-anchored surface proteins of gram-positive pathogens play important roles during the establishment of many infectious diseases, but the contributions of surface proteins to the pathogenesis of anthrax have not yet been revealed. Cell wall anchoring in Staphylococcus aureus occurs by a transpeptidation mechanism requiring surface proteins with C-terminal sorting signals as well as sortase enzymes. The genome sequence of Bacillus anthracis encodes three sortase genes and eleven surface proteins with different types of cell wall sorting signals. Purified B. anthracis sortase A cleaved peptides encompassing LPXTG motif-type sorting signals between the threonine (T) and the glycine (G) residues in vitro. Sortase A activity could be inhibited by thiol-reactive reagents, similar to staphylococcal sortases. B. anthracis parent strain Sterne 34F(2), but not variants lacking the srtA gene, anchored the collagen-binding MSCRAMM (microbial surface components recognizing adhesive matrix molecules) BasC (BA5258/BAS4884) to the bacterial cell wall. These results suggest that B. anthracis SrtA anchors surface proteins bearing LPXTG motif sorting signals to the cell wall envelope of vegetative bacilli.     

New method for site-specific modification of liposomes with proteins using sortase A-mediated transpeptidation

A new method was developed for site-specific modifications of liposomes by proteins via sortase A (SrtA)-mediated transpeptidation reactions. In this regard, the enhanced green fluorescent protein (eGFP) was biologically engineered to carry at its polypeptide C-terminus the LPATG motif recognized by SrtA and used as the protein donor for linking to liposomes that were decorated with phospholipids carrying a diglycine motif as the other SrtA substrate and the eGFP acceptor. Under the influence of SrtA, eGFP was efficiently attached to liposomes, as proved by analyzing the enzymatic reaction products and the resultant fluorescent liposomes. It was observed that increasing the concentration and the distance of the diglycine motif on and from the liposome surface could significantly improve the efficiency of liposome modification by proteins. It is anticipated that this strategy can be widely useful for the modification of liposomes by other proteins.     

Housekeeping sortase facilitates the cell wall anchoring of pilus polymers in Corynebacterium diphtheriae

Many surface proteins in Gram-positive bacteria are covalently linked to the cell wall through a transpeptidation reaction catalysed by the enzyme sortase. Corynebacterium diphtheriae encodes six sortases, five of which are devoted to the assembly of three distinct types of pilus fibres--SrtA for the SpaA-type pilus, SrtB/SrtC for the SpaD-type pilus, and SrtD/SrtE for the SpaH-type pilus. We demonstrate here the function of SrtF, the so-called housekeeping sortase, in the cell wall anchoring of pili. We show that a multiple deletion mutant strain expressing only SrtA secretes a large portion of SpaA polymers into the culture medium, with concomitant decrease in the cell wall-linked pili. The same phenotype is observed with the mutant that is missing SrtF alone. By contrast, a strain that expresses only SrtF displays surface-linked pilins but no polymers. Therefore, SrtF can catalyse the cell wall anchoring of pilin monomers as well as pili, but it does not polymerize pilins. We show that SrtA and SrtF together generate wild-type levels of the SpaA-type pilus on the bacterial surface. Furthermore, by regulating the expression of SpaA in the cell, we demonstrate that the SrtF function becomes critical when the SpaA level is sufficiently high. Together, these findings provide key evidence for a two-stage model of pilus assembly: pilins are first polymerized by a pilus-specific sortase, and the resulting fibre is then attached to the cell wall by either the cognate sortase or the housekeeping sortase.     

Crystal structure of Spy0129, a Streptococcus pyogenes class B sortase involved in pilus assembly

Sortase enzymes are cysteine transpeptidases that mediate the covalent attachment of substrate proteins to the cell walls of Gram-positive bacteria, and thereby play a crucial role in virulence, infection and colonisation by pathogens. Many cell-surface proteins are anchored by the housekeeping sortase SrtA but other more specialised sortases exist that attach sub-sets of proteins or function in pilus assembly. The sortase Spy0129, or SrtC1, from the M1 SF370 strain of Streptococcus pyogenes is responsible for generating the covalent linkages between the pilin subunits in the pili of this organism. The crystal structure of Spy0129 has been determined at 2.3 Å resolution (R = 20.4%, Rfree  = 26.0%). The structure shows that Spy0129 is a class B sortase, in contrast to other characterised pilin polymerases, which belong to class C. Spy0129 lacks a flap believed to function in substrate recognition in class C enzymes and instead has an elaborated β6/β7 loop. The two independent Spy0129 molecules in the crystal show differences in the positions and orientations of the catalytic Cys and His residues, Cys221 and His126, correlated with movements of the β7/β8 and β4/β5 loops that respectively follow these residues. Bound zinc ions stabilise these alternative conformations in the crystal. This conformational variability is likely to be important for function although there is no evidence that zinc is involved in vivo.     

Single mutation on the surface of Staphylococcus aureus Sortase A can disrupt its dimerization

Staphylococcus aureus Sortase A (SrtA) is an important Gram-positive membrane enzyme which catalyzes the anchoring of many cell surface proteins conserved with the LPXTG sequence. Recently SrtA has been demonstrated to be a dimer with a Kd of 55 microM in vitro. Herein, we show that a single point mutation of amino acid residue on the surface of SrtA can completely disrupt the dimerization. Native polyacrylamide gel electrophoresis and analytical gel filtration chromatography were used to detect the dimer-monomer equilibrium of SrtA mutants. Circular dichroism spectrum experiments were performed to study the conformational change of each SrtA mutant. An enzyme activity assay confirmed that all the SrtA mutants were active in vitro. Our results not only are important for understanding the SrtA protein self-associating mechanism but also provided the necessary starting materials for the study of sortase A pathway in vivo, which may have significant implications for discovering microbial physiology and give a potential target for novel Gram-positive antibiotics.     

Mutational analysis of active site residues in the Staphylococcus aureus transpeptidase SrtA

In Staphylococcus aureus, virulence and colonization-associated surface proteins are covalently anchored to the cell wall by the transpeptidase Sortase A (SrtA). In order to better understand the contribution of specific active site residues to substrate recognition and catalysis, we performed mutational analysis of several key residues in the SrtA active site. Analysis of protein stability, kinetic parameters, solvent isotope effects, and pH-rate profiles for key SrtA variants are consistent with a reverse protonated Cys184-His120 catalytic dyad, and implicate a role for Arg197 in formation of an oxyanion hole to stabilize the transition state. In contrast, mutation of Asp185 and Asp186 produced negligible effects on catalysis, and no evidence was found to support the existence of a functional catalytic triad. Mutation of Thr180, Leu181, and Ile182 to alanine produced modest decreases in SrtA activity and led to substrate inhibition. Thermodynamic stability measurements by SUPREX (stability of unpurified proteins from rates of H/D exchange) revealed decreases in conformational stability that correlate with the observed substrate inhibition for each variant, signifying a potential role for the conserved 180TLITC184 motif in defining the active-site architecture of SrtA. In contrast, mutation of Thr183 to alanine led to a significant 1200-fold decrease in kcat, which appears to be unrelated to conformational stability. Potential explanations for these results are discussed, and a revised model for SrtA catalysis is presented.     

Development of an HPLC assay for Staphylococcus aureus sortase: evidence for the formation of the kinetically competent acyl enzyme intermediate

Many bacterial surface proteins containing an LPXTG motif are anchored to the cell wall peptidoglycan by catalysis with the thiol transpeptidase sortase. The transpeptidation and hydrolysis reactions of sortase have been proposed to proceed through a common acyl enzyme intermediate. The reactions of Staphylococcus aureus sortase with fluorogenic substrate Abz-LPETG-Dnp in the presence or absence of triglycine were characterized in this study to gain additional insight into the kinetic mechanism of sortase. We report here the development of a reverse-phase HPLC assay to identify and characterize sortase reaction intermediates. The HPLC results provide for the first time clear evidence for the formation of a kinetically competent acyl enzyme intermediate during the overall transpeptidation reaction. The results also suggest that sortase undergoes an unexpected intramolecular acyl transfer reaction in the absence of a nucleophile. The significance of this type of HPLC assay as a tool to study enzyme mechanism is discussed.     

Development of a high-performance liquid chromatography assay and revision of kinetic parameters for the Staphylococcus aureus sortase transpeptidase SrtA

The SrtA isoform of the Staphylococcus aureus sortase transpeptidase is responsible for the covalent attachment of virulence- and colonization-associated proteins to the bacterial peptidoglycan. Sortase utilizes two substrates, undecaprenol-pyrophosphoryl-MurNAc(GlcNAc)-Ala-d-isoGlu-Lys(-Gly5)-d-Ala-d-Ala (branched Lipid II) and secreted proteins containing a highly conserved LPXTG sequence near their C termini. SrtA simultaneously cleaves the Thr-Gly bond of the LPXTG-containing protein and forms a new amide bond with the nucleophilic amino group of the Gly5 portion of branched Lipid II, anchoring the protein to this key intermediate that is subsequently polymerized into peptidoglycan. Here we show that reported fluorescence quenching activity assays for SrtA are subject to marked fluorescence inner filter effect quenching, resulting in prematurely hyperbolic velocity versus substrate profiles and underestimates of the true kinetic parameters kcat and Km. We therefore devised a discontinuous high-performance liquid chromatography (HPLC)-based assay to monitor the SrtA reaction employing the same substrates used in the fluorescence quenching assay: Gly5 and Abz-LPETG-Dap(Dnp)-NH2. Fluorescence or UV detection using these substrates facilitates separate analysis of both the acylation and the transpeptidation steps of the reaction. Because HPLC was performed using fast-flow analytical columns (<8min/run), high-throughput applications of this assay for analysis of SrtA substrate specificity, kinetic mechanism, and inhibition are now feasible. Kinetic analysis using the HPLC assay revealed that the kinetic parameters for SrtA with Abz-LPETG-Dap(Dnp)-NH2 are 5.5mM for Km and 0.27s-1 for kcat. The Km for Gly5 was determined to be 140microM. These values represent a 300-fold increase in Km for the LPXTG substrate and a 12,000-fold increase in kcat over literature-reported values, suggesting that SrtA is more a robust enzyme than previous analyses indicated.     

Probing of the cis-5-phenyl proline scaffold as a platform for the synthesis of mechanism-based inhibitors of the Staphylococcus aureus sortase SrtA isoform

cis-5-Phenyl prolinates with electrophilic substituents at the fourth position of a pyrrolidine ring were synthesized by 1,3-dipolar cycloaddition of arylimino esters with divinyl sulfone and acrylonitrile. 4-Vinylsulfonyl 5-phenyl prolinates inhibit Staphylococcus aureus sortase SrtA irreversibly by modification of the enzyme Cys184 and could be used as hits for the development of antibacterials and antivirulence agents.     

3C-like proteinase from SARS coronavirus catalyzes substrate hydrolysis by a general base mechanism

SARS 3C-like proteinase has been proposed to be a key enzyme for drug design against SARS. Lack of a suitable assay has been a major hindrance for enzyme kinetic studies and a large-scale inhibitor screen for SARS 3CL proteinase. Since SARS 3CL proteinase belongs to the cysteine protease family (family C3 in clan CB) with a chymotrypsin fold, it is important to understand the catalytic mechanism of SARS 3CL proteinase to determine whether the proteolysis proceeds through a general base catalysis mechanism like chymotrypsin or an ion pair mechanism like papain. We have established a continuous colorimetric assay for SARS 3CL proteinase and applied it to study the enzyme catalytic mechanism. The proposed catalytic residues His41 and Cys145 were confirmed to be critical for catalysis by mutating to Ala, while the Cys145 to Ser mutation resulted in an active enzyme with a 40-fold lower activity. From the pH dependency of catalytic activity, the pK(a)'s for His41 and Cys145 in the wild-type enzyme were estimated to be 6.38 and 8.34, while the pK(a)'s for His41 and Ser145 in the C145S mutant were estimated to be 6.15 and 9.09, respectively. The C145S mutant has a normal isotope effect in D(2)O for general base catalysis, that is, reacts slower in D(2)O, while the wild-type enzyme shows an inverse isotope effect which may come from the lower activation enthalpy. The pK(a) values measured for the active site residues and the activity of the C145S mutant are consistent with a general base catalysis mechanism and cannot be explained by a thiolate-imidazolium ion pair model.