Functional interaction among catalytic residues in subtilisin BPN'

Improvement of the fibrinolytic activity, acid resistance and thermostability of nattokinase by surface charge engineering

Nattokinase is a promising thrombolytic drug due to its powerful fibrinolytic effect and few side effects. However, the low fibrinolytic activity and stability of nattokinase have limited its industrial production and oral application. In this study, the basic and neutral amino acid residues on the surface of recombinant nattokinase AprY from Bacillus mojavensis LY-06 (rAprY) were mutated to acidic amino acid residues by surface charge engineering strategy, and two variants K12D and N109D with 92.6 % and 8.4 % increased fibrinolytic activity were obtained. The R45E variant with enhanced acid stability and thermostability was also screened, its acid stability at pH 4 and t1/2 at 55 °C were 3.7-fold and 1.8-fold higher than that of wild type rAprY, respectively. Bioinformatics analysis showed that the increased activities of K12D and N109D variants were related to the increased flexibility of the region around their active centers. The increased rigidity of 97-103 amino acid residues around the active center of R45E may be the reason for its enhanced stability and reduced catalytic activity. The multipoint mutation K12D-N109D (M2)'s catalytic activity did not increase cumulatively, but its pH stability did. The nattokinase variants generated in this study have potential for industrial production and application.

Transesterification of Non‐Activated Esters Promoted by Small Molecules Mimicking the Active Site of Hydrolases

The synthesis of small molecules able to mimic the active site of hydrolytic enzymes has been largely pursued in recent decades. The high reaction rates and specificity shown by natural hydrolases present an attractive target, and yet the preparation of suitable small‐molecule mimics remains challenging, requiring activated substrates to achieve productive outcomes. Here we present small synthetic artificial enzymes which mimic the catalytic site and the oxyanion hole of chymotrypsin and N‐terminal hydrolases and are able to perform, for the first time, the transesterification of a non‐activated ester such as ethyl acetate with methanol under mild and neutral reaction conditions.

Biotechnology, Bioengineering and Applications of Bacillus Nattokinase

Thrombosis has threatened human health in past decades. Bacillus nattokinase is a potential low-cost thrombolytic drug without side-effects and has been introduced into the consumer market as a functional food or dietary supplement. This review firstly summarizes the biodiversity of sources and the fermentation process of nattokinase, and systematically elucidates the structure, catalytic mechanism and enzymatic properties of nattokinase. In view of the problems of low fermentation yield, insufficient activity and stability of nattokinase, this review discusses the heterologous expression of nattokinase in different microbial hosts and summarizes the protein and genetic engineering progress of nattokinase-producing strains. Finally, this review summarizes the clinical applications of nattokinase.

Molecular mechanism of carbon nanotube to activate Subtilisin Carlsberg in polar and non-polar organic media

In the work, we mainly used molecular dynamics (MD) simulation and protein structure network (PSN) to study subtilisin Carlsberg (SC) immobilized onto carbon nanotube (CNT) in water, acetonitrile and heptane solvents, in order to explore activation mechanism of enzymes in non-aqueous media. The result indicates that the affinity of SC with CNT follows the decreasing order of water > acetonitrile > heptane. The overall structure of SC and the catalytic triad display strong robustness to the change of environments, responsible for the activity retaining. However, the distances between two β-strands of substrate-binding pocket are significantly expanded by the immobilization in the increasing order of water < acetonitrile < heptane, contributing to the highest substrate-binding energy in heptane media. PSN analysis further reveals that the immobilization enhances structural communication paths to the substrate-binding pocket, leading to its larger change than the free-enzymes. Interestingly, the increase in the number of the pathways upon immobilization is not dependent on the absorbed extent but the desorbed one, indicating significant role of shifting process of experimental operations in influencing the functional region. In addition, some conserved and important hot-residues in the paths are identified, providing molecular information for functional modification.

Probing catalytic rate enhancement during intramembrane proteolysis

Rhomboids are ubiquitous intramembrane serine proteases involved in various signaling pathways. While the high-resolution structures of the Escherichia coli rhomboid GlpG with various inhibitors revealed an active site comprised of a serine-histidine dyad and an extensive oxyanion hole, the molecular details of rhomboid catalysis were unclear because substrates are unknown for most of the family members. Here we used the only known physiological pair of AarA rhomboid with its psTatA substrate to decipher the contribution of catalytically important residues to the reaction rate enhancement. An MD-refined homology model of AarA was used to identify residues important for catalysis. We demonstrated that the AarA active site geometry is strict and intolerant to alterations. We probed the roles of H83 and N87 oxyanion hole residues and determined that substitution of H83 either abolished AarA activity or reduced the transition state stabilization energy (ΔΔG‡) by 3.1 kcal/mol; substitution of N87 decreased ΔΔG‡ by 1.6–3.9 kcal/mol. Substitution M154, a residue conserved in most rhomboids that stabilizes the catalytic general base, to tyrosine, provided insight into the mechanism of nucleophile generation for the catalytic dyad. This study provides a quantitative evaluation of the role of several residues important for hydrolytic efficiency and oxyanion stabilization during intramembrane proteolysis.

Analysis of the Resistance Mechanism of a Benzoxaborole Inhibitor Reveals Insight into the Leucyl-tRNA Synthetase Editing Mechanism

A new class of antimicrobial benzoxaborole compounds was identified as a potent inhibitor of leucyl-tRNA synthetase (LeuRS) and therefore of protein synthesis. In a novel mechanism, AN2690 (5-fluoro-1,3-dihydro-1-hydroxy-2,1-benzoxaborole) blocks fungal cytoplasmic LeuRS by covalently trapping tRNA(Leu) in the editing site of the enzyme's CP1 domain. However, some resistant mutation sites are located outside of the CP1 hydrolytic editing active site. Thus, their mode of action that undermines drug inhibition was not understood. A combination of X-ray crystallography, molecular dynamics, metadynamics, biochemical experiments, and mutational analysis of a distal benzoxaborole-resistant mutant uncovered a eukaryote-specific tyrosine "switch" that is critical to tRNA-dependent post-transfer editing. The tyrosine "switch" has three states that shift between interactions with a lysine and the 3'-hydroxyl of the tRNA terminus, to inhibit or promote post-transfer editing. The oxaborole's mechanism of action capitalizes upon one of these editing active site states. This tunable editing mechanism in eukaryotic and archaeal LeuRSs is proposed to facilitate precise quality control of aminoacylation fidelity. These mechanistic distinctions could also be capitalized upon for development of the benzoxaboroles as a broad spectrum antibacterial.

Quantum mechanical modeling: a tool for the understanding of enzyme reactions

Most enzyme reactions involve formation and cleavage of covalent bonds, while electrostatic effects, as well as dynamics of the active site and surrounding protein regions, may also be crucial. Accordingly, special computational methods are needed to provide an adequate description, which combine quantum mechanics for the reactive region with molecular mechanics and molecular dynamics describing the environment and dynamic effects, respectively. In this review we intend to give an overview to non-specialists on various enzyme models as well as established computational methods and describe applications to some specific cases. For the treatment of various enzyme mechanisms, special approaches are often needed to obtain results, which adequately refer to experimental data. As a result of the spectacular progress in the last two decades, most enzyme reactions can be quite precisely treated by various computational methods.

Fundamental challenges in mechanistic enzymology: progress toward understanding the rate enhancements of enzymes

Enzymes are remarkable catalysts that lie at the heart of biology, accelerating chemical reactions to an astounding extent with extraordinary specificity. Enormous progress in understanding the chemical basis of enzymatic transformations and the basic mechanisms underlying rate enhancements over the past decades is apparent. Nevertheless, it has been difficult to achieve a quantitative understanding of how the underlying mechanisms account for the energetics of catalysis, because of the complexity of enzyme systems and the absence of underlying energetic additivity. We review case studies from our own work that illustrate the power of precisely defined and clearly articulated questions when dealing with such complex and multifaceted systems, and we also use this approach to evaluate our current ability to design enzymes. We close by highlighting a series of questions that help frame some of what remains to be understood, and we encourage the reader to define additional questions and directions that will deepen and broaden our understanding of enzymes and their catalysis.

Ground state destabilization from a positioned general base in the ketosteroid isomerase active site

We compared the binding affinities of ground state analogues for bacterial ketosteroid isomerase (KSI) with a wild-type anionic Asp general base and with uncharged Asn and Ala in the general base position to provide a measure of potential ground state destabilization that could arise from the close juxtaposition of the anionic Asp and hydrophobic steroid in the reaction's Michaelis complex. The analogue binding affinity increased ~1 order of magnitude for the Asp38Asn mutation and ~2 orders of magnitude for the Asp38Ala mutation, relative to the affinity with Asp38, for KSI from two sources. The increased level of binding suggests that the abutment of a charged general base and a hydrophobic steroid is modestly destabilizing, relative to a standard state in water, and that this destabilization is relieved in the transition state and intermediate in which the charge on the general base has been neutralized because of proton abstraction. Stronger binding also arose from mutation of Pro39, the residue adjacent to the Asp general base, consistent with an ability of the Asp general base to now reorient to avoid the destabilizing interaction. Consistent with this model, the Pro mutants reduced or eliminated the increased level of binding upon replacement of Asp38 with Asn or Ala. These results, supported by additional structural observations, suggest that ground state destabilization from the negatively charged Asp38 general base provides a modest contribution to KSI catalysis. They also provide a clear illustration of the well-recognized concept that enzymes evolve for catalytic function and not, in general, to maximize ground state binding. This ground state destabilization mechanism may be common to the many enzymes with anionic side chains that deprotonate carbon acids.

Hybrid molecular structure of the giant protease tripeptidyl peptidase II

Tripeptidyl peptidase II (TPP II) is the largest known eukaryotic protease (6 MDa). It is believed to act downstream of the 26S proteasome, cleaving tripeptides from the N termini of longer peptides, and it is implicated in numerous cellular processes. Here we report the structure of Drosophila TPP II determined by a hybrid approach. We solved the structure of the dimer by X-ray crystallography and docked it into the three-dimensional map of the holocomplex, which we obtained by single-particle cryo-electron microscopy. The resulting structure reveals the compartmentalization of the active sites inside a system of chambers and suggests the existence of a molecular ruler determining the size of the cleavage products. Furthermore, the structure suggests a model for activation of TPP II involving the relocation of a flexible loop and a repositioning of the active-site serine, coupling it to holocomplex assembly and active-site sequestration.

Active-site motions and polarity enhance catalytic turnover of hydrated subtilisin dissolved in organic solvents

The enzyme subtilisin Carlsberg was surfactant-solubilized into two organic solvents, isooctane and tetrahydrofuran, and hydrated through stepwise changes in the thermodynamic water activity, a(w). The apparent turnover number k(cat)(app) in these systems ranged from 0.2 to 80 s(-1) and increased 11-fold in isooctane and up to 50-fold in tetrahydrofuran with increasing a(w). (19)F NMR relaxation experiments employing an active-site inhibitor were used to assess the dependence of active-site motions on a(w). The rates of NMR-derived fast (k > 10(7) s(-1)) and slow (k < 10(4) s(-1)) active-site motions increased in both solvents upon hydration, but only the slow motions correlated with k(cat). The (19)F chemical shift was a sensitive probe of the local electronic environment and provided an empirical measure of the active-site dielectric constant epsilon(as), which increased with hydration to epsilon(as) approximately 13 in each solvent. In both solvents, the transition state free energy data and epsilon(as) followed Kirkwood's model for the continuum solvation of a dipole, indicating that water also enhanced catalysis by altering the active-site's electronic environment and increasing its polarity to better stabilize the transition state. These results reveal that favorable dynamic and electrostatic effects both contribute to accelerated catalysis by solubilized subtilisin Carlsberg upon hydration in organic solvents.

Engineered mononuclear variants in Bacillus cereus metallo-beta-lactamase BcII are inactive

Metallo-beta-lactamases (MbetaLs) are zinc enzymes able to hydrolyze almost all beta-lactam antibiotics, rendering them inactive, at the same time endowing bacteria high levels of resistance. The design of inhibitors active against all classes of MbetaLs has been hampered by their structural diversity and by the heterogeneity in metal content in enzymes from different sources. BcII is the metallo-beta-lactamase from Bacillus cereus, which is found in both the mononuclear and dinuclear forms. Despite extensive studies, there is still controversy about the nature of the active BcII species. Here we have designed two mutant enzymes in which each one of the metal binding sites was selectively removed. Both mutants were almost inactive, despite preserving most of the structural features of each metal site. These results reveal that neither site isolated in the MbetaL scaffold is sufficient to render a fully active enzyme. This suggests that only the dinuclear species is active or that the mononuclear variants can be active only if aided by other residues that would be metal ligands in the dinuclear species.

Structural and kinetic contributions of the oxyanion binding site to the catalytic activity of acylaminoacyl peptidase

It is widely accepted that the catalytic activity of serine proteases depends primarily on the Asp-His-Ser catalytic triad and other residues within the vicinity of this motif. Some of these residues form the oxyanion binding site that stabilizes the tetrahedral intermediate by hydrogen bonding to the negatively charged oxyanion. In acylaminoacyl peptidase from the thermophile Aeropyrum pernix, the main chain NH group of Gly369 is one of the hydrogen bond donors forming the oxyanion binding site. The side chain of His367, a conserved residue in acylaminoacyl peptidases across all species, fastens the loop holding Gly369. Determination of the crystal structure of the H367A mutant revealed that this loop, including Gly369, moves away considerably, accounting for the observed three orders of magnitude decrease in the specificity rate constant. For the wild-type enzyme ln(k(cat)/K(m)) vs. 1/T deviates from linearity indicating greater rate enhancement with increasing temperature for the dissociation of the enzyme-substrate complex compared with its decomposition to product. In contrast, the H367A variant provided a linear Arrhenius plot, and its reaction was associated with unfavourable entropy of activation. These results show that a residue relatively distant from the active site can significantly affect the catalytic activity of acylaminoacyl peptidase without changing the overall structure of the enzyme.

Tritylase antibodies

We have used a tris(4-methoxyphenyl)-phosphonium compound as a hapten to elicit catalytic antibodies that selectively remove trityl protecting groups at neutral pH. One antibody, 37C4, was characterized kinetically with a number of trityl substrates. The rate enhancement was consistently near 200; the Km was approximately 30 microM for the methoxytrityl substrates. Compounds with no methoxy substituents on the trityl group were not hydrolysed by the antibody. No decrease in the rate of reaction was detected through 21 turnovers, which suggests that the presumptive trityl cation formed during the cleavage reaction does not alkylate the antibody binding pocket. The rates of the background and antibody-catalysed reactions both increase logarithmically with decreasing pH, implying that general acid catalysis is not involved: further studies will test this assumption. The favoured mechanism for the catalytic activity of antibody 37C4 is charge complementarity in the binding site stabilizing a positively charged intermediate(s) in the cleavage reaction. The coding sequence for 37C4 is being cloned into a phage lambda vector in preparation for site-directed mutagenesis to improve the catalytic efficiency of the antibody.

Catalytic antibodies: contributions from engineering and expression in Escherichia coli

Antibodies have been raised against the transition state of many reactions and shown to catalyse the relevant reaction. Their moderate catalytic efficiencies can be increased by protein engineering, if ways can be found to express the engineered antibody. We have developed a system by which fully functional Fv and Fab fragments can be expressed in Escherichia coli. The Fv fragment dissociates at low concentrations; we therefore devised methods to stabilize the fragment. We showed that the Fv fragment of the antibody McPC603, a phosphorylcholine-binding immunoglobulin A, binds the antigen with the same affinity as does the intact antibody isolated from mouse ascites. Phosphorylcholine is an analogue of the transition state for the hydrolysis of choline carboxylate ester. The Fv fragment of McPC603 catalysed this hydrolysis. Mutational analysis of the residues in the binding site of the antibody has shown which are essential for binding and for catalysis, and the importance of charged residues in certain positions. The E. coli expression system combined with protein engineering and screening methods will facilitate understanding of enzyme catalysis and the development of new catalytic antibodies.

The acylaminoacyl peptidase from Aeropyrum pernix K1 thought to be an exopeptidase displays endopeptidase activity

Mammalian acylaminoacyl peptidase, a member of the prolyl oligopeptidase family of serine peptidases, is an exopeptidase, which removes acylated amino acid residues from the N terminus of oligopeptides. We have investigated the kinetics and inhibitor binding of the orthologous acylaminoacyl peptidase from the thermophile Aeropyrum pernix K1 (ApAAP). Complex pH-rate profiles were found with charged substrates, indicating a strong electrostatic effect in the surroundings of the active site. Unexpectedly, we have found that oligopeptides can be hydrolysed beyond the N-terminal peptide bond, demonstrating that ApAAP exhibits endopeptidase activity. It was thought that the enzyme is specific for hydrophobic amino acids, in particular phenylalanine, in accord with the non-polar S1 subsite of ApAAP. However, cleavage after an Ala residue contradicted this notion and demonstrated that P1 residues of different nature may bind to the S1 subsite depending on the remaining peptide residues. The crystal structures of the complexes formed between the enzyme and product-like inhibitors identified the oxyanion-binding site unambiguously and demonstrated that the phenylalanine ring of the P1 peptide residue assumes a position different from that established in a previous study, using 4-nitrophenylphosphate. We have found that the substrate-binding site extends beyond the S2 subsite, being capable of binding peptides with a longer N terminus. The S2 subsite displays a non-polar character, which is unique among the enzymes of this family. The S3 site was identified as a hydrophobic region that does not form hydrogen bonds with the inhibitor P3 residue. The enzyme-inhibitor complexes revealed that, upon ligand-binding, the S1 subsite undergoes significant conformational changes, demonstrating the plasticity of the specificity site.

Challenges in enzyme mechanism and energetics

Since the discovery of enzymes as biological catalysts, study of their enormous catalytic power and exquisite specificity has been central to biochemistry. Nevertheless, there is no universally accepted comprehensive description. Rather, numerous proposals have been presented over the past half century. The difficulty in developing a comprehensive description for the catalytic power of enzymes derives from the highly cooperative nature of their energetics, which renders impossible a simple division of mechanistic features and an absolute partitioning of catalytic contributions into independent and energetically additive components. Site-directed mutagenesis has emerged as an enormously powerful approach to probe enzymatic catalysis, illuminating many basic features of enzyme function and behavior. The emphasis of site-directed mutagenesis on the role of individual residues has also, inadvertently, limited experimental and conceptual attention to the fundamentally cooperative nature of enzyme function and energetics. The first part of this review highlights the structural and functional interconnectivity central to enzymatic catalysis. In the second part we ask: What are the features of enzymes that distinguish them from simple chemical catalysts? The answers are presented in conceptual models that, while simplified, help illustrate the vast amount known about how enzymes achieve catalysis. In the last section, we highlight the molecular and energetic questions that remain for future investigation and describe experimental approaches that will be necessary to answer these questions. The promise of advancing and integrating cutting edge conceptual, experimental, and computational tools brings mechanistic enzymology to a new era, one poised for novel fundamental insights into biological catalysis.

Electrostatic environment at the active site of prolyl oligopeptidase is highly influential during substrate binding

The positive electrostatic environment of the active site of prolyl oligopeptidase was investigated by using substrates with glutamic acid at positions P2, P3, P4, and P5, respectively. The different substrates gave various pH rate profiles. The pKa values extracted from the curves are apparent parameters, presumably affected by the nearby charged residues, and do not reflect the ionization of a simple catalytic histidine as found in the classic serine peptidases like chymotrypsin and subtilisin. The temperature dependence of kcat/Km did not produce linear Arrhenius plots, indicating different changes in the individual rate constants with the increase in temperature. This rendered it possible to calculate these constants, i.e. the formation (k1) and decomposition (k-1) of the enzyme-substrate complex and the acylation constant (k2), as well as the corresponding activation energies. The results have revealed the relationship between the complex Michaelis parameters and the individual rate constants. Structure determination of the enzyme-substrate complexes has shown that the different substrates display a uniform binding mode. None of the glutamic acids interacts with a charged group. We conclude that the specific rate constant is controlled by k1 rather than k2 and that the charged residues from the substrate and the enzyme can markedly affect the formation but not the structure of the enzyme-substrate complexes.

The sequence and crystal structure of the alpha-amino acid ester hydrolase from Xanthomonas citri define a new family of beta-lactam antibiotic acylases

alpha-Amino acid ester hydrolases (AEHs) catalyze the hydrolysis and synthesis of esters and amides with an alpha-amino group. As such, they can synthesize beta-lactam antibiotics from acyl compounds and beta-lactam nuclei obtained from the hydrolysis of natural antibiotics. This article describes the gene sequence and the 1.9-A resolution crystal structure of the AEH from Xanthomonas citri. The enzyme consists of an alpha/beta-hydrolase fold domain, a helical cap domain, and a jellyroll beta-domain. Structural homology was observed to the Rhodococcus cocaine esterase, indicating that both enzymes belong to the same class of bacterial hydrolases. Docking of a beta-lactam antibiotic in the active site explains the substrate specificity, specifically the necessity of an alpha-amino group on the substrate, and explains the low specificity toward the beta-lactam nucleus.

Esterolytic antibodies as mechanistic and structural models of hydrolases-a quantitative analysis

Understanding enzymes quantitatively and mimicking their remarkable catalytic efficiency is a paramount challenge. Here, we applied esterolytic antibodies (the D-Abs) to dissect and quantify individual elements of enzymatic catalysis such as transition state (TS) stabilization, nucleophilic reactivity and conformational changes. Kinetic and mutagenic analysis of the D-Abs were combined with existing structural evidence to show that catalysis by the D-Abs is driven primarily by stabilization of the tetrahedral oxyanionic intermediate of ester hydrolysis formed by the nucleophilic attack of an exogenous (solution) hydroxide anion. The side-chain of TyrH100d is shown to be the main H-bond donor of the D-Abs oxyanion hole. The pH-rate and pH-binding profiles indicate that the strength of this H-bond increases dramatically as the neutral substrate develops into the oxyanionic TS, resulting in TS stabilization of 5-7 kcal/mol, which is comparable to oxyanionic TS stabilization in serine hydrolases. We show that the rate of the exogenous (intermolecular) nucleophilic attack can be enhanced by 2000-fold by replacing the hydroxide nucleophile with peroxide, an alpha-nucleophile that is much more reactive than hydroxide. In the presence of peroxide, the rate saturates (k(cat)(max)) at 6 s(-1). This rate-ceiling appears to be dictated by the rate of the induced-fit conformational rearrangement leading to the active antibody-TS complex. The selective usage of negatively charged exogenous nucleophiles by the D-Abs led to the identification of a positively charged channel. Imprinted by the negatively-charged TS-analogue against which these antibodies were elicited, this channel presumably directs the nucleophile to the antibody-bound substrate. Our findings are discussed in comparison with serine esterases and, in particular, with cocaine esterase (cocE), which possesses a tyrosine based oxyanion hole.

Enzyme catalysis: removing chemically 'essential' residues by site-directed mutagenesis

Enzymatic catalysis relies on the action of the amino acid side chains arrayed in the enzyme active sites. Usually, only two or three 'essential' residues are directly involved in the bond making and breaking steps leading to product formation. For the past 20 years, enzymologists have been addressing the role of such residues by changing them into chemically inert side chains. Removal of an 'essential' group often does not abolish activity, but can significantly alter the catalytic mechanism. Such results underscore the sophistication of enzyme catalysis and the functional plasticity of enzyme active sites.

Protein engineering of subtilisin

The serine protease subtilisin is an important industrial enzyme as well as a model for understanding the enormous rate enhancements affected by enzymes. For these reasons along with the timely cloning of the gene, ease of expression and purification and availability of atomic resolution structures, subtilisin became a model system for protein engineering studies in the 1980s. Fifteen years later, mutations in well over 50% of the 275 amino acids of subtilisin have been reported in the scientific literature. Most subtilisin engineering has involved catalytic amino acids, substrate binding regions and stabilizing mutations. Stability has been the property of subtilisin which has been most amenable to enhancement, yet perhaps least understood. This review will give a brief overview of the subtilisin engineering field, critically review what has been learned about subtilisin stability from protein engineering experiments and conclude with some speculation about the prospects for future subtilisin engineering.

The Oxyanion Hole in Serine beta-Lactamase Catalysis: Interactions of Thiono Substrates with the Active Site

Both functional and structural studies of serine beta-lactamases indicate the existence of an oxyanion hole at the active site with an important role in catalysis. The functional presence of the oxyanion hole is demonstrated by the previous observation that thiono-beta-lactams are very poor substrates of beta-lactamases (B. P. Murphy, and R. F. Pratt, 1988, Biochem. J. 256, 669-672) and in the present paper by the inability of these enzymes to catalyze hydrolysis of a thiono analog of a depsipeptide substrate. This thiono effect was first noted and interpreted in regard to classical serine hydrolases although the chemical basis for it has not been firmly established either in those enzymes or in beta-lactamases. In this paper a computational approach to a further understanding of the effect has been taken. The results for a class C beta-lactamase show that the deacylation tetrahedral intermediate interacted more strongly with the enzyme with an O(-) placed in the oxyanion hole than an S(-). On the other hand, the converse was true for acylation tetrahedral intermediate species, a result distinctly not in accord with experiment. These results indicate that the thiono effect does not arise from unfavorable interactions between enzyme and thiono substrate at the tetrahedral intermediate stage but must be purely kinetic in nature, i.e., arise in a transitional species at an early stage of the acylation reaction. The same conclusion as to the origin of the thiono effect was also indicated by a less extensive series of calculations on a class A beta-lactamase and on chymotrypsin.

Clarifying the catalytic roles of conserved residues in the amidase signature family

Fatty acid amide hydrolase (FAAH) is a mammalian integral membrane enzyme responsible for the hydrolysis of a number of neuromodulatory fatty acid amides, including the endogenous cannabinoid anandamide and the sleep-inducing lipid oleamide. FAAH belongs to a large class of hydrolytic enzymes termed the "amidase signature family," whose members are defined by a conserved stretch of approximately 130 amino acids termed the "amidase signature sequence." Recently, site-directed mutagenesis studies of FAAH have targeted a limited number of conserved residues in the amidase signature sequence of the enzyme, identifying Ser-241 as the catalytic nucleophile and Lys-142 as an acid/base catalyst. The roles of several other conserved residues with potentially important and/or overlapping catalytic functions have not yet been examined. In this study, we have mutated all potentially catalytic residues in FAAH that are conserved among members of the amidase signature family, and have assessed their individual roles in catalysis through chemical labeling and kinetic methods. Several of these residues appear to serve primarily structural roles, as their mutation produced FAAH variants with considerable catalytic activity but reduced expression in prokaryotic and/or eukaryotic systems. In contrast, five mutations, K142A, S217A, S218A, S241A, and R243A, decreased the amidase activity of FAAH greater than 100-fold without detectably impacting the structural integrity of the enzyme. The pH rate profiles, amide/ester selectivities, and fluorophosphonate reactivities of these mutants revealed distinct catalytic roles for each residue. Of particular interest, one mutant, R243A, displayed uncompromised esterase activity but severely reduced amidase activity, indicating that the amidase and esterase efficiencies of FAAH can be functionally uncoupled. Collectively, these studies provide evidence that amidase signature enzymes represent a large class of serine-lysine catalytic dyad hydrolases whose evolutionary distribution rivals that of the catalytic triad superfamily.

Characterization of the streptococcal C5a peptidase using a C5a-green fluorescent protein fusion protein substrate

A glutathione-S-transferase (GST)-C5a-green fluorescent protein (GFP) fusion protein was designed for use as a substrate for the streptococcal C5a peptidase (SCPA). The substrate was immobilized on a glutathione-Sepharose affinity matrix and used to measure wild-type SCPA activity in the range of 0.8 to 800 nM. The results of the assay demonstrated that SCPA is highly heat stable and has optimal activity on the synthetic substrate at or above pH 8.0. SCPA activity was unaffected by 0.1 to 10 mM Ca(2+), Mg(2+), and Mn(2+) but was inhibited by the same concentrations of Zn(2+). The assay shows high sensitivity to ionic strength; NaCl inhibits SCPA cleavage of GST-C5a-GFP in a dose-dependent manner. Based on previously published computer homology modeling, four substitutions were introduced into the putative active site of SCPA: Asp(130)-Ala, His(193)-Ala, Asn(295)-Ala, and Ser(512)-Ala. All four mutant proteins had over 1,000-fold less proteolytic activity on C5a in vitro, as determined both by the GFP assay described here and by a polymorphonuclear cell adherence assay. In addition, recombinant SCPA1 and SCPA49, from two distinct lineages of Streptococcus pyogenes (group A streptococci), and recombinant SCPB, from Streptococcus agalactiae (group B streptococci), were compared in the GFP assay. The three enzymes had similar activities, all cleaving approximately 6 mol of C5a mmol of SCP(-1) liter(-1) min(-1).

Substrate- and pH-dependent contribution of oxyanion binding site to the catalysis of prolyl oligopeptidase, a paradigm of the serine oligopeptidase family

Prolyl oligopeptidase, an enzyme implicated in memory disorders, is a member of a new serine peptidase family. Crystallographic studies (Fülöp et al., 1998) revealed a novel oxyanion binding site containing a tyrosine residue, Tyr473. To study the importance of Tyr473 OH, we have produced prolyl oligopeptidase and its Tyr473Phe variant in Escherichia coli. The specificity rate constant, k(cat)/Km, for the modified enzyme decreased by a factor of 8-40 with highly specific substrates, Z-Gly-Pro-Nap, and a fluorogenic octapeptide. With these compounds, the decline in k(cat) was partly compensated for by reduction in Km, a difference from the extensively studied subtilisin. With the less specific suc-Gly-Pro-Nap, the Km value, which approximates Ks, was not significantly changed, resulting in greater diminution (approximately 500-fold) in k(cat)/Km. The second-order rate constant for the reaction with Z-Pro-prolinal, a slow tight-binding transition-state analogue inhibitor, and the Ki values for a slow substrate and two product-like inhibitors were not significantly affected by the Tyr473 OH group. The mechanism of transition-state stabilization was markedly dependent upon the nature of substrate and varied with pH as the enzyme interconverted between its two catalytically competent forms.

Properties of a subtilisin-like proteinase from a psychrotrophic Vibrio species comparison with proteinase K and aqualysin I

An extracellular serine proteinase purified from cultures of a psychrotrophic Vibrio species (strain PA-44) belongs to the proteinase K family of the superfamily of subtilisin-like proteinases. The enzyme is secreted as a 47-kDa protein, but under mild heat treatment (30 min at 40 degrees C) undergoes autoproteolytic cleavage on the carboxyl-side of the molecule to give a proteinase with a molecular mass of about 36 kDa that apparently shares most of the enzymatic characteristics and the stability of the 47-kDa protein. In this study, selected enzymatic properties of the Vibrio proteinase were compared with those of the related proteinases, proteinase K and aqualysin I, as representative mesophilic and thermophilic enzymes, respectively. The catalytic efficiency (kcat/Km) for the amidase activity of the cold-adapted enzyme against succinyl-AAPF-p-nitroanilide was significantly higher than that of its mesophilic and thermophilic counterparts, especially when compared with aqualysin I. The stability of the Vibrio proteinase, both towards heat and denaturants, was found to be significantly lower than of either proteinase K or aqualysin I. One or more disulfide bonds in the psychrotrophic proteinase are important for the integrity of the active enzyme structure, as disulfide cleavage, either by reduction with dithiothreitol or by sulfitolysis, led to a loss in its activity. Under the same conditions, aqualysin I was also partially inactivated by dithiothreitol, but the activity of proteinase K was unaffected. The disulfides of either proteinase K or aqualysin I were not reactive towards sulfitolysis, except under denaturing conditions, while all disulfides of the Vibrio proteinase reacted in absence of a denaturant. The reactivity of the disulfides of the proteins as a function of denaturant concentration followed the order: Vibrio proteinase > proteinase K > aqualysin I. The same order of reactivity was also observed for the inactivation of the enzymes by H2O2-oxidation, as a function of temperature. The order of reactivity observed in these reactions most likely reflects the accessibility of the reactive cystine or methionine side chains present in the three related proteinases, and hence a difference in the compactness of their protein structures.

Functional characteristics of the oxyanion hole in human acetylcholinesterase

The contribution of the oxyanion hole to the functional architecture and to the hydrolytic efficiency of human acetylcholinesterase (HuAChE) was investigated through single replacements of its elements, residues Gly-121, Gly-122 and the adjacent residue Gly-120, by alanine. All three substitutions resulted in about 100-fold decrease of the bimolecular rate constants for hydrolysis of acetylthiocholine; however, whereas replacements of Gly-120 and Gly-121 affected only the turnover number, mutation of residue Gly-122 had an effect also on the Michaelis constant. The differential behavior of the G121A and G122A enzymes was manifested also toward the transition state analog m-(N,N, N-trimethylammonio)trifluoroacetophenone (TMTFA), organophosphorous inhibitors, carbamates, and toward selected noncovalent active center ligands. Reactivity of both mutants toward TMTFA was 2000-11, 000-fold lower than that of the wild type HuAChE; however, the G121A enzyme exhibited a rapid inhibition pattern, as opposed to the slow binding kinetics shown by the G122A enzyme. For both phosphates (diethyl phosphorofluoridate, diisopropyl phosphorofluoridate, and paraoxon) and phosphonates (sarin and soman), the decrease in inhibitory activity toward the G121A enzyme was very substantial (2000-6700-fold), irrespective of size of the alkoxy substituents on the phosphorus atom. On the other hand, for the G122A HuAChE the relative decline in reactivity toward phosphonates (500-460-fold) differed from that toward the phosphates (12-95-fold). Although formation of Michaelis complexes with substrates does not seem to involve significant interaction with the oxyanion hole, interactions with this motif are a major stabilizing element in accommodation of covalent inhibitors like organophosphates or carbamates. These observations and molecular modeling suggest that replacements of residues Gly-120 or Gly-121 by alanine alter the structure of the oxyanion hole motif, abolishing the H-bonding capacity of residue at position 121. These mutations weaken the interaction between HuAChE and the various ligands by 2.7-5.0 kcal/mol. In contrast, variations in reactivity due to replacement of residue Gly-122 seem to result from steric hindrance at the active center acyl pocket.

Computer simulations of enzyme catalysis: finding out what has been optimized by evolution

The origin of the catalytic power of enzymes is discussed, paying attention to evolutionary constraints. It is pointed out that enzyme catalysis reflects energy contributions that cannot be determined uniquely by current experimental approaches without augmenting the analysis by computer simulation studies. The use of energy considerations and computer simulations allows one to exclude many of the popular proposals for the way enzymes work. It appears that the standard approaches used by organic chemists to catalyze reactions in solutions are not used by enzymes. This point is illustrated by considering the desolvation hypothesis and showing that it cannot account for a large increase in kcat relative to the corresponding kcage for the reference reaction in a solvent cage. The problems associated with other frequently invoked mechanisms also are outlined. Furthermore, it is pointed out that mutation studies are inconsistent with ground state destabilization mechanisms. After considering factors that were not optimized by evolution, we review computer simulation studies that reproduced the overall catalytic effect of different enzymes. These studies pointed toward electrostatic effects as the most important catalytic contributions. The nature of this electrostatic stabilization mechanism is far from being obvious because the electrostatic interaction between the reacting system and the surrounding area is similar in enzymes and in solution. However, the difference is that enzymes have a preorganized dipolar environment that does not have to pay the reorganization energy for stabilizing the relevant transition states. Apparently, the catalytic power of enzymes is stored in their folding energy in the form of the preorganized polar environment.

A 13C-NMR study of the role of Asn-155 in stabilizing the oxyanion of a subtilisin tetrahedral adduct

By removing one of the hydrogen-bond donors in the oxyanion hole of subtilisin BPN, we have been able to determine how it affects the catalytic efficiency of the enzyme and the pKa of the oxyanion formed in a choloromethane inhibitor derivative. Variant 8397 of subtilisin BPN contains five mutations which enhance its stability. Site-directed mutagenesis was used to prepare the N155A mutant of this variant. The catalytic efficiencies of wild-type and variant 8397 are similar, but replacing Asn-155 with alanine reduces catalytic efficiency approx. 300-fold. All three forms of subtilisin were alkylated using benzyloxycarbonylglycylglycyl[2-13C]phenylalanylchloromethane++ + and examined by 13C-NMR. A single signal due to the 13C-enriched carbon was detected in all the derivatives and it was assigned to the hemiketal carbon of a tetrahedral adduct formed between the hydroxy group of Ser-221 and the inhibitor. This signal had chemical shifts in the range 98.3-103.6 p.p.m., depending on the pH. The titration shift of 4.7-4.8 p.p.m. was assigned to oxyanion formation. The oxyanion pKa values in the wild-type and 8397 variants were 6.92 and 7.00 respectively. In the N155A mutant of the 8397 variant the oxyanion pKa increased to 8.09. We explain why such a small increase is observed and we conclude that it is the interaction between the oxyanion and the imidazolium cation of the active-site histidine that is the main factor responsible for lowering the oxyanion pKa.

Additivity of protein-guanine interactions in ribonuclease T1

It has been established that Tyr-42, Tyr-45, and Glu-46 take part in a structural motif that renders guanine specificity to ribonuclease T1. We report on the impact of Tyr-42, Tyr-45, and Glu-46 substitutions on the guanine specificity of RNase T1. The Y42A and E46A mutations profoundly affect substrate binding. No such effect is observed for Y45A RNase T1. From the kinetics of the Y42A/Y45A and Y42A/E46A double mutants, we conclude that these pairs of residues contribute to guanine specificity in a mutually independent way. From our results, it appears that the energetic contribution of aromatic face-to-face stacking interactions may be significant if polycyclic molecules, such as guanine, are involved.

Subtilases: the superfamily of subtilisin-like serine proteases

Subtilases are members of the clan (or superfamily) of subtilisin-like serine proteases. Over 200 subtilases are presently known, more than 170 of which with their complete amino acid sequence. In this update of our previous overview (Siezen RJ, de Vos WM, Leunissen JAM, Dijkstra BW, 1991, Protein Eng 4:719-731), details of more than 100 new subtilases discovered in the past five years are summarized, and amino acid sequences of their catalytic domains are compared in a multiple sequence alignment. Based on sequence homology, a subdivision into six families is proposed. Highly conserved residues of the catalytic domain are identified, as are large or unusual deletions and insertions. Predictions have been updated for Ca(2+)-binding sites, disulfide bonds, and substrate specificity, based on both sequence alignment and three-dimensional homology modeling.

Thermitase - kinetic differentiation to the subtilisins

In the last 12 years more than 80 peptidyl substrates and substrate analogous inhibitors were synthesized in our group and used to characterize thermitase, a serine proteinase of the subtilisin family produced by Thermoactinomyces vulgaris. The kinetic parameters of hydrolysis and inhibition reactions, respectively, with thermitase were determined and compared with those found with related enzymes. Conclusions with respect to the extent of the active site of thermitase and to the specificity of the different subsites could be drawn.

Analysis of the role of the KMSKS loop in the catalytic mechanism of the tyrosyl-tRNA synthetase using multimutant cycles

A mobile loop in tyrosyl-tRNA synthetase, which corresponds to the KMSKS signature sequence of class I aminoacyl-tRNA synthetases, destabilizes the E.Tyr.ATP complex but stabilizes the following E.[Tyr-ATP]not equal to transition state for the formation of E.Tyr-AMP. Three amino acid residues in the mobile loop, K230, K233, and T234, are known to be primarily responsible for these effects. We now analyze the network of interactions between these three amino acids using multiple mutant free energy cycles. The complete characterization of the coupling energies within the mobile loop allows each of the steps leading to the formation of the transition state complex to be dissected into its energetic components. In particular, it is found that, in the absence of a functional mobile loop, there is synergistic coupling between the tyrosine and ATP substrates (i.e., each enhances the binding affinity of the other) which stabilizes the E.Tyr.ATP intermediate preceding the transition state complex. Thus, the mobile loop disrupts the synergism between the ATP and tyrosine substrates, using the ATP binding energy to stabilize the transition state for the reaction. Whereas the net effect of the mobile loop in the E.Tyr.ATP complex results from several conflicting side chain interactions that tend to offset each other, conflicting interactions in the E.[Tyr-ATP]not equal to transition state complex have been minimized and stabilizing pairwise interactions between the K230, K233, and T234 side chains are optimized. The tight coupling between the side chains of K230, K233, and T234 suggests that the mobile loop adopts a highly constrained conformation during formation of the transition state complex. These results quantitatively demonstrate the importance of side chain interactions in enzyme catalysis and illustrate the use of binding energy to stabilize the transition state of a reaction and the presence of unfavorable interactions to destabilize the ground state.

A study of the stabilization of the oxyanion of tetrahedral adducts by trypsin, chymotrypsin and subtilisin

Subtilisin and delta-chymotrypsin have been alkylated using 2-13C-enriched benzyloxycarbonylglycylglycylphenylalanylchloromethane. A single signal due to the 13C-enriched carbon was detected in both the intact subtilisin and delta-chymotrypsin derivatives. The signal titrated from 98.9 p.p.m. to 103.6 p.p.m. with a pKa value of 6.9 in the subtilisin derivative and it is assigned to a tetrahedral adduct formed between the hydroxy group of serine-221 and the inhibitor. The signal in the delta-chymotrypsin derivative titrated from 98.5 p.p.m. to 103.2 p.p.m. with a pKa value of 8.92 and it is assigned to a tetrahedral adduct formed between the hydroxy group of serine-195 and the inhibitor. In both derivatives the titration shift is assigned to the formation of the oxyanion of the tetrahedral adduct. delta-Chymotrypsin has been inhibited by benzyloxycarbonylphenylalanylchloromethane and two signals due to 13C-enriched carbons were detected. One of these signals titrated from 98.8 p.p.m. to 103.6 p.p.m. with a pKa value of 9.4 and it was assigned in the same way as in the previous delta-chymotrypsin derivative. The second signal had a chemical shift of 204.5 +/- 0.5 p.p.m. and it did not titrate from pH 3.5 to 9.0. This signal was assigned to alkylated methionine-192. We discuss how subtilisin and chymotrypsin could stabilize the oxyanion of tetrahedral adducts.

Structural basis of substrate specificity in the serine proteases

Structure-based mutational analysis of serine protease specificity has produced a large database of information useful in addressing biological function and in establishing a basis for targeted design efforts. Critical issues examined include the function of water molecules in providing strength and specificity of binding, the extent to which binding subsites are interdependent, and the roles of polypeptide chain flexibility and distal structural elements in contributing to specificity profiles. The studies also provide a foundation for exploring why specificity modification can be either straightforward or complex, depending on the particular system.

Modification of the electrostatic environment is tolerated in the oxyanion hole of the cysteine protease papain

The oxyanion hole in cysteine and serine proteases can be viewed as an arrangement of prealigned dipoles that complements the changes in charge distribution during the enzymatic reaction. Because of the electrostatic nature of the interaction involved in the oxyanion hole, the introduction of charged residues in that region could have a major effect on the catalytic properties of the enzyme. In this study, residue Gln19, which contributes to one of the hydrogen bonds in the oxyanion hole of papain, has been replaced by glutamic acid, histidine, and asparagine residues. These mutations result in 65-315-fold decreases in kcat/KM, supporting our previous finding that the side chain of Gln19 contributes to transition state stabilization in the oxyanion hole of papain (Ménard et al., 1991a). Since papain is active over a wide range of pH values, the influence of side chain ionization on activity could be measured quantitatively with the mutant Gln19Glu. The pH dependency of kcat/KM for Gln19Glu is not of the classical bell-shaped form normally observed for papain, but instead is modulated by ionization of the Glu19 side chain with a pKa of 6.02. The Gln19Glu mutant at low pH, where the Glu19 side chain is neutral, is the enzyme that displays activity closest to that of wild-type enzyme, with a (kcat/KM)1lim value only 20-fold lower than that for papain. As expected, the activity of the Gln19Glu mutant decreases when the Glu19 side chain ionizes. However, introduction of the negatively charged glutamate into the oxyanion hole of papain leads to a further reduction in activity of only 12-fold, and this mutant is still more active than the Gln19Ser enzyme and only 3-fold less active than Gln19Asn.(ABSTRACT TRUNCATED AT 250 WORDS)

The sequence, crystal structure determination and refinement of two crystal forms of lipase B from Candida antarctica

BACKGROUND

Lipases constitute a family of enzymes that hydrolyze triglycerides. They occur in many organisms and display a wide variety of substrate specificities. In recent years, much progress has been made towards explaining the mechanism of these enzymes and their ability to hydrolyze their substrates at an oil-water interface.

RESULTS

We have determined the DNA and amino acid sequences for lipase B from the yeast Candida antarctica. The primary sequence has no significant homology to any other known lipase and deviates from the consensus sequence around the active site serine that is found in other lipases. We have determined the crystal structure of this enzyme using multiple isomorphous replacement methods for two crystal forms. Models for the orthorhombic and monoclinic crystal forms of the enzyme have been refined to 1.55 A and 2.1 A resolution, respectively. Lipase B is an alpha/beta type protein that has many features in common with previously determined lipase structures and other related enzymes. In the monoclinic crystal form, lipid-like molecules, most likely beta-octyl glucoside, can be seen close to the active site. The behaviour of these lipid molecules in the crystal structure has been studied at different pH values.

CONCLUSION

The structure of Candida antarctica lipase B shows that the enzyme has a Ser-His-Asp catalytic triad in its active site. The structure appears to be in an 'open' conformation with a rather restricted entrance to the active site. We believe that this accounts for the substrate specificity and high degree of stereospecificity of this lipase.

Replacement of catalytic histidine-195 of chloramphenicol acetyltransferase: evidence for a general base role for glutamate

The imidazole N epsilon 2 of His-195 plays an essential part in the proposed general base mechanism of chloramphenicol acetyltransferase (CAT), hydrogen bonding to and a abstracting a proton from the primary hydroxyl group of chloramphenicol. Replacement of His-195 by alanine or glutamine results in apparent decreases in kcat of (9 x 10(5)- and (3 x 10(5))-fold, respectively, whereas Km values for both substrates (chloramphenicol and acetyl-CoA) are similar to those of wild-type CAT. The structure of Gln-195 CAT has been solved at 2.5-A resolution and is largely isosteric with that of wild-type CAT. Substitution of His-195 by glutamate resulted in a (5 x 10(4))-fold decrease in kcat together with a 3-fold increase in the Km for chloramphenicol. Direct determination of binding constants for both substrates demonstrated that these substitutions result in only small decreases in the affinity of CAT for acetyl-CoA (Kd values increased 2- to 3-fold), whereas chloramphenicol Kd values are elevated 26-, 20-, and 53-fold for Ala-195 CAT, Gln-195 CAT and Glu-195 CAT, respectively. The pH dependence of kcat/Km yields apparent pKa values of 6.5 and 6.7 for Ala-195 CAT and Gln-195 CAT, respectively, which are very similar to that (6.6) determined for the ionization of His-195 in wild-type CAT. In contrast, the pH dependence of kcat/Km for Glu-195 CAT (pKa = 8.3) is very different from that of wild-type CAT.(ABSTRACT TRUNCATED AT 250 WORDS)