Role of protein conformational dynamics in the catalysis by 6-hydroxymethyl-7,8-dihydropterin pyrophosphokinase

Enzymatic catalysis has conflicting structural requirements of the enzyme. In order for the enzyme to form a Michaelis complex, the enzyme must be in an open conformation so that the substrate can get into its active center. On the other hand, in order to maximize the stabilization of the transition state of the enzymatic reaction, the enzyme must be in a closed conformation to maximize its interactions with the transition state. The conflicting structural requirements can be resolved by a flexible active center that can sample both open and closed conformational states. For a bisubstrate enzyme, the Michaelis complex consists of two substrates in addition to the enzyme. The enzyme must remain flexible upon the binding of the first substrate so that the second substrate can get into the active center. The active center is fully assembled and stabilized only when both substrates bind to the enzyme. However, the side-chain positions of the catalytic residues in the Michaelis complex are still not optimally aligned for the stabilization of the transition state, which lasts only approximately 10(-13) s. The instantaneous and optimal alignment of catalytic groups for the transition state stabilization requires a dynamic enzyme, not an enzyme which undergoes a large scale of movements but an enzyme which permits at least a small scale of adjustment of catalytic group positions. This review will summarize the structure, catalytic mechanism, and dynamic properties of 6-hydroxymethyl-7,8-dihydropterin pyrophosphokinase and examine the role of protein conformational dynamics in the catalysis of a bisubstrate enzymatic reaction.     

Dissecting the Microscopic Steps of the Cyclophilin A Enzymatic Cycle on the Biological HIV-1 Capsid Substrate by NMR

Peptidyl-prolyl isomerases (PPIases) are emerging as key regulators of many diverse biological processes. Elucidating the role of PPIase activity in vivo has been challenging because mutagenesis of active-site residues not only reduces the catalytic activity of these enzymes but also dramatically affects substrate binding. Employing the cyclophilin A PPIase together with its biologically relevant and natively folded substrate, the N-terminal domain of the human immunodeficiency virus type 1 capsid (CA^N) protein, we demonstrate here how to dissect residue-specific contributions to PPIase catalysis versus substrate binding utilizing NMR spectroscopy. Surprisingly, a number of cyclophilin A active-site mutants previously assumed to be strongly diminished in activity toward biological substrates based only on a peptide assay catalyze the human immunodeficiency virus capsid with wild-type activity but with a change in the rate-limiting step of the enzymatic cycle. The results illustrate that a quantitative analysis of catalysis using the biological substrates is critical when interpreting the effects of PPIase mutations in biological assays.     

Unique oligomeric intermediates of bovine liver catalase

Catalases, although synthesized from single genes and built up from only one type of subunit, exist in heterogeneous form with respect to their conformations and association states in biological systems. This heterogeneity is not of genetic origin, but rather reflects the instability of this oligomeric heme enzyme. To understand better the factors that stabilize the various association states of catalase, we performed studies on the multimeric intermediates that are stabilized during guanidine-hydrochloride- and urea-induced unfolding of bovine liver catalase (BLC). For the first time, we have observed an enzymatically active, folded dimer of native BLC. This dimer has slightly higher enzymatic activity and altered structural properties compared to the native tetramer. Comparative studies of the effect of NaCl, GdmCl, and urea on BLC show that cation binding to negatively charged groups present in amino acid side chains of the enzyme leads to stabilization of an enzymatically active, folded dimer of BLC. Besides the folded dimer, an enzymatically active expanded tetramer and a partially unfolded, enzymatically inactive dimer of BLC were also observed. A complete recovery of native enzyme was observed on refolding of expanded tetramers and folded dimers; however, a very low recovery (maximum of approximately 5%) of native enzyme was observed on refolding of partially unfolded dimers and fully unfolded monomers.     

Correlation between catalysis and tertiary structure arrangement in an archaeal halophilic subtilase

Nep (Natrialba magadii extracellular protease) is a halolysin-like peptidase secreted by the haloalkaliphilic archaeon N. magadii that exhibits optimal activity and stability in salt-saturated solutions. In this work, the effect of salt on the function and structure of Nep was investigated. In absence of salt, Nep became unfolded and aggregated, leading to the loss of activity. The enzyme did not recover its structural and functional properties even after restoring the ideal conditions for catalysis. At salt concentrations higher than 1 M (NaCl), Nep behaved as monomers in solution and its enzymatic activity displayed a nonlinear concave-up dependence with salt concentration resulting in a 20-fold activation at 4 M NaCl. Although transition from a high to a low-saline environment (3–1 M NaCl) did not affect its secondary structure contents, it diminished the enzyme stability and provoked large structural rearrangements, changing from an elongated shape at 3 M NaCl to a compact conformational state at 1 M NaCl. The thermodynamic analysis of peptide hydrolysis by Nep suggests a significant enzyme reorganization depending on the environmental salinity, which supports in solution SAXS and DLS studies. Moreover, solvent kinetic isotopic effect (SKIE) data indicates the general acid-base mechanism as the rate-limiting step for Nep catalysis, like classical serine-peptidases. All these data correlate the Nep conformational states with the enzymatic behavior providing a further understanding on the stability and structural determinants for the functioning of halolysins under different salinities.     

Conformationally specific misfolding of an integral membrane protein

Membrane protein misfolding is related to the etiology of many diseases, but is poorly understood, particularly from a structural standpoint. This study focuses upon misfolding of a mutant form of diacylglycerol kinase (s-DAGK), a 40 kDa homotrimeric protein having nine transmembrane segments. Preparations of s-DAGK sometimes contain a kinetically trapped misfolded population, as evidenced by lower-than-expected enzyme activity (with no accompanying change in substrate K(m)) and by the appearance of a second band in electrophoresis gels. Misfolding of s-DAGK may take place during cellular overexpression, but can also be reproduced using the purified enzyme. TROSY NMR spectra of s-DAGK as a 100 kDa complex with detergent micelles exhibit a single additional set of resonances from the misfolded form, indicating a single misfolded conformational state. The relative intensities of these extra resonances correlate with the percent reduction in enzyme activity below the maximum observed for fully folded s-DAGK. Misfolded s-DAGK exhibits a modest difference in its far-UV CD spectrum compared to the folded enzyme, consistent with a small degree of variance in secondary structural content between the two forms. However, differences in NMR chemical shift dispersion and temperature-dependent line widths exhibited by folded and misfolded s-DAGK support the notion that they represent very different structural states. Cross-linking experiments indicate that both the correctly folded enzyme and the kinetically trapped misfolded form are homotrimers. This work appears to represent the first documentation of conformationally specific misfolding of an integral membrane protein.     

Electrostatic guidance of glycosyl cation migration along the reaction coordinate of uracil DNA glycosylase

The DNA repair enzyme uracil DNA glycosylase has been crystallized with a cationic 1-aza-2'-deoxyribose-containing DNA that mimics the ultimate transition state of the reaction in which the water nucleophile attacks the anomeric center of the oxacarbenium ion-uracil anion reaction intermediate. Comparison with substrate and product structures, and the previous structure of the intermediate determined by kinetic isotope effects, reveals an exquisite example of geometric strain, least atomic motion, and electrophile migration in biological catalysis. This structure provides a rare opportunity to reconstruct the detailed structural transformations that occur along an enzymatic reaction coordinate.     

Sorbitol counteracts temperature- and chemical-induced denaturation of a recombinant α-amylase from alkaliphilic Bacillus sp. TS-23

Enzymes are highly complex systems with a substantial degree of structural variability in their folded state. In the presence of cosolvents, fluctuations among vast numbers of folded and unfolded conformations occur via many different pathways; alternatively, certain conformations can be stabilized or destabilized. To understand the contribution of osmolytes to the stabilization of structural changes and enzymatic activity of a truncated Bacillus sp. TS-23 α-amylase (BACΔNC), we monitored amylolytic activity, circular dichroism, and fluorescence as a function of osmolytes. In the presence of trimethylamine N-oxide (TMAO) and sorbitol, BACΔNC activity was retained significantly at elevated temperatures. As compared to the control, the secondary structures of this enzyme were essentially conserved upon the addition of these two kinds of osmolytes. Fluorescence results revealed that the temperature-induced conformational change of BACΔNC was prevented by TMAO and sorbitol. However, glycerol did not provide profound protection against thermal denaturation of the enzyme. Sorbitol was further found to counteract guanidine hydrochloride- and SDS-induced denaturation of BACΔNC. Thus, some well-known naturally occurring osmolytes make a dominant contribution to the stabilization of BACΔNC.     

Self-assembly of bacteriophage-associated hyaluronate lyase (HYLP2) into an enzymatically active fibrillar film

The in vitro assembly of a soluble protein into its mature fibrillar form is usually accompanied by loss of its functional activity. Our study is the first demonstration of a natural enzyme (HylP2) retaining its enzymatic activity on conversion from pre-fibril to mature fibril and supports the contention that minor conformational changes in the native folded form of a protein can lead to the formation of a functional fibril. Hyaluronate lyase (HylP2) is a natural enzyme of bacteriophage 10403 of Streptococcus pyogenes. At pH 5.0, the enzyme undergoes partial unfolding localized in its N-terminal domain while the C-terminal domain maintains its folded trimeric conformation. This structural variant of HylP2 retains about 70% enzymatic activity with hyaluronan. It further self-assembles into a fibrillar film in vitro through solvent-exposed nonpolar surfaces and intermolecular beta-sheet formation by the beta-strands in the protein. Interestingly, the mature fibrillar film of HylP2 also retains about 60 and 20% enzymatic activity for hyaluronic acid and chondroitin sulfate, respectively. The possession of broad substrate specificity by the fibrillar form of HylP2 indicates that fluctuations in pH, which do not lead to loss of functionality of HylP2, might assist in bacterial pathogenesis. The formation of fibrillar film-like structure has been observed for the first time among the hyaluronidase enzymes. After acquiring this film-like structure in bacteriophage, HylP2 still retains its enzymatic activity, which establishes that these fibrils are a genuinely acquired protein fold/structure.     

Real-time enzyme dynamics illustrated with fluorescence spectroscopy of p-hydroxybenzoate hydroxylase

We have used the flavoenzyme p-hydroxybenzoate hydroxylase (PHBH) to illustrate that a strongly fluorescent donor label can communicate with the flavin via single-pair F?rster resonance energy transfer (spFRET). The accessible Cys-116 of PHBH was labeled with two different fluorescent maleimides with full preservation of enzymatic activity. One of these labels shows overlap between its fluorescence spectrum and the absorption spectrum of the FAD prosthetic group in the oxidized state, while the other fluorescent probe does not have this spectral overlap. The spectral overlap strongly diminished when the flavin becomes reduced during catalysis. The donor fluorescence properties can then be used as a sensitive antenna for the flavin redox state. Time-resolved fluorescence experiments on ensembles of labeled PHBH molecules were carried out in the absence and presence of enzymatic turnover. Distinct changes in fluorescence decays of spFRET-active PHBH can be observed when the enzyme is performing catalysis using both substrates p-hydroxybenzoate and NADPH. Single-molecule fluorescence correlation spectroscopy on spFRET-active PHBH showed the presence of a relaxation process (relaxation time of 23 micros) that is related to catalysis. In addition, in both labeled PHBH preparations the number of enzyme molecules reversibly increased during enzymatic turnover indicating that the dimer-monomer equilibrium is affected.     

Folding and stability of different oligomeric states of thiamin diphosphate dependent homomeric pyruvate decarboxylase

The folding and stability of recombinant homomeric (alpha-only) pyruvate decarboxylase from yeast was investigated. Different oligomeric states (tetramers, dimers and monomers) of the enzyme occur under defined conditions. The enzymatic activity is used as a sensitive probe for structural differences between the active and inactive form (mis-assembled forms, aggregates) of the folded protein. Unfolding kinetics starting from the native protein comprise both the dissociation of the oligomers into monomers and their subsequent denaturation, which could be monitored by stopped-flow kinetics. In the course of unfolding, the tetramers do not directly dissociate into monomers, but via a stable dimeric state. Starting from the unfolded state, a reactivation of homomeric pyruvate decarboxylase requires both refolding to monomers and their correct association to enzymatically active dimers or tetramers. The reactivation yield under the in vitro conditions used follows an optimum behavior.     

Transition-state ensemble in enzyme catalysis: possibility, reality, or necessity?

Proteins are not rigid structures; they are dynamic entities, with numerous conformational isomers (substates). The dynamic nature of protein structures amplifies the structural variation of the transition state for chemical reactions performed by proteins. This suggests that utilizing a transition state ensemble to describe chemical reactions involving proteins may be a useful representation. Here we re-examine the nature of the transition state of protein chemical reactions (enzyme catalysis), considering both recent developments in chemical reaction theory (Marcus theory for SN2 reactions), and protein dynamics effects. The classical theory of chemical reactions relies on the assumption that a reaction must pass through an obligatory transition-state structure. The widely accepted view of enzymatic catalysis holds that there is tight binding of the substrate to the transition-state structure, lowering the activation energy. This picture, may, however, be oversimplified. The real meaning of a transition state is a surface, not a single saddle point on the potential energy surface. In a reaction with a "loose" transition-state structure, the entire transition-state region, rather than a single saddle point, contributes to reaction kinetics. Consequently, here we explore the validity of such a model, namely, the enzymatic modulation of the transition-state surface. We examine its utility in explaining enzyme catalysis. We analyse the possibility that instead of optimizing binding to a well-defined transition-state structure, enzymes are optimized by evolution to bind efficiently with a transition-state ensemble, with a broad range of activated conformations. For enzyme catalysis, the key issue is still transition state (ensemble) stabilization. The source of the catalytic power is the modulation of the transition state. However, our definition of the transition state is the entire transition-state surface rather just than a single well-defined structure. This view of the transition-state ensemble is consistent with the nature of the protein molecule, as embodied and depicted in the protein energy landscape of folding, and binding, funnels.     

Selective probing of a NADPH site controlled light‐induced enzymatic catalysis

Achieving molecular recognition of NADPH binding sites is a compelling strategy to control many redox biological processes. The NADPH sites recognize the ubiquitous NADPH cofactor via highly conserved binding interactions, despite differences in the regulation of the hydride transfer in redox active proteins. We recently developed a photoactive NADPH substitute, called nanotrigger NT synchronizing the initiation of enzymatic catalysis of the endothelial NO‐synthase (eNOS) with a laser pulse. Spatial and temporal control of enzymatic activity by such a designed light‐driven activator would benefit from achieving molecular selectivity, i.e. activation of a single NADPH‐mediated enzyme. In this work, we probe the ability of NT to discriminate between two NADPH sites with light. The selected NADPH sites belong to dihydrofolate reductase dihydrofolate reductase enzyme (DHFR) and endothelial NO‐synthase (eNOS). Ultrafast kinetics showed that NT could not activate DHFR catalysis with a laser pulse in contrast with the observed trigger of eNOS catalysis leading to NO formation. Homology modelling, molecular dynamics simulations showed that NT discriminated between the two NADPH sites by different donor to acceptor distances and by local steric effects hindering light activation of DHFR catalysis. The data suggested that the narrow NADPH site required a tight fit of the nanotrigger at a suitable distance/angle to the electron acceptor for a specific activation of the catalysis. The ability of the nanotrigger to activate eNOS combined with a low reactivity in unfavourable NADPH sites makes NT a highly promising tool for targeting eNOS in endothelial cells with a laser pulse. Copyright © 2009 John Wiley & Sons, Ltd.     

Dynamic theory of enzymatic catalysis]

Formal kinetics of an enzymatic reaction is considered in terms of a dynamic scheme of catalysis. Conformation reconstructions of a liberated enzyme and e-s-complex are analysed upon the phase plane. An expression for the enzyme stationary activity depending on the rate of conformation reconstructions is obtained. The case of purely dynamic catalysis is analysed and possible initiation of enzymatic activity variation in time connected with initial synchronization of molecules is shown. This phenomenon is considered as a possible criterion of the dynamic character of enzymatic catalysis.     

Production, purification, and characterization of a Mg2+-responsive porphobilinogen synthase from Pseudomonas aeruginosa.

During tetrapyrrole biosynthesis the metalloenzyme porphobilinogen synthase (PBGS) catalyzes the condensation of two molecules of 5-aminolevulinic acid to form the pyrrole porphobilinogen. Pseudomonas aeruginosa PBGS was synthesized in Escherichia coli, and the enzyme was purified as a fusion protein with glutathione S-transferase (GST). After removal of GST, a molecular mass of 280 000 +/- 10 000 with a Stokes radius of 57 A was determined for native PBGS, indicating a homooctameric structure of the enzyme. Mg2+ stabilized the oligomeric state but was not essential for octamer formation. Alteration of N-terminal amino acids changed the oligomeric state and reduced the activity of the enzyme, revealing the importance of this region for oligomerization and activity. EDTA treatment severely inhibited enzymatic activity which could be completely restored by the addition of Mg2+ or Mn2+. At concentrations in the micromolar range Co2+, Zn2+, and Ni2+ partially restored EDTA-inhibited enzymatic activity while higher concentrations of Zn2+ inhibited the enzyme. Pb2+, Cd2+, and Hg2+ did not restore activity. A stimulatory effect of monovalent ions was observed. A Km of 0.33 mM for ALA and a maximal specific activity of 60 micromol h-1 mg-1 at the pH optimum of 8.6 in the presence of Mg2+ and K+ were found. pH-dependent kinetic studies were combined with protein modifications to determine the structural basis of two observed pKa values of approximately 7.9 (pKa1) and 9.5 (pKa2). These are postulated respectively as ionization of an active site lysine residue and of free substrate during catalysis. Some PBGS inhibitors were characterized. Finally, we succeeded in obtaining well-ordered crystals of P. aeruginosa PBGS complexed with the substrate analogue levulinic acid.     

Structural proteomics: a tool for genome annotation

In any newly sequenced genome, 30% to 50% of genes encode proteins with unknown molecular or cellular function. Fortunately, structural genomics is emerging as a powerful approach of functional annotation. Because of recent developments in high-throughput technologies, ongoing structural genomics projects are generating new structures at an unprecedented rate. In the past year, structural studies have identified many new structural motifs involved in enzymatic catalysis or in binding ligands or other macromolecules (DNA, RNA, protein). The efficiency by which function is deduced from structure can be further improved by the integration of structure with bioinformatics and other experimental approaches, such as screening for enzymatic activity or ligand binding.     

Function of conserved residues of human glutathione synthetase: implications for the ATP-grasp enzymes

Glutathione synthetase is an enzyme that belongs to the glutathione synthetase ATP-binding domain-like superfamily. It catalyzes the second step in the biosynthesis of glutathione from gamma-glutamylcysteine and glycine in an ATP-dependent manner. Glutathione synthetase has been purified and sequenced from a variety of biological sources; still, its exact mechanism is not fully understood. A variety of structural alignment methods were applied and four highly conserved residues of human glutathione synthetase (Glu-144, Asn-146, Lys-305, and Lys-364) were identified in the binding site. The function of these was studied by experimental and computational site-directed mutagenesis. The three-dimensional coordinates for several human glutathione synthetase mutant enzymes were obtained using molecular mechanics and molecular dynamics simulation techniques, starting from the reported crystal structure of human glutathione synthetase. Consistent with circular dichroism spectroscopy, our results showed no major changes to overall enzyme structure upon residue mutation. However, semiempirical calculations revealed that ligand binding is affected by these mutations. The key interactions between conserved residues and ligands were detected and found to be essential for enzymatic activity. Particularly, the negatively charged Glu-144 residue plays a major role in catalysis.     

Autoprocessing of Helicobacter pylori gamma-glutamyltranspeptidase leads to the formation of a threonine-threonine catalytic dyad

Helicobacter pylorigamma-glutamyltranspeptidase (HpGT) is a glutathione-degrading enzyme that has been shown to be a virulence factor in infection. It is expressed as a 60-kDa inactive precursor that must undergo autocatalytic processing to generate a 40-kDa/20-kDa heterodimer with full gamma-glutamyl amide bond hydrolase activity. The new N terminus of the processed enzyme, Thr-380, is the catalytic nucleophile in both the autoprocessing and enzymatic reactions, indicating that HpGT is a member of the N-terminal nucleophile hydrolase superfamily. To further investigate activation as a result of autoprocessing, the structure of HpGT has been determined to a resolution of 1.9 A. The refined model contains two 40-kDa/20-kDa heterodimers in the asymmetric unit and has structural features comparable with other N-terminal nucleophile hydrolases. Autoprocessing of HpGT leads to a large conformational change, with the loop preceding the catalytic Thr-380 moving >35 A, thus relieving steric constraints that likely limit substrate binding. In addition, cleavage of the proenzyme results in the formation of a threonine-threonine dyad comprised of Thr-380 and a second conserved threonine residue, Thr-398. The hydroxyl group of Thr-398 is located equidistant from the alpha-amino group and hydroxyl side chain of Thr-380. Mutation of Thr-398 to an alanine results in an enzyme that is fully capable of autoprocessing but is devoid of enzymatic activity. Substrate docking studies in combination with homology modeling studies of the human homologue reveal additional mechanistic details of enzyme maturation and activation, substrate recognition, and catalysis.     

Hydrogen bonding and catalysis: a novel explanation for how a single amino acid substitution can change the pH optimum of a glycosidase

The pH optima of family 11 xylanases are well correlated with the nature of the residue adjacent to the acid/base catalyst. In xylanases that function optimally under acidic conditions, this residue is aspartic acid, whereas it is asparagine in those that function under more alkaline conditions. Previous studies of wild-type (WT) Bacillus circulans xylanase (BCX), with an asparagine residue at position 35, demonstrated that its pH-dependent activity follows the ionization states of the nucleophile Glu78 (pKa 4.6) and the acid/base catalyst Glu172 (pKa 6.7). As predicted from sequence comparisons, substitution of this asparagine residue with an aspartic acid residue (N35D BCX) shifts its pH optimum from 5.7 to 4.6, with an approximately 20% increase in activity. The bell-shaped pH-activity profile of this mutant enzyme follows apparent pKa values of 3.5 and 5.8. Based on 13C-NMR titrations, the predominant pKa values of its active-site carboxyl groups are 3.7 (Asp35), 5.7 (Glu78) and 8.4 (Glu172). Thus, in contrast to the WT enzyme, the pH-activity profile of N35D BCX appears to be set by Asp35 and Glu78. Mutational, kinetic, and structural studies of N35D BCX, both in its native and covalently modified 2-fluoro-xylobiosyl glycosyl-enzyme intermediate states, reveal that the xylanase still follows a double-displacement mechanism with Glu78 serving as the nucleophile. We therefore propose that Asp35 and Glu172 function together as the general acid/base catalyst, and that N35D BCX exhibits a "reverse protonation" mechanism in which it is catalytically active when Asp35, with the lower pKa, is protonated, while Glu78, with the higher pKa, is deprotonated. This implies that the mutant enzyme must have an inherent catalytic efficiency at least 100-fold higher than that of the parental WT, because only approximately 1% of its population is in the correct ionization state for catalysis at its pH optimum. The increased efficiency of N35D BCX, and by inference all "acidic" family 11 xylanases, is attributed to the formation of a short (2.7 A) hydrogen bond between Asp35 and Glu172, observed in the crystal structure of the glycosyl-enzyme intermediate of this enzyme, that will substantially stabilize the transition state for glycosyl transfer. Such a mechanism may be much more commonly employed than is generally realized, necessitating careful analysis of the pH-dependence of enzymatic catalysis.     

Mechanisms and structures of vitamin B(6)-dependent enzymes involved in deoxy sugar biosynthesis

PLP is well-regarded for its role as a coenzyme in a number of diverse enzymatic reactions. Transamination, deoxygenation, and aldol reactions mediated by PLP-dependent enzymes enliven and enrich deoxy sugar biosynthesis, endowing these compounds with unique structures and contributing to their roles as determinants of biological activity in many natural products. The importance of deoxy aminosugars in natural product biosynthesis has spurred several recent structural investigations of sugar aminotransferases. The structure of a PMP-dependent enzyme catalyzing the C-3 deoxygenation reaction in the biosynthesis of ascarylose was also determined. These studies, and the crystal structures they have provided, offer a wealth of new insights regarding the enzymology of PLP/PMP-dependent enzymes in deoxy sugar biosynthesis. In this review, we consider these recent achievements in the structural biology of deoxy sugar biosynthetic enzymes and the important implications they hold for understanding enzyme catalysis and natural product biosynthesis in general. This article is part of a Special Issue entitled: Pyridoxal Phosphate Enzymology.     

Expression and characterization of the biofilm-related and carnosine-hydrolyzing aminoacylhistidine dipeptidase from Vibrio alginolyticus

The biofilm-related and carnosine-hydrolyzing aminoacylhistidine dipeptidase (pepD) gene from Vibrio alginolyticus was cloned and sequenced. The recombinant PepD protein was produced and biochemically characterized and the putative active-site residues responsible for metal binding and catalysis were identified. The recombinant enzyme, which was identified as a homodimeric dipeptidase in solution, exhibited broad substrate specificity for Xaa-His and His-Xaa dipeptides, with the highest activity for the His-His dipeptide. Sequence and structural homologies suggest that the enzyme is a member of the metal-dependent metallopeptidase family. Indeed, the purified enzyme contains two zinc ions per monomer. Reconstitution of His.Tag-cleaved native apo-PepD with various metal ions indicated that enzymatic activity could be optimally restored when Zn2+ was replaced with other divalent metal ions, including Mn2+, Co2+, Ni2+, Cu2+ and Cd2+, and partially restored when Zn2+ was replaced with Mg2+. Structural homology modeling of PepD also revealed a 'catalytic domain' and a 'lid domain' similar to those of the Lactobacillus delbrueckii PepV protein. Mutational analysis of the putative active-site residues supported the involvement of His80, Asp119, Glu150, Asp173 and His461 in metal binding and Asp82 and Glu149 in catalysis. In addition, individual substitution of Glu149 and Glu150 with aspartic acid resulted in the partial retention of enzymatic activity, indicating a functional role for these residues on the catalysis and zinc ions, respectively. These effects may be necessary either for the activation of the catalytic water molecule or for the stabilization of the substrate-enzyme tetrahedral intermediate. Taken together, these results may facilitate the design of PepD inhibitors for application in antimicrobial treatment and antibody-directed enzyme prodrug therapy.