Probing the mechanism and improving the rate of substrate-assisted catalysis in subtilisin BPN'

A mutant of the serine protease, subtilisin BPN', in which the catalytic His64 is replaced by Ala (H64A), is very specific for substrates containing a histidine, presumably by the substrate-bound histidine assisting in catalysis [Carter, P., & Wells, J.A. (1987) Science (Washington, D.C.) 237, 394-399]. Here we probe the catalytic mechanism of H64A subtilisin for cleaving His and non-His substrates. We show that the ratio of aminolysis to hydrolysis is the same for ester and amide substrates as catalyzed by the H64A subtilisin. This is consistent with formation of a common acyl-enzyme intermediate for H64A subtilisin, analogous to the mechanism of the wild-type enzyme. However, the catalytic efficiencies (kcat/KM) for amidase and esterase activities with His-containing substrates are reduced by 5000-fold and 14-fold, respectively, relative to wild-type subtilisin BPN, suggesting that acylation is more compromised than deacylation in the H64A mutant. High concentrations of imidazole are much less effective than His substrates in promoting hydrolysis by the H64A variant, suggesting that the His residue on the bound (not free) substrate is involved in catalysis. The reduction in catalytic efficiency kcat/KM for hydrolysis of the amide substrate upon replacement of the oxyanion stabilizing asparagine (N155G) is only 7-fold greater for wild-type than H64A subtilisin. In contrast, the reductions in kcat/KM upon replacement of the catalytic serine (S221A) or aspartate (D32A) are about 3000-fold greater for wild-type than H64A subtilisin, suggesting that the functional interactions between the Asp32 and Ser221 with the substrate histidine are more compromised in substrate-assisted catalysis.(ABSTRACT TRUNCATED AT 250 WORDS)     

NMR studies of the hydrogen bonds involving the catalytic triad of Escherichia coli thioesterase/protease I

Escherichia coli thioesterase/protease I (TEP-I) is a lipolytic enzyme of the serine protease superfamily with Ser(10), Asp(154) and His(157) as the catalytic triad residues. Based on comparison of the low-field (1)H nuclear magnetic resonance spectra of two mutants (S10G and S12G) and two transition state analogue complexes we have assigned the exchangeable proton resonances at 16.3 ppm, 14.3 ppm, and 12.8 ppm at pH 3.5 to His(157)-N(delta1)H, Ser(10)-O(gamma)H and His(157)-N(epsilon2)H, respectively. Thus, the presence of a strong Asp(154)-His(157) hydrogen bond in free TEP-I was observed. However, Ser(10)-O(gamma)H was shown to form a H-bond with a residue other than His(157)-N(epsilon2).     

Investigating the role of histidine 157 in the catalytic activity of human cytomegalovirus protease

Herpesvirus proteases belong to a new class of serine proteases and contain a novel Ser-His-His catalytic triad, while classical serine proteases have an acidic residue as the third member. To gain a better understanding of the molecular basis for the functional role of the third-member His residue, we have carried out structural and biochemical investigations of human cytomegalovirus (HCMV) protease that bears mutations of the His157 third member. Kinetic studies showed that all the mutants have reduced catalytic activity. Structural studies revealed that a solvent molecule is hydrogen-bonded to the His63 second member and Ser134 in the H157A mutant, partly rescuing the activity of this mutant. This is confirmed by our kinetic and structural observations on the S134A/H157A double mutant, which showed further reductions in the catalytic activity. The structure of the H157A mutant is also in complex with the PMSF inhibitor. The H157E mutant has the best catalytic activity among the mutants; its structure, however, showed conformational readjustments of the His63 and Ser132 residues. The Ser132-His63 diad of HCMV protease has similar activity as the diads in classical serine proteases, whereas the contribution of the His157 third member to the catalysis is much smaller. Finally, structural comparisons revealed the presence of two conserved structural water molecules at the bottom of the S(1) pocket, suggesting a possible new direction for the design of HCMV protease inhibitors.     

Design of a serine protease-like catalytic triad on an antibody light chain displayed on the yeast cell surface

Lc-WT, the wild-type light chain of antibody, and Lc-Triad, its double mutant with E1D and T27aS designing for the construction of catalytic triad within Asp1, Ser27a, and original His93 residues, were displayed on the cell surface of the protease-deficient yeast strain BJ2168. When each cell suspension was reacted with BODIPY FL casein and seven kinds of peptide-MCA substrates, respectively, a remarkable difference in hydrolytic activities toward Suc-GPLGP-MCA (succinyl-Gly-Pro-Leu-Gly-Pro-MCA), a substrate toward collagenase-like peptidase, was observed between the constructs: Lc-Triad-displaying cells showed higher catalytic activity than Lc-WT-displaying cells. The difference disappeared in the presence of the serine protease inhibitor diisopropylfluorophosphate, suggesting that the three amino acid residues, Ser27a, His93, and Asp1, functioned as a catalytic triad responsible for the proteolytic activity in a similar way to the anti-vasoactive intestinal peptide (VIP) antibody light chain. A serine protease-like catalytic triad (Ser, His, and Asp) is considered to be directly involved in the catalytic mechanism of the anti-VIP antibody light chain, which moderately catalyzes the hydrolysis of VIP. These results suggest the possibility of new approach for the creation of tailor-made proteases beyond limitations of the traditional immunization approach.     

Identification of active-site amino acid residues in the Chiba virus 3C-like protease

The 3C-like protease of the Chiba virus, a Norwalk-like virus, is one of the chymotrypsin-like proteases. To identify active-site amino acid residues in this protease, 37 charged amino acid residues and a putative nucleophile, Cys139, within the GDCG sequence were individually replaced with Ala in the 3BC precursor, followed by expression in Escherichia coli, where the active 3C-like protease would cleave 3BC into 3B (VPg) and 3C (protease). Among 38 Ala mutants, 7 mutants (R8A, H30A, K88A, R89A, D138A, C139A, and H157A) completely or nearly completely lost the proteolytic activity. Cys139 was replaceable only with Ser, suggesting that an SH or OH group in the less bulky side chain was required for the side chain of the residue at position 139. His30, Arg89, and Asp138 could not be replaced with any other amino acids. Although Arg8 was also not replaceable for the 3B/3C cleavage and the 3C/3D cleavage, the N-terminal truncated mutant devoid of Arg8 significantly cleaved 3CD into 3C and 3D (polymerase), indicating that Arg8 itself was not directly involved in the proteolytic cleavage. As for position 88, a positively charged residue was required because the Arg mutant showed significant activity. As deduced by the X-ray structure of the hepatitis A virus 3C protease, Arg8, Lys88, and Arg89 are far away from the active site, and the side chain of Asp138 is directed away from the active site. Therefore, these are not catalytic residues. On the other hand, all of the mutants of His157 in the S1 specificity pocket tended to retain very slight activity, suggesting a decreased level of substrate recognition. These results, together with a sequence alignment with the picornavirus 3C proteases, indicate that His30 and Cys139 are active-site residues, forming a catalytic dyad without a carboxylate directly participating in the proteolysis.     

Saturation mutagenesis reveals that GLU54 of norovirus 3C-like protease is not essential for the proteolytic activity

The norovirus 3C-like protease is a member of the chymotrypsin-like serine protease superfamily. Previous characterization of its crystal structure has implicated the Glu54-His30-Cys139 triad in the catalysis. In the present study, the Glu54 residue of the protease was subjected to site-saturation mutagenesis, with the result that nearly half of the mutants retained the significant proteolytic activity. It was suggested that a carboxylate at position 54 was not essential for the activity. The in vitro assays of the proteolysis revealed that most of Glu54 mutants retained relatively high proteolytic activity. When the Glu54 mutation was combined with the Ser mutation of the Cys139 residue, a nucleophile, only the Asp54 and Gln54 mutations showed proteolytic activity comparable to that of the Ser139 single mutant, suggesting that a hydrogen bond between Glu54 and His30 was critical in the Ser139 background. These results suggested that the mechanism of the proteolysis by the wild-type norovirus 3C-like protease was different from that of typical chymotrypsin-like serine proteases.     

Substrate-dependent competency of the catalytic triad of prolyl oligopeptidase

Prolyl oligopeptidase, a serine peptidase unrelated to trypsin and subtilisin, is implicated in memory disorders and is an important target of drug design. The catalytic competence of the Asp(641) residue of the catalytic triad (Ser(554), Asp(641), His(680)) was studied using the D641N and D641A variants of the enzyme. Both variants displayed 3 orders of magnitude reduction in k(cat)/K(m) for benzyloxycarbonyl-Gly-Pro-2-naphthylamide. Using an octapeptide substrate, the decrease was 6 orders of magnitude, whereas with Z-Gly-Pro-4-nitrophenyl ester there was virtually no change in k(cat)/K(m). This indicates that the contribution of Asp(641) is very much dependent on the substrate-leaving group, which was not the case for the classic serine peptidase, trypsin. The rate constant for benzyloxycarbonyl-Gly-Pro-thiobenzylester conformed to this series as demonstrated by a method designed for monitoring the hydrolysis of thiolesters in the presence of thiol groups. Alkylation of His(680) with Z-Gly-Pro-CH(2)Cl was concluded with similar rate constants for wild-type and D641A variant. However, kinetic measurements with Z-Gly-Pro-OH, a product-like inhibitor, indicated that the His(680) is not accessible in the enzyme variants. Crystal structure determination of these mutants revealed subtle perturbations related to the catalytic activity. Many of these observations show differences in the catalysis between trypsin and prolyl oligopeptidase.     

Biochemical characterization of recombinant acetyl xylan esterase from Aspergillus awamori expressed in Pichia pastoris: mutational analysis of catalytic residues

We engineered an acetyl xylan esterase (AwaxeA) gene from Aspergillus awamori into a heterologous expression system in Pichia pastoris. Purified recombinant AwAXEA (rAwAXEA) displayed the greatest hydrolytic activity toward alpha-naphthylacetate (C2), lower activity toward alpha-naphthylpropionate (C3) and no detectable activity toward acyl-chain substrates containing four or more carbon atoms. Putative catalytic residues, Ser(119), Ser(146), Asp(168) and Asp(202), were substituted for alanine by site-directed mutagenesis. The biochemical properties and kinetic parameters of the four mutant enzymes were examined. The S119A and D202A mutant enzymes were catalytically inactive, whereas S146A and D168A mutants displayed significant hydrolytic activity. These observations indicate that Ser(119) and Asp(202) are important for catalysis. The S146A mutant enzyme showed lower specific activity toward the C2 substrate and higher thermal stability than wild-type enzyme. The lower activity of S146A was due to a combination of increased K(m) and decreased k(cat). The catalytic efficiency of S146A was 41% lower than that of wild-type enzyme. The synthesis of ethyl acetate was >10-fold than that of ethyl n-hexanoate synthesis for the wild-type, S146A and D168A mutant enzymes. However, the D202A showed greater synthetic activity of ethyl n-hexanoate as compared with the wild-type and other mutants.     

Role of serine 214 and tyrosine 171, components of the S2 subsite of alpha-lytic protease, in catalysis.

The function of a hydrogen bond network, comprised of the hydroxyl groups of Tyr 171 and Ser 214, in the hydrophobic S2 subsite of alpha-lytic protease, was investigated by mutagenesis and the kinetics of a substrate analog series. To study the catalytic role of the Tyr 171 and Ser 214 hydroxyl groups, Tyr 171 was converted to phenylalanine (Y171F) and Ser 214 to alanine (S214A). The double mutant (Y171F: S214A) also was generated. The single S214A and double Y171F:S214A mutations cause differential effects on catalysis and proenzyme processing. For S214A, kcat/Km is (4.9 x 10(3))-fold lower than that of wild type and proenzyme processing is blocked. For the double mutant (Y171F:S214A), kcat/Km is 82-fold lower than that of wild type and proenzyme processing occurs. In Y171F, kcat/Km is 34-fold lower than that of wild type, and the proenzyme is processed. The data indicate that Ser 214, although conserved among serine proteases and hydrogen bonded to the catalytic triad [Brayer, G. D., Delbaere, L. T. J., & James, M. N. G. (1979) J. Mol. Biol. 131, 743], is not essential for catalytic function in alpha-lytic protease. A substrate series (in which peptide length is varied) established that the mutations (Y171F and Y171F:S214A) do not alter enzyme-substrate interactions in subsites other than S2. The pH dependence of kcat/Km for Y171F and Y171F:S214A has changed less than 0.5 unit from that of wild type; this suggests the catalytic triad is unperturbed. In wild type, hydrophobic interactions at S2 increase kcat/Km by up to (1.2 x 10(3))-fold with no effect on Km.(ABSTRACT TRUNCATED AT 250 WORDS)     

Evaluation of the mechanism of aromatase cytochrome P450. A site-directed mutagenesis study.

Aromatase (CYP19) catalyzes three consecutive hydroxylation reactions converting C19 androgens to aromatic C18 estrogenic steroids. In this study, five human aromatase mutants (E302D, S478A, S478T, H480K, and H480Q) were prepared using a mammalian cell expression system. These mutants were evaluated by enzyme kinetic analysis, inhibitory profile studies, and reaction intermediate measurements. Three steroidal inhibitors [4-hydroxyandrostenedione (4-OHA), 7alpha-(4'-amino)phenylthio-1,4-androstandiene-3,17-dione (7alpha-APTADD), and bridge (2,19-methyleneoxy) androstene-3,17-dione (MDL 101003)], and four nonsteroidal inhibitors [aminoglutethimide (AG), CGS 20267, ICI D1033, and vorozole (R83842)] were used in the inhibitory profile studies. Our computer model of aromatase suggests that Glu302 is situated in the conserved I-helix region and located near the C-19 position of the steroid substrate. The model was supported by significant changes in kinetic parameters and a sevenfold increase in the Ki value of MDL 101,003 for the mutant E302D. As S478A was found to have kinetic properties similar to the wild-type enzyme and a much higher activity than S478T, Ser478 is thought to be situated in a rather restricted environment. There was a 10-fold increase in the Ki value of 7alpha-APTADD for S478T over that for the wild-type enzyme, suggesting that Ser478 might be near the C-7 position of the substrate. The reaction intermediate analysis revealed that significantly more 19-ol intermediate was generated by both S478A and S478T than the wild-type enzyme. These results would support a hypothesis that Ser478 plays a role in the first and second hydroxylation reactions. A positive charged amino acid is preferred at position 480 as shown by the fact that H480K has a significantly higher activity than H480Q. The Ki value of 4-OHA for H480Q was found to be three times that of the wild-type enzyme. In addition, significantly more 19-ol and 19-al intermediates were detected for both mutants H480K and H480Q than for the wild-type enzyme. Evaluation of the two mutations at His480 allows us to propose that this residue may participate in the aromatization reaction (the third step) by acting as a hydrogen bond donor for the C-3 keto group of the substrate. Furthermore, new products were generated when the enzyme was mutated at Ser478 and His480. Thus, these two residues must play an important role in the catalysis and are likely closer to the substrate binding site than previously predicted.     

Processing, catalytic activity and crystal structures of kumamolisin-As with an engineered active site

Kumamolisin-As is an acid collagenase with a subtilisin-like fold. Its active site contains a unique catalytic triad, Ser278-Glu78-Asp82, and a putative transition-state stabilizing residue, Asp164. In this study, the mutants D164N and E78H/D164N were engineered in order to replace parts of the catalytic machinery of kumamolisin-As with the residues found in the equivalent positions in subtilisin. Unlike the wild-type and D164N proenzymes, which undergo instantaneous processing to produce their 37-kDa mature forms, the expressed E78H/D164N proenzyme exists as an equilibrated mixture of the nicked and intact forms of the precursor. X-ray crystallographic structures of the mature forms of the two mutants showed that, in each of them, the catalytic Ser278 makes direct hydrogen bonds with the side chain of Asn164. In addition, His78 of the double mutant is distant from Ser278 and Asp82, and the catalytic triad no longer exists. Consistent with these structural alterations around the active site, these mutants showed only low catalytic activity (relative k(cat) at pH 4.0 1.3% for D164N and 0.0001% for E78H/D164N). pH-dependent kinetic studies showed that the single D164N substitution did not significantly alter the logk(cat) vs. pH and log(k(cat)/Km) vs. pH profiles of the enzyme. In contrast, the double mutation resulted in a dramatic switch of the logk(cat) vs. pH profile to one that was consistent with catalysis by means of the Ser278-His78 dyad and Asn164, which may also account for the observed ligation/cleavage equilibrium of the precursor of E78H/D164N. These results corroborate the mechanistic importance of the glutamate-mediated catalytic triad and oxyanion-stabilizing aspartic acid residue for low-pH peptidase activity of the enzyme.     

Structure and function of poly(3-hydroxybutyrate) depolymerase from Alcaligenes faecalis T1.

Poly(3-hydroxybutyrate) (PHB) depolymerase from Alcaligenes faecalis T1 is composed of three domains: the catalytic (C) domain, the fibronectin type III-like (F) domain, and the substrate-binding (S) domain. We constructed domain deletion, inversion, chimera, and extra-F-domain mutants and examined their enzyme activity and PHB-binding ability. In addition, we performed substitution of 214Asp and 273His with glycine and aspartate, respectively, to examine their participation in a catalytic triad together with 139Ser. The mutant with both the F and S domains deleted and the trypsin-digested enzyme showed no PHB-hydrolyzing activity and less PHB-binding ability than that of the wild-type enzyme but retained D-(-)-3-hydroxybutyrate trimer-hydrolyzing activity at a level similar to that of the wild-type enzyme. The mutant with the F domain deleted and the mutant which had the order of the F and S domains inverted retained PHB-binding ability and trimer-hydrolyzing activity at levels similar to those of the wild-type enzyme but lost PHB-hydrolyzing activity. The chimera mutant, in which the F domain was substituted with a Thr-rich domain of PHB depolymerase A from Pseudomonas lemoignei, and the extra-F-domain mutant, with an additional F domain, retained trimer- and PHB-hydrolyzing activities and PHB-binding ability at levels similar to those of the wild-type enzyme. Two mutants (D214G and H273D) showed no enzymatic activity toward trimer and PHB, and they were not labeled with [3H]diisopropylfluorophosphate.     

Catalytic mechanism of C-C hydrolase MhpC from Escherichia coli: kinetic analysis of His263 and Ser110 site-directed mutants

C-C hydrolase MhpC (2-hydroxy-6-keto-nona-1,9-dioic acid 5,6-hydrolase) from Escherichia coli catalyses the hydrolytic C-C cleavage of the meta-ring fission product on the phenylpropionic acid catabolic pathway. The crystal structure of E. coli MhpC has revealed a number of active-site amino acid residues that may participate in catalysis. Site-directed mutants of His263, Ser110, His114, and Ser40 have been analysed using steady-state and stopped-flow kinetics. Mutants H263A, S110A and S110G show 10(4)-fold reduced catalytic efficiency, but still retain catalytic activity for C-C cleavage. Two distinct steps are observed by stopped-flow UV/Vis spectrophotometry, corresponding to ketonisation and C-C cleavage: H263A exhibits very slow ketonisation and C-C cleavage, whereas S110A and S110G exhibit fast ketonisation, an intermediate phase, and slow C-C cleavage. H114A shows only twofold-reduced catalytic efficiency, ruling out a catalytic role, but shows a fivefold-reduced K(M) for the natural substrate, and an ability to process an aryl-containing substrate, implying a role for His114 in positioning of the substrate. S40A shows only twofold-reduced catalytic efficiency, but shows a very fast (500 s(-1)) interconversion of dienol (317 nm) to dienolate (394 nm) forms of the substrate, indicating that the enzyme accepts the dienol form of the substrate. These data imply that His263 is responsible for both ketonisation of the substrate and for deprotonation of water for C-C cleavage, a novel catalytic role in a serine hydrolase. Ser110 has an important but non-essential role in catalysis, which appears not to be to act as a nucleophile. A catalytic mechanism is proposed involving stabilisation of reactive intermediates and activation of a nucleophilic water molecule by Ser110.     

Mass spectrometric analysis of the reactions catalyzed by -2-haloacid dehalogenase mutants and implications for the roles of the catalytic amino acid residues

-2-Haloacid dehalogenase catalyzes the hydrolytic dehalogenation of -2-haloalkanoic acids to produce the corresponding -2-hydroxyalkanoic acids. Asp10 of -2-haloacid dehalogenase from Pseudomonas sp. YL nucleophilically attacks the α-carbon atom of the substrate to form an ester intermediate, which is subsequently hydrolyzed by an activated water molecule. We previously showed that the replacement of Thr14, Arg41, Ser118, Lys151, Tyr157, Ser175, Asn177, and Asp180 causes significant loss in the enzyme activity, indicating the involvement of these residues in catalysis. In the present study, we tried to determine which process these residues are involved in by monitoring the formation of the ester intermediate by measuring the molecular masses of the mutant enzymes using ionspray mass spectrometry. When the wild-type enzyme and the T14A, S118D, K151R, Y157F, S175A, and N177D mutant enzymes were mixed with the substrate, the ester intermediate was immediately produced. In contrast, the R41K, D180N, and D180A mutants formed the intermediate much more slowly than the wild-type enzyme, indicating that Arg41 and Asp180 participate in the formation of the ester intermediate. This study presents a new method to analyze the roles of amino acid residues in catalysis.     

Dynamic properties of the first enzymatic reaction steps of porcine pancreatic elastase. How rigid is the active site of the native enzyme? Molecular dynamics simulation

Two molecular dynamics simulations (100 and 50 ps) of native porcine pancreatic elastase i.e., without bound substrate and with the active site hydrated by a dome of water (630 molecules) have been performed. Dynamical properties of the catalytic tetrad have been examined. While relative conformations of the Asp 102, His 57, and Ser 214 are rather stable in time, the side chain of Ser 195 undergoes several conformational changes. No preferences are observed for the formation of a hydrogen bond between the O gamma-H group (Ser 195) and nitrogen N, (His 57). A cluster of ordered water molecules effectively competes with the H-O gamma group (Ser 195) and thereby prevents the formation of this H bond, which is generally agreed to be crucial for catalysis.     

Identification of active site serine and histidine residues in Escherichia coli outer membrane protease OmpT

Escherichia coli outer membrane protease OmpT has been characterised as a serine protease based on its inhibitor profile, but serine protease consensus sequences are absent. By site-directed mutagenesis we substituted all conserved serines and histidines. Substitution of His(101) and His(212) by Ala, Asn or Gln resulted in variant enzymes with 0.01 and 9-20% residual enzymatic activity towards a fluorogenic pentapeptide substrate, respectively. The mutations S140A and S201A did not decrease activity, while variants S40A and S99A yielded 0.5 and 0.2% residual activities, respectively. When measured with a dipeptide substrate the variant S40A demonstrated full activity, whereas variant S99A displayed at least 500-fold reduced activity. We conclude that Ser(99) and His(212) are essential active site residues. We propose that OmpT is a novel serine protease with Ser(99) as the active site nucleophile and His(212) as general base.     

Crystal structures of two engineered thiol trypsins

We have determined the three-dimensional structures of engineered rat trypsins which mimic the active sites of two classes of cysteine proteases. The catalytic serine was replaced with cysteine (S195C) to test the ability of sulfur to function as a nucleophile in a serine protease environment. This variant mimics the cysteine trypsin class of thiol proteases. An additional mutation of the active site aspartate to an asparagine (D102N) created the catalytic triad of the papain-type cysteine proteases. Rat trypsins S195C and D102N,S195C were solved to 2.5 and 2.0 A, respectively. The refined structures were analyzed to determine the structural basis for the 10(6)-fold loss of activity of trypsin S195C and the 10(8)-fold loss of activity of trypsin D102N,S195C, relative to rat trypsin. The active site thiols were found in a reduced state in contrast to the oxidized thiols found in previous thiol protease structures. These are the first reported structures of serine proteases with the catalytic centers of sulfhydryl proteases. Structure analysis revealed only subtle global changes in enzyme conformation. The substrate binding pocket is unaltered, and active site amino acid 102 forms hydrogen bonds to H57 and S214 as well as to the backbone amides of A56 and H57. In trypsin S195C, D102 is a hydrogen-bond acceptor for H57 which allows the other imidazole nitrogen to function as a base during catalysis. In trypsin D102N,S195C, the asparagine at position 102 is a hydrogen-bond donor to H57 which places a proton on the imidazole nitrogen proximal to the nucleophile. This tautomer of H57 is unable to act as a base in catalysis.(ABSTRACT TRUNCATED AT 250 WORDS)     

Important roles of hydroxylic amino acid residues in the function of Bacillus subtilis adenylosuccinate lyase

Thr(93), Ser(94), Thr(140), and Ser(306) are conserved in all adenylosuccinate lyases (ASL) and are close to other amino acids previously identified by mutagenesis as being in the active site. To test their involvement in the enzyme's function, each of these amino acids was replaced by alanine. All the mutants exhibit circular dichroism spectra which are similar to that of wild-type enzyme, indicating there is no appreciable change in secondary structure. T93A exhibits 0.5% of the V(max) of wild-type ASL with a 10-fold increase in K(m) for adenylosuccinate. S94A has 65% of the V(max) of wild-type ASL with little change in K(m). T140A exhibits 0.03% of the activity of wild-type enzyme with an 11-fold increase in K(m). S306A has 0.4% of the V(max) of wild-type ASL with a sevenfold increase in K(m). Measurements of the pH-V(max) profile reveal a pK(2) value for S94A of 7.83 and S306A of 7.65, in contrast to 8.24 for the wild-type enzyme and 8.42 for T93A. Thr(93) may orient adenylosuccinate optimally for catalysis, while Ser(94) stabilizes protonated His(89), a determinant of pK(2). Thr(140) may, through hydrogen bonding, interact with Asn(270), an amino acid essential for catalysis. Ser(306) may be involved in a hydrogen bond network that ultimately stabilizes protonated His(68), which is probably the general acid in the reaction of enzyme with substrate. The results of this paper demonstrate the importance in the catalytic function of ASL of hydrogen bonds and hydrogen bonding networks involving serine and threonine.     

Differential mechanisms of recognition and activation of interleukin-8 receptor subtypes

We have probed an epitope sequence (His18-Pro19-Lys20-Phe21) in interleukin-8 (IL-8) by site-directed mutagenesis. This work shows that single and double Ala substitutions of His18 and Phe21 in IL-8 reduced up to 77-fold the binding affinity to IL-8 receptor subtypes A (CXCR1) and B (CXCR2) and to the Duffy antigen. These Ala mutants triggered neutrophil degranulation and induced calcium responses mediated by CXCR1 and CXCR2. Single Asp or Ser substitutions, H18D, F21D, F21S, and double substitutions, H18A/F21D, H18A/F21S, and H18D/F21D, reduced up to 431-fold the binding affinity to CXCR1, CXCR2, and the Duffy antigen. Interestingly, double mutants with charged residue substitutions failed to trigger degranulation or to induce wild-type calcium responses mediated by CXCR1. Except for the H18A and F21A mutants, all other IL-8 mutants failed to induce superoxide production in neutrophils. This study demonstrates that IL-8 recognizes and activates CXCR1, CXCR2, and the Duffy antigen by distinct mechanisms.     

Identification and evaluation as a DNA vaccine candidate of a virulence-associated serine protease from a pathogenic Vibrio parahaemolyticus isolate

A putative serine protease gene was cloned from the genomic DNA of Vibrio parahaemolyticus FYZ8621.4. The gene consisted of 1779 base pairs and encoded a 592 amino acid protein. The gene was expressed in Escherichia coli. The expressed protease was purified by Ni-NTA His-Bind Resin column and showed a 63 kDa band on SDS-PAGE. The protease exhibited proteolytic activity on gelatin agar plate and showed maximal proteolytic activity at pH 8.0 and 37 °C. It hydrolyzed N-α-benzoyl-L-tyrosine p-nitroanilide (BAPNA), but did not N-benzoyl-L-arginine ethylester (BAEE), N-benzoyl-L-tyrosine ethylester (BTEE) and N-acetyl-L-tyrosine ethylester (ATEE). Mutants at conserved residues Asp(51) (Asp(51)-Asn), His(89) (His(89)-Asp) and Ser(318) (Ser(318)-Leu, Ser(318)-Pro) lost proteolytic activities completely. The protein was confirmed to belong to serine protease. The purified serine protease was toxic to zebrafish with a LD(50) of 15.4 μg/fish. A DNA vaccine was constructed by inserting the mutated serine protease (Ser(318)-Pro) gene into pEGFP-N1 plasmid. The pEGFP-N1/m-vps was transfected in HeLa cells. The serine protease was confirmed to be expressed by fluorescence microscopy observation and Western blotting analysis. The pEGFP-N1/m-vps was further observed to express in muscle of the injected turbot (Scophthalmus maximus) by Western blotting seven days after immunization. Efficient protection against lethal V. parahaemolyticus challenge was observed on the vaccinated turbot with pEGFP-N1/m-vps, with the highest relative percent survival (RPS) of 96.11%. Significant specific antibody responses were also observed in the turbot vaccinated with the DNA vaccine. The results indicated that the serine protease might be a potential virulence factor and could be used as an efficient vaccine candidate for the disease control caused by V. parahaemolyticus.