Effect of Glu-143 and His-231 substitutions on the catalytic activity and secretion of Bacillus subtilis neutral protease

On the basis of the homology with the Bacillus thermoproteolyticuszinc endopeptidase thermotysin, we hypothesized that Glu-143and His-231 are the key residues for the catalytic activityof the Bacillus subtilis neutral protease. To test this possibilityby site-directed mutagenesis, we substituted these two residueswith Ala, Ser, Trp and Arg, and Leu, Val and Cys respectively.All these substitutions dramatically affected the amount ofsecreted mutant proteins, as determined by immunological methods,and their catalytic activities. No appreciable secretion wasobserved with the three Glu mutants Trp, Ser and Arg, whereasthe Glu–Ala mutant enzyme was secreted at a level of afew hundred micrograms per litre of culture. The His mutantswere all secreted at higher levels (in the order of a few milligramsper litre) and their residual catalytic activity could be determinedusing Z-Ala-Leu-Ala as substrate. Our results confirm the keyrole played by Glu-143 and His-231 in catalysis and moreoversuggest the existence of a relationship between the catalyticactivity of the enzyme and the extent of its secretion. In thiscontext, we present data suggesting an autoproteolytic mechanismof cleavage of the precursor form of the enzyme, analogous tothe one previously reported for the B.subtilis subtilisin.     

Functional roles and subsite locations of Leu177, Trp178 and Asn182 of Aspergillus awamori glucoamylase determined by site-directed mutagenesis

Fungal glucoamylases contain four conserved regions. One regionfrom the Aspergillus niger enzyme contains three key carboxylicacid residues, the general acid catalytic group, Glu179, alongwith Asp176 and Glu180. Three site-directed mutations, Leu177– His, Trp178 – Arg and Asn182 – Ala, wereconstructed near these acidic groups to reveal the functionof other conserved residues in this region. Leu177 and Trp178are strictly conserved among fungal glucoamylases, while anamide, predominantly Asn, always occurs at position 182. Substitutionsof Leu177 or Trp178 cause significant decreases in k_cat withthe substrates tested. Similar increases in activation energiesobtained with Leu177 – His with both -(1,4)- and -(1,6)-linkedsubstrates indicate Leu177 is located in subsite 1. K_M valuesobtained with the Trp178 – Arg mutation increase for an-(1,6)-linked substrate, but not for -(1,4)-linked substrates.Calculated differences in activation energy between substratesindicate Trp178 interacts specifically with subsite 2. The Asn182 Ala mutation did not change k_cat or K_M values, indicating thatAsn182 is not crucial for activity. These results support amechanism for glucoamylase catalytic activity consisting ofa fast substrate binding step followed by a conformational changeat subsite 1 to stabilize the transition state complex.     

EcoRV-T94V: a mutant restriction endonuclease with an altered substrate specificity towards modified oligodexynucleotides

Synthetic oligodeoxynucleotides with single methyl phosphonate(mp) substitutions were used for an analysis of the contributionof phosphate contacts to the recognition of the cleavage siteby the restriction endonuclease EcoRV. Only in the last positionwithin the recognition sequence, is the methyl phosphonate substitutiontolerated by the enzyme. The wild-type enzyme cleaves the S_Pdiastereomer of the oligodeoxynucleotide GACGATAT_mpCGTC andthe unmodified sequence with equal rates, whereas the R_P diastereomeris cleaved much more slowly. Inspection of the crystal structureof an EcoRV–DNA complex revealed that the non-bridgingoxygen atoms of the phosphodiester bond between the T and Cbases are in hydrogen bonding distance of the hydroxyl groupof the amino acid Thr94. We therefore tried to engineer a variantof EcoRV that would prefer a methyl phosphonate linkage overa normal phosphodiester bond and produced mutants with aminoacid exchanges at position 94. One of them, Thr94Val, showsa dramatically reduced activity towards the unmodified DNA anddoes not accept the R_p diastereomer, but cleaves the S_P diastereomerwith the same rate as wild-type EcoRV. Its selectivity, i.e.the ratio of cleavage rates determined for the unmodified andmodified substrates, differs by three orders of magnitude fromthat of the wild-type enzyme.     

FK506-binding protein mutational analysis: defining the active-site residue contributions to catalysis and the stability of ligand complexes

The 12 kDa FK506-binding protein FKBP12 is a cis-trans peptidyl-prolylisomerase that binds the macrolides FK506 and rapamycin. Wehave examined the role of the binding pocket residues of FKBP12in protein–ligand interactions by making conservativesubstitutions of 12 of these residues by site-directed mutagenesis.For each mutant FKBP12, we measured the affinity for FK506 andrapamycin and the catalytic efficiency in the cis–transpeptidyl-prolyl isomerase reaction. The mutation of Trp59 orPhe99 generates an FKBP12 with a significantly lower affinityfor FK506 than wild-type protein. Tyr26 and Tyr82 mutants areenzymatically active, demonstrating that hydrogen bonding bythese residues is not required for catalysis of the cis–transpeptidyl-prolyl isomerase reaction, although these mutationsalter the substrate specificity of the enzyme. We conclude thathydrophobic interactions in the active site dominate in thestabilization of FKBP12 binding to macrolide ligands and tothe twisted-amide peptidyl-prolyl substrate intermediate.     

Effect of Lys->Arg mutation on the thermal stability of Cu,Zn superoxide dismutase: influence on the monomer-dimer equilibrium

The thermal stability of two single (K3R, K67R) and one double(K3R-K67R) mutants of Xenopus laevis B Cu,Zn superoxide dismutasehas been studied to test LysArg substitution as an ‘electrostaticallyconservative’ strategy to increase protein stability.The K3R mutant displays an increased thermostability with respectto the wild-type enzyme, whilst a decreased stability was observedin the case of the K67R and K3R-K67R mutants. Concentrationdependence of the apparent inactivation constant (k_app) of thelatter mutants, as compared to that of the wild type enzymeand K3R mutant, indicates that their higher sensitivity to heatinactivation is due to a perturbation of the dimer association.These results are confirmed also by fluorescence anisotropymeasurements of the internal probe Tyr149. The possible roleof Arg67 in perturbing the dimer dissociation equilibrium towardthe monomeric form is discussed.     

Protein engineering of the high-alkaline serine protease PB92 from Bacillus alcalophilus: functional and structural consequences of mutation at the S4 substrate binding pocket

Serine endoproteases such as trypsins and subtilisins are knownto have an extended substrate binding region that interactswith residues P6 to P3' of a substrate. In order to investigatethe structural and functional effects of replacing residuesat the S4 substrate binding pocket, the serine protease fromthe alkalophilic Bacillus strain PB92, which shows homologywith the subtilisins, was mutated at positions 102 and 126–128.Substitution of Val102 by Trp results in a 12–fold increasein activity towards succinyl-L-Ala-L-Ala-L-Pro-L-Phe-p-nitroanilide(sAAPFpNA). An X-ray structure analysis of the V102W mutantshows that the Trp side chain occupies a hydrophobic pocketat the surface of the molecule leaving a narrow crevice forthe P4 residue of a substrate. Better binding of sAAPFpNA bythe mutant compared with the wild type protein as indicatedby the kinetic data might be due to the hydrophobic interactionof Ala P4 of the substrate with the introduced Trp102 side chain.The observed difference in binding of sAAPFpNA by protease PB92and thermitase, both of which possess a Trp at position 102,is probably related to the amino acid substitutions at positions105 and 126 (in the protease PB92 numbering).Kinetic data forthe variants obtained by random mutation of residues Serl26,Prol27 and Serl28 reveal that the activity towards sAAPFpNAincreases when a hydrophobic residue is introduced at position126. An X-ray diffraction analysis was carried out for the threeprotease PB92 mutants which have residues Serl26-Prol27-Serl28replaced by Met-Ala-Gly(‘MAG’ mutant), Phe-Gln-Ser(‘FQS’ mutant) and Asn-Ser-Ala (‘NSA’mutant). Met 126 and Phel26 in the crystal structures of thecorresponding mutants are fixed in the same hydrophobic environmentas Trp102 in the V102W mutant.In contrast, Asnl26 in the ‘NSA’mutant is completely disordered in both crystal forms for whichthe structure has been determined. According to our kineticmeasurements none of the mutants with Met, Phe, Leu or Val atposition 126 binds sAAPFpNA better than the wild type enzyme.Resultsof the site-directed mutagenesis at position 127 imply thatpossible interaction of this residue with a substrate has almostno effect on activity towards sAAPFpNA and casein.     

Influence of size and polarity of residue 31 in porcine pancreatic phospholipase A2 on catalytic properties

Residue 31 of porcine pancreatic phospholipase A₂ (PLA₂) islocated at the entrance to the active site. To study the roleof residue 31 in PLA₂, six mutant enzymes were produced by site-directedmutagenesis, replacing Leu by either Trp, Arg, Ala, Thr, Seror Gly. Direct binding studies indicated a three to six timesgreater affinity of the Trp31 PLA₂ for both monomeric and micellarsubstrate analogs, relative to the wild-type enzyme. The otherfive mutants possess an unchanged affinity for monomers of theproduct analog n-decylphosphocholine and for micelles of thediacyl substrate analog rac-l,2-dioctanoylamino-dideoxy-glycero-3-phosphocholine.The affinities for micelles of the monoacyl product analog n-hexadecylphosphocholinewere decreased 9–20 times for these five mutants. Kineticstudies with monomeric substrates showed that the mutants haveV_max values which range between 15 and 70% relative to the wild-typeenzyme. The V_max values for micelles of the zwitterionic substratel,2-dioctanoyl-sn-glycero-3-phosphocholine were lowered 3–50times. The K_m values for the monomeric substrate and the k_mvalues for the micellar substrate were hardly affected in thecase of five of the six mutants, but were considerably decreasedwhen Trp was present at position 31. The results of these investigationspoint to a versatile role for the residue at position 31: involvementin the binding and orientating of monomeric substrate (analogs),involvement in the binding of the enzyme to micellar substrateanalogs and possibly involvement in shielding the active sitefrom excess water.     

The {alpha}/{beta} hydrolase fold

We have identified a new protein fold—the /ßhydrolase fold—that is common to several hydrolytic enzymesof widely differing phylogenetic origin and catalytic function.The core of each enzyme is similar: an /ß sheet, notbarrel, of eight ß-sheets connected by -helices. Theseenzymes have diverged from a common ancestor so as to preservethe arrangement of the catalytic residues, not the binding site.They all have a catalytic triad, the elements of which are borneon loops which are the best-conserved structural features inthe fold. Only the histidine in the nucleophile-histidine-acidcatalytic triad is completely conserved, with the nucleophileand acid loops accommodating more than one type of amino acid.The unique topological and sequence arrangement of the triadresidues produces a catalytic triad which is, in a sense, amirror-image of the serine protease catalytic triad. There arenow four groups of enzymes which contain catalytic triads andwhich are related by convergent evolution towards a stable,useful active site: the eukaryotic serine proteases, the cysteineproteases, subtilisins and the /ß hydrolase fold enzymes.     

Comparative stability of dihydrofolate reductase mutants in vitro and in vivo

Dihydrofolate reductase mutants with amino acid replacementsin the active center (Thr35 Asp mutant, Arg57 His mutant andthe mutant with triple replacement Thr35 Asp, Asn37 Ser, Arg57 His) were obtained by site-directed mutagenesis. The stabilizationeffect of trimethoprim and NADP·H on the protein tertiarystructure in vitro has been investigated. In the case of mutantswith a ‘weak’ tertiary structure (Thr35 Asp35 andthe triple mutant) the separate addition of ligands does notaffect their stability. The simultaneous addition of these ligandsto Thr35 Asp35 and the triple mutant leads to the large increasein their stability. A distinct correlation was found betweenthe in vitro studied stability of the mutant proteins to theurea- or heat-induced denaturation and the level of proteolyticdegradation of these mutants previously observed in vivo.     

Structure-function relationships in the catalytic and starch binding domains of glucoamylase

Sixteen primary sequences from five sub-families of fungal,yeast and bacterial glucoamylases were related to structuralinformation from the model of the catalytic domain of Aspergillusawamori var. X100 glucoamylase obtained by protein crystallography.This domain is composed of thirteen -belices, with five conservedregions defining the active site. Interactions between methyl-maltoside and active site residues were modelled, and the importanceof these residues on the catalytic action of different glucoamylaseswas shown by their presence in each primary sequence. The overallstructure of the starch binding domain of some fungal glucoamylaseswas determined based on homology to the Cterminal domains ofBacillus cyclodextrin glucosyltransferases. Crystallographyindicated that this domain contains 6–8 ß-strandsand homology allowed the attribution of a disulfide bridge inthe glucoamylase starch binding domain. Glucoamylase residuesThr525, Asn530 and Trp560, homologous to Bacillus stearothermophiluscyclodextrin glucosyltransferase residues binding to maltosein the Cterminal domain, could be involved in raw-starch binding.The structure and length of the linker region between the catalyticand starch binding domains in fungal glucoamylases can varysubstantially, a further indication of the functional independenceof the two domains.     

Improved peptide function from random mutagenesis over short 'windows'

We have applied random mutagenesis over short contiguous residuetracts (‘windows’) within an active peptide (the-peptide of ß-galactosidase) such that all windowresidues are replaced simultaneously. A novel technique usingmixed synthetic oligonucleotides and selection against an EcoKrestrictionsite has allowed the construction of libraries of mutants fortwo separate windows, sites A and B. Mutant phenotypes can beeasily assessed in vivoby a complementation test, and panelsof mutants have been quantitatively tested in vivoThis allowedthe rapid probing of structural requirements for each site.The two windows yielded markedly disparate results. Site B wasmuch less stringent in its sequence requirements for significantfunction than Site A, and mutants with improved function wereisolated at Site B alone. In addition, one Site B mutant withwild-type levels of activity showed enhanced stability to heator a protein denaturant. We propose that short tracts with thecharacteristics of Site B constitute ‘secondary’interaction sites which are more tolerant of sequence diversity.Random manipulation of such secondary sites is thus more likelyto yield up-mutations for standard or altered environments.Window mutagenesis can in principle be applied to any protein-proteinor protein-Ugand interaction.     

High-level expression, purification, kinetic characterization and crystallization of protein farnesyltransferase -subunit C-terminal mutants

Protein farnesyltransferase (FPT) is a 97 000 Da heterodimericenzyme that catalyzes post-translational farnesylation of manycellular regulatory proteins including p21 Ras. To facilitatethe construction of site-directed mutants, a novel translationallycoupled, two-cistron Escherichia coli expression system forrat FPT has been developed. This expression system enabled yieldsof >5 mg of purified protein per liter of E.coli cultureto be obtained. The E.coli-derived FPT demonstrated an activitycomparable to that of protein isolated from other sources. Thereported expression system was used to construct three ß-subunitC-terminal truncation mutants, 5, 10 and 14, which were designedto eliminate a lattice interaction between the ß-subunitC-terminus of one molecule and the active site of a symmetry-relatedmolecule. Steady-state kinetic analyses of these mutants showedthat deletion up to 14 residues at the C-terminus did not reducethe value of k_cat; however, K_m values for both peptide and FPPincreased 2–3-fold. A new crystalline form of FPT was obtainedfor the 10 C-terminal mutant grown in the presence of the substrateanalogs acetyl-Cys-Val-Ile-Met-COOH peptide and -hydroxyfarnesylphosphonicacid. The crystals diffract to beyond 2.0 Å resolution.The refined structure clearly shows that both substrate analogsadopt extended conformations within the FPT active site cavity.     

Bipartite organization of the Bacillus subtilis endo-{beta}-1,4-glucanase revealed by C-terminal mutations

The C-terminal boundary of primary sequence of the Bacillussubtilis PAP115 endo-ß-1,4-glucanase (EG) requiredfor stable catalytic activity has been mapped by site-directedmutagenesis using Escherichia coli as host. The 52 kDa cel geneproduct, EG₄₇₀ and a 33 kDa mutant (EG₃₀₀), lacking 170 residuesthrough a nonsense mutation at the leucine-330 codon of thegene, exhibited similar patterns of enzymatic activity and pHoptima using cellooligopentaose as substrate.CD spectra indicatedthat the bulk of the -helical secondary structure in EG₄₇₀ wascontained within EG₃₀₀. However, relative to EG₄₇₀, the specificactivity of EG₃₀₀ was 3- to 4-fold lower with amorphous celluloseas substrate and {small tilde}4-to5-fold higher with carboxymethylcellulose(soluble cellulose).These results along with data which showthat EG₄₇₀ binding capacity to mirocrystalline cellulose is{small tilde} 11 times more than that of EG₃₀₀, demonstratethe importance of residues 330–499 for non-catalytic bindingof cellulose. A construct of the cel gene carrying a deletionof codons 330–499 and an insertion of a nonsense codonat leucine-330, was further used to make mutants EG₂₉₆ and EG₂₉₁with nonsense codon substitutions at arginine and serine-321,respectively.Western analysis using EG-specific antiserum revealedthat relative losses in enzymatic activity of EG₂₉₆ (50%) andEG₂₉₁ (95%) could be accounted for by the extent of their proteolysis,signifying a marked destabilization of these enzymes by removalof only a few amino acids.     

Site-directed mutagenesis at the active site Trpl20 of Aspergillus awamori glucoamylase

Trpl20 of Aspergillus awamori glucoamylase has previously beenshown by chemical modification to be essential for activityand tentatively to be located near subsite 4 of the active site.To further test its role, restriction sites were inserted inthe cloned A.awamori gene around the Trpl20 coding region, andcassette mutagenesis was used to replace it with His, Leu, Pheand Tyr. All four mutants displayed 2% or less of the maximalactivity (k_cat) of wild-type glucoamylase towards maltose andmaltoheptaose. MichaelLs constants (K_M) of mutants decreased2- to 3-fold for maltose and were essentially unchanged formaltoheptaose compared with the wild type, except for a >3-fold decrease for maltoheptaose with the Trp120 – Tyrmutant. This mutant also bound isomaltose more strongly andhad more selectivity for its hydrolysis than wild-type glucoamylase.A subsite map generated from malto-oligosaecharide substrateshaving 2 – 7 D-glucosyl residues indicated that subsites1 and 2 had greater affinity for D-glucosyl residues in theTrp120 – Tyr mutant than in wild-type glucoamylase. Theseresults suggest that Trpl20 from a distant subsite is crucialfor the stabilization of the transition-state complex in subsites1 and 2.     

Mutagenesis of conserved residues within the active site of Escherichia coli alkaline phosphatase yields enzymes with increased kcat

The likelihood for improvement in the catalytic properties ofEscherichia coli alkaline phosphatase was examined using site-directedmutagenesis. Mutants were constructed by introducing sequencechanges into nine preselected amino acid sites within 10 A ofthe catalytic residue serine 102. When highly conserved residuesin the family of alkaline phosphatases were mutated, many ofthe resulting enzymes not only maintained activity, but alsoexhibited greatly improved tra,. Of –170 mutant enzymesscreened, 5% (eight mutants) exhibited significant increasesin specific activity. In particular, a substitution by serineof a totally invariant AsplOl resulted in a 35-fold increaseof specific activity over wild-type at pH 10.0. Up to 6-foldincreases the k_cat/k_m ratio were observed.     

On the possibilities and limitations of rational protein design to expand the specificity of restriction enzymes: a case study employing EcoRV as the target

The restriction endonuclease EcoRV has been characterized instructural and functional terms in great detail. Based on thisdetailed information we employed a structure-guided approachto engineer variants of EcoRV that should be able to discriminatebetween differently flanked EcoRV recognition sites. In crystalstructures of EcoRV complexed with d(CGGGATATCCC)₂ and d(AAAGATATCTT)₂,Lys104 and Ala181 closely approach the two base pairs flankingthe GATATC recognition site and thus were proposed to be a reasonablestarting point for the rational extension of site specificityin EcoRV [Horton,N.C. and Perona,J.J. (1998) J. Biol. Chem.,273, 21721–21729]. To test this proposal, several single(K104R, A181E, A181K) and double mutants of EcoRV (K104R/A181E,K104R/A181K) were generated. A detailed characterization ofall variants examined shows that only the substitution of Ala181by Glu leads to a considerably altered selectivity with botholigodeoxynucleotide and macromolecular DNA substrates, butnot the predicted one, as these variants prefer cleavage ofa TA flanked site over all other sites, under all conditionstested. The substitution of Lys104 by Arg, in contrast, whichappeared to be very promising on the basis of the crystallographicanalysis, does not lead to variants which differ very much fromthe EcoRV wild-type enzyme with respect to the flanking sequencepreferences. The K104R/A181E and K104R/A181K double mutantsshow nearly the same preferences as the A181E and A181K singlemutants. We conclude that even for the very well characterizedrestriction enzyme EcoRV, properties that determine specificityand selectivity are difficult to model on the basis of the availablestructural information.     

Conformation and stability of barley chymotrypsin inhibitor-2 (CI-2) mutants containing multiple lysine substitutions

A major goal of agricultural biotechnology is to increase thenutritional value of maize seed through the expression of heterologousproteins enriched in lysine. One promising candidate is barleychymotrypsin inhibitor-2 (CI-2), a plant protein that has beenextensively characterized with respect to structure and function.Based on the tertiary structure of wild-type (WT) CI-2, fivemutants with lysine contents ranging from 20 to 25 mol percentwere designed, expressed in Escherichia coli and purified byion exchange and gel permeation chromatography. Inasmuch asprevious transgenic experiments suggested that proper foldingand stability may be essential for in vivo accumulation of theengineered proteins in plant cells, we first undertook an invitro study of the conformation and thermodynamic stabilityof the CI-2 mutants in order to select an ideal candidate forplant expression. Mutant and WT CI-2 proteins had similar circulardichroism spectra, suggesting similar secondary structures.However, differences in the accessibility of the sole tryptophanresidue, Trp24, indicated that the local conformation differedamong the mutants. The thermodynamic stability of the mutantsranged from <2 to 4.9 kcal/mol compared with ~7 kcal/molfor the wild-type protein. In conjunction with proteolytic stabilitystudies, we have identified one mutant that has the potentialto be expressed in a stable manner in plant cells.     

Specificity determinants of rat tissue kallikrein probed by site-directed mutagenesis

Site-specific mutagenesis was employed to study structure-functionrelationships at the substrate binding site of rat tissue kallikrein.Four kallikrein mutants, the Pro219 deletion (P219del), the34–38 loop Tyr-Tyr-Phe-Gly to Ile-Asn mutation [YYFG(34–38)IN],the Trp215Gly exchange (W215G) and the double mutant with Tyr99Hisand Trp215Gly exchange (Y99H:W215G) were created by site-directedmutagenesis to probe their function in substrate binding. Themutant proteins were expressed in Esclzerichia coli at highlevels and analyzed by Western blot. These mutant enzymes werepurified to apparent homogeneity. Each migrated as a singleband on SDS-PAGE, with slightly lower molecular mass (36 kDa)than that of the native enzyme, (38 kDa) because of their lackof glycosylation. The recombinant kallikreins are immunologicallyidentical to the native enzyme, displaying parallelism withthe native enzyme in a direct radioimmunoassay for rat tissuekallikrein. Kinetic analyses of K_m and k_cat using fluorogenicpeptide substrates support the hypothesis that the Tyr99–Trp215interaction is a major determinant for hydrophobic P2 specificity.The results suggest an important role for the 34–38 loopin hydrophobic P3 affinity and further show that Pro219 is essentialto substrate binding and efficient catalysis of tissue kallikrein.     

Engineering of the substrate-binding region of the sublilisin-like, cell-envelop proteinase of Lactococcus lactis

The substrate-binding region of the cell-envelope proteinaseof Lactococcus lactis strain SK11 was modelled, based on sequencebomology of the catalytic domain with the serine proteinasessubtilisin and thermitase. Substitutions, deletions and insertionswere introduced, by site-directed and cassette mutagenesfe ofthe prtP gene encoding this enzyme, based on sequence comparisonboth with subtilisin and with the homologous L.lactis strainWg2 proteinase, which has different proteolytic properties.The engineered enzymes were investigated for thermal stability,proteolytic activity and cleavage specificity towards smallchromogenk peptide substrates and the peptide _g1-casein(l–23).Mutations in the subtilisin-like substrate-binding region showedthat Ser433 is the active site residue, and that residues 138and 166 at either side of the binding cleft play an importantrole in substrate specificity, particularly when these residuesand the substrate are oppositely charged. The K748T mutationin a different domain also affected specificity and stability,suggesting that this residue is in close proximity to the subtilisin-likedomain and may form part of the substratebinding site. Severalmutant SK11 proteinases have novel properties not previouslyencountered in natural variants. Replacements of residues 137–139AKTalong one side of the binding cleft produced the 137–139GPPmutant proteinase with reduced activity and narrowed specificity,and the 137–139GLA mutant with increased activity andbroader specificity. Furthermore, the 137–139GDT mutanthad a specificity towards _g1,-casein(l–23) closely resemblingthat of L.lactis Wg2 proteinase. Mutants with an additionalnegative charge in the binding region were more stable towardsautoproteolysis.     

Analysis of the structure of Pseudomonas glumae lipase

The lipase produced by Pseudomonas glumae is monomeric in thecrystalline state and has a serine protease-like catalytic triad;Ser87-His285-Asp263. The largest domain of the protein resemblesclosely a subset of the frequently observed /ß-hydrolasefold and contains a well-defined calcium site. This paper describesstructural analysis of this protein, focusing on (i) structuralcomparison with the lipase from Geotrichum candidum, (ii) theprobable nature of the conformational change involved in substratebinding and (iii) structural variations amongst the family ofPseudomonas Upases. This analysis reveals similarities betweenP.glumae lipase and G.candidum lipase involving secondary structuralelements of the hydrolase core and the loops carrying the catalyticserine and histidine residues. A possible functional equivalencehas also been identified between parts of the two moleculesthought to be involved in a confonmational change. In addition,determination of the structure of P.glumae lipase has allowedrationalization of previously reported protein engineering experiments,which succeeded in improving the stability of the enzyme withrespect to proteolysis.