Involvement of various amino- and carboxyl-terminal residues in the active site of the histidine-containing protein HPr of the phosphoenolpyruvate-dependent phosphotransferase system of Staphylococcus carnosus: site-directed mutagenesis with the ptsH gene, biochemical characterization and NMR studies of the mutant proteins

The phosphocarrier HPr (heat stable protein) of Staphylococcuscarnosus was modified by site-directed mutagenesis of the correspondingptsH gene in order to analyse the importance of amino acidswhich were supposed to be part of the active centre of the protein.Three residues which are conserved in all HPrs, Argl7, Prol8and Glu84, were mutated: Argl7 was changed to His (17RH) andPro18 and Glu84 were changed into Ala (18PA and 84EA). In addition,Leu86 was changed into Ala (86LA) and one mutant protein wasmissing the last six residues of the HPr (83). The wild typegene and all mutant genes were overexpressed and the gene productspurified to homogeneity. Three-dimensional structures of wildtype and mutant proteins were monitored by NMR spectroscopy.All five mutant HPrs had native conformations. The ATP-dependentHPr kinase can phosphorylate all HPr derivatives at Ser46. ThePTS activity of the amino-terminal HPr mutant proteins 17RHand 18PA was different compared to wild type HPr. In contrast,the car boxy-terminal mutant HPrs possessed a similar enzymeactivity to the wild type HPr. The 17RH and 18PA HPrs with substitutionnear the active centre His15 showed a very slow phosphorylationby enzyme I but the further transfer of the phosphoryl groupto enzyme III was also strongly inhibited. The enzyme activityof the HPr 17RH was significantly improved at low pH. NMR pH-titrationexperiments showed that Arg17 is not responsible for the lowpK_a, of the active centre His15 but this positively chargedresidue is essential in this position for the HPr activity.     

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.     

Analysis of several key active site residues of ricin A chain by mutagenesis and X-ray crystallography

Active she residues of ricin A chain were analyzed by sitedirectedmutagenesis and X-ray diffraction to help assess their rolesin the mechanism of action of this toxic N-glycosidase enzyme.Argl80 is thought, from X-ray studies, to protonate the adeninesubstrate at N3; this facilitates bond cleavage and is crucialto the mechanisms of action. The residue was converted to Glnand initial rate data measured. Km for the mutant is not significantlyaffected, increasing only 2-fold. The K_cat, however, is decreased 1000-fold. This is consistent with a simple interpretationthat Argl80 is involved more in transition state stabilizationthan in substrate binding. Tyrosines 80 and 123 are known fromX-ray models to stack on either side of the substrate adeninering. When they were each converted to serine overall activitywas reduced 160- and 70-fold respectively against ribosomesfrom Artemia salina. These effects are each 10 times greaterthan when the residues were previously converted to phenylalanines.Sufficient protein for the Tyr80 to Phe mutant was obtainedto carry out an X-ray analysis. Together with mutagenesis data,the structure suggests that the invariance of the two activesite Tyr residues is largely caused by structural stability.     

Structure prediction of the EcoRV DNA methyltransferase based on mutant profiling, secondary structure analysis, comparison with known structures of methyltransferases and isolation of catalytically inactive single mutants

The EcoRV DNA methyltransferase (M·EcoRV) is an -adeninemethyltransferase. We have used two different programs to predictthe secondary structure of M·EcoRV. The resulting consensusprediction was tested by a mutant profiling analysis. 29 neutralmutations of M·EcoRV were generated by five cycles ofrandom mutagenesis and selection for active variants to increasethe reliability of the prediction and to get a secondary structureprediction for some ambiguously predicted regions. The predictedconsensus secondary structure elements could be aligned to thecommon topology of the structures of the catalytic domains ofM·HhaI and M·TaqI. In a complementary approachwe have isolated nine catalytically inactive single mutants.Five of these mutants contain an amino acid exchange withinthe catalytic domain of M·EcoRV (Val20-Ala, Lys81Arg,Cys192Arg, Asp193Gly, Trp231Arg). The Trp231Arg mutant bindsDNA similarly to wild-type M·EcoRV, but is catalyticallyinactive. Hence this mutant behaves like a bona fide activesite mutant. According to the structure prediction, Trp231 islocated in a loop at the putative active site of M·EcoRV.The other inactive mutants were insoluble. They contain aminoacid exchanges within the conserved amino acid motifs X, IIIor IV in M·EcoRV confirming the importance of these regions.     

Chemical modification and site-directed mutagenesis of Tyr36 of 3-isopropylmalate dehydrogenase from Thermits thermophUus HB8

3-Isopropylmalate dehydrogenase from an extreme thermo-phile,Thermus thermophUus HB8, was chemically modified with tetranitromethanewhich nitrated 1.5-2.0 Tyr residues per subunit. The nitrationwas biphask and parallel to the loss of activity. The modifiedresidue in the first phase was identified to be Tyr36, whichis distantly located from the active site of the enzyme. Thefunction of Tyr36 was investigated by site-specific replacementwith Phe. The Michaelis constant for the substrate or co-enzymewas not altered by the replacement, whereas the catalytic constantdecreased down to -5%. X-ray analysis of the mutant enzyme revealedthat Arg94 moved the largest distance among the active siteresidues, that is, the NH1 and NH2 of the guanidino group moved1.11 and 1.32 Å respectively. The results suggest thatArg94 is responsible for the enzyme catalysis     

The stability and unfolding of an IgG binding protein based upon the B domain of protein A from Staphylococcus aureus probed by tryptophan substitution and fluorescence spectroscopy

The stability and unfolding of an immunoglobulin (Ig) G bindingprotein based upon the B domain of protein A (SpAB) from Staphylococcusaureus were studied by substituting tryptophan residues at strategiclocations within each of the three a-helical regions (al-a3)of the domain. The role of the C-terminal helix, a3, was investigatedby generating two protein constructs, one corresponding to thecomplete SpAB, the other lacking a part of ct3; the Trp substitutionswere made in both one-and two-domain versions of each of theseconstructs. The fluorescence properties of each of the single-tryptophanmutants were studied in the native state and as a function ofguanidine-HCl-mediated unfolding, and their IgG binding activitieswere determined by a competitive enzyme-linked immunosorbentassay. The free energies of folding and of binding to IgG foreach mutant were compared with those for the native domains.The effect of each substitution upon the overall structure andupon the IgG binding interface was modelled by molecular graphicsand energy minimization. These studies indicate that (i) 3 contributesto the overall stability of the domain and to the formationof the IgG binding site in l and 2, and (ii) al unfolds first,followed by 2 and 3 together.     

Characterization of the apparent negative co-operativity induced in Escherichia coli aspartate aminotransferase by the replacement of Asp222 with alanine. Evidence for an extremely slow conformational change

The strictly conserved active site residue, Asp222, which formsa hydrogen-bonded salt bridge with the pyridine nitrogen atomof the pyridoxal 5' phosphate (PLP) co-factor of aspartate aminotransferase(AATase), was replaced with alanine (D222A) in the Escherichiacoli enzyme. The D222A mutant exhibits non–hyberbolicsaturation behavior with amino acid substrates which appearas apparent negative eooperativity in steady–state kineticanalyses. Single turnover progress curves for D222A are welldescribed by the sum of two exponentials, contrasting with themonophasic kinetics of the wild-type enzyme. An active/inactiveheterodimer containing the D222A mutation retains this biphasickinetic response, proving that the observed eooperativity isnot the result of induced allostery. The anomalous behavioris explained by a hysteretic kinetic model involving two slowlyinterconverting enzyme forms, only one of which is catalyticallycompetent. The slow functional transition between the two formshas a half–life of 10 mins. Preincubation of the mutantwith the dicarboxylk inhibitor maleate shifts the equilibriumpopulation of the enzyme towards the catalytically active form,suggesting that the slow transition is related to the domainclosure known to occur upon association of this inhibitor withthe wild-type enzyme. The importance of Asp222 in the chemicalsteps of transamination is confirmed by the l0⁵fold decreasein catalytic competence in the D222A mutant, and by the largeprimary C–deuterium kinetic isotope effect (6.7 versus2.2 for the wild–type). The transamination activity ofthe D222A mutant is enhanced 4– to 20–fold by reconstltutionwith the co-factor analog N–methylpyridoxal–5–phosphate(N–MePLP), and the C–proton abstraction step isless rate determining, as evidenced by the decrease in the primarykinetic isotope effect from 6.7 to 2.3. These results suggestthat the conserved interaction between the protonated pyridinenitrogen of PLP and the negatively charged carboxylate of Asp222is important not only for efficient C–proton abstraction,but also for conformational transitions concomitant with thetransamination process     

Interspecific luciferase {beta} subunit hybrids between Vibrio harveyi, Vibrio fischeri and Photobacterium leiognathi

Bacterial luciferase (EC 1.14.143) is a heterodimer composedof and ß-chains encoded by luxA and luxB, respectively.Although some interspecific combinations of these subunits leadto active enzyme, others do not. The ß subunits ofVibrio fischeri and Photobacterium leiognathi form active enzymewith the subunits of V.fischeri, P.leiognathi and Vibrio harveyi,while the ß subunit from V.harveyi only complementsthe subunit of V.harveyi. Inactivity is caused by a lack ofdimerization of the ß subunit of V.harveyi with the subunits of V.fischeri and P.leiognathi. These observationsserved as the basis for a search to discover which segment ofthe ß polypeptide confers the ability to dimerizewith the subunits of V.fischeri and P.leiognathi. Intragenicß subunit hybrids were made between V.harveyi, V.fischeriand P.leiognathi. Unique restriction sites were introduced intothe respective luxB genes to divide them into four roughly equalsegments. In all, 78 hybrids were constructed by in vitro techniques.The N-terminal segment of the peptide contains the signals thatdifferentiate between the ß subunits of V.fischeriand P.leiognathi and the ß subunit of V.harveyi, andallow the former to dimerize with their a subunits. The secondsegment has no major effect on enzyme activity but does exhibitsome context effects. Important interactions were found betweenthe third and fourth segments of the polypeptide with respectto enzymatic activity.     

Phage-enzymes: expression and affinity chromatography of functional alkaline phosphatase on the surface of bacteriophage

We have demonstrated that an active enzyme can be expressedon the surface of a bacteriophage. The gene encoding alkalinephosphatase from Escherichia coli was cloned upstream of gene3, which encodes a minor coat protein of the filamentous bacteriophage,fd. A fusion protein of the correct size was detected from viralparticles by Western blotting. Ultrafiltration confirmed thatthe enzyme fusion behaves as part of a larger structure as wouldbe expected of an enzyme fused to a viral particle. Both wild-typealkaline phosphatase (Argl66) and an active site mutant (Ala166) expressed in this way retain catalytic activity and havequalitatively similar kinetic properties to free enzyme. Valueswere obtained for K_m of 72.7 and 1070 µM respectivelywhilst relative k_cat for the mutant was 36% of that for wild-type.Phage particles expressing alkaline phosphatase were bound toan immobilized inhibitor (arsenate-Sepharose) and eluted withproduct (20 mM inorganic phosphate). In this way, the functionalenzyme is co-purified with the DNA encoding it. This may permita novel approach to enzyme engineering based on affinity chromatographyof mutant enzymes expressed on the phage surface.     

The structure of a designed peptidomimetic inhibitor complex of {alpha}-thrombin

Thrombin displays remarkable specificity, effecting the removalof fibrinopeptides A and B of fibrinogen through the selectivecleavage of two Arg–Gly bonds between the 181 Arg/Lys–Xaabonds in fibrinogen. Significant advances have been made inrecent years towards understanding the origin of the specificityof cleavage of the Argl6–Gly17 bond of the A-chain ofhuman fibrinogen. We have previously proposed a model for thebound structure of fibrinopeptide A_7–16 (FPA), based uponNMR data, computer-assisted molecular modeling and the synthesisand study of peptidomimetic substrates and inhibitors of thrombin.We now report the structure of the ternary complex of an FPAmimetic (FPAM), hirugen and thrombin at 2.5 Å resolution(R-factor = 0.138) and specificity data for the inhibition ofthrombin and related trypsin-like proteinases by FPAM. The crystallographicstructures of FPA and its chloromethyl ketone derivative boundto thrombin were determined. Although there are differencesbetween these structures in the above modeled FPA structureand that of the crystal structure of FPAM bound to thrombin,the , angles in the critical region of P1–P2–P3in all of the structures are similar to those of bovine pancreatictrypsin inhibitor (BPTI) in the BPTI–trypsin complex andD–Phe–Pro–Arg (PPACK) in the PPACK–thrombinstructure. A comparison between these and an NMR-derived structureis carried out and discussed.     

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.     

C-terminal truncations of a thermostable Bacillus stearothermophilus {alpha}-amylase

A series of truncated proteins from a thermostable Bacillusstearothermophilus -amylase was prepared to study the importanceof the extension in the C-terminus compared with other liquefyingBacillus -amylases. The mutations introducing new translationtermination sites shortened the 515 amino acid residue-longwild type enzyme by 17, 32, 47, 73 or 93 residues. The longerthe truncation, the lower the specific activity of the enzyme.Only the two longest mutant proteins were active: the specificactivity of the 498 residue variant was 97% and protein 483was 36% that of the parental enzyme. The K_m values of starchhydrolysis changed from 1.09 for wild type enzyme to 0.35 and0.21 for mutants 498 and 483, respectively, indicating alteredsubstrate binding. The mutant enzymes had almost identical pHand temperature optima with the wild type amylase, but enhancedthermal stability and altered end product profile. The consequencesof the truncation to the structure and function of the enzymeswere explored with molecular modeling. The liquefying amylasesseem to require {small tilde}480 residues to be active, whereasthe C-terminal end of B.stearothermophilus amylase is requiredfor increased activity.     

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.     

The effect of cavity-filling mutations on the thermostability of Bacillus stearothermophilus neutral protease

Cavities in the hydrophobic core of the neutral protease ofBacillus stearothermophilus were analyzed using a threedimensionalmodel that was inferred from the crystal structure of thermolysin,the highly homologous neutral protease of B.thermoproteolyticus(85% sequence identity). Site–directed mutagenesis wasused to fill some of these cavities, thereby improving hydrophobicpacking in the protein interior. The mutations had small effectson the thermostability, even after drastic changes, such asLeu284Trp and Met168Trp. The effects on T50, the temperatureat which 50% of the enzyme is irreversibly inactivated in 30min, ranged from 0.0 to +0.4°C. These results can be explainedby assuming that the mutations have positive and negative structuraleffects of approximately the same magnitude. Alternatively,it could be envisaged that the local unfolding steps, whichrender the enzyme susceptible towards autolysis and which arerate limiting in the process of thermal inactivation, are onlyslightly affected by alterations in the hydrophobic core.     

Protein modification from mutational analysis of an autologous peptide fragment

In the -complementation of ß-galactosidase an N-terminalpeptide fragment (-peptide) of the wild-type enzyme interactswith a defective ß-galactosidase enzyme to restorecapacity for subunit assembly and activity. We have used previouslya random mutagenesis and screening approach to identify a pentapeptideresidue tract in the -peptide that was highly tolerant of residuesubstitution, with some mutations conferring improved function.This tract is of clear importance for -peptide function butis apparently dispensible in the intact parental enzyme. Toinvestigate this further, we selected tract mutations and placedthem into intact ß-galactosidase, at the correspondingN-terminal position as in the -peptide. We then tested whethersuch specific tract sequences conferred properties to the wholeenzyme which could be predicted from the behaviour of the defectiveenzyme complemented with the corresponding mutant -peptide.This was shown for mutations which positively or negativelyaffected enzyme stability. Additionally, a subset of mutationswhich affected complementation efficiency in vivo were predictedto affect the formation of higher-order structures in the intactprotein, and this was observed experimentally. Mutations whichdecreased peptide complementation dramatically decreased thelevel of formation of multimers in the intact protein and amutation which increased peptide complementation produced markedenhancement of multimer formation in a protein with a preexistingimpairment in higher-order structure formation. Such subtleeffects are difficult to detect directly in the whole proteinby randomization/selection approaches, but in the complementingpeptide the role of the residues within the pentapeptide tractis effectively amplified. Identification of residue tracts exhibitingfunctional tolerance to amino acid substitution in an activepeptide fragment can thus be combined with transferral of potentiallyuseful mutant peptide sequences back into the intact protein.Manipulation of a complementation system in this manner affordsa sensitive approach towards targeted improvement of proteins.     

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.     

Structure--activity relationships in human interleukin-1{alpha}: identification of key residues for expression of biological activities

To identify the sites important for the different biologicalactivities of human interleukin-l (hIL-1), 56 single-amino acid-substitutedmutants of hIL-l were produced in Escherichia coli using site-directedmutagenesis, and were examined for their biological activitiessuch as mouse lymphocyte activating factor activity (LAF activity),cytostatic activity against human melanoma cells A-375 (A375activity) and prostaglandin E2 (PGE2) inducing activity in humanosteosarcoma cells MG-63 (PEI activity). Two amino acid residues,Asp26 and Asp151, were found to be important for these activities.The replacement of Asp26 by Val caused a decrease in LAF andA375 activities by one or two orders of magnitude and a slightdecrease in A375 activity. The Tyr or Phe substitution for Asp151caused decreases in LAF and A375 activities by one or two ordersof magnitude and complete loss of PEI activity. The change fromAsp151 to Lys or Arg resulted in marked decrease in LAF activityand complete loss of A375 and PEI activities. Since Asp26 andAsp151 are close to each other in the three-dimensional structure,the region involving these amino acids seems to be importantfor the biological activities of hIL-1.     

Stability, activity and flexibility in {alpha}-lactalbumin

-Lactalbumins and the type-c lysozymes are homologues with similarfolds that differ in function and stability. To determine ifthe lower stability of -lactalbumin results from specific substitutionsrequired for its adaptation to a new function, the effects oflysozyme-based and other substitutions on thermal stabilitywere determined. Unblocking the upper cleft in -lactalbuminby replacing Tyr103 with Ala, perturbs stability and structurebut Pro, which also generates an open cleft, is compatible withnormal structure and activity. These effects appear to reflectalternative enthalpic and entropic forms of structural stabilizationby Tyr and Pro. Of 23 mutations, only three, which involve substitutionsfor residues in flexible substructures adjacent to the functionalsite, increase stability. Two are lysozyme-based substitutionsfor Leu110, a component of a region with alternative helix andloop conformations, and one is Asn for Lys114, a residue whosemicroenvironment changes when -lactalbumin interacts with itstarget enzyme. While all substitutions for Leu110 perturb activity,a Lys114 to Asn mutation increases T_m by more than 10°Cand reduces activity, but two other destabilizing substitutionsdo not affect activity. It is proposed that increased stabilityand reduced activity in Lys114Asn result from reduced flexibilityin the functional site of -lactalbumin.     

Contribution of a disulfide bridge to the stability of 1,3-1,4-P-D-glucan 4-glucanohydrolase from Bacillus licheniformis

Bacillus 1,3-1,4-ß-glucanases possess a highly conserveddisulfide bridge connecting a ß-strand with a solventexposedloop lying on top of the extended binding site cleft The contributionof the disulfide bond and of both individual cysteines (Cys61and Cys90) in the Bacillus licheniformis enzyme to stabilityand activity has been evaluated by protein engineering methods.Reduction of the disulfide bond has no effect on kinetic parameters,has only a minor effect on the activity-temperature profileat high temperatures, and destabilizes the protein by less than0.7 kcal/mol as measured by equilibrium urea denatu ration at37°C. Replacing either of the Cys residues with Ala destabilizesthe protein and lowers the specific activity. C90A retains 70%of wild-type (wt) activity (in terms of Vmax), whereas C61Aand the double mutant C61A–C90A have 10% of wt V_max. Alarger change in free energy of unfolding is seen by equilibriumurea denaturation for the C61A mutation (loop residue, 3.2 kcal/molrelative to reduced wt) as compared with the C90A mutation (ß-strandresidue, 1.8 kcal/mol relative to reduced wt), while the doublemutant C61A–C90A is 0.8 kcal/mol less stable than thesingle C61A mutant. The effects on stability are interpretedas a result of the change in hydrophobic packing that occursupon removal of the sulfur atoms in the Cys to Ala mutations     

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.