Modulation of the enzymatic activity of papain by interdomain residues remote from the active site

The two main catalytic residues Cys25 and Hisl59 of the monomericcysteine protease papain are located on different walls of acleft formed by two domains. This topology suggests a possiblerelationship between relative domain organization and catalyticmechanism. The effect on enzymatic parameters of structuralmodifications at various locations of the twodomain interfaceof papain was examined by individual or double replacementsby Ala of pairs of interacting residues. Most modificationshad no effect on enzyme activity. However, the enzyme's substrateturnover (k_cat) decreased following simultaneous alterationof the two most conserved residues, forming an apolar contactlocated 15 Å away from the active site. The pH activityprofile of the double mutant was unchanged, indicating a conservedionization state of the active site thiolate-imidazolium ionpair. This state is strongly dependent on the distance separatingthe two residues, thus suggesting that the active site geometryhas not been significantly altered. Efficient enzymatic activityin papain requires more than a correct active site geometryand is influenced by domain packing properties in a region remotefrom the active site.     

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.     

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.     

Alteration of aspartate 101 in the active site of Escherichia coli alkaline phosphatase enhances the catalytic activity

The function of aspartic acid residue 101 in the active siteof Escherichia coli alkaline phosphatase was investigated bysite-specific mutagenesis. A mutant version of alkaline phosphatasewas constructed with alanine in place of aspartic acid at position101. When kinetic measurements are carried out in the presenceof a phosphate acceptor, 1.0 M Tris, pH 8.0, both the k_cat andthe K_m, for the mutant enzyme increase by –2-fold, resultingin almost no change in the k_cat/K_m ratio. Under conditions ofno external phosphate acceptor and pH 8.0, both the k_cat andthe K_m for the mutant enzyme decrease by {small tilde}2-fold,again resulting in almost no change in the k_cat/K_m ratio. Thek_cat for the hydrolysis of 4-methyl-umbelliferyl phosphate andp-nitrophenyl phosphate are nearly identical for both the wild-typeand mutant enzymes, as is the K₁ for inorganic phosphate. Thereplacement of aspartic acid 101 by alanine does have a significanteffect on the activity of the enzyme as a function of pH, especiallyin the presence of a phosphate acceptor. At pH 9.4 the mutantenzyme exhibits 3-fold higher activity than the wild-type. Themutant enzyme also exhibits a substantial decrease in thermalstability: it is half inactivated by treatment at 49°C for15 min compared to 71°C for the wild-type enzyme. The datareported here suggest that this amino acid substitution altersthe rates of steps after the formation of the phospho-enzymeintermediate. Analysis of the X-ray structure of the wild-typeenzyme indicates that the increase in catalytic rate of themutant enzyme in the presence of a phosphate acceptor may bedue to an increase in accessibility of the active site nearSerl02. The increased catalytic rate of this mutant enzyme maybe utilized to improve diagnostic tests that require alkalinephosphatase, and the reduced heat stability of the mutant enzymemay make it useful in recombinant DNA techniques that requirethe ability to heat-inactivate the enzyme after use.     

Determination of the pKa values of titratable groups of an antigen-antibody complex, HyHEL-5-hen egg lysozyme

The titration behavior of the ionizable residues of the HyHEL-5–henegg lysozyme complex and its individual components has beenstudied using continuum electrostatic calculations. Severalresidues of HyHEL-5 had pK_a values shifted away from model valuesfor isolated residues by more than three pH units. Shifts awayfrom the model values were smaller for the residues of hen egglysozyme. A moderate variation in the pK_a values of the titratablegroups was observed upon increase of the ionic strength from0 to 100 mM, amounting to 1–2 pH units in most cases.Under physiological conditions, the net charge of HyHEL-5 wasopposite that for hen egg lysozyme. Several residues, includingthose involved in the Arg–Glu salt bridges that have beenproposed to be important in antibody-antigen binding, had pK_avalues that were changed significantly upon binding. The maintitration event upon antibody-antigen binding appears to beloss of a proton from residue GluH50 of the Fv molecule. Thelimitations of our calculation methods and the role they mightplay in the design of antibodies for use in assays, sensorsand separations are discussed     

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.     

Trp59 to Tyr substitution enhances the catalytic activity of RNase T1 and of the Tyr to Trp variants in positions 24, 42 and 45

Using point mutated overproducing strains of E.coli, ribonucleaseT1 was prepared with the single substitutions Tyr24Trp, Tyr42Trp,Tyr45Trp or Trp59Tyr and the corresponding double substitutionsTyr24Trp/Trp59Tyr, Tyr42Trp/Trp59Tyr and Tyr45Trp/Trp59Tyr.Steady state kinetics of the transesterification reaction forthe two dinucleoside monophosphate substrates guanylyl-3', 5'-cytidineand guanylyl-3', 5'-adenosine indicate that the tryptophan canbe introduced in different positions within the ribonucleaseT1 molecule without abolishing enzymatic activity. The Trp59Tyrexchange even enhances catalysis of the cleavage reaction (k_cat/K_m)relative to the wild type enzyme and similar effects are foundwith single tyrosine to tryptophan substitutions. For the pHdependencies of the guanylyl-3', 5'-cytidine transesterificationreaction of wild type ribonuclease T1 and of the variants, typicallybell-shaped curves are observed with a plateau in the rangepH 4.5–7.0. Their shapes and slopes indicate that theenzymes are comparable in their macroscopic pK_a, values. AtpH 7.5, the variant Tyr45Trp/Trp59Tyr shows a more than 3-foldhigher transesterification activity for guanylyl-3', 5'-adenosineand a 2-fold increase for guanylyl-3', 5'-cytidine comparedto the wild type enzyme, i.e. this variant catalyses the transesterificationof the substrate guanylyl-3', 5'-adenosine with the same orbetter efficiency as guanylyl-3', 5'-cytidine.     

A lysine to arginine substitution at position 146 of rabbit aldolase A changes the rate-determining step to Schiff base formation

Lys146 of rabbit aldolase A [D-fructose-1,6-bis(phosphate):D-glyceraldehyde-3-phosphate lyase, EC 4.1.2.13 [EC] ] was changedto arginine by site-directed mutagenesis. The k_cat of the resultingmutant protein, K146R, was 500 times slower than wild-type insteady-state kinetic assays for both cleavage and condensationof fructose-1,6-bis(phosphate), while the Km for this substratewas unchanged. Analysis of the rate of formation of catalyticintermediates showed K146R was significantly different fromthe wild-type enzyme and other enzymes mutated at this site.Single-turnover experiments using acid precipitation to trapthe Schiff base intermediate on the wild-type enzyme failedto show a build-up of this intermediate on K146R. However, K146Rretained the ability to form the Schiff base intermediate asshown by the significant amounts of Schiff base intermediatetrapped with NaBH₄. In the single-turnover experiments it appearedthat the Schiff base intermediate was converted to productsmore rapidly than it was produced. This suggested a maximalrate of Schiff base formation of 0.022 s^–1, which wasclose to the value of k_cat for this enzyme. This observationis strikingly different from the wild-type enzyme in which Schiffbase formation is >100 times faster than k_cat. For K146Rit appears that steps up to and including Schiff base formationare rate limiting for the catalytic reaction. The carbanionintermediate derived from either substrate or product, and theequilibrium concentrations of covalent enzyme-substrate intermediates,were much lower on K146R than on the wild-type enzyme. The greaterbulk of the guanidino moiety may destabilize the covalent enzyme-substrateintermediates, thereby slowing the rate of Schiff base formationsuch that it becomes rate limiting. The K146R mutant enzymeis significantly more active than other enzymes mutated at thissite, perhaps because it maintains a positively charged groupat an essential position in the active site or perhaps the Argfunctionally substitutes as a general acid/base catalyst inboth Schiff base formation and in subsequent abstraction ofthe C4-hydroxyl proton.     

Cassette mutagenesis of Aspergillus awamori glucoamylase near its general acid residue to probe its catalytic and pH properties

Nine single amino add mutations in the active site of Aspergillusawamori glucoamylase were made by cassette mutagenesis to alterthe pH dependence of the enzyme and to determine possible functionsof the mutated residues. The Glul79-Asp mutation expressed inyeast led to a very large decrease in k_cat but to no changein K_m, verifying this residue's catalytic function. Aspl76-Gluand Glul80-Asp mutations affected K_m a more than k_cat, implyingthat Aspl76 and Glul80 are involved in substrate binding orstructural integrity. The Leul77-Asp mutation decreased k_catonly moderately, probably by changing the position of the generalacid catalytic group, and did not affect K_m. The Trpl78-Aspmutation greatly decreased k_cat while increasing K_m, showingthe importance of Trpl78 in the active site. Vall81-Asp andAsnl82-Asp mutations changed kinetk values little, suggestingthat Vall81 and Asnl82 are of minor catalytic and structuralimportance. Finally, insertions of Asp or Gly between residues176 and 177 resulted in almost complete loss of activity, probablycaused by destruction of the active site structure. No largechanges in pH dependence occurred in those mutations where kineticvalues could be determined, in spite of the increase in mostcases of the total negative charge. Increases in activationenergy of maltoheptaose hydrolysis in most of the mutant glucoamylasessuggested cleavage of individual hydrogen bonds in enzyme-substratecomplexes.     

Incorporation of an unnatural amino acid in the active site of porcine pancreatic phospholipase A2. Substitution of histidine by l,2,4-triazole-3-alanine yields an enzyme with high activity at acidic pH

The effect of the substitution of the active site histidine48 by the unnatural 1,2,4-triazole-3-alanine (TAA) amino acidanalogue in porcine pancreas phospholipase A₂ (PLA₂) was studied.TAA was introduced biosynthetically using a his-auxotrophicEscherichia coli strain. To study solely the effect of the substitutionof the active site histidine, two nonessential histidines (i.e.His17 and His 115) were replaced by asparagines, resulting ina fully active mutant enzyme (His-PLA₂). In this His-PLA₂ thesingle histidine at position 48 was substituted by TAA withan incorporation efficiency of about 90%, giving a mixture ofHis-PLA₂ and TAA-PLA₂. Based on the charge difference at acidicpH, both forms could be separated by FPLC, allowing for thepurification of TAA-PLA₂ free from His-PLA₂. At pH 6, TAA-PLA₂has a fivefold reduced activity compared with His-PLA₂. Thisreduced activity paralells a reduced rate of covalent modificationwith p-nitrophenacyl bromide of TAA-PLA₂ compared with His-PLA₂.Competitive inhibition gave comparable IC₅₀ values for WT-PLA₂,His-PLA₂ and TAA-PLA₂. These results indicate that the reductionin activity is not caused by a different affinity for the substrate,but more likely results from a reduced k_cat value in TAA-PLA₂.The enzymatic activities for native and mutant PLA₂s were measuredat different pH values. For WT-PLA₂ and His-PLA₂ the activityis optimal at pH 6 and is strongly deminished at acidic pH,with no observable activity at pH 3. In contrast, TAA-PLA₂ isas active at pH 3 as at pH 6. Most likely, the decrease in activityobserved for WT-PLA₂ and His-PLA₂ is caused by the protonationof the active site His48, which is the general base involvedin the activation of the nucleophilic water molecule. In TAA-PLA₂,however, the active site residue TAA48 is unprotonated at bothpH 3 and 6 as a result of the low pK_a of TAA compared with histidine.     

An unequivocal example of cysteine proteinase activity affected by multiple electrostatic interactions

The role of electrostatic interactions between the ionizableAsp158 and the active site thiolate-imidazolium ion pair ofsome cysteine proteinases has been the subject of controversyfor some time. This study reports the expression of wild typeprocaricain and Asp158Glu, Asp158Asn and Asp158Ala mutants fromEscherichia coli. Purification of autocatalytically maturedenzymes yielded sufficient fully active material for pH (k_cat/K_m)profiles to be obtained. Use of both uncharged and charged substratesallowed the effects of different reactive enzyme species tobe separated from the complications of electrostatic effectsbetween enzyme and substrate. At least three ionizations aredetectable in the acid limb of wild type caricain and the Gluand Asn mutants. Only two pK_a, values, however, are detectablein the acid limb using the Ala mutant. Comparison of pH activityprofiles shows that whilst an ionizable residue at position158 is not essential for the formation of the thiolate-imidazoliumion pair, it does form a substantial part of the electrostaticfield responsible for increased catalytic competence. Changingthe position of this ionizable group in any way reduces activity.Complete removal of the charged group reduces catalytic competenceeven further. This work indicates that hydronations distantto the active site are contributing to the electrostatic effectsleading to multiple active ionization states of the enzyme.     

Zinc ions bound to chimeric His4/lactate dehydrogenase facilitate decarboxylation of oxaloacetate

A chemically synthesized DNA linker coding for a peptide fragmentthat contains four histidines was fused in-frame to the 5'-endof the Bacillus stearothermophilus lactate dehydrogenase gene.The gene product, His₄/lactate dehydrogenase, could be purifiedto homogeneity using either immobilized metal (Zn²⁺)-affinitychromatography or affinity chromatography on oxamate agarose.The stability against heat and urea for the modified enzymeswas decreased as compared to the native lactate dehydrogenasebut could be increased if zinc ions were present during thedenaturation. In the presence of zinc ions the His₄/lactatedehydrogenase could catalyse the sequential reaction from oxaloacetateto L-lactate, hence operating as a semi-synthetic bifunctionalenzyme. A small increase in the apparent secondorder rate constant(k_cat/K_m) of the coupled reaction was observed as compared toa corresponding system with native lactate dehydrogenase.     

Effects of substitution of Thr63 by alanine on the structure and function of Lactobacillus casei dihydrofolate reductase

A mutant of Lactobacillus casei dihydrofolate reductase hasbeen constructed in which Thr63, a residue which interacts withthe 2'-phosphate group of the bound coenzyme, is replaced byalanine. This substitution does not affect k_cat, but producesan 800-fold increase in the K_m for NADPH, which reflects dissociationof NADPH from the enzyme-NADPH-tetrahydrofolate complex, anda 625-fold increase (corresponding to 3.8 kcal/mol) in the dissociationconstant for the enzyme-NADPH complex. The difference in magnitudeof these effects indicates a small effect of the substitutionon the negative cooperativity between NADPH and tetrahydrofolate.Stopped-flow studies of the kinetics of NADPH binding show thatthe weaker binding arises predominantly from a decrease in theassociation rate constant. NMR spectroscopy was used to comparethe structures of the mutant and wild-type enzymes in solution,in their complexes with methotrexate and with methotrexate andNADPH. This showed that only minimal structural changes resultfrom the mutation; a total of 47 residues were monitored fromtheir resolved ¹H resonances, and of these nine in the binarycomplex and six in the ternary differed in chemical shift betweenmutant and wild-type enzyme. These affected residues are confinedto the immediate vicinity of residue 63. There is a substantialdifference in the ³¹P chemical shift of the 2'-phosphate ofthe bound coenzyme, reflecting the loss of the interaction withthe side chain of Thr63. The only changes in nuclear Overhausereffects (NOEs) observed were decreases in the intensity of NOEsbetween protons of the adenine ring of the bound coenzyme andthe nearby residues Leu62 and Ile102, showing that the substitutionof Thr63 does cause a change in the position or orientationof the adenine ring in its binding site.     

Point mutation of alanine (31) to valine prohibits the folding of reduced lysozyme by sulfhydryl--disulfide interchange

In the preceding paper in this issue, we described the overproduction of one mutant chicken lysozyme in Escherichia coil.Since this lysozyme contained two amino acid substitutions (Ala³¹ValandAsn¹⁰⁶Ser)in addition to an extra methionine residue at theNH₂-terminus the substituted amino acid residues were convertedback to the original ones by means of oligonucleotide-directedsite-specific mutagenesis and in vitro recombination. Thus fourkinds of chicken lysozyme [Met^–1 Val³¹Ser¹⁰⁶-, Met^–1Ser¹⁰⁶-,Met^–1 Val³¹-and Met^–1 (wild type)] wereexpressed in E. coli. From the results of folding experimentsof the reduced lysozymes by sulfhydryl-disulfide interchangeat pH 8.0 and 38°C, follow ed by the specific activity measurementsof the folded en zymes, the following conclusions can be drawn:(i) an extra methionine residue at the NH₂-terminus reducesthe folding rate but does not affect the lysozyme activity ofthe folded enzyme; (ii) the substitution of Asn¹⁰⁶ by Ser decreasesthe activity to 58% of that of intact native lysozyme withoutchanging the folding rate; and (iii) the substitution of Ala³¹Val prohibits the correct folding of lysozyme. Since the wildtype enzyme (Met^–1-lysozyme) was activated in vitro withoutloss of specific activity, the systems described in this study(mutagenesis, overproduction, purification and folding of inactivemutant lysozymes) may be useful in the study of folding pathways,expression of biological activity and stability of lysozyme.     

Analysis of a catalytic pathway via a covalent adduct of D52E hen egg white mutant lysozyme by further mutation

We previously demonstrated by X-ray crystallography and electrospraymass spectrometry that D52E mutant hen lysozyme formed a covalentenzyme–substrate adduct on reaction with N-acetylglucosamineoligomer. This observation indicates that D52E lysozyme mayacquire a catalytic pathway via a covalent adduct. To explainthis pathway, the formation and hydrolysis reactions of thecovalent adduct were investigated. Kinetic analysis indicatedthat the hydrolysis step was the rate-limiting step, 60-foldslower than the formation reaction. In the formation reaction,the pH dependence was bell-shaped, which was plausibly explainedby the functions of the two catalytic pK_as of Glu35 and Glu52.On the other hand, the pH dependence in the hydrolysis was sigmoidalwith a transition at pH 4.5, which was identical with the experimentallydetermined pK_a of Glu35 in the covalent adduct, indicating thatGlu35 functions as a general base to hydrolyze the adduct. Toimprove the turnover rate of D52E lysozyme, the mutation ofN46D was designed and introduced to D52E lysozyme. This mutationreduced the activation energy in the hydrolysis reaction ofthe covalent adduct by 1.8 kcal/mol at pH 5.0 and 40°C butdid not affect the formation reaction. Our data may providea useful approach to understanding the precise mechanism ofthe function of natural glycosidases, which catalyze via a covalentadduct.     

Contribution of a salt bridge to binding affinity and dUMP orientation to catalytic rate: mutation of a substrate-binding arginine in thymidylate synthase

Invariant arginine 179, one of four arginines that are conservedin all thymidylate synthases (TS) and that bind the phosphatemoiety of the substrate 2'-deoxyuridine-5'-monophosphate (dUMP),can be altered even to a negatively charged glutainic acid withlittle effect on k_cat. In the mutant structures, ordered wateror the other phosphate binding arginines compensate for thehydrogen bonds made by Arg179 in the wild-type enzyme and thereis almost no change in the conformation or binding site of dUMP.Correlation of dUMP K_ds for TS R179A and TS R179K with the structuresof their binary complexes shows that the positive charge onArg179 contributes significantly to dUMP binding affinity. k_cat/Kmfor dUMP measures the rate of dUMP binding to TS during theordered bi-substrate reaction, and in the ternary complex dUMPprovides a binding surface for the cofactor. k_cat/Km reflectsthe ability of the enzyme to accept a properly oriented dUMPfor catalysis and is less sensitive than is K_d to the changesin electrostatics at the phosphate binding site.     

Removal of an inter-domain hydrogen bond through site-directed mutagenesis: role of serine 176 in the mechanism of papain

A mutant of papain, where an inter-domain hydrogen bond betweenthe side chain hydroxyl group of a serine residue at position176 and the side chain carbonyl oxygen of a glutamine residueat position 19 has been removed by site-directed mutagenesis,has been produced and characterized kinetically. The mutationof Ser176 to an alanine has only a small effect on the kineticparameters, the k_cat/K_m for hydrolysis of CBZ-Phe-Arg-MCA bythe Serl76Ala enzyme being of 8.1 x 10⁴ /M/s compared with 1.2x 10⁵ /M/s for papain. Serine 176 is therefore not essentialfor the catalytic functioning of papain, even though this residueis conserved in all cysteine proteases sequenced. The pH-activityprofiles were shown to be narrower in the mutant enzyme by upto 1 pH unit at high ionic strength. This result is interpretedto indicate that replacing Ser 176 by an alanine destabilizesthe thiolate—imidazolium form of the catalytic site Cys25-Hisl59residues of papain. Possible explanations for that effect aregiven and the role of a serine residue at position 176 in papainis discussed.     

Redesign of the substrate specificity of human cathepsin D: the dominant role of position 287 in the S2 subsite

Interest in the active site specificity of human cathepsin Dstems from the search for specific therapeutic agents againstmany of the sequentially and structurally homologous membersofthe aspartic proteinase family. The work presented here examinedone amino acid in the cathepsin D sequence, located in the S₂subsite, which contributes substantially to the specificityof enzyme-Ugand interactions at the enzyme active site. Previousstudies reported on the specificity of binding and catalysisby native and recombinant human cathepsin D explored throughkinetic studies using a systematic series of synthetic substrates.Utilizing a rulebased molecular model of human cathepsin D,Met287 was suggested as a candidate for mutagenesis to furtherexplore selectivity within the S₂ subsite of the cathepsin Dactive site. Met287 mutant derivatives of human cathepsin Dwere designed, expressed and characterized in kineticstudies.Native cathepsin D accommodates large hydrophobic residues inthe P₂ position of a substrate; positively charged residuesin P₂ are not favorable for catalysis.It was demonstrated thataltering Met287 of human cathepsin D to more polar amino acidsproduced active mutant enzymes with significantly altered substratespecificity.     

Function of the fully conserved residues Asp99, Tyr52 and Tyr73 in phospholipase A2

In the active centre of pancreatic phospholipase A₂ His48 isat hydrogen-bonding distance to Asp99. This Asp-His couple isassumed to act together with a water molecule as a catalytictriad. Asp99 is also linked via an extended hydrogen bondingsystem to the side chains of Tyr52 and Tyr73. To probe the functionof the fully conserved Asp99, Tyr52 and Tyr73 residues in phospholipaseA₂, the Asp99 residue was replaced by Asn, and each of the twotyrosines was separately replaced by either a Phe or a Gln.The catalytic and binding properties of the Phe52 and Phe73mutants did not change significantly relative to the wild-typeenzyme. This rules out the possibility that either one of thetwo Tyr residues in the wild-type enzyme can function as anacyl acceptor or proton donor in catalysis. The Gln73 mutantcould not be obtained in any significant amounts probably dueto incorrect folding. The Gln52 mutant was isolated in low yield.This mutant showed a large decrease in catalytic activity whileits substrate binding was nearly unchanged. The results suggesta structural role rather than a catalytic function of Tyr52and Tyr73. Substitution of asparagine for aspartate hardly affectsthe binding constants for both monomeric and micellar substrateanalogues. Kinetic characterization revealed that the Asn99mutant has retained no less than 65% of its enzymatic activityon the monomeric substrate rac 1,2-dihexanoyldithio-propyl-3-phosphocholine,probably due to the fact that during hydrolysis of monomericsubstrate by phospholipase A₂ proton transfer is not the rate-limitingstep. The Asp to Asn substitution decreases the catalytic rateon micellar 1,2-dioctanoyl-sn-glycero-3-phosphocholine 25-fold.To explain this remaining activity we suggest that in the mutantthe Asn99 orients His48 in the same way as Asp99 orients His48in native phospholipase A₂ and that the lowered activity iscaused by a reduced stabilization of the transition state.     

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.