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.     

Biased random mutagenesis of peptides: determination of mutation frequency by computer simulation

Cassette mutagenesis is a method of protein engineering whichgenerates a wide diversity of genetic variants that can be subjectedto either selection or screening. As long as the target sequenceto be modified is kept short (corresponding to four to six aminoacids), complete combinatorial libraries can be produced. Amajor problem arises when longer peptides are to be engineeredfor desired functions. In such situations the production ofa limited collection of variants can be helpful; thus, biasedrandom mutagenesis and ‘doping schemes’ have beenreported previously. Here we describe a computer algorithm thatenables the determination of the degree of phosphoramidite contaminationof nucleotide precursor reservoirs. Through simulation of biologicaltranslation, the algorithm allows the prediction of the effectof contamination levels on the number of mutations to occurfor any given peptide sequence. In this study the cholinergicbinding site was used as a model sequence (22 amino acids).Considerations, based on the computer program, are discussedregarding the efficient design of phage-display combinatoriallibraries.     

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.     

Probing the substrate specificity of the intracellular brain platelet-activating factor acetylhydrolase

Platelet-activating factor acetylhydrolases (PAF-AHs) are uniquePLA2s which hydrolyze the sn-2 ester linkage in PAF-like phospholipidswith a marked preference for very short acyl chains, typicallyacetyl. The recent solution of the crystal structure of the₁ catalytic subunit of isoform Ib of bovine brain intracellularPAF-AH at 1.7 Å resolution paved the way for a detailedexamination of the molecular basis of substrate specificityin this enzyme. The crystal structure suggests that the sidechains of Thr103, Leu48 and Leu194 are involved in substraterecognition. Three single site mutants (L48A, T103S and L194A)were overexpressed and their structures were solved to 2.3 Åresolution or better by X-ray diffraction methods. Enzyme kineticsshowed that, compared with wild-type protein, all three mutantshave higher relative activity against phospholipids with sn-2acyl chains longer than an acetyl. However, for each of themutants we observed an unexpected and substantial reductionin the V_max of the reaction. These results are consistent withthe model in which residues Leu48, Thr103 and Leu194 indeedcontribute to substrate specificity and in addition suggestthat the integrity of the specificity pocket is critical forthe expression of full catalytic function, thus conferring veryhigh substrate selectivity on the enzyme.     

Thermosensitive mutants of Aspergillus awamori glucoamylase by random mutagenesis: inactivation kinetics and structural interpretation

Abstract Seven thermosensitive glucoamylase mutants generated by randommutagenesis and expressed inSaccharomyces cerevisiae were sequencedand their inactivation kinetics were determined. Wild-type glucoamylaseexpressed in S.cerevisiae was more glycosylated and more stablethan the native Aspergillus niger enzyme. All mutants had lowerfree energies of inactivation than wild-type glucoamylase. Inthe Ala39 Val, Ala302 Val and Leu410 Phe mutants, small hydrophobicresidues were replaced by larger ones, showing that increasesin size and hydrophobicity of residues included in hydrophobicclusters were destabilizing. The Gly396 Ser and Gly407 Aspmutants had very flexible residues replaced by more rigid ones,and this probably induced changes in the backbone conformationthat destabilized the protein. The Prol28 Ser mutation changeda rigid residue in an a-helix to a more flexible one, and destabilizedthe protein by increasing the entropy of the unfolded state.The Ala residue in the Ala442 Thr mutation is in the highlyO-glycosylated region surrounded by hydrophilk residues, whereitmay be a hydrophobic anchor Unking the O-glycosylated arm tothe catalytic core. It was replaced by a residue that potentiallyis O-glycosylated. In five of the seven mutations, residuesthat were part of hydrophobic microdomains were changed, confirmingthe importance of the latter in protein stability and structure     

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.     

Study of antibody-antigen interaction through site-directed mutagenesis of the VH region of a hybrid phage-antibody fragment

An important aspect of the study of antibody structure–functionrelationships involves analysis of natural or synthetic mutationsof antigen-combining sites. The anti-hen egg lysozyme monoclonalantibody HyHEL-10 has been a focus for antibody structure–functionstudies. We have displayed on bacteriophage of a hybrid singlechain Fv, containing the light chain variable region of HyHEL-10and the heavy chain variable region of a structurally relatedbut functionally distinct antibody, AS32. By using a combinationof site-directed mutagenesis, complementary determining regiongrafting and molecular modeling, we have identified a numberof contact and non-contact residues that are important in theaffinity of HyHEL-10 for lysozyme. In particular, the heavychain variable region framework residue at position 94 was shownto be an important determinant of high-affinity binding. Thephage display approach eliminates the need for purificationof antibodies and, when used in combination with polymerasechain reaction for variable region sequence mutagenesis, facilitatesthe rapid generation and characterization of mutant antibodies.     

Effects of introduced aspartic and glutamic acid residues on the Pi substrate specificity, pH dependence and stability of carboxypeptidase Y

Carboxypeptidase Y is a serine carboxypeptidase isolated fromSaccharomyces cerevisiae with a preference for Cterminal hydrophobicamino acid residues. In order to alter the inherent substratespecificity of CPD-Y into one for basic amino acid residuesin P'₁, we have introduced Asp and/or Glu residues at a numberof selected positions within the Si binding site. Hie effectsof these substitutions on the substrate specificity, pH dependenceand protein stability have been evaluated. The results presentedhere demonstrate that it is possible to obtain significant changesin the substrate preference by introducing charged amino acidsinto the framework provided by an enzyme with a quite differentspecificity. The introduced acidic amino acid residues providea marked pH dependence of the (k_{cat/Km)FA-A-R-OH/(kcatm})_FA-A-R-OHratio. The change in stability upon introduction of Asp/Gluresidues can be correlated to the difference in the mean buriedsurfac surface area between the substituted and the substitutingamino acid. Thus, the effects of acidic amino acid residueson the protein stability depend upon whether the introducedamino acid protrudes from the solvent accessible surface asdefined by the surrounding residues in the wild type enzymeor is submerged below.     

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.     

Alteration of the amino acid substrate specificity of clostridial glutamate dehydrogenase by site-directed mutagenesis of an active-site lysine residue

Two residues, K89 and S380, thought to interact with the -carboxylgroup of the substrate L-glutamate, have been altered by site-directedmutagenesis of clostridial glutamate dehydrogenase (GDH). Thesingle mutants K89L and S380V and the combined double mutantK89L/S380V were constructed. All three mutants were satisfactorilyoverproduced in soluble form. However, only the K89L mutantwas retained by the dye column normally used in purifying thewild-type enzyme. All three mutant enzymes were purified tohomogeneity and tested for substrate specificity with 24 aminoacids. The single mutant S380V showed no detectable activity.The alternative single mutant K89L showed an activity towardsL-glutamate that was decreased nearly 2000-fold compared withwild-type enzyme, whereas the activities towards the monocarboxylicsubstrates -aminobutyrate and norvaline were increased 2- to3-fold. A similar level of activity was obtained with methionine(0.005 U/mg) and norleucine (0.012 U/mg), neither of which giveany activity with the wild-type enzyme under the same conditions.The double mutant showed decreased activity with all substratescompared with the wild-type GDH. In view of its novel activities,the K89L mutant was investigated in greater detail. A strictlylinear relationship between reaction velocity and substrateconcentration was observed up to 80 mM L-methionine and 200mM L-norleucine, implying very high K_m values. Values of k_cat/K_m,for L-methionine and L-norleucine were 6.7x10^–2 and 0.15s^–1M^–1, respectively. Measurements with dithiobisnitrobenzoicacid showed that the mutant enzymes all reacted with a stoichiometryof one -SH group per subunit and all showed protection by coenzyme,indicating essentially unimpaired coenzyme binding. With glutamateor 2-oxoglutarate as substrate the K_m values for the vestigialactivity in the mutant enzyme preparations were strikingly closeto the wild-type K_m values. Both for wild-type GDH and K89L,L-glutamate gave competitive product inhibition of 2-oxoglutaratereduction but did not inhibit the reduction of 2-oxocaproatecatalysed by K89L enzyme. This suggests that the low levelsof glutamate/2-oxoglutarate activity shown by the mutant enzymeare due to trace contamination. Since stringent precautionswere taken, it appears possible that this reflects the levelof reading error during overexpression of the mutant proteins.CD measurements indicate that the S380V mutant has an alteredconformation, whereas the K89L enzyme gave an identical CD spectrumto that of wild-type GDH; the spectrum of the double mutantwas similar, although somewhat altered in intensity. The resultsconfirm the key role of K89 in dicarboxylate recognition byGDH.     

Replacing the glutamate ligand in the structural zinc site of Sulfolobus solfataricus alcohol dehydrogenase with a cysteine decreases thermostability

The alcohol dehydrogenase gene from the thermophilic archaeumSulfolobus solfataricus has been subcloned and expressed inEscherichia coli under the control of the T7 inducible promoter.Therecombinant protein shows properties analogous to those of thenative enzyme, including thermostability, despite the fact thatE.coli does not post-translationally modify two lysine residueswhich are N--methylated in the native enzyme. We constructeda 3-D model of the S.solfataricus alcohol dehydrogenase usingthe known structure of its isozyme from horse liver as a template.Our analysis of the structural zinc binding site suggested thatthis site is present andfunctional in the S.solfataricus enzymeand that a glutamate ligand can contribute to thermostabilityby influencing electrostatic interactions around the metal centre.To investigate thishypothesis, we constructed, expressed andcharacterized a mutant where the glutamate is replaced by acysteine, thus restoring the zinc binding site of mesophilicalcohol dehydrogenases. Themutant shows the same activity buta reduced thermostability with respect to the wild-type recombinantprotein, as suggested by our model.     

Altering the association properties of insulin by amino acid replacement

The importance of Pro^B28 and Lys^B29 on the self-associationof insulin was established by systematically truncating theC terminus of the B chain. The relationship between structureand association was further explored by making numerous aminoacid replacements at B²⁸ and B²⁹ Association was studied bycircular dichroism, size-exclusion chromatography and ultracentrifugation.Our results show that the location of a prolyl residue at B²⁸is critical for high-affinity self-association. Removal of Pro^B28in a series of C-terminal truncated insulins, or amino acidreplacement of Pro²⁸, greatly reduced association. The largestdisruption to association was achieved by replacing Lys^B29 withPro and varying the amino acid at B²⁸ Several of the analogswere predominantly monomers in solutions up to 3 mg/ml. Theseamino acid substitutions decreased association by primarilydisrupting the formation of dimers. Such amino acid substitutionsalso substantially reduced the Zn-induced insulin hexamer formation.The formation of monomeric insulins through amino acid replacementswas accompanied by conformational changes that may be the causefor decreased association. It is demonstrated that self-associationof insulin can be drastically altered by substitution of oneor two key amino acids.     

Activity of linked HIV-1 proteinase dimers containing mutations in the active site region

Mutations were introduced into the active site triplet (Asp–Thr–Gly)of one or both subunits of a linked dimer of human immunodeficiencyvirus type 1 proteinase. Mutation of Thr to Ser in one or bothsubunits did not alter the activity of the enzyme substantially,whereas its mutation to Asn in one subunit caused a dramaticdecrease in catalytic efficiency. Mutation of Gly to Val inone subunit also yielded an enzyme with very low activity. Theenzymes containing Thr Asn and Gly Val mutations in both subunitsresulted in inactive enzymes, based on their inability to self-processand on assay with an oligopeptide substrate. The dramatic decreasein enzyme efficiency of the mutants was interpreted using molecularmodels of the enzymes.     

X-ray structures of two single-residue mutants of DNase I: H134Q and Y76A

The structures of the single-residue mutants H134Q and Y76Aof bovine pancreatic DNase I have been determined and refinedincluding data to 2.3 and 2.4 Å resolution respectively,by X-ray crystallography. H134 is an essential catalytic residue,while Y76 contributes to the binding of DNA by providing a largevan der Waals contact area that stabilizes the wide minor grooveseen in DNase I-DNA complexes. The mutant proteins, which showstrongly reduced activities of 0.001% (H134Q) and 0.3% (Y76A),were expressed in E.coli and both crystallize in space-groupC2 with almost identical unit cells. The crystal packing schemeis different from that found in wild type crystals grown undervery similar conditions, presumably due to the absence of thecarbohydrate moiety. In both mutants the conformation of theprotein is nearly identical to that of the wild type enzymeand changes are confined to surface loops involved in packing.The disruption of the hydrogen bonds between H134, E78 and Y76in both mutants leads to an increased mobility and positionalshifts in the DNA-binding loop, mainly around residue Y76. Thisin turn may further reduce DNA-binding affinity and, thus, contributeto the low activity. In contrast, symmetry contacts involvingresidues 97–108 lead to a stabilization of the flexibleloop compared to wild type DNase I.     

Consensus guided mutagenesis of Renilla luciferase yields enhanced stability and light output

Luciferases, which have seen expansive employment as reporter genes in biological research, could also be used in applications where the protein itself is conjugated to ligands to create probes that are appropriate for use in small animal imaging. As the bioluminescence activity of commonly used luciferases is too labile in serum to permit this application, specific mutations of Renilla luciferase, selected using a consensus sequence driven strategy, were screened for their ability to confer stability of activity in serum as well as their light output. Using this information, a total of eight favorable mutations were combined to generate a mutant Renilla luciferase (RLuc8) that, compared with the parental enzyme, is 200-fold more resistant to inactivation in murine serum and exhibits a 4-fold improvement in light output. Results of the mutational analysis were also used to generate a double mutant optimized for use as a reporter gene. The double mutant had half the resistance to inactivation in serum of the native enzyme while yielding a 5-fold improvement in light output. These variants of Renilla luciferase, which exhibit significantly improved properties compared with the native enzyme, will allow enhanced sensitivity in existing luciferase-based assays as well as enable the development of novel probes labeled with the luciferase protein.     

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.     

Construction of stabilized proteins by combinatorial consensus mutagenesis

We constructed stabilized variants of beta-lactamase (BLA) from Enterobacter cloacae by combinatorial recruitment of consensus mutations. By aligning the sequences of 38 BLA homologs, we identified 29 positions where the E.cloacae gene differs from the consensus sequence of lactamases and constructed combinatorial libraries using mixtures of mutagenic oligonucleotides encompassing all 29 positions. Screening of 90 random isolates from these libraries identified 15 variants with significantly increased thermostability. The stability of these isolates suggest that all tested mutations make additive contributions to protein stability. A statistical analysis of sequence and stability data identified 11 mutations that made stabilizing contributions and eight mutations that destabilized the protein. A second-generation library recombining these 11 stabilizing mutations led to the identification of BLA variants that showed further stabilization. The most stable variant had a mid-point of thermal denaturation (Tm) that was 9.1 degrees C higher than the starting molecule and contained eight consensus mutations. Incubation of three stabilized BLA variants with several proteases showed that all tested isolates have significantly increased resistance to proteolysis. Our data demonstrate that combinatorial consensus mutagenesis (CCM) allows the rapid generation of protein variants with improved thermal and proteolytic stability.     

Alteration of catalytic properties of chymosin by site-directed mutagenesis

Artificial mutations of chymosin by recombinant DNA techniqueswere generated to analyze the structure–function relationshipin this characteristic aspartk proteinase. In order to preparethe mutant enzymes in their active form, we established proceduresfor purification of correctly refolded prochymosin from inclusionbodies produced in Escherichia coli transformants and for itssubsequent activation. Mutagenesis by linker insertion intocDNA produced several mutants with an altered ratio of milkclotting activity to proteolytic activity and a different extentof stability. In addition to these mutants, several mutantswith a single amino acid exchange were also constructed by site-directedmutagenesis and kinetic parameters of these mutant enzymes weredetermined by using synthetic hexa- and octa-peptides as substrates.Exchange of Tyr75 on the flap of the enzyme to Phe caused amarked change of substrate specificity due to the change ofk_cat or K_m, depending on the substrate used. Exchange of Val110and Phe111 also caused a change of kinetic parameters, whichindicates functional involvement of these hydrophobic residuesin both the catalytic function and substrate binding. The mutantLys220–Leu showed a marked shift of the optimum pH tothe acidic side for hydrolysis of acid-denatured haemoglobinalong with a distinct increase in k_cat for the octa-peptidein a wide pH range.     

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.     

Site-directed mutagenesis of aspartic acid 372 at the ATP binding site of yeast phosphoglycerate kinase: over-expression and characterization of the mutant enzyme

A new phosphoglycerate kinase over-expression vector, pYE-PGK,has been constructed which greatly facilitates the insertionand removal of mutant enzyme genes by cleavage at newly introducedBamtHI sites. This vector has been used to prepare mutant proteinin appreciable (100 mg) quantities for use in kinetic, crystaUographicand NMR experiments. Aspartate 372 is an invariant amino acidresidue in genes known to code for a functionally active PGK.The function of this acidic residue appears to be to help desolvatethe magnesium ion compfexed with either ADP or ATP when thissubstrate binds to the enzyme. Both crystallographk and nuclearmagnetic resonance experiments show that the replacement ofthe residue with asparagine has only minimal effects on theoverall structure. The substitution of the charged carboxylgroup with that of the neutral amide affects the binding ofthe nucleotide substrate as predicted but not, as might havebeen expected, the binding of 3-phospho-glycerate. The overallvelocity of the enzymic reaction (V_max) is reduced 10-fold bythe substitution of aspartic acid 372 by an asparagine residue(D372N). This reduction in V_max is considerably less than onewould expect from its known position within the structure ofthe enzyme. This result therefore poses questions about ourunderstanding of charged groups at the active centres of enzymesand of the reason for their apparent conservation.