Effects of non-conservative changes to tyrosine 76, a key DNA binding residue of DNase I, on phosphodiester bond cleavage and DNA hydrolysis selectivity

Non-conservative changes, consisting of Y76E, Y76L, Y76Q and Y76W, have been made to tyrosine 76, one of the key DNA binding residues in DNase I. Normally Y76 inserts into the minor groove of DNA and makes an unusual, hydrophobic, stacking interaction with one of the sugars. All four mutants bind to DNA more tightly than the wild type, but cut it more slowly as assessed by Kunitz assays. This gives a rather small decrease in the specificity constants (Vmax/K(m)) for the hydrolysis of DNA, which is roughly paralleled by the loss of activity towards the non-DNA small chromophoric substrate, thymidine-3',5'-di(p- nitrophenyl)phosphate. These non-conservative mutants, therefore, show different behaviour to Y76A and Y76G, studied previously [Doherty A.J., Worrall A.F. and Connolly B.A. (1995) J: Mol. Biol., 251, 366-377]. These two mutants both bind to and cut DNA poorly, resulting in large decreases in Vmax/K(m) values. However, they showed little reduction in rates with the chromophoric substrate. It is likely that the altered side chains in the non-conservative mutants are still able to interact productively with the DNA and contribute to the observed DNA distortion that is essential for efficient catalysis. However, these mutations disrupt the active site, most probably by interference with the hydrogen bonded Y76-E78-H134 triad. H134 is a critical hydrolytic residue of DNase I that is essential for catalysis. The DNA cleavage selectivity of the Y76E, Y76L, Y76Q and Y76W mutants were little altered as compared with the wild-type enzyme as measured using the cutting patterns of a 160 base-pair Escherichia coli Tyr T promoter DNA fragment. This confirms earlier observations, with Y76F, Y76A and Y76G, that showed that this tyrosine has little role in DNA cleavage specificity.      

Proposal for new catalytic roles for two invariant residues in Escherichia coli ribonuclease HI

Three mutants of Escherichia coli ribonuclease HI, in whichan invariant acidic residue Asp134 was replaced, were crystallized,and their three-dimensional structures were determined by X-raycrystallography. The D134A mutant is completely inactive, whereasthe other two mutants, D134H and D134N, retain 59 and 90% activitiesrelative to the wild-type, respectively. The overall structuresof these three mutant proteins are identical with that of thewild-type enzyme, except for local conformational changes ofthe flexible loops. The ribonuclease H family has a common activesite, which is composed of four invariant acidic residues (Asp10,G1u48, Asp70 and Asp134 in E.coli ribonuclease HI), and theirrelative positions in the mutants, even including the side-chainatoms, are almost the same as those in the wild-type. The positionsof the -polar atoms at residue 134 in the wild-type, as wellas D134H and D134N, coincide well with each other. They arelocated near the imidazole side chain of His124, which is assumedto participate in the catalytic reaction, in addition to thefour invariant acidic residues. Combined with the pH profilesof the enzymatic activities of the two other mutants, H124Aand H124A/D134N, the crystallographic results allow us to proposea new catalytic mechanism of ribonuclease H, which includesthe roles for Asp134 and His124.     

pH-sensitive interactions between IgG and a mutated IgG-binding protein based upon two B domains of Protein A from Staphylococcus aureus

A fusion protein, consisting of the N-terminal 81 amino acidsfrom an inactive bovine DNase I (Q38,E39–E38,Q39) andtwo sequential synthetic IgG-binding domains based upon domainB of Protein A from Staphylococcus aureus has been shown tobind to porcine IgG with a similar affinity and pH profile toProtein A. The same residue in each B domain (Tyr111 and Tyr169)has been mutated by cassette mutagenesis to Ser, Glu, His, Lysor Arg and the effect of the mutation on binding interactionswith porcine IgG investigated. The evidence presented suggeststhat the interactions at the B domain are highly sensitive tothe presence of a charged residue.     

Double-site ricin B chain mutants retain galactose binding

Three distinct double-site and two single-site ricin B chain(RTB) mutants were expressed in Spodoptera frugiperda insectcells and purified from infected cell supernatants. The yieldsof recombinant proteins were 0.01–0.2 mg/1. The purityafter monoclonal antibody affinity chromatography was 1–20%.The mutant proteins were soluble, immuno-reactive with monoclonalantibodies and polyclonal antibodies to RTB and demonstratedmolecular weights of 32 kDa, similar to plant RTB. All threedouble-site and both single-site mutants bound asialofetuinand mammalian cell surfaces based on an asialofetuin ELISA andcell binding immunofluorescence assay. While one double-sitemutant, W37S/Y248S, had a 1 log drop in sugar binding, the othertwo double-site mutants W37S/Y248H and D22E/D234E had 2 logreductions in sugar binding. Each mutant reassociated efficiently(25–75%) with plant ricin A chain (RTA) to form cytotoxicheterodimers. The concentration of protein required to reduceprotein synthesis 50% (ID₅₀) was 1 log higher than plant ricinfor W37S/Y248S-RTA and the single-site mutant heterodimers,Q35N-RTA and D22E-RTA and 2 logs higher than plant ricin forthe other two double-site mutant heterodimers. The results suggestamino acid residues in both the 1 and 2 subdomains of RTB participatein sugar binding. However, other subdomains must contributeto the avidity of ricin for cell surface oligosaccharides.     

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.     

Analysis of RNA phage fr coat protein assembly by insertion, deletion and substitution mutagenesis

A structure-function analysis of the icosahedral RNA bacteriophagefr coat protein (CP) assembly was undertaken using linker-insertion,deletion and substitution mutagenesis. Mutations were specificallyintroduced into either pre-existing or artificially createdrestriction enzyme sites within fr CP gene expressed in Escherichiacoli from a recombinant plasmid. This directs synthesis of wildtype protein that undergoes self-assembly and forms capsid-likeparticles indistinguishable morphologically and immunologicallyfrom native phage particles. A series of fr CP variants containingsequence alterations in the regions which are (i) exposed onthe external surface of capsid or (ii) located on the contactingareas between CP subunits were obtained and their assembly propertiesinvestigated. The majority of mutants demonstrated reductionof assembly ability and formed either CP dimers (mutations atresidues 2, 10, 63 or 129) or both dimer and capsid structures(residue 2 or 69). The exceptions were variants demonstratingnormal assembly and containing insertions at residues 2, 50or 129 of thefr CP. A third type of assembled structure wasformed by a variant with a single amino acid substitution I104T.The aA-helix region (residues 97-111) is particularly sensitiveto mutation and any alteration in this region decreases accumulationof mutant protein in E.coli. The relative contributions of particularfr CP domains in maintenance of capsid structural integrityas well as the possible capsid assembly mechanism are discussed.     

Altering substrate preference of carboxypeptidase Y by a novel strategy of mutagenesis eliminating wild type background

To change the substrate preference of carboxypeptidase Y theputative substrate binding pocket was subjected to random mutagenesis.Based upon the three-dimensional structure of a homologous enzymefrom wheat, we hypothesized that Tyr147, Leu178, Glu215, Arg216,Ile340 and Cys341 are the amino acid residues of carboxypeptidaseY that constitute S₁ the binding pocket for the penultimateamino acid side chain of the substrate. We developed a new andgenerally applicable mutagenesis strategy to facilitate efficientscreening of a large number of mutants with multiple changesin carboxypeptidase Y. The key feature is the elimination ofwild type background by introducing a nonsense codon at eachtarget site for subsequent mutagenesis by degenerate oligonucleotides.The entire hypothesized S₁ binding pocket and subsets of itwere subjected to saturation mutagenesis by this strategy, andscreening yielded a number of mutant enzymes which have up to150 times more activity (k_cat/K_m towards CBZ-LysLeu-OH thanthe wild type enzyme. All selected mutants with increased activityhave mutations at position 178. Mutagenesis of positions 215and 216 has virtually no effect on the activity, while mutatingpositions 340 and 341 generally reduces activity.     

Characterization of active-site aromatic residues in xylanase A from Streptomyces lividans

The role of four aromatic residues (W85, Y172, W266 and W274)in the structure–function relationship in xylanase A fromStreptomyces lividans (XlnA) was investigated by site-directedmutagenesis where each residue was subjected to three substitutions(W85A/H/F; W266A/H/F; W274A/H/F and Y172A/F/S). These four aminoacids are highly conserved among family 10 xylanases and structuraldata have implicated them in substrate binding at the activesite. Far-UV circular dichroism spectroscopy was used to showthat the overall structure of XlnA was not affected by any ofthese mutations. High-performance liquid chromatographic analysisof the hydrolysis products of birchwood xylan and xylopentaoseshowed that mutation of these aromatic residues did not alterthe enzyme's mode of action. As expected, though, it did reducethe affinity of XlnA for birchwood xylan. A comparison of thekinetic parameters of different mutants at the same positiondemonstrated the importance of the aromatic nature of W85, Y172and W274 in substrate binding. Replacement of these residuesby a phenylalanine resulted in mutant proteins with a K_M closerto that of the wild-type protein in comparison with the othermutations analyzed. The kinetic analysis of the mutant proteinsat position W266 indicated that this amino acid is importantfor both substrate binding and efficient catalysis by XlnA.These studies also demonstrated the crucial role of these activesite aromatic residues for the thermal stability of XlnA.     

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.     

Identification of interaction site of pseudoazurin with its redox partner, copper-containing nitrite reductase from Alcaligenes faecalis S-6

Pseudoazurin, a low molecular weight protein containing a singletype I copper, functions as an electron donor to a copper-containingnitrite reductase (NIR) in a denitrifying bacterium Alcaligenesfaecalis S-6. To elucidate the proteinprotein interaction betweenthese two copper-containing proteins, each of nine out of 13lysine residues on the surface of pseudoazurin were independentlyreplaced by alanine or aspartate, and the effects of the mutationson the interaction with NIR, as well as the physicochemicalproperties of pseudoazurin, were analyzed. All of the mutatedpseudoazurins showed optical spectra and oxidation-reductionpotentials almost identical to those of wildtype pseudoazurin,suggesting that none of the replacements of these lysine residuesaffected the environment around the type I copper site. Kineticanalysis of electron transfer between mutated pseudoazurinsand NIR reveals that the lysine mutations have very little effecton the rate of electron transfer to NIR, but substitution atresidues 10, 38, 57 and 77, all close to the copper site, substantiallydecreases the affinity of pseudoazurin for NIR. This suggeststhat pseudoazurin interacts with NIR through the region closeto the type I copper site. The refined X-ray structures of Lys38Aspand Lys10Asp/Lys38Asp show that the molecular structure hasindeed changed little. A new space group is observed for theLys109Ala mutant crystal. Crystal packing interactions changefor the Lys10Asp/Lys38Asp mutant but remain the same for Lys38Aspand Lys59Ala mutants.     

Site-directed mutagenesis of a calcium binding site modifies specifically the different biochemical properties of annexin I

All the functions of annexins in vitro as well as in vivo aremediated and probably regulated by calcium. We have used recombinantannexin I, synthesized by Escherichia coli, and we have performedsite-directed mutagenesis. We have mutated the endonexin foldof domain 2 that binds calcium. Mutations were performed inthis domain of the molecule because it perfectly matches thecalcium binding consensus sequence. The two glycines of thisfold were mutated into glutamic acid. The helix content andthe stability of the mutants are identical to those of the wild-type,suggesting that the mutations did not drastically affect thestructure of the protein. The two mutants showed modified calciumbinding affinities. However, the calcium binding affinity ofthe G131E mutant was far more altered than that of the G129Emutant. Furthermore, other biochemical properties of these mutantswere modified to different extents. The binding to phospholipidwas not seriously affected, whereas the selfassociation waslost by the G131E mutant. In the same way, liposome aggregationis conserved, but modified, while the calcium affinity measuredby equilibrium dialysis is dramatically altered.     

The structural basis for the altered substrate specificity of the R292D active site mutant of aspartate aminotransferase from E.coli

Two refined crystal structures of aspartate aminotransferasefrom E.coli are reported. The wild type enzyme is in the pyridoxalphosphate (PLP) form and its structure has been determined to2.4 Å resolution, refined to an R-factor of 23.2%. Thestructure of the Arg292Asp mutant has been determined at 2.8Å resolution, refined to an R–factor of 20.3%. Thewild type and mutant crystals are isomorphous and the two structuresare very similar, with only minor changes in positions of importantactive site residues. As residue Arg292 is primarily responsiblefor the substrate charge specificity in the wild type enzyme,the mutant containing a charge reversal at this position mightbe expected to catalyze transamination of arginine as efficientlyas the wild type enzyme effects transamination of aspartate[Cronin,C.N. and Kirsch,J.F. (1988) Biochemistry, 27, 4572–4579].This mutant does in fact prefer arginine over aspartate as asubstrate, however, the rate of catalysis is much slower thanthat of the wild type enzyme with its physiological substrate,aspartate. A comparison of these two structures indicates thatthe poorer catalytic efficiency of R292D, when presented witharginine, is not due to a gross conformational difference, butis rather a consequence of both small side chain and main chainreorientations and the pre–existing active site polarenvironment, which greatly favors the wild type ion pair interaction.     

Directed evolution converts subtilisin E into a functional equivalent of thermitase

We used directed evolution to convert Bacillus subtilis subtilisinE into an enzyme functionally equivalent to its thermophilichomolog thermitase from Thermoactinomyces vulgaris. Five generationsof random mutagenesis, recombination and screening created subtilisinE 5-3H5, whose half-life at 83°C (3.5 min) and temperatureoptimum for activity (T_opt, 76°C) are identical with thoseof thermitase. The T_opt of the evolved enzyme is 17°C higherand its half-life at 65°C is >200 times that of wild-typesubtilisin E. In addition, 5-3H5 is more active towards thehydrolysis of succinyl-Ala-Ala-Pro-Phe-p-nitroanilide than wild-typeat all temperatures from 10 to 90°C. Thermitase differsfrom subtilisin E at 157 amino acid positions. However, onlyeight amino acid substitutions were sufficient to convert subtilisinE into an enzyme equally thermostable. The eight substitutions,which include known stabilizing mutations (N218S, N76D) andalso several not previously reported, are distributed over thesurface of the enzyme. Only two (N218S, N181D) are found inthermitase. Directed evolution provides a powerful tool to unveilmechanisms of thermal adaptation and is an effective and efficientapproach to increasing thermostability without compromisingenzyme activity.     

Effects of engineered salt bridges on the stability of subtilisin BPN'

Variants designed using PROTEUS have been produced in an attemptto engineer stabilizing salt bridges into subtilisin BPN'. Allthe mutants constructed by site-directed mutagenesis were secretedby Bacillus subtillus, except L75K. Q19E, expressed as a singlevariant and also in a double variant, Q19E/Q271E, appears toform a stabilizing salt bridge based on X-ray crystal structuredetermination and differential scanning calorimeter measurements.Although the double mutant was found to be less thermodynamicallystable than the wild-type, it did exhibit an autolytic stabilityabout two fold greater under hydrophobic conditions. Four variants,A98K, S89E, V26R and L235R, were found to be nearly identicalto wild-type in thermal stability, indicative of stable structureswithout evidence of salt bridge formation. Variants Q271E, V51Kand T164R led to structures that resulted in varying degreesof thermodynamic and autolytic instability. A computer-modelinganalysis of the PROTEUS predictions reveals that the low percentageof salt bridge formation is probably due to an overly simplisticelectrostatic model, which does not account for the geometryof the pairwise interactions.     

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.     

Multiple interactions of lysine-128 of Escherichia coli glutamate dehydrogenase revealed by site-directed mutagenesis studies

A highly conserved lysine at position 128 of Escherichia coliglutamate dehydrogenase (GDH) has been altered by sitedirectedmutagenesis of the gdhA gene. Chemical modification studieshave previously shown the importance of this residue for catalyticactivity. We report the properties of mutants in which lysine-128has been changed to histidine (K128H) or arginine (K128R). Bothmutants have substantially reduced catalytic centre activitiesand raised pH optima for activity. K128H also has increasedrelative activity with amino acid substrates other than glutamate,especially L-norvaline. These differences, together with alterationsin K_m values, K_d values for NADPH and K₁ values for D-glutamate,imply that lysine-128 is intimately involved in either director indirect interactions with all the substrates and also incatalysis. These multiple interactions of lysine-128 explainthe diverse effects of chemical modifications of the correspondinglysine in homologous GDHs. In contrast, lysine-27, another highlyreactive residue in bovine GDH, is not conserved in all of thesequenced NADP-specific GDHs and is therefore not likely tobe involved in catalysis.     

Engineered disulfide bonds in recombinant human interferon-{gamma}: the impact of the N-terminal helix A and the AB-loop on protein stability

Insertion sites for cysteines with optimal stereochemistry forthe formation of unstrained disulfide bridges were identifiedin recombinant human interferon- (rhu-IFN-) by computer modelling.We have engineered two different disulfide cross-linked mutants,containing a pair of symmetry-related disulfide bonds, whichstabilize the N-termini of both monomers of the homodimenc protein.Mutations E7C and S69C allow the formation of an intramonomerdisuffide bond between helices A and D. In contrast, the A17Cand H111C mutations lead to a covalent cross-link between bothmonomers. The AB-loop is linked to helix F. The fluorescenceproperties of native and disulfide cross-linked proteins werestudied as a function of guanidine hydrochloride concentration.Melting temperatures (T_m) were calculated from the decreasein CD ellipticity at 220 nm. The induction of the antiviraleffect was measured using A549 fibroblast cells infected withencephalomyocarditis virus. The ability to induce the expressionof the HLA-DR antigen in Colo 205 cells was determined by fluorescence-activatedcell scanning analysis. The stability of both mutants was stronglyenhanced against temperature- and cosolvent-induced unfolding.The T_m of mutant IFN- E7C/S69C was 15°C. All measured biologicalactivities of this mutant were equal to wild type. In the caseof the other mutant IFN- A17C/H111C, the T_m value was 25°C.This mutation abolishes nearly the entire biological activity(<1%) with no detectable changes of secondary structure inthe CD spectrum. Our results illustrate the importance of theN-terminal helix A and the AB-loop for the unfolding pathwayand thermodynamic stability of rhu-IFN-.     

Mutagenesis and kinetic analysis of the active site Glu177 of ricin A-chain

Ricin A-chain (RTA) is an N-glycosidase which removes a specificadenine residue from the large rRNA of eukaryotic ribosomes.As a consequence, the ribosome is inactivated and protein synthesisis inhibited leading to cell death. This report describes theeffects on enzyme activity of specific mutations of the conservedactive site Glu177. The activity of mutant proteins was initiallyscreened using an in vitro translation system. It was foundthat mutagenesis of Glu177 to Lys led to an apparent total inactivationof the enzyme, Glu177 to Ala had a small effect on activity,whereas the conservative Glu177 to Asp mutation had a significanteffect. The properties of Glu177 to Asp were investigated moreclosely. Mutant protein was purified from an Escherichia coliexpression system and kinetic analysis of the depurination activityassessed using salt-washed yeast ribosomes. It was shown thatthe K, of the mutant protein was unchanged when compared todata of wild type RTA; however, the k_cat was significantly decreased(49-fold compared to wild type RTA). This suggests that Glu177plays a predominant role in the rate-limiting step of the enzymaticmechanism and not in substrate binding. These data are discussedin relation to other reports of ricin Glu177 substitutions.     

The crystal structure of thermostable mutants of chimeric 3-isopropylmalate dehydrogenase, 2T2M6T

A chimeric 3-isopropylmalate dehydrogenase (IPMDH), 2T2M6T,was produced by replacing the amino acid sequences of the Thermusthermophilus enzyme with those of the Bacillus subtilis enzymefrom residues 75 to 113. Decreased thermostability of the chiaiericenzyme was recovered by either evolutionary engineering (I93L)or site-directed mutagenesis (S82R). The 3-D structures of themutants have been determined by X-ray diffraction at 2.1 Åresolution. Although S82R was refined routinely, (I93L) requiredthe preliminary rigid-body refinement of each domain. The X-factorswere reduced to 0.18 for both mutants. Removal of the unfavorabletorsion angle at isoleucine 93 may have made I93L more thermostablethan 2T2M6T. In the case of S82R, the replaced arginine residuecontributed to the extra hydrogen bond with water molecules.The large replaced residue decreased the entropy of the solvent,which may have caused the improvement in enzyme thermostability.Denatu ration by heating may be interpreted from these structuralresults.     

Structural and mutagenesis studies of leishmania triosephosphate isomerase: a point mutation can convert a mesophilic enzyme into a superstable enzyme without losing catalytic power

The dimeric enzyme triosephosphate isomerase (TIM) has a verytight and rigid dimer interface. At this interface a criticalhydrogen bond is formed between the main chain oxygen atom ofthe catalytic residue Lys13 and the completely buried side chainof Gln65 (of the same subunit). The sequence of Leishmania mexicanaTIM, closely related to Trypanosoma brucei TIM (68% sequenceidentity), shows that this highly conserved glutamine has beenreplaced by a glutamate. Therefore, the 1.8 Å crystalstructure of leishmania TIM (at pH 5.9) was determined. Thecomparison with the structure of trypanosomal TIM shows no rearrangementsin the vicinity of Glu65, suggesting that its side chain isprotonated and is hydrogen bonded to the main chain oxygen ofLys13. Ionization of this glutamic acid side chain causes apH-dependent decrease in the thermal stability of leishmaniaTIM. The presence of this glutamate, also in its protonatedstate, disrupts to some extent the conserved hydrogen bond network,as seen in all other TIMs. Restoration of the hydrogen bondingnetwork by its mutation to glutamine in the E65Q variant ofleishmania TIM results in much higher stability; for example,at pH 7, the apparent melting temperature increases by 26°C(57°C for leishmania TIM to 83°C for the E65Q variant).This mutation does not affect the kinetic properties, showingthat even point mutations can convert a mesophilic enzyme intoa superstable enzyme without losing catalytic power at the mesophilictemperature.