Module shuffling of a family F/10 xylanase: replacement of modules M4 and M5 of the FXYN of Streptomyces olivaceoviridis E-86 with those of the Cex of Cellulomonas fimi

To facilitate an understanding of structure–function relationships,chimeric xylanases were constructed by module shuffling betweenthe catalytic domains of the FXYN from Streptomyces olivaceoviridisE-86 and the Cex from Cellulomonas fimi. In the family F/10xylanases, the modules M4 and M5 relate to substrate bindingso that modules M4 and M5 of the FXYN were replaced with thoseof the Cex and the chimeric enzymes denoted FCF-C4, FCF-C5 andFCF-C4,5 were constructed. The k_cat value of FCF-C5 for p-nitrophenyl-ß-D-cellobiosidewas similar to that of the FXYN (2.2 s^–1); however, thek_cat value of FCF-C4 for p-nitrophenyl-ß-D-cellobiosidewas significantly higher (7.0 s^–1). The loss of the hydrogenbond between E46 and S22 or the presence of the I49W mutationwould be expected to change the position of Q88, which playsa pivotal role in discriminating between glucose and xylose,resulting in the increased k_cat value observed for FCF-C4 actingon p-nitrophenyl-ß-D-cellobioside since module M4directly interacts with Q88. To investigate the synergisticeffects of the different modules, module M10 of the FCF-C4 chimerawas replaced with that of the Cex. The effects of replacementof module M4 and M10 were almost additive with regard to theK_m and k_cat values.     

Improvement of binding of Puumala virus neutralization site resembling peptide with a second-generation phage library

We have previously selected a peptide insert FPCDRLSGYWERGIPSPCVRrecognizing the Puumala virus (PUUV) G2-glycoprotein-specificneutralizing monoclonal antibody (MAb) 1C9 with K_d of 2.85x10^–8from a random peptide library X₂CX₁₄CX₂ expressed on the pIIIprotein of the filamentous phage fd-tet. We have now createda second-generation phage-displayed peptide library in whicheach amino acid of the peptide was mutated randomly to anotherwith a certain probability. Peptides were selected for higheraffinity for MAb 1C9 and for a common binding motif for MAb4G2 having an overlapping epitope with MAb 1C9 in G2 glycoprotein.The resulting peptides were synthesized as spots on cellulosemembrane. Amino acid changes which improved the reactivity ofthe peptides to MAb 1C9 were combined in the peptide ATCDKLFGYYERGIPLPCALwith K_d of 1.49x10^–9 in biosensor measurements. Our resultsshow that the binding properties of peptides, the affinity andthe specificity can be improved and the binding specificitydetermining amino acids and structural factors can be analyzedby combining binding assays with synthetic peptides on membranewith the use of second-generation phage display libraries. Received October 18, 2002; revised April 16, 2003; accepted May 26, 2003.     

A structure-function relationship for the calcium affinities of regulatory proteins containing 'EF-hand' pairs

Using a series of homologous calcium-binding proteins, a quantitativestructure–activity relationship (QSAR), log(1/K_d) = –18.986– 1.6278(X₁) + 0.7981(X₂) + 0.2312(X₃), has been established,which relates the calcium-binding affinities (1/K_d) of the regulatoryproteins with (i) the net ligand charge (X₁) of the two calciumbinding loops, (ii) the hydrophobicity (X₂) of the ß-sheetsegment of the loops and (iii) the hydrophobicity (X₃) of thefour ‘EF-hand’ helices. It is found that the bindingaffinities are influenced by the ‘EF-hand’ pairrather than the individual ‘EF-hands’. The QSAR,in addition to explaining satisfactorily the large variationin the observed calcium affinities, can predict the affinitiesof the ‘EF-hand’ pairs in other proteins from theamino acid sequence and can also account for the changes inthe affinities caused by substitution in the hydrophobic and/ormetal-coordinating residues. Thus, this relationship can beemployed in protein design and engineering. The method is potentiallyuseful in the development of similar relationships for the bindingof other proteins to substrates, inhibitors, drugs and co-factors.     

Expression and characterization of Lactobacillus 30a histidine decarboxylase in Escherichia coli

The genes coding for histidine decarboxylase from a wild-typestrain and an autoactivation mutant strain of Lactobacillus30a have been cloned and expressed in Escherichia coli. Themutant protein, G58D, has a single Asp for Gly substitutionat position 58. The cloned genes were placed under control ofthe ß-galactosidase promoter and the products arenatural length, not fusion proteins. The enzyme kinetics ofthe proteins isolated from E. coli are comparable to those isolatedfrom Lactobacillus 30a. At pH 4.8 the K_m of wild-type enzymeis 0.4 mM and the k_cat = 2800 min^–1; the correspondingvalues for G58D are 0.5 mM and 2750 min^–1. The wild-typeand G58D have autoactivation half-times of 21 and 9 h respectivelyunder pseudophysiological conditions of 150 mM K⁺ and pH 7.0.At pH 7.6 and 0.8 M K⁺ the half times are 4.9 and 2.9 h. Therelatively slow rate of autoactivation for purified proteinand the differences in cellular and non-cellular activationrates, coupled with the fact that wild-type protein is readilyactivated in wild-type Lactobacillus 30a but poorly activatedin E. coli, suggest that wild-type Lactobacillus 30a containsa factor, possibly an enzyme, that enhances the activation rate.     

Control of antibody-antigen interaction using anion-induced conformational change in antigen peptide

The binding of a monoclonal antibody to an epitope peptide wascontrolled by the conformational change of the epitope peptideinduced by anions. We synthesized peptides in which the epitopesequence DTYRYI for the monoclonal antibody AU1 is located betweenamphiphilic peptides (KKLL)_n and (LLKK)_n. In the absence ofan appropriate anion, the peptide was in a random coil stateand the epitope was linear. In contrast, in the presence ofan appropriate anion, the peptide exhibited an anti-parallel-helical structure and the epitope was subsequently `bent'.In the presence of 41 µM triphosphate, the associationconstant between the antibody and the peptide was decreasedby one order of magnitude in the case of n = 3 and at leastthree orders of magnitude in the case of n = 4 or 5. Oligo-DNAs,as anions, dissociated the antibody–peptide complex, whereastriphosphate did not. The DNA concentrations required for 50%dissociation of the antibody–peptide complex at pH 7.5were 4x10^–8, 1x10^–7 and 6x10^–6 M for decamer,octamer and hexamer DNA, respectively.     

Interactions of (Ala*Ala*Lys*Pro)n and (Lys*Lys*Ser*Pro)n with DNA. Proposed coiled-coil structure of AlgR3 and AlgP from Pseudomonas aeruginosa

The proteins, AlgR3 and AlgP, are involved in the regulationof alginate synthesis in Pseudomonas. They contain multiplerepeats of Ala^*Ala^*Lys^*Pro as do several other proteins thatresemble histones. The interactions of synthesis oligopeptidescomposed of repeated Ala^*Ala^*Lys^*Pro or Lys^*Lys^*Ser^*Pro unitswith DNA were studied by fluorescence of the Fmoc (9-fluorenylmethyloxycarbonyl)group attached to the N-termini of the peptides. DNA quenchingof the Fmoc fluorescence of the peptides was used to estimatethe apparent association constants for the interaction of Fmoc(AAKP)_nOH(n = 2, 4, 8, 18, 32) and of Fmoc(KKSP)_nOH (n = 2, 4, 8, 16,20, 32) with DNA. The Fmoc(AAKP)_nOH peptides bind to DNA onlyat low ionic strength; the Fmoc(KKSP)_n OH peptides interactwith DNA at both low (0.05 M KCl) and high (0.2 M KCl) saltAt low ionic strength an increase in the number of the repeatunits causes an increase in the apparent association constantup to {small tilde}2 x 10⁶ M^–1 for both types of peptidesat N 24. The insertion of an AAKTA unit into the middle ofthe Fmoc(AAKP)₈OH peptide increases its affinity to DNA. Wepropose a model of (AAKP)_n and of its interaction with DNA.The repeat unit consists of a single turn of -helix followedby a bend necessitated by Pro. The resultant coiled-coil formsa right-handed superhelix with 10 AAKPs per repeat distanceof {small tilde}33 Å. With only slight modification ofthe canonical parameters of this model the AAKP super helixfits into the major groove of B-form DNA with one AAKP tetramerper base pair repeat of 3.4 Å. The -amine nitrogen ofLys can form a polar hydrogen bond with a phosphate oxygen atomof the DNA backbone. A better fit is obtained when the modelis modified to accommodate [(AAKP)₅AAKTA]_n as actually observedin AlgR3. We suggest that this coiled-coil represents a generalmotif for other protein–DNA interactions.     

Multimer formation as a consequence of separate homodimerization domains: the human c-Jun leucine zipper is a transplantable dimerization module

Human c-Jun and c-Fos leucine zipper domains were examined fortheir ability to serve as autonomous dimerization domains aspart of a heterologous protein construct. Schistosoma japonicumglutathione S-transferase (GST) was fused to recombinant Junleucine zipper (rJunLZ) and Fos leucine zipper (rFosLZ) domains.SDS–PAGE ‘snapshot’ analyses based on disulphidelinkage of monomers demonstrated the ability of rJunLZ to functionas a dimerization motif in a foreign protein environment. Sterichindrance prevented formation of rJunLZ–GST::rFosLZ–GSTheterodimers whereas rJunLZ–GST::rFosLZ and rJunLZ::rFosLZ–GSTformed readily. Furthermore, rJunLZ–GST generated homodimerssuggesting fusion protein heterodimers interact differentlyto homodimers. Gel filtration chromatography confirmed thatGST is a dimer in solution and that attachment of a leucinezipper domain allows further interactions to take place. Sedimentationequilibrium analyses showed that GST is a stable dimer (K_a >10⁶ M^-1) with no higher multimeric forms. rFosLZ–GST weaklyassociates beyond a dimer (K_a {small tilde}4x10⁵ M^-1) and rJunLZ–GSTassociates indefinitely (K_a {small tilde}4x10⁶ M^-1), consistentwith an isodesmic model of association. The interaction of theseleucine zippers independently of GST association demonstratestheir utility in the modification of proteins when multimerformation is desired.     

Bacterial expression, purification and preliminary kinetic description of the kinase domain of v-fps

The gene coding for the tyrosine protein kinase domain of v-fpswas subcloned into a plasmid vector expressing glutathione-S-transferase(GST). This new vector expresses a fusion protein in Escherichiacoli composed of the kinase domain linked with GST at the N-terminus(GST-kin). A portion of the total expressed protein was solubleupon cell lysis and was purified by affinity chromatographyusing glutathione cross-linked agarose. GST-kin (M_r 57 000)is a phosphoprotein as judged by ³²P autoradiography, consistentwith the known autophosphorylation site within the kinase core[Weinmaster et aL (1984) Cell, 37, 559–568]. Cleavageof the fusion protein with thrombin and purification on phosphocelluloseresin yielded the pure kinase domain (M_r 33 000). The activityof the kinase domain is indistinguishable from that of GST-kinusing the peptide substrate EEEIYEEIE, indicating that Nterminalfusion has no effect on the kinase domain. GSTkin phosphorylatesa second peptide, EAEIYEAIE, with improved catalytic efficiency.Initial velocity data are consistent with a random bireactantmechanism with no substrate synergism observed in the ternarycomplex. Steady-state kinetic analyses reveal that this peptideis phosphorylated, with a k_cat of 3.6 s^–1, a K_peptideof 500 µM and a K_ATP of 250 µM. The expression,purification and preliminary kinetic analysis of the kinasedomain of v-fps provide the first step in the application ofstructurefunction studies for this oncoprotein     

The structural roles of conserved Pro196, Pro197 and His199 in the mechanism of thymidylate synthase

We generated replacement sets for three highly conserved residues,Pro196, Pro197 and His199, that flank the catalytic nucleophile,Cys198. Pro196 and Pro197 have restricted mobility that couldbe important for the structural transitions known to be essentialfor activity. To test this hypothesis we obtained and characterized13 amino acid substitutions for Pro196, 14 for Pro197 and 14for His199. All of the Pro196 and Pro197 variants, except P197R,and four of the His199 variants complemented TS-deficient Escherichiacoli cells, indicating they had at least 1% of wild-type activity.For all His199 mutations, k_cat/K_m for substrate and cofactordecreased more than 40-fold, suggesting that the conserved hydrogenbond network co-ordinated by His199 is important for catalysis.Pro196 can be substituted with small hydrophilic residues withlittle loss in k_cat, but 15- to 23-fold increases in K_m^dUMP.Small hydrophobic substitutions for Pro197 were most active,and the most conservative mutant, P197A, had only a 5-fold lowerk_cat/K_m^dUMP than wild-type TS. Several Pro196 and Pro197 variantswere temperature sensitive. The small effects of Pro196 or Pro197mutations on enzyme kinetics suggest that the conformationalrestrictions encoded by the Pro–Pro sequence are largelymaintained when either member of the pair is mutated. Received February 24, 2003; revised June 19, 2003; accepted June 20, 2003.     

Modular construction of extended DNA recognition surfaces: mutant DNA-binding domains of the 434 repressor as building blocks

Single-chain derivatives of the 434 repressor containing onewild-type and one mutant DNA-binding domain recognize the generaloperator ACAA–6 base pairs–NNNN, where the ACAAoperator subsite is contacted by the wild-type and the NNNNtetramer by the mutant domain. The DNA-binding specificitiesof several single-chain mutants were studied in detail and theoptimal subsites of the mutant domains were determined. Thecharacterized mutant domains were used as building units toobtain homo- and heterodimeric single-chain derivatives. TheDNA-binding properties of these domain-shuffled derivativeswere tested with a series of designed operators of NNNN–6base pairs–NNNN type. It was found that the binding specificitiesof the mutant domains were generally maintained in the new environmentsand the binding affinities for the optimal DNA ligands werehigh (with K_d values in the range of 10^–11–10^–10M). Considering that only certain sequence motifs in place ofthe six base pair spacer can support optimal contacts betweenthe mutant domains and their subsites, the single-chain 434repressor mutants are highly specific for a limited subset of14 base pair long DNA targets.     

Production of an activated form of Bacillus stearothermophilus L-2-hydroxyacid dehydrogenase by directed evolution

Bacillus stearothermophillus lactate dehydrogenase (bsLDH) isactivated in the presence of fructose 1,6 bisphosphate (FBP).The activator is expensive and representative of the sort ofco-factor complications that are undesirable in industrial processes.Three rounds of random mutagenesis and screening produced amutant (6A) which is almost fully activated in the absence ofFBP. Wild-type bsLDH has a K^pyr_M of 5 mM in the absence of FBPbut when activated (+FBP) the K^pyr_M drops to 0.05 mM. The mutant6A has a K^pyr_M of 0.07 mM in the absence of FBP. 6A has threeamino acid substitutions—R118C, Q203L and N307S—resultingin a 70-fold activation, none of the mutations are near theactive site. The activation of wild type bsLDH is due to anFBP induced tetramerization of dimeric bsLDH bringing abouta structural rearrangement of key active site residues. Themost likely explanation for the activation of 6A is derivedfrom the position of Q203L, which is at the dimer–dimerinterface. The suggestion is that the hydrophilic to hydrophobicchange has altered the dimer–tetramer equilibrium positiontowards that of the tetramer. What is significant is the activationof bsLDH by a subtle long range event produced by the `blind'directed evolution approach.     

Secretion of recombinant human IgE-Fc by mammalian cells and biological activity of glycosylation site mutants

We have constructed an expression vector that leads to secretionof the whole Fc of human immunoglobulin E (hIgE-Fc) from mammaliancells at levels up to 100 mg/l of culture. Two surface glycosylationsites at Asn265 and Asn371 have been changed to glutamine, toobtain a more homogeneous preparation of hIgE-Fc for structuralstudies. Comparison of wild-type and mutant products revealedthat Asn371 is rarely glycosylated in Chinese hamster ovarycells. Both the double mutant and wild-type hIgEFc bind to thehigh-affinity IgE receptor, FcRI, with about the same affinityas myeloma IgE (K_a in the range 10¹⁰–10¹¹ M^–1),and were able to sensitize isolated human basophils for anti-IgEtriggering of histamine release. However, only the double mutanthIgE-Fc approached the affinity of myeloma IgE for the low-affinityreceptor, FcRII (K_a = 7.3x10⁷ M^–1), whereas the wild-type hIgE-Fc bound with a 10-fold lower affinity (K_a = 4.1x10⁶M^–1).     

Elastase substrate specificity tailored through substrate-assisted catalysis and phage display

The catalytic histidine of human neutrophil elastase was replacedwith alanine (H57A) to determine if a substrate histidine couldsubstitute for the missing catalytic group—`substrate-assistedcatalysis'. H57A and wild-type elastase were recovered directlyfrom Pichia pastoris following expression from a synthetic genelacking the elastase pro sequence, thereby obviating the needfor zymogen activation. Potential histidine-containing substratesfor H57A elastase were identified from a phage library of randomizedsequences. One such sequence, REHVVY, was cleaved by H57A elastasewith a catalytic efficiency, k_cat/K_M, of 2800 s^–1 M^–1,that is within 160-fold of wild-type elastase. In contrast,wild-type but not H57A elastase cleaved the related non-histidinecontaining sequence, REAVVY. Ten different histidine-containinglinkers were cleaved by H57A elastase. In addition to the requirementfor a P2 histidine, significant preferences were observed atother subsites including valine or threonine at P1, and methionineor arginine at P4. A designed sequence, MEHVVY, containing thepreferred residues identified at each subsite proved to be amore favorable substrate than any of the phage-derived sequences.Extension of substrate-assisted catalysis to elastase suggeststhat this engineering strategy may be widely applicable to otherserine proteases thereby creating a family of highly specifichistidine-dependant proteases.     

Catalytic mechanism of fungal glucoamylase as defined by mutagenesis of Asp176, Glu179 and Glu180 in the enzyme from Aspergillus awamori

Asp176, Glu179 and Glu180 of Aspergillus awamori glucoamylaseappeared by differential labeling to be in the active site.To test their functions, they were replaced by mutagenesis withAsn, Gln and Gln respectively, and kinetic parameters and pHdependencies of all enzyme forms were determined. Glu179 –Gln glucoamylase was not active on maltose or isomaltose, whilethe k_cat for maltoheptaose hydrolysis decreased almost 2000-foldand the K_M was essentially unchanged from wild-type glucoamylase.The Glu180 – Gln mutation drastically increased the K_Mand moderately decreased the k_cat with maltose and maltoheptaose,but affected isomaltose hydrolysis less. Differences in substrateactivation energies between Glu180 – Gln and wild-typeglucoamylases indicate that Glu180 binds D-glucosyl residuesin subsite 2. The Asp176 – Asn substitution gave moderateincreases and decreases in K_M and k_cat respectively, and thereforesimilar increases in activation energies for the three substrates.This and the differences in subsite binding energies betweenAsp176 – Asn and wild-type glucoamylases suggest thatAsp176 is near subsite 1, where it stabilizes the transitionstate and interacts with Trp120 at subsite 4. Glu179 and Asp176are thus proposed as the general catalytic acid and base ofpK_a 5.9 and 2.7 respectively. The charged Glu180 contributesto the high pK_a value of Glul79. Received May 25, 1989; accepted October 19, 1989.     

Synthesis of a squash-type protease inhibitor by gene engineering and effects of replacements of conserved hydrophobic amino acid residues on its inhibitory activity

Cucurbita maxima trypsin inhibitor I (CMTI-I), a member of thesquash-type protease inhibitor family, is composed of 29 aminoacids and shows strong inhibition of trypsin by its compactstructure. To study the structure–function relationshipof this inhibitor using protein engineering methods, we constructedan expression system for CMTI-I as a fused protein with porcineadenylate kinase (ADK). A Met residue was introduced into thejunction of ADK and CMTI-I to cleave the fusion protein withCNBr, whereas a Met at position 8 of authentic CMTI-I was replacedby Leu. Escherichia coli JM109 transformed with the constructedplasmid expressed the fused protein as an inclusion body. Aftercleavage of the expressed protein with CNBr, fully reduced speciesof CMTI-I were purified by reversed-phase HPLC and then oxidizedwith air by shaking. For efficient refolding of CMTI-I, we used50 mM NH₄HCO₃ (pH 7.8) containing 0.1% PEG 6000 at higher proteinconcentration. Strong inhibitory activity toward trypsin wasdetected only in the first of three HPLC peaks. The inhibitorconstant of CMTI-I thus obtained, in which Met8 was replacedby Leu, was 1.4x10-¹⁰ M. The effect of replacement of Met withLeu at position 8 was shown to be small by comparison of theinhibitor constant of authentic CMTI-III bearing Lys at position9 (8.9x10-¹¹ M) with that of its mutant bearing Leu at position8 and Lys at position 9 (1.8x10-¹⁰ M). To investigate the roleof the well conserved hydrophobic residues of CMTI-I in itsinteraction with trypsin, CMTI-I mutants in which one or allof the four hydrophobic residues were replaced by Ala were prepared.The inhibitor constants of these mutants indicated that thosewith single replacements were 5–40 times less effectiveas trypsin inhibitors and that the quadruple mutant was –450times less effective, suggesting that the hydrophobic residuesin CMTI-I contribute to its tight binding with trypsin. However,each mutant was not converted to a temporary inhibitor.     

Protein engineering of cytochrome P450cam (CYP101) for the oxidation of polycyclic aromatic hydrocarbons

Mutations of the active site residues F87 and Y96 greatly enhancedthe activity of cytochrome P450_cam (CYP101) from Pseudomonasputida for the oxidation of the polycyclic aromatic hydrocarbonsphenanthrene, fluoranthene, pyrene and benzo[a]pyrene. Wild-typeP450_cam had low (<0.01 min^–1) activity with these substrates.Phenanthrene was oxidized to 1-, 2-, 3- and 4-phenanthrol, whilefluoranthene gave mainly 3-fluoranthol. Pyrene was oxidizedto 1-pyrenol and then to 1,6- and 1,8-pyrenequinone, with smallamounts of 2-pyrenol also formed with the Y96A mutant. Benzo[a]pyrenegave 3-hydroxybenzo[a]pyrene as the major product. The NADHoxidation rate of the mutants with phenanthrene was as highas 374 min^–1, which was 31% of the camphor oxidation rateby wild-type P450_cam, and with fluoranthene the fastest ratewas 144 min^–1. The oxidation of phenanthrene and fluoranthenewere highly uncoupled, with highest couplings of 1.3 and 3.1%,respectively. The highest coupling efficiency for pyrene oxidationwas a reasonable 23%, but the NADH turnover rate was slow. Theproduct distributions varied significantly between mutants,suggesting that substrate binding orientations can be manipulatedby protein engineering, and that genetic variants of P450_cammay be useful for studying the oxidation of polycyclic aromatichydrocarbons by P450 enzymes.     

Engineering linear F(ab')2 fragments for efficient production in Escherichia coli and enhanced antiproliferative activity

We developed a novel bivalent antibody fragment, the linear(L-) F(ab')₂, comprising tandem repeats of a heavy chain fragmentV_H–C_H1–V_H–C_H1 cosecreted with a light chain.Functional humanized L-F(ab')₂ directed against p185^HER2 wassecreted from Escherichia coli at high titer (100 mg/l) andpurified to homogeneity. The L-F(ab')₂ binds two equivalentsof antigen with an apparent affinity (K_d = 0.46 nM) that iswithin 3-fold of the corresponding thioether-linked F(ab')₂fragment The N-terminal site binds antigen with an affinity(K_d = 1.2 nM) that is 4-fold greater than that for the C-terminalsite, as shown by the comparison of L-F(ab')₂ variants containinga single functional binding site. L-F(ab')₂ has greater antiproliferativeactivity than the thioether-linked F(ab')₂ against the p185^HER2-overexpressingtumor cell line BT474. Linear and thioether-linked F(ab')₂ havevery similar pharmacokinetic properties in normal mice, andtheir serum permanence times are respectively 7- and 8-foldlonger than the corresponding Fab fragment L-F(ab')₂ offersa facile route to bivalent antibody fragments that are potentiallysuitable for clinical applications, and that may have improvedbiological activity compared with thioether-linked F(ab')₂ fragments.     

Replacement set mutagenesis of the four phosphate-binding arginine residues of thymidylate synthase

Arginines R23, R178, R179 and R218 in thymidylate synthase (TS,EC 2.1.1.45) are hydrogen bond donors to the phosphate moietyof the substrate, dUMP. In order to investigate how these argininescontribute to enzyme function, we prepared complete replacementsets of mutants at each of the four sites in Lactobacillus caseiTS. Mutations of R23 increase K_m for dUMP 2–20-fold, increaseK_m for cofactor 8–40-fold and decrease k_cat 9–20-fold,reflecting the direct role of the R23 side chain in bindingand orienting the cofactor in ternary complexes of the enzyme.Mutations of R178 increase K_m for dUMP 40–2000-fold, increaseK_m for cofactor 3–20-fold and do not significantly affectk_cat. These results are consistent with the fact that this residueis an integral part of the dUMP-binding wall and contributesto the orientation and ordering of several other dUMP bindingresidues. Kinetic parameters for all R179 mutations except R179Pwere not significantly different from wild-type values, reflectingthe fact that this external arginine does not directly contactthe cofactor or other ligand-binding residues. R218 is essentialfor the structure of the catalytic site and all mutations ofthis arginine except R218K were inactive.     

Cold-adaptation mechanism of mutant enzymes of 3-isopropylmalate dehydrogenase from Thermus thermophilus

Random mutagenesis of Thermus thermophilus 3-isopropylmalatedehydrogenase revealed that a substitution of Val126Met in ahinge region caused a marked increase in specific activity,particularly at low temperatures, although the site is far fromthe binding residues for 3-isopropylmalate and NAD. To understandthe molecular mechanism, residue 126 was substituted with oneof eight other residues, Gly, Ala, Ser, Thr, Glu, Leu, Ile orPhe. Circular dichroism analyses revealed a decreased thermalstability of the mutants (T= 0–13°C), indicating structuralperturbations caused by steric conflict with surrounding residueshaving larger side chains. Kinetic parameters, k_cat and K_m valuesfor isopropylmalate and NAD, were also affected by the mutation,but the resulting k_cat/K_m values were similar to that of thewild-type enzyme, suggesting that the change in the catalyticproperty is caused by the change in free-energy level of theMichaelis complex state relative to that of the initial state.The kinetic parameters and activation enthalpy change (H) showedgood correlation with the van der Waals volume of residue 126.These results suggested that the artificial cold adaptation(enhancement of k_cat value at low temperatures) resulted fromthe destabilization of the ternary complex caused by the increasein the volume of the residue at position 126.