Site-directed mutagenesis of the active site glutamate in human matrilysin: investigation of its role in catalysis

Glu-198 of human matrilysin is a conserved residue in the matrix metalloproteinases and is considered to play an important role in catalysis by acting as a general base catalyst toward the zinc-bound water molecule, on the basis of mechanistic proposals for other zinc proteases. In the present study, Glu-198 is mutated into Asp, Cys, Gln, and Ala, and the zinc binding properties, kinetic parameters, and pH dependence of each mutant are determined in order to examine the role of Glu-198 in catalysis. The mutations chosen either modify (C and D) or eliminate (A and Q) the general base properties of residue-198. All the mutants bind 2 mol of zinc per mol of enzyme, indicating that Glu-198 is not crucial to the binding of the catalytic zinc to the enzyme. The value of kcat/Km for the E198D mutant is only 4-fold lower than that of wild-type enzyme at the pH optimum of 7.5, while that for the E198C mutant is decreased by 160-fold. The E198Q and E198A enzymes containing the mutations that have eliminated the nucleophilic and acid/base properties of the residue are still active, having lower kcat/Km values of 590- and 1900-fold, respectively. The decrease in activity of all the mutants is essentially due to a decrease in kcat. The kcat/Km values of the mutants as a function of pH display broad bell-shaped curves that are similar to the wild-type enzyme. The acidic pKa value is not greatly affected by the change in the chemical properties of residue-198. The similarity in the pH profiles for the mutant and wild-type enzymes indicates that the ionization of Glu-198 is not responsible for the acidic pKa. Ionization of the zinc-bound water may be responsible for this pKa since the three His ligands and the scaffolding of the matrilysin catalytic zinc site are different from that observed in carboxypeptidase A and would predict a lower pKa for the metal-bound water. If the zinc-bound water is the nucleophile in the reaction, the role of Glu-198 in catalysis may be to stabilize the transition state or act as a general acid catalyst after the rate-determining step.     

Catalysis in human hypoxanthine-guanine phosphoribosyltransferase: Asp 137 acts as a general acid/base

Hypoxanthine-guanine phosphoribosyltransferase (HGPRTase) catalyzes the reversible formation of IMP and GMP from their respective bases hypoxanthine (Hx) and guanine (Gua) and the phosphoribosyl donor 5-phosphoribosyl-1-pyrophosphate (PRPP). The net formation and cleavage of the nucleosidic bond requires removal/addition of a proton at the purine moiety, allowing enzymic catalysis to reduce the energy barrier associated with the reaction. The pH profile of kcat for IMP pyrophosphorolysis revealed an essential acidic group with pKa of 7.9 whereas those for IMP or GMP formation indicated involvement of essential basic groups. Based on the crystal structure of human HGPRTase, protonation/deprotonation is likely to occur at N7 of the purine ring, and Lys 165 or Asp 137 are each candidates for the general base/acid. We have constructed, purified, and kinetically characterized two mutant HGPRTases to test this hypothesis. D137N displayed an 18-fold decrease in kcat for nucleotide formation with Hx as substrate, a 275-fold decrease in kcat with Gua, and a 500-fold decrease in kcat for IMP pyrophosphorolysis. D137N also showed lower KD values for nucleotides and PRPP. The pH profiles of kcat for D137N were severely altered. In contrast to D137N, the kcat for K165Q was decreased only 2-fold in the forward reaction and was slightly increased in the reverse reaction. The Km and KD values showed that K165Q interacts with substrates more weakly than does the wild-type enzyme. Pre-steady-state experiments with K165Q indicated that the phosphoribosyl transfer step was fast in the forward reaction, as observed with the wild type. In contrast, D137N showed slower phosphoribosyl transfer chemistry, although guanine (3000-fold reduction) was affected much more than hypoxanthine (32-fold reduction). In conclusion, Asp137 acts as a general catalytic acid/base for HGPRTase and Lys165 makes ground-state interactions with substrates.     

Role of the active-site carboxylate in dihydrofolate reductase: kinetic and spectroscopic studies of the aspartate 26-->asparagine mutant of the Lactobacillus casei enzyme

A mutant of Lactobacillus casei dihydrofolate reductase, D26N, in which the active site aspartic acid residue has been replaced by asparagine by oligonucleotide-directed mutagenesis has been studied by NMR and optical spectroscopy and its kinetic behavior characterized in detail. On the basis of comparisons of a large number of chemical shifts and NOEs, it is clear that there are only very slight structural differences between the methotrexate complexes of the wild-type and mutant enzymes and that these are restricted to the immediate environment of the substitution. The data suggest a slight difference in orientation of the pteridine ring in the binding site in the mutant enzyme. Both NMR and UV spectroscopy show that methotrexate is protonated on N1 when bound to the wild-type enzyme but not when bound to the mutant. Binding constant measurements by fluorescence quenching and steady-state kinetic measurements of dihydrofolate (FH2) and folate reduction show that the substitution has little or no effect on substrate, coenzyme, and inhibitor binding (< 7-fold increase in Kd) and only a modest effect on kcat (up to a factor of 9 for FH2 and 25 for folate) and kcat/KM (up to a factor of 13 for FH2 and 14 for folate). Measurements of deuterium isotope effects and direct measurements of hydride ion transfer and product release by stopped-flow methods revealed that for the mutant enzyme hydride ion transfer is rate-limiting across the pH range 5-8. This allowed a direct comparison of the rate of hydride ion transfer in the wild-type and mutant enzymes; the asparagine substitution was found to decrease this rate by 62-fold at pH 5.5 and 9-fold at pH 7.5. This effect is much smaller than that seen for the corresponding mutant of Escherichia coli dihydrofolate reductase [Howell, E. E., Villafranca, J. E., Warren, M. S., Oatley, S. J., & Kraut, J. (1986) Science 231, 1123-1128], estimated as a 1000-fold decrease in the rate of hydride ion transfer. The change in pH dependence of kcat resulting from the substitution is consistent with, but does not prove, the idea that the group of pK 6.0 which must be protonated for hydride ion transfer to occur is Asp26. For folate reduction, the pH dependence of kcat is determined by two pKs, one of which, pK 5, disappears in the mutant enzyme, suggesting that it may correspond to ionization of Asp26.(ABSTRACT TRUNCATED AT 400 WORDS)     

Mutations in the activation loop tyrosine of the oncoprotein v-Fps

Mutations were made in the activation loop tyrosine of the kinase domain of the oncoprotein v-Fps to assess the role of autophosphorylation in catalysis. Three mutant proteins, Y1073E, Y1073Q, and Y1073F, were expressed and purified as fusion proteins of glutathione-S-transferase from Escherichia coli and their catalytic properties were evaluated. Y1073E, Y1073Q, and Y1073F have k(cat) values that are reduced by 5-, 35-, and 40-fold relative to the wild-type enzyme, respectively. For all mutant enzymes, the Km values for ATP and a peptide substrate, EAEIYEAIE, are changed by 0.4-2-fold compared to the wild-type enzyme. The slopes for the plots of relative turnover versus solvent viscosity [(k(cat))eta] are 0.71 +/- 0.08, 0.10 +/- 0.06, and approximately 0 for wild type, Y1073Q, and Y1073E, respectively. These results imply that the phosphoryl transfer rate constant is reduced by 19- and 130-fold for Y1073E and Y1073Q compared to the wild-type enzyme. The dissociation constant of the substrate peptide is 1.5-2.5-fold lower for the mutants compared to wild type. The inhibition constant for EAEIFEAIE, a competitive inhibitor, is unaffected for Y1073E and raised 3-fold for Y1073Q compared to wild type. Y1073E and Y1073Q are strongly activated by free magnesium to the same extent and the apparent affinity constant for the metal is similar to that for the wild-type enzyme. The data indicate that the major role of autophosphorylation in the tyrosine kinase domain of v-Fps is to increase the rate of phosphoryl transfer without greatly affecting active-site accessibility or the local environment of the activating metal. Finally, the similar rate enhancements for phosphoryl transfer in v-Fps compared to protein kinase A [Adams et al. (1995) Biochemistry 34, 2447-2454] upon autophosphorylation suggest a conserved mechanism for communication between the activation loop and the catalytic residues of these two enzymes.     

Major changes in the kinetic mechanism of AMP inhibition and AMP cooperativity attend the mutation of Arg49 in fructose-1,6-bisphosphatase

The significance of subunit interface residues Arg49 and Lys50 in the function of porcine liver fructose-1,6-bisphosphatase was explored by site-directed mutagenesis, initial rate kinetics, and circular dichroism spectroscopy. The Lys50 --> Met mutant had kinetic properties similar to the wild-type enzyme but was more thermostable. Mutants Arg49 --> Leu, Arg49 --> Asp, Arg49 --> Cys were less thermostable than the wild-type enzyme yet exhibited wild-type values for kcat and Km. The Ki for the competitive inhibitor fructose 2,6-bisphosphate increased 3- and 5-fold in Arg49 --> Leu and Arg49 --> Asp, respectively. The Ka for Mg2+ increased 4-8-fold for the Arg49 mutants, with no alteration in the cooperativity of Mg2+ binding. Position 49 mutants had 4-10-fold lower AMP affinity. Most significantly, the mechanism of AMP inhibition with respect to fructose 1,6-bisphosphate changed from noncompetitive (wild-type enzyme) to competitive (Arg49 --> Leu and Arg49 --> Asp mutants) and to uncompetitive (Arg49 --> Cys mutant). In addition, AMP cooperativity was absent in the Arg49 mutants. The R and T-state circular dichroism spectra of the position 49 mutants were identical and superimposable on only the R-state spectrum of the wild-type enzyme. Changes from noncompetitive to competitive inhibition by AMP can be accommodated within the framework of a steady-state Random Bi Bi mechanism. The appearance of uncompetitive inhibition, however, suggests that a more complex mechanism may be necessary to account for the kinetic properties of the enzyme.     

Isolation and characterization of the heat-responsive genes in Escherichia coli

Isocitrate lyase from Escherichia coli has been expressed in transformed E. coli JE10 cells lacking the isocitrate lyase (icl) gene. After directed mutagenesis of icl by the restriction-site elimination method, partially purified isocitrate lyase mutants in which His 356 has been converted to Lys, Arg, Gln, Asp, or Leu have been characterized after induction of transformed, induced JE10 cells. Values of kcat compared to those for wild-type (wt) enzyme (100) at 37 degrees C, pH 7.3, are 18, 1, <1, 0, and 0 for H356K, H356R, H356E, H356Q, and H356L mutant enzymes, respectively. Km values for the 1:1 Mg-isocitrate complex (in millimolar units) are: 0.13, wt; 0.11, H356K; and 0.63, H356R. Further chromatographic purification of isocitrate lyase yields highly purified wt, H356K, and H356R enzymes. The pH profile of the stability of isocitrate lyase, which has never been reported, showed that the H356R enzyme was unstable in the pH range investigated; the wt and H356R variant differed but each was sufficiently stable to study the pH dependence of catalysis. The log kcat/pH profiles for highly purified wt and H356K enzymes are roughly bell-shaped and have pKa and pKb values for dissociation of an ionizable group on the enzyme-substrate complex of <6.3 and 8.4 for wt and 5.9 and 7.9 for H356K enzymes. Plots of pKm vs pH were different for the wt and H356K variant. Values of pKa and pKb (derived from log kcat/Km plots vs pH) for the dissociation of an activity-related ionizable group on the variant were 5.3 and 7.6, whereas the analogous pKb value for the wt enzyme was 8.4. The data suggest that His 356 is an important functional residue in isocitrate lyase, perhaps in deprotonating isocitrate during catalytic cleavage.     

ATP-binding site of human brain hexokinase as studied by molecular modeling and site-directed mutagenesis

The interaction of ATP with the active site of hexokinase is unknown since the crystal structure of the hexokinase-ATP complex is unavailable. It was found that the ATP binding site of brain hexokinase is homologous to that of actin, heat shock protein hsc70, and glycerol kinase. On the basis of these similarities, the ATP molecule was positioned in the catalytic domain of human brain hexokinase, which was modeled from the X-ray structure of yeast hexokinase. Site-directed mutagenesis was performed to test the function of residues presumably involved in interaction with the tripolyphosphoryl moiety of ATP. Asp532, which is though to be involved in binding the Mg2+ ion of the MgATP2- complex, was mutated to Lys and Glu. The kcat values decreased 1000- and 200-fold, respectively, for the two mutants. Another residue, Thr680 was proposed to interact with the gamma-phosphoryl group of ATP through hydrogen bonds and was mutated to Val and Ser. The kcat value of the Thr680Val mutant decreased 2000-fold, whereas the kcat value of the Thr680Ser decreased only 2.5-fold, implying the importance of the hydroxyl group. The Km and dissociation constant values for either ATP or glucose of all the above mutants showed little or no change relative to the wild-type enzyme. The Ki values for the glucose 6-phosphate analogue 1,5-anhydroglucitol 6-phosphate, were the same as that of the wild-type enzyme, and the inhibition was reversed by inorganic phosphate (Pi) for all four mutants. The circular dichroism spectra of the mutants were the same as that of the wild-type enzyme. The results from the site-directed mutagenesis demonstrate that the presumed interactions of investigated residues with ATP are important for the stabilization of the transition state.     

A study of subunit interface residues of fructose-1,6-bisphosphatase by site-directed mutagenesis: effects on AMP and Mg2+ affinities

The structural transformation of fructose-1,6-bisphosphatase upon binding of the allosteric regulator AMP dramatically changes the interactions across the C1-C4 (C2-C3) subunit interface of the enzyme. Asn9, Met18, and Ser87 residues were modified by site-directed mutagenesis to probe the function of the interface residues in porcine liver fructose-1,6-bisphosphatase. The wild-type and mutant forms of the enzyme were purified to homogeneity and characterized by initial rate kinetics and circular dichroism (CD) spectrometry. No discernible alterations in structure were observed among the wild-type and Asn9Asp, Met18Ile, Met18Arg, and Ser87Ala mutant forms of the enzyme as measured by CD spectrometry. Kinetic analyses revealed 1.6- and 1.8-fold increases in kcat with Met18Arg and Asn9Asp, respectively. The K(m) for fructose 1,6-bisphosphate increased about 2-approximately 4-fold relative to that of the wild-type enzyme in the four mutants. A 50-fold lower Ka value for Mg2+ compared with that of the wild-type enzyme was obtained for Met18Ile with no alteration of the Ki for AMP. However, the replacement of Met18 with Arg caused a dramatic decrease in AMP affinity (20 000-fold) without a change in Mg2+ affinity. Increases of 6- and 2-fold in the Ki values for AMP were found with Asn9Asp and Ser87Ala, respectively. There was no difference in the cooperativity for AMP inhibition between the wild-type and the mutant forms of fructose-1,6-bisphosphatase. This study demonstrates that the mutation of residues in the C1-C4 (C2-C3) interface of fructose-1,6-bisphosphatase can significantly affect the affinity for Mg2+, which is presumably bound 30 A away. Moreover the mutations alternatively reduce AMP and Mg2+ affinities, and this finding may be associated with the destabilization of the corresponding allosteric states of the enzyme. The kinetics and structural modeling studies of the interface residues provide new insights into the conformational equilibrium of fructose-1,6-bisphosphatase.     

Identification of a residue involved in transition-state stabilization in the ATPase reaction of DNA gyrase

Examination of the X-ray crystal structure of the 43 kDa N-terminal domain of the DNA gyrase B protein (GyrB) shows that the majority of the interactions with bound ATP are made with subdomain 1 (residues 2-220). However, two residues from subdomain 2, Gln335 and Lys337, interact with the gamma-phosphate of ATP. The proposed roles for these residues include nucleotide binding, transition-state stabilization, and triggering protein conformational changes. We have used site-directed mutagenesis to convert Gln335 to Asn and Ala and Lys337 to Gln and Ala in the N-terminal domain of GyrB. Two of the resultant mutant proteins, GyrB43(Q335A) and GyrB43(K337Q), were shown to be correctly folded, and their interactions with ATP have been analyzed in detail. The Q335A protein is apparently unchanged with regard to nucleotide binding and hydrolysis, whereas the K337Q protein shows a modest decrease in nucleotide binding and a drastic reduction in ATPase activity. This is manifested by a approximately 10(3)-fold decrease in kcat. When the two mutations were moved into full-length GyrB, the Q335A mutation again showed little or no effect on activity, whereas the K337Q mutation had undetectable supercoiling and ATPase activities. We conclude that Gln335 is dispensable for ATP binding and hydrolysis by the gyrase B protein, whereas Lys337 has a critical role in the ATPase reaction and is likely to be a key residue in transition-state stabilization.     

Ser644 is important for catalytic activity but is not involved in cAMP-dependent phosphorylation of yeast 6-phosphofructo-2-kinase

To identify the target amino acid for the cAMP-dependent phosphorylation of yeast 6-phosphofructo-2-kinase Ser644 was mutated to Ala. The plasmid-encoded wild-type and mutant enzymes were overexpressed in E. coli TG2 cells and in the yeast strain DFY658. Like the wild-type enzyme, the Ser644-->Ala mutant was phosphorylated in vivo after addition of glucose to yeast cells and in vitro by the catalytic subunit of protein kinase A. The specific activity of the mutant enzyme was 6-fold lower than that of the wild-type yeast 6-phosphofructo-2-kinase, but both enzymes were activated in response to the addition of glucose to yeast cells.     

Quantitative assessment of enzyme specificity in vivo: P2 recognition by Kex2 protease defined in a genetic system

The specificity of the yeast proprotein-processing Kex2 protease was examined in vivo by using a sensitive, quantitative assay. A truncated prepro-alpha-factor gene encoding an alpha-factor precursor with a single alpha-factor repeat was constructed with restriction sites for cassette mutagenesis flanking the single Kex2 cleavage site (-SLDKR downward arrowEAEA-). All of the 19 substitutions for the Lys (P2) residue in the cleavage site were made. The wild-type and mutant precursors were expressed in a yeast strain lacking the chromosomal genes encoding Kex2 and prepro-alpha-factor. Cleavage of the 20 sites by Kex2, expressed at the wild-type level, was assessed by using a quantitative-mating assay with an effective range greater than six orders of magnitude. All substitutions for Lys at P2 decreased mating, from 2-fold for Arg to >10(6)-fold for Trp. Eviction of the Kex2-encoding plasmid indicated that cleavage of mutant sites by other cellular proteases was not a complicating factor. Mating efficiencies of strains expressing the mutant precursors correlated well with the specificity (kcat/KM) of purified Kex2 for comparable model peptide substrates, validating the in vivo approach as a quantitative method. The results support the conclusion that KM, which is heavily influenced by the nature of the P2 residue, is a major determinant of cleavage efficiency in vivo. P2 preference followed the rank order: Lys > Arg > Thr > Pro > Glu > Ile > Ser > Ala > Asn > Val > Cys > AsP > Gln > Gly > His > Met > Leu > Tyr > Phe > Trp.     

Low-level laser therapy in osteoarticular diseases in geriatric patients]

The formation of the antibody variable domain binding unit (Fv) is the net result of three competing assembly reactions. The affinities of concurrent homologous interactions of heavy and light chain variable domains limits the heterologous interaction leading to productive formation of the Fv. To address the possible role of light chain dimerization in this phenomenon, the Gln38 residue at the dimer interface of an immunoglobulin light chain variable domain (VL) was replaced by charged amino acids. The effects of these mutations on VL homodimer formation were monitored by small-zone size exclusion HPLC and the affinities of interaction were determined by computer simulation. Reduced VL homodimerization was observed in three of the four mutants, Q38R, Q38D and Q38K. The association constants for the Q38R and Q38D homodimers were 1.2 x 10(4) and 3.2 x 10(3) M(-1), respectively. This corresponded to a 20-75-fold reduction in the homodimer association constant relative to the wild-type VL, which had an association constant of 2.4 x 10(5) M(-1). Surprisingly, the fourth charge mutant, Q38E, had a higher association constant than the wild-type VL. The potential for charged residues to facilitate heterodimeric assembly of immunoglobulin domains was also tested. Heterodimerization was observed between the Q38D and Q38R V(L)s, but with an association constant of 4.7 x 10(4) M(-1), approximately fivefold lower than that obtained for homodimerization of the native V(L). In addition, replacement of the neutral, solvent-accessible Gln38 residue with either Asp or Arg was found to be significantly destabilizing. These results suggest that charged residues could be introduced at immunoglobulin domain interfaces to guide heterodimer formation and to minimize unfavorable competing homologous associations. Nonetheless, these apparently simple modifications may also result in unintended consequences that are likely to depend upon structural features of particular variable domains.     

The active-site arginine of S-adenosylmethionine synthetase orients the reaction intermediate

S-Adenosylmethionine (AdoMet) synthetase catalyzes the formation of AdoMet and tripolyphosphate (PPPi) from ATP and L-methionine and the subsequent hydrolysis of the PPPi to PPi and Pi before product release. Little is known about the roles of active-site residues involved in catalysis of the two sequential reactions that occur at opposite ends of the polyphosphate chain. Crystallographic studies of Escherichia coli AdoMet synthetase showed that arginine-244 is the only arginine near the polyphosphate-binding site. Arginine-244 is embedded as the seventh residue in the conserved sequence DxGxTxxKxI which is also found at the active site of inorganic pyrophosphatases, suggesting a potential pyrophosphate-binding motif. Chemical modification of AdoMet synthetase by the arginine-specific reagents phenylglyoxal or p-hydroxyphenylglyoxal inactivates the enzyme. ATP and PPPi protect the enzyme from inactivation, consistent with the presence of an important arginine residue in the vicinity of the polyphosphate-binding site. Site-specific mutagenesis has been used to change the conserved arginine-244 to either leucine (R244L) or histidine (R244H). In the overall reaction, the R244L mutant has the kcat reduced approximately 10(3)-fold, with a 7 to 10-fold increase in substrate Km values; the R244H mutant has an approximately 10(5)-fold decrease in kcat. In contrast, the kcat values for hydrolysis of added PPPi by the R244L and R244H mutants have been reduced by less than 2 orders of magnitude. In contrast to the wild-type enzyme in which 98% of the Pi formed originates as the gamma-phosphoryl group of ATP, in the R244L mutant the orientation of the PPPi intermediate equilibrates at the active site yielding equal amounts of Pi from the alpha- and gamma-phosphoryl groups of ATP. Thus, the active-site arginine has a profound role in the cleavage of PPPi from ATP during AdoMet formation and in maintaining the orientation of PPPi in the active site, while playing a lesser role in the subsequent PPPi hydrolytic reaction.     

Crystal structure of Y34F mutant human mitochondrial manganese superoxide dismutase and the functional role of tyrosine 34

Tyrosine 34 is a prominent and conserved residue in the active site of the manganese superoxide dismutases in organisms from bacteria to man. We have prepared the mutant containing the replacement Tyr 34 --> Phe (Y34F) in human manganese superoxide dismutase (hMnSOD) and crystallized it in two different crystal forms, orthorhombic and hexagonal. Crystal structures of hMnSOD Y34F have been solved to 1.9 A resolution in a hexagonal crystal form, denoted as Y34Fhex, and to 2.2 A resolution in an orthorhombic crystal form, denoted as Y34Fortho. Both crystal forms give structures that are closely superimposable with that of wild-type hMnSOD, with the phenyl rings of Tyr 34 in the wild type and Phe 34 in the mutant very similar in orientation. Therefore, in Y34F, a hydrogen-bonded relay that links the metal-bound hydroxyl to ordered solvent (Mn-OH to Gln 143 to Tyr 34 to H2O to His 30) is broken. Surprisingly, the loss of the Tyr 34 hydrogen bonds resulted in large increases in stability (measured by Tm), suggesting that the Tyr 34 hydroxyl does not play a role in stabilizing active-site architecture. The functional role of the side chain hydroxyl of Tyr 34 can be evaluated by comparison of the Y34F mutant with the wild-type hMnSOD. Both wild-type and Y34F had kcat/Km near 10(9) M-1 s-1, close to diffusion-controlled; however, Y34F showed kcat for maximal catalysis smaller by 10-fold than the wild type. In addition, the mutant Y34F was more susceptible to product inhibition by peroxide than the wild-type enzyme. This activity profile and the breaking of the hydrogen-bonding chain at the active site caused by the replacement Tyr 34 --> Phe suggest that Tyr 34 is a proton donor for O2* - reduction to H2O2 or is involved indirectly by orienting solvent or other residues for proton transfer. Up to 100 mM buffers in solution failed to enhance catalysis by either Y34F or the wild-type hMnSOD, suggesting that protonation from solution cannot enhance the release of the inhibiting bound peroxide ion, likely reflecting the enclosure of the active site by conserved residues as shown by the X-ray structures. The increased thermostability of the mutant Y34F and equal diffusion-controlled activity of Y34F and wild-type enzymes with normal superoxide levels suggest that evolutionary conservation of active-site residues in metalloenzymes reflects constraints from extreme rather than average cellular conditions. This new hypothesis that extreme rather than normal substrate concentrations are a powerful constraint on residue conservation may apply most strongly to enzyme defenses where the ability to meet extreme conditions directly affects cell survival.     

Mutational analysis of the major loop of Bacillus 1,3-1,4-beta-D-glucan 4-glucanohydrolases. Effects on protein stability and substrate binding

The carbohydrate-binding cleft of Bacillus licheniformis 1,3-1, 4-beta-D-glucan 4-glucanohydrolase is partially covered by the surface loop between residues 51 and 67, which is linked to beta-strand-(87-95) of the minor beta-sheet III of the protein core by a single disulfide bond at Cys61-Cys90. An alanine scanning mutagenesis approach has been applied to analyze the role of loop residues from Asp51 to Arg64 in substrate binding and stability by means of equilibrium urea denaturation, enzyme thermotolerance, and kinetics. The DeltaDeltaGU between oxidized and reduced forms is approximately constant for all mutants, with a contribution of 5.3 +/- 0.2 kcal.mol-1 for the disulfide bridge to protein stability. A good correlation is observed between DeltaGU values by reversible unfolding and enzyme thermotolerance. The N57A mutant, however, is more thermotolerant than the wild-type enzyme, whereas it is slightly less stable to reversible urea denaturation. Mutants with a <2-fold increase in Km correspond to mutations at residues not involved in substrate binding, for which the reduction in catalytic efficiency (kcat/Km) is proportional to the loss of stability relative to the wild-type enzyme. Y53A, N55A, F59A, and W63A, on the other hand, show a pronounced effect on catalytic efficiency, with Km > 2-fold and kcat < 5% of the wild-type values. These mutated residues are directly involved in substrate binding or in hydrophobic packing of the loop. Interestingly, the mutation M58A yields an enzyme that is more active than the wild-type enzyme (7-fold increase in kcat), but it is slightly less stable.     

In bacterial reaction centers rapid delivery of the second proton to QB can be achieved in the absence of L212Glu

In the reaction center (RC) of Rhodobacter capsulatus, residue L212Glu is a component of the pathway for proton transfer to the reduced secondary quinone, QB. We isolated phenotypic revertants of the photosynthetically incompetent (PS-) L212Glu-->Gln mutant; all of them retain the L212Glu-->Gln substitution and carry a second-site mutation: L227Leu-->Phe, L228Gly-->Asp, L231Arg-->Cys, or M231Arg-->Cys. We also characterized the L212Ala strain, which is a phenotypic revertant of the PS- L212Glu-L213Asp-->Ala-Ala mutant. The activities of the RCs of these strains--all of which lack L212Glu--were studied by flash-induced absorption spectroscopy. At pH 7.5, the rate of second electron transfer in the L212Q mutant is comparable to the wild-type rate. However, this mutant shows a marked decrease in the rate of cytochrome oxidation under strong continuous illumination and a very slow phase (0.66 s-1) of the proton transfer kinetics following the second flash, indicating that transfer of the second proton to QB is slowed more than 1000-fold. The levels of recovery of the functional capabilities in the revertant RCs vary widely; their rates of cytochrome oxidation were intermediate between those of the wild-type and the L212Q mutant. The kinetics of proton transfer following the second flash show a significant recovery in the L212Q + M231C and L212A RCs (330-540 s-1), but the L212Q + L227F RCs recover this function only partially. Compensation for the lack of L212Glu in revertant RCs is discussed in terms of (i) conformational changes that could allow water molecules to approach closer to QB and/or (ii) the increase in the negative electrostatic environment and the resultant rise in the free energy level of QB- that is induced by the mutations. The stoichiometries of H+/QB- proton uptake below pH 7.5 in the L212Q mutant, the L212Q + M231C revertant, and the wild-type strains are essentially equivalent, suggesting that L212Glu is protonated at neutral pH in wild-type RCs. This is also supported by the P+QB- charge recombination data. Comparison of H+/QB- proton uptake data with those obtained previously for the stoichiometries of H+/QA- proton uptake [Miksovska, J., Maróti, P., Tandori, J., Schiffer, M., Hanson, D. K., Sebban, P. (1996) Biochemistry 35, 15411-15417] suggests that L212Glu is the key to the electrostatic and perhaps structural interaction between the two quinone sites.     

Role of electrostatic interactions in defining the potency of neurotoxin B-IV from Cerebratulus lacteus

Chemical modification implicates arginine residues of the Cerebratulus lacteus neurotoxin B-IV in biological activity. In the present study, we used site-directed mutagenesis to assess the functional contributions of each of these residues. Panels of mutants at each site have been constructed by polymerase chain reaction and recombinant proteins expressed and purified to homogeneity using an Escherichia coli expression system developed in this laboratory. All substitutions for Arg-17 (Gln, Ala, or Lys) yield proteins having undetectable levels of activity, while charge neutralizing replacement of Arg-25 (R25Q) causes a 400-fold reduction in specific toxicity. However, the R25K mutein is almost as active as natural toxin. Circular dichroism spectroscopy indicates that there are no major conformational changes in any of these muteins. These results therefore demonstrate the requirement for a guanidinium group at position 17, and a positive charge at position 25. NMR analyses (Hansen, P. E., Kem, W. R., Bieber, A. L., and Norton, R. S. (1992) Eur. J. Biochem. 210, 231-240) reveal neurotoxin B-IV to contain two antiparallel alpha-helices, which together include 57% of the sequence. Both Arg-17 and Arg-25 lie on the same face of the N-terminal helix (residues 13-26), as do the carboxyl groups of Glu-13 and Asp-21. However, charge neutralizing mutations of the latter two sites have no effects on biological activity. Arg-34, situated near the N terminus of helix 2 (residues 33-49) is also important for activity, as its replacement by Gln or Ala diminishes activity by 20- and 80-fold, respectively. However, unlike Arg-17 and Arg-25, thermal denaturation experiments suggest that R34Q may be structurally destabilized relative to wild-type B-IV.     

Effect of an amino acid insertion into the omega loop region of a class C beta-lactamase on its substrate specificity

The extended-substrate specificity of Enterobacter cloacae GC1 beta-lactamase is entirely due to a three amino acid insertion after position 207. To clarify the reason for the extended-substrate specificity, Ala, Ala-Ala, Ala-Ala-Ala, and Ala-Ala-Ala-Ala were inserted after position 207 on the basis of the class C beta-lactamase from E. cloacae P99, respectively. The kcat and Km values of all the mutant enzymes for cephalothin, benzylpenicillin and ampicillin were almost the same as those of the wild-type enzyme, except for those of P99-210-4A which were decreased 4-15-fold. On the other hand, the kcat and Km values for oxyimino beta-lactams such as cefuroxime, ceftazidime, and aztreonam increased with increasing numbers of inserted alanines. The kcat values of the mutant enzymes for cefroxime increased 140-7400-fold compared with that of the wild-type. The Km values also increased with almost the same magnitude, resulting in about the same kcat/Km values as that of the wild-type. On progressive inhibition analysis of aztreonam of the mutant enzymes, two kinds of inactive acyl-enzyme with distinct stabilities were observed, and the proportion of the less stable inactive enzyme increased with increasing numbers of inserted alanines. This suggests that the extension of the substrate specificity is due to instability of the acyl-intermediate caused by an increased deacylation rate in the reaction process.     

Engineering a change in metal-ion specificity of the iron-dependent superoxide dismutase from Mycobacterium tuberculosis-- X-ray structure analysis of site-directed mutants

We have refined the X-ray structures of two site-directed mutants of the iron-dependent superoxide dismutase (SOD) from Mycobacterium tuberculosis. These mutations which affect residue 145 in the enzyme (H145Q and H145E) were designed to alter its metal-ion specificity. This residue is either Gln or His in homologous SOD enzymes and has previously been shown to play a role in active-site interactions since its side-chain helps to coordinate the metal ion via a solvent molecule which is thought to be a hydroxide ion. The mutations were based on the observation that in the closely homologous manganese dependent SOD from Mycobacterium leprae, the only significant difference from the M. tuberculosis SOD within 10 A of the metal-binding site is the substitution of Gln for His at position 145. Hence an H145Q mutant of the M. tuberculosis (TB) SOD was engineered to investigate this residue's role in metal ion dependence and an isosteric H145E mutant was also expressed. The X-ray structures of the H145Q and H145E mutants have been solved at resolutions of 4.0 A and 2.5 A, respectively, confirming that neither mutation has any gross effects on the conformation of the enzyme or the structure of the active site. The residue substitutions are accommodated in the enzyme's three-dimensional structure by small local conformational changes. Peroxide inhibition experiments and atomic absorption spectroscopy establish surprisingly the H145E mutant SOD has manganese bound to it whereas the H145Q mutant SOD retains iron as the active-site metal. This alteration in metal specificity may reflect on the preference of manganese ions for anionic ligands.     

Role of the TIGN sequence in E. coli tryptophanyl-tRNA synthetase

Tryptophanyl-tRNA synthetase in E. coli does not have the HIGH sequence that is normally characteristic of class I aminoacyl-tRNA synthetases (EC 6.1.1.2), but instead contains a TIGN sequence at residues 17-20, which has been suggested to be equivalent to the HIGH sequence (Jones, M.D. et al. (1986) Biochemistry 25, 1887-1891). We have overexpressed E. coli Trp-tRNA synthetase and have used site-directed mutagenesis to mutate Thr-17 in the TIGN sequence to alanine. The mutant enzyme has the same Km values as the wild-type for tryptophan or tRNA(Trp), and a slightly increased Km for ATP, from 0.37 to 0.64 mM. On the other hand, the kcat for either the first step or the overall reaction is decreased by a factor of 30. In comparing the Thr-17 and Ala-17 enzymes, the delta delta G for the conversion of substrate to transition state is +9.6 kJ/mol (2.3 kcal/mol). Thr-17 is therefore important in binding the substrate in the transition state, thus supporting the suggestion that TIGN may fulfill the role of a HIGH sequence.