The steady-state kinetics of the enzyme reaction tested by site-directed mutagenesis of hydrophobic residues (Val, Leu, and Cys) in the C-terminal alpha-helix of human adenylate kinase

To elucidate whether the C-terminal region in human adenylate kinase participates in the interaction with the substrate (MgATP(2-) and/or AMP(2-)), hydrophobic residues (Val182, Val186, Cys187, Leu190, and Leu193) were substituted by site-directed mutagenesis and the steady-state kinetics of fifteen mutants were analyzed. A change in the hydrophobic residues in the C-terminal domain affects the affinity for substrates (K(m)), that is, not only for MgATP(2-) but also for AMP(2-), and the catalytic efficiency (k(cat)). The results obtained have led to the following conclusions: (i) Val182 may interact with both MgATP(2-) and AMP(2-) substrates, but to a greater extent with MgATP(2-), and play a role in catalysis. (ii) Val186 appears to play a functional role in catalysis by interacting with both MgATP(2-) and AMP(2-) to nearly the same extent. (iii) Cys187 appears to play a functional role in catalysis. (iv) Leu190 appears to interact with both MgATP(2-) and AMP(2-) substrates but to a greater extent with AMP(2-). (v) Leu193 appears to interact with both MgATP(2-) and AMP(2-) but to a greater extent with AMP(2-). The activity of all mutants decreased due to the change in substrate-affinity. The closer the residue is located to the C-terminal end, the more its mutation affects not only MgATP(2-) but also AMP(2-) substrate binding. The hydrophobic alterations disrupt hydrophobic interactions with substrates and that might destabilize the conformation of the active site. The more C-terminal part of the alpha-helix appears to interact with AMP, as if it has swung out and rotated to cover the adenine moieties. The C-terminal alpha-helix of human adenylate kinase appears to be essential for the interaction with adenine substrates by swinging out during catalysis.     

NMR studies of differences in the conformations and dynamics of ligand complexes formed with mutant dihydrofolate reductases

Two mutants of Lactobacillus casei dihydrofolate reductase, Trp 21----Leu and Asp 26----Glu, have been prepared by using site-directed mutagenesis methods, and their ligand binding and structural properties have been compared with those of the wild-type enzyme. 1H, 13C, and 31P NMR studies have been carried out to characterize the structural changes in the complexes of the mutant and wild-type enzymes. Replacement of the conserved Trp 21 by a Leu residue causes a decrease in activity of the enzyme and reduces the NADPH binding constant by a factor of 400. The binding of substrates and substrate analogues is only slightly affected. 1H NMR studies of the Trp 21----Leu enzyme complexes have confirmed the original resonance assignments for Trp 21. In complexes formed with methotrexate and the mutant enzyme, the results indicate some small changes in conformation occurring as much as 14 A away from the site of substitution. For the enzyme-NADPH complexes, the chemical shifts of nuclei in the bound coenzyme indicate that the nicotinamide ring binds differently in complexes with the mutant and the wild-type enzyme. There are complexes where the wild-type enzyme has been shown to exist in solution as a mixture of conformations, and studies on the corresponding complexes with the Trp 21----Leu mutant indicate that the delicately poised equilibria can be perturbed. For example, in the case of the ternary complex formed between enzyme, trimethoprim, and NADP+, two almost equally populated conformations (forms I and II) are seen with the wild-type enzyme but only form II (the one in which the nicotinamide ring of the coenzyme is extended away from the enzyme structure and into the solvent) is observed for the mutant enzyme complex. It appears that the Trp 21----Leu substitution has a major effect on the binding of the nicotinamide ring of the coenzyme. For the Asp 26----Glu enzyme there is a change in the bound conformation of the substrate folate. Further indications that some conformational adjustments are required to allow the carboxylate of Glu 26 to bind effectively to the N1 proton of inhibitors such as methotrexate and trimethoprim come from the observation of a change in the dynamics of the bound trimethoprim molecule as seen from the increased rate of the flipping of the 13C-labeled benzyl ring and the increased rate of the N1-H bond breaking.     

Site-directed mutagenesis of Pro-17 located in the glycine-rich region of adenylate kinase

Proline 17 in the glycine-rich region of adenylate kinase was replaced by Gly (the Gly-mutant) or Val (the Val-mutant) by site-directed mutagenesis. The mutant enzymes were purified to homogeneous states on sodium dodecyl sulfate-gel electrophoresis after solubilization of the proteins from the pellets of cell lysates of Escherichia coli. The apparent Km values of the Gly- and the Val-mutants for AMP increased approximately 7- and 24-fold, respectively, as compared with that of the wild-type enzyme. The apparent Km values for ATP also increased 7- and 42-fold in the Gly- and Val-mutants, respectively. In contrast, Vmax values of both mutant enzymes were comparable to that of the wild-type enzyme. These results suggest that Pro-17 plays an important role for the binding of substrates, but not for catalytic efficiency, although it does not directly interact with substrates. Adenosine diphosphopyridoxal, which specifically modifies Lys-21 in adenylate kinase (Tagaya, M., Yagami, T., and Fukui, T. (1987) J. Biol. Chem. 262, 8257-8261), inactivated the wild-type and mutant enzymes at almost the same rates. Interestingly, both mutant enzymes showed higher specificities for adenine nucleotides than the wild-type enzyme. Both mutant enzymes were less resistant than the wild-type enzyme against inactivation at elevated temperatures or by treatment with trypsin. It would appear that most of the properties of the mutant enzymes may be explained on the basis of a need for conformational flexibility of the loop which includes Pro-17 for substrate binding.     

Influence of size and polarity of residue 31 in porcine pancreatic phospholipase A2 on catalytic properties

Residue 31 of porcine pancreatic phospholipase A2 (PLA2) is located at the entrance to the active site. To study the role of residue 31 in PLA2, six mutant enzymes were produced by site-directed mutagenesis, replacing Leu by either Trp, Arg, Ala, Thr, Ser or Gly. Direct binding studies indicated a three to six times greater affinity of the Trp31 PLA2 for both monomeric and micellar substrate analogs, relative to the wild-type enzyme. The other five mutants possess an unchanged affinity for monomers of the product analog n-decylphosphocholine and for micelles of the diacyl substrate analog rac-1,2-dioctanoylamino-dideoxy-glycero-3-phosphocholine. The affinities for micelles of the monoacyl product analog n-hexadecylphosphocholine were decreased 9-20 times for these five mutants. Kinetic studies with monomeric substrates showed that the mutants have Vmax values which range between 15 and 70% relative to the wild-type enzyme. The Vmax values for micelles of the zwitterionic substrate 1,2-dioctanoyl-sn-glycero-3-phosphocholine were lowered 3-50 times. The Km values for the monomeric substrate and the Km values for the micellar substrate were hardly affected in the case of five of the six mutants, but were considerably decreased when Trp was present at position 31. The results of these investigations point to a versatile role for the residue at position 31: involvement in the binding and orientating of monomeric substrate (analogs), involvement in the binding of the enzyme to micellar substrate analogs and possibly involvement in shielding the active site from excess water.     

Role of Tryptophan 95 in substrate specificity and structural stability of Sulfolobus solfataricus alcohol dehydrogenase

A mutant of the thermostable NAD⁺-dependent (S)-stereospecific alcohol dehydrogenase from Sulfolobus solfataricus (SsADH) which has a single substitution, Trp95Leu, located at the substrate binding pocket, was fully characterized to ascertain the role of Trp95 in discriminating between chiral secondary alcohols suggested by the wild-type SsADH crystallographic structure. The Trp95Leu mutant displays no apparent activity with short-chain primary and secondary alcohols and poor activity with aromatic substrates and coenzyme. Moreover, the Trp → Leu substitution affects the structural stability of the archaeal ADH, decreasing its thermal stability without relevant changes in secondary structure. The double mutant Trp95Leu/Asn249Tyr was also purified to assist in crystallographic analysis. This mutant exhibits higher activity but decreased affinity toward aliphatic alcohols, aldehydes as well as NAD⁺ and NADH compared to the wild-type enzyme. The crystal structure of the Trp95Leu/Asn249Tyr mutant apo form, determined at 2.0 Å resolution, reveals a large local rearrangement of the substrate site with dramatic consequences. The Leu95 side-chain conformation points away from the catalytic metal center and the widening of the substrate site is partially counteracted by a concomitant change of Trp117 side chain conformation. Structural changes at the active site are consistent with the reduced activity on substrates and decreased coenzyme binding.     

In vitro mutagenesis studies at the arginine residues of adenylate kinase. A revised binding site for AMP in the X-ray-deduced model

Although X-ray crystallographic and NMR studies have been made on the adenylate kinases, the substrate-binding sites are not unequivocally established. In an attempt to shed light on the binding sites for MgATP2- and for AMP2- in human cytosolic adenylate kinase (EC 2.7.4.3, hAK1), we have investigated the enzymic effects of replacement of the arginine residues (R44, R132, R138, and R149), which had been assumed by Pai et al. [Pai, E. F., Sachsenheimer, W., Schirmer, R. H., & Schulz, G. E. (1977) J. Mol. Biol. 114, 37-45] to interact with the phosphoryl groups of AMP2- and MgATP2-. With use of the site-directed mutagenesis method, point mutations were made in the artificial gene for hAK1 [Kim, H. J., Nishikawa, S., Tanaka, T., Uesugi, S., Takenaka, H., Hamada, M., & Kuby, S. A. (1989) Protein Eng. 2, 379-386] to replace these arginine residues with alanyl residues and yield the mutants R44A hAK1, R132A hAK1, R138A hAK1, and R149A hAK1. The resulting large increases in the Km,app values for AMP2- of the mutant enzymes, the relatively small increases in the Km,app values for MgATP2-, and the fact that the R132A, R138A, and R149A mutant enzymes proved to be very poor catalysts are consistent with the idea that the assigned substrate binding sites of Pai et al. (1977) have been reversed and that their ATP-binding site may be assigned as the AMP site.     

Comparison of adenosine 3':5'-monophosphate-dependent protein kinases from rabbit skeletal and bovine heart muscle.

Homogeneous preparations of adenosine 3':5'-monophosphate (cyclic AMP)-dependent protein kinase from rabbit skeletal (Peak I) and bovine heart muscle have been compared. Each enzyme has an S20,w value of 7.0. Each enzyme binds 2 mol of cyclic AMP per mol of enzyme and is dissociated in the presence of saturating concentrations of cyclic AMP into a demeric regulatory subunit-cyclic AMP complex and two catalytic subunits. The isolated subunits recombine, resulting in the formation of the original holoenzyme in each case. Several differences between the two enzymes were found. Different salt concentrations are necessary for elution of the respective enzyme from DEAE-cellulose. Their regulatory subunits differ with respect to their sedimentation constants and mobility on sodium dodecyl sulfate gel electrophoresis. The regulatory subunit of the heart enzyme is rapidly phosphorylated by MgATP but this does not occur with the skeletal muscle enzyme. MgATP is bound with high affinity only to the skeletal muscle enzyme. The enzymes have different apparent dissociation constants and Hill coefficients for cyclic AMP binding. With the skeletal muscle enzyme MgATP increases the dissociation constants for cyclic AMP about 10-fold and decreases the Hill coefficient, while with the heart enzyme phosphorylation decreases the cissociation constant for cyclic AMP 5- to 6-fold and increases the Hill coefficient. Different concentrations of cyclic AMP are required to dissociate the skeletal and heart muscle enzymes. The presence of MgATP increases the concentration of cyclic AMP required to dissociate the skeletal muscle enzyme but decreases the concentration necessary to dissociate the heart enzyme.     

Regulation of deoxyadenosine and nucleoside analog phosphorylation by human placental adenosine kinase

The enzymes responsible for the phosphorylation of deoxyadenosine and nucleoside analogs are important in the pathogenesis of adenosine deaminase deficiency and in the activation of specific anticancer and antiviral drugs. We examined the role of adenosine kinase in catalyzing these reactions using an enzyme purified 4000-fold (2.1 mumol/min/mg) from human placenta. The Km values of deoxyadenosine and ATP are 135 and 4 microM, respectively. Potassium and magnesium are absolute requirements for deoxyadenosine phosphorylation, and 150 mM potassium and 5 mM MgCl2 are critical for linear kinetics. With only 0.4 mM MgCl2 in excess of ATP levels, the Km for deoxyadenosine is increased 10-fold. ADP is a competitive inhibitor with a Ki of 13 microM with variable MgATP2-, while it is a mixed inhibitor with a Ki and Ki' of 600 and 92 microM, respectively, when deoxyadenosine is variable. AMP is a mixed inhibitor with Ki and Ki' of 177 and 15 microM, respectively, with variable deoxyadenosine; it is a non-competitive inhibitor with a Ki of 17 microM and Ki' of 27 microM with variable ATP. Adenosine kinase phosphorylates adenine arabinoside with an apparent Km of 1 mM using deoxyadenosine kinase assay conditions. The Km values for 6-methylmercaptopurine riboside and 5-iodotubercidin, substrates for adenosine kinase, are estimated to be 4.5 microM and 2.6 nM, respectively. Other nucleoside analogs are potent inhibitors of deoxyadenosine phosphorylation, but their status as substrates remains unknown. These data indicate that deoxyadenosine phosphorylation by adenosine kinase is primarily regulated by its Km and the concentrations of Mg2+, ADP, and AMP. The high Km values for phosphorylation of deoxyadenosine and adenine arabinoside suggest that adenosine kinase may be less likely to phosphorylate these nucleosides in vivo than other enzymes with lower Km values. Adenosine kinase appears to be important for adenosine analog phosphorylation where the Michaelis constant is in the low micromolar range.     

Identification of the tRNA anticodon recognition site of Escherichia coli methionyl-tRNA synthetase

We have previously shown that the anticodon of methionine tRNAs contains most, if not all, of the nucleotides required for specific recognition of tRNA substrates by Escherichia coli methionyl-tRNA synthetase [Schulman, L. H., & Pelka, H. (1988) Science 242, 765-768]. Previous cross-linking experiments have also identified a site in the synthetase that lies within 14 A of the anticodon binding domain [Leon, O., & Schulman, L. H. (1987) Biochemistry 26, 5416-5422]. In the present work, we have carried out site-directed mutagenesis of this domain, creating conservative amino acid changes at residues that contain side chains having potential hydrogen-bond donors or acceptors. Only one of these changes, converting Trp461----Phe, had a significant effect on aminoacylation. The mutant enzyme showed an approximately 60-100-fold increase in Km for methionine tRNAs, with little or no change in the Km for methionine or ATP or in the maximal velocity of the aminoacylation reaction. Conversion of the adjacent Pro460 to Leu resulted in a smaller increase in Km for tRNA(Mets), with no change in the other kinetic parameters. Examination of the interaction of the mutant enzymes with a series of tRNA(Met) derivatives containing base substitutions in the anticodon revealed sequence-specific interactions between the Phe461 mutant and different anticodons. Km values were highest for tRNA(mMet) derivatives containing the normal anticodon wobble base C. Base substitutions at this site decreased the Km for aminoacylation by the Phe461 mutant, while increasing the Km for the wild-type enzyme and for the Leu460 mutant to values greater than 100 microM.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effect of the epsilon-subunit on nucleotide binding to Escherichia coli F1-ATPase catalytic sites.

The influence of the epsilon-subunit on the nucleotide binding affinities of the three catalytic sites of Escherichia coli F1-ATPase was investigated, using a genetically engineered Trp probe in the adenine-binding subdomain (beta-Trp-331). The interaction between epsilon and F1 was not affected by the mutation. Kd for binding of epsilon to betaY331W mutant F1 was approximately 1 nM, and epsilon inhibited ATPase activity by 90%. The only nucleotide binding affinities that showed significant differences in the epsilon-depleted and epsilon-replete forms of the enzyme were those for MgATP and MgADP at the high-affinity catalytic site 1. Kd1(MgATP) and Kd1(MgADP) were an order of magnitude higher in the absence of epsilon than in its presence. In contrast, the binding affinities for MgATP and MgADP at sites 2 and 3 were similar in the epsilon-depleted and epsilon-replete enzymes, as were the affinities at all three sites for free ATP and ADP. Comparison of MgATP binding and hydrolysis parameters showed that in the presence as well as the absence of epsilon, Km equals Kd3. Thus, in both cases, all three catalytic binding sites have to be occupied to obtain rapid (Vmax) MgATP hydrolysis rates.     

Human salivary alpha-amylase Trp58 situated at subsite -2 is critical for enzyme activity.

The nonreducing end of the substrate-binding site of human salivary alpha-amylase contains two residues Trp58 and Trp59, which belong to beta2-alpha2 loop of the catalytic (beta/alpha)(8) barrel. While Trp59 stacks onto the substrate, the exact role of Trp58 is unknown. To investigate its role in enzyme activity the residue Trp58 was mutated to Ala, Leu or Tyr. Kinetic analysis of the wild-type and mutant enzymes was carried out with starch and oligosaccharides as substrates. All three mutants exhibited a reduction in specific activity (150-180-fold lower than the wild type) with starch as substrate. With oligosaccharides as substrates, a reduction in k(cat), an increase in K(m) and distinct differences in the cleavage pattern were observed for the mutants W58A and W58L compared with the wild type. Glucose was the smallest product generated by these two mutants in the hydrolysis oligosaccharides; in contrast, wild-type enzyme generated maltose as the smallest product. The production of glucose by W58L was confirmed from both reducing and nonreducing ends of CNP-labeled oligosaccharide substrates. The mutant W58L exhibited lower binding affinity at subsites -2, -3 and +2 and showed an increase in transglycosylation activity compared with the wild type. The lowered affinity at subsites -2 and -3 due to the mutation was also inferred from the electron density at these subsites in the structure of W58A in complex with acarbose-derived pseudooligosaccharide. Collectively, these results suggest that the residue Trp58 plays a critical role in substrate binding and hydrolytic activity of human salivary alpha-amylase.     

Functional role of the "aromatic cage" in human monoamine oxidase B: structures and catalytic properties of Tyr435 mutant proteins

Current structural results of several flavin-dependent amine oxidizing enzymes including human monoamine oxidases A and B (MAO A and MAO B) show aromatic amino acid residues oriented approximately perpendicular to the flavin ring, suggesting a functional role in catalysis. In the case of human MAO B, two tyrosyl residues (Y398 and Y435) are found in the substrate binding site on the re face of the covalent flavin ring [Binda et al. (2002) J. Biol. Chem. 277, 23973-23976]. To probe the functional significance of this structure, Tyr435 in MAO B was mutated with the amino acids Phe, His, Leu, or Trp, the mutant proteins expressed in Pichia pastoris, and purified to homogeneity. Each mutant protein contains covalent FAD and exhibits a high level of catalytic functionality. No major alterations in active site structures are detected on comparison of their respective crystal structures with that of WT enzyme. The relative k(cat)/K(m) values for each mutant enzyme show Y435 > Y435F = Y435L = Y435H > Y435W. A similar behavior is also observed with the membrane-bound forms of MAO A and MAO B (MAO A Y444 mutant enzymes are found to be unstable on membrane extraction). p-Nitrobenzylamine is found to be a poor substrate while p-nitrophenethylamine is found to be a good substrate for all WT and mutant forms of MAO B. Analysis of these kinetic and structural data suggests the function of the "aromatic cage" in MAO to include a steric role in substrate binding and access to the flavin coenzyme and to increase the nucleophilicity of the substrate amine moiety. These results are consistent with a proposed polar nucleophilic mechanism for catalytic amine oxidation.     

Roles of active site tryptophans in substrate binding and catalysis by alpha-1,3 galactosyltransferase

Aromatic amino acids are frequent components of the carbohydrate binding sites of lectins and enzymes. Previous structural studies have shown that in alpha-1,3 galactosyltransferase, the binding site for disaccharide acceptor substrates is encircled by four tryptophans, residues 249, 250, 314, and 356. To investigate their roles in enzyme specificity and catalysis, we expressed and characterized variants of the catalytic domain of alpha-1,3 galactosyltransferase with substitutions for each tryptophan. Substitution of glycine for tryptophan 249, whose indole ring interacts with the nonpolar B face of glucose or GlcNAc, greatly increases the K(m) for the acceptor substrate. In contrast, the substitution of tyrosine for tryptophan 314, which interacts with the beta-galactosyl moiety of the acceptor and UDP-galactose, decreases k(cat) for the galactosyltransferase reaction but does not affect the low UDP-galactose hydrolase activity. Thus, this highly conserved residue stabilizes the transition state for the galactose transfer to disaccharide but not to water. High-resolution crystallographic structures of the Trp(249)Gly mutant and the Trp(314)Tyr mutant indicate that the mutations do not affect the overall structure of the enzyme or its interactions with ligands. Substitutions for tryptophan 250 have only small effects on catalytic activity, but mutation of tryptophan 356 to threonine reduces catalytic activity for both transferase and hydrolase activities and reduces affinity for the acceptor substrate. This residue is adjacent to the flexible C-terminus that becomes ordered on binding UDP to assemble the acceptor binding site and influence catalysis. The results highlight the diverse roles of these tryptophans in enzyme action and the importance of k(cat) changes in modulating glycosyltransferase specificity.     

Effects of replacement of tryptophan-140 by phenylalanine or glycine on the function of Escherichia coli aspartate aminotransferase

Trp140 of E. coli aspartate aminotransferase has been converted to Phe or Gly by site-directed mutagenesis. As compared to the wild-type enzyme, either of the mutant enzymes showed 10- to 100-fold increase in Km's for natural dicarboxylic substrates, but did not show appreciable changes in Km's for aromatic substrates. Teh kcat values for dicarboxylic and aromatic substrates were greatly decreased by [Trp140----Gly] mutation, but were decreased to lesser extents by [Trp140----Phe] mutation. These findings suggested that N(1) of Trp140 may not be essential for catalysis, but may be partly involved in the binding of the distal carboxylate group of the dicarboxylic substrates.     

The amino terminus regulates binding to and activation of cGMP-dependent protein kinase

The allosteric regulation of binding to and the activation of cGMP-dependent protein kinase (cGMP kinase) was studied under identical conditions at 30 degrees C using three forms of cGMP-kinase which differed in the amino-terminal segment, e.g. native cGMP kinase, phosphorylated cGMP kinase which contained 1.4 +/- 0.4 mol phosphate/subunit and constitutively active cGMP kinase which lacked the amino-terminal dimerization domain. These three enzyme forms have identical kinetic constants, e.g. number of cGMP-binding sites, Km values for MgATP and the heptapeptide kemptide, and Vmax values. In the native enzyme, MgATP decreases the affinity for binding site 1. This effect is abolished by 1 M NaCl. In contrast, high concentrations of Kemptide increase the affinity of binding site 2 about fivefold. Under the latter conditions, identical Kd values of 0.2 microM were obtained for sites 1 and 2. Salt, MgATP and Kemptide do not affect the binding kinetics of the phosphorylated or the constitutively active enzyme, suggesting that allosteric regulation depends solely on the presence of a native amino-terminal segment. Cyclic GMP activates the native enzyme at Ka values which are identical with the Kd values for both binding sites. The activation of cGMP-dependent protein kinase is noncooperative but the Ka value depends on the substrate peptide concentration. These results show that the activity of cGMP kinase is primarily regulated by conformational changes within the amino-terminal domain.     

Function of conserved aromatic residues in the Gal/GalNAc-glycosyltransferase motif of UDP-GalNAc:polypeptide N-acetylgalactosaminyltransferase 1

UDP-GalNAc:polypeptide N-acetylgalactosaminyltransferases (GalNAc transferases), which initiate mucin-type O-glycan biosynthesis, have broad acceptor substrate specificities, and it is still unclear how they recognize peptides with different sequences. To increase our understanding of the catalytic mechanism of GalNAc-T1, one of the most ubiquitous isozymes, we studied the effect of substituting six conserved aromatic residues in the highly conserved Gal/GalNAc-glycosyltransferase motif with leucine on the catalytic properties of the enzyme. Our results indicate that substitutions of Trp302 and Phe325 have little impact on enzyme function and that substitutions of Phe303 and Tyr309 could be made with only limited impact on the interaction(s) with donor and/or acceptor substrates. By contrast, Trp328 and Trp316 are essential residues for enzyme functions, as substitution with leucine, at either site, led to complete inactivation of the enzymes. The roles of these tryptophan residues were further analyzed by evaluating the impact of substitutions with additional amino acids. All evaluated substitutions at Trp328 resulted in enzymes that were completely inactive, suggesting that the invariant Trp328 is essential for enzymatic activity. Trp316 mutant enzymes with nonaromatic replacements were again completely inactive, whereas two mutant enzymes containing a different aromatic amino acid, at position 316, showed low catalytic activity. Somewhat surprisingly, a kinetic analysis revealed that these two amino acid substitutions had a moderate impact on the enzyme's affinity for the donor substrate. By contrast, the drastically reduced affinity of the Trp316 mutant enzymes for the acceptor substrates suggests that Trp316 is important for this interaction.     

Enzymatic and fluorescence studies of four single-tryptophan mutants of rat testis fructose 6-phosphate,2-kinase:fructose 2,6-bisphosphatase.

In order to determine environments around four tryptophan residues, located in the N-terminus, in the kinase and in the phosphatase domains of rat testis Fru 6-P,2-kinase:Fru 2,6-bisphosphatase, mutant enzymes containing a single tryptophan were constructed by site-directed mutagenesis. The kinetic constants of these mutant enzymes were similar to those of the wild-type enzyme. The sum of the fluorescence intensities of the enzymes was 1.5 x that of the wild-type enzyme, and Trp 299, Trp 64, Trp 15, and Trp 320 contributed 38%, 28%, 17%, and 17%, respectively. The fluorescence polarization of the wild-type enzyme was significantly lower than any of the mutant enzymes, suggesting proximity of two tryptophan residues in the wild-type enzyme. The polarization in the presence of Fru 6-P affected only Trp 15, which suggested that it is located near the Fru 6-P binding site, but Trp 64 is not. Inactivation of both enzyme activities and unfolding of these enzymes in guanidine were monitored by activity assays and fluorescence intensities and maxima. Both Fru 6-P,2-kinase and Fru 2,6-bisphosphatase activities of all these enzymes were inactivated between 0.7 and 1 M guanidine. Enzymes containing Trp 64 or Trp 15 showed biphasic fractional unfolding curves, but those of Trp 299 or Trp 320 showed gradual steady changes. Fluorescence quenching by iodide indicated that Trp 64 was not accessible and that other Trp residues were only slightly accessible to solvent. These results suggest that all the Trp residues are in heterogeneous environments and that none are exposed on the protein surface.     

Replacement of an interdomain residue Val39 of Escherichia coli aspartate aminotransferase affects the catalytic competence without altering the substrate specificity of the enzyme

Three mutant Escherichia coli aspartate aminotransferases in which Val39 was changed to Ala, Leu, and Phe by site-directed mutagenesis were prepared and characterized. Among the three mutant and the wild-type enzymes, the Leu39 enzyme had the lowest Km values for dicarboxylic substrates. The Km values of the Ala39 enzyme for dicarboxylates were essentially the same as those of the wild-type (Val39) enzyme. These two mutant enzymes showed essentially the same kcat values for dicarboxylic substrates as did the wild-type enzyme. On the other hand, incorporation of a bulky side-chain at position 39 (Phe39 enzyme) decreased both the affinity (1/Km) and catalytic ability (kcat) toward dicarboxylic substrates. These results show that the position 39 residue is involved in the modulation of both the binding of dicarboxylic substrates to enzyme and the catalytic ability of the enzyme. Although the replacement of Val39 with other residues altered both the kcat and Km values toward various substrates including dicarboxylic and aromatic amino acids and the corresponding oxo acids, it did not alter the ratio of the kcat/Km value of the enzyme toward a dicarboxylic substrate to that for an aromatic substrate. The affinity for aromatic substrates was not affected by changing the residue at position 39. These data indicate that, although the side chain bulkiness of the residue at position 39 correlates well with the activity toward aromatic substrates in the sequence alignment of several aminotransferases [Seville, M., Vincent M.G., & Hahn, K. (1988) Biochemistry 27, 8344-8349], the residue does not seem to be involved in the recognition of aromatic substrates.