Conserved catalytic residues of the ALDH1L1 aldehyde dehydrogenase domain control binding and discharging of the coenzyme

The C-terminal domain (C(t)-FDH) of 10-formyltetrahydrofolate dehydrogenase (FDH, ALDH1L1) is an NADP(+)-dependent oxidoreductase and a structural and functional homolog of aldehyde dehydrogenases. Here we report the crystal structures of several C(t)-FDH mutants in which two essential catalytic residues adjacent to the nicotinamide ring of bound NADP(+), Cys-707 and Glu-673, were replaced separately or simultaneously. The replacement of the glutamate with an alanine causes irreversible binding of the coenzyme without any noticeable conformational changes in the vicinity of the nicotinamide ring. Additional replacement of cysteine 707 with an alanine (E673A/C707A double mutant) did not affect this irreversible binding indicating that the lack of the glutamate is solely responsible for the enhanced interaction between the enzyme and the coenzyme. The substitution of the cysteine with an alanine did not affect binding of NADP(+) but resulted in the enzyme lacking the ability to differentiate between the oxidized and reduced coenzyme: unlike the wild-type C(t)-FDH/NADPH complex, in the C707A mutant the position of NADPH is identical to the position of NADP(+) with the nicotinamide ring well ordered within the catalytic center. Thus, whereas the glutamate restricts the affinity for the coenzyme, the cysteine is the sensor of the coenzyme redox state. These conclusions were confirmed by coenzyme binding experiments. Our study further suggests that the binding of the coenzyme is additionally controlled by a long-range communication between the catalytic center and the coenzyme-binding domain and points toward an α-helix involved in the adenine moiety binding as a participant of this communication.     

Function of arginine-166 in the active site of Escherichia coli alkaline phosphatase

The function of arginine residue 166 in the active site of Escherichia coli alkaline phosphatase was investigated by site-directed mutagenesis. Two mutant versions of alkaline phosphatase, with either serine or alanine in the place of arginine at position 166, were generated by using a specially constructed M13 phage carrying the wild-type phoA gene. The mutant enzymes with serine and alanine at position 166 have very similar kinetic properties. Under conditions of no external phosphate acceptor, the kcat for the mutant enzymes decreases by approximately 30-fold while the Km increases by less than 2-fold. When kinetic measurements are carried out in the presence of a phosphate acceptor, 1.0 M Tris, the kcat for the mutant enzymes is reduced by less than 3-fold, while the Km increases by more than 50-fold. For both mutant enzymes, in either the absence or the presence of a phosphate acceptor, the catalytic efficiency as measured by the kcat/Km ratio decreases by approximately 50-fold as compared to the wild type. Measurements of the Ki for inorganic phosphate show an increase of approximately 50-fold for both mutants. Phenylglyoxal, which inactivates the wild-type enzyme, does not inactivate the Arg-166----Ala enzyme. This result indicates that Arg-166 is the same arginine residue that when chemically modified causes loss of activity [Daemen, F.J.M., & Riordan, J.F. (1974) Biochemistry 13, 2865-2871]. The data reported here suggest that although Arg-166 is important for activity is not essential. The analysis of the kinetic data also suggests that the loss of arginine-166 at the active site of alkaline phosphatase has two different effects on the enzyme. First, the binding of the substrate, and phosphate as a competitive inhibitor, is reduced; second, the rate of hydrolysis of the covalent phosphoenzyme may be diminished.     

Site-directed mutagenesis of human nucleoside triphosphate diphosphohydrolase 3: the importance of residues in the apyrase conserved regions

Ecto-nucleoside triphosphate diphosphohydrolase 3 (eNTPDase-3, also known as HB6 and CD39L3) is a membrane-associated ecto-apyrase. Only a few functionally significant residues have been elucidated for this enzyme, as well as for the whole family of eNTPDase enzymes. Four highly conserved regions (apyrase conserved regions, ACRs) have been identified in all the members of eNTPDase family, suggesting their importance for biological activity. In an effort to identify those amino acids important for the catalytic activity of the eNTPDase family, as well as those residues mediating substrate specificity, 11 point mutations of 7 amino acid residues in ACR1-4 of eNTPDase-3 were constructed by site-directed mutagenesis. Mutagenesis of asparagine 191 to alanine (N191A), glutamine 226 to alanine (Q226A), and arginine 67 to glycine (R67G) resulted in an increase in the rates of hydrolysis of nucleoside diphosphates relative to triphosphates. Mutagenesis of arginine 146 to proline (R146P) essentially converted the eNTPDase-3 ecto-apyrase to an ecto-ATPase (eNTPDase-2), mainly by decreasing the hydrolysis rates for nucleoside diphosphates. The Q226A mutant exhibited a change in the divalent cation requirement for nucleotidase activity relative to the wild-type and the other mutants. Mutation of glutamate 182 to aspartate (E182D) or glutamine (E182Q), and mutation of serine 224 to alanine (S224A) completely abolished enzymatic activity. We conclude that the residues corresponding to eNTPDase-3 glutamate 182 in ACR3 and serine 224 in ACR4 are essential for the enzymatic activity of eNTPDases in general, and that arginine 67, arginine 146, asparagine 191, and glutamine 226 are important for determining substrate specificity for human ecto-nucleoside triphosphate diphosphohydrolase 3.     

Mutational analysis of substrate recognition by human arginase type I--agmatinase activity of the N130D variant

Upon mutation of Asn130 to aspartate, the catalytic activity of human arginase I was reduced to approximately 17% of wild-type activity, the Km value for arginine was increased approximately 9-fold, and the kcat/Km value was reduced approximately 50-fold. The kinetic properties were much less affected by replacement of Asn130 with glutamine. In contrast with the wild-type and N130Q enzymes, the N130D variant was active not only on arginine but also on its decarboxylated derivative, agmatine. Moreover, it exhibited no preferential substrate specificity for arginine over agmatine (kcat/Km values of 2.48 x 10(3) M(-1) x s(-1) and 2.14 x 10(3) M(-1) x s(-1), respectively). After dialysis against EDTA and assay in the absence of added Mn2+, the N130D mutant enzyme was inactive, whereas about 50% full activity was expressed by the wild-type and N130Q variants. Mutations were not accompanied by changes in the tryptophan fluorescence properties, thermal stability or chromatographic behavior of the enzyme. An active site conformational change is proposed as an explanation for the altered substrate specificity and low catalytic efficiency of the N130D variant.     

Alteration of aspartate 101 in the active site of Escherichia coli alkaline phosphatase enhances the catalytic activity

The function of aspartic acid residue 101 in the active site of Escherichia coli alkaline phosphatase was investigated by site-specific mutagenesis. A mutant version of alkaline phosphatase was constructed with alanine in place of aspartic acid at position 101. When kinetic measurements are carried out in the presence of a phosphate acceptor, 1.0 M Tris, pH 8.0, both the kcat and the Km for the mutant enzyme increase by approximately 2-fold, resulting in almost no change in the kcat/Km ratio. Under conditions of no external phosphate acceptor and pH 8.0, both the kcat and the Km for the mutant enzyme decrease by approximately 2-fold, again resulting in almost no change in the kcat/Km ratio. The kcat for the hydrolysis of 4-methyl-umbelliferyl phosphate and p-nitrophenyl phosphate are nearly identical for both the wild-type and mutant enzymes, as is the Ki for inorganic phosphate. The replacement of aspartic acid 101 by alanine does have a significant effect on the activity of the enzyme as a function of pH, especially in the presence of a phosphate acceptor. At pH 9.4 the mutant enzyme exhibits 3-fold higher activity than the wild-type. The mutant enzyme also exhibits a substantial decrease in thermal stability: it is half inactivated by treatment at 49 degrees C for 15 min compared to 71 degrees C for the wild-type enzyme. The data reported here suggest that this amino acid substitution alters the rates of steps after the formation of the phospho-enzyme intermediate.(ABSTRACT TRUNCATED AT 250 WORDS)     

Partial reactions of bacterial D-amino acid transaminase with asparagine substituted for the lysine that binds coenzyme pyridoxal 5'-phosphate.

In bacterial D-amino acid transaminase (EC 2.6.1.21) replacement of Lys-145, which is covalently linked to the coenzyme pyridoxal 5'-phosphate in the wild-type enzyme, by an Asn residue gave a mutant enzyme (K145N) that slowly performed each half-reaction, as determined by spectral measurements. With the wild-type enzyme, the kinetics of these events were so rapid that pre-steady-state conditions were needed for their determination. The internal aldimine between coenzyme and Lys-145 was rapidly reduced with NaCNBH3 in the wild-type enzyme, whereas in the mutant enzyme the coenzyme, which is not covalently linked to the protein, was more resistant to reduction; the reduced forms of both wild-type and mutant enzymes were inactive. With large amounts of the K145N mutant enzyme and either amino acid or keto acid substrate alone, the formation of some reaction intermediates, i.e., the external aldimine with D-alanine and the ketimine with alpha-ketoglutarate, can be measured by conventional spectroscopy. Suicide substrates also induced slow spectral shifts of the E-PLP form of the enzyme. For the K145N enzyme, exogenous amines affected only the rate of the transaldimination but not the removal of the alpha-proton of the substrate. These results suggest that in the mutant enzyme some amino acid side chain other than Lys-145 performs this function. In order to identify this site, the K145N mutant enzyme was completely inactivated by the radiolabeled suicide substrate D-serine. Peptide mapping of tryptic digests showed that Lys-267 was the modified site.(ABSTRACT TRUNCATED AT 250 WORDS)     

Lysine-60 in the regulatory chain of Escherichia coli aspartate transcarbamoylase is important for the discrimination between CTP and ATP

Lysine-60 in the regulatory chain of aspartate transcarbamoylase has been changed to an alanine by site-specific mutagenesis. The resulting enzyme exhibits activity and homotropic cooperativity identical with those of the wild-type enzyme. The substrate concentration at half the maximal observed specific activity decreases from 13.3 mM for the wild-type enzyme to 9.6 mM for the mutant enzyme. ATP activates the mutant enzyme to the same extent that it does the wild-type enzyme, but the concentration of ATP required to reach half of the maximal activation is reduced approximately 5-fold for the mutant enzyme. CTP at a concentration of 10 mM does not inhibit the mutant enzyme, while under the same conditions CTP at concentrations less than 1 mM will inhibit the wild-type enzyme to the maximal extent. Higher concentrations of CTP result in some inhibition of the mutant enzyme that may be due either to hetertropic effects at the regulatory site or to competitive binding at the active site. UTP alone or in the presence of CTP has no effect on the mutant enzyme. Kinetic competition experiments indicate that CTP is still able to displace ATP from the regulatory sites of the mutant enzyme. Binding measurements by equilibrium dialysis were used to estimate a lower limit on the dissociation constant for CTP binding to the mutant enzyme (greater than 1 x 10(-3) M). Equilibrium competition binding experiments between ATP and CTP verified that CTP still can bind to the regulatory site of the enzyme. For the mutant enzyme, CTP affinity is reduced approximately 100-fold, while ATP affinity is increased by 5-fold.(ABSTRACT TRUNCATED AT 250 WORDS)     

Induced mutations in cassava using somatic embryos and the identification of mutant plants with altered starch yield and composition

A cyclic somatic embryogenic system was used to induce mutations in cassava variety PRC 60a in vitro. Globular-stage somatic embryos were selected as suitable experimental materials, and 50 Gy of -rays was determined to be the optimal dose for inducing mutations. During subsequent field trials, more than 50% of the regenerated mutant lines varied morphologically from wild-type plants. Consequently, we used this approach to induce genetic variability for obtaining novel cassava cultivars. Among the different mutant lines obtained, lines S14 and S15 showed large morphological variations. In 10-month-old S14 and S15 mutant lines, storage root yield was reduced 17-fold and 60-fold, respectively, compared to wild-type plants, while the storage roots of S15 mutant plants also exhibited an almost 50% decrease in starch content and a significant reduction (30%) in amylose content. These two features were observed throughout the different developmental stages of the storage roots in S15 plants.Abbreviations BA 6-Benzylaminopurine - 2,4-D 2,4-Dichlorophenoxyacetic acid - EMS Ethylmethanesulfonate - IBA Indole-3-butyric acid     

Identification of arginine residues important for the activity of Escherichia coli signal peptidase I

Escherichia coil signal peptidase I (leader peptidase, SPase I) is an integral membrane serine protease that catalyzes the cleavage of signal (leader) peptides from pre-forms of membrane or secretory proteins. We previously demonstrated that E. coil SPase I was significantly inactivated by reaction with phenylglyoxal with concomitant modification of three to four of the total 17 arginine residues in the enzyme. This result indicated that several arginine residues are important for the optimal activity of the enzyme. In the present study, we have constructed 17 mutants of the enzyme by site-directed mutagenesis to investigate the role of individual arginine residues in the enzyme. Mutation of Arg127, Arg146, Arg198, Arg199, Arg226, Arg236, Arg275, Arg282, and Arg295 scarcely affected the enzyme activity in vivo and in vitro. However, the enzymatic activity toward a synthetic substrate was significantly decreased by replacements of Arg77, Arg222, Arg315, or Arg318 with alanine/lysine. The kcat values of the R77A, R77K, R222A, R222K, R315A, R318A, and R318K mutant enzymes were about 5.5-fold smaller than that of the wild-type enzyme, whereas the Km values of these mutant enzymes were almost identical with that of the wild-type. Moreover, the complementing abilities in E. Arg222, Arg315, coil IT41 were lost completely when Arg77, or Arg318 was replaced with alanine/lysine. The circular dichroism spectra and other enzymatic properties of these mutants were comparable to those of the wild-type enzyme, indicating no global conformational changes. However, the thermostability of R222A, R222K, R315A, and R318K was significantly lower compared to the wild type. Therefore, Arg77, Arg222, Arg315, and Arg318 are thought to be important for maintaining the proper and stable conformation of SPase I.     

Arginine 49 is a bifunctional residue important in catalysis and biosynthesis of monomeric sarcosine oxidase: a context-sensitive model for the electrostatic impact of arginine to lysine mutations

Monomeric sarcosine oxidase (MSOX) contains covalently bound FAD and catalyzes the oxidative demethylation of sarcosine ( N-methylglycine). The side chain of Arg49 is in van der Waals contact with the si face of the flavin ring; sarcosine binds just above the re face. Covalent flavin attachment requires a basic residue (Arg or Lys) at position 49. Although flavinylation is scarcely affected, mutation of Arg49 to Lys causes a 40-fold decrease in k cat and a 150-fold decrease in k cat/ K m sarcosine. The overall structure of the Arg49Lys mutant is very similar to wild-type MSOX; the side chain of Lys49 in the mutant is nearly congruent to that of Arg49 in the wild-type enzyme. The Arg49Lys mutant exhibits several features consistent with a less electropositive active site: (1) Charge transfer bands observed for mutant enzyme complexes with competitive inhibitors absorb at higher energy than the corresponding wild-type complexes. (2) The p K a for ionization at N(3)H of FAD is more than two pH units higher in the mutant than in wild-type MSOX. (3) The reduction potential of the oxidized/radical couple in the mutant is 100 mV lower than in the wild-type enzyme. The lower reduction potential is likely to be a major cause of the reduced catalytic activity of the mutant. Electrostatic interactions with Arg49 play an important role in catalysis and covalent flavinylation. A context-sensitive model for the electrostatic impact of an arginine to lysine mutation can account for the dramatically different consequences of the Arg49Lys mutation on MSOX catalysis and holoenzyme biosysnthesis.     

Site-directed mutations of arginine 65 at the periphery of the active site cleft of yeast 3-phosphoglycerate kinase enhance the catalytic activity and eliminate anion-dependent activation.

The function of arginine 65, a conserved residue located at the periphery of the active site cleft in yeast 3-phosphoglycerate kinase (PGK), has been investigated by site-directed mutagenesis. Mutant enzymes with glutamine, serine and alanine at position 65 all have very similar kinetic properties. The maximum velocities, determined in the absence of sulfate anion, are approximately 100% higher than the Vmax of wild-type PGK. The Km values are increased 2- to 3-fold for ATP and 5- to 6-fold for 3-phosphoglycerate (3PG). These results demonstrate that arginine 65 is not essential for catalysis. In contrast to wild-type enzyme, the mutants are not activated by sulfate ions. In addition, steady-state kinetic experiments indicate that the mutants are no longer activated by high concentrations of either 3PG or ATP. The dissociation constants for anions were determined by spectral titrations of the R65Q mutant labeled with a chromophoric probe. The Kd for 3PG is increased 6-fold, as compared to wild-type PGK, whereas the Kd for ATP is essentially unchanged. The Kd for sulfate is decreased less than 2-fold. The suppression of substrate- and sulfate-dependent activation suggests that arginine 65 participates in the regulatory mechanism responsible for activation of the enzyme.     

Role of aspartate 400, arginine 262, and arginine 401 in the catalytic mechanism of human coproporphyrinogen oxidase

Coproporphyrinogen oxidase (CPO) is the sixth enzyme in the heme biosynthetic pathway, catalyzing two sequential oxidative decarboxylations of propionate moieties on coproporphyrinogen-III forming protoporphyrinogen-IX through a monovinyl intermediate, harderoporphyrinogen. Site-directed mutagenesis studies were carried out on three invariant amino acids, aspartate 400, arginine 262, and arginine 401, to determine residue contribution to substrate binding and/or catalysis by human recombinant CPO. Kinetic analyses were performed on mutant enzymes incubated with three substrates, coproporphyrinogen-III, harderoporphyrinogen, or mesoporphyrinogen-VI, in order to determine catalytic ability to perform the first and/or second oxidative decarboxylation. When Asp400 was mutated to alanine no divinyl product was detected, but the production of a small amount of monovinyl product suggested the K(m) value for coproporphyrinogen-III did not change significantly compared to the wild-type enzyme. Upon mutation of Arg262 to alanine, CPO was again a poor catalyst for the production of a divinyl product, with a catalytic efficiency <0.01% compared to wild-type, including a 15-fold higher K(m) for coproporphyrinogen-III. The efficiency of divinyl product formation for mutant enzyme Arg401Ala was approximately 3% compared to wild-type CPO, with a threefold increase in the K(m) value for coproporphyrinogen-III. These data suggest Asp400, Arg262, and Arg401 are active site amino acids critical for substrate binding and/or catalysis. Possible roles for arginine 262 and 401 include coordination of carboxylate groups of coproporphyrinogen-III, while aspartate 400 may initiate deprotonation of substrate, resulting in an oxidative decarboxylation.     

The structure of Apo R268A human aldose reductase: hinges and latches that control the kinetic mechanism

Aldose reductase (AR) catalyzes the NADPH-dependent reduction of glucose and other sugars to their respective sugar alcohols. The NADP+/NADPH exchange is the rate-limiting step for this enzyme and contributes in varying degrees to the catalytic rates of other aldo-keto reductase superfamily enzymes. The mutation of Arg268 to alanine in human recombinant AR removes one of the ligands of the C2-phosphate of NADP+ and markedly reduces the interaction of the apoenzyme with the nucleotide. The crystal structure of human R268A apo-aldose reductase determined to a resolution of 2.1 A is described. The R268A mutant enzyme has similar kinetic parameters to the wild-type enzyme for aldehyde substrates, yet has greatly reduced affinity for the nucleotide substrate which greatly facilitates its crystallization in the apoenzyme form. The apo-structure shows that a high temperature factor loop (between residues 214 and 226) is displaced by as much as 17 A in a rigid body fashion about Gly213 and Ser226 in the absence of the nucleotide cofactor as compared to the wild-type holoenzyme structure. Several factors act to stabilize the NADPH-holding loop in either the 'open' or 'closed' conformations: (1) the presence and interactions of the nucleotide cofactor, (2) the residues surrounding the Gly213 and Ser226 hinges which form unique hydrogen bonds in the 'open' or 'closed' structure, and (3) the Trp219 "latch" residue which interacts with an arginine residue, Arg293, in the 'open' conformation or with a cysteine residue, Cys298, in the 'closed' conformation. Several mutations in and around the high temperature factor loop are examined to elucidate the role of the loop in the mechanism by which aldose reductase binds and releases its nucleotide substrate.     

Substitution of arginine for histidine-47 in the coenzyme binding site of yeast alcohol dehydrogenase I

Molecular modeling of alcohol dehydrogenase suggests that His-47 in the yeast enzyme (His-44 in the protein sequence, corresponding to Arg-47 in the horse liver enzyme) binds the pyrophosphate of the NAD coenzyme. His-47 in the Saccharomyces cerevisiae isoenzyme I was substituted with an arginine by a directed mutation. Steady-state kinetic results at pH 7.3 and 30 degrees C of the mutant and wild-type enzymes were consistent with an ordered Bi-Bi mechanism. The substitution decreased dissociation constants by 4-fold for NAD+ and 2-fold for NADH while turnover numbers were decreased by 4-fold for ethanol oxidation and 6-fold for acetaldehyde reduction. The magnitudes of these effects are smaller than those found for the same mutation in the human liver beta enzyme, suggesting that other amino acid residues in the active site modulate the effects of the substitution. The pH dependencies of dissociation constants and other kinetic constants were similar in the two yeast enzymes. Thus, it appears that His-47 is not solely responsible for a pK value near 7 that controls activity and coenzyme binding rates in the wild-type enzyme. The small substrate deuterium isotope effect above pH 7 and the single exponential phase of NADH production during the transient oxidation of ethanol by the Arg-47 enzyme suggest that the mutation makes an isomerization of the enzyme-NAD+ complex limiting for turnover with ethanol.     

Reversal of the extreme coenzyme selectivity of Clostridium symbiosum glutamate dehydrogenase

Active-site mutants of glutamate dehydrogenase from Clostridium?symbiosum have been designed and constructed and the effects on coenzyme preference evaluated by detailed kinetic measurements. The triple mutant F238S/P262S/D263K shows complete reversal in coenzyme selectivity from NAD(H) to NADP(H) with retention of high levels of catalytic activity for the new coenzyme. For oxidized coenzymes, k(cat) /K(m) ratios of the wild-type and triple mutant enzyme indicate a shift in preference of approximately 1.6?×?10(7) -fold, from ～?80?000-fold in favour of NAD(+) to ～?200-fold in favour of NADP(+) . For reduced coenzymes the corresponding figure is 1.7?×?10(4) -fold, from ～?1000-fold in favour of NADH to ～?17-fold in favour of NADPH. A fourth mutation (N290G), previously identified as having a potential bearing on coenzyme specificity, did not engender any further shift in preference when incorporated into the triple mutant, despite having a significant effect when expressed as a single mutant.     

Reduced ability of C-type natriuretic peptide (CNP) to activate natriuretic peptide receptor B (NPR-B) causes dwarfism in lbab -/- mice

C-type natriuretic peptide (CNP) stimulates endochondrial ossification by activating the transmembrane guanylyl cyclase, natriuretic peptide receptor-B (NPR-B). Recently, a spontaneous autosomal recessive mutation that causes severe dwarfism in mice was identified. The mutant, called long bone abnormality (lbab), contains a single point mutation that converts an arginine to a glycine in a conserved coding region of the CNP gene, but how this mutation affects CNP activity has not been reported. Here, we determined that 30-fold to greater than 100-fold more CNP(lbab) was required to activate NPR-B as compared to wild-type CNP in whole cell cGMP elevation and membrane guanylyl cyclase assays. The reduced ability of CNP(lbab) to activate NPR-B was explained, at least in part, by decreased binding since 10-fold more CNP(lbab) than wild-type CNP was required to compete with [(125)I][Tyr(0)]CNP for receptor binding. Molecular modeling suggested that the conserved arginine is critical for binding to an equally conserved acidic pocket in NPR-B. These results indicate that reduced binding to and activation of NPR-B causes dwarfism in lbab(-/-) mice.     

Aminoethylcysteine can replace the function of the essential active site lysine of Pseudomonas mevalonii 3-hydroxy-3-methylglutaryl coenzyme A reductase.

The biodegradative 3-hydroxy-3-methylglutaryl coenzyme A (HMG-CoA) reductase of Pseudomonas mevalonii catalyzes the NAD(+)-dependent conversion of (S)-HMG-CoA to (R)-mevalonate. Crystallographic analysis of abortive ternary complexes of this enzyme revealed lysine 267 located at a position in the active site, suggesting that it might serve as the general acid/base for catalysis. Site-directed mutagenesis and subsequent chemical derivatization were therefore employed to investigate this active site lysine. Replacement of lysine 267 by alanine, histidine, or arginine resulted in mutant enzymes that lacked detectable activity. Lysine 267 was next replaced by the lysine analogues aminoethylcysteine and carboxyamidomethylcysteine. Using instead of the wild-type enzyme the fully active, cysteine-free mutant enzyme C156A/C296A, lysine 267 was first replaced by cysteine. Cysteine 267 of mutant enzyme C156A/C296A/K267C was then treated with bromoethylamine or iodoacetamide to insert aminoethylcysteine (AEC) or carboxyamidomethylcysteine at position 267. The carboxyamidomethylcysteine derivative was inactive, whereas mutant enzyme C156A/C296A/K267AEC exhibited high catalytic activity. That aminoethylcysteine, but not other basic amino acids, can replace the function of lysine 267 documents both the importance of this residue and the requirement for a precisely positioned positive charge at the active site of the enzyme.     

Mutation of amino acids in the alpha 1,3-fucosyltransferase motif affects enzyme activity and Km for donor and acceptor substrates

Alpha 1,3-fucosyltransferases (FucT) share a conserved amino acid sequence designated the alpha 1,3 FucT motif that has been proposed to be important for nucleotide sugar binding. To evaluate the importance of the amino acids in this motif, each of the alpha 1,3 FucT motif amino acids was replaced with alanine (alanine scanning mutagenesis) in human FucT VI, and the resulting mutant proteins were analyzed for enzyme activity and kinetically characterized in those cases in which the mutant protein had sufficient activity. Two of the mutant proteins were inactive, six had less than 1% of wild-type activity, and four had approximately 10-50% of wild-type enzyme activity. Three of the mutant proteins with significant enzyme activity had substantially larger Km (5 to 15 times) for GDP-fucose than FucT VI wild-type enzyme. The fourth mutant protein with significant enzyme activity (S249A) had a Km at least 10 times larger than wild-type FucT VI for the acceptor substrate, with only a slightly larger (2-3 times) Km for GDP-fucose. Thus mutation of any of the amino acids within the alpha 1,3 FucT motif to Ala affects alpha 1,3-FucT activity, and substitution of Ala for some of the alpha 1,3 FucT motif amino acids results in proteins with altered kinetic constants for both the acceptor and donor substrates. Secondary structure prediction suggests a helix-loop-helix fold for the alpha 1,3 FucT motif, which can be used to rationalize the effects of mutations in terms of 3D structure.     

Role of Asp222 in the catalytic mechanism of Escherichia coli aspartate aminotransferase: the amino acid residue which enhances the function of the enzyme-bound coenzyme pyridoxal 5'-phosphate.

Asp222 is an invariant residue in all known sequences of aspartate aminotransferases from a variety of sources and is located within a distance of strong ionic interaction with N(1) of the coenzyme, pyridoxal 5'-phosphate (PLP), or pyridoxamine 5'-phosphate (PMP). This residue of Escherichia coli aspartate aminotransferase was replaced by Ala, Asn, or Glu by site-directed mutagenesis. The PLP form of the mutant enzyme D222E showed pH-dependent spectral changes with a pKa value of 6.44 for the protonation of the internal aldimine bond, slightly lower than that (6.7) for the wild-type enzyme. In contrast, the internal aldimine bond in the D222A or D222N enzyme did not titrate over the pH range 5.3-9.5, and a 430-nm band attributed to the protonated aldimine persisted even at high pH. The binding affinity of the D222A and D222N enzymes for PMP decreased by 3 orders of magnitude as compared to that of the wild-type enzyme. Pre-steady-state half-transamination reactions of all the mutant enzymes with substrates exhibited anomalous progress curves comprising multiphasic exponential processes, which were accounted for by postulating several kinetically different enzyme species for both the PLP and PMP forms of each mutant enzyme. While the replacement of Asp222 by Glu yielded fairly active enzyme species, the replacement by Ala and Asn resulted in 8600- and 20,000-fold decreases, respectively, in the catalytic efficiency (kmax/Kd value for the most active species of each mutant enzyme) in the reactions of the PLP form with aspartate. In contrast, the catalytic efficiency of the PMP form of the D222A or D222N enzyme with 2-oxoglutarate was still retained at a level as high as 2-10% of that of the wild-type enzyme. The presteady-state reactions of these two mutant enzymes with [2-2H]aspartate revealed a deuterium isotope effect (kH/kD = 6.0) greater than that [kH/kD = 2.2; Kuramitsu, S., Hiromi, K., Hayashi, H., Morino, Y., & Kagamiyama, H. (1990) Biochemistry 29, 5469-5476] for the wild-type enzyme. These findings indicate that the presence of a negatively charged residue at position 222 is particularly critical for the withdrawal of the alpha-proton of the amino acid substrate and accelerates this rate-determining step by about 5 kcal.mol-1. Thus it is concluded that Asp222 serves as a protein ligand tethering the coenzyme in a productive mode within the active site and stabilizes the protonated N(1) of the coenzyme to strengthen the electron-withdrawing capacity of the coenzyme.