The role of residues outside the active site: structural basis for function of C191 mutants of Escherichia coli aspartate aminotransferase

In previous kinetic studies of Escherichia coli aspartate aminotransferase, it was determined that some substitutions of conserved cysteine 191, which is located outside of the active site, altered the kinetic parameters of the enzyme (Gloss,L.M., Spencer,D. E. and Kirsch,J.F., 1996, Protein Struct. Funct. Genet., 24, 195-208). The mutations resulted in an alkaline shift of 0.6-0.8 pH units for the pK(a) of the internal aldimine between the PLP cofactor and Lys258. The change in the pK(a) affected the pH dependence of the k(cat)/K(m) (aspartate) values for the mutant enzymes. To help to understand these observations, crystal structures of five mutant forms of E.coli aspartate aminotransferase (the maleate complexes of C191S, C191F, C191Y and C191W, and C191S without maleate) were determined at about 2 A resolution in the presence of the pyridoxal phosphate cofactor. The overall three-dimensional fold of each mutant enzyme is the same as that of the wild-type protein, but there is a rotation of the mutated side chain around its C(alpha)-C(beta) bond. This side chain rotation results in a change in the pattern of hydrogen bonding connecting the mutant residue and the protonated Schiff base of the cofactor, which could account for the altered pK(a) of the Schiff base imine nitrogen that was reported previously. These results demonstrate how residues outside the active site can be important in helping determine the subtleties of the active site amino acid geometries and interactions and how mutations outside the active site can have effects on catalysis. In addition, these results help explain the surprising result previously reported that, for some mutant proteins, replacement of a buried cysteine with an aromatic side chain did not destabilize the protein fold. Instead, rotation around the C(alpha)-C(beta) bond allowed each large aromatic side chain to become buried in a nearby pocket without large changes in the enzyme's backbone geometry.     

Substitution of a lysyl residue for arginine 386 of Escherichia coli aspartate aminotransferase

Substitution of a lysyl residue for Arg-386 of Escherichia coli aspartate aminotransferase resulted in an extensive decrease in Vmax values (0.8% with the aspartate-2-oxoglutarate pair and 0.2% with the glutamate-oxalacetate pair, compared with the corresponding values for the wild-type enzyme). Kinetic analysis of the four sets of half-reactions, the pyridoxal form of the enzyme with aspartate or glutamate and the pyridoxamine form with 2-oxoglutarate or oxalacetate, allowed us to define the independent effect of the mutation on the reactivity of each substrate. Decrease in the first order rate constant (kmax) was more pronounced in the reactions with five-carbon substrates (glutamate and 2-oxoglutarate) than in those with four-carbon substrates (aspartate and oxalacetate), while the increase in the apparent dissociation constant (Kd) was greater for four-carbon substrates than for five-carbon substrates. The decrease of overall catalytic efficiency as judged by the values, kmax/Kd, was more pronounced in the reactions with five-carbon substrates than in those with four-carbon substrates. Affinities for substrate analogs such as succinate, glutarate, 2-methylaspartate, and erythro-3-hydroxyaspartate, were also considerably decreased by the mutation of the enzyme. These findings indicate that the side chain of the lysyl residue, although it bears a positive charge similar to that of the arginyl residue, is not structurally adequate for the productive binding of a substrate during catalysis.     

Determination of active site residues in Escherichia coli endonuclease VIII.

Endonuclease VIII from Escherichia coli is a DNA glycosylase/lyase that removes oxidatively damaged bases. EndoVIII is a functional homologue of endonuclease III, but a sequence homologue of formamidopyrimidine-DNA glycosylase (Fpg). Using multiple sequence alignments, we have identified six target residues in endoVIII that may be involved in the enzyme's glycosylase and/or lyase functions: the N-terminal proline, and five acidic residues that are completely conserved in the endoVIII-Fpg proteins. To investigate the contribution of these residues, site-directed mutagenesis was used to create seven mutants: P2T, E3D, E3Q, E6Q, D129N, D160N, and E174Q. Each mutant was assayed both for lyase activity on abasic (AP) sites and for glycosylase/lyase activity on 5-hydroxyuracil, thymine glycol, and gamma-irradiated DNA with multiple lesions. The P2T mutant did not have lyase or glycosylase/lyase activity but could efficiently form Schiff base intermediates on AP sites. E6Q, D129N, and D160N behaved essentially as endoVIII in all assays. E3D, E3Q, and E174Q retained significant AP lyase activity but had severely diminished or abolished glycosylase/lyase activities on the DNA lesions tested. These studies provide detailed predictions concerning the active site of endoVIII.     

The active site of Sulfolobus solfataricus aspartate aminotransferase

Aspartate aminotransferase from the archaebacterium Sulfolobus solfataricus binds pyridoxal 5' phosphate, via an aldimine bond, with Lys-241. This residue has been identified by reducing the enzyme in the pyridoxal form with sodium cyanoboro[3H]hydride and sequencing the specifically labeled peptic peptides. The amino acid sequence centered around the coenzyme binding site is highly conserved between thermophilic aspartate aminotransferases and differs from that found in mesophilic isoenzymes. An alignment of aspartate aminotransferase from Sulfolobus solfataricus with mesophilic isoenzymes, attempted in spite of the low degree of similarity, was confirmed by the correspondence between pyridoxal 5' phosphate binding residues. Using this alignment it was possible to insert the archaebacterial aspartate aminotransferase into a subclass, subclass I, of pyridoxal 5' phosphate binding enzymes comprising mesophilic aspartate aminotransferases, tyrosine aminotransferases and histidinol phosphate aminotransferases. These enzymes share 12 invariant amino acids most of which interact with the coenzyme or with the substrates. Some enzymes of subclass I and in particular aspartate aminotransferase from Sulfolobus solfataricus, lack a positively charged residue, corresponding to Arg-292, which in pig cytosolic aspartate aminotransferase interacts with the distal carboxylate of the substrates (and determines the specificity towards dicarboxylic acids). It was confirmed that aspartate aminotransferase from Sulfolobus solfataricus does not possess any arginine residue exposed to chemical modifications responsible for the binding of omega-carboxylate of the substrates. Furthermore, it has been found that aspartate aminotransferase from Sulfolobus solfataricus is fairly active when alanine is used as substrate and that this activity is not affected by the presence of formate. The KM value of the thermophilic aspartate aminotransferase towards alanine is at least one order of magnitude lower than that of the mesophilic analogue enzymes.     

Strong nucleic acid binding to the Escherichia coli RNase HI mutant with two arginine residues at the active site

The biochemical properties of the mutant protein D10R/E48R of Escherichia coli RNase HI, in which Asp(10) and Glu(48) are both replaced by Arg, were characterized. This mutant protein has been reported to have metal-independent RNase H activity at acidic pH [Casareno et al. (1995) J. Am. Chem. Soc. 117, 11011-11012]. The far- and near-UV CD spectra of this mutant protein were similar to those of the wild-type protein, suggesting that the protein conformation is not markedly changed by these mutations. Nevertheless, we found that this mutant protein did not show any RNase H activity in vitro. Instead, it showed high-nucleic-acid-binding affinity. Protein footprinting analyses suggest that DNA/RNA hybrid binds to or around the presumed substrate-binding site of the protein. In addition, this mutant protein did not complement the temperature-sensitive growth phenotype of the rnhA mutant strain, E. coli MIC3001, even at pH 6.0, suggesting that it does not show RNase H activity in vivo as well. These results are consistent with a current model for the catalytic mechanism of the enzyme, in which Glu(48) is not responsible for Mg(2+) binding but is involved in the catalytic function.     

Ligand interactions at the active site of aspartate transcarbamoylase from Escherichia coli

The active site of aspartate transcarbamoylase from Escherichia coli was probed by studying the inhibitory effects of substrate analogues on the catalytic subunit of the enzyme. The inhibitors were chosen to satisfy the structural requirements for binding to either the phosphate or the dicarboxylate region. In addition, they also contained a side chain that would extend into the normal position occupied by the carbamoyl group. All the compounds tested showed competitive inhibition against carbamoyl phosphate. The ionic character of the side chain was found to be highly important in determining the affinity of the inhibitor. On the other hand, very little effect on binding was produced by changing the geometry of the functional group from trigonal to tetrahedral. Our findings suggest that the electrostatic stabilization of the negative charge that develops in the transition state may be a major factor in promoting catalysis. From the available X-ray diffraction data, we propose His-134 as the residue most likely to participate in this interaction. These results have significant implications on the design of reversible and irreversible inhibitors to this enzyme.     

Expression of a hyperthermophilic aspartate aminotransferase in Escherichia coli.

The gene for an archaebacterial hyperthermophilic enzyme, aspartate aminotransferase from Sulfolobus solfataricus (AspATSs), was expressed in Escherichia coli and the enzyme purified to homogeneity. A suitable expression vector and host strain were selected and culture conditions were optimized so that 6-7 mg of pure enzyme per litre of culture were obtained repeatedly. The recombinant enzyme and the authentic AspATSs are indistinguishable: in fact, they have the same molecular weight, estimated by means of SDS-PAGE and gel filtration, the same Km values for 2-oxo-glutarate and cysteine sulphinate and the same UV-visible spectra. Moreover, recombinant AspATSs is thermophilic and thermostable just as the enzyme extracted from Sulfolobus solfataricus. The protocol described may be used to produce thermostable arachaebacterial enzymes in mesophilic hosts.     

The purification and properties of the aspartate aminotransferase and aromatic-amino-acid aminotransferase from Escherichia coli.

A simple and convenient procedure is described for the isolation in good yield of two amino-transferases from various strains of Escherichia coli. On the basis of their substrate specificities one of the enzymes has been classified as an aromatic amino acid aminotransferase and the other as an aspartate aminotransferase, but both act on a wide range of substrates. Pyridoxal phosphate is bound more strongly to the aspartate aminotransferase than to the aromatic amino transferase which cannot be fully re-activated after removal of the prosthetic group. Both enzymes are composed of two subunits which appear to be identical.     

Characterization of Escherichia coli thioredoxins with altered active site residues

Escherichia coli thioredoxin is a small disulfide-containing redox protein with the active site sequence Cys-Gly-Pro-Cys-Lys. Mutations were made in this region of the thioredoxin gene and the mutant proteins expressed in E. coli strains lacking thioredoxin. Mutant proteins with a 17-membered or 11-membered disulfide ring were inactive in vivo. However, purified thioredoxin with the active site sequence Cys-Gly-Arg-Pro-Cys-Lys is still able to serve as a substrate for thioredoxin reductase and a reducing agent in the ribonucleotide reductase reaction, although with greatly reduced catalytic efficiency. A smaller disulfide ring, with the active site sequence Cys-Ala-Cys, does not turn over at a sufficient rate to be an effective reducing agent. Strain in the small ring favors the formation of intermolecular disulfide bonds. Alteration of the invariant proline to a serine has little effect on redox activity. The function of this residue may be in maintaining the stability of the active site region rather than participation in redox activity or protein-protein interactions. Mutation of the positively charged lysine in the active site to a glutamate residue raises the Km values with interacting enzymes. Although it has been proposed that the positive residue at position 36 is conserved to maintain the thiolate anion on Cys-32 (Kallis & Holmgren, 1985), the presence of the negative charge at this position does not alter the pH dependence of activity or fluorescence behavior. The lysine is most likely conserved to facilitate thioredoxin-protein interactions.     

Characterization of tryptophan phosphorescence of aspartate aminotransferase from Escherichia coli.

The Trp phosphorescence spectrum, intensity and decay kinetics of apo-aspartate aminotransferase, pyridoxamine-5P-aspartate-aminotransferase and pyridoxal-5P-aspartate aminotransferase were measured over a temperature range 160-273 K. The fine structure of the phosphorescence spectra in low-temperature glasses, with 0-0 vibrational bands centered at 408, 415 and 417 nm, for both apoenzyme and pyridoxamine-5P-enzyme reveals a marked heterogeneity of the chromophore environments. Only for the pyridoxal-5P form of the enzyme is the triplet emission strongly quenched and, in this case, the spectrum displays a unique 0-0 vibrational band centered at 415 nm. Concomitant to quenching, there is Trp-sensitized delayed fluorescence of the Schiff base, an indication that quenching of the excited triplet state is due, at least in part, to a process of triplet singlet energy transfer to the ketoenamine tautomer. All three forms of the enzyme are phosphorescent for temperatures up to 273 K. However, across the glass transition temperature the pyridoxal-5P enzyme shows a decrease in lifetime-normalized phosphorescence intensity, a thermal quenching that reduces even further the number of phosphorescing residues at ambient temperature. In fluid solution, the triplet decay is nonexponential and multiple lifetimes stress the heterogeneity in dynamical structure of the chromophores' sites. For the pyridoxal-5P enzyme, where only one or at most two residues are phosphorescent at 273 K, the nonexponential nature of the decay implies the presence of different conformers of the protein not interconverting in the millisecond time scale.     

Redesign of the substrate specificity of Escherichia coli aspartate aminotransferase to that of Escherichia coli tyrosine aminotransferase by homology modeling and site-directed mutagenesis.

Although several high-resolution X-ray crystallographic structures have been determined for Escherichia coli aspartate aminotransferase (eAATase), efforts to crystallize E. coli tyrosine aminotransferase (eTATase) have been unsuccessful. Sequence alignment analyses of eTATase and eAATase show 43% sequence identity and 72% sequence similarity, allowing for conservative substitutions. The high similarity of the two sequences indicates that both enzymes must have similar secondary and tertiary structures. Six active site residues of eAATase were targeted by homology modeling as being important for aromatic amino acid reactivity with eTATase. Two of these positions (Thr 109 and Asn 297) are invariant in all known aspartate aminotransferase enzymes, but differ in eTATase (Ser 109 and Ser 297). The other four positions (Val 39, Lys 41, Thr 47, and Asn 69) line the active site pocket of eAATase and are replaced by amino acids with more hydrophobic side chains in eTATase (Leu 39, Tyr 41, Ile 47, and Leu 69). These six positions in eAATase were mutated by site-directed mutagenesis to the corresponding amino acids found in eTATase in an attempt to redesign the substrate specificity of eAATase to that of eTATase. Five combinations of the individual mutations were obtained from mutagenesis reactions. The redesigned eAATase mutant containing all six mutations (Hex) displays second-order rate constants for the transamination of aspartate and phenylalanine that are within an order of magnitude of those observed for eTATase. Thus, the reactivity of eAATase with phenylalanine was increased by over three orders of magnitude without sacrificing the high transamination activity with aspartate observed for both enzymes.(ABSTRACT TRUNCATED AT 250 WORDS)     

Domain closure in mitochondrial aspartate aminotransferase.

The subunits of the dimeric enzyme aspartate aminotransferase have two domains: one large and one small. The active site lies in a cavity that is close to both the subunit interface and the interface between the two domains. On binding the substrate the domains close together. This closure completely buries the substrate in the active site and moves two arginine side-chains so they form salt bridges with carboxylate groups of the substrate. The salt bridges hold the substrate close to the pyridoxal 5'-phosphate cofactor and in the right position and orientation for the catalysis of the transamination reaction. We describe here the structural changes that produce the domain movements and the closure of the active site. Structural changes occur at the interface between the domains and within the small domain itself. On closure, the core of the small domain rotates by 13 degrees relative to the large domain. Two other regions of the small domain, which form part of the active site, move somewhat differently. A loop, residues 39 to 49, above the active site moves about 1 A less than the core of the small domain. A helix within the small domain forms the "door" of the active site. It moves with the core of the small domain and, in addition, shifts by 1.2 A, rotates by 10 degrees, and switches its first turn from the alpha to the 3(10) conformation. This results in the helix closing the active site. The domain movements are produced by a co-ordinated series of small changes. Within one subunit the polypeptide chain passes twice between the large and small domains. One link involves a peptide in an extended conformation. The second link is in the middle of a long helix that spans both domains. At the interface this helix is kinked and, on closure, the angle of the kink changes to accommodate the movement of the small domain. The interface between the domains is formed by 15 residues in the large domain packing against 12 residues in the small domain and the manner in which these residues pack is essentially the same in the open and closed structures. Domain movements involve changes in the main-chain and side-chain torsion angles in the residues on both sides of the interface. Most of these changes are small; only a few side-chains switch to new conformations.(ABSTRACT TRUNCATED AT 400 WORDS)     

Structural studies on aspartate aminotransferase from Escherichia coli. Covalent structure

The amino acid sequence of aspartate aminotransferase from Escherichia coli was established by sequence analysis and alignment of 39 tryptic peptides and 7 cyanogen bromide peptides. The total number of amino acid residues of the subunit was 396, and the molecular weight was calculated to be 43,573. A comparison of the primary structure of the E. coli enzyme with all known sequences of the two types of isoenzyme (mitochondrial and cytosolic enzymes) in vertebrates revealed that approximately 25% of all residues are invariant. The amino acid residues which were proposed from crystallographic studies on the vertebrate enzymes to be essential for the enzymic action are well conserved in the E. coli enzyme. The E. coli enzyme shows a similar degree of sequence homology to both the mitochondrial and cytosolic isoenzymes (close to 40%). The finding that the positions of deletions introduced into the sequence of E. coli enzyme to give the maximum homology agree well with those of the mitochondrial enzymes supports the endosymbiotic hypothesis of mitochondrial origin.     

Identification of catalytically important residues in the active site of Escherichia coli transaldolase.

The roles of invariant residues at the active site of transaldolase B from Escherichia coli have been probed by site-directed mutagenesis. The mutant enzymes D17A, N35A, E96A, T156A, and S176A were purified from a talB-deficient host and analyzed with respect to their 3D structure and kinetic behavior. X-ray analysis showed that side chain replacement did not induce unanticipated structural changes in the mutant enzymes. Three mutations, N35A, E96A, and T156A resulted mainly in an effect on apparent kcat, with little changes in apparent Km values for the substrates. Residues N35 and T156 are involved in the positioning of a catalytic water molecule at the active site and the side chain of E96 participates in concert with this water molecule in proton transfer during catalysis. Substitution of Ser176 by alanine resulted in a mutant enzyme with 2.5% residual activity. The apparent Km value for the donor substrate, fructose 6-phosphate, was increased nearly fivefold while the apparent Km value for the acceptor substrate, erythrose 4-phosphate remained unchanged, consistent with a function for S176 in the binding of the C1 hydroxyl group of the donor substrate. The mutant D17A showed a 300-fold decrease in kcat, and a fivefold increase in the apparent Km value for the acceptor substrate erythrose 4-phosphate, suggesting a role of this residue in carbon-carbon bond cleavage and stabilization of the carbanion/enamine intermediate.     

Labeling of the active site of cytoplasmic aspartate aminotransferase by -chloro-L-alanine

Syncatalytic inactivation of pig heart cytoplasmic aspartate aminotransferase by β-chloro-[U-¹⁴C]L-alanine resulted in the incorporation of radioactivity corresponding to one mole of the label per mole of the monomeric unit of the enzyme. A borohydride-reduced and then carboxymethylated preparation of the labeled enzyme was digested by trypsin. A radioactive peptide was isolated and found to contain a covalently linked pyridoxyl derivative which absorbed at 325 nm. The amino acid sequence of this peptide was Tyr-Phe-Val-Ser-Glu-Gly-Phe -Glu-Leu-Phe-Cys-Ala-Gln-Ser-Phe-Ser-Lys-Asn-Phe-Gly-Leu-Tyr-Asn-Glu-Arg. In the peptide the phosphopyridoxyl group seems to be covalently bound via alanyl moiety derived from β-chloro-L-alanine, the β-carbon atom of which is covalently linked to the ?-nitrogen atom of the lysyl residue(Lys). From a comparison with the amino acid composition of the phosphopyridoxyl peptide isolated from the tryptic digest of a borohydride-reduced holoenzyme, it was concluded that the modified lysul residue was identical to that involved in binding pyridoxal phosphate to the apoenzyme.     

Site-directed mutagenesis identifies catalytic residues in the active site of Escherichia coli phosphofructokinase.

Six active site mutants of Escherichia coli phosphofructokinase have been constructed and characterized using steady-state kinetics. All but one of the mutants (ES222) have significantly lower maximal activity, implicating these residues in the catalytic process. Replacement of Asp127, the key catalytic residue in the forward reaction with Glu, results in an enzyme with wild-type cooperative and allosteric behavior but severely decreased Fru6P binding. Replacement of the same residue with Tyr abolishes cooperativity while retaining sensitivity to allosteric inhibition and activation. Thus, this mutant has uncoupled homotropic from heterotropic allostery. Mutation of Asp103 to Ala results in an enzyme which retains wild-type Fru6P-binding characteristics with reduced activity. GDP, which allosterically activates the wild-type enzyme, acts as a mixed inhibitor for this mutant. Mutation of Thr125 to Ala and Asp129 to Ser produces mutants with impaired Fru6P binding and decreased cooperativity. In the presence of the activator GDP, both these mutants display apparent negative cooperativity. In addition, ATP binding is now allosterically altered by GDP. These results extend the number of active site residues known to participate in the catalytic process and help to define the mechanisms behind catalysis and homotropic and heterotropic allostery.     

Preliminary X-ray data for aspartate aminotransferase from Escherichia coli

Crystals of the aspartate aminotransferase from Escherichia coli (aspC gene product) have been examined by X-ray analysis. The crystals grow as elongated rectangular prisms, with the symmetry of space group C2221. Unit cell dimensions are a = 156 A, b = 87.6 A, c = 80.6 A and alpha = beta = gamma = 90 degrees. There is one protein subunit of molecular weight 43,600 per asymmetric unit.     

Solvent interactions with the active site of the pig heart cytosolic aspartate aminotransferase.

Aqueous solvent interactions with the chromophoric pyridoxal phosphate prosthetic group of aspartate aminotransferase (EC 2.6.1.1) were analyzed quantitatively with ethylene glycol, glycerol, dimethylsulfoxide (DMSO), sucrose, and xylitol as cosolvents. The smaller cosolvents perturb the visible absorption and visible dichroic spectra of the free enzyme, but this solvent perturbation is not observed with the acidic enzymeglutarate complex. Addition of cosolvents caused an increase in the enzyme's affinity for glutarate. This increase in affinity resulted from an increase in the acidic dissociation constant (pK₂) of the enzyme-glutarate complex. The changes in the acidic dissociation constant of the enzyme-glutarate complex, upon addition of cosolvents, correlate well with the changes observed in the pK_a's of carboxylic acids in comparable solvents. Since these solvents have little effect on the pK_a of the enzyme itself, it is concluded that the increase in affinity is due to a specific solvation effect on a carboxyl group of the enzymebound glutarate, rather than resulting from a conformational change in the protein.     

Essential arginine residues in tryptophanase from Escherichia coli.

Tryptophanase from Escherichia coli B/1t7-A is inactivated by the arginine-specific reagent, phenylglyoxal, in potassium phosphate buffer at pH 7.8 AND 25 degrees. Apo- and holoenzyme are inactivated at the same rate, and inactivation of both is correlated with modification of 2 arginine residues/tryptophanase monomer. Substrate analogs having a carboxyl group protect the holoenzyme against both inactivation and arginine modification but have no effect on the inactivation or modification of the apoenzyme. Phenylglyoxal-modified apotryptophanase retains the capacity to bind the coenzyme, pyridoxal-P, but the spectrum of this reconstituted species differs from that of native holotryptophanase. Neither this reconstituted species nor the phenyglyoxal-modified holoenzyme shows the 500 nm absorption characteristic of the native enzyme when substrates are added. These results demonstrate a requirement for specific arginine residues for substrate binding and are discussed in the context of the known conformational and spectal forms of tryptophanase with regard to a possible role for arginine residues in formation of a catalytically effective enzyme-pyridoxal-P complex.