Structural similarity between ornithine and aspartate transcarbamoylases of Escherichia coli: implications for domain switching.

Each catalytic (c) polypeptide chain of Escherichia coli aspartate transcarbamoylase (ATCase) is composed of two globular domains connected by two interdomain helices. Helix 12, near the C-terminus, extends from the second domain back through the first domain, bringing the two termini close together. This helix is of critical importance for the assembly of a stable enzyme. The trimeric E. coli enzyme ornithine transcarbamoylase (OTCase) is proposed to be similar in tertiary and quaternary structure to the ATCase trimer and has a predicted alpha-helical segment near its C-terminus. In our companion paper, we have shown that this putative helix is essential for OTCase folding and assembly (Murata L, Schachman HK, 1996, Protein Sci 5:709-718). Here, the similarity between OTCase and the ATCase trimer, which are 32% identical in sequence, was tested further by the construction of several chimeras in which various structural elements were switched between the enzymes by genetic techniques. These elements included the two globular domains and regions containing the C-terminal helices. In contrast to results reported previously (Houghton J, O'Donovan G, Wild J, 1989, Nature 338:172-174), none of the chimeric proteins exhibited in vivo activity and all were insoluble when overexpressed. Attempts to make hybrid trimers composed of c chains from ATCase and OTCase were also unsuccessful. These results underscore the complexities of specific intrachain and interchain side-chain interactions required to maintain tertiary and quaternary structures in these enzymes.     

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.     

Probing the regulatory site of Escherichia coli aspartate transcarbamoylase by site-specific mutagenesis.

The effector binding site of Escherichia coli aspartate transcarbamoylase, composed of the triphosphate and ribose-base subsites, is located on the regulatory (r) chains of the enzyme. In order to probe the function of amino acid side chains at this nucleotide triphosphate site, site-specific mutagenesis was used to create three mutant versions of the enzyme. On the basis of the three-dimensional structure of the enzyme with CTP bound, three residues were selected. Specifically, Arg-96r was replaced with Gln, and His-20r and Tyr-89r were both replaced with Ala. Analyses of these mutant enzymes indicate that none of these substitutions significantly alter the catalytic properties of the enzyme. However, the mutations at His-20r and Tyr-89r produced altered response to the regulatory nucleotides. For the His-20r----Ala enzyme, the affinities of the enzyme for ATP and CTP are reduced 40-fold and 10-fold, respectively, when compared with the wild-type enzyme. Furthermore, CTP is able to inhibit the His-20r----Ala enzyme 40% more than the wild-type enzyme. In the case of the Tyr-89r----Ala enzyme. ATP can increase the mutant enzyme's activity 181% compared to 157% for the wild-type enzyme, while simultaneously the affinity of this enzyme for ATP decreases about 70%. These results suggest that Tyr-89r does have an indirect role in the discrimination between ATP and CTP. The His-20r----Ala enzyme shows no UTP synergistic inhibition in the presence of CTP.(ABSTRACT TRUNCATED AT 250 WORDS)     

Comparison of active mutants and wild-type aspartate transcarbamoylase of Escherichia coli

Two active mutants of aspartate transcarbamoylase from Escherichia coli have been purified from strains which produce large quantities of enzyme. Each enzyme was isolated from a different spontaneous revertant of a pyrimidine auxotrophic strain produced by mutagenesis with nitrogen mustard. Both enzymes exhibit allosteric properties with one having significantly less and the other more cooperativity than wild-type enzyme. Isolated catalytic subunits had different values of Km and Vmax. Studies on hybrids constructed from mutant catalytic and wild-type regulatory subunits (and vice versa) indicate that catalytic chains encoded by pyrB and not the regulatory chains encoded by pyrI were affected by the mutations. Differential scanning calorimetry experiments support these conclusions. Both mutant enzymes undergo ligand-promoted conformational changes analogous to those exhibited by wild-type enzyme: a 3% decrease in the sedimentation coefficient and a 5-fold increase in the reactivity of the sulfhydryl groups of the regulatory chains. Interactions between catalytic and regulatory chains in the mutants are weaker than those in the wild-type enzyme. The gross conformational changes of the mutants upon adding the bisubstrate ligand, N-(phosphonacetyl)-L-aspartate, in the presence of the substrate, carbamoylphosphate, and the activator, ATP, correlate with differences in cooperativity. The mutant with lower cooperativity is more readily converted from the low-affinity, compact, T-state to the high-affinity, swollen, R-state than is wild-type enzyme; this conversion for the more cooperative enzyme is energetically less favorable.     

A single amino acid substitution in the active site of Escherichia coli aspartate transcarbamoylase prevents the allosteric transition

Modeling of the tetrahedral intermediate within the active site of Escherichia coli aspartate transcarbamoylase revealed a specific interaction with the side-chain of Gln137, an interaction not previously observed in the structure of the X-ray enzyme in the presence of N-phosphonacetyl-L-aspartate (PALA). Previous site-specific mutagenesis experiments showed that when Gln137 was replaced by alanine, the resulting mutant enzyme (Q137A) exhibited approximately 50-fold less activity than the wild-type enzyme, exhibited no homotropic cooperativity, and the binding of both carbamoyl phosphate and aspartate were extremely compromised. To elucidate the structural alterations in the mutant enzyme that might lead to such pronounced changes in kinetic and binding properties, the Q137A enzyme was studied by time-resolved, small-angle X-ray scattering and its structure was determined in the presence of PALA to 2.7 angstroms resolution. Time-resolved, small-angle X-ray scattering established that the natural substrates, carbamoyl phosphate and L-aspartate, do not induce in the Q137A enzyme the same conformational changes as observed for the wild-type enzyme, although the scattering pattern of the Q137A and wild-type enzymes in the presence of PALA were identical. The overall structure of the Q137A enzyme is similar to that of the R-state structure of wild-type enzyme with PALA bound. However, there are differences in the manner by which the Q137A enzyme coordinates PALA, especially in the side-chain positions of Arg105 and His134. The replacement of Gln137 by Ala also has a dramatic effect on the electrostatics of the active site. These data taken together suggest that the side-chain of Gln137 in the wild-type enzyme is required for the binding of carbamoyl phosphate in the proper orientation so as to induce conformational changes required for the creation of the high-affinity aspartate-binding site. The inability of carbamoyl phosphate to create the high-affinity binding site in the Q137A enzyme results in an enzyme locked in the low-activity low-affinity T state. These results emphasize the absolute requirement of the binding of carbamoyl phosphate for the creation of the high-affinity aspartate-binding site and for inducing the homotropic cooperativity in aspartate transcarbamoylase.     

Direct structural evidence for a concerted allosteric transition in Escherichia coli aspartate transcarbamoylase

Regulation of protein function, often achieved by allosteric mechanisms, is central to normal physiology and cellular processes. Although numerous models have been proposed to account for the cooperative binding of ligands to allosteric proteins and enzymes, direct structural support has been lacking. Here, we used a combination of X-ray crystallography and small angle X-ray scattering in solution to provide direct structural evidence that the binding of ligand to just one of the six active sites of Escherichia coli aspartate transcarbamoylase induces a concerted structural transition from the T to the R state.     

Comparison of the aspartate transcarbamoylases from Serratia marcescens and Escherichia coli

The aspartate transcarbamoylases (ATCase, EC 2.1.3.2) of Escherichia coli and Serratia marcescens have similar dodecameric enzyme structures (2(c3):3(r2] but differ in both regulatory and catalytic characteristics. The catalytic cistrons (pyrB) of the ATCases from E. coli and S. marcescens encode polypeptides of 311 and 306 amino acids, respectively; there is a 76% identity between the DNA sequences and an overall amino acid homology of 88% (38 differences). The regulatory cistrons (pyrI) of these ATCases encode polypeptides of 153 and 154 amino acids, respectively, and there is a 75% identity between the DNA sequences and an overall amino acid homology of 77% (36 differences). In both species, the two genes are arranged as a bicistronic operon, with pyrB promoter proximal. A comparison of the deduced amino acid sequences reveals that the active site and the allosteric binding sites, as well as most of the intrasubunit interactions and intersubunit associations, are conserved in the E. coli and the S. marcescens enzymes; however, there are specific differences which undoubtedly contribute to the catalytic and regulatory differences between the enzymes of the two species. These differences include residues that have been implicated in the T-R transition, c1:r1 interface interactions, and the CTP binding site. A hybrid ATCase assembled in vivo with catalytic subunits from E. coli and regulatory subunits from S. marcescens has a 6 mM requirement for aspartate at half-maximal saturation, similar to the 5.5 mM aspartate requirement of the native E. coli holoenzyme at half-maximal saturation. However, the heterotropic response of this hybrid enzyme is characteristic of the heterotropic response of the native S. marcescens holoenzyme: ATP activation and CTP activation. Activation by both allosteric effectors indicates that the heterotropic response of this hybrid holoenzyme (Cec:Rsm) is determined by the associated S. marcescens regulatory subunits.     

Function of threonine-55 in the carbamoyl phosphate binding site of Escherichia coli aspartate transcarbamoylase

Carbamoyl phosphate is held in the active site of Escherichia coli aspartate transcarbamoylase by a variety of interactions with specific side chains of the enzyme. In particular, the carbonyl group of carbamoyl phosphate interacts with Thr-55, Arg-105, and His-134. Site-specific mutagenesis was used to create a mutant version of the enzyme in which Thr-55 was replaced by alanine in order to help define the role of this residue in the catalytic mechanism. The Thr-55----Ala holoenzyme exhibits a 4.7-fold reduction in maximal observed specific activity, no alteration in aspartate cooperativity, and a small reduction in carbamoyl phosphate cooperativity. The mutation also causes 14-fold and 35-fold increases in the carbamoyl phosphate and aspartate concentrations required for half the maximal observed specific activity, respectively. Circular dichroism spectroscopy has shown that saturating carbamoyl phosphate does not induce a conformational change in the Thr-55----Ala holoenzyme as it does for the wild-type holoenzyme. The kinetic properties of the Thr-55----Ala catalytic subunit are altered to a greater extent than the mutant holoenzyme. The mutant catalytic subunit cannot be saturated by either substrate under the experimental conditions. Furthermore, as opposed to the wild-type catalytic subunit, the Thr-55----Ala catalytic subunit shows cooperativity for aspartate and can be activated by N-(phosphonoacetyl)-L-aspartate in the presence of low concentrations of aspartate and high concentrations of carbamoyl phosphate. As deduced by circular dichroism spectroscopy, the conformation of the Thr-55----Ala catalytic subunit in the absence of active-site ligands is distinctly different from the wild-type catalytic subunit.(ABSTRACT TRUNCATED AT 250 WORDS)     

Structural model of the R state of Escherichia coli aspartate transcarbamoylase with substrates bound

The allosteric enzyme aspartate transcarbamoylase (ATCase) exists in two conformational states. The enzyme, in the absence of substrates is primarily in the low-activity T state, is converted to the high-activity R state upon substrate binding, and remains in the R state until substrates are exhausted. These conformational changes have made it difficult to obtain structural data on R-state active-site complexes. Here we report the R-state structure of ATCase with the substrate Asp and the substrate analog phosphonoactamide (PAM) bound. This R-state structure represents the stage in the catalytic mechanism immediately before the formation of the covalent bond between the nitrogen of the amino group of Asp and the carbonyl carbon of carbamoyl phosphate. The binding mode of the PAM is similar to the binding mode of the phosphonate moiety of N-(phosphonoacetyl)-l-aspartate (PALA), the carboxylates of Asp interact with the same residues that interact with the carboxylates of PALA, although the position and orientations are shifted. The amino group of Asp is 2.9 A away from the carbonyl oxygen of PAM, positioned correctly for the nucleophilic attack. Arg105 and Leu267 in the catalytic chain interact with PAM and Asp and help to position the substrates correctly for catalysis. This structure fills a key gap in the structural determination of each of the steps in the catalytic cycle. By combining these data with previously determined structures we can now visualize the allosteric transition through detailed atomic motions that underlie the molecular mechanism.     

The role of an active site histidine in the catalytic mechanism of aspartate transcarbamoylase

Although the allosteric enzyme aspartate transcarbamoylase from Escherichia coli has been the focus of numerous physical and enzymological studies for over 2 decades, the catalytic mechanism is still poorly understood. There has been much speculation regarding the role of a conserved histidine residue at position 134 which recent crystallographic studies have implicated in the catalytic mechanism as a general acid or as a general base. We have used a combination of site-directed mutagenesis, 13C-isotope incorporation, and high field NMR to probe the role of His134 in the catalytic mechanism of aspartate transcarbamoylase. By comparing the wild-type catalytic trimer with that from a partially active mutant in which His134 is replaced by alanine, we have assigned the 13C resonance for His134 in the wild-type enzyme. This residue is shown to have a pK less than 6, indicating that the imidazole ring is unprotonated at pH values optimal for enzymatic activity (pH 8.0). This result eliminates the possibility of His134 participating as a general acid in the carbamoyl transfer mechanism. Since the crystallographic studies indicate that His134 is close enough to hydrogen-bond to the carbonyl of the liganded bisubstrate analog N-(phosphonacetyl)-L-aspartate, the imidazole ring would be oriented as to make it unlikely that the N1 lone pair of electrons could participate in general base catalysis. Moreover, if His134 is implicated in base catalysis, we would have expected a much greater loss of activity upon its replacement by alanine. Perhaps the role of His134 is merely to help position the carbonyl group of carbamoyl phosphate for nucleophilic attack by the alpha-amino group of aspartate.     

Arginine 54 in the active site of Escherichia coli aspartate transcarbamoylase is critical for catalysis: a site-specific mutagenesis, NMR, and X-ray crystallographic study.

The replacement of Arg-54 by Ala in the active site of Escherichia coli aspartate transcarbamoylase causes a 17,000-fold loss of activity but does not significantly influence the binding of substrates or substrate analogs (Stebbins, J.W., Xu, W., & Kantrowitz, E.R., 1989, Biochemistry 28, 2592-2600). In the X-ray structure of the wild-type enzyme, Arg-54 interacts with both the anhydride oxygen and a phosphate oxygen of carbamoyl phosphate (CP) (Gouaux, J.E. & Lipscomb, W.N., 1988, Proc. Natl. Acad. Sci. USA 85, 4205-4208). The Arg-54-->Ala enzyme was crystallized in the presence of the transition state analog N-phosphonacetyl-L-aspartate (PALA), data were collected to a resolution limit of 2.8 A, and the structure was solved by molecular replacement. The analysis of the refined structure (R factor = 0.18) indicates that the substitution did not cause any significant alterations to the active site, except that the side chain of the arginine was replaced by two water molecules. 31P-NMR studies indicate that the binding of CP to the wild-type catalytic subunit produces an upfield chemical shift that cannot reflect a significant change in the ionization state of the CP but rather indicates that there are perturbations in the electronic environment around the phosphate moiety when CP binds to the enzyme. The pH dependence of this upfield shift for bound CP indicates that the catalytic subunit undergoes a conformational change with a pKa approximately 7.7 upon CP binding. Furthermore, the linewidth of the 31P signal of CP bound to the Arg-54-->Ala enzyme is significantly narrower than that of CP bound to the wild-type catalytic subunit at any pH, although the change in chemical shift for the CP bound to the mutant enzyme is unaltered. 31P-NMR studies of PALA complexed to the wild-type catalytic subunit indicate that the phosphonate group of the bound PALA exists as the dianion at pH 7.0 and 8.8, whereas in the Arg-54-->Ala catalytic subunit the phosphonate group of the bound PALA exists as the monoanion at pH 7.0 and 8.8. Thus, the side chain of Arg-54 is essential for the proper ionization of the phosphonate group of PALA and by analogy the phosphate group in the transition state. These data support the previously proposed proton transfer mechanism, in which a fully ionized phosphate group in the transition state accepts a proton during catalysis.     

Escherichia coli aspartate transcarbamoylase: the molecular basis for a concerted allosteric transition

Aspartate transcarbamoylase from Escherichia coli has become a model system for the study of both homotropic and heterotropic interactions in proteins. Analysis of the X-ray structures of the enzyme in the absence and presence of substrates and substrate analogs has revealed sets of interactions that appear to stabilize either the 'T' or the 'R' states of the enzyme. Site-specific mutagenesis has been used to test which of these interactions are functionally important. By combining the structural data from X-ray crystallography, and the functional data from site-specific mutagenesis a model is proposed for homotropic cooperativity in aspartate transcarbamoylase that suggests that the allosteric transition occurs in a concerted fashion.     

On the mechanism of assembly of the aspartate transcarbamoylase from Escherichia coli.

The mechanism of subunit assembly of aspartate transcarbamoylase from Escherichia coli was studied by following the kinetics of reassociation. The isolated trimetric catalytic subunit (c3) and dimeric regulatory subunit (r2) were mixed together and formation of the dodecameric native enzyme (c6r6) was monitored by measuring changes in activity. Under appropriate conditions the reassociation was second order with respect to the c3 concentration and the effects of varying r2 concentration on the second-order rate constant were examined. An optimum R2 concentration of about 0.07 micrometer was observed. A scheme of the assembly pathways is proposed and is based on the reversible formation of c3r2n (n = 0, 1, 2 or 3) as intermediates. Various combinations of two such c3r2n species are considered as possible rate-limiting steps. This model yields an expression which relates the experimentally determined (overall) second-order rate constant to the equilibrium constant (Kd) governing the formation of c3r2n, the r2 concentration, and four coefficients which reflect the contribution of different types of assembly processes. Using previously determined values of Kd, the above expression for each r2 concentration reduces to a linear equation with four unknowns. The experimental data were subjected to multiple linear-regression analysis and values for the four coefficients were found which gave an excellent fit. Our results show that reassociation of the subunits is a fast bimolecular reaction with rate constants in excess of 10(6) M-1 s-1. Our analysis also suggests that interactions involving a total of more than three r2 subunits (e.g. the combination of c3r2 with c3r6) might contribute significantly to the overall assembly. The influence of various ligands on the reassociation rate profile was also studied. All ligands examined were partially inhibitory to the formation of native enzyme. The effects of substrates were similar to those of CTP whereas the effects of ATP were substantially different. These observations can be readily interpreted by postulating different conformational changes induced by the ligands. These changes should alter the relative orientation of the subunit contacts which must be formed in the reassociation process. The interpretation is consistent with our previous model of the allosteric mechanism.     

Weakening of the interface between adjacent catalytic chains promotes domain closure in Escherichia coli aspartate transcarbamoylase.

Aspartate transcarbamoylase from Escherichia coli is a dodecameric enzyme consisting of two trimeric catalytic subunits and three dimeric regulatory subunits. Asp-100, from one catalytic chain, is involved in stabilizing the C1-C2 interface by means of its interaction with Arg-65 from an adjacent catalytic chain. Replacement of Asp-100 by Ala has been shown previously to result in increases in the maximal specific activity, homotropic cooperativity, and the affinity for aspartate (Baker DP, Kantrowitz ER, 1993, Biochemistry 32:10150-10158). In order to determine whether these properties were due to promotion of domain closure induced by the weakening of the C1-C2 interface, we constructed a double mutant version of aspartate transcarbamoylase in which the Asp-100-->Ala mutation was introduced into the Glu-50-->Ala holoenzyme, a mutant in which domain closure is impaired. The Glu-50/Asp-100-->Ala enzyme is fourfold more active than the Glu-50-->Ala enzyme, and exhibits significant restoration of homotropic cooperativity with respect to aspartate. In addition, the Asp-100-->Ala mutation restores the ability of the Glu-50-->Ala enzyme to be activated by succinate and increases the affinity of the enzyme for the bisubstrate analogue N-(phosphonacetyl)-L-aspartate (PALA). At subsaturating concentrations of aspartate, the Glu-50/Asp-100-->Ala enzyme is activated more by ATP than the Glu-50-->Ala enzyme and is also inhibited more by CTP than either the wild-type or the Glu-50-->Ala enzyme. As opposed to the wild-type enzyme, the Glu-50/Asp-100-->Ala enzyme is activated by ATP and inhibited by CTP at saturating concentrations of aspartate. Structural analysis of the Glu-50/Asp-100-->Ala enzyme by solution X-ray scattering indicates that the double mutant exists in the same T quaternary structure as the wild-type enzyme in the absence of ligands and in the same R quaternary structure in the presence of saturating PALA. However, saturating concentrations of carbamoyl phosphate and succinate only convert a fraction of the Glu-50/Asp-100-->Ala enzyme population to the R quaternary structure, a behavior intermediate between that observed for the Glu-50-->Ala and wild-type enzymes. Solution X-ray scattering was also used to investigate the structural consequences of nucleotide binding to the Glu-50/Asp-100-->Ala enzyme.     

Importance of domain closure for the catalysis and regulation of Escherichia coli aspartate transcarbamoylase

Two hybrid versions of Escherichia coli aspartate transcarbamoylase were studied to determine the influence of domain closure on the homotropic and heterotropic properties of the enzyme. Each hybrid holoenzyme had one wild-type and one inactive catalytic subunit. In the first case the inactive catalytic subunit had Arg-54 replaced by alanine. The holoenzyme with this mutation in all six catalytic chains exhibits a 17,000-fold reduction in activity, no loss in substrate affinity, and an R state structurally identical to that of the wild-type enzyme. In the second case, the inactive catalytic subunit had Arg-105 replaced by alanine. The holoenzyme with this mutation in all six catalytic chains exhibits a 1,100-fold reduction in activity, substantial loss in substrate affinity, and loss of the ability to be converted to the R state. Thus, the R54A substitution results in a holoenzyme that can undergo closure of the catalytic chain domains to form the high activity, high affinity active site and to undergo the allosteric transition, whereas the R105A substitution results in a holoenzyme that can neither undergo domain closure nor the allosteric transition. The hybrid holoenzyme with one wild-type and one R54A catalytic subunit exhibited the same maximal velocity per active site as the wild-type holoenzyme, reduced cooperativity, and normal heterotropic interactions. The hybrid with one wild-type and one R105A catalytic subunit exhibited significantly reduced maximal velocity per active site as compared with the wild-type holoenzyme, reduced cooperativity, and substantially reduced heterotropic interactions. Small angle x-ray scattered was used to verify that the R105A-containing hybrid could attain an R state structure. These results indicate the global nature of the conformational changes associated with the allosteric transition in the enzyme. If one catalytic subunit cannot undergo domain closure to create the active sites, then the entire molecule cannot attain the high activity, high activity R state.     

Control of L-ornithine specificity in Escherichia coli ornithine transcarbamoylase. Site-directed mutagenic and pH studies

Escherichia coli ornithine transcarbamoylase displays a strict specificity toward its second substrate L-ornithine. After forming a binary complex with carbamoyl phosphate and undergoing an induced-fit isomerization (Miller, A. W., and Kuo, L. C. (1990) J. Biol. Chem. 265, 15023-15027), the enzyme selects only the minor, zwitterionic ornithine with an uncharged delta-amino group for transcarbamoylation. Formation of the productive ternary complex is linked to two enzymic ionizations (pK alpha 6.2 approximately 6.3 and 9.1 approximately 9.3) and two ornithine ionizations (pK alpha 8.5 and 10.6) (Kuo, L. C., Herzberg, W., and Lipscomb, W. N. (1985) Biochemistry 24, 4754-4761). To elucidate the mechanism through which substrate specificity is achieved, the binding of L-ornithine to two site-specific point mutants (Arg-57----Gly and Cys-273----Ala) of the enzyme has been examined. For the Gly-57 mutant enzyme, which does not undergo the induced-fit isomerization, affinity for ornithine drops by a factor of 500. The pH profile of the apparent equilibrium constant governing the association of L-ornithine to the binary complex of this mutant reveals that only two enzymic ionizations affect ornithine binding. The ionizations linked to L-ornithine are not detected. Hence, the preisomerized binary complex binds not only poorly but also indiscriminately all ionic species of L-ornithine. For the Ala-273 mutant enzyme, which exhibits the induced-fit isomerization, affinity of the amino acid is decreased by an order of magnitude. Ionizations of L-ornithine to yield a zwitterion for binding are detected in pH analyses for this mutant, but the pK alpha of 6.2 associated with the enzymic deprotonation in the wild type is absent. Therefore, Cys-273 is a binding site of L-ornithine. The D-isomer of ornithine is a very weak, deadend ligand to all three forms of the enzyme with affinities in the millimolar range. Employing the estimated affinities of D- and L-ornithine, the binding stereospecificity of the wild-type and mutant binary complexes toward the amino acid substrate may be evaluated. L-Ornithine binds preferentially over D-ornithine by two and four orders of magnitude in the absence and presence of protein isomerization, respectively.(ABSTRACT TRUNCATED AT 400 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)     

The influence of quaternary structure on the active site of an oligomeric enzyme. Catalytic subunit of aspartate transcarbamoylase

The catalytic subunit of aspartate transcarbamoylase from Escherichia coli reacts readily with 2,4,6-trinitrobenzenesulfonate, resulting in the loss of enzymatic activity. Substrates and substrate analogs protect the enzyme in a competitive manner, indicating that the loss of activity is due to modification of active-site residues. This conclusion was confirmed by fractionating tryptic digests of the modified protein followed by the identification of active-site lysines 83 and 84 as the modified residues. When three trinitrophenyl groups are incorporated per catalytic trimer, 70% of the activity is lost. The modified protein retains the sedimentation velocity and electrophoretic properties of the native catalytic subunit and can associate with regulatory subunit to form a holoenzyme-like molecule. The trinitrophenylated catalytic trimers have two strong absorption bands at 345 and 420 nm which serve as sensitive spectral probes in difference-spectroscopy experiments. Results from such experiments show that 1) the modified trimeric enzyme binds active-site ligands; 2) dissociation of the trimer into compact, highly structured monomers gives a spectral response distinguishable from that observed when the chains are completely unfolded; and 3) even though dissociation of the trimers to folded monomers causes the complete loss of enzyme activity, the resulting monomers still retain the ability to bind the bisubstrate analog N-(phosphonacetyl)-L-aspartate. These results indicate that the active site must be at least partially formed in the absence of any quaternary structure.     

Importance of a conserved residue, aspartate-162, for the function of Escherichia coli aspartate transcarbamoylase.

Aspartate-162 in the catalytic chain of aspartate transcarbamoylase is conserved in all of the sequences determined to date. The X-ray structure of the Escherichia coli enzyme indicates that this residue is located in a loop region (160's loop) that is near the interface between two catalytic trimers and is also close to the active site. In order to test whether this conserved residue is important for support of the internal architecture of the enzyme and/or involved in transmitting homotropic and heterotropic effects, the function of this residue was studied using a mutant version of the enzyme with an alanine at this position (Asp-162----Ala) created by site-specific mutagenesis. The Asp-162----Ala enzyme exhibits a 400-fold reduction in the maximal observed specific activity, approximately 2-fold and 10-fold decreases in the aspartate and carbamoyl phosphate concentrations at half the maximal observed specific activity respectively, a loss of homotropic cooperativity, and loss of response to the regulatory nucleotides ATP and CTP. Furthermore, equilibrium binding studies indicate that the affinity of the mutant enzyme for CTP is reduced more than 10-fold. The isolated catalytic subunit exhibits a 660-fold reduction in maximal observed specific activity compared to the wild-type catalytic subunit. The Km values for aspartate and carbamoyl phosphate for the Asp-162----Ala catalytic subunit were within 2-fold of the values observed for the wild-type catalytic subunit. Computer simulations of the energy-minimized mutant enzyme indicate that the space once occupied by the side chain of Asp-162 may be filled by other side chains, suggesting that Asp-162 is important for stabilizing the internal architecture of the wild-type enzyme.