Proton magnetic relaxation of aspartate transcarbamylase - succinate complexes.

Nuclear magnetic relaxation methods were used to investigate the interaction of the inhibitor succinate with aspartate transcarbamylase from Escherichia coli. Over the pH range 7 to 9, the dissociation constant for succinate remains less than the inhibitor concentration used for most of this work (0.05 M). As a result, the enzyme predominantly exists in a single "gross" conformational state. Succinate binding to this enzyme state (generally known as the R form) parallels the behavior seen previously with the isolated catalytic subunit (Beard, C. B., and Schmidt, P.G. (1973) Biochemistry 12, 2255-2264). The pH and temperature dependence of succinate proton relaxation rates, 1/T2 - 1/T1, in the presence of carbamyl phosphate, is interpreted in terms of a binding mechanism involving three forms of the enzyme, differing by their states of protonation. The least protonated form of the enzyme does not interact with succinate, the singly protonated species binds succinate to form a rapidly dissociating complex, and the doubly protonated species undergoes a conformational isomerization upon succinate binding, yielding a slow exchange complex. Relaxation data provide sufficient information to determine pKa values of 7.2 and 8.9 for two ionizing groups, as well as the dissociation constant for succinate in the fast exchange complex, Kd =1.6 X 10(-2) M. Rate constants for the forward and reverse steps of the isomerization, 1.3 X 10(3) s-1 and 33 s-1, respectively, indicate a significantly slower reverse rate from that obtained in the earlier NMR study of the isolated catalytic subunit. In experiments where the succinate concentration was varied, the relaxation rates showed sigmoidal binding of that ligand to the fast exchange complex above pH 9.1, (a) indicating cooperative binding of succinate, and (b) suggesting that above pH 9.1, the system cannot be characterized by a single dissociation constant, ionization constant, or relaxation effect. CTP and ATP were tested for their ability to affect succinate binding to the fast exchange complex. Heterotropic interactions were observed for CTP but not for ATP. Addition of low concentrations of the transition state analog N-(phosphonacetyl)-L-aspartate to the enzyme-carbamyl phosphate-succinate complex sharply decreased the relaxation rate, indicating that the measurements are sensitive only to succinate bound specifically to the active site.     

Interaction of rose bengal with mung bean aspartate transcarbamylase

The fluorescein dye, rose bengal in the dark: (i) inhibited the activity of mung bean aspartate transcarbamylase (EC 2.1.3.2) in a non-competitive manner, when aspartate was the varied substrate; (ii) induced a lag in the time course of reaction and this hysteresis was abolished upon preincubation with carbamyl phosphate; and (iii) converted the multiple bands observed on polyacrylamide gel electrophoresis of enzyme into a single band. The binding of the dye to the enzyme induced a red shift in the visible spectrum of dye suggesting that it was probably interacting at a hydrophobic region in the enzyme. The dye, in the presence of light, inactivated the enzyme and the inactivation was not dependent on pH. All the effects of the dye could be reversed by UMP, an allosteric inhibitor of the enzyme. The loss of enzyme activity on photoinactivation and the partial protection afforded by N-phosphonoacetyl-L-aspartate, a transition state analog and carbamyl phosphate plus succinate, a competitive inhibitor for aspartate, as well as the reversal of the dye difference spectrum by N-phosphonoacetyl-L-aspartate suggested that in the mung bean aspartate transcarbamylase, unlike in the case ofEscherichia coli enzyme, the active and allosteric sites may be located close to each other.     

Interaction of succinate dehydrogenase with succinate and oxaloacetate during enzyme activation-deactivation

The interaction of succinate dehydrogenase from the bovine adrenal cortex with succinate and oxaloacetate was studied in the process of its activation-deactivation. It is supposed that an intermediate unstable complex of succinate dehydrogenase with oxaloacetate plays an important role in the changed enzymic activity.     

Substrate specificity of a nitroalkane-oxidizing enzyme

The flavoprotein nitroalkane oxidase from Fusarium oxysporum catalyzes the oxidation of nitroalkanes to aldehydes with production of hydrogen peroxide and nitrite. The substrate specificity of the FAD-containing enzyme has been determined as a probe of the active site structure. Nitroalkane oxidase is active on primary and secondary nitroalkanes, with a marked preference for unbranched primary nitroalkanes. The V/K values for primary nitroalkanes increase with increasing length of the alkyl chain, reaching a maximum with 1-nitrobutane, suggesting a hydrophobic binding site sufficient to accommodate a four carbon chain. Each methylene group of the substrate contributes approximately 2.6 kcal mol-1 in binding energy. The V/K values for substrates containing a hydroxyl group are two orders of magnitude smaller than those of the corresponding nitroalkanes, also consistent with a hydrophobic binding site. 3-Nitro-1-propionate is a competitive inhibitor with a Kis value of 3.1 +/- 0.2 mM.     

A model of an enzyme with mixed cooperation: 3 states of aspartate transcarbamylase

Allosteric enzyme models on the basis of the known properties of aspartate transcarbamylase (ATCase) from Escherichia coli are suggested. In the first model molecules are supposed to equilibrate between two states. In contrast to the classical Monod-Wyman-Changeux model the symmetry of enzyme molecules changes during the conformational transition. It is shown that the number of binding sites of the enzyme defined from the Scatchard plots is sufficiently dependent on values of parameters of enzyme reaction. This fact results from the mixed (both positive and negative) cooperative effects. However the complex kinetic of ATCase is not completely simulated by this model. Therefore the model is complicated by taking into account the inactive third state of the enzyme. Thus the complex kinetic behaviour of ATCase is explained. The models may be also used for other enzymes.     

Purification and properties of Bacillus subtilis aspartate transcarbamylase.

Aspartate transcarbamylase from Bacillus subtilis has been purified to apparent homogeneity. A subunit molecular weight of 33,500 +/- 1,000 was obtained from electrophoresis in polyarcylamide gels containing sodium dodecyl sulfate and from sedimentation equilibrium analysis of the protein dissolved in 6 M guanidine hydrochloride. The molecular weight of the native enzyme was determined to be 102,000 +/- 2,000 by sedimentation velocity and sedimentation equilibrium analysis. Aspartate transcarbamylase thus appears to be a trimeric protein; cross-linking with dimethyl suberimidate and electrophoretic analysis confirmed this structure. B. subtilis aspartate transcarbamylase has an amino acid composition quite similar to that of the catalytic subunit from Escherichia coli aspartate transcarbamylase; only the content of four amino acids is substantially different. The denaturated enzyme has one free sulfhydryl group. Aspartate transcarbamylase exhibited Michaelis-Menten kinetics and was neither inhibited nor activated by nucleotides. Several anions stimulated activity 2- to 5-fold. Immunochemical studies indicated very little similarity between B. subtilis and E. coli aspartate transcarbamylase or E. coli aspartate transcarbamylase catalytic subunit.     

HNMR of succinate binding to aspartate transcarbamylase. A comparison of results in D2O and H2O.

The interaction of succinate with asparatete transcarbamylase from Escherichia coli has been studied by magnetic resonance relaxation measurements of the dicarboxylic acid methylene protons in H2O solutions. The pH and temperature dependence of the relaxation in the presence of either native asparte transcarbamylase or its catalytic subunit in H2O solutions is qualitatively very similar to the corresponding situation utilizing D2O as the solvent. From previous result of measurements in D2O[C.B. Beard and P.G. Schmidt, Biochemistry 12(1973)2255] a mechanism was proposed involving 2 protonated groups affecting succinate binding and titratable over the pH range 7-10. Quantitatively, fitting the data from H2O solutions to the mechanism yeilds values of the fitting parameters generally in good agreement with the D2O experiments. The main exceptions are the pKa values calculated for the two titratable groups. For these species the values obtained in the presence of the catalytic subunit are 6.7 and 7.8 in H2O solutions versus 7.3 and 8.6 in D2O solutions. In the presence of native enzyme the corresponding values are 6.8 and 8.3 in H2O versus 7.6 and 9.2 in D2O. These observed differences are consistent with differences in ionization constants of weak acids in D2O relative to H2O. The results imply that succinate interaction with the enzyme active site is similar in the two solvents.     

Functionally important arginine residues of aspartate transcarbamylase.

The reaction of phenylglyoxal with aspartate transcarbamylase and its isolated catalytic subunit results in complete loss of enzymatic activity (Kantrowitz, E. R., and Lipscomb, W. N. (1976) J. Biol. Chem. 251, 2688-2695). If N-(phosphonacetyl)-L-aspartate is used to protect the active site, we find that phenylglyoxal causes destruction of the enzyme's susceptibility to activation by ATP and inhibition by CTP. Furthermore, CTP only minimally protects the regulatory site from reaction with this reagent. The modified enzyme still binds CTP although with reduced affinity. After reaction with phenylglyoxal, the native enzyme shows reduced cooperativity. The hybrid with modified regulatory subunits and native catalytic subunits exhibits slight heterotropic or homotropic properties, while the reverse hybrid, with modified catalytic subunits and native regulatory subunits, shows much reduced homotropic properties but practically normal heterotropic interactions. The decrease in the ability of CTP to inhibit the enzyme correlates with the loss of 2 arginine residues/regulatory chain (Mr = 17,000). Under these reaction conditions, 1 arginine residue is also modified on each catalytic chain (Mr = 33,000). Reaction rate studies of p-hydroxymercuribenzoate, with the liganded and unliganded modified enzyme suggest that the reaction with phenylglyoxal locks the enzyme into the liganded conformation. The conformational state of the regulatory subunit is implicated as having a critical role in the expression of the enzyme's heterotropic and homotropic properties.     

Purification of aspartate transcarbamylase from Drosophila melanogaster.

A purification procedure is described by which aspartate transcarbamylase was obtained from cultured cells of Drosophila melanogaster as part of a high-molecular-weight enzyme complex. The complex is shown to contain several polypeptides. An antiserum directed against the complex enzyme inhibited in vitro the activity of aspartate transcarbamylase, carbamylphosphate synthetase and dihydro-orotase which were shown to copurify on a sucrose gradient and by gel electrophoresis. A fast preparation procedure using this antiserum yielded a 220 000-molecular-weight protein in addition to the polypeptides present in the complex. A purification procedure is also described to obtain aspartate transcarbamylase from second instar larvae of Drosophila. At this stage, the enzyme is not complexed with carbamylphosphate synthetase and dihydro-orotase but exhibits the same molecular weight as the aspartate transcarbamylase moiety found in the high-molecular-weight complex of cultured cells.