Pyrimidine nucleotide biosynthesis in Phaseolus aureus. Enzymic aspects of the control of carbamoyl phosphate synthesis and utilization

1. Aspartate transcarbamoylase from 4-day-old radicles of Phaseolus aureus was purified 190-fold by (NH(4))(2)SO(4) fractionation, DEAE-cellulose and DEAE-Sephadex chromatography and Sephadex-gel filtration. The partially purified enzyme, which required P(i) for maximum stability, had an apparent molecular weight of 83000+/-5000. 2. Uridine nucleotides were found to inhibit the activity; UMP was the most potent inhibitor, followed by UDP and UTP. No other nucleotide was found to affect the enzyme, nor could UMP inhibition be overcome by adding another nucleotide. Aspartate gives a hyperbolic substrate-saturation curve, both with and without UMP. The nucleotide inhibitor is non-competitive with respect to this substrate. Carbamoyl phosphate also yields a hyperbolic substrate-saturation curve in the absence of feedback inhibitor, but when UMP is added a sigmoidal pattern results, and the inhibition is competitive with carbamoyl phosphate. 3. The degree of inhibition by UMP is not affected by p-chloromercuribenzoate, urea, mild heat pretreatment or change in pH over the range 8.5-10.5, but is affected by temperature. 4. The aspartate analogue, succinate, both activates and inhibits the reaction, depending on the concentrations of aspartate and succinate used. 5. Kinetic studies with the partially purified enzyme showed that the K(m) for carbamoyl phosphate (0.091 mm) is much lower than that for aspartate (1.7mm). A sequential reaction mechanism was inferred from product-inhibition kinetics, with carbamoyl phosphate binding to the enzyme before aspartate, and the product, carbamoylaspartate, being released ahead of P(i). Initial-velocity studies gave a set of parallel reciprocal plots, compatible with an essentially irreversible step occurring before the binding of aspartate.     

Aspartate transcarbamoylase from Phaseolus aureus. Partial purification and properties

1. Aspartate transcarbamoylase from 4-day-old radicles of Phaseolus aureus was purified 190-fold by (NH₄)₂SO₄ fractionation, DEAE-cellulose and DEAE-Sephadex chromatography and Sephadex-gel filtration. The partially purified enzyme, which required P_i for maximum stability, had an apparent molecular weight of 83000±5000. 2. Uridine nucleotides were found to inhibit the activity; UMP was the most potent inhibitor, followed by UDP and UTP. No other nucleotide was found to affect the enzyme, nor could UMP inhibition be overcome by adding another nucleotide. Aspartate gives a hyperbolic substrate-saturation curve, both with and without UMP. The nucleotide inhibitor is non-competitive with respect to this substrate. Carbamoyl phosphate also yields a hyperbolic substrate-saturation curve in the absence of feedback inhibitor, but when UMP is added a sigmoidal pattern results, and the inhibition is competitive with carbamoyl phosphate. 3. The degree of inhibition by UMP is not affected by p-chloromercuribenzoate, urea, mild heat pretreatment or change in pH over the range 8.5–10.5, but is affected by temperature. 4. The aspartate analogue, succinate, both activates and inhibits the reaction, depending on the concentrations of aspartate and succinate used. 5. Kinetic studies with the partially purified enzyme showed that the K_m for carbamoyl phosphate (0.091 mm) is much lower than that for aspartate (1.7mm). A sequential reaction mechanism was inferred from product-inhibition kinetics, with carbamoyl phosphate binding to the enzyme before aspartate, and the product, carbamoylaspartate, being released ahead of P_i. Initial-velocity studies gave a set of parallel reciprocal plots, compatible with an essentially irreversible step occurring before the binding of aspartate.     

Inactivation of wheat-germ aspartate transcarbamoylase by the arginine-specific reagent phenylglyoxal.

Wheat-germ aspartate transcarbamoylase (EC 2.1.3.2) was inactivated by phenylglyoxal in a first-order process, provided that the inactivation time did not exceed 10 min. Apparent first-order rate constants were linearly dependent on phenylglyoxal concentration, indicating a bimolecular reaction between a single active-centre residue and phenylglyoxal, with second-order constant of 0.023 mM-1 X min-1. A plot of apparent first-order rate constant versus pH showed a steep rise above pH 9.5, indicating that the essential residue has a pKa value of 10.5 or higher, consistent with an arginine residue. Saturating concentrations of the following ligands provided a degree of protection (percentages in parentheses) against 1 mM-phenylglyoxal: N-phosphonoacetyl-L-aspartate, a bisubstrate analogue (94%); carbamoyl phosphate (75%); UMP, an end-product inhibitor (53%). Succinate (an analogue of L-aspartate) alone gave no protection, but in combination with carbamoyl phosphate raised the protection to 92%, in agreement with the known binding order of the two substrates. These results indicate that the essential arginine residue is close to the carbamoyl phosphate site, probably oriented towards the aspartate site. Attempts to desensitize the UMP-binding site by reaction with phenylglyoxal, while protecting the active centre, were unsuccessful. The essential active-centre arginine residue is compared with a similar residue in the Escherichia coli enzyme.     

Wheat-germ aspartate transcarbamoylase. The effect of ligands on the inactivation of the enzyme by trypsin and denaturing agents

In the absence of added ligands aspartate transcarbamoylase (EC 2.1.3.2) from wheat germ is inactivated fairly rapidly by trypsin, by heat (60 degrees C), by highly alkaline conditions (pH11.3) and by sodium dodecyl sulphate. Addition of UMP alone, at low concentrations, decreases the rate of inactivation by each of these agents significantly. Carbamoyl phosphate alone does not alter the rate of inactivation by trypsin and by the detergent, but it antagonizes the effect of UMP in protecting the enzyme against these agents. These results have been interpreted to mean that two conformational states are reversibly accessible to the enzyme, namely an easily inactivated state favoured in the presence of carbamoyl phosphate and a more resistant state favoured in the presence of UMP. In the absence of ligands the enzyme is in the easily inactivated conformation. At very high concentrations l-aspartate also protects the enzyme but to a smaller extent than UMP. Some implications of these results are discussed.     

Active-site-directed inactivation of wheat-germ aspartate transcarbamoylase by pyridoxal 5''-phosphate.

Treatment of 1 microM wheat-germ aspartate transcarbamoylase with 1 mM-pyridoxal 5'-phosphate caused a rapid loss of activity, concomitant with the formation of a Schiff base. Complete loss of activity occurred within 10 min when the Schiff base was reduced with a 100-fold excess of NaBH4. Concomitantly, one amino group per chain was modified. No further residues were modified in the ensuing 30 min. The kinetics of inactivation were examined under conditions where the Schiff base was reduced before assay. Inactivation was apparently first-order. The pseudo-first-order rate constant, kapp., showed a hyperbolic dependence upon the concentration of pyridoxal 5'-phosphate, suggesting that the enzyme first formed a non-covalent complex with the reagent, modification of a lysine then proceeding within this complex. Inactivation of the enzyme by pyridoxal was 20 times slower than that by pyridoxal 5'-phosphate, indicating that the phosphate group was important in forming the initial complex. Partial protection against pyridoxal phosphate was provided by the leading substrate, carbamoyl phosphate, and nearly complete protection was provided by the bisubstrate analogue, N-phosphonoacetyl-L-aspartate, and the ligand-pair carbamoyl phosphate plus succinate. Steady-state kinetic studies, under conditions that minimized inactivation, showed that pyridoxal 5'-phosphate was also a competitive inhibitor with respect to the leading substrate, carbamoyl phosphate. Pyridoxal 5'-phosphate therefore appears to be an active-site-directed reagent. A sample of the enzyme containing one reduced pyridoxyl group per chain was digested with trypsin, and the labelled peptide was isolated and shown to contain a single pyridoxyl-lysine residue. Partial sequencing around the labelled lysine showed little homology with the sequence surrounding lysine-84, an active-centre residue of the catalytic subunit of aspartate transcarbamoylase from Escherichia coli, whose reaction with pyridoxal 5'-phosphate shows many similarities to the results described in the present paper. Arguably the reactive lysine is conserved between the two enzymes whereas the residues immediately surrounding the lysine are not. The same conclusion has been drawn in a comparison of reactive histidine residues in the two enzymes [Cole & Yon (1986) Biochemistry 25, 7168-7174].     

Domain structure of the large subunit of Escherichia coli carbamoyl phosphate synthetase. Location of the binding site for the allosteric inhibitor UMP in the COOH-terminal domain

The large subunit of Escherichia coli carbamoyl phosphate synthetase (a polypeptide of 117.7 kDa that consists of two homologous halves) is responsible for carbamoyl phosphate synthesis from NH3 and for the binding of the allosteric activators ornithine and IMP and of the inhibitor UMP. Elastase, trypsin, and chymotrypsin inactivate the enzyme and cleave the large subunit at a site approximately 15 kDa from the COOH terminus (demonstrated by NH2-terminal sequencing). UMP, IMP, and ornithine prevent this cleavage and the inactivation. Upon irradiation with ultraviolet light in the presence of [14C]UMP, the large subunit is labeled selectively and specifically. The labeling is inhibited by ornithine and IMP. Cleavage of the 15-kDa COOH-terminal region by prior treatment of the enzyme with trypsin prevents the labeling on subsequent irradiation with [14C]UMP. The [14C]UMP-labeled large subunit is resistant to proteolytic cleavage, but if it is treated with SDS the resistance is lost, indicating that UMP is cross-linked to its binding site and that the protection is due to conformational factors. In the presence of SDS, the labeled large subunit is cleaved by trypsin or by V8 staphylococcal protease at a site located 15 or 25 kDa, respectively, from the COOH terminus (shown by NH2-terminal sequencing), and only the 15- or 25-kDa fragments are labeled. Similarly, upon cleavage of the aspartyl-prolyl bonds of the [14C]UMP-labeled enzyme with 70% formic acid, labeling was found only in the 18.5-kDa fragment that contains the COOH terminus of the subunit. Thus, UMP binds to the COOH-terminal domain.(ABSTRACT TRUNCATED AT 250 WORDS)     

Regulatory kinetics of wheat-germ aspartate transcarbamoylase. Adaptation of the concerted model to account for complex kinetic effects of uridine 5''-monophosphate.

The kinetic effects of the end-product inhibitor UMP on aspartate transcarbamoylase (EC 2.1.3.2) purified to homogeneity from wheat germ were studied. In agreement with an earlier study of the relatively crude enzyme [Yon (1972) Biochem. J. 128, 311-320], the half-saturating concentrations of UMP and of the first substrate, carbamoyl phosphate (but not of the second, L-aspartate), were found to be strongly interdependent. However, the kinetic behaviour of the pure enzyme differed from that of the crude enzyme in several important respects, namely: (a) the apparent affinity for UMP was lower with the pure enzyme; (b) sigmoidicity was absent from plots of initial rate versus carbamoyl phosphate concentration, each at a fixed UMP concentration; (c) sigmoidicity was greatly exaggerated in plots of initial rate versus UMP concentration, each at a fixed carbamoyl phosphate concentration, owing to the occurrence of a slight but definite maximum in each plot at low UMP concentration; (d) there was a relative increase in this maximum in the presence of N-phosphonacetyl-L-aspartate, an inhibitor competitive with carbamoyl phosphate. It is shown that a modified two-conformation concerted-transition model can be used to account for most of these features of the pure enzyme. The model treats carbamoyl phosphate and UMP as antagonistic allosteric ligands binding to alternative conformational states [Monod, Wyman & Changeux (1965) J. Mol. Biol. 12, 88-118], carbamoyl phosphate binding non-exclusively (dissociation constants 20 microM and 85 microM respectively) and UMP binding exclusively (dissociation constant 2.5 microM). The model postulates further that the conformation with lower affinity for carbamoyl phosphate has the higher value of kcat., and that it binds UMP in competition with carbamoyl phosphate. Parameters giving the best fit of experimental data to this model were found by a non-linear least-squares search procedure.     

A 70-amino acid zinc-binding polypeptide fragment from the regulatory chain of aspartate transcarbamoylase causes marked changes in the kinetic mechanism of the catalytic trimer.

Interaction between a 70-amino acid and zinc-binding polypeptide from the regulatory chain and the catalytic (C) trimer of aspartate transcarbamoylase (ATCase) leads to dramatic changes in enzyme activity and affinity for active site ligands. The hypothesis that the complex between a C trimer and 3 polypeptide fragments (zinc domain) is an analog of R state ATCase has been examined by steady-state kinetics, heavy-atom isotope effects, and isotope trapping experiments. Inhibition by the bisubstrate ligand, N-(phosphonacetyl)-L-aspartate (PALA), or the substrate analog, succinate, at varying concentrations of substrates, aspartate, or carbamoyl phosphate indicated a compulsory ordered kinetic mechanism with carbamoyl phosphate binding prior to aspartate. In contrast, inhibition studies on C trimer were consistent with a preferred order mechanism. Similarly, 13C kinetic isotope effects in carbamoyl phosphate at infinite aspartate indicated a partially random kinetic mechanism for C trimer, whereas results for the complex of C trimer and zinc domain were consistent with a compulsory ordered mechanism of substrate binding. The dependence of isotope effect on aspartate concentration observed for the Zn domain-C trimer complex was similar to that obtained earlier for intact ATCase. Isotope trapping experiments showed that the compulsory ordered mechanism for the complex was attributable to increased "stickiness" of carbamoyl phosphate to the Zn domain-C trimer complex as compared to C trimer alone. The rate of dissociation of carbamoyl phosphate from the Zn domain-C trimer complex was about 10(-2) that from C trimer.(ABSTRACT TRUNCATED AT 250 WORDS)     

Long-range allosteric transitions in carbamoyl phosphate synthetase

Carbamoyl phosphate synthetase plays a key role in both pyrimidine and arginine biosynthesis by catalyzing the production of carbamoyl phosphate from one molecule of bicarbonate, two molecules of MgATP, and one molecule of glutamine. The enzyme from Escherichia coli consists of two polypeptide chains referred to as the small and large subunits, which contain a total of three separate active sites that are connected by an intramolecular tunnel. The small subunit harbors one of these active sites and is responsible for the hydrolysis of glutamine to glutamate and ammonia. The large subunit binds the two required molecules of MgATP and is involved in assembling the final product. Compounds such as L-ornithine, UMP, and IMP allosterically regulate the enzyme. Here, we report the three-dimensional structure of a site-directed mutant protein of carbamoyl phosphate synthetase from E. coli, where Cys 248 in the small subunit was changed to an aspartate. This residue was targeted for a structural investigation because previous studies demonstrated that the partial glutaminase activity of the C248D mutant protein was increased 40-fold relative to the wild-type enzyme, whereas the formation of carbamoyl phosphate using glutamine as a nitrogen source was completely abolished. Remarkably, although Cys 248 in the small subunit is located at approximately 100 A from the allosteric binding pocket in the large subunit, the electron density map clearly revealed the presence of UMP, although this ligand was never included in the purification or crystallization schemes. The manner in which UMP binds to carbamoyl phosphate synthetase is described.     

A fluorescent probe-labeled Escherichia coli aspartate transcarbamoylase that monitors the allosteric conformational state

A new system has been developed capable of monitoring conformational changes of the 240s loop of aspartate transcarbamoylase, which are tightly correlated with the quaternary structural transition, with high sensitivity in solution. Pyrene, a fluorescent probe, was conjugated to residue 241 in the 240s loop of aspartate transcarbamoylase to monitor changes in conformation by fluorescence spectroscopy. Pyrene maleimide was conjugated to a cysteine residue on the 240s loop of a previously constructed double catalytic chain mutant version of the enzyme, C47A/A241C. The pyrene-labeled enzyme undergoes the normal T to R structural transition, as demonstrated by small-angle x-ray scattering. Like the wild-type enzyme, the pyrene-labeled enzyme exhibits cooperativity toward aspartate, and is activated by ATP and inhibited by CTP at subsaturating concentrations of aspartate. The binding of the bisubstrate analogue N-(phosphonoacetyl)-l-aspartate (PALA), or the aspartate analogue succinate, in the presence of saturating carbamoyl phosphate, to the pyrenelabeled enzyme caused a sigmoidal change in the fluorescence emission. Saturation with ATP and CTP (in the presence of either subsaturating amounts of PALA or succinate and carbamoyl phosphate) caused a hyperbolic increase and decrease, respectively, in the fluorescence emission. The half-saturation values from the fluorescence saturation curves and kinetic saturation curves were, within error, identical. Fluorescence and small-angle x-ray scattering stopped-flow experiments, using aspartate and carbamoyl phosphate, confirm that the change in excimer fluorescence and the quaternary structure change correlate. These results in conjunction with previous studies suggest that the allosteric transition involves both global and local conformational changes and that the heterotropic effect of the nucleotides may be exerted through local conformational changes in the active site by directly influencing the conformation of the 240s loop.     

pH-dependence of the triose phosphate isomerase reaction

1. Some kinetic properties of aspartate transcarbamoylase (EC 2.1.3.2), that had been purified approx. 20-fold from wheat germ, were studied. 2. A plot of enzyme activity against pH showed a low maximum at pH8.4 and a second, higher, maximum at pH10.5. A plot of percentage inhibition by 0.2mm-UMP against pH was approximately parallel to the plot of activity against pH, except that between pH6.5 and 7.5 the enzyme was insensitive to 0.2mm-UMP. 3. Kinetics were studied in detail at pH10.0 and 25 degrees C. In the absence of UMP, initial-rate plots were hyperbolic when the concentration of either substrate was varied. UMP decreased both V(max.) and K(m) in plots of initial rate against l-aspartate concentration, but the plots remained hyperbolic. However, UMP converted plots of initial rate against carbamoyl phosphate concentration into a sigmoidal shape, without significantly affecting V(max.). Plots of initial rate against UMP concentration were also sigmoidal. 4. The theoretical model proposed by Monod et al. (1965) gave a partial explanation of these results. When quasi-equilibrium conditions were assumed analysis in terms of this model suggested a trimeric enzyme binding the allosteric ligands, carbamoyl phosphate and UMP, nearly exclusively to the R and T conformational states respectively, and existing predominantly in the R state when ligands were absent. However, the values of the Hill coefficients for the co-operativity of each allosteric ligand were somewhat less than those predicted by the theory. 5. Some of the implications of these results are discussed, and the enzyme is contrasted with the well-known aspartate transcarbamoylase of Escherichia coli.     

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.     

Steady-state kinetics and isotope effects on the mutant catalytic trimer of aspartate transcarbamoylase containing the replacement of histidine 134 by alanine.

A detailed kinetic analysis of the catalytic trimer of aspartate transcarbamoylase containing the active site substitution H134A was performed to investigate the role of His 134 in the catalytic mechanism. Replacement of histidine by alanine resulted in decreases in the affinities for the two substrates, carbamoyl phosphate and aspartate, and the inhibitor succinate, by factors of 50, 10, and 6, respectively, and yielded a maximum velocity that was 5% that of the wild-type enzyme. However, the pK values determined from the pH dependence of the kinetic parameters, log V and log (V/K) for aspartate, the pK(i) for succinate, and the pK(ia) for carbamoyl phosphate, were similar for both the mutant and the wild-type enzymes, indicating that the protonated form of His 134 does not participate in binding and catalysis between pH 6.2 and 9.2. 13C and 15N isotope effects were studied to determine which steps in the catalytic mechanism were altered by the amino acid substitutions. The 13(V/K) for carbamoyl phosphate exhibited by the catalytic trimer containing alanine at position 134 revealed an isotope effect of 4.1%, probably equal to the intrinsic value and, together with quantitative analysis of the 15N isotope effects, showed that formation of the tetrahedral intermediate is rate-determining for the mutant enzyme. Thus, His 134 plays a role in the chemistry of the reaction in addition to substrate binding. The initial velocity pattern for the reaction catalyzed by the H134A mutant intersected to the left of the vertical axis, negating an equilibrium ordered kinetic mechanism.(ABSTRACT TRUNCATED AT 250 WORDS)     

Function of serine-171 in domain closure, cooperativity, and catalysis in Escherichia coli aspartate transcarbamoylase

Structural studies of Escherichia coli aspartate transcarbamoylase suggest that the R state of the enzyme is stabilized by an interaction between Ser-171 of the aspartate domain and both the backbone carbonyl of His-134 and the side chain of Gln-133 of the carbamoyl phosphate domain of a catalytic chain [Ke, H.-M., Lipscomb, W.N., Cho, Y., & Honzatko, R. B. (1988) J. Mol. Biol. 204, 725-747]. In the present study, site-specific mutagenesis is used to replace Ser-171 by alanine, thereby eliminating the interactions between Ser-171 and both Gln-133 and His-134. The Ser-171----Ala holoenzyme exhibits no cooperativity, more than a 140-fold loss of activity, little change in the carbamoyl phosphate concentration at half the maximal observed specific activity, and a 7-fold increase in the aspartate concentration at half the maximal observed specific activity. Although the Ser-171----Ala enzyme exhibits no homotropic cooperativity, it is still activated by N-(phosphonacetyl)-L-aspartate (PALA), but not by succinate, in the presence of saturating carbamoyl phosphate and subsaturating aspartate. At subsaturating concentrations of aspartate, the Ser-171----Ala enzyme is still activated by ATP but is inhibited less by CTP than is the wild-type enzyme. At saturating concentrations of aspartate, the Ser-171----Ala enzyme is activated by ATP and inhibited by CTP to an even greater extent than at subsaturating concentrations of aspartate. At saturating aspartate, the wild-type enzyme is neither activated by ATP nor inhibited by CTP.(ABSTRACT TRUNCATED AT 250 WORDS)     

Nucleotide ligands protect the inter-domain regions of the multifunctional polypeptide CAD against limited proteolysis, and also stabilize the thermolabile part-reactions of the carbamoyl-phosphate synthase II domains within the CAD polypeptide.

Improved methodologies are described which allow the measurement of the part-reactions, with glutamine or ammonia as nitrogen donor, of mammalian carbamoyl-phosphate synthase II (EC 6.3.5.5) through the incorporation of [14C]bicarbonate into either carbamoyl phosphate or carbamoylaspartate. The enzyme is part of the multifunctional polypeptide (CAD) which also comprises the pyrimidine-biosynthetic enzymes aspartate transcarbamoylase (EC 2.1.3.2) and dihydro-orotase (EC 3.5.2.3). The conformational stability of the carbamoyl-phosphate synthase was investigated through the inactivation of the part-reactions which occurred during incubation at 37 degrees C. The domain involved in the removal of the amide N from glutamine was more thermolabile than the ammonia-dependent synthase moiety. The former activity was stabilized in the presence of sodium aspartate or MgATP, whereas the latter was stabilized by MgATP and MgUTP. Binding of MgUTP and MgATP to CAD restricted the initial proteolysis by trypsin and elastase of one or both regions linking the carbamoyl-phosphate synthase domain to the other major domains. A model is described to account for both aspects of nucleotide binding to CAD; these stabilizing effects may be important in the cell, where similar concentrations of nucleotides are found.     

An essential residue at the active site of aspartate transcarbamylase.

Reaction of phenylglyoxal with aspartate transcarbamylase and its isolated catalytic subunit results in complete loss of enzymatic activity. This modification reaction is markedly influenced by pH and is partially reversible upon dialysis. Carbamyl phosphate or carbamyl phosphate with succinate partially protect the catalytic subunit and the native enzyme from inactivation by phenylglyoxal. In the native enzyme complete protection from inactivation is afforded by N-(phosphonacetyl)-L-aspartate. The decrease in enzymatic activity correlates with the modification of 6 arginine residues on each aspartate transcarbamylase molecule, i.e. 1 arginine per catalytic site. The data suggest that the essential arginine is involved in the binding of carbamyl phosphate to the enzyme. Reaction of the single thiol on the catalytic chain with 2-chloromercuri-4-nitrophenol does not prevent subsequent reaction with phenylglyoxal. If N-(phosphonacetyl)-L-aspartate is used to protect the active site we find that phenylglyoxal also causes the loss of activation of ATP and inhibition by CTP. The rate of loss of heterotropic effects is exactly the same for both nucleotides indicating that the two opposite regulatory effects originate at the same location on the enzyme, or are transmitted by the same mechanism between the subunits, or both.     

Crystal structures of phosphonoacetamide ligated T and phosphonoacetamide and malonate ligated R states of aspartate carbamoyltransferase at 2.8-A resolution and neutral pH

The T----R transition of the cooperative enzyme aspartate carbamoyltransferase occurs at pH 7 in single crystals without visibly cracking many of the crystals and leaving those uncracked suitable for single-crystal X-ray analysis. To promote the T----R transition, we employ the competitive inhibitors of carbamoyl phosphate and aspartate, which are phosphonoacetamide (PAM) and malonate, respectively. In response to PAM binding to the T-state crystals, residues Thr 53-Thr 55 and Pro 266-Pro 268 move to their R-state positions to bind to the phosphonate and amino group of PAM. These changes induce a conformation that can bind tightly the aspartate analogue malonate, which thereby effects the allosteric transition. We prove this by showing that PAM-ligated T-state crystals (Tpam), space group P321 (a = 122.2 A, c = 142.2 A), when transferred to a solution containing 20 mM PAM and 8 mM malonate at pH 7, isomerize to R-state crystals (Rpam,mal,soak), space group also P321 (a = 122.2 A, c = 156.4 A). The R-state structure in which the T----R transition occurs within the crystal at pH 7 compares very well (rms = 0.19 A for all atoms) with an R-state structure determined at pH 7 in which the crystals were initially grown in a solution of PAM and malonate at pH 5.9 and subsequently transferred to a buffer containing the ligands at pH 7 (Rpam,mal,crys). In fact, both of the PAM and malonate ligated R-state structures are very similar to both the carbamoyl phosphate and succinate or the N-(phosphonoacetyl)-L-aspartate ligated structures, even though the R-state structures reported here were determined at pH 7. Crystallographic residuals refined to 0.16-0.18 at 2.8-A resolution for the three structures.     

Factors accelerating pyrimidine production in <Emphasis Type="Italic">Deinococcus radiophilus</Emphasis>

In studying the pyrimidine synthesising pathway in Deinococcus radiophilus two instances of anomalous behaviour were observed. One was the strikingly different results obtained for two types of assay for carbamoyl phosphate synthetase. Both depend on the fixation of ¹⁴C from the substrate bicarbonate to give radioactive products. In the coupled assay the carbamoyl phosphate product of the enzyme is converted to carbamoyl aspartate in the presence of aspartate and aspartate transcarbamoylase. In the direct assay aspartate is omitted from the reaction mixture and the carbamoyl phosphate is converted to urea. It was found that the radioactive counts in the direct assay were about 5% of those measured in the coupled assay. The second anomaly was that omission of glutamine from both assay mixtures had no significant effect on the fixation of radioactive carbon. These results suggested that aspartate amino-N could be the source of nitrogen for glutamine synthesis by a substrate-channelled pathway which delivered glutamine to carbamoyl phosphate synthetase, and that externally added glutamine could not access its binding site on the enzyme.     

Half of Saccharomyces cerevisiae carbamoyl phosphate synthetase produces and channels carbamoyl phosphate to the fused aspartate transcarbamoylase domain.

The first two steps of the de novo pyrimidine biosynthetic pathway in Saccharomyces cerevisiae are catalyzed by a 240-kDa bifunctional protein encoded by the ura2 locus. Although the constituent enzymes, carbamoyl phosphate synthetase (CPSase) and aspartate transcarbamoylase (ATCase) function independently, there are interdomain interactions uniquely associated with the multifunctional protein. Both CPSase and ATCase are feedback inhibited by UTP. Moreover, the intermediate carbamoyl phosphate is channeled from the CPSase domain where it is synthesized to the ATCase domain where it is used in the synthesis of carbamoyl aspartate. To better understand these processes, a recombinant plasmid was constructed that encoded a protein lacking the amidotransferase domain and the amino half of the CPSase domain, a 100-kDa chain segment. The truncated complex consisted of the carboxyl half of the CPSase domain fused to the ATCase domain via the pDHO domain, an inactive dihydroorotase homologue that bridges the two functional domains in the native molecule. Not only was the "half CPSase" catalytically active, but it was regulated by UTP to the same extent as the parent molecule. In contrast, the ATCase domain was no longer sensitive to the nucleotide, suggesting that the two catalytic activities are controlled by distinct mechanisms. Most remarkably, isotope dilution and transient time measurements showed that the truncated complex channels carbamoyl phosphate. The overall CPSase-ATCase reaction is much less sensitive than the parent molecule to the ATCase bisubstrate analogue, N-phosphonacetyl-L-aspartate (PALA), providing evidence that the endogenously produced carbamoyl phosphate is sequestered and channeled to the ATCase active site.     

Aspartate carbamoyltransferase from rat liver

1. Aspartate-carbamoyltransferase activity was concentrated from rat-liver preparations. Only l-aspartate, beta-benzyl-l-aspartate and beta-erythro-hydroxy-dl-aspartate were carbamoylated enzymically. The K(m) for l-aspartate and carbamoyl phosphate have been determined by three methods: colorimetric procedure, radioactive assay with [(14)C]aspartate and an assay with [(14)C]carbamoyl phosphate. 2. The K(m) for aspartate has been determined as a function of the pH; the pK of the functional group at the active site of the enzyme, pK(e), was at pH9.0. Enzymic activity was diminished in the presence of N-ethylmaleimide, p-hydroxymercuribenzoate and the heavy metals Ag(+), Hg(2+), or Zn(2+). The inhibitions could be prevented by mercaptoethanol. These findings suggested the association of a thiol group with the enzymic activity. 3. Enzymic activity was also decreased by sodium lauryl sulphate, urea and dioxan. Competitive inhibition (with l-aspartate) was manifested by maleate, succinate, oxaloacetate, beta-erythro-hydroxy-dl-aspartate and beta-benzyl-l-aspartate. The K(i) for most of these inhibitions has been determined. 4. The properties of the liver enzyme are compared with those of Escherichia coli aspartate carbamoyltransferase and the implications of the findings are discussed.