EC:6.3.5.5 - FACTA Search

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Query: EC:6.3.5.5 (CPS)
1,262 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

This paper demonstrates the formation of "active CO2" (CO2-P), a precursor of carbamoyl phosphate (CP), with frog liver carbamoyl-phosphate synthetase. Absence of ammonia is essential for the demonstration by pulse incubation with H14CO3- of CO2-P. Adenosine triphosphate (ATP) and acetylglutamate are required for the synthesis of CO2-P, which is highly unstable in aqueous solutions (t1/2 = 0.75 s at 24 degrees C at neutral pH). In the absence of ammonia, CO2-P attains rapidly a steady-state level, which depends on the concentration of ATP and HCO3-. The "apparent KM'S" are approximately equal to those found for the adenosine triphosphate (ATPase) activity of the enzyme. The maximum level of CO2-P is limited by the amount of enzyme, and approximates 4 mol of intermediate/mol of enzyme. The unprotonated form of ammonia seems to be the species reacting with CO2-P to produce CP. The reaction of CO2-P and NH3 is very fast (rate constant kn = 8 x 10(4) M-1 S-1) and does not consume free ATP. Therefore, the 2 mol of ATP necessary for CP synthesis binds or reacts with the enzyme and/or CO2 prior to reaction with NH3. The reaction of CO2-P with NH3 also takes place in acetone under conditions at which the enzyme is not active, suggesting little or no assistance from enzyme catalysis or that a part of the catalytic site is "frozen" by the solvent in the active conformation. In the light of these and other findings, a new scheme is proposed for the mechanism of frog liver carbamoyl-phosphate synthetase and some considerations are made on the chemical nature of the intermediate and on the possible evolutionary significance of the reaction of CO2-P with NH3 in acetone.
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PMID:Mechanism of mitochondrial carbamoyl-phosphate synthetase: synthesis and properties of active CO2, precursor of carbamoyl phosphate. 1 11

1. The influence of ammonia and ornithine on the oxygen uptake and the formation of citrulline was investigated with isolated rat liver mitochondria. The experiments were performed in a cytosol-like saline medium at 38 degrees C. 2. Under these conditions an increase of the respiration rate by ammonia and ornithine was observed, but a small response to external ADP, only. The missing stimulation by ADP was due to a partial inhibition of the respiratory chain by traces of zinc (approximately 1 microM) present in the medium. This inhibition was only detected at low concentrations of mitochondria. 3. For activation of respiration by ammonia plus ornithine two different processes were responsible: (i) chelation of the inhibiting zinc by ornithine, which could be prevented by EDTA; (ii) ADP production in the matrix space during formation of carbamoyl phosphate, which could be prevented by oligomycin but not by carboxyatractyloside. 4. This stimulus of the carbamoyl phosphate formation and of the equivalent citrulline synthesis on the mitochondrial respiration ran to 12% of that increase caused by phosphorylation of external ADP. The maximum rate of citrulline formation was limited by the activity of carbamoyl phosphate synthetase. 5. Added ADP suppresses the production of citrulline probably by the exchange of extramitochondrial ADP versus intramitochondrial ATP. The data suggest a common adenine nucleotide pool delivering ATP to the adenine nucleotide translocase as well as to the carbamoyl phosphate synthetase.
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PMID:The stimulation of the mitochondrial respiration by citrulline synthesis. 11 92

Mutants resistant to 5-fluorouracil, 5-fluorouridine and 5-fluorodeoxyuridine have been selected in Aspergillus nidulans. Growth tests combined with genetic analysis showed that mutations conferring resistance to fluoropyrimidines could occur in at least seven genes. Three of these fulE, fulF and furA were concerned with either the uptake of pyrimidines or their conversion to uridine monophosphate. The other four genes did not affect these functions. Mutations in fulA probably confer resistance by lowering ornithine transcarbamoylase, thereby making the normally arginine-specific carbamoyl phosphate pool available for increased uracil synthesis. Mutations in fulD may make the arginine-specific carbamoyl phosphate synthetase insensitive to inhibition or repression by arginine, and so lead to increased carbamoyl phosphate pool sizes, and increased uracil synthesis. Both fulA and fulD mutants suppress pyrA mutants which lack the uracil-specific carbamoyl phosphate synthetase. Mutations in fulB and fulC do not suppress pyrA, and so may act more directly to increase uracil synthesis. The synthesis of aspartate carbamoyl transferase in fulB7 strains is not repressed by uracil. fulC mutants are closely linked to the pyrA, B, C, N region which codes for the first two enzymes of pyrimidine biosynthesis, and may result in these enzymes being less sensitive to inhibition by uracil.
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PMID:Pyrimidine biosynthesis in Aspergillus nidulans. Isolation and characterisation of mutants resistant to fluoropyrimidines. 12 29

The activated CO2 intermediate formed in the reaction catalyzed by glutamine-dependent carbamyl phosphate synthetase was identified as carbonic-phosphoric anhydride through the use of two independent procedures. The carboxy phosphate intermediate was reduced to formate by treatment with potassium borohydride. Although both free CO2 and the enzyme-bound activated CO2 are reduced to formic acid by borohydride, it was possible to selectively introduce a 14C label into the enzyme-bound activated CO2 and thus into the formic acid derived from it. Such [14C]formate formation required the presence of ATP, KCl, and the enzyme, and evidence was obtained that the [14C]formate found is not derived from carbamyl phosphate or from bicarbonate bound nonspecifically to the enzyme. When the enzyme was treated with L-2-amino-4-oxo-5-chloropentanoate (or cyanate), the formation of [14C]formate was increased about 2-fold, a finding consistent with the previous observation that such treatment effects a similar increase in the bicarbonate-dependent cleavage of ATP catalyzed by the enzyme. When reaction mixtures containing the enzyme, [gamma-32P]ATP, and [14C]bicarbonate were methylated by treatment with diazomethane, a labeled compound was formed which cochromatographed with authentic trimethyl carboxy phosphate. Equimolar quantities of 14C and 32P wer incorporated into the intermediate, thus confirming its identification as carboxy phosphate. Nonenzymatic transphosphorylation from ATP to bicarbonate to form carboxy phosphate was also detected by diazomethane trapping.
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PMID:Identification of enzyme-bound activated CO2 as carbonic-phosphoric anhydride: isolation of the corresponding trimethyl derivative from the active site of glutamine-dependent carbamyl phosphate synthetase. 18 54

Application of the pulse-chase procedure to study of the binding and utilization of ATP by glutamine-dependent carbamyl phosphate synthetase from Escherichia coli showed that the enzyme binds the two molecules of ATP used in this reaction at the same time, and that the two ATP-binding sites are functionally different. Thus, ATP bound to the first ATP site is used for carboxy phosphate formation, and ATP bound to the second ATP site is used for phosphorylation of carbamate. The present and previous findings support a mechanism that involves intermediate formation of two highly unstable intermediates: carboxy phosphate and carbamate. It is proposed that the presence of all of the reactants on the enzyme at the start of the catalytic cycle allows immediate utilization of these labile compounds in the carbamyl phosphate synthesis reaction.
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PMID:Mechanism of the reaction catalyzed by carbamyl phosphate synthetase. Binding of ATP to the two functionally different ATP sites. 20 98

The arginine-specific carbamoyl-phosphate synthase of yeast was stabilized sufficiently to allow partial purification of the enzyme (30- to 40-fold). The synthase (mol. wt 115000) comprised two unequal subunits: a heavy subunit (mol. wt 80000) capable of catalysing synthesis of carbamoyl phosphate with ammonia as a nitrogen donor and a light subunit conferring upon the holoenzyme the ability to utilize glutamine. The enzyme had unusually high affinity for ATP (Km = 0.2 mM) and atypical negative cooperativity for glutamine binding ([S]0.5 = 0.25 mM). Glutamine activity was not modulated by possible effectors such as arginine, ornithine or N-acetylglutamate. Thus, although the yeast arginine enzyme physically and functionally resembles the single enteric synthase, the systems differ substantially both in kinetic properties and in regulation of activity.
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PMID:Purification and properties of the arginine-specific carbamoyl-phosphate synthase from Saccharomyces cerevisiae. 20 52

The pyrimidine-3 locus of Neurospora crassa specifies a multienzyme complex comprising pyrimidine-specific carbamoyl phosphate synthase (CPSpyr) and aspartate carbamoyl transferase (ACT). It appears to be divided into a translationally proximal CPS-specific region and a distal ACT-specific region. Levels of complementation for ACT activity between pairs of four pyr-3 CPS+ ACT- mutants showed a range from 12% to 68% of the wild-type level of the enzyme. This is interpreted as interallelic complementation, contradicting certain earlier suggestion of two dissimilar ACT subunits. Proteolysis of an extract from a heterokaryon formed from two of the above CPS+ ACT- alleles (alpha and beta) did not lead to loss of ACT activity, but led to the formation of a fragment with ACT activity with a similar molecular weight (92,000 daltons) to that produced in extracts of wild type strain. The pyr-3 polar mutant 43-174 which is enzymatically CPS+ ACT- and which fails to complement with any other CPS+ ACT- alleles, thus suggesting its location towards the proximal end of the ACT region, has CPS activity associated with a form of 180,000 daltons molecular weight. These findings are used to contruct a model for structure of the native enzyme complex.
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PMID:A possible model for the structure of the Neurospora carbamoyl phosphate synthase-aspartate carbamoyl transferase complex enzyme. 20 7

The kinetic mechanism of Escherichia coli carbamoyl-phosphate synthetase has been determined at pH 7.5, 25 degrees C. With ammonia as the nitrogen source, the initial velocity and product inhibition patterns are consistent with the ordered addition of MgATP, HCO3-, and NH3. Phosphate is then released and the second MgATP adds to the enzyme, which is followed by the ordered release of MgADP, carbamoyl phosphate, and MgADP. With glutamine as the ammonia donor, the patterns are consistent with a two-site mechanism in which glutamine binds randomly to the small molecular weight subunit producing glutamate and ammonia. Glutamate is released and the ammonia is transferred to the larger subunit. Carbamoyl-phosphate synthetase has also been shown to require a free divalent cation for full activity.
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PMID:Kinetic mechanism of Escherichia coli carbamoyl-phosphate synthetase. 21 4

This paper demonstrates, by pulse-chase techniques, the binding to rat liver mitochondrial carbamoyl phosphate synthetase of the ATP molecule (ATPB) which transfers its gamma-phosphoryl group to carbamoyl phosphate. This bound APTB can react with NH3, HCO-3 and ATP (see below) to produce carbamoyl phosphate before it exchanges with free ATP. Mg2+ and N-acetylglutamate, but not NH3 or HCO-3, are required for this binding; the amount bound depends on the concentration of ATP (Kapp = 10--30 microns ATP) and the amount of enzyme. At saturation at least one ATPB molecule binds per enzyme dimer. Binding of ATPB follows a slow exponential time course (t1/2 8--16 s, 22 degrees C), independent of ATP concentration and little affected by NH3, NCO-3 or by incubation of the enzyme with unlabelled ATP prior to the pulse of [gamma-32P]ATP. Formation of carbamoyl phosphate from traces of NH3 and HCO-3 when the enzyme is incubated with ATP follows the kinetics expected if it were generated from the bound ATPB, indicating that the latter is a precursor of carbamoyl phosphate ('Cbm-P precursor') in the normal enzyme reaction. This indicates that the site for ATPB is usually inaccessible to ATP in solution but becomes accessible when the enzyme undergoes a periodical conformational change. Bound ATP becomes Cbm-P precursor when the enzyme reverts to the inaccessible conformation. Pulse-chase experiments in the absence of NH3 and HCO-3 (less than 0.2 mM) also demonstrate binding of ATPA (the molecule which yields Pi in the normal enzyme reaction), as shown by a 'burst' in 32Pi production. Therefore, (in accordance with our previous findings) both ATPA and ATPB can bind simultaneously to the enzyme and react with NH3 and HCO-3 in the chase solution before they can exchange with free ATP. However, at low ATP concentration (18 micron) in the pulse incubation, only ATPB binds since ATP is required in the chase (see above). Despite the presence of two ATP binding sites, the bifunctional inhibitor adenosine(5')pentaphospho(5')adenosine(Ap5A) fails to inhibit the enzyme significantly. A more detailed modification of the scheme previously published [Rubio, V. & Grisolia, S. (1977) Biochemistry, 16, 321--329] is proposed; it is suggested that ATPB gains access to the active centre when the products leave the enzyme and the active centre is in an accessible configuration. The transformation from accessible to inaccessible configuration appears to be part of the normal enzyme reaction and may represent to conformational change postulated by others from steady-state kinetics. The properties of the intermediates also indicate that hydrolysis of ATPA must be largely responsible for the HCO-3-dependent ATPase activity of the enzyme. The lack of inhibition of the enzyme by Ap5A indicates substantial differences between the Escherichia coli and the rat liver synthetase.
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PMID:Mechanism of carbamoyl-phosphate synthetase. Binding of ATP by the rat-liver mitochondrial enzyme. 21 11

The reaction of phenylglyoxal with two enzymes in which ATP plays a complex role has been studied. Both ovine brain glutamine synthetase and Escherichia coli carbamyl phosphate synthetase [carbamoyl-phosphate synthase (glutamine); ATP:carbamate phosphotransferase (dephosphorylating, amido-transferring); EC 2.7.2.9]were inactivated by phenylglyoxal. The specificity of this reagent for arginyl residues of the two proteins was confirmed by amino acid analysis. ATP, but not the other substrates, protected these enzymes against inactivation by phenylglyoxal. Carbamyl phosphate synthetase was also protected by IMP and ornithine, positive allosteric effectors that alter the enzymatic activity be increasing the affinity for ATP. UMP, a negative allosteric effector that decreases the affinity for ATP, did not protect against inactivation. Differential labeling experiments with [14C]phenylglyoxal showed that the number of arginyl residues protected by ATP corresponded quite well to the known number of ATP catalytic sites for each protein. These data indicate that arginyl residues at the active sites of glutamine synthetase and carbamyl phosphate synthetase are involved in the binding of ATP. This phenylglyoxal inactivation study also provided information about the mechanistic role of ATP in the two synthetases. The data obtained on glutamine synthetase support the theory that ATP is attached to the enzyme as a portion of the catalytic site, and that its presence is essential for the binding of glutamate and glutamine. The data obtained on carbamyl phosphate synthetase are consistent with the previous proposal that carbonyl phosphate is an intermediate in the ATP-dependent activation of bicarbonate by this enzyme. It is also of interest that, with both glutamine synthetase and carbamyl phosphate synthetase, only a small portion of the total arginyl population of these enzymes reacted with phenylglyoxal. A summary of previous studies on the modification of enzyme arginyl residues is presented.
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PMID:Functional arginyl residues as ATP binding sites of glutamine synthetase and carbamyl phosphate synthetase. 24 Oct 76

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