Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound

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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)

Glutamine has an important role as a source of energy for enterocytes. However, it may also have a key role as a source of nitrogen for the synthesis of nucleotides. The relative contribution of de novo synthesis and salvage pathways seems to be affected by the position of enterocytes within the crypt-villus axis as well as the dietary intake of nucleic acids and glutamine. Nucleotides are especially important to enterocytes during intestinal development, maturation, and repair. Hence an understanding of nucleotide metabolism within enterocytes has important implications regarding both the composition and route of administration of nutrient solutions. Many important questions remain unanswered, in particular: Does glutamine stimulate intestinal de novo pyrimidine synthesis via the action of carbamoyl phosphate synthetase I? Can de novo purine synthesis maintain intestinal purine pools in the absence of dietary nucleic acids? And, what are the specific effects of parenterally administered nucleotides on the metabolism and well-being of enterocytes? A greater understanding of these issues will lead to a more rational approach toward the nutritional modulation of gut dysfunction.
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PMID:Glutamine and nucleotide metabolism within enterocytes. 952 69

Carbamoyl-phosphate synthetase consists of an amidotransferase domain or subunit (GLN) that hydrolyzes glutamine and transfers the ammonia to the synthetase component (CPS) where the biosynthetic reaction occurs. The CPS domain is composed of two homologous subdomains, CPS.A and CPS.B, that catalyze different ATP-dependent reactions involved in carbamoyl phosphate synthesis. When the individual CPS.A and CPS.B subdomains were individually cloned and expressed in Escherichia coli (Guy, H. I., and Evans, D. R. (1996) J. Biol. Chem. 271, 13762-13769), they were found to be functionally equivalent and could each independently catalyze carbamoyl phosphate synthesis. The proposal was advanced that, although the monomers could catalyze the individual partial reactions, overall synthesis of carbamoyl phosphate required a homodimer of CPS.A or CPS.B. To test this hypothesis, the GLN-CPS.B dimer was reversibly dissociated at 1500 bar in a high pressure cell. Dissociation was accompanied by a loss of both glutamine- and ammonia-dependent CPSase activity. Activity was recovered once the protein was returned to atmospheric pressure. If the sample was cross-linked before exposure to high pressure, there was no dissociation and no loss of biosynthetic activity. In contrast, the bicarbonate-dependent ATPase and the carbamoyl phosphate-dependent ATP synthetase activities were largely unaffected by pressure-induced dissociation. These experiments confirmed the hypothesis that the synthesis of carbamoyl phosphate requires the concerted action of the two active sites within the homodimer.
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PMID:Pressure-induced dissociation of carbamoyl-phosphate synthetase domains. The catalytically active form is dimeric. 960 18

Carbamoyl phosphate synthetase from Escherichia coli catalyzes the production of carbamoyl phosphate from two molecules of Mg2+ATP, one molecule of bicarbonate, and one molecule of glutamine. The enzyme consists of two polypeptide chains referred to as the large and small subunits. While the large subunit provides the active sites responsible for the binding of nucleotides and other effector ligands, the small subunit contains those amino acid residues that catalyze the hydrolysis of glutamine to glutamate and ammonia. From both amino acid sequence analyses and structural studies it is now known that the small subunit belongs to the class I amidotransferase family of enzymes. Numerous biochemical studies have suggested that the reaction mechanism of the small subunit proceeds through the formation of the glutamyl thioester intermediate and that both Cys 269 and His 353 are critical for catalysis. Here we describe the X-ray crystallographic structure of carbamoyl phosphate synthetase from E. coli in which His 353 has been replaced with an asparagine residue. Crystals employed in the investigation were grown in the presence of glutamine, and the model has been refined to a crystallographic R-factor of 19.1% for all measured X-ray data from 30 to 1.8 A resolution. The active site of the small subunit clearly contains a covalently bound thioester intermediate at Cys 269, and indeed, this investigation provides the first direct structural observation of an enzyme intermediate in the amidotransferase family.
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PMID:Carbamoyl phosphate synthetase: caught in the act of glutamine hydrolysis. 963 22

The conflicting data on the binding of the two molecules of ATP that are involved in the overall reaction catalyzed by carbamoyl-phosphate synthetase (CPS) of Escherichia coli, and a mechanism recently proposed for this reaction, has led us to reexamine ATP binding using pulse/chase techniques. With [gamma-32P]ATP and bicarbonate in the pulse solution, there is a positive intercept at zero time of approximately 1 mol Pi/mol CPS in the plot of 32Pi formation against time, irrespective of whether the incubation is terminated by the addition of acid or by addition of a chase solution containing glutamine, excess unlabeled ATP and bicarbonate. The intercept is decreased to about 50% if the excess unlabeled ATP is added prior to the addition of the glutamine. These are the expected results if the intercept reflects the reversible formation of enzyme-bound ADP and carboxyphosphate. Approximately 0.6 mol carbamoyl [32P]phosphate/mol enzyme is formed in these experiments when the pulse step is terminated by addition to the chase solution. The ATP molecule that provides the phosphoryl group of carbamoyl phosphate, therefore, also binds to the enzyme in the absence of ammonia or glutamine and reacts in the chase to give carbamoyl phosphate before it can dissociate from the enzyme. At 1 mM ATP, the binding of both ATP molecules is essentially complete at 2.5 s, but the dissociation of the ATP that yields carbamoyl phosphate is extremely slow (t(1/2) of about 6 min at 22 degrees C; HCO3-, 40 mM), although it is faster in the absence of bicarbonate. The extreme sequestration from the aqueous environment of this ATP allows the enzyme-ATP complex to be separated from the surrounding ATP by centrifugal gel filtration. After two successive steps of gel filtration through Sephadex G-50 equilibrated with unlabeled ATP and bicarbonate, the majority of the radioactivity remaining in the solution is bound to the enzyme and is released as [gamma-32P]ATP if acid is added, or is converted to carbamoyl [32P]phosphate by addition to chase solution, without concomitant release of 32Pi. K+ is necessary in the pulse solution, but not in the chase solution, to demonstrate this binding. These findings and other confirmatory experiments demonstrate conclusively that, in the presence of K+, both ATP molecules bind to the enzyme in the absence of ammonia or glutamine. The bound ATP that yields Pi in the overall reaction is replaced relatively rapidly by exchange and by hydrolysis in the bicarbonate-dependent ATPase activity of the enzyme, whereas the bound ATP that provides the phosphoryl group of carbamoyl phosphate is replaced very slowly. The temporal pattern of carbamoyl [32P]phosphate formation from [gamma-32P]ATP, in pulse/chase experiments in which a small concentration of ammonia is added to the pulse solution, shows that, in the normal enzyme reaction, this last ATP molecule binds to the enzyme before ammonia. These findings exclude a recently proposed mechanism [Kothe, M., Eroglu, B., Mazza, H., Samudera, H. & Powers-Lee, S. (1997) Proc. Natl Acad. Sci. USA 94, 12348-12353] in which a single molecule of ATP bound at the catalytic center phosphorylates bicarbonate and provides the phosphoryl group of carbamoyl phosphate. A mechanism in which a single ATP molecule binds, followed by the binding of bicarbonate and ammonia (from glutamine) and the release of Pi before the second molecule of ATP is bound is also excluded. We have previously reported very similar findings for carbamoyl-phosphate synthetase (ammonia), strongly suggesting that the different types of CPS share a common mechanism. The virtual sequestration of the ATP that provides the phosphoryl group of carbamoyl phosphate is consistent with a palmate-binding site, with the nucleotide bound within a beta-sheet sandwich, and a loop closure mechanism triggered by the binding of bicarbonate or the formation of carboxyphosphate.
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PMID:Mechanism of carbamoyl phosphate synthetase from Escherichia coli--binding of the ATP molecules used in the reaction and sequestration by the enzyme of the ATP molecule that yields carbamoyl phosphate. 969 27

Genes for carbamoyl-phosphate synthetase II (CPS II), the first enzyme of de novo pyrimidine biosynthesis, were cloned from kinetoplastids, Trypanosoma cruzi and Leishmania mexicana. T. cruzi CPS II gene encodes a protein of 1524 amino acids that encompasses the glutaminase and CPS domains, but incorporates neither aspartate carbamoyltransferase nor dihydroorotase. The residue corresponding to lysine 993 of Escherichia coli CPS, a residue that characterizes the CPS inhibited by UMP and that is replaced by tryptophan in those inhibited by UTP, is in kinetoplastids a hydrophilic glutamine, in line with the preferential inhibition by UDP of kinetoplastid CPS II.
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PMID:Carbamoyl-phosphate synthetase II in kinetoplastids. 974 64

The formation of carbamoyl phosphate is catalyzed by a single enzyme using glutamine, bicarbonate and two molecules of ATP via a reaction mechanism that requires a minimum of four consecutive reactions and three unstable intermediates. The recently determined X-ray crystal structure of carbamoyl phosphate synthetase has revealed the location of three separate active sites connected by two molecular tunnels that run through the interior of the protein. It has been demonstrated that the amidotransferase domain within the small subunit of the enzyme from Escherichia coli hydrolyzes glutamine to ammonia via a thioester intermediate with Cys269. The ammonia migrates through the interior of the protein, where it reacts with carboxy phosphate to produce the carbamate intermediate. The carboxy phosphate intermediate is formed by the phosphorylation of bicarbonate by ATP at a site contained within the amino-terminal half of the large subunit. The carbamate intermediate is transported through the interior of the protein to a second site within the carboxy-terminal half of the large subunit, where it is phosphorylated by another ATP to yield the final product, carbamoyl phosphate. The entire journey from substrate to product covers a distance of nearly 100 A.
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PMID:Carbamoyl phosphate synthetase: a crooked path from substrates to products. 981 89

Carbamoyl phosphate synthetase catalyzes the hydrolysis of glutamine by the nucleophilic attack of an active site cysteine residue through a mechanism that requires the formation of a gamma-glutamyl thioester intermediate. The steady-state mole fraction of the thioester intermediate was determined to be 0.23 in the presence and absence of ATP and bicarbonate. The kinetics of formation and hydrolysis of the gamma-glutamyl thioester intermediate during CPS catalyzed hydrolysis of glutamine were determined. When ATP and bicarbonate are added to CPS and glutamine, the kcat for glutamine hydrolysis increases from 0.17 to 150 min-1. The observed rate constant for thioester intermediate formation increases from 18 to 580 min-1, and the microscopic rate constant for hydrolysis of the intermediate increases from 0.15 to 460 min-1. These results demonstrate the kinetic competence of the thioester intermediate during glutamine hydrolysis. The rate-determining step changes from the hydrolysis of the intermediate when ATP and bicarbonate are absent to the formation of the intermediate upon the addition of ATP and bicarbonate. The 3 order of magnitude increase in the rate of glutamine hydrolysis upon the addition of ATP and bicarbonate is indicative of the allosteric communication between two of the three reaction centers of CPS. These sites are physically separated by approximately 45 A.
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PMID:Regulatory control of the amidotransferase domain of carbamoyl phosphate synthetase. 984 48

The synthesis of carbamoyl phosphate by the mammalian multifunctional protein, CAD, involves the concerted action of the 40 kDa amidotransferase domain (GLN), that hydrolyzes glutamine and the 120 kDa synthetase (CPS) domain that uses the ammonia, thus produced, ATP and bicarbonate to make carbamoyl phosphate. The separately cloned GLN domain has very low activity due to a reduction in kcat and an increase in Km but forms a hybrid complex with the isolated Escherichia coli CPS subunit. The hybrid has full glutamine-dependent catalytic activity and a functional interdomain linkage. The mammalian-E. coli hybrid was used to investigate the functional consequence of replacing His336 and Glu338, two residues postulated to participate in catalysis as part of a catalytic triad. The mutant mammalian GLN domains formed stable complexes with the E. coli CPS subunit, but the catalytic activity was severely impaired. While the His336Asn mutant does not form measurable amounts of the gamma-glutamyl thioester, the steady state concentration of the intermediate with the Glu338Gly mutant was comparable to the wild type hybrid because both the rate of formation and breakdown of the thioester are reduced. This result is consistent with the postulated role of Glu338 in maintaining His336 in the optimal orientation for catalysis and suggests a mechanism for the GLN CPS functional linkage.
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PMID:The function of Glu338 in the catalytic triad of the carbamoyl phosphate synthetase amidotransferase domain. 985 83

A 25 kb segment of genomic DNA from Trypanosoma cruzi, the causative agent of Chagas' disease, was sequenced. It contains five genes, pyr1, pyr2, pyr3, pyr4, and pyr6-5, encoding all six enzymes involved in de novo pyrimidine biosynthesis, glutamine-dependent carbamoyl-phosphate synthetase, aspartate carbamoyltransferase, dihydroorotase, dihydroorotate dehydrogenase, and orotidine-5'-phosphate decarboxylase linked with orotate phosphoribosyltransferase, respectively. The pyr genes constitute a polycistronic transcription unit on an 800 kb chromosomal DNA in the order of pyr1, pyr3, pyr6-5, pyr2, and pyr4 from the 5' terminus, with intervening sequences of 2.2, 0.4, 8.1, and 0.8 kb. The amino acid sequences deduced from the trypanosomatid pyr genes, except for pyr6, showed closer similarities to mammalian and yeast sequences, and less similarity to archaeal and bacterial sequences. The last two enzymes encoded by a single gene, pyr6-5, are covalently linked in the order opposite to mammalian pyr5-6, and possess a putative glycosomal targeting signal tripeptide, serine-lysine-leucine, at the C terminus. The calculated isoelectric points of 9.3 and 9.9 are also diagnostic of the glycosomal localization of these enzymes. We conclude that the T. cruzi pyr gene organization represents an early progenitor in de novo pyrimidine biosynthesis in eukaryotic lineage, and that the independent pyr genes may have evolved before the gene fusion events that resulted in the three mammalian-type genes, pyr1-3-2, pyr4, and pyr5-6, for UMP synthesis. Peculiarities in the trypanosomatid pyr6-5 gene product are discussed.
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PMID:Novel organization and sequences of five genes encoding all six enzymes for de novo pyrimidine biosynthesis in Trypanosoma cruzi. 987 95

In contrast to several other glutamine amidotransferases including asparagine synthetase, cytidine 5'-triphosphate (CTP) synthetase, carbamoyl phosphate synthetase, and phosphoribosyl pyrophosphate (PRPP) amidotransferase, guanosine monophosphate synthetase (GMPS) will not utilize hydroxylamine as an alternative nitrogen source. Instead, the enzyme is inhibited by an unknown mechanism. One untested hypothesis was that hydroxylamine serves as a substrate and intercepts a xanthosine 5'-monophosphate- (XMP-) adenylate intermediate in the enzyme active site. The nucleotide product of this substitution reaction would be N2-hydroxyguanosine 5'-monophosphate (N2-OH-GMP, 2). Here we describe the chemoenzymatic preparation of 2, via the nucleotide 2-fluoroinosine 5'-monophosphate (F-IMP, 5), and characterization of both these compounds as inhibitors of Escherichia coli GMPS. F-IMP was conceived as an electronic mimic of a reactive intermediate in the GMPS reaction but was found to bind weakly to the enzyme (IC50 > 2 mM). In contrast, N2-OH-GMP shows time-dependent inhibition and is competitive with respect to XMP (Ki = 92 nM), representing the first example of a compound that displays these kinetic properties with GMPS. The mechanism of inhibition is proposed to occur via formation of a ternary E.ATP.2 complex, followed by a rate-determining isomerization to a higher affinity complex that has a t1/2 =7.5 min. The contrast in inhibitory activity for 2-substituted purines with GMPS formulates a basis for future inhibitor design. In addition, these results complement recent structural studies of GMPS and implicate the formation of the XMP-adenylate intermediate inducing a probable conformational change that stimulates the hydrolysis of glutamine.
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PMID:N2-hydroxyguanosine 5'-monophosphate is a time-dependent inhibitor of Escherichia coli guanosine monophosphate synthetase. 989 Sep 11


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