Domain structure of rat liver carbamoyl phosphate synthetase I

Independently folded structural domains of rat liver carbamoyl phosphate synthetase I have been identified by partial proteolytic cleavage under nondenaturing conditions. The pattern of fragments produced was analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The NH2-terminal sequences of the fragments were determined by automated Edman degradation. Comparison of these fragment sequences with the sequence of the intact protein allowed alignment of the fragments. The hydrolysis of carbamoyl phosphate synthetase I (Mr 160,000) by either trypsin or elastase proceeded in two stages, with two alternative routes of degradation for elastase. The alignment of the final tryptic fragments from the NH2 terminus to the COOH terminus was: Mr 87,000 fragment-Mr 62,000 fragment-group of small peptides. The alignment of the final elastase fragments was: Mr 37,000 fragment-Mr 108,000 fragment-group of small peptides. The rates of cleavage were affected by the presence of the substrate ATP or the positive allosteric effector N-acetylglutamate; the preferred route of elastase cleavage was also affected. In addition to providing a map of the carbamoyl phosphate synthetase I domains and preliminary information on the interaction of substrates with these domains, the present studies provide further support for the proposal that domains serve as units of protein evolution since the 37-kDa fragment encompasses the region of the rat liver synthetase that is homologous to the 40-kDa subunit of the Escherichia coli synthetase.     

The interaction of cardiolipin with rat liver carbamoyl phosphate synthetase I

A selective interaction of rat liver carbamoyl phosphate synthetase I with cardiolipin, and other anionic phospholipids, has been demonstrated. The enzymatic activity of the synthetase is inhibited by cardiolipin and, to a lesser extent, by phosphatidylglycerol, phosphatidylinositol, and phosphatidylserine. This group of anionic phospholipids also induced a conformational change in the synthetase, yielding a species with increased exposure of the linkages between independently folded domains of the enzyme, as determined by limited proteolysis under nondenaturing conditions. The interaction of cardiolipin with carbamoyl phosphate synthetase I was a fairly slow process, with complex kinetics, and was apparently irreversible. The inclusion of Mg2+ or of MgATP in the incubation mixture prevented the cardiolipin effects. The zwitterionic phospholipids phosphatidylcholine and phosphatidylethanolamine had negligible effects on the structure and activity of the synthetase. This interaction between cardiolipin and carbamoyl phosphate synthetase I potentially constitutes one of the mechanisms by which the synthetase forms its loose association with the inner mitochondrial membrane. Multiple mechanisms, including synthetase conformational changes, cardiolipin phase changes, and ATP/ADP binding site involvement, are possibly involved in the phospholipid/synthetase interaction and the resulting potential regulatory mechanism(s) for urea cycle activity.     

Photoaffinity labeling of rat liver carbamoyl phosphate synthetase I by 8-azido-ATP

8-Azido-ATP has been found to serve as a photoaffinity label for two distinct ATP sites on rat liver carbamoyl phosphate synthetase I and to allow preliminary localization of these sites. In the dark, 8-azido-ATP acted as a competitive inhibitor with respect to ATP. Ultraviolet irradiation of carbamoyl phosphate synthetase I in the presence of 8-azido-ATP led to an irreversible loss of activity. ATP specifically protected against this inactivation. The incorporation of 2 mol of 8-azido-ATP per mol of enzyme was required for complete inactivation. To localize the 8-azido-ATP-binding sites to discrete regions of carbamoyl phosphate synthetase I which appear to be structural domains, the enzyme was photolabeled with [gamma-32P]8-azido-ATP and subjected to limited proteolytic digestion. The resulting model for the functional roles of the domains is that there is one ATP site on each of the two large internal structural domains of the enzyme. Each of these domains was found to contain the consensus sequences A and B common to many other nucleotide-binding proteins (Walker, J.E., Saraste, M., Runswick, M. J., and Gay, N. J. (1982) EMBO J. 1, 945-951). In addition, there is extensive structural and possibly functional interaction of the smaller N-terminal domain with one of the internal ATP-binding domains, analogous to a subunit interaction observed with the evolutionarily related Escherichia coli carbamoyl phosphate synthetase.     

Kinetic studies of bovine liver carbamoyl phosphate synthetase

A through study of initial-rate data has been made on carbamoyl phosphate synthetase from bovine liver. On the basis of the results the order of substrate binding to the enzyme is ATPMg followed by HCO₃⁻, ATPMg and NH₄⁺. A model for the enzymic mechanism is proposed, and the rate equations describing it are presented. Details of the derivation of the initial-rate equation for the kinetic mechanism proposed have been deposited as Supplementary Publication SUP 50032 (6 pages) at the British Library, Lending Division (formerly the National Lending Library for Science and Technology), Boston Spa, Yorks. LS23 7QB, U.K., from whom copies may be obtained on the terms indicated in Biochem. J. (1973), 131, 5.     

Product inhibition studies on bovine liver carbamoyl phosphate synthetase

A study of the product-inhibition patterns of carbamoyl phosphate synthetase from bovine liver is reported. Inhibition by adenosine, AMP and inorganic ions is also reported. The results are in agreement with the previously proposed model in which the order of substrate binding is ATPMg, followed by HCO(3) (-), ATPMg and NH(4) (+). The order of product release on the basis of the reported results is carbamoyl phosphate, followed by ADPMg, ADPMg and inorganic phosphate.     

The interaction of rat liver carbamoyl phosphate synthetase and ornithine transcarbamoylase with inner mitochondrial membranes

The intramitochondrial localization of the urea cycle enzymes, carbamoyl phosphate synthetase and ornithine transcarbamoylase, has been examined by both in vitro and in situ studies. The following three lines of evidence are presented to establish that significant fractions of the rat liver enzymes are loosely associated with the inner mitochondrial membrane: 1) when the mitochondrion is fractionated, the enzymes partition between the matrix and membrane fractions in the absence of detergent and partition solely to the matrix in the presence of detergent; 2) the purified enzymes associate with purified inner membrane preparations; and, 3) protein A-gold electron microscopic immunocytochemical analysis of rat liver sections reveals a nonrandom arrangement of the enzyme, with the maximal enzyme density adjacent to the inner mitochondrial membrane. These findings serve as the basis for novel potential mechanisms for regulation of the activity of the enzymes and provide additional evidence for the extensive organization of the mitochondrial matrix. The membrane interaction might also serve as the organizing factor for a carbamoyl phosphate synthetase-ornithine transcarbamoylase or other multienzyme complex.     

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.     

The regulation of carbamoyl phosphate synthase activity in rat liver mitochondria.

The rate at which isolated rat liver mitochondria synthesized citrulline with NH4C1 as nitrogen source was markedly dependent on the protein content of the diet. 2. Citrulline synthesis was not rate-limited by substrate concentration, substrate transport or ornithine transcarbamoylase activity under the conditions used. 3. The intramitochondrial content of an activator of carbamoyl phosphate synthase, assumed to be N-acetyl-glutamate, varied markedly with dietary protein content. The variation in the concentration of this activator was sufficient to account for the observed variation in the rates of citrulline synthesis if this synthesis were rate-limited by the activity of carbamoyl phosphate synthase. 4. The rates of urea formation from NH4Cl as nitrogen source in isolated liver cells showed variations in response to diet that closely paralleled the variations in the rates of citrulline synthesis observed in isolated mitochondria. 5. These results are consistent with the postulate that when NH4Cl plus ornithine are present in an excess, the rate of urea synthesis is regulated at the level of carbamoyl phosphate synthase activity.     

Direct demonstration of carbamoyl phosphate formation on the C-terminal domain of carbamoyl phosphate synthetase

Carbamoyl phosphate synthetase synchronizes the utilization of two ATP molecules at duplicated ATP-grasp folds to catalyze carbamoyl phosphate formation. To define the dedicated functional role played by each of the two ATP sites, we have carried out pulse/labeling studies using the synthetases from Aquifex aeolicus and Methanococcus jannaschii, hyperthermophilic organisms that encode the two ATP-grasp folds on separate subunits. These studies allowed us to differentially label each active site with [gamma-(32)P]ATP and determine the fate of the labeled gamma-phosphate in the synthetase reaction. Our results provide the first direct demonstration that enzyme-catalyzed transfer of phosphate from ATP to carbamate occurs on the more C-terminal of the two ATP-grasp folds. These findings rule out one mechanism proposed for carbamoyl phosphate synthetase, where one ATP acts as a molecular switch, and provide additional support for a sequential reaction mechanism where the gamma-phosphate groups of both ATP molecules are transferred to reactants. CP synthesis by subunit C in our single turnover pulse/chase assays did not require subunit N, but subunit N was required for detectable CP synthesis in the traditional continuous assay. These findings suggest that cross-talk between domain N and C is required for product release from subunit C.     

Activation of carbamoyl phosphate synthetase by cryoprotectants

Molecular and Cellular Biochemistry - Carbamoyl phosphate synthetase I (E.C.6.3.4.16) from rat liver is activated by a range of cryoprotectants. Their diverse chemical structure and the normal...     

Control of pyrimidine biosynthesis in the perfused liver. Feedback inhibition of glutamine-dependent carbamoyl phosphate synthetase.

The site of feedback inhibition of the biosynthesis of pyrimidine nucleotides de novo was investigated in the isolated perfused rat liver. Hepatic uridine phosphate contents were specifically depleted by use of D-galactosamine. The effective activities of enzymes involved in the synthetic pathway were deduced from the rats of incorporation of labeled precursors into the acid-soluble uracil nucleotide pool and into some intermediates of the pathway. The labeling of hepatic urea was also monitored. When the uridine phosphate contents were less than 20% of controls, the incorporation of [14-C]-bicarbonate was stimulated about 20-fold. Label from [U-14C]oxaloacetate used as permeable precursor of intrace-lular aspartate was introduced into the uridylates to the same extent in normal and UTP-depleted livers. Similar results were obtained with labeled carbamoyl phosphate although the uptake of this compound by the liver was rather low. The lack of labeling of urea from exogenous carbamoyl phosphate does not indicate a free exchange of extra- and intramitochondrial carbamoyl phosphate. [ureido-14C]Ureidosuccinate produced in normal and D-galactosamine-treated livers almost identical labeling patterns of dihydroorotate, orotate and orotidine 5'-phosphate. The steady state concentrations of these intermediates were all below 15 nmol/g liver wet weight.     

Characterization of carbamoyl phosphate synthetase of Streptomyces spp

Carbamoyl phosphate synthetase (CPS) activity in Streptomyces lividans was repressed (70%) by addition of arginine and uracil in the growth medium. Enzyme activity was also inhibited by UMP and activated by ornithine and IMP. Pattern of inhibition and activation was similar irrespective of whether the cells were grown in medium supplemented with arginine or with uracil. A mutant of S. coelicolor with dual auxotrophy for arginine and uracil possessed only about 20% of CPS activity compared to the wild-type strain. An activity staining protocol has been developed for CPS enzyme. Using this method a single CPS band has been observed in the crude extracts of Escherichia coli as well as in S. lividans. Taken together, our results supported the conclusion that Streptomyces species might possess a single CPS enzyme unlike other gram-positive bacteria, which show the presence of two pathway-specific isozymes (Bacillus) or none (Lactobacillus and Leuconostoc).     

Nucleotide recognition in the ATP-grasp protein carbamoyl phosphate synthetase

Synthesis of carbamoyl phosphate by carbamoyl phosphate synthetase (CPS) requires the coordinated utilization of two molecules of ATP per reaction cycle on duplicated nucleotide-binding sites (N and C). To clarify the contributions of sites N and C to the overall reaction, we carried out site-directed mutagenesis aimed at changing the substrate specificity of either of the two sites from ATP to GTP. Mutant design was based in part on an analysis of the nucleotide-binding sites of succinyl-CoA synthetases, which share membership in the ATP-grasp family with CPS and occur as GTP- and ATP-specific isoforms. We constructed and analyzed Escherichia coli CPS single mutations A144Q, D207A, D207N, S209A, I211S, P690Q, D753A, D753N, and F755A, as well as combinations thereof. All of the mutants retained ATP specificity, arguing for a lack of plasticity of the ATP sites of CPS with respect to nucleotide recognition. GTP-specific ATP-grasp proteins appear to accommodate this substrate by a displacement of the base relative to the ATP-bound state, an interaction that is precluded by the architecture of the potassium-binding loop in CPS. Analysis of the ATP-dependent kinetic parameters revealed that mutation of several residues conserved in ATP-grasp proteins and CPSs had surprisingly small effects, whereas constructs containing either A144Q or P690Q exerted the strongest effects on ATP utilization. We propose that these mutations affect proper movement of the lids covering the active sites of CPS, and interfere with access of substrate.     

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.     

Some regulatory properties of pea leaf carbamoyl phosphate synthetase

Carbamoyl phosphate synthetase of pea shoots (Pisum sativum L.) was purified 101-fold. Its stability was greatly increased by the addition of substrates and activators. The enzyme was strongly inhibited by micromolar amounts of UMP (Ki less than 2 mum). UDP, UTP, TMP, and ADP were also inhibitory. AMP caused either slight activation (under certain conditions) or was inhibitory. Uridine nucleotides were competitive inhibitors, as was AMP, while ADP was a noncompetitive inhibitor. Enzyme activity was increased manyfold by the activator ornithine. Ornithine acted by increasing the affinity for Mg.ATP by a factor of 8 or more. Other activators were IMP, GMP, ITP, and GTP, IMP, like ornithine, increased the Michaelis constant for Mg.ATP. The activators ornithine, GMP, and IMP (but not GTP and ITP) completely reversed inhibition caused by pyrimidine nucleotides while increasing the inhibition caused by ADP and AMP.     

Access to the carbamate tunnel of carbamoyl phosphate synthetase

The X-ray crystal structure of carbamoyl phosphate synthetase (CPS) from Escherichia coli revealed the existence of a molecular tunnel that has been proposed to facilitate the translocation of reaction intermediates between remotely located active sites. Five highly conserved glutamate residues, including Glu-25, Glu-383, Glu-577, Glu-604, and Glu-916, are close together in two clusters in the interior wall of the molecular tunnel that enables the intermediate carbamate to migrate from the site of synthesis to the site of utilization. Two arginines, Arg-306 and Arg-848, are located at either end of the carbamate tunnel and participate in the binding of ATP at each of the two active sites within the large subunit of CPS. The mutation of Glu-25 or Glu-577 results in a diminution in the overall rate of carbamoyl phosphate formation. Similar effects are observed upon mutation of Arg-306 and Arg-848 to alanine residues. The conserved glutamate and arginine residues may function in concert with one another to control entry of carbamate into the tunnel prior to phosphorylation to carbamoyl phosphate. The electrostatic environment of tunnel interior may help to stabilize the tunnel architecture and prevent decomposition of carbamate through protonation.     

The binding of inosine monophosphate to Escherichia coli carbamoyl phosphate synthetase.

Carbamoyl phosphate synthetase (CPS) from Escherichia coli catalyzes the formation of carbamoyl phosphate, which is subsequently employed in both the pyrimidine and arginine biosynthetic pathways. The reaction mechanism is known to proceed through at least three highly reactive intermediates: ammonia, carboxyphosphate, and carbamate. In keeping with the fact that the product of CPS is utilized in two competing metabolic pathways, the enzyme is highly regulated by a variety of effector molecules including potassium and ornithine, which function as activators, and UMP, which acts as an inhibitor. IMP is also known to bind to CPS but the actual effect of this ligand on the activity of the enzyme is dependent upon both temperature and assay conditions. Here we describe the three-dimensional architecture of CPS with bound IMP determined and refined to 2.1 A resolution. The nucleotide is situated at the C-terminal portion of a five-stranded parallel beta-sheet in the allosteric domain formed by Ser(937) to Lys(1073). Those amino acid side chains responsible for anchoring the nucleotide to the polypeptide chain include Lys(954), Thr(974), Thr(977), Lys(993), Asn(1015), and Thr(1017). A series of hydrogen bonds connect the IMP-binding pocket to the active site of the large subunit known to function in the phosphorylation of the unstable intermediate, carbamate. This structural analysis reveals, for the first time, the detailed manner in which CPS accommodates nucleotide monophosphate effector molecules within the allosteric domain.     

Conversion of carbamoyl phosphate to hydroxyurea. An assay for carbamoylphosphate synthetase

A specific colorimetric method for determination of hydroxyurea is described. Using this method it was shown that carbamoyl phosphate or cyanate (a decomposition product of carbamoyl phosphate) and hydroxylamine react to form hydroxyurea. Hydroxylamine was employed to trap carbamoyl phosphate produced by carbamoylphosphate synthetase. A radio chemical assay for activity of carbamoylphosphate synthetase gives results in agreement with the method based on coupling the formation of carbamoyl phosphate with ornithine transcarbamoylase. This new assay is sensitive, rapid, and reproducible, and does not require supplementary enzymes or their substrates in the incubation medium.     

Structural defects within the carbamate tunnel of carbamoyl phosphate synthetase

The X-ray crystal structure of carbamoyl phosphate synthetase (CPS) from Escherichia coli has unveiled the existence of two molecular tunnels within the heterodimeric enzyme. These two interdomain tunnels connect the three distinct active sites within this remarkably complex protein and apparently function as conduits for the transport of unstable reaction intermediates between successive active sites. The operational significance of the ammonia tunnel for the migration of NH3 is supported experimentally by isotope competition and protein modification. The passage of carbamate through the carbamate tunnel has now been assessed by the insertion of site-directed structural blockages within this tunnel. Gln-22, Ala-23, and Gly-575 from the large subunit of CPS were substituted by mutagenesis with bulkier amino acids in an attempt to obstruct and/or hinder the passage of the unstable intermediate through the carbamate tunnel. The structurally modified proteins G575L, A23L/G575S, and A23L/G575L exhibited a substantially reduced rate of carbamoyl phosphate synthesis, but the rate of ATP turnover and glutamine hydrolysis was not significantly altered. These data are consistent with a model for the catalytic mechanism of CPS that requires the diffusion of carbamate through the interior of the enzyme from the site of synthesis within the N-terminal domain of the large subunit to the site of phosphorylation within the C-terminal domain. The partial reactions of CPS have not been significantly impaired by these mutations, and thus, the catalytic machinery at the individual active sites has not been functionally perturbed.     

Synchronization of the three reaction centers within carbamoyl phosphate synthetase

Carbamoyl phosphate synthetase from E. coli catalyzes the synthesis of carbamoyl phosphate through a series of four reactions occurring at three active sites connected by a molecular tunnel of 100 A. To understand the mechanism for coordination and synchronization among the active sites, the pre-steady-state time courses for the formation of phosphate, ADP, glutamate, and carbamoyl phosphate were determined. When bicarbonate and ATP were rapidly mixed with CPS, a stoichiometric burst of acid-labile phosphate and ADP was observed with a formation rate constant of 1100 min(-)(1). The burst phase was followed by a linear steady-state phase with a rate constant of 12 min(-)(1). When glutamine or ammonia was added to the initial reaction mixture, the magnitude and the rate of formation of the burst phase for either phosphate or ADP were unchanged, but the rate constant for the linear steady-state phase increased to an average value of 78 min(-)(1). These results demonstrate that the initial phosphorylation of bicarbonate is independent of the binding or hydrolysis of glutamine. The pre-steady-state time course for the hydrolysis of glutamine in the absence of ATP exhibited a burst of glutamate formation with a rate constant of 4 min(-)(1) when the reaction was quenched with base. In the presence of ATP and bicarbonate, the rate constant for the formation of the burst of glutamate was 1100 min(-)(1). The hydrolysis of ATP thus enhanced the hydrolysis of glutamine by a factor of 275, but there was no effect by glutamine on the initial phosphorylation of bicarbonate. The pre-steady-state time course for the formation of carbamoyl phosphate was linear with an overall rate constant of 72 min(-)(1). The absence of an initial burst of carbamoyl phosphate formation eliminates product release as a rate-determining step for CPS. Overall, these results have been interpreted to be consistent with a mechanism whereby the phosphorylation of bicarbonate serves as the initial trigger for the rest of the reaction cascade. The formation of the carboxy phosphate intermediate within the large subunit must induce a conformational change to the active site of the small subunit that enhances the hydrolysis of glutamine. Thus, ammonia is not released into the molecular tunnel until the activated bicarbonate is ready to form carbamate. The rate-limiting step for the steady-state assembly of carbamoyl phosphate is either the formation, migration, or phosphorylation of the carbamate intermediate.