Autophosphorylation of the mammalian multifunctional protein that initiates de novo pyrimidine biosynthesis

CAD, a large multifunctional protein that carries carbamoyl phosphate synthetase (CPSase), aspartate transcarbamoylase, and dihydroorotase activities, catalyzes the first three steps of de novo pyrimidine biosynthesis in mammalian cells. The CPSase component, which catalyzes the initial, rate-limiting step, exhibits complex regulatory mechanisms involving allosteric effectors and phosphorylation that control the flux of metabolites through the pathway. Incubation of CAD with ATP in the absence of exogenous kinases resulted in the incorporation of 1 mol of P(i)/mol of CAD monomer. Mass spectrometry analysis of tryptic digests showed that Thr(1037) located within the CAD CPS.B subdomain was specifically modified. The reaction is specific for MgATP, ADP was a competitive inhibitor, and the native tertiary structure of the protein was required. Phosphorylation occurred after denaturation, further purification of CAD by SDS gel electrophoresis, and renaturation on a nitrocellulose membrane, strongly suggesting that phosphate incorporation resulted from an intrinsic kinase activity and was not the result of contaminating kinases. Chemical modification with the ATP analog, 5'-p-fluorosulfonylbenzoyladenosine, showed that one or both of the active sites that catalyze the ATP-dependent partial reactions are also involved in autophosphorylation. The rate of phosphorylation was dependent on the concentration of CAD, indicating that the reaction was, at least in part, intermolecular. Autophosphorylation resulted in a 2-fold increase in CPSase activity, an increased sensitivity to the feedback inhibitor UTP, and decreased allosteric activation by 5-phosphoribosyl-1-pyrophosphate, functional changes that were distinctly different from those resulting from phosphorylation by either the protein kinase A or mitogen-activated protein kinase cascades.     

Structure of the gene for CAD, the multifunctional protein that initiates UMP synthesis in Syrian hamster cells.

Two adjacent fragments of genomic DNA spanning the gene for CAD, which encodes the first three enzymes of UMP biosynthesis, were cloned from a mutant Syrian hamster cell line containing multiple copies of this gene. The mutant was selected for resistance to N-(phosphonacetyl)-L-aspartate, a potent and specific inhibitor of aspartate transcarbamylase, the second enzyme in the pathway. The sizes and positions of about 37 intervening sequences within the 25-kilobase CAD gene were mapped by electron microscopy, and the locations of the 5' and 3' ends of the 7.9-kilobase CAD mRNA were established by electron microscopy and by other hybridization methods. The coding sequences are small (100 to 400 bases), as are most of the intervening sequences (50 to 300 bases). However, there are also several large intervening sequences of up to 5,000 bases each. Two small cytoplasmic polyadenylated RNAs are transcribed from a region just beyond the 5' end of the CAD gene, and their abundance reflects the degree of gene amplification.     

Purification from hamster cells of the multifunctional protein that initiates de novo synthesis of pyrimidine nucleotides.

Carbamyl-P synthetase (EC 2.7.2.9), aspartate transcarbamylase (EC 2.1.3.2), and dihydro-orotase (EC 3.5.2.3), the first three enzymes of the de novo pathway for synthesis of pyrimidine nucleotides, have been co-purified as a single oligomeric protein from a mutant line of hamster cells selected for its ability to resist N-(phosphonacetyl)-L-aspartate (PALA), a potent and specific inhibitor of aspartate transcarbamylase. All three enzymes overaccum,late in the mutant cells (Kempe, T.D., Swyryd, E.A., Bruist, M., and Stark, G.R. (1976) Cell 9, 541-550) and the oligomer represents nearly 10% of the total cellular protein. Tens of milligrams of oligomer have been purified to homogeneity by a simple and rapid procedure, with recovery of about 50% of all three activities. The pure protein contains only one size of polypeptide, Mr approximately 200,000, as revealed by electrophoresis in danaturing gels. All three enzyme activities are associated with this polypeptide, indicating that it is multifunctional. Further evidence for a multifunctional protein is provided by titration of the oligomer with radioactive PALA, which reveals that the number of PALA binding sites approximately equals the number of polypeptide chains. The isolated multifunctional protein is a mixture of trimers and hexamers.     

Organization of a multifunctional protein in pyrimidine biosynthesis. A domain hypersensitive to proteolysis.

When the multifunctional protein that catalyses the first three steps of pyrimidine biosynthesis in hamster cells is treated with staphylococcal V8 proteinase, a single cleavage takes place. The activities of carbamoyl-phosphate synthetase (EC 6.3.5.5), aspartate carbamoyltransferase (EC 2.1.3.2) and dihydro-orotase (EC 3.5.2.3) and the allosteric inhibition by UTP are unaffected. One fragment, of Mr 182000, has the first and third enzyme activities, whereas the other fragment, of Mr 42000, has aspartate carbamoyltransferase activity and an aggregation site. A similar small fragment is observed in protein digested with low concentrations of trypsin. A similar large fragment is seen after digestion with trypsin and as the predominating form of this protein in certain mutants defective in pyrimidine biosynthesis. These results indicate that a region located adjacent to the aspartate carbamoyltransferase domain is hypersensitive to proteinase action in vitro and may also be sensitive to proteolysis in vivo.     

The dihydroorotase domain of the multifunctional protein CAD. Subunit structure, zinc content, and kinetics

Dihydroorotase (DHOase) catalyzes the third step in eukaryotic de novo pyrimidine biosynthesis. In mammalian cells, this enzyme activity is carried by a large chimeric protein, CAD, that also catalyzes the first two steps in the pathway: glutamine-dependent carbamyl phosphate synthetase (CPSase) and aspartate transcarbamylase (ATCase). Controlled elastase cleavage of CAD released a 44,000 +/- 2,000-dalton proteolytic fragment which catalyzed only the dihydroorotase reaction. We have devised a rapid and simple method for the isolation of the DHO domain from elastase digests. The domain, which was obtained in 36% yield, was found to be homogeneous by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and isoelectric focusing. The domain was also characterized by amino acid analysis and analytical high pressure liquid chromatography peptide mapping. The amino terminus of both the DHO domain and intact CAD was blocked suggesting that this domain is located at the extreme amino terminus of the CAD polypeptide, a result consistent with the suspected juxtaposition of domains as DHO-CPS-ATC. The isoelectric point of the DHO domain was 5.1, while that of the ATC domain was 9.4, so that the ends of the CAD polypeptide are oppositely charged at physiological pH. Immunoblotting with DHO domain-specific antibodies showed that a 47-kDa species was generated in the early stages of controlled proteolysis of CAD. Thus there are two elastase cleavage sites within a 3-kDa connecting region that links the DHO and CPS domains. The domain was shown by atomic absorption spectrophotometry and by isolating a 65Zn-containing DHO domain from mammalian cells grown in the presence of the radionuclide to contain 1 g eq of tightly bound zinc in each polypeptide chain. Zinc was not found in any other CAD domain. Chelating agents inhibit dihydroorotase activity of the isolated domain supporting the conclusion, based on studies of intact CAD by others, that zinc participates in catalysis. At moderate protein concentrations the DHO domain was a 88,000 dimer with a Stokes radius of 37.6 A, a S20,w = 5.1 X 10(-13) s, a diffusion coefficient of 3.17 X 10(-7) cm2 s-1, and a frictional ratio of 1.26. On dilution the dimer dissociated and was in rapid concentration-dependent equilibrium with a 43,500 monomer. The hydrodynamic parameters of the monomer have also been estimated (Stokes radius of 29.8 A, D20,w = 4.11 X 10(-7) cm2 s-1, and f/f0 1.21).(ABSTRACT TRUNCATED AT 400 WORDS)     

Organization of a multifunctional protein in pyrimidine biosynthesis. Analyses of active, tryptic fragments

The multifunctional protein which catalyzes the first three steps of pyrimidine biosynthesis in hamster cells can be cleaved by trypsin into enzymatically active fragments. When the fragments are separated by nondenaturing polyacrylamide gel electrophoresis, three major polypeptide bands appear. Carbamyl phosphate synthetase (EC 2.7.2.9), aspartate transcarbamylase (EC 2.1.3.2), and dihydroorotase (EC 3.5.2.3) activities are associated with 129,000-, 660,000-, and 94,000-dalton bands, respectively. Further analysis of these fragments by denaturing polyacrylamide gel electrophoresis has shown that the aspartate transcarbamylase band seen on the nondenaturing gel is actually a large aggregate of 39,000-dalton fragments and the dihydroorotase band is a dimer of 44,000-dalton fragments. The data reported here indicate that (i) this multifunctional protein is composed of three enzymatically independent domains, (ii) the sum of the molecular weights of these three domains (129,000 + 39,000 + 44,000 = 212,000) is similar to that of the undigested monomer (220,000 daltons), and (iii) a site important to the formation of the native multimeric protein is probably near the aspartate transcarbamylase domain.     

Identification, function and structure of the mycobacterial sulfotransferase that initiates sulfolipid-1 biosynthesis

Sulfolipid-1 (SL-1) is an abundant sulfated glycolipid and potential virulence factor found in Mycobacterium tuberculosis. SL-1 consists of a trehalose-2-sulfate (T2S) disaccharide elaborated with four lipids. We identified and characterized a conserved mycobacterial sulfotransferase, Stf0, which generates the T2S moiety of SL-1. Biochemical studies demonstrated that the enzyme requires unmodified trehalose as substrate and is sensitive to small structural perturbations of the disaccharide. Disruption of stf0 in Mycobacterium smegmatis and M. tuberculosis resulted in the loss of T2S and SL-1 formation, respectively. The structure of Stf0 at a resolution of 2.6 A reveals the molecular basis of trehalose recognition and a unique dimer configuration that encloses the substrate into a bipartite active site. These data provide strong evidence that Stf0 carries out the first committed step in the biosynthesis of SL-1 and establish a system for probing the role of SL-1 in M. tuberculosis infection.     

Intracellular location of the multidomain protein CAD in mammalian cells

The first three steps of mammalian de novo pyrimidine biosynthesis are catalyzed by the multifunctional protein CAD, consisting of glutamine-dependent carbamylphosphate synthetase, aspartate transcarbamylase, and dihydroorotase. The intracellular distribution of CAD in two hamster cell lines, BHK 21 and BHK 165-23 (a strain in which the CAD gene was selectively amplified), was determined by differential centrifugation and by two different cytochemical immunolocalization methods. Ammonia-dependent carbamylphosphate synthetase I was found in both cell types at a concentration of 0.01% of the total cell protein, so its distribution was also determined as a control for possible cross-reactivity of the CAD antibody probes and as a mitochondrial marker. CAD was localized in the cytoplasmic compartment and almost completely excluded from the nucleus. A punctate staining pattern suggested that it was not uniformly dispersed throughout the cytosol (unlike typical soluble proteins) but was associated with subcellular organelles. Although there was a slight tendency for CAD to be localized in the vicinity of the nuclear envelope, the amount of staining was much less than expected from differential centrifugation, which showed that 30% of the protein was found in the nuclear fraction. No interactions with other subcellular components could be detected by centrifugation. It is possible, however, that CAD is associated with subcellular structures that cosediment with the nuclei. Despite a 150-fold increase in CAD concentration in the over-producing cells, the distribution of the protein was unaltered. CAD was not concentrated near the mitochondria where the next enzyme of the de novo pathway, dihydroorotate dehydrogenase, is localized, which indicates that the intermediate dihydroorotate is not channeled, but rather dissociates from CAD and diffuses through the bulk cellular fluid.     

Association of CAD,a multifunctional protein involved in pyrimidine synthesis,with mLST8, a component of the mTOR complexes

Background

mTOR is a genetically conserved serine/threonine protein kinase, which controls cell growth, proliferation, and survival. A multifunctional protein CAD, catalyzing the initial three steps in de novo pyrimidine synthesis, is regulated by the phosphorylation reaction with different protein kinases, but the relationship with mTOR protein kinase has not been known.

Results

CAD was recovered as a binding protein with mLST8, a component of the mTOR complexes, from HEK293 cells transfected with the FLAG-mLST8 vector. Association of these two proteins was confirmed by the co-immuoprecipitaiton followed by immunoblot analysis of transfected myc-CAD and FLAG-mLST8 as well as that of the endogenous proteins in the cells. Analysis using mutant constructs suggested that CAD has more than one region for the binding with mLST8, and that mLST8 recognizes CAD and mTOR in distinct ways. The CAD enzymatic activity decreased in the cells depleted of amino acids and serum, in which the mTOR activity is suppressed.

Conclusion

The results obtained indicate that mLST8 bridges between CAD and mTOR, and plays a role in the signaling mechanism where CAD is regulated in the mTOR pathway through the association with mLST8.     

Synthesis of the nonconserved dihydroorotase domain of the multifunctional hamster CAD protein in Escherichia coli.

CAD is the multifunctional protein of higher eukaryotes which catalyzes the first three steps of pyrimidine biosynthesis. Its enzymatic activities exist as independent domains in the order: N terminus-carbamylphosphate synthetase II(CPSase)-dihydroorotase(DHOase)-aspartate transcarbamylase(ATCase)-C terminus. To functionally define the minimum hamster cDNA region required to encode an active DHOase, expression constructs were generated. Many such constructs complement Escherichia coli mutants defective not only in DHOase but also in ATCase. Constructs deleted for most of the sequence encoding the ATCase domain continue to complement E. coli mutants defective in DHOase. All of these smaller constructs also lack the region encoding CPSase. Therefore, a 'genetic cassette', containing information for neither the CPSase nor the ATCase domain, can direct the synthesis of a polypeptide with DHOase activity. Interestingly, inclusion of a portion of the DHOase-ATCase interdomain bridge appears to be required for optimum activity.     

Growth-dependent regulation of mammalian pyrimidine biosynthesis by the protein kinase A and MAPK signaling cascades

The carbamoyl phosphate synthetase domain of the multifunctional protein CAD catalyzes the initial, rate-limiting step in mammalian de novo pyrimidine biosynthesis. In addition to allosteric regulation by the inhibitor UTP and the activator PRPP, the carbamoyl phosphate synthetase activity is controlled by mitogen-activated protein kinase (MAPK)- and protein kinase A (PKA)-mediated phosphorylation. MAPK phosphorylation, both in vivo and in vitro, increases sensitivity to PRPP and decreases sensitivity to the inhibitor UTP, whereas PKA phosphorylation reduces the response to both allosteric effectors. To elucidate the factors responsible for growth state-dependent regulation of pyrimidine biosynthesis, the activity of the de novo pyrimidine pathway, the MAPK and PKA activities, the phosphorylation state, and the allosteric regulation of CAD were measured as a function of growth state. As cells entered the exponential growth phase, there was an 8-fold increase in pyrimidine biosynthesis that was accompanied by a 40-fold increase in MAPK activity and a 4-fold increase in CAD threonine phosphorylation. PRPP activation increased to 21-fold, and UTP became a modest activator. These changes were reversed when the cultures approach confluence and growth ceases. Moreover, CAD phosphoserine, a measure of PKA phosphorylation, increased 2-fold in confluent cells. These results are consistent with the activation of CAD by MAPK during periods of rapid growth and its down-regulation in confluent cells associated with decreased MAPK phosphorylation and a concomitant increase in PKA phosphorylation. A scheme is proposed that could account for growth-dependent regulation of pyrimidine biosynthesis based on the sequential action of MAPK and PKA on the carbamoyl phosphate synthetase activity of CAD.     

Biochemical genetic analysis of pyrimidine biosynthesis in mammalian cells: I. Isolation of a mutant defective in the early steps of de novo pyrimidine synthesis.

The isolation and characterization of a new mutant of Chinese hamster ovary cells is described. This mutant, Urd-A, shows an absolute requirement for exogenously added pyrimidines for growth. Complementation analysis indicates that the lesion in this mutant is recessive. Revertants can be isolated at frequencies suggesting that it is a single gene alteration. Biochemical analysis of cell-free extracts of CHO-K1 (Urd+) and Urd-A revealed that Urd-A possesses no more than 10% of wild-type levels of carbamyl phosphate synthetase (EC 2.7.2.9) activity, no more than 1% of wild-type levels of aspartate transcarbamylase (EC 1.2.3.2) activity, and undetectable levels of dihydroorotase (EC 3.5.2.3) activity. Thus, this mutant appears simultaneously to possess marked or complete deficiencies in the activities of the first three enzymes of pyrimidine biosynthesis. Activities of the other enzymes of the pathway appear normal. The use of this mutant for biochemical-genetic studies of pyrimidine biosynthesis is discussed.     

Mapping of the gene encoding the multifunctional protein carrying out the first three steps of pyrimidine biosynthesis to human chromosome 2

Summary The CAD gene encodes a trifunctional protein that carries the activities of the first three enzymes (carbamyl phosphate synthetase II, aspartate transcarbamylase, and dihydroorotase) of de novo pyrimidine biosynthesis. Genomic fragments of the human CAD gene have been obtained by screening a human genomic library in bacteriophage lambda using a Syrian hamster cDNA clone as a probe. These human genomic clones have been used to assign the CAD gene to human chromosome 2 using in situ hybridization to human metaphase chromosomes and Southern blot hybridization analysis of DNA isolated from a panel of Chinese hamster/human hybrid cells. In situ hybridization analysis has allowed further localization of this gene to the chromosomal region 2p21-p22.     

Nuclear localization and mitogen-activated protein kinase phosphorylation of the multifunctional protein CAD

CAD is a multifunctional protein that initiates and regulates mammalian de novo pyrimidine biosynthesis. The activation of the pathway required for cell proliferation is a consequence of the phosphorylation of CAD Thr-456 by mitogen-activated protein (MAP) kinase. Although most of the CAD in the cell was cytosolic, cell fractionation and fluorescence microscopy showed that Thr(P)-456 CAD was primarily localized within the nucleus in association with insoluble nuclear substructures, including the nuclear matrix. CAD in resting cells was cytosolic and unphosphorylated. Upon epidermal growth factor stimulation, CAD moved to the nucleus, and Thr-456 was found to be phosphorylated. Mutation of the CAD Thr-456 and inhibitor studies showed that nuclear import is not mediated by MAP kinase phosphorylation. Two fluorescent CAD constructs, NLS-CAD and NES-CAD, were prepared that incorporated strong nuclear import and export signals, respectively. NLS-CAD was exclusively nuclear and extensively phosphorylated. In contrast, NES-CAD was confined to the cytoplasm, and Thr-456 remained unphosphorylated. Although alternative explanations can be envisioned, it is likely that phosphorylation occurs within the nucleus where much of the activated MAP kinase is localized. Trapping CAD in the nucleus had a minimal effect on pyrimidine metabolism. In contrast, when CAD was excluded from the nucleus, the rate of pyrimidine biosynthesis, the nucleotide pools, and the growth rate were reduced by 21, 36, and 60%, respectively. Thus, the nuclear import of CAD appears to promote optimal cell growth. UMP synthase, the bifunctional protein that catalyzes the last two steps in the pathway, was also found in both the cytoplasm and nucleus.     

Advances in our understanding of peroxiredoxin,a multifunctional,mammalian redox protein

Abstract

Organisms living under aerobic conditions have developed various anti-oxidative mechanisms to protect them from damage by reactive oxygen species (ROS). A novel family of anti-oxidative proteins, designated as peroxiredoxin (Prx), has been identified in the past two decades and currently comprises six members in mammals. They share a common reactive Cys residue in the N-terminal region, and are capable of serving as a peroxidase and involve thioredoxin and/or glutathione as the electron donor. Prx1 to Prx4 have an additional Cys residue in the conserved C-terminal region, and are cross members as judged by the amino acid sequence similarity. Prx5 also contains an additional Cys in its C-terminal region which is less conserved. On the other hand, Prx6 has only one unique Cys. These Prx family members are distributed in the cytosol, mitochondria, peroxisome and plasma, all of which are potential sites of ROS production. In addition to their role as a peroxidase, however, a body of evidence has accumulated to suggest that individual members also serve divergent functions which are associated with various biological processes such as the detoxification of oxidants, cell proliferation, differentiation and gene expression. It would be expected that these functions might not necessarily depend on peroxidase activity and, therefore, it seems likely that the divergence is due to unique molecular characteristics intrinsic to each member. A comparative study of the divergence would lead to a better understanding of the biological significance of the Prx family.     

Advances in our understanding of peroxiredoxin,a multifunctional,mammalian redox protein

Organisms living under aerobic conditions have developed various anti-oxidative mechanisms to protect them from damage by reactive oxygen species (ROS). A novel family of anti-oxidative proteins, designated as peroxiredoxin (Prx), has been identified in the past two decades and currently comprises six members in mammals. They share a common reactive Cys residue in the N-terminal region, and are capable of serving as a peroxidase and involve thioredoxin and/or glutathione as the electron donor. Prx1 to Prx4 have an additional Cys residue in the conserved C-terminal region, and are cross members as judged by the amino acid sequence similarity. Prx5 also contains an additional Cys in its C-terminal region which is less conserved. On the other hand, Prx6 has only one unique Cys. These Prx family members are distributed in the cytosol, mitochondria, peroxisome and plasma, all of which are potential sites of ROS production. In addition to their role as a peroxidase, however, a body of evidence has accumulated to suggest that individual members also serve divergent functions which are associated with various biological processes such as the detoxification of oxidants, cell proliferation, differentiation and gene expression. It would be expected that these functions might not necessarily depend on peroxidase activity and, therefore, it seems likely that the divergence is due to unique molecular characteristics intrinsic to each member. A comparative study of the divergence would lead to a better understanding of the biological significance of the Prx family.