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.     

Immunochemical analysis of the domain structure of CAD, the multifunctional protein that initiates pyrimidine biosynthesis in mammalian cells

CAD, is a multidomain polypeptide, with a molecular weight of over 200,000, that has glutamine-dependent carbamyl-phosphate synthetase, aspartate transcarbamylase, and dihydroorotase activity as well as regulatory sites that bind UTP and 5-phosphoribosyl 1-pyrophosphate. The protein thus catalyzes the first three steps of de novo pyrimidine biosynthesis and controls the activity of the pathway in higher eukaryotes. Controlled proteolysis of CAD isolated from Syrian hamster cells, cleaves the molecule into seven major proteolytic fragments that contain one or more of the functional domains. The two smallest fragments, which had molecular weights of 44,000 and 40,000, corresponded to the fully active dihydroorotase (DHO) and aspartate transcarbamylase (ATC) domains, respectively, but the larger fragments have not been previously characterized. In this study, enzymatic assays of partially fractionated digests and immunoblotting with antibodies specifically directed against the purified ATC domain, the purified dihydroorotase domain and an 80-kDa fragment of the putative carbamyl-phosphate synthetase domain established the precursor-product relationships among all of the major proteolytic fragments of CAD. These results indicate that 1) only the intact molecule had all of the functional domains, 2) a species with a molecular weight of 200,000 was produced in the first step of proteolysis which had glutamine-dependent carbamyl-phosphate synthetase and dihydroorotase activity, but neither aspartate transcarbamylase activity nor the antigenic determinants present on the isolated ATC domain, and 3) cleavage of the 200-kDa species produced a species, with a molecular mass of 150,000 which lacked both aspartate transcarbamylase and dihydroorotase domains. This 150-kDa species, containing the postulated carbamyl-phosphate synthetase, glutamine, and regulatory (UTP, 5-phosphoribosyl 1-pyrophosphate) domains, had two elastase-sensitive sites that divided this region of the polypeptide chain into 10-, 65-, and 80-kDa segments. The location of the functional sites on these segments has not yet been established. The immunochemical analysis also revealed the existence of possible precursors of the stable aspartate transcarbamylase and dihydroorotase domains, suggesting that the chain segments connecting the functional domains of CAD are extensive and that the overall size of the intact polypeptide chain has been underestimated. On the basis of these studies we have proposed a model of the domain structure of CAD.     

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.     

The structural organization of the hamster multifunctional protein CAD. Controlled proteolysis, domains, and linkers.

CAD is a multidomain protein that catalyzes the first three steps in mammalian de novo pyrimidine biosynthesis. The 243-kDa polypeptide consists of four functional domains; glutamine amidotransferase (GLNase), carbamyl phosphate synthetase (CPSase), aspartate transcarbamylase (ATCase), and dihydroorotase (DHOase). Controlled proteolysis of hamster CAD was found to cleave the molecule into 18 fragments which successively accumulate and disappear during the course of digestion. Each fragment was isolated and partially sequenced to determine its location in the polypeptide chain. Proteolysis was found to usually occur at the junctions between the domains and sub-domains identified by sequence homology. All proteases of low to moderate specificity cleaved the molecule in a similar fashion. The rate of proteolysis widely varied and the interdomain regions were not always accessible to proteases. Each of the major functional domains is postulated to consist of subdomains. The duplicated halves of the CPSase domain (116 kDa) have a homologous structure consisting of 11-, 25-26-, and 21-22-kDa subdomains. Prolonged digestion cleaved the DHOase domain (36.6 kDa) into two stable species suggesting that this region is comprised of 11.5- and 15.0-kDa subdomains. Similarly, proteolysis of the 21-kDa catalytic subdomain of the GLNase domain (40 kDa) indicated a bilobal structure consisting of 12.3- and 8.5-kDa chain segments. The connecting region between the two ATCase subdomains (16.4 and 18 kDa) was not cleaved. Copurification of many of the domains showed that they remain associated by noncovalent interactions even after the connecting segments have been cleaved. The chain segments, the linkers, which connect the domains and subdomains were conserved in length but not in sequence, were predicted to be relatively hydrophilic and flexible but did not show a tendency to assume a particular secondary structure. These studies provide a more detailed map of the structural organization of the CAD polypeptide.     

The catalytic mechanism of the amidotransferase domain of the Syrian hamster multifunctional protein CAD. Evidence for a CAD-glutamyl covalent intermediate in the formation of carbamyl phosphate.

The multifunctional protein CAD catalyzes the first three steps in pyrimidine biosynthesis in mammalian cells, including the synthesis of carbamyl phosphate from bicarbonate, MgATP and glutamine. The Syrian hamster CAD glutaminase (GLNase) domain, a trpG-type amidotransferase, catalyzes glutamine hydrolysis in the absence of MgATP and bicarbonate (Km = 95 microM and kcat = 0.14 s-1). Unlike E. coli carbamyl phosphate synthetase (Wellner, V.P., Anderson, P.M., and Meister, A. (1973) Biochemistry 12, 2061-2066), a stable thioester intermediate did not accumulate when the mammalian enzyme was incubated with glutamine. However, a covalent adduct could be isolated when the protein was denatured in acid. The steady state concentration of the intermediate increased with increasing glutamine concentration to nearly one mole per mole of enzyme with half saturation at 105 microM, close to the Km value for glutamine. The adduct formed at the active site of the glutaminase domain. The rate of breakdown of the intermediate (k4), determined directly, was 0.17 s-1 and the rate of formation (k3) was estimated as 0.52 s-1. In the absence of MgATP and bicarbonate, k4 = kcat indicating that the decomposition of the intermediate is the rate-limiting step. The intermediate was chemically and kinetically competent, and the glutamine dissociation constant (330 microM) and rate constants were consistent with steady state kinetics and accurately predicted the steady state concentration of the intermediate. These studies suggest a mechanism similar to the cysteine proteases such as recently proposed by Mei and Zalkin (Mei, B., and Zalkin, H. (1989) J. Biol. Chem. 264, 16613-16619) who identified a catalytic triad in glutamine phosphoribosyl-5'-pyrophosphate amidotransferase, a purF-type enzyme. MgATP and bicarbonate increased kcat of the glutaminase reaction 14-fold by accelerating both the rate of formation and the rate of breakdown of the intermediate, and prevented the accumulation of the intermediate; however, the Km value for glutamine was not significantly altered. The instability of the thioester intermediate leads to appreciable hydrolysis of glutamine in the absence of the other substrates. However, bicarbonate alone spares glutamine by increasing the Km and Ks of glutamine to 600 and 8960 microM, respectively, thus reducing kcat/Km 3-fold when MgATP is limiting. In the absence of MgATP and bicarbonate, ammonia decreased the rate of hydrolysis and the accumulation of the thioester intermediate indicating that ammonia had direct access to the thioester at the GLNase domain active site.(ABSTRACT TRUNCATED AT 400 WORDS)     

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.     

Mammalian carbamyl phosphate synthetase (CPS). DNA sequence and evolution of the CPS domain of the Syrian hamster multifunctional protein CAD

Glutamine-dependent carbamoyl-phosphate synthetase (EC 6.3.5.5) catalyzes the first step in de novo pyrimidine biosynthesis. The mammalian enzyme is part of a 240-kDa multifunctional protein which also has the second (aspartate carbamoyltransferase, EC 2.1.3.2), and third (dihydroorotase, EC 3.5.2.3) activities of the pathway. Shigesada et al. (Shigesada, K., Stark, G.R., Maley, J.A., and Davidson, J.N. (1985) Mol. Cell Biol. 175, 1-7) produced a truncated cDNA clone from a Syrian hamster cell line that contained most of the coding region for this protein. We have completed sequencing this clone, known as pCAD142. The cDNA insert contained all of the coding region for the glutaminase (GLN) and carbamyl phosphate synthetase (CPS) domains but lacked a short amino-terminal segment. By comparing the primary structure of the mammalian chimera to monofunctional proteins we have identified the borders of the functional domains. The GLN domain is 21 kDa, close to the size of the functionally similar polypeptide products of the Escherichia coli pabA and hisH genes. The domain has the three regions of homology common to trpG-type glutamine amidotransferases, as well as a fourth region specific to the carbamyl phosphate synthetases. The CPSase domain is similar to other reported CPSases in size (120 kDa), primary structure (37-67% amino acid identity), and homology between its amino and carboxyl halves. Analysis of the nucleotide and amino acid sequence identities among the various carbamyl phosphate synthetases suggests that the gene fusion which joined the GLN and CPS domains was an early event in the evolution of eukaryotic organisms and that the Saccharomyces cerevisiae enzyme consisting of separate subunits arose by defusion from an ancestral multifunctional protein.     

Structure of a class I gene from Syrian hamster

Syrian hamsters possess a multigene class I family yet fail to perform several associative immunologic functions. In an attempt to determine whether representative hamster genes are structurally functional, we have cloned two closely linked class I-like genes and determined the complete sequence of the 5' member. Its exon organization is similar to that seen in mouse and man, although only two intracytoplasmic domains are encoded instead of the usual three. Comparison of the predicted amino acid sequence and the 3' untranslated region to mouse and human genes suggest along with the linkage data that the hamster gene may be related to either or both K and Qa region genes but probably not to D and L region genes.     

Changes in gene expression accompanying neoplastic transformation of Syrian hamster cells

Proteins solubilized from the chemically transformed, highly tumorigenic Syrian hamster cell line, BP6T, and the untransformed parental embryo cells, have been analyzed by two-dimensional gel electrophoresis. Differences in seven major polypeptides have been identified in cytoplasmic and nuclear cell fractions from these two related cell types. The tumorigenic cells have lost the ability to synthesize detectable amounts of five major polypeptides which are found in untransformed cells; in addition, the tumorigenic cells synthesize two new major polypeptide species not found in the untransformed cells. Butyric acid, an agent which suppresses in vitro cellular properties frequently associated with neoplasia, induces in a reversible fashion synthesis of two of these missing polypeptide species in the tumorigenic cells. The results indicate that a change in the synthesis of less than 1% of the major polypeptide species is associated with a chemical mediated induction of the high tumorigenic state of Syrian hamster cells.     

Co-amplification of rRNA genes with CAD genes in N-(phosphonacetyl)-L-aspartate-resistant Syrian hamster cells.

The amplified CAD genes in N-(phosphonacetyl)-L-aspartate (PALA)-resistant Syrian hamster cells are located in an expanded chromosomal region emanating from the site of the wild-type gene at the tip of the short arm of chromosome B-9. The terminus of B-9 in PALA-sensitive cells contains a cluster of rRNA genes (i.e., a nucleolus organizer, rDNA). We have used a molecular clone containing sequences complementary to Syrian hamster 28S rRNA to investigate whether rDNA is coamplified with CAD genes in the PALA-resistant mutants. In situ hybridization of this probe to metaphase chromosomes demonstrates that rDNA and CAD genes do coamplify in two independently isolated PALA-resistant mutants. The tight linkage of CAD and rDNA genes was demonstrated by their coordinate translocation from B-9 to the end of the long arm of chromosome C-11 in one mutant. Blot hybridization studies substantiate the in situ hybridization results. Both types of analysis indicate that only one or two rDNA genes, on the average, are coamplified per CAD gene. The data are consistent with the model that unequal exchanges between rDNA genes mediate the amplification of CAD genes in the Syrian hamster mutants that were analyzed.     

Distinctive chromosomal structures are formed very early in the amplification of CAD genes in Syrian hamster cells

As visualized by in situ hybridization with fluorescence detection, newly amplified CAD genes in 10(5) cell colonies are contained in multiple copies of very large regions of DNA, each tens of megabases long. The extra DNA is usually linked to the short arm of chromosome B9, which retains CAD at its normal site. The widely spaced genes are often interspersed with new G-negative regions. Individual cells within a clone have highly variable numbers of CAD genes (range 2-15). When resistant clones are examined later, at the 10(15) cell stage, the amplified genes are usually found in much more condensed structures. We propose that, in the initial event of CAD gene amplification, much of the short arm is transferred from one B9 chromosome to another. In subsequent cell cycles this initial duplication expands rapidly through unequal but homologous sister chromatid exchanges. Relatively rare secondary events lead to more condensed structures.     

Characterization of an unscheduled DNA synthesis assay with Syrian hamster embryo cells

The Syrian hamster embryo cell transformation assay is widely used for studies of carcinogenesis. The characterization of an unscheduled DNA synthesis (UDS) assay for these cells is reported. Benzo[a]pyrene, aflatoxin B1 and UV light induced UDS in the cells in a dose-dependent manner without exogenous metabolic activity. Nitrosopiperidine induced UDS as well as gene mutations and cell transformation only in the presence of an exogenous metabolic activation system. The utility of this UDS assay with these cells is discussed.     

Localization of the multifunctional protein CAD in astrocytes of rodent brain.

The CAD multidomain protein, which includes active sites of carbamyl phosphate synthetase II (CPS II, glutamine-dependent), aspartate transcarbamylase, and dihydroorotase, was immunostained in normal rat brains, the gliotic brains of myelin-deficient mutant rats, and brains from normal weanling hamsters. In each of these tissues CAD was observed in cells resembling astrocytes. In hamster brain, CAD immunofluorescence was also found in cells closely related to astrocytes, i.e., the Bergmann glia in cerebellum and the tanycytes surrounding the third ventricle. The astrocytic identity of the CAD-positive cells in rat brain was confirmed by double immunofluorescence staining with antibodies against glial fibrillary acidic protein (GFAP). The two enzymes carbonic anhydrase and glutamine synthetase occur in the cytoplasm of normal astrocytes in gray matter and of reactive astrocytes during gliosis. Products of each enzyme, i.e., bicarbonate and glutamine, are required for the CPS II reaction, which is the first step in the biosynthesis of pyrimidines. Therefore, the present results suggest roles for carbonic anhydrase and glutamine synthetase, as well as CAD, in pyrimidine biosynthesis in brain and a role for the astrocytes in the de novo synthesis of pyrimidines.     

Gene amplification causes overproduction of the first three enzymes of UMP synthesis in N-(phosphonacetyl)-L-aspartate-resistant hamster cells.

Mutant Syrian hamster cells resistant to N-(phosphonacetyl)-L-aspartate (PALA), a transition state analog inhibitor of aspartate transcarbamylase, overproduce CAD, a multifunctional protein which catalyzes the first three reactions of de novo UMP biosynthesis. Increased levels of a single mRNA cause the overproduction of CAD in all PALA-resistant mutants examined thus far. A recombinant plasmid containing a 2,3-kilobase insert complementary to the 3'-proximal region of this 7.9-kilobase mRNA has been prepared and used to show that the CAD gene is amplified in each of the 10 PALA-resistant mutants examined. Rates of association of CAD sequences in DNA isolated from PALA-sensitive and PALA-resistant cells with labeled plasmid DNA indicated that the degree of amplification is approximately equal to the degree of overproduction of protein and mRNA in each mutant. The patterns of digestion of these DNAs with restriction enzymes confirmed this result and showed that the lower limit for the size of the amplified unit is 19 kilobases, much larger than the mRNA. A comparison of restriction endonuclease digests of the cloned cDNA with digests of genomic DNA indicated that part of this difference is attributable to intervening sequences in the CAD gene. A 10.2-kilobase RNA which contains CAD sequences is found in cytoplasmic fractions from some PALA-resistant mutants but not in wild type cells. Restriction patterns were analyzed by a new method in which fragments of DNA are transferred from agarose gels to diazo paper with a high efficiency which is independent of size.     

Amitrole-induced cell transformation and gene mutations in Syrian hamster embryo cells in culture

Amitrole, a widely used herbicide, is an animal carcinogen and an inducer of cell transformation. However, it is inactive as a mutagen in bacterial test systems. Thus, it has been suggested that amitrole is a non-mutagenic carcinogen. Over the dose range that induces morphological transformation of Syrian hamster embryo cells in culture, amitrole induced gene mutations at the Na+/K+ ATPase and hypoxanthine phosphoribosyl transferase loci measured concomitantly in the same cells. These results indicate that amitrole may act via a mutational mechanism.     

Genetic studies of the Syrian hamster. VIII. The sex-linked gene Tortoiseshell

The occurrence of sex-linked yellow is described and designated as tortoiseshell (symbol To). The phenotype produced by the heterozygous female (To+) is a mosaic of that of ToTo and ++. Genetic inactivation of one X chromosome per cell is thus indicated. The To gene interacts phenotypically with genes Ba, Ds and Wh.     

Control of macromolecular synthesis in proliferating and resting Syrian hamster cells in monolayer culture. I. Ribosome function

The rate of protein synthesis per cell in cultured hamster embryo fibroblasts in the stationary growth phase falls to about one third of the rate in the exponential growth phase. This reduction can be entirely accounted for by the following observations: (1) the average cell in stationary phase contains about one-half the number of ribosomes per cell compared to the average cell in exponential phase; (2) only two thirds of the ribosomes are bound to polysomes in stationary phase, while nearly all of the ribosomes are polysome-bound in exponential phase. In stationary phase, ribosomes which are polysome-bound function with the same efficiency and produce proteins of approximately the same average length as in exponential phase. Experimental findings are presented which suggest that the generation of a higher proportion of free ribosomes in stationary phase in not due to a limitation in messenger RNA, but to a decreased attachment probability of ribosomes to messenger RNA.