Properties of asparagine synthetase in asparagine-independent variants of Jensen rat sarcoma cells induced by 5-azacytidine.

Jensen rat sarcoma cells in culture require L-asparagine for growth and lack detectable levels of asparagine synthetase. Cultures exposed for 24 h to graded concentrations of 5-azacytidine give rise to asparagine-independent variants in high frequency. These prototrophs are stable phenotypically whether maintained in the presence or absence of L-asparagine. Asparagine synthetase activity in several variant clones was uniform in thermolability and several kinetic parameters, as well as in immunological properties. Parental Jensen rat sarcoma cells contained no detectable immunologically cross-reacting material. Our data suggest that transitions between asparagine dependence and independence in these cells are mediated by stable shifts in gene expression rather than by structural gene mutations.     

Ultraviolet-induced mutations to asparagine independence in Jensen sarcoma cells in vitro

UV-irradiation induces an exponential increase in the frequency of mutation from asparagine requirement to asparagine non-requirement in Jensen sarcoma cells grown in vitro. The corrected mutation frequency increases from the spontaneous rate of 5.1·10^?6 per cell to 1248·10^?6 per cell with a dose of 180 erg/mm² of 254 nm UV A substantial increase was oberved even without correction for survivors, and no significant difference was observed in the UV sensitivity of asparagine-requiring and non-requiring Jensen clones. When Jensen cells were plated at low densities in a feeder layer of LMTK-cells inactivated by HAT medium, an increase in the cloning ability of the former was observed as compared to appropriate controls without the feeder layer, but the increase was constant over all doses of UV tested. Revertants are stable and possess measurable asparagine synthetase.It is concluded that UV is an extremely effective mutagen in this system.     

Isolation of human cDNAs for asparagine synthetase and expression in Jensen rat sarcoma cells.

Asparagine synthetase cDNAs containing the complete coding region were isolated from a human fibroblast cDNA library. DNA sequence analysis of the clones showed that the message contained one open reading frame encoding a protein of 64,400 Mr, 184 nucleotides of 5' untranslated region, and 120 nucleotides of 3' noncoding sequence. Plasmids containing the asparagine synthetase cDNAs were used in DNA-mediated transfer of genes into asparagine-requiring Jensen rat sarcoma cells. The cDNAs containing the entire protein-coding sequence expressed asparagine synthetase activity and were capable of conferring asparagine prototrophy on the Jensen rat sarcoma cells. However, cDNAs which lacked sequence for as few as 20 amino acids at the amino terminal could not rescue the cells from auxotrophy. The transferant cell lines contained multiple copies of the human asparagine synthetase cDNAs and produced human asparagine synthetase mRNA and asparagine synthetase protein. Several transferants with numerous copies of the cDNAs exhibited only basal levels of enzyme activity. Treatment of these transferant cell lines with 5-azacytidine greatly increased the expression of asparagine synthetase mRNA, protein, and activity.     

Interspecific somatic cell hybridization between asparagine-requiring and drug-resistant cell lines

Interspecific hybrids between Walker 256 carcinosarcoma rat cells which are asparagine requiring, and LMTK^t mouse cells which are drug resistant and asparagine independent have been isolated. The hybrids were selectively isolated by taking advantage of the asparagine requirement, or, in some cases, combining the asparagine requirement with an azaguanine resistance marker. The hybrids: (a) possessed a chromosome complement which was additive between the two parent lines; (b) showed two marker chromosomes; (c) possessed both rat and mouse forms of a number of different isozymes. The specific activities of asparagine synthetase was measured in the two parents and the hybrids. The enzyme level in the hybrids was found to be higher than the levels observed in the W 256 line, but only 10% of that observed in the LMTK⁻. The results are in agreement with, but do not prove, the hypothesis that asparagine requirement is due to a mutation in a structural cistron specifying the asparagine synthetase polypeptide.     

Elevated levels of asparagine synthetase activity in physiologically and genetically derepressed Chinese hamster ovary cells are due to increased rates of enzyme synthesis

The activity of asparagine synthetase in Chinese hamster ovary (CHO) cells is increased in response to asparagine deprivation or decreased aminoacylation of several tRNAs (Andrulis, I. L., Hatfield, G. W., and Arfin, S. M. (1979) J. Biol. Chem. 254, 10629-10633). CHO cells resistant to beta-aspartylhydroxamate have up to 5-fold higher levels of asparagine synthetase than the parental line (Gantt, J. S., Chiang, C. S., Hatfield, G. W., and Arfin, S. M. (1980) J. Biol. Chem. 255, 4808-4813). We have investigated the basis for these differences in enzyme activity by combined radiochemical and immunological techniques. The asparagine synthetase of beef pancreas was purified to apparent homogeneity. Antibodies raised against the purified protein cross-react with the asparagine synthetase of CHO cells. Immunotitrations show that the amount of enzyme protein in physiologically or genetically derepressed CHO strains is proportional to the level of enzyme activity. Measurement of the relative rates of asparagine synthetase synthesis by pulse-labeling experiments demonstrate that the difference in the number of asparagine synthetase molecules is closely correlated with the rate of enzyme synthesis. In contrast, the half-life of asparagine synthetase in wild type cells and in physiologically or genetically derepressed cells is very similar. It appears that the increased levels of asparagine synthetase can be attributed solely to an increased rate of enzyme synthesis.     

Chinese hamster ovary cells resistant to beta-aspartylhydroxamate contain increased levels of asparagine synthetase

The growth of Chinese hamster ovary cells in a complete medium lacking asparagine is inhibited by beta-aspartylhydroxamate. The inhibition is overcome by the presence of asparagine in the growth medium. beta-Aspartylhydroxamate inhibits the activity of both asparagine synthetase and asparaginyl-tRNA synthetase in vitro. beta-Aspartylhydroxamate-resistant clones of Chinese hamster ovary cells have been isolated and three of these have been characterized. One clone, AH12, is 3-fold more resistant to beta-aspartylhydroxamate than the parental line and has 2 times higher levels of asparagine synthetase activity. Strains AH2 and AH5 are 6- to 7-fold more resistant to beta-aspartylhydroxamate and have 5 times higher levels of asparagine synthetase. The regulation of the expression of asparagine synthetase is altered in all three resistant cell lines. Whereas asparagine synthetase activity varies 2- to 3-fold in response to the asparagine content of the medium or to the extent of aminoacylation of tRNALeu in the parental cells, the activity of asparagine synthetase in the resistant cells is elevated under all growth conditions. No significant changes in the Km for substrates, Ki for beta-aspartylhydroxamate, or thermal stability were found for the asparagine synthetase of the resistant cells. These variants should prove useful in understanding the mechanisms involved in regulating the levels of asparagine synthetase in mammalian cells.     

DNA methylation patterns associated with asparagine synthetase expression in asparagine-overproducing and -auxotrophic cells.

In Chinese hamster ovary cells, the gene for asparagine synthetase, which spans 20 kilobase pairs, was found to contain a cluster of potential sites for CpG methylation in a 1-kilobase-pair region surrounding the first exon. Fourteen of the sites that could be assayed for methylation by MspI-HpaII digestions were found in this region, with an additional nine MspI sites spread throughout the remainder of the gene. The methylation status of the gene was analyzed in a series of cell lines that differed in the amount of asparagine synthetase activity. The level of expression showed a direct correlation with the extent of methylation of a subset of the MspI sites found in the 5' region of the gene. The rest of the gene was completely methylated in most cell lines. Wild-type cells, which expressed a basal level of asparagine synthetase activity, were partially demethylated in the 5' region. In contrast, asparagine-requiring N3 cells, which lacked detectable mRNA for asparagine synthetase, were methylated throughout the entire gene. Spontaneous revertants of strain N3, selected for growth in asparagine-free medium, exhibited extensive hypomethylation of the asparagine synthetase gene. The methylation pattern of the gene in cell lines that overproduced the enzyme was also examined. Albizziin-resistant cell lines, which had amplified copies of the gene, were extensively demethylated in the 5' region. Overexpression of asparagine synthetase in beta-aspartyl hydroxamate-resistant lines without amplified copies of the gene was also correlated with DNA hypomethylation.     

Characterization of single step albizziin-resistant Chinese hamster ovary cell lines with elevated levels of asparagine synthetase activity

The amino acid analog, albizziin, which acts as a competitive inhibitor of asparagine synthetase with respect to glutamine was used to isolate mutants of Chinese hamster ovary cells with alterations in levels of the target enzyme. These mutant lines have been characterized biochemically and genetically. Mutants selected in a single step are up to 40-fold more resistant to the drug than the parental line, express levels of asparagine synthetase activity 6-17-fold greater than that of wild type cells, and act co-dominantly in hybrids. Several classes of mutations can be distinguished on the basis of cross-resistance to beta-aspartyl hydroxamate, another amino acid analog. Studies on asparagine synthetase indicate that resistance to albizziin may be due to altered regulation of asparagine synthetase, structural mutations of the enzyme, and gene amplification.     

Isolation and characterization of CHO cell mutants with altered asparagine synthetase.

Two asparagine auxotrophic mutants (N3, N4) were isolated from the Gat- strain of Chinese hamster ovary cells, using a selection procedure modified from that of Goldfarb et al. (1). The defect in these mutants is due to a deficiency in asparagine synthetase activity. N3, in particular, had no measurable enzyme activity. Complementation analysis by PEG-mediated cell fusion showed that the auxotrophic phenotype behaved as a recessive trait; complementation was obtained between N3 or N4 and the pseudoauxotroph, Asn3, which has a temperature-sensitive asparagyl-tRNA synthetase activity. Revertants obtained by plating N3 or N4 in asparagine-free medium had about normal levels of asparagine synthetase activity and were produced with a probability of about 10(-6) per cell per generation. Three particular revertants of N3 and one revertant of N4 were shown to have asparagine synthetase activities that were different in thermolability from that of the wild type. This observation is consistent with the suggestion that N3 and N4 have defective structural genes rather than defective regulatory genes for asparagine synthetase.     

The isolation and characterization of asparagine-requiring mutants of Chinese hamster cells

Nine asparagine-requiring mutants were isolated in culture from the Don line of Chinese hamster cells. Investigation of the asparagine requirements of the mutants, the effect of asparagine deprivation on macromolecular synthesis, and the rates of reversion to asparagine independence indicated that there were differences between the mutant clones. Biochemical analysis revealed that the defect in the mutants was due to a deficiency of the enzyme asparagine synthetase, and that the enzyme activity in the mutants and Asn⁺ revertants obtained from them was not influenced by the concentration of asparagine in the growth medium. Complementation analysis by Sendai virusmediated cell fusion indicated that the lesion behaved as a recessive trait, and was probably located in the same gene in all the mutant clones.     

Cloning of cDNA for argininosuccinate synthetase mRNA and study of enzyme overproduction in a human cell line

Previous studies of the human cell line RPMI-2650 (wild type) and its canavanine-resistant variants have demonstrated differences in argininosuccinate synthetase activity as follows: canavanine-resistant much greater than wild type grown in citrulline greater than wild type grown in arginine (Su, T.-S., Beaudet, A. L., and O'Brien, W. E. (1981) Biochemistry 20, 2956-2960). A recombinant plasmid containing a 1.55-kilobase insert complementary to the mRNA for human argininosuccinate synthetase was isolated by the combined use of differential colony hybridization and immunoprecipitation of the products of plasmid-selected mRNA translation. Both blot and dot hybridization analysis of polyadenylated RNA indicated a major mRNA species of 1.67 kilobase in all cells, and the levels of mRNA correlated well with the levels of enzyme activity: canavanine-resistant, 180; wild type grown in citrulline, 7; and wild type grown in arginine, 1. One major mRNA species of 1.67 kilobase and one minor species of 2.68 kilobase were observed in wild type and canavanine-resistant cell lines. Reassociation kinetics of pAS1 with genomic DNA from human liver, canavanine-resistant cells, and wild type cells were not significantly different. Blot hybridization of genomic DNA revealed no detectable differences between wild type cells, canavanine-resistant cells, and human leukocytes. The data demonstrated that there were multiple copies, perhaps 10 or more, of argininosuccinate synthetase-like sequences in human DNA and that the canavanine-resistant phenotype was not due to gene amplification.     

Isolation of Chinese hamster ovary cells that overproduce asparaginyl-tRNA synthetase.

Temperature-resistant revertants, derived from the temperature-sensitive CHO asparaginyl-tRNA synthetase mutant, Asn-5, were isolated and characterized. Several lines of evidence indicate that the temperature-resistant phenotype of the revertants is due to their overproducing the same altered enzyme present in the Asn-5 parent.     

Taurine catabolism. III. Evidence for the participation of the glyoxylate cycle

The metabolic fate of acetate, produced during taurine catabolism in Pseudomonas aeruginosa TAU-5, appears to involve the glyoxylate cycle. Organisms grown on taurine have significantly higher levels of malate synthetase and isocritrate lyase than cells grown on nutrient broth, but were comparable to the levels found in acetate-grown organisms. Itaconate, an isocitrate lyase inhibitor, produced a prolonged lag phase and reduced the growth rate of organisms when it was present in the taurine or acetate growth medium. Ethylmethanesulfonate treatment of TAU-5 yielded mutant strains unable to grow on taurine or acetate as sole carbon sources, due to a lack of either malate synthetase or isocitrate lyase. Spontaneous revertants derived from these mutant strains regained the missing enzyme activity and the ability to grow on taurine or acetate.     

Taurine catabolism: III. Evidence for the participation of the glyoxylate cycle

The metabolic fate of acetate, produced during taurine catabolism in Pseudomonas aeruginosa TAU-5, appear to involve the glyoxylate cycle. Organisms grown on taurine have significantly higher levels of malate synthetase and isocitrate lyase than cells grown on nutrient broth, but were comparable to the levels found in acetate-grown organisms. Itaconate, an isocitrate lyase inhibitor, produced a prolonged lag phase and reduced the growth rate of organisms when it was present in the taurine or acetate growth medium. Ethylmethanesulfonate treatment of TAU-5 yielded mutant strains unable to grow on taurine or acetate as sole carbon sources, due to a lack of either malate synthetase or isocitrate lyase. Spontaneous revertants derived from these mutant strains regained the missing enzyme activity and the ability to grow on taurine or acetate.     

Transfer of a mutant viral thymidine kinase gene results in temperature-sensitive mouse cells.

Temperature-sensitive cell lines were obtained by DNA-mediated transfer of the thymidine kinase (TK) gene from a mutant, ts1117, of herpes simplex virus type 1. The cells died at 39 degrees C in selective medium which contained low levels (1 microgram/ml) of thymidine. In this lethal condition, no revertants were detected among 10(8) cells. It was shown by in vitro analysis of the TK activity that the temperature-sensitive cell line contains an enzyme whose activity is temperature sensitive and relatively unaffected by dTTP. The viral enzyme has these properties. The effect of the lethal growth conditions in the cell line was characterized by cell cycle analysis and rescue experiments which involved a shift to the permissive conditions. The successful transfer of the mutant viral TK activity to cells provides an additional selective marker for gene transfer.     

Monoclonal antibodies specific for bovine pancreatic asparagine synthetase. Production and use in structural studies

Thirteen stable hybridoma cell lines producing monoclonal antibodies specific for asparagine synthetase were established and one monoclonal antibody was chosen to produce an immunoaffinity resin for the purification of asparagine synthetase. Bovine pancreatic asparagine synthetase was purified to a specific activity of 395 nmol of Asn produced/min/mg. Electrophoresis of the affinity-purified enzyme in sodium dodecyl sulfate polyacrylamide gels resulted in a single Mr = 54,000 polypeptide. Prior cross-linking with dimethyl suberimidate resulted in a band at Mr = 52,500 (monomer) and two additional bands at Mr = 97,000 and 98,000 (dimers), suggesting the possibility of a heterogeneous enzyme population with slight differences in subunit composition. The ratio of Gln-dependent and NH3-dependent asparagine synthetase activities was constant for immunoaffinity-purified enzyme, but the ratios of glutaminase activity to synthetase activities varied, suggesting separate aspartate and glutamine binding sites. The monoclonal antibodies were tested as inhibitors of the Gln-dependent and NH3-dependent asparagine synthetase activities as well as for inhibition of the glutaminase activity of the enzyme. Two antibodies inhibited Gln- and NH3-dependent synthesis of asparagine, but did not affect the glutaminase activity of immunoaffinity-purified asparagine synthetase. A third monoclonal antibody inhibited Gln-dependent synthesis of asparagine and glutaminase activity, but activated NH3-dependent asparagine synthetase activity. These data are discussed in terms of multiple substrate binding domains within the asparagine synthetase molecule.     

Gene amplification as a mechanism of reversion at the HPRT locus in V79 Chinese hamster cells

Spontaneous phenotypic revertants of hypoxanthine phosphoribosyl-transferase (HPRT) temperature-sensitive V79 Chinese hamster cells were selected by plating a temperature-sensitive mutant in HAT medium at 39 degrees C. The incidence of such revertants was approximately 2 X 10(-4) per cell. The majority of the revertants examined had increases of between three- and tenfold in their specific activity of the enzyme, and they were able to grow continuously in the presence of HAT medium at 39 degrees C. When the revertants were cultivated in the absence of HAT, they recovered their HAT-sensitive phenotype and their lowered level of HPRT. Three of the revertants were examined for their temperature inactivation profiles, and all were found to have profiles identical to the ts parent, and quite different from the V79 wild type. The kinetic properties of the cell lines were studied: the Km for both PRPP and hypoxanthine was significantly different in the temperature-sensitive cells but was not significantly altered in the revertants with respect to the ts mutants. A specific antibody to Chinese hamster brain HPRT was employed in immunoprecipitation experiments. By measuring the point at which the immunoprecipitation of the antibody to HPRT was overcome by increasing concentrations of cell supernatant, it was possible to estimate the relative amount of enzyme molecules in the cell lines. From these data, it could be concluded that the revertants overproduced an enzyme with the same immunological properties as the ts line. Southern blots of the Hind III restricted DNA from the ts mutant and two revertant cell lines were examined with an HPRT cDNA probe. This established that the HPRT gene was amplified twofold in one of the revertants, and threefold in the other. However, if the revertants were reintroduced into nonselective medium, the gene copy number declined to one. Finally, northern blots of RNA extracted from the various cell lines demonstrated that the HPRT mRNA was augmented 1.5-fold in one revertant and 1.4-fold in the other. Reintroduction into non-selective medium resulted in a decline in mRNA level for the second mutant, whereas the first mutant appeared to be stabilized. We conclude that gene amplification and concomitant amplification of messenger RNA and enzyme levels are mechanisms of phenotypic reversion at the HPRT locus in Chinese hamster cells.     

Regulation of the tyrosine biosynthetic enzymes in Salmonella typhimurium: analysis of the involvement of tyrosyl-transfer ribonucleic acid and tyrosyl-transfer ribonucleic acid synthetase

Mutants of Salmonella typhimurium were isolated that require tyrosine for growth because of an altered tyrosyl-transfer ribonucleic acid (tRNA) synthetase. Extracts of one strain (JK10) contain a labile enzyme with decreased ability to transfer tyrosine to tRNA(Tyr) and a higher K(m) for tyrosine than the wild-type enzyme. Strain JK10 maintains repressed levels of the tyrosine biosynthetic enzymes when the growth rate is restricted due to limitation of charged tRNA(Tyr). Several second-site revertants of strain JK10 exhibit temperature-sensitive growth due to partially repaired, heat-labile tyrosyl-tRNA synthetase. The tyrosine biosynthetic enzymes are not derepressed in thermosensitive strains grown at the restrictive temperature. A class of tyrosine regulatory mutants, designated tyrR, contains normal levels of tyrosyl-tRNA synthetase and tRNA(Tyr). These results suggest that charging of tRNA(Tyr) is not necessary for repression. This conclusion is substantiated by the finding that 4-aminophenylalanine, a tyrosine analogue which causes repression of the tyrosine biosynthetic enzymes, is not attached to tRNA(Tyr) in vivo, nor does it inhibit the attachment reaction in vitro. A combined regulatory effect due to the simultaneous presence of tyrS and tyrR mutations in the same strain was detected. The possibility of direct participation of tyrosyl-tRNA synthetase in tyrosine regulation is discussed.     

Bovine pancreatic asparagine synthetase explored with substrate analogs and specific monoclonal antibodies.

Several substrate analogs were tested for their ability to inhibit bovine pancreatic asparagine synthetase. Of the substrate analogs tested both 6-diazo-5-oxo-L-norleucine (DON) and 5-chloro-4-oxo-L-norvaline (CONV) were shown to inhibit the enzyme strongly. DON inhibited the glutaminase and glutamine-dependent asparagine synthetase activities and CONV inhibited the ammonia-dependent activity as well. Both of these inhibitors appeared to be relatively tight binding since desalting failed to remove the inhibition. The inactivation of bovine pancreatic asparagine synthetase by DON is accompanied by a shift from a 47,000 molecular weight monomer to a 96,000 molecular weight dimer as observed by HPLC gel filtration chromatography. This DON-induced shift is prevented by the presence of the substrate glutamine. A monoclonal antibody known to inhibit specifically the ammonia-dependent and glutamine-dependent asparagine synthetase activities but not glutaminase (monoclonal antibody 2B4) binds to both the monomer and the dimer forms of untreated enzyme, as well as to the dimer form of the DON-inactivated enzyme. On the other hand, a monoclonal antibody known to inhibit specifically the glutaminase and glutamine-dependent activities and not the ammonia-dependent asparagine synthetase (monoclonal antibody 5A6) binds to both forms of untreated enzyme but cannot bind to the DON-inactivated enzyme. These data are used to describe the relation of regions of the active site of asparagine synthetase in relation to antibody binding sites.     

Inhibition of glutamine synthetase triggers apoptosis in asparaginase-resistant cells.

The resistance to L-asparaginase (ASNase) has been associated to the overexpression of asparagine synthetase (AS), although the role played by other metabolic adaptations has not been yet defined. Both in ASNase-sensitive Jensen rat sarcoma cells and in ARJ cells, their ASNase-resistant counterparts endowed with a five-fold increased AS activity, ASNase treatment rapidly depletes intracellular asparagine. Under these conditions, cell glutamine is also severely reduced and the activity of glutamine synthetase (GS) is very low. After 24 h of treatment, while sensitive cells have undergone massive apoptosis, ARJ cells exhibit a marked increase in GS activity, associated with overexpression of GS protein but not of GS mRNA, and a partial restoration of glutamine and asparagine. However, when ARJ cells are treated with both ASNase and L-methionine-sulfoximine (MSO), an inhibitor of GS, no restoration of cell amino acids occurs and the cell population undergoes a typical apoptosis. No toxicity is observed upon MSO treatment in the absence of ASNase. The effects of MSO are not referable to depletion of cell glutathione or inhibition of AS. These findings indicate that, in the presence of ASNase, the inhibition of GS triggers apoptosis. GS may thus constitute a target for the suppression of ASNase-resistant phenotypes.