Derepression of Synthesis of the Aminoacyl-Transfer Ribonucleic Acid Synthetases for the Branched-Chain Amino Acids of Escherichia coli

The kinetics of derepression of valyl-, isoleucyl-, and leucyl-transfer ribonucleic acid (tRNA) synthetase formation was examined during valine-, isoleucine-, and leucine-limited growth. When valine was limiting growth, valyl-tRNA synthetase formation was maximally derepressed within 5 min, whereas the rates of synthesis of isoleucyl-, and leucyl-tRNA synthetases were unchanged. Isoleucine-restricted growth caused a maximal derepression of isoleucyl-tRNA synthetase formation in 5 min and derepression of valyl-tRNA synthetase formation in 15 min with no effect on leucyl-tRNA synthetase formation. When leucine was limiting growth, leucyl-tRNA synthetase formation was immediately derepressed, whereas valyl- and isoleucyl-tRNA synthetase formation was unaffected by manipulation of the leucine supply to the cells. These results support our previous findings that valyl-tRNA synthetase formation is subject to multivalent repression control by both isoleucine and valine. In contrast, repression control of iso-leucyl- and leucyl-tRNA synthetase formation is specifically mediated by the supply of the cognate amino acid.     

Subcellular distribution and characteristics of trihydroxycoprostanoyl-CoA synthetase in rat liver.

The subcellular distribution and characteristics of trihydroxycoprostanoyl-CoA synthetase were studied in rat liver and were compared with those of palmitoyl-CoA synthetase and choloyl-CoA synthetase. Trihydroxycoprostanoyl-CoA synthetase and choloyl-CoA synthetase were localized almost completely in the endoplasmic reticulum. A quantitatively insignificant part of trihydroxycoprostanoyl-CoA synthetase was perhaps present in mitochondria. Peroxisomes, which convert trihydroxycoprostanoyl-CoA into choloyl-CoA, were devoid of trihydroxycoprostanoyl-CoA synthetase. As already known, palmitoyl-CoA synthetase was distributed among mitochondria, peroxisomes and endoplasmic reticulum. Substrate- and cofactor- (ATP, CoASH) dependence of the three synthesis activities were also studied. Cholic acid and trihydroxycoprostanic acid did not inhibit palmitoyl-CoA synthetase; palmitate inhibited the other synthetases non-competitively. Likewise, cholic acid inhibited trihydroxycoprostanic acid activation non-competitively and vice versa. The pH curves of the synthetases did not coincide. Triton X-100 affected the activity of each of the synthetases differently. Trihydroxycoprostanoyl-CoA synthetase was less sensitive towards inhibition by pyrophosphate than choloyl-CoA synthetase. The synthetases could not be solubilized from microsomal membranes by treatment with 1 M-NaCl, but could be solubilized with Triton X-100 or Triton X-100 plus NaCl. The detergent-solubilized trihydroxycoprostanoyl-CoA synthetase could be separated from the solubilized choloyl-CoA synthetase and palmitoyl-CoA synthetase by affinity chromatograpy on Sepharose to which trihydroxycoprostanic acid was bound. Choloyl-CoA synthetase and trihydroxycoprostanoyl-CoA synthetase could not be detected in homogenates from kidney or intestinal mucosa. The results indicate that long-chain fatty acids, cholic acid and trihydroxycoprostanic acid are activated by three separate enzymes.     

Comparison of the enzymatic behavior of high molecular weight and free lysyl-tRNA synthetase from rat liver: kinetic analysis of lysylation of tRNA

Lysyl-tRNA synthetase occurs in the high molecular weight form in rat liver. The high molecular weight lysyl-tRNA synthetase has been previously demonstrated to exist as multienzyme complexes of aminoacyl-tRNA synthetases. The multienzyme complexes can be dissociated by hydrophobic interaction chromatography and yield fully active, free lysyl-tRNA synthetase. The free form is found to be twice as active as the complexed form in lysylation. Bisubstrate and product inhibition kinetics of lysylation are systematically carried out for highly purified free lysyl-tRNA synthetase and the 18 S synthetase complex. Surprisingly, the two enzyme forms exhibit distinctly different kinetic patterns in bisubstrate and product inhibition kinetics under identical conditions. The 18 S synthetase complex shows kinetic patterns consistent with an ordered bi uni uni bi ping pong mechanism, while the results of free lysyl-tRNA synthetase do not. We conclude that structural organization of lysyl-tRNA synthetase beyond quaternary structure of proteins may alter the enzyme behavior.     

Organisation and sequence determination of glutamine-dependent carbamoyl phosphate synthetase II in Toxoplasma gondii

Carbamoyl phosphate synthetase II encodes the first enzymic step of de novo pyrimidine biosynthesis. Carbamoyl phosphate synthetase II is essential for Toxoplasma gondii replication and virulence. In this study, we characterised the primary structure of a 28kb gene encoding Toxoplasma gondii carbamoyl phosphate synthetase II. The carbamoyl phosphate synthetase II gene was interrupted by 36 introns. The predicted protein encoded by the 37 carbamoyl phosphate synthetase II exons was a 1,687 amino acid polypeptide with an N-terminal glutamine amidotransferase domain fused with C-terminal carbamoyl phosphate synthetase domains. This bifunctional organisation of carbamoyl phosphate synthetase II is unique, so far, to protozoan parasites from the phylum Apicomplexa (Plasmodium, Babesia, Toxoplasma) or zoomastigina (Trypanosoma, Leishmania). Apicomplexan parasites possessed the largest carbamoyl phosphate synthetase II enzymes due to insertions in the glutamine amidotransferase and carbamoyl phosphate synthetase domains that were not present in the corresponding gene segments from bacteria, plants, fungi and mammals. The C-terminal allosteric regulatory domain, the carbamoyl phosphate synthetase linker domain and the oligomerisation domain were also distinct from the corresponding domains in other species. The novel C-terminal regulatory domain may explain the lack of activation of Toxoplasma gondii carbamoyl phosphate synthetase II by the allosteric effector 5-phosphoribosyl 1-pyrophosphate. Toxoplasma gondii growth in vitro was markedly inhibited by the glutamine antagonist acivicin, an inhibitor of glutamine amidotransferase activity typically associated with carbamoyl phosphate synthetase II, guanosine monophosphate synthetase, or CTP synthetase.     

Influence of supramolecular structure on the enzyme mechanisms of rat liver lysyl-tRNA synthetase-catalyzed reactions. Synthesis of P1,P4-bis(5'-adenosyl)tetraphosphate

Lysyl-tRNA synthetase, dissociated from the multienzyme complexes of aminoacyl-tRNA synthetases from rat liver, was previously found to be 6-fold more active than the synthetase complex in the enzymatic synthesis of P1,P4-bis(5'-adenosyl)tetraphosphate. The bi-substrate and product inhibition kinetics of the reaction are analyzed. Free lysyl-tRNA synthetase exhibits distinctly different kinetic patterns from those of an 18 S synthetase complex containing lysyl-tRNA synthetase. The 18 S synthetase complex shows kinetic patterns which are consistent with an ordered Bi Uni Uni Bi ping-pong mechanism. Free lysyl-tRNA synthetase shows kinetic patterns consistent with a random mechanism. The differences in the enzymatic properties are attributed to the organization of the supramolecular structure of the synthetase complex. The results suggest that association of the synthetases may affect the mechanisms of the synthesis of AppppA.     

Translation and characterization of the fatty acid synthetase messenger RNA

Fatty acid synthetase messenger RNA was obtained from rat liver polysomal RNA and then injected into Xenopus laevis oocytes. The radioactive fatty acid synthetase protein synthesized in the oocytes was identified by immunoprecipitation with anti-fatty acid synthetase antibody and the immunoprecipitate was then characterized by electrophoresis on sodium dodecyl sulfate-polyacrylamide gel. Co-migration of authentic fatty acid synthetase and the labeled product synthesized in oocytes was observed. Based on sucrose density gradient analysis, the rat liver fatty acid synthetase mRNA has a sedimentation coefficient of approximately 33 S, which agrees with the predicted minimum size necessary to code for the fatty acid synthetase protein. In addition, this mRNA was partially purified with oligo(dT)-cellulose, which indicates that it has a polyadenylate region. The relative in vivo rate of synthesis of fatty acid synthetase and the level of fatty acid synthetase mRNA in liver were also determined during the course of dietary induction of this enzyme. The results indicate that the dietary-induced increase in the level of fatty acid synthetase is probably due to an increased level of the fatty acid synthetase mRNA.     

Expression of glutamine synthetase in macrophages.

We studied the expression of glutamine synthetase in liver macrophages (Kupffer cells, KCs) in situ and in culture. Glutamine synthetase was detectable at the mRNA and protein level in freshly isolated and short-term-cultured rat liver macrophages. Enzyme activity and protein content were about 9% of that in liver parenchymal cells. In contrast, glutamine synthetase mRNA levels in liver macrophages apparently exceeded those in parenchymal liver cells (PCs). By use of confocal laser scanning microscopy and specific macrophage markers, immunoreactive glutamine synthetase was localized to macrophages in normal rat liver and normal human liver in situ. All liver macrophages stained positive for glutamine synthetase. In addition, macrophages in rat pancreas contained immunoreactive glutamine synthetase, whereas glutamine synthetase was not detectable at the mRNA and protein level in blood monocytes and RAW 264.7 mouse macrophages. No significant amounts of glutamine synthetase were found in isolated rat liver sinusoidal endothelial cells (SECs). The data suggest a constitutive expression of glutamine synthetase not only, as previously believed, in perivenous liver parenchymal cells but also in resident liver macrophages.     

Evidence of covalent modification of glutamine synthetase in the purple sulfur bacterium Thiocapsa roseopersicina

Abstract It was shown that glutamine synthetase of purple sulfur bacterium Thiocapsa roseopersicina is regulated by covalent modification. This conclusion is made on the basis of results showing that: (i) incubation of cells under conditions of nitrogen deprivation in the light lead to an increase of glutamine synthetase activity; (ii) addition of ammonium to nitrogen-starved cell suspensions caused a rapid decrease of glutamine synthetase activity; (iii) inhibition of glutamine synthetase by feedback modifiers was higher in ammonium-treated cells than in those starved for a nitrogen source; (iv) treatment of purified glutamine synthetase and cell-free extracts with phosphodiesterase was accompanied by an increase of glutamine synthetase activity, indicating the cleavage of modifying residues covalently bound to glutamine synthetase molecules.     

Affinity chromatography of rat liver aminoacyl-tRNA synthetase complex

The affinity column lysyldiaminohexyl-Sepharose 4B has been synthesized for the purification of aminoacyl-tRNA synthetase complexes. Lysyl-tRNA synthetase (EC 6.1.1.6) bound specifically to the Sepharose-bound lysine. The purified lysyl-tRNA synthetase was associated with arginyl-tRNA synthetase (EC 6.1.1.16) and sedimented at 18S and 12S. A 24S lysyl-tRNA synthetase bound specifically to the affinity column and also found associated with arginyl-tRNA synthetase. The results favor the model of a heterotypic multienzyme complex of mammalian aminoacyl-tRNA synthetases.     

In vitro synthesis of alpha-carboxyl-linked folylpolyglutamates by an enzyme preparation from Escherichia coli

Extracts of Escherichia coli contained an enzymatic activity which catalyzed the addition of L-glutamate to the alpha-carboxyl of various polyglutamate substrates, including folylpolyglutamates. Much of the enzyme activity was separated by DE52 chromatography and gel filtration from the enzyme which adds the first three glutamates in the biosynthesis of folylpolyglutamates, dihydrofolate synthetase-folylpolyglutamate synthetase. The two enzyme activities differed in many properties. Whereas dihydrofolate synthetase-folylpolyglutamate synthetase preferred pteroate or pteroylmonoglutamate substrates, the folylpoly-alpha-glutamate synthetase preparations effectively utilized tetrahydropteroylpolyglutamates, pteroylpolyglutamates, p-aminobenzoylpolyglutamates (pAB(Glu)n), and even a polyglutamate tripeptide. Several di- and triglutamyl peptides were inhibitory to folylpoly-alpha-glutamate synthetase activity, but not to dihydrofolate synthetase-folylpolyglutamate synthetase. Conversely, dihydropteroate noncompetitively inhibits the folylpolyglutamate synthetase reaction of the dihydrofolate synthetase-folylpolyglutamate synthetase protein, but did not inhibit the folylpoly-alpha-glutamate synthetase reaction. Potassium chloride was inhibitory to folylpoly-alpha-glutamate synthetase activity (as were other salts and several polyanions), in contrast to the absolute requirement of dihydrofolate synthetase-folylpolyglutamate synthetase activity for a monovalent cation such as K+. Incubation of a folylpoly-alpha-glutamate synthetase preparation with (6S)-tetrahydropteroyltri(gamma)glutamate generated products which after chemical cleavage to pAB(Glu)n were identical to those from growing E. coli, in high performance liquid chromatography retention times and in pattern of digestion by alpha-COOH bond-specific carboxypeptidase Y. High performance liquid chromatography and mass spectral analysis of the products of the in vitro reactions of folylpoly-alpha-glutamate synthetase with several substrates also demonstrated the addition of glutamate residues via alpha-COOH linkages. Thus, there appear to be two folylpolyglutamate synthetase activities in E. coli, dihydrofolate synthetase-folylpolyglutamate synthetase which adds the first three glutamate residues by gamma-COOH linkages and the folylpoly-alpha-glutamate synthetase activity which extends the folylpolyglutamate chain via gamma-COOH peptide bonds.     

Inhibitory effect of interferon-gamma-dependent induction of major histocompatibility complex class II antigen by expressing exogenous poly(ADP-ribose) synthetase gene

Ia antigen, one of class II major histocompatibility complexes, was induced by treatment of mouse macrophage P388D1 cells with interferon-gamma. During the process, expression of poly(ADP-ribose) synthetase gene was depressed. We examined whether or not down-regulation of the synthetase was required for the interferon-gamma-dependent induction of Ia antigen. We constructed expression plasmid harboring metallothionein promoter-regulated synthetase gene. The enzyme activity and mRNA level of the synthetase were increased in exogenous synthetase gene-transfected clones. Induction of Ia antigen gene was strongly inhibited by expressing the exogenous synthetase gene upon treatment of the transfected clones with interferon-gamma. The result suggests that interferon-gamma-dependent down-regulation of the synthetase may be involved in a step of the signal transduction to induce Ia antigen.     

Purification and comparison of two forms of S-adenosyl-L-methionine synthetase from rat liver

Only two S-adenosyl-L-methionine synthetase forms exist in rat liver: high-Mr S-adenosyl-L-methionine synthetase and low-Mr S-adenosyl-L-methionine synthetase, which have been purified to apparent homogeneity as judged by sodium dodecyl sulfate/polyacrylamide gel electrophoresis. High-Mr S-adenosyl-L-methionine synthetase had an apparent molecular mass, determined by gel filtration, of 210 kDa and was a tetramer constituted by 48.5-kDa subunits, estimated by sodium dodecyl sulfate/polyacrylamide gel electrophoresis. The apparent molecular mass of low-Mr S-adenosyl-L-methionine synthetase, as estimated by gel filtration, was 110 kDa and was constituted by two subunits of 47 kDa. An antiserum against low-Mr S-adenosyl-L-methionine synthetase cross-reacted with the two forms. Reverse-phase HPLC runs of tryptic digestions of high-Mr and low-Mr S-adenosyl-L-methionine synthetase showed that the peptide maps of the two forms were very similar, if not identical. High-Mr S-adenosyl-L-methionine synthetase activity was inhibited by S-adenosyl-L-methionine and pyrophosphate. Depending on the dose used, S-adenosyl-L-methionine activated or inhibited low-Mr S-adenosyl-L-methionine synthetase and pyrophosphate had no effect on this form. The two synthetases showed a different specific activity at the physiological concentration of methionine. This report shows that even though the two forms are constructed of the same polypeptide chains, they are regulated in a different manner by methionine and by the products of the reaction.     

Repression of 3-deoxy-D-arabinoheptulosonic acid-7-phosphate synthetase (trp) and enzymes of the tryptophan pathway in Escherichia coli K-12

Mutant strains of Escherichia coli K-12 have been isolated in which the synthesis of 3-deoxy-d-arabinoheptulosonic acid-7-phosphate (DAHP) synthetase (trp) is partially constitutive. The mutation causing derepression is closely linked to aroH [the structural gene for DAHP synthetase (trp)] and occurs in a locus designated aroJ. The aroJ mutation is not recessive in an aroJ(+)/aroJ(-) diploid strain, as the synthesis of DAHP synthetase (trp) is still derepressed in this strain. On the basis of its close linkage to aroH and its continued expression in an aroJ(+)/aroJ(-) diploid, it is postulated that aroJ is an operator locus controlling the expression of the structural gene aroH. In support of this conclusion, the synthesis of anthranilate synthetase is still normally repressible in aroJ(-) strains, whereas, in trpR(-) strains, both DAHP synthetase (trp) and anthranilate synthetase are synthesized constitutively. The synthesis of DAHP synthetase (trp) remains repressible in an operator-constitutive mutant of the tryptophan operon. In two trpS mutants which possess defective tryptophanyl transfer ribonucleic acid synthetase enzymes, neither DAHP synthetase (trp) nor anthranilate synthetase derepress under conditions in which the defective synthetase causes a decrease in growth rate. On the other hand, an effect of the trpS mutant alleles on the level of anthranilate synthetase has been observed in strains which are derepressed for the synthesis of this enzyme, because of a mutation in the gene trpR. Possible explanations for this effect are presented.     

Expression of Human CTP synthetase in Saccharomyces cerevisiae reveals phosphorylation by protein kinase A

CTP synthetase (EC 6.3.4.2, UTP:ammonia ligase (ADP-forming)) is an essential enzyme in all organisms; it generates the CTP required for the synthesis of nucleic acids and membrane phospholipids. In this work we showed that the human CTP synthetase genes, CTPS1 and CTPS2, were functional in Saccharomyces cerevisiae and complemented the lethal phenotype of the ura7Delta ura8Delta mutant lacking CTP synthetase activity. The expression of the CTPS1- and CTPS2-encoded human CTP synthetase enzymes in the ura7Delta ura8Delta mutant was shown by immunoblot analysis of CTP synthetase proteins, the measurement of CTP synthetase activity, and the synthesis of CTP in vivo. Phosphoamino acid and phosphopeptide mapping analyses of human CTP synthetase 1 isolated from (32)P(i)-labeled cells revealed that the enzyme was phosphorylated on multiple serine residues in vivo. Activation of protein kinase A activity in yeast resulted in transient increases (2-fold) in the phosphorylation of human CTP synthetase 1 and the cellular level of CTP. Human CTP synthetase 1 was also phosphorylated by mammalian protein kinase A in vitro. Using human CTP synthetase 1 purified from Escherichia coli as a substrate, protein kinase A activity was dose- and time-dependent, and dependent on the concentrations of CTP synthetase 1 and ATP. These studies showed that S. cerevisiae was useful for the analysis of human CTP synthetase phosphorylation.     

Myositis autoantibody reactivity and catalytic function of threonyl-tRNA synthetase

Spontaneously occurring autoantibody to threonyl-tRNA synthetase found in the serum of patients with polymyositis and experimentally induced antibody against highly purified rabbit reticulocyte threonyl-tRNA synthetase were used to analyze the epitopes of threonyl-tRNA synthetase. The PL-7 autoantibody reacted with the native but not the denatured form of threonyl-tRNA synthetase, whereas the experimentally induced antibody recognized both the native and denatured forms of the enzyme. In addition, the PL-7 autoantibody specifically inhibited threonyl-tRNA synthetase activity whereas the experimentally induced antibody had no effect on aminoacylation. Thus, the epitopes recognized by the PL-7 autoantibody are formed by the tertiary structure of the enzyme and are associated with the catalytic site of the synthetase whereas the experimentally induced antibody recognizes epitopes formed by primary sequences not related to the catalytic function of the synthetase.     

Generation of multiple forms of methionyl-tRNA synthetase from the multi-enzyme complex of mammalian aminoacyl-tRNA synthetases by endogenous proteolysis

Methionyl-tRNA synthetase occurs free and as high-molecular-weight multi-enzyme complexes in rat liver. The free form is purified to near homogeneity by conventional column chromatography and affinity chromatography on tRNA-Sepharose. The native molecular weight of free methionyl-tRNA synthetase is 64 500, based on its sedimentation coefficient of 4.5 S and Stokes radius of 33 A. The free methionyl-tRNA synthetase apparently belongs to alpha-type subunit structure, since the subunit molecular weight is 68 000, as determined by sodium dodecyl sulfate polyacrylamide gel electrophoresis. Methionyl-tRNA synthetase is dissociated from the high-molecular-weight synthetase complex by controlled trypsinization, according to Kellermann, O., Viel, C. and Waller, J.P. (Eur. J. Biochem. 88 (1978) 197-204). The dissociated, free methionyl-tRNA synthetase is subsequently purified to near homogeneity. The subunit structure of dissociated methionyl-tRNA synthetase is identical to that of endogenous free methionyl-tRNA synthetase. Anti-serum raised against Mr 104 000 protein in the synthetase complex, specifically inhibited methionyl-tRNA synthetase in both the free and the high-molecular-weight forms to the same extent. These results suggest that the occurrence of multiple forms of methionyl-tRNA synthetases in mammalian cells may, in part, be due to proteolytic cleavage.     

Regulation of glutamine synthetase, aspartokinase, and total protein turnover in Klebsiella aerogenes

When suspensions of Klebsiella aerogenes are incubated in a nitrogen-free medium there is a gradual decrease in the levels of acid-precipitable protein and of aspartokinase III (lysine-sensitive) and aspartokinase I (threonine-sensitive) activities. In contrast, the level of glutamine synthetase increases slightly and then remains constant. Under these conditions, the glutamine synthetase and other proteins continue to be synthesized as judged by the incorporation of [14C]leucine into the acid-precipitable protein fraction and into protein precipitated by anti-glutamine synthetase antibodies, by the fact that growth-inhibiting concentrations of chloramphenicol also inhibit the incorporation of [14C]leucine into protein and into protein precipitated by anti-glutamine synthetase antibody, and by the fact that chloramphenicol leads to acceleration in the loss of aspartokinases I and III and promotes a net decrease in the level of glutamine synthetase and its cross-reactive protein. The loss of aspartokinases I and III in cell suspensions is stimulated by glucose and is inhibited by 2,4-dinitrophenol. Glucose also stimulates the loss of aspartokinases and glutamine synthetase in the presence of chloramphenicol. Cell-free extracts of K. aerogenes catalyze rapid inactivation of endogenous glutamine synthetase as well as exogenously added pure glutamine synthetase. This loss of glutamine synthetase is not associated with a loss of protein that cross-reacts with anti-glutamine synthetase antibodies. The inactivation of glutamine synthetase in extracts is not due to adenylylation. It is partially prevented by sulfhydryl reagents, Mn2+, antimycin A, 2,4-dinitrophenol, EDTA, anaerobiosis and by dialysis. Following 18 h dialysis, the capacity of extracts to catalyze inactivation of glutamine synthetase is lost but can be restored by the addition of Fe2+ (or Ni2+) together with ATP (or other nucleoside di- and triphosphates. After 40-60 h dialysis Fe3+ together with NADH (but not ATP) are required for glutamine synthetase inactivation. The results suggest that accelerated protein degradation in cells exposed to nitrogen-limited conditions reflects the differential destruction of some proteins, including aspartokinases I and III, in order to sustain the biosynthesis of others such as glutamine synthetase. The loss of glutamine synthetase activity in cell-free extracts is likely mediated in part by mixed-function oxidation systems and could represent a 'marking' step in protein turnover.     

Identification of bacteriophage T4D gene 29 product, a baseplate hub component, as a folylpolyglutamate synthetase

An assay for folylpolyglutamate synthetase activity in extracts of uninfected and bacteriophage T4D-infected Escherichia coli B has been developed. T4D infection induced the formation of a new synthetase raising the total synthetase activity three-fold. Extracts obtained after infection with T4 gene 51, 27 or 28 amber mutants showed increased synthetase activities while extracts obtained from cells infected with a T4D gene 29 amber mutant did not show any increase in synthetase activity. The phage-induced synthetase was found to copurify with the gene 29 product and a 100-fold purified synthetase of molecular size of 74,000 daltons has been obtained. The purified synthetase has a folate substrate specificity different from the host synthetase since it added glutamate residues to dihydrofolate as well as to the usual tetrahydrofolate substrate.