Two forms of glutamine synthetase from pumpkin leaves

Two molecular forms of glutamine synthetase localized in the cytoplasm and in chloroplasts, respectively, were detected in pumpkin leaves. Ammonium infiltrated into intact pumpkin leaves activated the synthesis of both enzyme forms. Glutamine synthetase from chloroplasts and the cytoplasmic enzyme were purified to homogeneity by ammonium sulfate fractionation, ion-exchange chromatography on DEAE-cellulose DE-32, selective adsorption on potassium phosphate gel and preparative electrophoresis in polyacrylamide gel. The molecular weights of both forms of glutamine synthetase as determined by gel-filtration through Sephacryl S-200 are equal to 370,000 and 480,000, respectively. During SDS polyacrylamide gel electrophoresis the enzymes from both sources produced polypeptide chains with respective molecular weights of 50,000 and 58,000. The amino acid composition of the enzymes differed considerably. The content of alpha-helix moities in the chloroplast and cytoplasmic enzyme made up to 17% and 34%, respectively. In the presence of Mg+ the pH optima for the enzymes were equal to 7.75 and 7.25, respectively, and the Km values for L-glutamate were 46 and 13 mM, respectively. It may be concluded that the enzyme forms under study are isoenzymes.     

Two forms of glutamine synthetase in leaves of Cucurbita pepo

It has been shown that the leaves of pumpkin (Cucurbita pepo) contain two molecular forms of glutamine synthetase (GS), one occurring in the cytosol (GS₁)and the other in the chloroplasts (GS₂). The activities of both forms were greater when ammonium ion was infiltrated into the leaves and this was shown to be due to de novo synthesis. The two synthetases were purified by ammonium sulphate fractionation, ion exchange chromatography on DEAE-cellulose, selective adsorption on calcium phosphate gel, and preparative polyacrylamide gel electrophoresis. The MWs of GS₁ and GS₂, estimated by gel filtration on Sephacryl S-200, were 480 000 and 370 000 respectively. During polyacrylamide gel electrophoresis in the presence of SDS both GS₁ and GS₂ were dissociated into polypeptide chains with MWs of 58 000 and 50 000 respectively, suggesting that GS, ₁ and GS₂ are octamers consisting of identical monomers. The synthetases showed noticeable differences in their amino acid composition. In GS₁ and GS₂ the proportions of α- helical segments were 34 and 17 % respectively. In the presence of Mg²⁺, the pH optima for GS₁ and GS₂ were 7.25 and 7.75 respectively, and K_m values toward l-glutamate were 13 and 46 mM respectively. From the experimental data it is inferred that GS₁ and GS₂ are isoenzymes.     

Regulation of glutamine synthetase activity and synthesis in free-living and symbiotic Anabaena spp.

Regulation of the synthesis and activity of glutamine synthetase (GS) in the cyanobacterium Anabaena sp. strain 7120 was studied by determining GS transferase activity and GS antigen concentration under a variety of conditions. Extracts prepared from cells growing exponentially on a medium supplemented with combined nitrogen had a GS activity of 17 mumol of gamma-glutamyl transferase activity per min per mg of protein at 37 degrees C. This activity doubled in 12 h after transfer of cells to a nitrogen-free medium, corresponding to the time required for heterocyst differentiation and the start of nitrogen fixation. Addition of NH3 to a culture 11 h after an inducing transfer immediately blocked the increase in GS activity. In the Enterobacteriaceae, addition of NH3 after induction results in the covalent modification of GS by adenylylation. The GS of Anabaena is not adenylylated by such a protocol, as shown by the resistance of the transferase activity of the enzyme to inhibition by Mg2+ and by the failure of the enzyme to incorporate 32P after NH3 upshift. Methionine sulfoximine inhibited Anabaena GS activity rapidly and irreversibly in vivo. After the addition of methionine sulfoximine to Anabaena, the level of GS antigen neither increased nor decreased, indicating that Glutamine cannot be the only small molecule capable of regulating GS synthesis. Methionine sulfoximine permitted heterocyst differentiation and nitrogenase induction to escape repression by NH3. Nitrogen-fixing cultures treated with methionine sulfoximine excreted NH3. The fern Azolla caroliniana contains an Anabaena species living in symbiotic association. The Anabaena species carries out nitrogen fixation sufficient to satisfy all of the combined nitrogen requirements of the host fern. Experiments by other workers have shown that the activity of GS in the symbiont is significantly lower than the activity of GS in free-living Anabaena. Using a sensitive radioimmune assay and a normalization procedure based on the content of diaminopimelic acid, a component unique to the symbiont, we found that the level of GS antigen in the symbiont was about 5% of the level in free-living Anabaena cells. Thus, the host fern appears to repress synthesis of Anabaena GS in the symbiotic association.     

Multiple molecular forms of glutamine synthetase in pea seeds

Summary Multiple molecular forms of glutamine synthetase (GS, EC 6.3.1.2) have been studied in pea seeds of different varieties. The number of GS molecular forms in the seeds proved to be related to their colour. Two GS forms in the green seeds have been found and only one of them in the yellow seeds. Green seeds had chlorophyll content amounted to 0.4% of the total pigment content in the leaves. Chloroplasts, somewhat smaller than those in pea leaves of the same variety, have been isolated from green seeds. The presence of the second GS form in the pea green seeds we relate to the chloroplasts. By electrophoretic mobility both forms of GS from the green seeds are not identical to the chloroplast GS and the cytosol GS of leaves. Thus, we believe pea plant to contain, at least, four GS forms.     

Multiple molecular forms of glutamine synthetase in carp muscles]

Cytoplasmic and mitochondrial molecular forms of glutamine synthetase (CE 6.3.1.2) have been isolated from the carp muscle with purification degree of 100 and 165 times and output 9.0%. It is established that the temperature optimum of the cytoplasmic form activity is 30 degrees C and that of mitochondrial one--20 degrees C; the pH optimum for the both molecular forms is 6.0 and 8.2. The optimal ratio [Me2+] : [ATP] for the isolated form is 2:1; Km (seeming) of the cytoplasmic form in the presence of Mg2+ is 6.0 mM for glutamate, 0.035 for ammonium, for ATP 0.5 and 0.7 for magnesium ions; these values for the mitochondrial form are: 14.3, 0.048, 1.0 and 0.8 mM, respectively. Activity of the both glutamine synthetases with Mg2+ ions is almost by 50% higher than that of glutamine synthetases with Mn2+ ions. Seasonal regularities of the synthesis of molecular glutamine synthetase forms have been established in vivo. Cytoplasmic form is present in the muscles all year round, while mitochondrial one only in winter at low temperature of the environment and fish starvation. Differences in properties and seasonal character of synthesis of molecular glutamine synthetase forms in carp muscles are a result of diversity of their functional role.     

Multiple forms of glutamine synthetase in Bacillus brevis AG 4

Glutamine synthetase in Bacillus brevis AG 4, a Gram-positive spore forming bacteria, has been found to exist in multiple molecular forms. It was purified to electrophoretic homogeneity by single-step Blue Sepharose affinity chromatography. The native enzyme has a molecular weight of 600,000 with subunits of 50,000. The enzyme samples purified from different stages of growth differed in Mg2+ sensitivity and other kinetic properties. Four different enzyme samples selected on the basis of Mg2+ sensitivity showed distinct mobilities at pH 6.3 on PAGE using discontinuous buffer system. A correlation amongst Mg2+ sensitivity, electrophoretic mobility, and kinetic properties was highly suggestive of multiple forms of glutamine synthetase in Bacillus brevis arising due to modification.     

Purification of glutamine synthetase from a variety of bacteria

We have developed two procedures which allow the very rapid purification of glutamine synthetase (GS) from a diverse variety of bacteria. The first procedure, based upon differential sedimentation, depends upon the association of GS with deoxyribonucleic acid in cell extracts. The second procedure, derived from the method of C. Gross et al (J. Bacteriol. 128:382-389, 1976) for purifying ribonucleic acid polymerase by polyethylene glycol (PEG) precipitation, enabled us to obtain high yields of GS from either small or large quantities of cells. We used the PEG procedure to purify GS from Klebsiella aerogenes, K. pneumoniae, Escherichia coli, Salmonella typhimurium, Rhizobium sp. strain 32H1, R. meliloti, Azotobacter vinelandii, Pseudomonas putida, Caulobacter crescentus, and Rhodopseudomonas capsulata. The purity of the GS obtained, judged by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, was high, and in many instances only a single protein band was detected.     

New crystal forms of glutamine synthetase and implications for the molecular structure.

New crystal forms of glutamine synthetase from Escherichia coli are reported. Two of these (II A and II B) demand that the dodecameric molecule contains a 2-fold axis of symmetry perpendicular to the apparent hexagonal face.Whereas forms II A and II B and others reported previously (I and III A) were grown from enzyme containing covalently bound AMP groups, a third new form (III C) was grown from enzyme lacking covalently bound AMP groups. Form III C is isomorphous with form III A. This demonstrates that the addition of AMP groups, which profoundly affect the catalytic and regulatory properties of glutamine synthetase, does not alter the dimensions of the molecular envelope. Thus adenylylation of the enzyme does not seem to cause a quaternary structural transition, though small changes of intensities suggest that there may be tertiary structural changes within the subunits.Other new forms include form III B, a low symmetry polymorph, closely related to form III A, and form IV, a trigonal polymorph with large asymmetric unit. All crystal forms are consistent with a symmetry of 622 for the glutamine synthetase molecule.     

Regulation of glutamine synthetase. VI. Interactions of inhibitors for Bacillus licheniformis glutamine synthetase

The relationships of five feedback inhibitors for the Bacillus licheniformis glutamine synthetase were investigated. The inhibitors were distinguishable by differences in their competitive relationship for the substrates of the enzyme. Mixtures of l-glutamine and adenosine-5'-monophosphate (AMP) or histidine and AMP caused synergistic inhibition of glutamine synthesis. Histidine, alanine, and glycine acted antagonistically toward the l-glutamine inhibition. Alanine acted antagonistically toward the glycine and histidine inhibitions. Independence of inhibitory action was observed with the other pairs of effectors. Possible mechanisms by which the inhibitors may interact to control glutamine synthesis are discussed. The low rate of catalysis of the glutamyl transfer reaction by the B. licheniformis glutamine synthetase can be attributed to the fact that l-glutamine serves both as a substrate and an inhibitor for the enzyme. Effectors which act antagonistically toward the l-glutamine inhibition stimulated glutamotransferase activity. The stimulation was not observed when d-glutamine was used as substrate for the glutamyl transfer reaction.     

Detection of two forms of glutamine synthetase in Bacillus brevis (A. G. 4)

A laboratory isolate of $\text{Bacillus}\text{brevis}$ could grow and sporulate on an amino acid, viz., alanine or glutamate or aspartate as single source of carbon and nitrogen. It failed to sporulate if the amino acid was replaced by the corresponding keto acid and ammonium sulphate in the medium, although, normal growth was observed. One of the key enzymes in nitrogen assimilation, the glutamine synthetase, has been purified by DE-52 and affinity column chromatography from both alanine and pyruvate grown cells. The kinetic and other properties of both of these enzymes were studied. The enzyme isolated from alanine grown cells differed significantly from that isolated from pyruvate grown cells (viz.,pH optima, response to Mg⁺⁺ and other effectors). A possible role of glutamine synthetase in the initiation of bacterial sporulation is discussed.     

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.     

Identification of two forms of glutamine synthetase in barley (Hordeum vulgare).

Hepatocytes of 14-day-old rats have no detectable glucokinase activity $\text{in}$$\text{vivo}$, but it was induced by insulin (10^?8M) in primary cultures of these hepatocytes. The glucokinase induced by insulin was separated by electrophoresis on a cellulose acetate membrane and identified by its low affinity for glucose. This precocious induction of glucokinase was completely prevented by the presence of either actinomycin D or cycloheximide. Glucagon also inhibited its induction by insulin. Dexamethasone and testosterone, which alone had no inductive effect, strongly enhanced the induction by insulin. When hepatocytes of 14-day-old rats were cultured with 10^?7M insulin, 10^?6M dexamethasone and 10^?7M testosterone for 48 hr, their glucokinase activity increased to the non-induced level in hepatocytes of adult rats. Estrogen, thyroxine or growth hormone did not induce glucokinase precociously. Testosterone did not enhance induction of glucokinase by insulin in cultured hepatocytes of adult rats.     

Regulation of glutamine synthetase. V. Partial purification and properties of glutamine synthetase from Bacillus licheniformis

The glutamine synthetase of Bacillus licheniformis has been obtained at about 15% purity. Sucrose gradient centrifugation gave a molecular weight value of approximately 612,000. Both l- and d-glutamate can be utilized as substrates in the biosynthetic reaction, although the l isomer was five times more active. The requirement for adenosine triphosphate (ATP) can be partially replaced by guanosine or inosine triphosphates, but not by cytidine or uridine triphosphates. The Mn(++) was required for activity, and the requirement cannot be satisfied with Mg(++). Maximal activity of the biosynthetic reaction was observed when ATP and Mn(++) were present in equimolar amounts. An excess of either reactant gave less activity. However, other purine and pyrimidine nucleotides, when added in combination with ATP, can partially substitute for ATP in attaining the equimolar ratio of nucleotide to Mn(++). A complex of ATP and Mn(++) is the preferred form of substrate. The B. licheniformis enzyme catalyzes the glutamyl transfer reaction but at a much slower rate than the Escherichia coli glutamine synthetase. Either adenosine diphosphate (ADP) or ATP can activate the glutamotransferase, although ADP is more active.