Chloroplast and cytosolic glutamine synthetase are encoded by homologous nuclear genes which are differentially expressed in vivo

We have shown that the individual members of the plant gene family for glutamine synthetase (GS) are differentially expressed in vivo, and each encode distinct GS polypeptides which are targeted to different subcellular compartments (chloroplast or cytosol). At the polypeptide level, chloroplast GS (GS2) and cytosolic GS (GS1 and GSn) are distinct and show an organ-specific distribution. We have characterized full length cDNA clones encoding chloroplast or cytosolic GS of pea. In vitro translation products encoded by three different GS cDNA clones, correspond to the mature GS2, GS1, and GSn polypeptides present in vivo. pGS185 encodes a precursor to the chloroplast GS2 polypeptide as shown by in vitro chloroplast uptake experiments. The pGS185 translation product is imported into the chloroplast stroma and processed to a polypeptide which corresponds in size and charge to that of mature chloroplast stromal GS2 (44 kDa). The 49 amino terminal amino acids encoded by pGS185 are designated as a chloroplast transit peptide by functionality in vitro, and amino acid homology to other transit peptides. The cytosolic forms of GS (GS1 and GSn) are encoded by highly homologous but distinct mRNAs. pGS299 encodes the cytosolic GS1 polypeptide (38 kDa), while pGS341 (Tingey, S. V., Walker, E. L., and Coruzzi, G. M. (1987) EMBO. J. 6, 1-9) encodes a cytosolic GSn polypeptide (37 kDa). The homologous nuclear genes for chloroplast and cytosolic GS show different patterns of expression in vivo. GS2 expression in leaves is modulated by light, at the level of steady state mRNA and protein, while the expression of cytosolic GS is unaffected by light. The light-induced expression of GS2 is due at least in part to a phytochrome mediated response. Nucleotide sequence analysis indicates that chloroplast and cytosolic GS have evolved from a common ancestor and suggest a molecular mechanism for chloroplast evolution.     

Interaction of substrates with glutamine synthetase after limited proteolysis

Previous studies [Dautry-Varsat, A., Cohen, G. N., & Stadtman, E.R. (1979) J. Biol. Chem. 254, 3124-3128; Lei, M., Aebi, U., Heidner, E. G., & Eisenberg, D. (1979) J. Biol. Chem. 254, 3129-3134] have shown that Escherichia coli glutamine synthetase (GS) can be cleaved by proteases to form a limited digestion species called nicked glutamine synthetase (GS). The present study gives the amino acid sequence of the protease-sensitive region of glutamine synthetase. The present study also shows that GS is enzymatically active, but this activity is low compared to the activity of GS. The apparent Michaelis constant value for glutamate was 90 mM for GS as compared to 3 mM for GS, while the Michaelis constant values for ATP were similar for GS and GS*. The dissociation constant values for ATP, as determined by intrinsic fluorescence measurements, were similar for GS and GS*. Glutamate decreased the dissociation constant value of ATP for GS because of synergism between the two binding sites; glutamate did not decrease the dissociation constant value of ATP for GS*. The glutamate analogue methionine sulfoximine bound very tightly to GS and inactivated the enzyme in the presence of ATP. Methionine sulfoximine did not appear to bind to GS* and did not inactivate GS* in the presence of ATP. The ATP analogue 5'-[p-(fluorosulfonyl)benzoyl]adenosine bound to GS and inactivated the enzyme by forming a covalent bond with it. Glutamate accelerated this inactivation because of the synergism between the ATP and glutamate binding sites of GS.(ABSTRACT TRUNCATED AT 250 WORDS)     

Convenient preparation of [Orn(Tfa)2]- and [Orn(Boc)2, Orn(Tfa)2]gramicidin S, versatile unsymmetrically protected derivatives of gramicidin S.

Treatment of gramicidin S (GS) with trifluoroacetic anhydride afforded a derivative in which only one of the two Orn side chains was trifluoroacetylated in 72% yield, furnishing the first efficient method for the preparation of a monoprotected derivative of GS. The mono(Tfa) derivative [Orn(Tfa)2']GS was treated with di-tert-butyl dicarbonate to yield dually protected derivative [Orn(Boc)2,Orn(Tfa)2']GS from which another monoprotected derivative [Orn(Boc)2]GS was prepared in high yield. These unsymmetrically protected GS derivatives are versatile starting materials for the preparation of various other GS derivatives. As an example of application of the unsymmetrically protected derivatives, a dimeric GS derivative was prepared via a singly p-nitrobenzenesulfonyl(NBS)-activated derivative [Orn(Boc)2,Orn(NBS)2']GS.     

The role of cytosolic glutamine synthetase in wheat

The role of glutamine synthetase (GS; EC 6.3.1.2) was studied in wheat. GS isoforms were separated by HPLC and the two major leaf isoforms (cytosolic GS1 and chloroplastic GS2) were found to change in content and activity throughout plant development. GS2 dominated activity in green, rapidly photosynthesising leaves compared to GS1 which was a minor component. GS2 remained the main isoform in flag leaves at the early stages of grain filling but GS1 activity increased as the leaves aged. During senescence, there was a decrease in total GS activity which resulted largely from the loss of GS2 and thus GS 1 became a greater contributor to total GS activity. The changes in the activities of the GS isoforms were mirrored by the changes in GS proteins measured by western blotting. The changes in GS during plant development reflect major transitions in metabolism from a photosynthetic leaf (high GS2 activity) towards a senescencing leaf (relatively high GS1 activity). It is likely that, during leaf maturation and subsequently senescence, GS1 is central for the efficient reassimilation of ammonium released from catabolic reactions when photosynthesis has declined and remobilisation of nitrogen is occurring. Preliminary analysis of transgenic wheat lines with increased GS1 activity in leaves showed that they develop an enhanced capacity to accumulate nitrogen in the plant, mainly in the grain, and this is accompanied by increases in root and grain dry matter. The possibility that the manipulation of GS may provide a means of enhancing nitrogen use in wheat is discussed.     

Partial purification, characterization and properties of two isoforms of glutamine synthetase from Pennisetum glaucum L. leaves

Two isozymes of glutamine synthetase GS1 and GS2 were partially purified from Pennisetum glaucum leaves by ion-exchange and gel filtration chromatography and their kinetic and regulatory properties were studied using semisynthetase assay of GS. Mg2+ was the most effective cation for activity of both the isozymes; however, it could be efficiently replaced by Co2+. The pH optima for GS1 and GS2 were 7.0 and 8.0, respectively. GS1 exhibited maximum activity at 42 degrees C, with activation energy of 18 KJ mol(-1) and a Q10 of 3.0, whereas GS2 showed maximum activity at 50 degrees C, with activation energy of 40 KJ mol(-1) and Q10 of 2.25. GS1 was more thermostable than GS2. The Km value for Mg2+ of GS1 was 2-fold higher than GS2; however, these isozymes did not differ much in their affinity for other substrates. Alanine, serine and glycine lowered GS1 and GS2 activities, whereas cysteine enhanced their activities with a more pronounced effect on GS2. Serine inhibited the activity of both the isoforms in a competitive-manner, whereas alanine was a non-competitive inhibitor, with respect to glutamate. AMP and ADP were competitive inhibitor with respect to ATP for both the isozymes.     

Glutamine Synthetase Regulation, Adenylylation State, and Strain Specificity Analyzed by Polyacrylamide Gel Electrophoresis

We used polyacrylamide gel electrophoresis to examine the regulation and adenylylation states of glutamine synthetases (GSs) from Escherichia coli (GS(E)) and Klebsiella aerogenes (GS(K)). In gels containing sodium dodecyl sulfate (SDS), we found that GS(K) had a mobility which differed significantly from that of GS(E). In addition, for both GS(K) and GS(E), adenylylated subunits (GS(K)-adenosine 5'-monophosphate [AMP] and GS(E)-AMP) had lesser mobilities in SDS gels than did the corresponding non-adenylylated subunits. The order of mobilities was GS(K)-AMP < GS(K) < GS(E)-AMP < GS(E). We were able to detect these mobility differences with purified and partially purified preparations of GS, crude cell extracts, and whole cell lysates. SDS gel electrophoresis thus provided a means of estimating the adenylylation state and the quantity of GS present independent of enzymatic activity measurements and of determining the strain origin. Using SDS gels, we showed that: (i) the constitutively produced GS in strains carrying the glnA4 allele was mostly adenylylated, (ii) the GS-like polypeptide produced by strains carrying the glnA51 allele was indistinguishable from wild-type GS(K), and (iii) strains carrying the glnA10 allele contained no polypeptide having the mobility of GS(K) or GS(K)-AMP. Using native polyacrylamide gels, we detected the increased amount of dodecameric GS present in cells grown under nitrogen limitation compared with cells grown under conditions of nitrogen excess. In native gels there was neither a significant difference in the mobilities of adenylylated and non-adenylylated GSs nor a GS-like protein in cells carrying the glnA10 allele.     

Glutamine synthetase and glutamine synthetase-like protein from human brain: purification and comparative characterization

Glutamine synthetase (GS; EC 6.3.1.2), a key enzyme of glutamate metabolism, and another enzyme possessing high hydroxylamine-L-glutamine transferase activity comparable to that of GS and termed GS-like protein (GSLP) were purified from human brain concurrently. In two-dimensional electrophoresis, GS subunits migrate to at least six different positions (44 +/- 1 kDa, pl = 6. 4-6.7), whereas GSLP subunits migrate to at least four different positions (54 +/- 1 kDa, pl = 5.9-6.2). Dependences of enzymatic activity in the transferase reaction on concentrations of Mn(2+) and Mg(2+) for GS and GSLP are different. High immunological cross-reactivity between GS and GSLP was observed in ELISA. Nevertheless, antisera were raised to GS and GSLP, and a method was developed for the separate detection of GS and GSLP in brain extracts by enzyme-chemiluminescent amplified (ECL) immunoblotting. The distribution of GS and GSLP immunoreactivities between soluble protein and crude mitochondrial fractions indicates tighter association with the particulate fraction for GSLP than for GS. The results from activity measurements suggest that the hydroxylamine-L-glutamine transferase activity measured routinely in protein extracts from brain is the sum of GS and GSLP activities. Similarly, immunoreactivity evaluated by ELISA is a sum of immunoreactivities of GS and GSLP. The relative contributions of GS and GSLP to the total immunoreactivity can be evaluated by ECL-immunoblotting.     

Vascular bundle-specific localization of cytosolic glutamine synthetase in rice leaves

Tissue localizations of cytosolic glutamine synthetase (GS1; EC 6.3.1.2), chloroplastic GS (GS2), and ferredoxin-dependent glutamate synthase (Fd-GOGAT; EC 1.4.7.1) in rice (Oryza sativa L.) leaf blades were investigated using a tissue-print immunoblot method with specific antibodies. The cross-sections of mature and senescent leaf blades from middle and basal regions were used for tissue printing. The anti-GS1 antibody, raised against a synthetic 17-residue peptide corresponding to the deduced N-terminal amino acid sequence of rice GS1, cross-reacted specifically with native GS1 protein, but not with GS2 after transfer onto a nitrocellulose membrane. Tissue-print immunoblots showed that the GS1 protein was located in large and small vascular bundles in all regions of the leaf blade prepared from either stage of maturity. On the other hand, GS2 and Fd-GOGAT proteins were mainly located in mesophyll cells. The intensity of the developed color on the membrane for GS1 was similar between the two leaf ages, whereas that for GS2 and Fd-GOGAT decreased during senescence. The tissue-specific localization of GS1 suggests that this GS isoform is important in the synthesis of glutamine, which is a major form of nitrogen exported from the senescing leaf in rice plants.     

Developmentally Regulated Expression of the Gene Family for Cytosolic Glutamine Synthetase in Pisum sativum

In Pisum sativum, two classes of genes encode distinct isoforms of cytosolic glutamine synthetase (GS). The first class comprises two nearly identical or “twin” GS genes (GS341 and GS132), while the second comprises a single GS gene (GS299) distinct in both coding and noncoding regions from the “twin” GS genes. Gene-specific analyses were used to monitor the individual contribution of each gene for cytosolic GS during root nodule development and in cotyledons during germination, two contexts where large amounts of ammonia must be assimilated by GS for nitrogen transport. mRNAs corresponding to all three genes for cytosolic GS were shown to accumulate coordinately during a time course of nodule development. All the GS mRNAs also accumulate to wild-type levels in mutant nodules formed by a nifD⁻ strain of Rhizobium leguminosarum indicating that induced GS expression in pea root nodules does not depend on the production of ammonia. Distinct patterns of expression for the two classes of GS genes were observed in certain mutant root nodules and most dramatically in cotyledons of germinating seedlings. The different patterns of expression between the two classes of genes for cytosolic GS suggests that their distinct gene products may serve nonoverlapping functions during pea development.     

Prediction of Eyespot Severity on Winter Wheat or Winter Barley Inoculated with W-type or R-type Isolates of Pseudocercosporella herpotrichoides

In crops of winter wheat (1986—88) or winter barley (1987—88) inoculated with W-type or R-type isolates of Pseudocercosporella herpotrichoides and sown on different dates (1986) or at different seed rates (1987,1988) eyespot epidemics developed in different ways. Methods of measuring eyespot incidence/severity during crop growth were compared for their ability to predict eyespot severity at grain filling. Regressions were calculated for eyespot severity score at GS 71 on earlier measurements, either at GS 30/31 (11 methods) or from GS 22 to GS 65 (3 methods). Based on measurements at GS 30/31, all the methods predicted eyespot severity at GS 71 well in plots of winter barley inoculated with W-type isolates (r, 0.83—0.97) but the accuracy of predictions in plots inoculated with R-type isolates was very variable (r, 0.09—0.71). Predictions for 1987 and 1988 were less accurate in wheat than in W-type plots of barley, but did not differ between W-type and R-type plots (r, 0.70—0.89). When the wheat data for 1986 were also included predictions were less accurate, especially in R-type plots (r, 0—0.59). Generally, it was easier to predict eyespot severity at GS 71 in W-type than in R-type plots, especially in barley and in wheat before GS 37/39. Predictions of eyespot severity at GS 71 based on measurements before GS 25 were inaccurate for both wheat and barley. After GS 25 the accuracy of the prediction was generally good in W-type plots and did not improve greatly except in wheat after GS 59. However, there was a steady improvement in the accuracy of the prediction in R-type plots of barley from GS 24 to GS 53. Assessments of eyespot incidence on stems predicted eyespot severity at GS 71 more accurately than assessments on leaf sheaths on wheat after GS 37/39, but were not as good on barley until GS 53.     

Skeletal muscle glycogen synthase subcellular localization: effects of insulin and PPAR-alpha agonist (K-111) administration in rhesus monkeys

Insulin covalently and allosterically regulates glycogen synthase (GS) and may also cause the translocation of GS from glycogen-poor to glycogen-rich locations. We examined the possible role of subcellular localization of GS and glycogen in insulin activation of GS in skeletal muscle of six obese monkeys and determined whether 1) insulin stimulation during a hyperinsulinemic euglycemic clamp and/or peroxisome proliferator-activated receptor (PPAR)-alpha agonist treatment (K-111, 3 mg.kg(-1).day(-1); Kowa) induced translocation of GS and 2) translocation of GS was associated with insulin activation of GS. GS and glycogen were present in all fractions obtained by differential centrifugation, except for the cytosolic fraction, under both basal and insulin-stimulated conditions. We found no evidence for translocation of GS by insulin. GS total (GST) activity was strongly associated with glycogen content (r = 0.70, P < 0.001). Six weeks of treatment with K-111 increased GST activity in all fractions, except the cytosolic fraction, and mean GST activity, GS independent activity, and glycogen content were significantly higher in the insulin-stimulated samples compared with basal samples, effects not seen with vehicle. The increase in GST activity was strongly related to the increase in glycogen content during the hyperinsulinemic euglycemic clamp after K-111 administration (r = 0.74, P < 0.001). Neither GS protein expression nor GS gene expression was affected by insulin or by K-111 treatment. We conclude that 1) in vivo insulin does not cause translocation of GS from a glycogen-poor to a glycogen-rich location in primate skeletal muscle and 2) the mechanism of action of K-111 to improve insulin sensitivity includes an increase in GST activity without an increase in GS gene or protein expression.     

Phosphorylation of the recombinant spliced variants of the alpha-sub-unit of the stimulatory guanine-nucleotide binding regulatory protein (Gs) by the catalytic sub-unit of protein kinase A.

Both GS alpha-1 and GS alpha-4 were phosphorylated by the purified catalytic sub-unit of protein kinase A. Phosphate incorporation into 220 pmol and 190 pmol of GS alpha-4 and GS alpha-1 after a 1 hour incubation with kinase was 14 pmol and 10 pmol, respectively. These low levels of phosphorylation are due to the thermal lability of purified recombinant GS alpha. However, the phosphorylation was inhibited by guanine nucleotides (GDP-beta-S, GppNHp and GTP) and is, therefore, a specific event. We suggest that, as for GS alpha phosphorylation by protein kinase C (Pyne et al., 1992), the guanine nucleotide-free form of GS alpha is the most likely substrate. Guanine-nucleotides reduce the lifetime and, therefore availability for phosphorylation, of guanine-nucleotide free GS alpha. GS alpha phosphorylation by protein kinase A in vitro provides preliminary evidence that a similar phosphorylation of GS alpha may be an important regulatory event in cells.     

Indicators for green spaces in contrasting urban settings

Urban green spaces (GS) are essential for the well-being of the population. Several works have shown a positive correlation between the amount of GS and the household incomes in both developed and developing countries. Thus, the higher the incomes, the larger the total area covered by GS, the better the quality of these spaces, the higher the amount of private GS. Public policies seek to correct this inequality, but existing indicators, especially the amount of GS per inhabitant, do not provide enough information for effective decision-making. Our aim was to provide tools to evaluate and plan better the location and quality of GS in complex urban areas. For this we applied a set of indicators for GS at two spatial scales city-level and local-level, in order to disclose existing inequalities. The indicators considered (i) the total area of GS in relation to population and urban context, (ii) the quality of GS based on its size, shape and vegetation cover, and (iii) the spatial distribution and accessibility of GS. The proposed indicators were tested in three municipalities, belonging to the Metropolitan Area of Santiago (Chile), with different household incomes. The indicators showed large differences in terms of quantity of GS per inhabitant, vegetation cover and accessibility. The GS proved to be an effective strategy to reduce areas that lack vegetation cover. The sustainability assessments must consider how the diversity of structural attributes of GS has an impact on the well-being of urban inhabitants.     

Overexpression of a soybean cytosolic glutamine synthetase gene linked to organ-specific promoters in pea plants grown in different concentrations of nitrate

A glutamine synthetase gene ( GS15) coding for soybean cytosolic glutamine synthetase (GS1) fused to a constitutive promoter (CaMV 35S), a putative nodule-specific promoter (LBC(3)) and a putative root-specific promoter (rolD) was transformed into Pisum sativum L. cv. Greenfeast. Four lines with single copies of GS15 (one 35S-GS15 line, one LBC (3) -GS15 line, and two rolD-GS15 lines) were tested for the expression of GS15, levels of GS1, GS activity, N accumulation, N(2) fixation, and plant growth at different levels of nitrate. Enhanced levels of GS1 were detected in leaves of three transformed lines (the 35S-GS15 and rolD-GS15 transformants), in nodules of three lines (the LBC (3) -GS15 and rolD-GS15 transformants), and in roots of all four transformants. Despite increased levels of GS1 in leaves and nodules, there were no differences in GS activity in these tissues or in whole-plant N content, N(2) fixation, or biomass accumulation among all the transgenic lines and the wild-type control. However, the rolD-GS15 transformants, which displayed the highest levels of GS1 in the roots of all the transformants, had significantly higher GS activity in roots than the wild type. In one of the rolD-GS15 transformed lines (Line 8), increased root GS activity resulted in a lower N content and biomass accumulation, supporting the findings of earlier studies with Lotus japonicus (Limami et al. 1999 ). However, N content and biomass accumulation was not negatively affected in the other rolD-GS15 transformant (Line 9) and, in fact, these parameters were positively affected in the 0.1 mM treatment. These findings indicate that overexpression of GS15 in various tissues of pea does not consistently result in increases in GS activity. The current study also indicates that the increase in root GS activity is not always consistent with decreases in plant N and biomass accumulation and that further investigation of the relationship between root GS activity and growth responses is warranted.     

Involvement of the product of the glnF gene in the autogenous regulation of glutamine synthetase formation in Klebsiella aerogenes.

Mutations in a site, glnF, linked by P1-mediated transduction of argG on the chromosome of Klebsiella aerogenes, result in a requirement for glutamine. Mutants in this gene have in all media a level of glutamine synthetase (GS) corresponding to the level found in the wild-type strain grown in the medium producing the strongest repression of GS. The adenylylation and deadenylylation of GS in glnF mutants is normal. The glutamine requirement of glnF mutants could be suppressed by mutations in the structural gene for GS, glnA. These mutations result in altered regulation of GS synthesis, regardless of the presence or absence of the glnF mutation (GlnR phenotype). In GlnR mutants the GS level is higher than in the wild-type strain when the cells are cultured in strongly repressing medium, but lower than in the wild-type strain when cells are cultured in a derepressing medium. Heterozygous merodiploids carrying a normal glnA gene as well as a glnA gene responsible for the GlnR phenotype behave in every respect like merodiploids carrying two normal glnA genes. These results confirm autogenous regulation of GS synthesis and indicate that GS is both a repressor and an activator of GS synthesis. The mutation in glnA responsible for the GLnR phenotype has apparently resulted in the formation of a GS that is incompetent both as repressor and as activator of GS synthesis. According to this hypothesis, the product of the glnF gene is necessary for activation of the glnA gene by GS.     

Functional expression of two pine glutamine synthetase genes in bacteria reveals that they encode cytosolic holoenzymes with different molecular and catalytic properties

Two glutamine synthetase isogenes, GS1a and GS1b, isolated from pine have been functionally expressed in E. coli and the characteristics of individual gene products compared. When bacteria were grown at 37 degrees C most pine GS1 protein was found in the insoluble fraction but lowering of the expression temperature increased yield of both GS1 polypeptide and activity in the soluble fraction. High levels of functionally active GS1a (309 + or - 35 nkat mg(-1)) and GS1b (1,166 + or - 65 nkat mg(-1)) enzymes were obtained by decreasing the expression temperature to 10 degrees C. Purification and characterization of recombinant products showed that pine GS1 polypeptides are assembled in octameric GS holoenzymes showing structural and kinetic differences. The results are discussed with regard to the specific localization of GS1a and GS1b in different cell types of pine seedlings. The isoform GS1a may control the assimilation of the high levels of ammonium released in photosynthetic tissues, whereas GS1b enzyme could mitigate oscillations in glutamate availability providing a constant flux of glutamine for nitrogen transport in vascular cells.     

Role of Light in the Appearance of Glutamine Synthetase in Leaves of Pennisetum glaucum

Leaves of Pennisetum [Pennisetum glaucum (L) HHB 67] seedlings contained two isozymes of glutamine synthetase (GS, EC 6.3.1.2): cytosolic GS1 and chloroplastic GS2. Leaves of seedlings grown in light for seven days contained about twofold higher GS activity than etiolated leaves. In both light and dark grown seedlings, total GS, GS1 and GS2 activity declined with plant age with more pronounced effect in leaves of etiolated seedlings, and GS2 declined at a much faster rate than GS1. Exposure of etiolated seedlings to light markedly enhanced GS1 and GS2 activity. This increase in activity was not affected by cycloheximide, precluding light dependent de novo synthesis of the enzyme. Treatment of etiolated seedlings with photosynthetic inhibitor, dichlorophenyl dimethyl urea (DCMU) inhibited light dependent appearance of GS. Exogenous supply of sucrose to dark grown seedlings greatly increased the GS activity in dark. These results suggest that light-mediated stimulation in activity of GS in Pennisetum leaves is dependent on photosynthetic reaction.