Genetic and physiological analysis of germination efficiency in maize in relation to nitrogen metabolism reveals the importance of cytosolic glutamine synthetase

We have developed an approach combining physiology and quantitative genetics to enhance our understanding of nitrogen (N) metabolism during kernel germination. The physiological study highlighted the central role of glutamine (Gln) synthetase (GS) and Gln synthesis during this developmental process because a concomitant increase of both the enzyme activity and the amino acid content was observed. This result suggests that Gln is acting either as a sink for ammonium released during both storage protein degradation and amino acid deamination or as a source for amino acid de novo synthesis by transamination. In the two parental lines used for the quantitative genetics approach, we found that the increase in Gln occurred earlier in Io compared with F(2), a result consistent with its faster germinating capacity. The genetic study was carried out on 140 F6 recombinant inbred lines derived from the cross between F(2) and Io. Quantitative trait locus mapping identified three quantitative trait loci (QTLs) related to germination trait (T50, time at which 50% of the kernels germinated) that explain 18.2% of the phenotypic variance; three QTLs related to a trait linked to germination performance, kernel size/weight (thousand kernels weight), that explain 17% of the phenotypic variance; two QTLs related to GS activity at early stages of germination that explain 17.7% of the phenotypic variance; and one QTL related to GS activity at late stages of germination that explains 7.3% of the phenotypic variance. Coincidences of QTL for germination efficiency and its components with genes encoding cytosolic GS (GS1) and the corresponding enzyme activity were detected, confirming the important role of the enzyme during the germination process. A triple colocalization on chromosome 4 between gln3 (a structural gene encoding GS1) and a QTL for GS activity and T50 was found; whereas on chromosome 5, a QTL for GS activity and thousand kernels weight colocalized with gln4, another structural gene encoding GS1. This observation suggests that for each gene, the corresponding enzyme activity is of major importance for germination efficiency either through the size of the grain or through its faster germinating capacity. Consistent with the possible nonoverlapping function of the two GS1 genes, we found that in the parental line Io, the expression of Gln3 was transiently enhanced during the first hours of germination, whereas that of gln4 was constitutive.     

Contribution of Gln9 and Phe80 to substrate binding in ribonuclease MC1 from bitter gourd seeds.

Ribonuclease MC1 (RNase MC1) isolated from bitter gourd (Momordica charantia) seeds specifically cleaves phosphodiester bonds on the 5'-side of uridine. The crystal structures of RNase MC1 in complex with 2'-UMP or 3'-UMP reveal that Gln9, Asn71, Leu73, and Phe80 are involved in uridine binding by hydrogen bonding and hydrophobic interactions [Suzuki et al. (2000) Biochem. Biophys. Res. Commun. 275, 572-576]. To evaluate the contribution of Gln9 and Phe80 to uridine binding, Gln9 was replaced with Ala, Phe, Glu, or His, and Phe80 with Ala by site-directed mutagenesis. The kinetic properties of the resulting mutant enzymes were characterized using cytidylyl-3',5'-uridine (CpU) as a substrate. The mutant Q9A exhibited a 3.7-fold increased K(m) and 27.6-fold decreased k(cat), while three other mutations, Q9F, Q9E, and Q9H, predominantly affected the k(cat) value. Replacing Phe80 with Ala drastically reduced the catalytic efficiency (k(cat)/K(m)) with a minimum K(m) value equal to 8 mM. It was further found that the hydrolytic activities of the mutants toward cytidine-2',3'-cyclic monophosphate (cCMP) were reduced. These results demonstrate that Gln9 and Phe80 play essential roles not only in uridine binding but also in hydrolytic activity. Moreover, we produced double Ala substituted mutants at Gln9, Asn71, Leu73, and Phe80, and compared their kinetic properties with those of the corresponding single mutants. The results suggest that these four residues may contribute to uridine binding in a mutually independent manner.     

Gln49 and Ser174 residues play critical roles in determining the catalytic efficiencies of plant glutamine synthetase

Two essential residues playing critical roles in determining the substrate specificities of cytosolic glutamine synthetase (GS1) have been identified from the alignment of high-affinity (GLN1;1 and GLN1;4) and low-affinity (GLN1;2 and GLN1;3) GS1 isoenzymes in Arabidopsis, and confirmed by site-directed mutagenesis. The results indicated that either K49Q or A174S mutation is sufficient to increase the catalytic efficiencies of GLN1;3 by decreasing its Km values for ammonium. In contrast, replacement of Gln49 and Ser174 by lysine and alanine, respectively, was detrimental to glutamine synthetic activities in GLN1;4. The results suggested that Gln49 and Ser174 in the high-affinity GS1 isoenzymes are interchangeable with Lys49 and Ala174 in the low-affinity variants at the corresponding positions.     

The cytosolic glutamine synthetase GLN1;2 plays a role in the control of plant growth and ammonium homeostasis in Arabidopsis rosettes when nitrate supply is not limiting

Glutamine synthetase (EC 6.3.1.2) is a key enzyme of ammonium assimilation and recycling in plants where it catalyses the synthesis of glutamine from ammonium and glutamate. In Arabidopsis, five GLN1 genes encode GS1 isoforms. GLN1;2 is the most highly expressed in leaves and is over-expressed in roots by ammonium supply and in rosettes by ample nitrate supply compared with limiting nitrate supply. It is shown here that the GLN1;2 promoter is mainly active in the minor veins of leaves and flowers and, to a lower extent, in the parenchyma of mature leaves. Cytoimmunochemistry reveals that the GLN1;2 protein is present in the companion cells. The role of GLN1;2 was determined by examining the physiology of gln1;2 knockout mutants. Mutants displayed lower glutamine synthetase activity, higher ammonium concentration, and reduced rosette biomass compared with the wild type (WT) under ample nitrate supply only. No difference between mutant and WT can be detected under limiting nitrate conditions. Despite total amino acid concentration was increased in the old leaves of mutants at high nitrate, no significant difference in nitrogen remobilization can be detected using (15)N tracing. Growing plants in vitro with ammonium or nitrate as the sole nitrogen source allowed us to confirm that GLN1;2 is induced by ammonium in roots and to observe that gln1;2 mutants displayed, under such conditions, longer root hair and smaller rosette phenotypes in ammonium. Altogether the results suggest that GLN1;2 is essential for nitrogen assimilation under ample nitrate supply and for ammonium detoxification.     

Isolation of photorespiratory mutants from Lotus japonicus deficient in glutamine synthetase

A mutagenesis programme using ethyl methanesulphonate (EMS) was carried out on Lotus japonicus (Regel) Larsen cv. Gifu in order to isolate photorespiratory mutants in this model legume. These mutants were able to grow in a CO₂-enriched atmosphere [0.7% (v/v) CO₂] but showed stress symptoms when transferred to air. Among them, three mutants displayed low levels of glutamine synthetase (GS; EC 6.3.1.2) activity in leaves. The mutants accumulated ammonium in leaves upon transfer from 0.7% (v/v) CO₂ to air. F₁ plants of back crosses to wild type were viable in air and F₂ populations segregated 3 : 1 (viable in air : air-sensitive) indicative of a single Mendelian recessive trait. Complementation tests showed that the three mutants obtained were allelic. Chromatography on DEAE-Sephacel used to separate the cytosolic and plastidic GS isoenzymes together with immunological data showed that: (1) mutants were specifically affected in the plastidic GS isoform, and (2) in L. japonicus the plastidic GS isoform eluted at lower ionic strength than the cytosolic isoform, contrary to what happens in most plants. The plastidic GS isoform present in roots of wild type L. japonicus was also absent in roots of the mutants, indicating that this plastidic isoform from roots was encoded by the same gene than the GS isoform expressed in leaf tissue. Viability of mutant plants in high-CO₂ conditions indicates that plastidic GS is not essentially required for primary ammonium assimilation. Nevertheless, mutant plants did not grow as well as wild type plants in high-CO₂ conditions.     

GLN3 encodes a global regulator of nitrogen metabolism and virulence of C. albicans.

The function of GLN3, a GATA factor encoding gene, in nitrogen metabolism of Candida albicans was examined. GLN3 null mutants had reduced growth rates on multiple nitrogen sources. More severe growth defects were observed in mutants lacking both GLN3 and GAT1, a second GATA factor gene. GLN3 was an activator of two genes involved in ammonium assimilation, GDH3, encoding NADP-dependent glutamate dehydrogenase, and MEP2, which encodes an ammonium permease. GAT1 contributed to MEP2 expression, but not that of GDH3. A putative general amino acid permease gene, GAP2, was also activated by both GLN3 and GAT1, but activation by GLN3 was nitrogen source dependent. GLN3 was constitutively expressed, but GAT1 expression varied with nitrogen source and was reduced 2- to 3-fold in gln3 mutants. Both gln3 and gat1 mutants exhibited reduced sensitivity to rapamycin, suggesting they function downstream of TOR kinase. Hyphae formation by gln3 and gat1 mutants differed in relation to nitrogen source. The gln3 mutants formed hyphae on several nitrogen sources, but not ammonium or urea, suggesting a defect in ammonium assimilation. Virulence of gln3 mutants was reduced in a murine model of disseminated disease. We conclude that GLN3 has a broad role in nitrogen metabolism, partially overlapping, but distinct from that of GAT1, and that its function is important for the ability of C. albicans to survive within the host environment.     

GLN3 encodes a global regulator of nitrogen metabolism and virulence of C. albicans

The function of GLN3, a GATA factor encoding gene, in nitrogen metabolism of Candida albicans was examined. GLN3 null mutants had reduced growth rates on multiple nitrogen sources. More severe growth defects were observed in mutants lacking both GLN3 and GAT1, a second GATA factor gene. GLN3 was an activator of two genes involved in ammonium assimilation, GDH3, encoding NADP-dependent glutamate dehydrogenase, and MEP2, which encodes an ammonium permease. GAT1 contributed to MEP2 expression, but not that of GDH3. A putative general amino acid permease gene, GAP2, was also activated by both GLN3 and GAT1, but activation by GLN3 was nitrogen source dependent. GLN3 was constitutively expressed, but GAT1 expression varied with nitrogen source and was reduced 2- to 3-fold in gln3 mutants. Both gln3 and gat1 mutants exhibited reduced sensitivity to rapamycin, suggesting they function downstream of TOR kinase. Hyphae formation by gln3 and gat1 mutants differed in relation to nitrogen source. The gln3 mutants formed hyphae on several nitrogen sources, but not ammonium or urea, suggesting a defect in ammonium assimilation. Virulence of gln3 mutants was reduced in a murine model of disseminated disease. We conclude that GLN3 has a broad role in nitrogen metabolism, partially overlapping, but distinct from that of GAT1, and that its function is important for the ability of C. albicans to survive within the host environment.     

酰胺态氮瞬间调节荚膜红假单孢菌光合固氮活性的GS传感机制

天门冬酰胺(Asn)和谷氨酰胺(Gln)对荚膜红假单孢菌固氮酶活性抑制,在表观上类似于氨关闭效应,这种抑制效应由GS参与,相似于氨抑的传感机制。中断Gln代谢的6-diazo-5-oxo-L-norleucine(DON)存在时,氨抑的持续时间延长,与此相类似,Gln抑制加剧,这可能归之于Gln的积累。但是,Gln抑制被methionine sulfoximine(MSX,GS的抑制剂)消除,消除时MSX对Gln的浓度比值约为0.2,与氨抑消除所需的MSX对氨的浓度比值相当。此外,MSX消除氨抑不为DON拮抗,表明Gln抑制固氮酶活性由GS传感。然而,不能抑制GS转谷酰基活性的methionine suffone(MSF,谷氨酸的类似物)却与MSX相同,能消除Gln和氨对固氮活性的抑制。上述观察结果也可延伸至Asn的关闭固氮酶活性效应。     

Post-translational regulation of cytosolic glutamine synthetase of Medicago truncatula

It was reported recently that the plastid-located glutamine synthetase (GS2) from Medicago truncatula is regulated by phosphorylation catalysed by a calcium-dependent protein kinase and 14-3-3 interaction. Here it is shown that the two cytosolic GS isoenzymes, GS1a and GS1b, are also regulated by phosphorylation but, in contrast to GS2, GS1 phosphorylation is catalysed by calcium-independent kinase(s) and the phosphorylated enzymes fail to interact with 14-3-3s. Phosphorylation of GS1a occurs at more than one residue and was found to increase the affinity of the enzyme for the substrate glutamate. In vitro phosphorylation assays were used to compare the activity of GS kinase, present in different plant organs, against the three M. truncatula GS isoenzymes. All three GS proteins were phosphorylated by kinases present in leaves, roots, and nodules, but to different extents, suggesting a differential regulation under different metabolic contexts. Cytosolic GS phosphorylation was found to be affected by light in leaves and by active nitrogen fixation in root nodules, whereas GS2 phosphorylation was unaffected by these conditions. Some putative GS-binding phosphoproteins were identified showing both isoenzyme and organ specificity. Two phosphoproteins of 70 and 72 kDa were specifically bound to the cytosolic GS isoenzymes. Interestingly, phosphorylation of these proteins was also influenced by the nitrogen-fixing status of the nodule, suggesting that their phosphorylation and/or binding to GS are related to nitrogen fixation. Taken together, the results presented indicate that GS phosphorylation is modulated by nitrogen fixation in root nodules; these findings open up new possibilities to explore the involvement of this post-translational mechanism in nodule functioning.     

Glutamine synthetase/glutamate synthase ammonium-assimilating pathway in Schizosaccharomyces pombe

Kinetic parameters of glutamine synthetase (GS) and glutamate synthase (glutamineoxoglutarate aminotransferase) (GOGAT) activities, including initial velocity, pH, and temperature optima, as well as K _m values, were estimated in Schizosaccharomyces pombe crude cell-free extracts. Five glutamine auxotrophic mutants of S. pombe were isolated following MNNG treatment. These were designated gln1-1,2,3,4,5, and their growth could be repaired only by glutamine. Mutants gln1-1,2,3,4,5 were found to lack GS activity, but retained wild-type levels of NADP-glutamate dehydrogenase (GDH), NAD-GDH, and GOGAT. One further glutamine auxotrophic mutant, gln1-6, was isolated and found to lack both GS and GOGAT but retained wild-type levels of NADP-GDH and NAD-GDH activities. Fortuitously, this isolate was found to harbor an unlinked second mutation (designated gog1-1), which resulted in complete loss of GOGAT activity but retained wild-type GS activity. The growth phenotype of mutant gog1-1 (in the absence of the gln1-6 mutation) was found to be indistinguishable from the wild type on various nitrogen sources, including ammonium as a sole nitrogen source. Double-mutant strains containing gog1-1 and gdh1-1 or gdh2-1 (mutations that result specifically in the abolition of NADP-GDH activity) result in a complete lack of growth on ammonium as sole nitrogen source in contrast to gdh or gog mutants alone.     

Scanning of key residues in antibody binding sites by two saturation-mutagenesis approaches.

The complementarity-determining region 3 of the heavy chain (CDRH3) generally contributes the most to antibody-antigen binding. His101H in CDRH3 of the antibody Se155-4, which is specific for a trisaccharide epitope of Salmonella serotype B O-antigen, was mutated systematically into all nineteen other amino acids by a double mutation approach. Enzyme immunoassay (EIA) and affinity chromatography showed that the Asn, Gln, Gly and Ser mutants exhibited moderate to strong activity. Some mutants, such as Thr and Pro, had weak binding activity, while the acidic and hydrophobic amino acid substitutions resulted in complete loss of activity. A second mutation approach which randomly changed a selected residue into all other nineteen amino acids, while precluding wild-type transformants, is also described.     

Glutamine synthetase in the phloem plays a major role in controlling proline production

To inhibit expression specifically in the phloem, a 274-bp fragment of a cDNA (Gln1-5) encoding cytosolic glutamine synthetase (GS1) from tobacco was placed in the antisense orientation downstream of the cytosolic Cu/Zn superoxide dismutase promoter of Nicotiana plumbaginifolia. After Agrobacterium-mediated transformation, two transgenic N. tabacum lines exhibiting reduced levels of GS1 mRNA and GS activity in midribs, stems, and roots were obtained. Immunogold labeling experiments allowed us to verify that the GS protein content was markedly decreased in the phloem companion cells of transformed plants. Moreover, a general decrease in proline content in the transgenic plants in comparison with wild-type tobacco was observed when plants were forced to assimilate large amounts of ammonium. In contrast, no major changes in the concentration of amino acids used for nitrogen transport were apparent. A (15)NH(4)(+)-labeling kinetic over a 48-hr period confirmed that in leaves of transgenic plants, the decrease in proline production was directly related to glutamine availability. After 2 weeks of salt treatment, the transgenic plants had a pronounced stress phenotype, consisting of wilting and bleaching in the older leaves. We conclude that GS in the phloem plays a major role in regulating proline production consistent with the function of proline as a nitrogen source and as a key metabolite synthesized in response to water stress.