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Induction of nitrate reductase, nitrite reductase, and glutamine synthetase isoforms in sunflower cotyledons as affected by nitrate, light, and plastid integrity

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Summary

We investigated the inducibility of nitrate reductase (NR; EC 1.6.6.1), nitrite reductase (NiR; EC 1.7.7.1), and glutamine synthetase (GS; EC 6.3.1.2) isoforms in cotyledons of 7-day-old seedlings of sunflower (Helianthus annuus L.) in relation to light, nitrogen source (NO 3 , NO 2 or NH +4 ), and the involvement of plastids. Nitrate was absolutely (and specifically) required for NR induction, and stimulated more effectively than NO 2 or NH +4 the synthesis of NiR and chloroplastic GS (GS2) over the constitutive levels present in N-free-grown seedlings. In vivo inhibition of NR activity by tungsten application to seedlings and measurements of tissue NO 3 concentration indicate that NO 3 -dependent enzyme induction is elicited by NO 3 per se and not by a product of its assimilatory reduction, e.g., NO 2 or NH +4 . In the presence of NO 3 , light remarkably enhanced the appearance of NR, NiR, and GS2, while the activity of the cytosolic GS isoform (GS1) was adversely affected. Cycloheximide suppressed much more efficiently than chloramphenicol the light- and NO 3 -dependent increase of GS2 activity, indicating that sunflower chloroplastic GS is synthesized on cytoplasmic 80S ribosomes. When the plastids were damaged by photooxidation in cotyledons made carotenoid-free by application of norflurazon, the positive action of light and NO 3 on the appearance of NR, NiR, and GS2 isoform was greatly abolished. Therefore, it is suggested that intact chloroplasts are required for the inductive effect of light and NO 3 and/or for the accumulation of newly formed enzymes in the organelle.

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Abbreviations

CAP:

chloramphenicol

CHX:

cycloheximide

GS:

glutamine synthetase

GS1 :

cytosolic GS

GS2 :

plastidic (chloroplastic) GS

NF:

norflurazon

NiR:

nitrite reductase

NR:

nitrate reductase

References

  • Agüera E, de la Haba P, Maldonado JM (1987) In vitro stabilization and tissue distribution of nitrogen-assimilating enzymes in sunflower. J Plant Physiol 128: 443–449

    Google Scholar 

  • Appenroth K-J, Oelmüller R (1995) Regulation of transcript level and nitrite reductase activity by phytochrome and nitrate in tarions ofSpirodela polyrhiza. Physiol Plant 93: 272–278

    Google Scholar 

  • Aslam M, Rosichan JL, Huffaker RC (1987) Comparative induction of nitrate reductase by nitrate and nitrite in barley leaves. Plant Physiol 83: 579–584

    PubMed  Google Scholar 

  • Back E, Burkhart W, Moyer M, Privalle L, Rothstein S (1988) Isolation of cDNA clones coding for spinach nitrite reductase: complete sequence and nitrate induction. Mol Gen Genet 212: 20–26

    PubMed  Google Scholar 

  • Bajracharya D, Bergfeld R, Hatzfeld W-D, Klein S, Schopfer P (1987) Regulatory involvement of plastids in the development of peroxisomal enzymes in cotyledons of mustard (Sinapisalba L.) seedlings. J Plant Physiol 126: 421–436

    Google Scholar 

  • Becker TW, Caboche M, Carrayol E, Hirel B (1992) Nucleotide sequence of a tobacco cDNA encoding plastidic glutamine synthetase and light inducibility, organ specificity and diurnal rhythmicity in the expression of the corresponding genes of tobacco and tomato. Plant Mol Biol 19: 367–379

    PubMed  Google Scholar 

  • Bishop NI, Humbeck K, Römer S, Senger H (1989) The mode of adaptation of the photosynthetic apparatus of a pigment mutant ofScenedesmus without light harvesting complex to different light intensities. J Plant Physiol 135: 144–149

    Google Scholar 

  • Cabello P, de la Haba P, Maldonado JM (1991) Isoforms of glutamine synthetase in cotyledons, leaves and roots of sunflower plants. J Plant Physiol 137: 378–380

    Google Scholar 

  • Cataldo DA, Haroon M, Schrader LE, Youngs VL (1975) Rapid colorimetric determination of nitrate in plant tissue by nitration of salicylic acid. Commun Soil Sci Plant Anal 6: 71–80

    Google Scholar 

  • Dalling MJ, Hucklesby DP, Hageman RH (1973) A comparison of nitrite reductase enzymes from green leaves, scutella and roots of corn (Zea mays L.). Plant Physiol 51: 481–484

    Google Scholar 

  • De la Haba P, Agüera E, Maldonado JM (1988) Development of nitrogen-assimilating enzymes in sunflower cotyledons during germination as affected by the exogenous nitrogen source. Planta 173: 52–57

    Google Scholar 

  • Echevarría C, Mauriño SG, Maldonado JM (1984) Reversible inactivation of maize leaf nitrate reductase. Phytochemistry 23: 2155–2158

    Google Scholar 

  • Edwards JW, Coruzzi GM (1989) Photorespiration and light act in concert to regulate the expression of the nuclear gene for chloroplast glutamine synthetase. Plant Cell 1: 241–248

    PubMed  Google Scholar 

  • Goodwin TW, Britton G (1988) Distribution and analysis of carotenoids. In: Goodwin TW (ed) Plant pigments. Academic Press, London, pp 61–132

    Google Scholar 

  • Harel E, Lea PJ, Miflin BJ (1977) The localization of enzymes of nitrogen assimilation in maize leaves and their activities during greening. Planta 134: 195–200

    Google Scholar 

  • Hewitt EJ (1966) Sand and water culture methods used in the study of plant nutrition. Commonwealth Bureau of Horticultural and Plantation Crops, Farnham Royal, East Mailing Tech Commun no 22

  • Hirel B, Perrot-Rechenmann C, Suzuki A, Vidal J, Gadal P (1982a) Glutamine synthetase in spinach leaves: immunological studies and immunocytochemical localization. Plant Physiol 69: 983–987

    Google Scholar 

  • —, Vidal J, Gadal P (1982b) Evidence for a cytosolic-dependent light induction of chloroplastic glutamine synthetase during greening of etiolated rice leaves. Planta 155: 17–23

    Google Scholar 

  • Kleinhofs A, Warner RL (1990) Advances in nitrate assimilation. In: Miflin BJ, Lea PJ (eds) The biochemistry of plants, vol 16. Academic Press, San Diego, pp 89–120

    Google Scholar 

  • Lahners K, Kramer V, Back E, Privalle L, Rothstein S (1988) Molecular cloning of complementary DNA encoding maize nitrite reductase: molecular analysis and nitrate induction. Plant Physiol 88: 741–746

    Google Scholar 

  • Lam H-M, Coschigano KT, Oliveira IC, Melo-Oliveira R, Coruzzi GM (1996) The molecular-genetics of nitrogen assimilation into amino acids in higher plants. Annu Rev Plant Physiol Plant Mol Biol 47: 569–593

    PubMed  Google Scholar 

  • Lea PJ, Robinson SA, Stewart GR (1990) The enzymology and metabolism of glutamine, glutamate, and asparagine. In: Miflin BJ, Lea PJ (eds) The biochemistry of plants, vol 16. Academic Press, San Diego, pp 121–159

    Google Scholar 

  • Li X-Z, Oaks A (1995) The effect of light on the nitrate and nitrite reductases inZea mays. Plant Sci 109: 115–118

    Google Scholar 

  • McNally SF, Hirel B, Gadal P, Mann AF, Stewart GR (1983) Glutamine synthetase of higher plants: evidence for a specific isoform content related to their physiological role and their compartmentation within the leaf. Plant Physiol 72: 22–25

    Google Scholar 

  • Migge A, Carrayol E, Kunz C, Hirel B, Fock H, Becker T (1997) The expression of the tobacco genes encoding plastidic glutamine synthetase or ferredoxin-dependent glutamate synthase does not depend on the rate of nitrate reduction, and is unaffected by suppression of photorespiration. J Exp Bot 48: 1175–1184

    Google Scholar 

  • Neininger A, Kronenberger J, Mohr H (1992) Coaction of light, nitrate and a plastidic factor in controlling nitrite-reductase gene expression in tobacco. Planta 187: 381–387

    Google Scholar 

  • Notton BA, Hewitt EJ (1971) The role of tungsten in the inhibition of nitrate reductase activity in spinach (Spinaceaoleracea L.) leaves. Biochem Biophys Res Commun 44: 702–710

    PubMed  Google Scholar 

  • Oelmüller R (1989) Photooxidative destruction of chloroplasts and its effect on nuclear gene expression and extraplastidic enzyme levels. Photochem Photobiol 49: 229–239

    Google Scholar 

  • —, Briggs WR (1990) Intact plastids are required for nitrate- and light-induced accumulation of nitrate reductase activity and mRNA in squash cotyledons. Plant Physiol 92: 434–439

    Google Scholar 

  • —, Schuster C, Mohr H (1988) Physiological characterization of a plastidic signal required for nitrate-induced appearance of nitrate and nitrite reductases. Planta 174: 75–83

    Google Scholar 

  • Redinbaugh MG, Campbell WH (1991) Higher plant responses to environmental nitrate. Physiol Plant 82: 640–650

    Google Scholar 

  • Reiss T, Bergfeld R, Link G, Thien W, Mohr H (1983) Photooxidative destruction of chloroplasts and its consequences for cytosolic enzyme levels and plant development. Planta 159: 518–528

    Google Scholar 

  • Schmidt S, Mohr H (1989) Regulation of the appearance of glutamine synthetase in mustard (Sinapisalba L.) cotyledons by light, nitrate and ammonium. Planta 177: 526–534

    Google Scholar 

  • Senge M, Senger H (1990) Response of the photosynthetic apparatus during adaptation ofChlorella andAnkistrodesmus to irradiance changes. J Plant Physiol 136: 675–679

    Google Scholar 

  • Swamp R, Bennett MJ, Cullimore JW (1990) Expression of glutamine-synthetase genes in cotyledons of germinatingPhaseolus vulgaris L. Planta 183: 51–56

    Google Scholar 

  • Thompson WF, White MJ (1991) Physiological and molecular studies of light-regulated nuclear genes in higher plants. Annu Rev Plant Physiol Plant Mol Biol 42: 423–466

    Google Scholar 

  • Tingey SV, Walker EL, Coruzzi GM (1987) Glutamine synthetase genes of pea encode distinct polypeptides which are regulated differentially in leaves, roots and nodules. EMBO J 6: 1–9

    PubMed  Google Scholar 

  • —, Tsai FY, Edwards JW, Walker EL, Coruzzi GM (1988) Chloroplast and cytosolic glutamine synthetase are encoded by homologous nuclear genes which are differentially expressed in vivo. J Biol Chem 263: 9651–9657

    PubMed  Google Scholar 

  • Vaughn KC, Campbell WH (1988) Immunogold localization of nitrate reductase in maize leaves. Plant Physiol 88: 1354–1357

    Google Scholar 

  • Wallsgrove RM, Lea PJ, Miflin BJ (1979) Distribution of the enzymes of nitrate assimilation within the pea leaf cell. Plant Physiol 63: 232–236

    Google Scholar 

Download references

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Authors and Affiliations

  1. Departamento de Biología Vegetal y Ecología, División de Fisiología Vegetal, Facultad de Ciencias, Universidad de Córdoba, E-14071, Córdoba, Spain

    P. Cabello, P. de la Haba, A. González-Fontes & J. M. Maldonado

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  1. P. Cabello
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  2. P. de la Haba
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  3. A. González-Fontes
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  4. J. M. Maldonado
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Cabello, P., de la Haba, P., González-Fontes, A. et al. Induction of nitrate reductase, nitrite reductase, and glutamine synthetase isoforms in sunflower cotyledons as affected by nitrate, light, and plastid integrity. Protoplasma 201, 1–7 (1998). https://doi.org/10.1007/BF01280705

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  • DOI: https://doi.org/10.1007/BF01280705

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