Transporte de compostos nitrogenados em soja cultivada com diferentes fontes de nitrogênio

Sawazaki, Haiko Enok; Sodek, Ladaslav; Teixeira, João Paulo Feijão

doi:10.1590/S0006-87051987000200011

Resumos

Plantas de soja inoculadas com Rhizobium japonicum foram cultivadas em vermiculita com solução nutritiva sem nitrogênio, em casa de vegetação, no Centro Experimental de Campinas, do Instituto Agronômico. Foi estudado o efeito quanto aos níveis de ureídeos (alantoína e ácido alantóico), aminoácidos (total e qualitativo por analisador de aminoácidos), NO3- e NH4+, encontrados na seiva do xilema. Para esse fim, as plantas (noduladas) foram tratadas durante sete dias com soluções nutritivas contendo os íons NO3- (15mM) ou NH4+ (10mM) aplicadas próximo à época de floração, ou sem nitrogênio (controle). O ácido alantóico predominou em relação à alantoína, e essa proporção tendeu a aumentar com a exposição da planta a N-mineral. O transporte de nitrogênio total pelo xilema foi maior para o processo de fixação de N2, decrescendo para o de absorção de NH4+ e para o de absorção de NO3-, sugerindo que o transporte de nitrogênio tenha dependido da interação entre presença de N-mineral no solo e disponibilidade de energia. A fixação de N2, processo mais dispendioso de energia, possibilita maior produção de ureídeos, que exportam mais nitrogênio que os aminoácidos. A asparagina foi o aminoácido encontrado em maior quantidade no xilema, independente do tratamento. O tratamento NH4+ não alterou o teor de N-NH4+, mas aumentou o nível de glutamina e asparagina em comparação com o tratamento NO3-, que, por sua vez, aumentou o teor de ácido aspártico e o de N-NO3-. Esses resultados sugerem que a diferenciação na formação de aminoácidos decorreu dos processos específicos de absorção de nitrogênio.

soja; aminoácidos; ureídeos; fixação simbiótica; nutrição nitrogenada

Soybean plants, inoculated with Rhizobium japonicum, were grown in vermiculite with a nitrogen free nutrient solution in a greenhouse, in the Experimental Station of Campinas, Instituto Agronômico, State of São Paulo, Brazil. The effects of NO3- and NH4+ were studied in terms of ureide and amino acid levels in the xylem sap. Nodulated plants were treated with nutrient solution either containing NO3- (15 mM), or NH4+ (10 mM), or without nitrogen (control) for 7 days, near the flowering period. Higher proportion of alantoic acid was found relative to allantoin, and this proportion increased in plants grown on mineral N. The NH4+ ion had an intermediary effect compared to the other N-assimilatory processes, with respect to the quantity of N transported to the aerial parts, suggesting that the mecanism of transport depended on the interaction between the soil mineral nitrogen and the energy available. Asparagin was the amino acid in the greatest quantity in the xylem, independent of the treatment. Ammonium did not alter the levels of N-NH4+ in the sap, but increased slightly the level of NO3-. Nitrate caused slight increase in aspartic acid and large in NO3- content in the sap. These results suggested that the differences in the amino acid synthesis proceeded of a specific pathway of nitrogen uptake.

soybean; amino acids; ureides; symbiotic fixation; nitrogen nutrition

ARTIGOS

Transporte de compostos nitrogenados em soja cultivada com diferentes fontes de nitrogênio

Xylem sap composition of soybean plants treated with different nitrogen sources

Haiko Enok Sawazaki^I; Ladaslav Sodek^II; João Paulo Feijão TeixeiraI, ^* * Com bolsa de pesquisa do CNPq.

^ISeção de Fitoquímica, Instituto Agronômico (IAC). Caixa Postal 28. 13001 Campinas (SP)

^IIDepartamento de Fisiologia Vegetal, Instituto de Biologia, Universidade de Campinas

RESUMO

Plantas de soja inoculadas com Rhizobium japonicum foram cultivadas em vermiculita com solução nutritiva sem nitrogênio, em casa de vegetação, no Centro Experimental de Campinas, do Instituto Agronômico. Foi estudado o efeito quanto aos níveis de ureídeos (alantoína e ácido alantóico), aminoácidos (total e qualitativo por analisador de aminoácidos), NO₃^- e NH₄⁺, encontrados na seiva do xilema. Para esse fim, as plantas (noduladas) foram tratadas durante sete dias com soluções nutritivas contendo os íons NO₃^- (15mM) ou NH₄⁺ (10mM) aplicadas próximo à época de floração, ou sem nitrogênio (controle). O ácido alantóico predominou em relação à alantoína, e essa proporção tendeu a aumentar com a exposição da planta a N-mineral. O transporte de nitrogênio total pelo xilema foi maior para o processo de fixação de N₂, decrescendo para o de absorção de NH₄⁺ e para o de absorção de NO₃^-, sugerindo que o transporte de nitrogênio tenha dependido da interação entre presença de N-mineral no solo e disponibilidade de energia. A fixação de N₂, processo mais dispendioso de energia, possibilita maior produção de ureídeos, que exportam mais nitrogênio que os aminoácidos. A asparagina foi o aminoácido encontrado em maior quantidade no xilema, independente do tratamento. O tratamento NH₄⁺ não alterou o teor de N-NH₄⁺, mas aumentou o nível de glutamina e asparagina em comparação com o tratamento NO₃^-, que, por sua vez, aumentou o teor de ácido aspártico e o de N-NO₃^-. Esses resultados sugerem que a diferenciação na formação de aminoácidos decorreu dos processos específicos de absorção de nitrogênio.

Termos de indexação: soja, aminoácidos, ureídeos, fixação simbiótica, nutrição nitrogenada.

SUMMARY

Soybean plants, inoculated with Rhizobium japonicum, were grown in vermiculite with a nitrogen free nutrient solution in a greenhouse, in the Experimental Station of Campinas, Instituto Agronômico, State of São Paulo, Brazil. The effects of NO₃^- and NH₄⁺ were studied in terms of ureide and amino acid levels in the xylem sap. Nodulated plants were treated with nutrient solution either containing NO₃^- (15 mM), or NH₄⁺ (10 mM), or without nitrogen (control) for 7 days, near the flowering period. Higher proportion of alantoic acid was found relative to allantoin, and this proportion increased in plants grown on mineral N. The NH₄⁺ ion had an intermediary effect compared to the other N-assimilatory processes, with respect to the quantity of N transported to the aerial parts, suggesting that the mecanism of transport depended on the interaction between the soil mineral nitrogen and the energy available. Asparagin was the amino acid in the greatest quantity in the xylem, independent of the treatment. Ammonium did not alter the levels of N-NH₄⁺ in the sap, but increased slightly the level of NO₃^-. Nitrate caused slight increase in aspartic acid and large in NO₃^- content in the sap. These results suggested that the differences in the amino acid synthesis proceeded of a specific pathway of nitrogen uptake.

Index terms: soybean, amino acids, ureides, symbiotic fixation, nitrogen nutrition.

Texto completo disponível apenas em PDF.

Full text available only in PDF format.

Recebido para publicação em 14 de novembro de 1986.

ATKINS, C.A.; PATE, J.S.; GRIFFITHS, G.J. & WHITE, S.T. Economy of carbon and nitrogen in nodulated and non-nodulated (NO₃^--grown) cowpea (Vigna unguiculata (L.) Walp). Plant Physiology, 66:978-983, 1980.
BOLLARD, E.G. Transport in the xylem. Annual Review of Plant Physiology, 11:141-166, 1960.
CATALDO, D.A.; HAROON, M.; SCHADER, L.E. & YOUNGS, U.L. Rapid colorimetric determination of nitrate in plant tissue by nitration of salicylic acid. Communication in Soil Science and Plant Analisys, 6:71-80, 1975.
COTTINGHAM, D.G.H. & JONES, L.C.P. The influence of nitrate supply on nitrogen fixation during growth of the field bean Vicia faba in sand. Physiologia Plantarum, 48:116-120, 1980.
FINKE, R.L.; HARPER, J.E. & HAGEMAN, R.H. Efficiency of nitrogen assimilation by N₂-fixing and nitrate-grown soybean plants (Glycine max (L.) Merr.). Plant Physiology, 70:1178-1184, 1982.
FUJIHARA, S. & YAMAGUCHI, M. Asparagine formation in soybean nodules. Plant Physiology, 66:139-151, 1980.
^__________; YAMAMOTO, K. & YAMAGUCHI, M. Possible role of allantoin and the influence of nodulation on its production in soybean plants. Plant and Soil, 48:233-242, 1977.
HAYNES, R.J. & GOH, K.M. Ammonium and nitrate nutrition of plant. Biological Review, 53:465-510, 1978.
HERRIDGE, D.F. Relative abundance of ureides and nitrate in plant tissues of soybean as a quantitative assay of nitrogen fixation. Plant Physiology, 70:1-6, 1982a.
^__________ Use of the ureide technique to describe the nitrogen economy of field-grown soybeans. Plant Physiology, 70:7-11, 1982b.
LEA, P.J. & MIFLIN, B.J. Transport and metabolism of the asparagine and other nitrogen compounds within the plant The Biochemistry of Plants, 5:569-607, 1980.
McCULLOUGH, H. The determination of ammonia in whole blood, by a direct colorimetric method. Nitrogen determination-Berthelot Clinica Chimica Acta, 17:297-304, 1967.
McCLURE, P.R.; ISRAEL, D.W. & VOLK, R.J. Evaluation of the relative ureide content of xylem sap as an indicator of N₂ fixation in soybeans. Plant Physiology, 66:720-725, 1980.
MARCUS-WYNER, L. & RAINS, D.W. Patterns of ammonium absorption and acetylene reduction during soybeans development growth. Plant Physiology, 59:79-82, 1983.
MATSUMOTO, T.; YATAZAWA, M. & YAMAMOTO, R. Incorporation of ¹⁵N into allantoin in nodulated soybean plants supplied with ¹⁵N₂ Plant & Cell Physiology, 18:459-462, 1977.
MIFLIN, B.J. & LEA, P.J. Amino acid metabolism. Annual Review of Plant Physiology, 28:299-329, 1977.
MITCHELL, D.J. & BIDWELL, R.C. Comportaments of organic acid in the synthesis of asparagine and homoserine in pea roots. Canadian Journal of Botany, 48:2001-2007, 1970.
NOEL, K.D.; CARNEOL, M. & BRILL, W.J. Nodule protein synthesis and nitrogenase activity of soybeans exposed to fixed nitrogen. Plant Physiology, 70:1236-1241, 1982.
OHYAMA, T. & KUMAZAWA, K. Assimilation and transport of nitrogenous compounds originated from ¹⁵N₂ fixation and ¹⁵NO₃^- absorption. Soil Science and Plant Nutrition, 25:9-19, 1979.
PERKIN-ELMER. Instruction manual for ligand exchange chromatography, nş 6499 - E. s.l., 1971.70p.
PURITCH, G.S. & BARKER, A.V. Structure and function of tomato leaf chloroplasts during ammonium toxicity. Plant Physiology, 42:1229-1238, 1967.
REYNOLDS, P.H.S.; BOLAND, M.J.; BLEVINS, D.G.; SCHUBERT, K.R. & RANDALL, D.D. Enzymes of amide and ureide biogenesis in developing soybean nodules. Plant Physiology, 69:1334-1338, 1982.
SAWAZAKI, H.E.; SODEK, L. & LOPES, E.S. Efeito de fonte externa de nitrogênio no transporte de compostos nitrogenados em plantas de soja (Glycine max (L.) Merrill) cultivar Santa Rosa. In: REUNIÃO LATINO-AMERICANA SOBRE RHIZOBIUM, 12., Campinas, 1986. Anais. Campinas, Instituto Agronômico, 1986. p.172-179.
SCHUBERT, K.R. Enzymes of purine biosynthesis and catabolism in Glycine max. Comparison of activities with N₂ fixation and composition of xylem exudate and nodule development. Plant Physiology, 68:1115-1122, 1981.
TRIJBELS, F. & VOGELS, G.D. Deqradation of allantoin by Pseudomonas acidovorans. Biochemica et Biophysica Acta, 113:292-301, 1966.
WONG, P.P. & STENBERG, N.E. Effects of directly and indirectly applied nitrate on nodulation and nitrogen fixation (acetylene reduction) activity of soybeans. Plant Physiology, 65(6):108, 1980. Suppl. Abstracts n. 594.
YEM, E.W. & COCKING, E.C. The determination of aminoacids with ninhydrin. Analyst, 80:209-213, 1955.
ZENGBÉ, M.; TILLARD, P.; CLEYET-MAREL, J.C. & SALSAC, L. Influence de la souche de Rhyzobium et de I'azote minéral sur la synthèse des uréides chez le soja. Physiologie Vegetale, 22:285-294, 1984.

*

Com bolsa de pesquisa do CNPq.

Datas de Publicação

Publicação nesta coleção
06 Dez 2007
Data do Fascículo
1987

Histórico

Recebido
14 Nov 1986

This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.

[1] ATKINS, C.A.; PATE, J.S.; GRIFFITHS, G.J. & WHITE, S.T. Economy of carbon and nitrogen in nodulated and non-nodulated (NO₃^--grown) cowpea (Vigna unguiculata (L.) Walp). Plant Physiology, 66:978-983, 1980.

[2] BOLLARD, E.G. Transport in the xylem. Annual Review of Plant Physiology, 11:141-166, 1960.

[3] CATALDO, D.A.; HAROON, M.; SCHADER, L.E. & YOUNGS, U.L. Rapid colorimetric determination of nitrate in plant tissue by nitration of salicylic acid. Communication in Soil Science and Plant Analisys, 6:71-80, 1975.

[4] COTTINGHAM, D.G.H. & JONES, L.C.P. The influence of nitrate supply on nitrogen fixation during growth of the field bean Vicia faba in sand. Physiologia Plantarum, 48:116-120, 1980.

[5] FINKE, R.L.; HARPER, J.E. & HAGEMAN, R.H. Efficiency of nitrogen assimilation by N₂-fixing and nitrate-grown soybean plants (Glycine max (L.) Merr.). Plant Physiology, 70:1178-1184, 1982.

[6] FUJIHARA, S. & YAMAGUCHI, M. Asparagine formation in soybean nodules. Plant Physiology, 66:139-151, 1980.

[7] ^__________; YAMAMOTO, K. & YAMAGUCHI, M. Possible role of allantoin and the influence of nodulation on its production in soybean plants. Plant and Soil, 48:233-242, 1977.

[8] HAYNES, R.J. & GOH, K.M. Ammonium and nitrate nutrition of plant. Biological Review, 53:465-510, 1978.

[9] HERRIDGE, D.F. Relative abundance of ureides and nitrate in plant tissues of soybean as a quantitative assay of nitrogen fixation. Plant Physiology, 70:1-6, 1982a.

[10] ^__________ Use of the ureide technique to describe the nitrogen economy of field-grown soybeans. Plant Physiology, 70:7-11, 1982b.

[11] LEA, P.J. & MIFLIN, B.J. Transport and metabolism of the asparagine and other nitrogen compounds within the plant The Biochemistry of Plants, 5:569-607, 1980.

[12] McCULLOUGH, H. The determination of ammonia in whole blood, by a direct colorimetric method. Nitrogen determination-Berthelot Clinica Chimica Acta, 17:297-304, 1967.

[13] McCLURE, P.R.; ISRAEL, D.W. & VOLK, R.J. Evaluation of the relative ureide content of xylem sap as an indicator of N₂ fixation in soybeans. Plant Physiology, 66:720-725, 1980.

[14] MARCUS-WYNER, L. & RAINS, D.W. Patterns of ammonium absorption and acetylene reduction during soybeans development growth. Plant Physiology, 59:79-82, 1983.

[15] MATSUMOTO, T.; YATAZAWA, M. & YAMAMOTO, R. Incorporation of ¹⁵N into allantoin in nodulated soybean plants supplied with ¹⁵N₂ Plant & Cell Physiology, 18:459-462, 1977.

[16] MIFLIN, B.J. & LEA, P.J. Amino acid metabolism. Annual Review of Plant Physiology, 28:299-329, 1977.

[17] MITCHELL, D.J. & BIDWELL, R.C. Comportaments of organic acid in the synthesis of asparagine and homoserine in pea roots. Canadian Journal of Botany, 48:2001-2007, 1970.

[18] NOEL, K.D.; CARNEOL, M. & BRILL, W.J. Nodule protein synthesis and nitrogenase activity of soybeans exposed to fixed nitrogen. Plant Physiology, 70:1236-1241, 1982.

[19] OHYAMA, T. & KUMAZAWA, K. Assimilation and transport of nitrogenous compounds originated from ¹⁵N₂ fixation and ¹⁵NO₃^- absorption. Soil Science and Plant Nutrition, 25:9-19, 1979.

[20] PERKIN-ELMER. Instruction manual for ligand exchange chromatography, nş 6499 - E. s.l., 1971.70p.

[21] PURITCH, G.S. & BARKER, A.V. Structure and function of tomato leaf chloroplasts during ammonium toxicity. Plant Physiology, 42:1229-1238, 1967.

[22] REYNOLDS, P.H.S.; BOLAND, M.J.; BLEVINS, D.G.; SCHUBERT, K.R. & RANDALL, D.D. Enzymes of amide and ureide biogenesis in developing soybean nodules. Plant Physiology, 69:1334-1338, 1982.

[23] SAWAZAKI, H.E.; SODEK, L. & LOPES, E.S. Efeito de fonte externa de nitrogênio no transporte de compostos nitrogenados em plantas de soja (Glycine max (L.) Merrill) cultivar Santa Rosa. In: REUNIÃO LATINO-AMERICANA SOBRE RHIZOBIUM, 12., Campinas, 1986. Anais. Campinas, Instituto Agronômico, 1986. p.172-179.

[24] SCHUBERT, K.R. Enzymes of purine biosynthesis and catabolism in Glycine max. Comparison of activities with N₂ fixation and composition of xylem exudate and nodule development. Plant Physiology, 68:1115-1122, 1981.

[25] TRIJBELS, F. & VOGELS, G.D. Deqradation of allantoin by Pseudomonas acidovorans. Biochemica et Biophysica Acta, 113:292-301, 1966.

[26] WONG, P.P. & STENBERG, N.E. Effects of directly and indirectly applied nitrate on nodulation and nitrogen fixation (acetylene reduction) activity of soybeans. Plant Physiology, 65(6):108, 1980. Suppl. Abstracts n. 594.

[27] YEM, E.W. & COCKING, E.C. The determination of aminoacids with ninhydrin. Analyst, 80:209-213, 1955.

[28] ZENGBÉ, M.; TILLARD, P.; CLEYET-MAREL, J.C. & SALSAC, L. Influence de la souche de Rhyzobium et de I'azote minéral sur la synthèse des uréides chez le soja. Physiologie Vegetale, 22:285-294, 1984.

Brasil

Brasil

Transporte de compostos nitrogenados em soja cultivada com diferentes fontes de nitrogênio

Xylem sap composition of soybean plants treated with different nitrogen sources

Resumos

Datas de Publicação

Histórico