Accumulation of some nitrogen compounds in response to salt stress and their relationships with salt tolerance in rice (Oryza sativa L.) seedlings

被引：110

作者：

Nguyen Thi Thu Hoai

Ie Sung Shim

Katsuichiro Kobayashi

Usui Kenji

机构：

[1] Environ. Plant Biochem. Laboratory, Institute of Applied Biochemistry, University of Tsukuba, Tsukuba

来源：

Plant Growth Regulation | 2003年 / 41卷 / 2期

关键词：

Ammonium; Ammonium assimilation; Na[!sup]+[!/sup] accumulation; Proline; Salt tolerance;

D O I：

10.1023/A:1027305522741

中图分类号：

学科分类号：

摘要：

The salt-induced accumulation of some nitrogen compounds (free amino acids, ammonium and urea) in shoots of eight rice cultivars differing in salt tolerance was investigated. Salt treatment (100 mM, 6 days) significantly increased the proline content of shoots but this appeared to be a reaction to stress damage and not associated with salt tolerance, because proline contents were higher in the more sensitive cultivars. Besides proline, some other free amino acids also accumulated leading to a significant increase in the total amino acid content of the stressed seedlings. High levels of free ammonium also accumulated under conditions of stress; this was highly correlated with the accumulation of Na+ in the shoots and negatively correlated with salt tolerance. The accumulation of ammonium was positively correlated with the accumulation of many free amino acids, and also associated with the production of urea in the stressed seedlings. Results from the present investigations suggest that an increase in the concentration of some free amino acids including proline, may be a result of the reassimilation of the stress-induced ammonium. A high capacity to assimilate ammonium may be an important factor in alleviating the consequence of stress because ammonium can be toxic at high concentrations.

引用

页码：159 / 164

页数：5

共 25 条

[1]

Bohnert H.J., Jensen R.G., Metabolic engineering for increased salt tolerance. The next step, Aust. J. Plant Physiol., 23, pp. 661-667, (1996)

[2]

Britto D.T., Kronzucker H.J., NH4+ toxicity in higher plants: A critical review, J. Plant Physiol., 159, pp. 567-584, (2002)

[3]

Chien H.F., Kao C.H., Accumulation of ammonium in rice leaves in response to excess cadmium, Plant Sci., 156, pp. 111-115, (2000)

[4]

Desmaison A.M., Marcher M.H., Tixier M., Changes in the free and total amino acid composition of ripening chestnut seeds, Phytochemistry, 23, 11, pp. 2453-2456, (1984)

[5]

Dubey R.S., Rani M., Influence of NaCl salinity on the behaviour of protease, aminopeptidase and carboxypeptidase in rice seedlings in relation to salt tolerance, Aust. J. Plant Physiol., 17, pp. 215-221, (1990)

[6]

Garcia A.B., Engler J.D., Iyer S., Gerats T., Van Montagu M., Caplan A.B., Effects of osmoprotectants upon NaCl stress in rice 1, Plant Physiol., 115, pp. 159-169, (1997)

[7]

Ghoulam C., Foursy A., Fares K., Effects of salt stress on growth, inorganic ions and proline accumulation in relation to osmotic adjustment in five sugar beet cultivars, Environ. Exp. Bot., 47, pp. 39-50, (2002)

[8]

Hajibagheri M.A., Yeo A.R., Flowers T.J., Collins J.C., Salinity resistance in Zea mays: Fluxes of potassium, sodium and chloride, cytoplasmic concentrations and microsomal membrane lipids, Plant Cell Environ., 12, pp. 753-757, (1989)

[9]

Hurkman W.J., Tanaka C.K., The effect of salt on the pattern of protein synthesis in barley roots, Plant Physiol., 83, pp. 517-524, (1987)

[10]

Husted S., Mattsson M., Mollers C., Wallbraun M., Schjoerring J.K., Photorespiratory NH4+ production in leaves of wild-type and glutamine synthetase 2 antisense oilseed rape 1, Plant Physiol., 130, pp. 989-998, (2002)

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