Concentrations of iron and phytosiderophores in xylem sap of iron-deficient barley plants

Soil Science and Plant Nutrition

Volumn 47, Issue 2, 2001, Pages 265-272

  Kawai, Shigenao ^a   Kamei, Shigeru ^a   Matsuda, Yuuki ^a   Ando, Ryoji ^a   Kondo, Seiichi ^a   Ishizawa, Ayako ^a   Alam, Shah ^a  

^a IWATE UNIVERSITY   (Japan)

Author keywords

Ethylenediamine tetraacetic acid; Iron deficiency; Mugineic acid; Phytosiderophores; Xylem sap

Indexed keywords

HORDEUM; HORDEUM VULGARE; HORDEUM VULGARE SUBSP. VULGARE;

EID: 0034936492     PISSN: 00380768     EISSN: 17470765     Source Type: Journal    
DOI: 10.1080/00380768.2001.10408390     Document Type: Article

References (28)

1. Brown, J.C., 1978. Mechanism of iron uptake by plants. Plant Cell Environ., 1:249–257.
2. Brown, J.C., and Chaney, R.L., 1971. Effect of iron on the transport of citrate into the xylem of soybeans and tomatoes. Plant Physiol., 47:836–840.
3. Brown, J.C., and Tiffin, L.O., 1965. Iron stress as related to the iron and citrate occurring in stem exudate. Plant Physiol., 40:395–400.
4. Fushiya, S., Takahashi, K., Nakatsuyama, S., Sato, Y., Nozoe, S., and Takagi, S., 1982. Co-occurrence of nicotianamine and avenic acids in Avena sativa and Oryza sativa. Phytochemistry, 21:1907–1908.
5. Ishida, Y., Fujita, T., and Asai, K., 1981. New detection and separation method for amino acids by high performance liquid chromatography. J. Chromatogr., 204:143–148.
6. Kawai, S., Sato, Y., Takagi, S., and Nomoto, K., 1987. Separation and determination of mugineic acid and its analogues by high-performance liquid chromatography. J. Chromatogr., 391:325–327.
7. Kawai, S., Takagi, S., and Sato, Y., 1988. Mugineic acid-family phytosiderophores in root-secretions of barley, corn and sorghum varieties. J. Plant Nutr., 11:633–642.
8. Kochian, L.V., 1991. “Mechanisms of micronutrient uptake and translocation in plants”. In Micronutrients in Agriculture, Edited by:Mortvedt, J.J., Cox, F.R., Shuman, L.M., and Welch, R.M., 229–296. Madison, Wisconsin:Soil Science Society of America, Inc.
9. Lindsay, W.L., 1974. “Role of chelation in micronutrient availability”. In The Plant Root and Its Environment, Edited by:Carson, E.W., 507–524. Charlottesville:University Press of Virginia.
10. Ma, J.F., Kusano, G., Kimura, S., and Nomoto, K., 1993. Specific recognition of mugineic acid-ferric complex by barley roots. Phytochemistry, 34:599–605.
11. Marschner, H., 1995. Mineral Nutrition of Higher Plants, 2, 313London:Academic Press.
12. Mori, S., 1998. “Iron transport in graminaceous plants”. In Metal Ions in Biological Systems, Edited by:Siegel, A., and Siegel, H., Vol. 35, 215–238. New York:Marcel Dekker, Inc.
13. Mori, S., Nishizawa, N., Hayashi, H., Chino, M., Yoshimura, E., and Ishihara, J., 1991. Why are young rice plants highly susceptible to iron deficiency?. Plant Soil, 130:143–156.
14. Nishizawa, N.K., Mori, S., Takahashi, S., and Ueda, T., 1989. Mugineic acid secretion by cultured barley cells derived from anther. Protoplasma, 148:164–166.
15. Nomoto, K., Mino, Y., Ishida, T., Yoshioka, H., Ota, N., Inoue, M., Takagi, S., and Takemoto, T., 1981. X-ray crystal structure of the copper (II) complex of mugineic acid, a naturally occurring metal chelator of graminaceous plants. J. Chem. Soc., Chem. Commun.:338–339.
16. Römheld, V., and Marschner, H., 1986. Evidence for a specific uptake system for iron phytosiderophores in roots of grasses. Plant Physiol., 80:175–180.
17. Rudolph, A., Becker, R., Scholz, G., Prochazka, Z., Toman, J., Macek, T., and Herout, V., 1985. The occurrence of the amino acid nicotianamine in plants and microorganisms. A reinvestigation. Biochem. Physiol. Pflanzen., 180:557–563.
18. Scholz, G., Schlesier, G., and Seifert, K., 1985. Effect of nicotianamine on iron uptake by the tomato mutant 'chloronerva.'. Physiol. Plant., 63:99–104.
19. Shi, W.-M., Chino, M., Youssef, R.A., Mori, S., and Takagi, S., 1988. The occurrence of mugineic acid in the rhizosphere soil of barley plant. Soil Sci. Plant Nutr., 34:585–592.
20. Stephan, V.W., and Scholz, G., 1990. Nicotianamine concentrations in iron sufficient and iron deficient sunflower and barley roots. J. Plant Physiol., 136:631–634.
21. Sugiura, Y., and Nomoto, K., 1984. “Phytosiderophores structures and properties of mugineic acids and their metal complexes”. In Structure and Bonding, Edited by:Clarke, M.J, Goodenough, J.B., Ibers, J.A., Jörgensen, C.K., Mingos, D.M.P., Neilands, J.B., Palmer, G.A., Reinen, D., Sadler, P.J., Weiss, R., and Williams, R.J.P., Vol. 58, 109–135. Berlin:Springer-Verlag.
22. Takagi, S., 1993. “Production of phytosiderophores”. In Iron Chelation in Plants and Soil Microorganisms, Edited by:Barton, L.L., and Hemming, B.C., 111–131. New York:Academic Press.
23. Takagi, S., Nomoto, K., and Takemoto, T., 1984. Physiological aspect ofmugineic acid, a possible phytosiderophore of graminaceous plants. J. Plant Nutr., 7:469–477.
24. Tiffin, L.O., 1966. Iron translocation. I. Plant culture, exudate sampling, iron-citrate analysis. Plant Physiol., 41:510–514.
25. Tiffin, L.O., Brown, J.C., and Krauss, R.W., 1960. Differential absorption of metal chelate components by plant roots. Plant PhysioL, 35:362–367.
26. II. Implications for metal transport in plants. Plant Physiol., 119:1107–1114.
27. Wang, T., and Peverly, J.H., 1999. Investigation of ferric iron reduction on the root surfaces of common reed using an EDTA-BPDS method. J. Plant Nutr., 22:1021–1032.
28. White, M.C., Decker, A.M., and Chaney, R.L., 1981. Metal complexation in xylem fluid. I. Chemical composition of tomato and soybean stem exudate. Plant Physiol., 67:292–300.