Metal micronutrients in xylem sap of iron-deficient barley as affected by plant-borne, microbial, and synthetic metal chelators

Soil Science and Plant Nutrition

Volumn 47, Issue 1, 2001, Pages 149-156

  Alam, Shah ^a   Kamei, Shigeru ^a   Kawai, Shigenao ^a  

^a IWATE UNIVERSITY   (Japan)

Author keywords

Barley; Iron deficiency; Phytosiderophore; Solubilization; Translocation

Indexed keywords

HORDEUM; HORDEUM VULGARE; HORDEUM VULGARE SUBSP. VULGARE;

EID: 0035042630     PISSN: 00380768     EISSN: 17470765     Source Type: Journal    
DOI: 10.1080/00380768.2001.10408377     Document Type: Article

References (33)

1. Alam, S., Kamei, S., and Kawai, S., 2000. Phytosiderophore release from manganese-induced iron deficiency in barley. J. Plant Nutr., 23:1193–1207.
2. Brown, J.C., 1961. Iron chlorosis in plants. Adv. Agran., 13:329–369.
3. Brown, J.C., 1978. Mechanism of iron uptake by plants. Plant Cell Environ., 1:249–257.
4. Brown, J.C., Tiffin, L.O., Specht, A.W., and Resnicky, J.W., 1961. Stability and concentration of metal chelates, factors in iron chlorosis of plants. Agran. J., 53:85–90.
5. Clark, R.B., 1982. Iron deficiency in plants grown in the Great Plains of the U.S. J. Plant Nutr., 5:251–268.
6. Crowley, D.E., Reid, C.P.P., and Szaniszlo, P.J., 1987. “Microbial siderophores as iron sources for plants”. In Iron Transport in Microbes, Plants and Animals, Edited by:Winkelmann, G., van der Helm, D., and Neilands, J.B., 375–386. Weinheim:VCH Publishers.
7. Crowley, D.E., Wang, Y.C., Reid, C.P.P., and Szaniszlo, P.J., 1991. Mechanisms of iron acquisition from siderophores by microorganisms and plants. Plant Soil, 130:179–198.
8. Graham, R.D., 1979. Transport of copper and manganese to the xylem exudate of sunflower. Plant Cell Environ., 2:139–143.
9. Gries, D., Klatt, S., and Runge, M., 1998. Copper-deficiency-induced phytosiderophore release in the calcicole grass Hordelymus europaeus. New Phytol., 140:95–101.
10. Kawai, S., Itoh, K., and Takagi, S., 1993. Incorporation of 15N and 14C of methionine into the mugineic acid family of phytosiderophores in iron-deficient barley roots. Physiol. Plant., 88:668–674.
11. Kawai, S., Takagi, S., and Sato, Y., 1988. Mugineic acid-family phytosiderophores in root-secretions of barley, com and sorghum varieties. J Plant Nutr., 11:633–642.
12. Marschner, H., 1995a. Mineral Nutrition of Higher Plants, 313–404. London:Academic Press.
13. Marschner, H., 1995b. Mineral Nutrition of Higher Plants, 79–115. London:Academic Press.
14. Marschner, H., Romheld, V., and Kissel, M., 1987. Localization of phytosiderophore release and of iron uptake along intact barley roots. Physiol. Plant., 72:157–162.
15. Marschner, H., Treeby, M., and Romheld, V., 1989. Role of root-induced changes in the rhizosphere for iron acquisition in higher plants. Z. Pfianzenerniihr. Bodenk., 152:197–204.
16. 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.
17. Murakami, T., Ise, K., Hayakawa, M., Kamei, S., and Takagi, S., 1989. Stabilities of metal complexes of mugineic acids and their specific affinities for iron (III). Chem. Lett., 1989:2137–2140.
18. Römheld, V., 1991. The role of phytosiderophores in acquisition of iron and other micronutrients in graminaceous species:An ecological approach. Plant Soil, 130:127–134.
19. Römheld, V., and Marschner, H., 1986. Evidence for a specific uptake system for iron phytosiderophores in roots of grasses. Plant Physiol., 80:175–180.
20. Römheld, V., Marschner, H., and Kramer, D., 1982. Responses to Fe deficiency in roots of "Fe-efficient" plant species. J. Plant Nutr., 5:489–498.
21. Sugiura, Y., Tanaka, H., Mino, Y., Ishida, T., Ota, N., Inoue, M., Nomoto, K., Yoshioka, H., and Takemoto, T., 1981. Structure, properties, and transport mechanism of Fe(III) complex ofmugineic acid, a possible phytosiderophore. J. Am. Chem. Soc., 103:6979–6982.
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., Kamei, S., and Yu, M.H., 1988. Efficiency of iron extraction from soil by mugineic acid family phytosiderophores. J. Plant Nutr., 11:643–651.
24. Takagi, S., Nomoto, K., and Takemoto, T., 1984. Physiological aspect ofmugineic acid, a possible phytosiderophore of graminaceous plans. 1. Plant Nutr., 7:469–477.
25. Tiffin, L.O., 1967. Translocation of manganese, iron, cobalt, and zinc in tomato. Plant Physiol., 42:1427–1432.
26. Treeby, M., Marschner, H., and Romheld, V., 1989. Mobilization of iron and other micronutrient cations from a calcareous soil by plant-borne, microbial, and synthetic metal chelators. Plant Soil, 114:217–226.
27. von Wiren, N., Marschner, H., and Romheld, V., 1996. Roots of iron-efficient maize also absorb phytosiderophore-chelated zinc. Plant Physiol., 111:1119–1125.
28. Warden, B.T., and Reisenauer, H.M., 1991. Manganese and iron interactions in the plant-soil system. J. Plant Nutr., 14:7–30.
29. White, M.C., Baker, F.D., Chaney, R.L., and Decker, A.M., 1981a. Metal complexation in xylem fluid. II. Theoretical equilibrium model and computational computer program. Plant Physiol., 67:301–310.
30. White, M.C., Decker, A.M., and Chaney, R.L., 1981b. Metal complexation in xylem fluid. J. Chemical composition of tomato and soybean stem exudate. Plant Physiol., 67:292–300.
31. Zhang, F.S., Römheld, V., and Marschner, H., 1991a. Release of zinc mobilizing root exudates in different plant species as affected by zinc nutritional status. J. Plant Nutr., 14:675–686.
32. Zhang, F.S., Römheld, V., and Marschner, H., 1991b. Role of the root apoplasm for iron acquisition by wheat plants. Plant Physiol., 97:1302–1305.
33. Zhang, F.S., Römheld, V., and Marschner, H., 1991c. Diurnal rhythm of release of phytosiderophores and uptake of zinc in iron-deficient wheat. Soil Sci. Plant Nutr., 37:671–678.