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Journal of Plant Nutrition Volume 25, 2002 - Issue 5
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Original Articles

BICARBONATE AND LOW IRON LEVEL INCREASE ROOT TO TOTAL PLANT WEIGHT RATIO IN OLIVE AND PEACH ROOTSTOCK

Manuel D. de laGuardia Departamento de Agronomía, Escuela Técnica Superior de Ingenieros Agrónomos y de Montes, Universidad de Córdoba, E-14080 Córdoba, SpainCorrespondence[email protected]
&
Esteban Alcántara Departamento de Agronomía, Escuela Técnica Superior de Ingenieros Agrónomos y de Montes, Universidad de Córdoba, E-14080 Córdoba, Spain
Pages 1021-1032 | Published online: 14 Feb 2007

REFERENCES

  • Rutland , R. B. 1971 . Radioisotopic Evidence of Immobilization of Iron in Azalea by Excess Calcium Carbonate. . J. Am. Soc. Hortic. Sci. , 96 : 653 – 655 .
  • Rutland , R. B. and Bukovac , M. J. 1971 . The Effect of Calcium Bicarbonate on Iron Absorption and Distribution byChrysanthemum morifolium (Ram). . Plant Soil , 35 : 225 – 236 .
  • Mengel , K. , Bübl , W. and Scherer , H. W. 1984 . Iron Distribution in Vine Leaves with HCO3 −Induced Chlorosis. . J. Plant Nutr. , 7 : 715 – 724 .
  • Shi , Y. , Byrne , D. H. , Reed , D. W. and Loeppert , R. H. 1993 . Iron Chlorosis Development and Growth Response of Peach Rootstocks to Bicarbonate. . J. Plant Nutr. , 16 : 1039 – 1046 .
  • Shi , Y. , Byrne , D. H. , Reed , D. W. and Loeppert , R. H. 1993 . Influence of Bicarbonate Level on Iron-Chlorosis Development and Nutrient Uptake of the Peach Rootstock Montclar. . J. Plant Nutr. , 16 : 1675 – 1689 .
  • Fleming , A. L. , Chaney , R. L. and Coulombe , B. A. 1984 . Bicarbonate Inhibits Fe-Stress Response and Fe Uptake-Translocation of Chlorosis Susceptible Soybean Cultivars. . J. Plant Nutr. , 7 : 699 – 714 .
  • Romera , F. J. , Alcántara , E. and de la Guardia , M. D. 1992 . Effects of Bicarbonate, Phosphate and High pH on the Reducing Capacity of Fe-Deficient Sunflower and Cucumber Plants. . J. Plant Nutr. , 15 : 1519 – 1530 .
  • White , P. F. and Robson , A. D. 1990 . Response of Lupins (Lupinus angustifolius L.) and Peas (Pisum sativum L.) to Fe Deficiency Induced by Low Concentrations of Fe in Solution or by Addition of HCO3 − . Plant Soil , 125 : 39 – 47 .
  • Glenn , D. M. and Welker , W. V. 1997 . Effects of Rhizosphere Carbon-Dioxide on the Nutrition and Growth of Peach-Trees. . HortScience , 32 : 1197 – 1199 .
  • Bialczyck , J. and Lechowski , Z. 1992 . Absorption of HCO3 − by Roots and its Effect on Carbon Metabolism of Tomato. . J. Plant Nutr. , 15 : 293 – 312 .
  • Schmidt , W. 1999 . Mechanisms and Regulation of Reduction-Based Iron Uptake in Plants. . New Phytol. , 141 : 126
  • Romera , F. J. , Alcántara , E. and de laGuardia , M. D. 1991 . Characterization of the Tolerance to Iron Chlorosis in Different Peach Rootstocks Grown in Nutrient Solution. II Iron Stress Response Mechanisms. . Plant Soil , 130 : 120 – 124 .
  • Murphy , J. and Riley , J. P. 1962 . A Modified Single Solution Method for the Determination of Phosphate in Natural Waters. . Anal. Chim. Acta , 27 : 31 – 36 .
  • Marschner , H. 1995 . Mineral Nutrition of Higher Plants London : Academic Press Limited .
  • Reichard , P. 1993 . From RNA to DNA, Why So Many Ribonucleotide Reductases? . Science , 260 : 1773 – 1776 .
  • Landsberg , E. C. 1981 . Organic Acid Synthesis and Release of Hydrogen Ions in Response t Fe Deficiency Stress of Mono- and Dicotyledonous Plant Species. . J. Plant Nutr. , 3 : 579 – 591 .
  • Rabotti , G. , De Nisi , P. and Zocchi , G. 1995 . Metabolic Implications in the Biochemical Responses to Iron Deficiency in Cucumber (Cucumis sativus L.)Roots. . Plant Physiol. , 107 : 1195 – 1199 .
  • Bialczyck , J. , Lechowski , Z. and Libik , A. 1994 . Growth of Tomato Seedlings Under Different HCO3 - Concentration in the Medium. . J. Plant Nutr. , 17 : 801 – 816 .
  • Kramer , P. J. 1969 . Plant and Soil Water Relationships: A Modern Synthesis New York : McGraw-Hill Book Co. .
  • Wu , Y. and Cosgrove , D. J. 2000 . Adaptation of Roots to Low Water Potentials by Changes in Cell Wall Extensibility and Cell Wall Proteins. . J. Exp. Bot. , 51 : 1543 – 1553 .

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