PHYSIOLOGICAL AND GENETIC ASPECTS OF PLANT ADAPTATION TO ELEMENTAL STRESSES IN ACID SOILS

Authors: YANG, XIAOE - ZHEJIANG UNIV, CHINA; WANG, WEIMU - ZHEJIANG UNIV, CHINA; ZHENQIAN, YE - ZHEJIANG UNIV, CHINA; ZHENLI, HE - ZHEJIANG UNIV, CHINA; Baligar, Virupax

Submitted to: The Red Soils of China: Their Nature, Management and Utilization
Publication Type: Book / Chapter
Publication Acceptance Date: 12/9/2003
Publication Date: 5/1/2004
Citation: Yang, X., Wang, W., Zhenqian, Y., Zhenli, H., Baligar, V.C. 2004. Physiological and genetic aspects of plant adaptation to elemental stresses in acid soils. In: wilson, J. He, Z., Yang, X. The Red Soils of China: Their Nature, Management and Utilization. The Netherlands: Kluwer Academic Publications. p. 179-232.

Interpretive Summary:

Technical Abstract: The world population is increasing rapidly and will likely reach 10 billion by the year 2050 of which half will probably be living in the region dominated by acid soils. The limited availability of additional arable land and the degradation of soil quality make food security a major challenge in the 21st century. Elemental toxicities and deficiencies are the major constraints limiting crop production in acid soils. Plant genotypes are known to differ greatly in their tolerance to elemental toxicities or deficiencies in soil. In this paper, physiological and genetic mechanisms of crop plant adaptation to stress of selected elements in acid soils are reviewed. Plant tolerance to toxicity stress such as aluminum (Al) and manganese (Mn), and deficiency stresses of nitrogen (N), phosphorus (P), potassium (K), boron (B), and zinc (Zn) are closely related to the physiological process of ion uptake, transport and re-distribution in the plant. In the last decade, considerable knowledge in mechanisms of Al resistance or tolerance has been gained. The resistance of many plant species to Al toxicity is associated with increased root excretion of organic acids and with the involvement of specific anion transporters in the plasma membrane, whereas Mn tolerance seems to be mainly related to its distribution and compartmentalization in plant cells. The mechanisms of N, P, K, B, and Zn use efficiency in crop plants are not fully understood even though in recent years research on these elements has increased considerably. The definition and expression of nutrient use efficiency (NUE) of the selected elements (N, P, K, B, and Zn) in crop plants and the physiological and genetic traits associated with the NUE are addressed in this context. To achieve sustainable crop production in acid soils, it is essential to increase crop plant tolerance to elemental stresses through genetic improvement and further optimize soil nutrient availability and pest management so that adaptive and efficient farming systems can be established.