Cellular and Molecular Mechanisms of Plant Tolerance to Waterlogging

Waterlogging can occur in diverse environments and vary in intensity and duration from temporary to intermittent or continuous, and in timing during different periods of the plant growth cycle. It is not only a major constraint for crop productivity but strongly affects species distribution. Waterlo...

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Bibliographic Details
Published inPlant-Environment Interactions pp. 203 - 234
Format Book Chapter
LanguageEnglish
Published United Kingdom CRC Press 2006
Taylor & Francis Group
Subjects
Agricultural science
Biodiversity
Botany & plant sciences
Maize Root Tips
Soil Water Saturation
LDH Activity
Adventitious Roots
Low Oxygen Stress
Root Tips
Plant Tolerance
Glutamate Decarboxylase
ATP Utilization
ROL
ATP Level
Calcium Dependent Protein Kinases
ATP Formation
Nonsymbiotic Hemoglobin
Acc Deaminase
Phosphoglycerate Mutase
ATP Supply
Anoxic Tolerance
Waterlogging Tolerance
UDP Glucose Pyrophosphorylase
Low Oxygen Conditions
ATP Regeneration
Glycolytic Flux
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ISBN9780849337277
0849337275
DOI10.1201/9781420019346-14

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Summary:Waterlogging can occur in diverse environments and vary in intensity and duration from temporary to intermittent or continuous, and in timing during different periods of the plant growth cycle. It is not only a major constraint for crop productivity but strongly affects species distribution. Waterlogging is distinguished from flooding by the limitation of excess water to the root system. The adverse effects of waterlogging have been attributed principally to lowered oxygen supply, which is exacerbated by soil microorganisms that consume oxygen and may also diminish the supply of nitrate. Highly toxic microelements accumulate, as do COand ethylene. Tolerance to waterlogging can be defined either in physiological terms as maintenance of high biomass production or minimal growth reduction due to waterlogging, or in agronomic terms as achieving high grain yields or less reduction in yields under waterlogged conditions. Tolerance is thus a complex trait, undoubtedly involving numerous mechanisms at cellular and molecular levels. The initial step must be the capacity to perceive and transmit a signal to its point of action. Some progress has been made in understanding mechanisms of waterlogging stress sensing and regulation, although it is still unclear which of many possible signals and which sensing mechanisms are involved in eliciting an appropriate plant response. The subject of perception and signaling of soil water saturation (also see [1]) is discussed in the first part of this chapter. The mechanisms of anoxic tolerance have previously been extensively reviewed [2,3]. This chapter succinctly presents and updates our understanding of plant tolerance to waterlogging. It also reviews studies with an aim to improve waterlogging tolerance by genetic manipulation and finally, addresses how the level of plant tolerance to waterlogging can be evaluated. Varietal differences in tolerance at the germination stage often differ from tolerance at later stages of development, in support of the hypothesis that different mechanisms are involved. This chapter discusses mechanisms of waterlogging tolerance of plants with developed root systems at the vegetative stage of their development.
ISBN:9780849337277
0849337275
DOI:10.1201/9781420019346-14