Abstract
Salt stress defense mechanisms in plant roots, such as active Na+ efflux and storage, require energy in the form of ATP. Understanding the energy required for these transport mechanisms is an important step toward achieving an understanding of salt tolerance. However, accurate measurements of the fluxes required to estimate these energy costs are difficult to achieve by experimental means. As a result, the magnitude of the energy costs of ion transport in salt-stressed roots relative to the available energy is unclear, as are the relative contributions of different defense mechanisms to the total cost. We used mathematical modeling to address three key questions about the energy costs of ion transport in salt-stressed Arabidopsis roots: are the energy requirements calculated on the basis of flux data feasible; which transport steps are the main contributors to the total energy costs; and which transport processes could be altered to minimize the total energy costs? Using our biophysical model of ion and water transport we calculated the energy expended in the trans-plasma membrane and trans-tonoplast transport of Na+, K+, Cl−, and H+ in different regions of a salt-stressed model Arabidopsis root. Our calculated energy costs exceeded experimental estimates of the energy supplied by root respiration for high external NaCl concentrations. We found that Na+ exclusion from, and Cl− uptake into, the outer root were the major contributors to the total energy expended. Reducing the leakage of Na+ and the active uptake of Cl− across outer root plasma membranes would lower energy costs while enhancing exclusion of these ions. The high energy cost of ion transport in roots demonstrates that the energetic consequences of altering ion transport processes should be considered when attempting to improve salt tolerance.
Highlights
Soil salinity is a global problem affecting 1 billion ha of land, including 20% of all irrigated land (FAO and ITPS, 2015)
At high external NaCl concentrations the energy demands may exceed the total amount of energy available, while even at low NaCl concentrations the energy demands of just ion transport require a substantial amount of the available ATP
To examine which transport processes place the greatest demand on energy, we quantified the individual energy costs associated with the active transport of each ion
Summary
Soil salinity is a global problem affecting 1 billion ha of land, including 20% of all irrigated land (FAO and ITPS, 2015). Salinity reduces growth and yields in many agriculturally important plant species The cause of this reduced growth and yield is an area of active research (Tyerman et al, 2019); it is already recognized that a reduction in energy production While Na+ transport into the root symplast is a passive process driven by a favorable electrochemical potential difference (Munns and Tester, 2008; Maathuis et al, 2014), active efflux of Na+ out of the cytosol is required to prevent Na+ toxicity (Munns and Tester, 2008; Foster and Miklavcic, 2019). If less ATP was required for these ion transport processes, more energy would be available for plant growth and grain production (Munns and Gilliham, 2015). When breeding crops with improved salt tolerance it would be beneficial to understand the energy demands resulting from salt stress, and to identify ways by which plants may reduce these energy requirements
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