Husain, Shaziavon Caemmerer, SusanneMunns, Rana Ellen2015-12-071445-4408http://hdl.handle.net/1885/27715Wheat genotypes with 5-fold difference in shoot Na+ concentrations were studied over a salinity range of 1-150 mM NaCl and CaCl 2 of 0.5-10 mM to assess their performance in saline and sodic soils. All genotypes had a maximum shoot Na+ concentration at 50 mM external NaCl when the supplemental Ca2+ provided an activity of 1 mM or more. Shoot Na+ concentrations either stayed constant from 50 to 150 mM external NaCl, or decreased in some genotypes at the higher salinity. Calculated rates of root uptake, and root: shoot transport, were at a maximum at 50 mM NaCl in all genotypes, and decreased at higher NaCl in some genotypes, indicating feedback regulation. K+ showed a pattern inverse to that of Na+. Cl- uptake and transport rates increased linearly with increasing salinity, and differed little between genotypes. Increasing external Ca2+ concentration reduced the accumulation of Na + in the shoot, the effects being greater in the low Na+ genotypes, and greater as the salinity increased, indicating that the plateau in shoot Na+ concentration relied on the maintenance of a minimal Ca2+ activity of 1 mM. Increasing external Ca2+ concentration did not reduce the root Na+ concentration, however, suggesting that Ca2+ influenced the loading of Na+ in the xylem.Keywords: Genes; Salinity measurement; Sodium chloride; Soils; Transport properties; Saline soil; Sodic soils; Crops; salinity tolerance; wheat; Genotypes; Roots; Salinity; Shoots; Sodium Chloride; Soil; Wheat; Triticum aestivum Salt sensitive; Salt tolerant; Wheat200410.1071/FP040782015-12-07