Differential reduction in cadmium accumulation in barley under cadmium-salt co-exposure involves specific HMA genes and antioxidative responses

Salinity and heavy metal accumulation adversely affect agricultural productivity and environmental sustainability. Little information exists about the combinatory effect of various stresses on plants, but it is assumed that stress interaction may trigger a specific response. Here, we assessed the combinatory effect of salinity and cadmium on various physiological and molecular traits in two cultivated barley genotypes with contrasting salinity tolerance; Rihane (RH, salt tolerant) and Lemsi (LM, salt sensitive). Studied genotypes were hydroponically exposed to CdCl2 (30 mu M), NaCl (300 mM) or the combined Cd-NaCl stresses for 15 days. Salinity and to a lesser degree Cd-NaCl stress significantly reduced growth, leaf water content, chlorophyll pigments, and K uptake, and increased Na and Cl contents for both genotypes, with LM being more affected than RH. Cd content in roots was higher than in shoots for both genotypes either under Cd alone or when combined with NaCl. Interestingly, NaCl addition reduced Cd accumulation in both roots and shoots of the two barley genotypes, suggesting that the interaction of NaCl and Cd on their uptake and accumulation is antagonistic. The tolerant genotype (RH) accumulated lower Cd levels in shoots and roots than the salt-sensitive one (LM). Cd-NaCl stress significantly lowered H2O2 and MDA contents relative to NaCl treatment alone. The activity of several antioxidant enzymes was essentially higher in RH than in LM, under the different stresses. These responses were in concomitant with an enhanced expression of specific Heavy Metal ATPases (HvHMA) genes, mainly in RH, which can partially, explain the reduced Cd accumulation in this genotype. Overall, these findings suggest the possibility of cultivating salt-tolerant barley genotypes in saline soils slightly contaminated with Cd, whereas barley sensitive genotypes could be assessed for phytoremediation purposes.