Kaundal, Amita; Hansen, Nathaniel; Ganesh, Jyothsna (Utah State University)
Plants are sessile and bound to their origin so they cannot move to defend themselves against adverse environmental conditions. Soil salinity is one of such environmental stress, which limits the growth and development of plants. Salt stress directly affects crop production. It has been predicted that by 2050, about 50% of arable land will be affected by salinity. About 23% of the worldwide farmland is affected by soil salinity and the crop losses due to salinity are estimated to be tens of billion dollars per year. On top of that, an increase in the world population, the demand for food production also increases. Thus, feeding the growing population under adverse conditions is a challenge. This challenge demands to create more resilient crops to adverse conditions and to feed the growing population. In this study we are investigating General Control Non-repressible 4 (GCN4) in Arabidopsis for salt stress tolerance. GCN4 is an AAA+-ATPase (ATPases associated with diverse cellular activities). AAA+ proteins have diverse functions, such as assembly or disassembly of protein complexes, protein folding or unfolding, protein transport or degradation. It has been shown previously that when AtGCN4 overexpressed in Arabidopsis, it plays a significant role in host-pathogen interaction and control stomatal movement upon pathogen infection by degrading RIN4 - 14-3-3 proteins in PM H+-ATPase complex. Besides this GCN4 when overexpressed exhibit drought tolerance. In this study, we have investigated the previously developed overexpressed and silenced GCN4 Arabidopsis transgenic lines along with wild type plants for salt tolerance at different NaCl concentrations of 90mM, 120mM, and 150mM. So far, the studies indicate that the overexpressor lines were able to tolerate up to 150mm of NaCl as compared to the WT and silenced lines. Further studies are in progress to confirm our hypothesis that GCN4 improves the salt tolerance of transgenic plants. The obtained knowledge will help to investigate the common link in the mechanisms involved in various abiotic and biotic stresses.