Ribosomal Protein Large subunit RPL6 modulates salt tolerance in rice

Abstract

The extra-ribosomal functions of ribosomal proteins RPL6 and RPL23a in stress-responsiveness have emanated from our previous studies on activation tagged mutants of rice screened for water-use efficiency (Moin et al., 2016a). In the present study, we functionally validated the RPL6, a Ribosomal Protein Large subunit member for salt stress tolerance in rice. The overexpression of RPL6 resulted in tolerance to moderate (150 mM) to high (200 mM) levels of salt (NaCl) in rice. The transgenic rice plants expressing RPL6 constitutively showed better phenotypic and physiological responses with high quantum efficiency, accumulation of more chlorophyll and proline contents, and an overall increase in seed yield compared with the wild type in salt stress treatments. An iTRAQ-based comparative proteomic analysis revealed the high expression of about 333 proteins among the 4,378 DEPs in a selected overexpression line of RPL6 treated with 200 mM of NaCl. The functional analysis showed that these highly expressed proteins (HEPs) are involved in photosynthesis, ribosome and chloroplast biogenesis, ion transportation, transcription and translation regulation, phytohormone and secondary metabolite signal transduction. An in silico network analysis of HEPs predicted that RPL6 binds with translation-related proteins and helicases, which coordinately affects the activities of a comprehensive signaling network, thereby inducing tolerance and promoting growth and yield in response to salt stress. Our overall findings identified a novel candidate, RPL6 whose characterization contributed to the existing knowledge on the complexity of salt tolerance mechanism in plants.