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Cadmium-resistant bacterium Ralstonia sp. YDR alleviated Cd toxicity in rice seedlings by enhancing antioxidant defense and inhibiting Cd2+ influx and H+ efflux

Daixia Yin, Li-Lu Niu, Jing Liu, Rui Yang, Bing Han, Zhou-Yu Liu, Yong-He Han, Xiaoli Zhao

2024Environmental Technology & Innovation10 citationsDOIOpen Access PDF

Abstract

Cadmium (Cd) accumulation in rice (Oryza sativa L.) and its potential risks for human health have attracted great attention. Several Cd-resistant bacteria can promote plant growth and alleviate Cd toxicity to rice, but how they regulate Cd2+ flux in rice roots is still poorly understood. Here, a new Cd-resistant endophytic bacterium Ralstonia sp. YDR was isolated and used to evaluate its role in reducing rice Cd accumulation. Ralstonia sp. YDR tolerated 80 mg L−1 Cd and removed amounts of Cd via bio-adsorption and bio-absorption. The strain also harbored good alkalizing ability and exhibited typical plant growth-promoting characteristics. Hydroponic experiments showed that inoculation with Ralstonia sp. YDR not only significantly promoted rice growth but also decreased rice Cd by 14.4-41.3%. Further analyses verified the involvement of Ralstonia sp. YDR in increasing the activities of CAT, GSH, POD, and SOD by 27.7-77.3%, 1.7-57.6%, 57.4-100.8%, and 5.31-60.2%, and decreasing the activity of MDA by up to 56% in rice seedlings as compared with control. Moreover, a significant reduction in Cd2+ influx and H+ efflux occurred in rice roots after inoculating with Ralstonia sp. YDR. Collectively, bacterial adsorption and absorption of Cd, bacteria-aided antioxidation, and bacterial regulation of Cd2+ and H+ flux all contributed to a low Cd accumulation in rice. Our study provides new clues to better understand microbial mechanisms underlying the low Cd accumulation in rice plants, which helps to enhance the production of low Cd rice in agricultural practice.

Topics & Concepts

CadmiumRalstonia solanacearumRalstoniaOryza sativaBacteriaInoculationEffluxBiologyMicrobiologyFood scienceChemistryBotanyHorticultureBiochemistryGeneticsOrganic chemistryGeneHeavy metals in environmentGeochemistry and Elemental AnalysisPlant Stress Responses and Tolerance
Cadmium-resistant bacterium Ralstonia sp. YDR alleviated Cd toxicity in rice seedlings by enhancing antioxidant defense and inhibiting Cd2+ influx and H+ efflux | Litcius