Improved Nodulation Under Stress Assisted by Sp. Endophytes

Overview

Journal Plants (Basel)

Date 2022 Apr 21

PMID 35448819

Authors

Noris J Flores-Duarte

Julia Perez-Perez

Salvadora Navarro-Torre

Enrique Mateos-Naranjo

Susana Redondo-Gomez

Eloisa Pajuelo

Ignacio D Rodriguez-Llorente

Affiliations

Soon will be listed here.

Abstract

Legumes are the recommended crops to fight against soil degradation and loss of fertility because of their known positive impacts on soils. Our interest is focused on the identification of plant-growth-promoting endophytes inhabiting nodules able to enhance legume growth in poor and/or degraded soils. The ability of S110 and JM-310 to promote alfalfa growth in nutrient-poor and metal-contaminated estuarine soils was studied. Both strains behaved as nodule endophytes and improved in vitro seed germination and plant growth, as well as nodulation in co-inoculation with MA11. ameliorated the physiological status of the plant, increased nodulation, chlorophyll and nitrogen content, and the response to stress and metal accumulation in the roots of alfalfa growing in degraded soils with moderate to high levels of contamination. The presence of plant-growth-promoting traits in , particularly ACC deaminase activity, could be under the observed in planta effects. Although the couple -MA11 reported a great benefit to plant growth and nodulation, the best result was observed in plants inoculated with the combination of the three bacteria. These results suggest that strains could be used as biofertilizers to improve the adaptation of legumes to degraded soils in soil-recovery programs.

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