Beneficial rhizobacteria mitigate combined water and phosphorus deficit effects on upland rice

Abstract

Background and aims Limited water and phosphorus availability are major challenges in upland rice production. Plant-microbe interactions, especially with beneficial rhizobacteria, have shown promise in mitigating these stresses. This study investigated the influence of microbial inoculants with hydration-promoting and phosphorus-solubilizing abilities on upland rice yield under drought and phosphorus deficiency. Methods Upland rice (BRS Esmeralda) plants were grown in a greenhouse with different water availability conditions (well-watered and drought), phosphorus levels (high 200 mg dm^− 3 and low 20 mg dm^− 3), and microbial treatments (no-microorganism and single and combined isolates of BRM 32114 and BRM 63523). Root and shoot traits, as well as production components, were analyzed. Results While the microbial treatments affected the roots, the larger effects were seen in the shoot rice plants. When both water and phosphorus were limited, grain yield decreased significantly. However, plants inoculated with beneficial rhizobacteria showed a substantial increase in grain yield (average of 39.5% in 2019/2020 and 18.8% in 2020/2021) compared to uninoculated plants under combined stresses. This increase was especially pronounced in plants treated with BRM 63523 (strain) alone or combined with BRM 32114 (strain), both Serratia marcescens. These inoculated plants also showed improved photosynthetic activity (average increase of 24.6%), which may have contributed to the higher grain yield. Conclusions Inoculating upland rice with specific Serratia strains effectively increased shoot and root traits under combined water and phosphorous stresses. These findings highlight the potential of plant-microbe interactions for sustainable upland rice production.