Melatonin production by rhizobacteria native strains: Towards sustainable plant growth promotion strategies

根际细菌 生物 耐旱性 非生物胁迫 拟南芥 植物生理学 非生物成分 植物 背景(考古学) 氯仿假单胞菌 假单胞菌 细菌 根际 生态学 生物化学 古生物学 突变体 基因 遗传学
作者
María Florencia Jofré,Sabrina B. Mammana,Martín Lopez Appiolaza,María Fernanda Silva,Federico J.V. Gómez,Ana Carmen Cohen
出处
期刊:Physiologia Plantarum [Wiley]
卷期号:175 (1): e13852-e13852 被引量:18
标识
DOI:10.1111/ppl.13852
摘要

In the current context of climate change and water deficit, the selection of native beneficial microorganisms, such as plant growth-promoting rhizobacteria (PGPR), has become a trend for sustainable agriculture due to their ability to improve plant-bacteria interaction with a minimal adverse effect on the soil microbiota compared to commercial PGPR. Until now, the production of phytohormones like melatonin (MT) by native PGPR and their effect on endogenous MT levels in plants have been poorly studied. MT is a ubiquitous phytohormone that protects plants against biotic and abiotic stress by improving the tolerance of stressed plants. In this work, the production of MT by two native PGPR, Enterobacter 64S1 and Pseudomonas 42P4, was evaluated and both PGPR were applied in Arabidopsis thaliana plants grown under drought conditions to assess the inoculation effects. Parameters such as plant growth, leaf cellular membrane damage, leaf protective compounds, and endogenous MT levels under drought and irrigation conditions were evaluated. The results demonstrated that the native strains Pseudomonas 42P4 and Enterobacter 64S1 produce MT and increase the content of endogenous MT in A. thaliana plants under drought. These native strains improved the tolerance of arabidopsis plants to drought by preventing oxidative and membrane damages and improving plant growth. To the best of our knowledge, this is the first report on MT production by native PGPR and their effects on endogenous MT levels in arabidopsis plants, setting the bases to elucidate the role of native PGPR on water deficit conditions.
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