Nonpathogenic Leaf-colonizing Bacteria Elicit Pathogen-like Responses in a Colonization Density-dependent Manner

Overview

Journal Plant Environ Interact

Date 2024 Mar 14

PMID 38482131

Authors

Moritz Miebach

Lea Faivre

Daniel Schubert

Paula Jameson

Mitja Remus-Emsermann

Affiliations

Soon will be listed here.

Abstract

Leaves are colonized by a complex mix of microbes, termed the leaf microbiota. Even though the leaf microbiota is increasingly recognized as an integral part of plant life and health, our understanding of its interactions with the plant host is still limited. Here, mature, axenically grown plants were spray inoculated with six diverse leaf-colonizing bacteria. The transcriptomic changes in leaves were tracked over time and significant changes in ethylene marker () expression were observed only 2-4 days after spray inoculation. Whole-transcriptome sequencing revealed that 4 days after inoculation, leaf transcriptional changes to colonization by nonpathogenic and pathogenic bacteria differed in strength but not in the type of response. Inoculation of plants with different densities of the nonpathogenic bacterium sp. Leaf354 showed that high bacterial titers resulted in disease phenotypes and led to severe transcriptional reprogramming with a strong focus on plant defense. An in silico epigenetic analysis of the data was congruent with the transcriptomic analysis. These findings suggest (1) that plant responses are not rapid after spray inoculation, (2) that plant responses only differ in strength, and (3) that plants respond to high titers of nonpathogenic bacteria with pathogen-like responses.

Citing Articles

Plant microbiota feedbacks through dose-responsive expression of general non-self response genes.

Keppler A, Roulier M, Pfeilmeier S, Petti G, Sintsova A, Maier B Nat Plants. 2024; 11(1):74-89.

PMID: 39627368 PMC: 11757152. DOI: 10.1038/s41477-024-01856-z.

Nonpathogenic leaf-colonizing bacteria elicit pathogen-like responses in a colonization density-dependent manner.

Miebach M, Faivre L, Schubert D, Jameson P, Remus-Emsermann M Plant Environ Interact. 2024; 5(2):e10137.

PMID: 38482131 PMC: 10934995. DOI: 10.1002/pei3.10137.

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