Phyllosphere Bacterial Assemblage is Affected by Plant Genotypes and Growth Stages

Overview

Journal Microbiol Res

Specialties Biotechnology
Environmental Health
Microbiology

Date 2021 Mar 13

PMID 33713869

Citations 12

Authors

Yan Li

Zhenyan Zhang

Wanyue Liu

Mingjing Ke

Qian Qu

Zhigao Zhou

Tao Lu

Haifeng Qian

Affiliations

Soon will be listed here.

Abstract

The interaction between plants and microorganisms directly affects plant health and sustainable agricultural development. Leaves represent a wide-area habitat populated by a variety of microorganisms, whose impact on host environmental adaptability could influence plant growth and function. The driving factors for phyllosphere microbiota assemblage are the focus of current research. Here, we investigated the effect of growth stage (i.e., bolting, flowering, and maturation) and genotype of Arabidopsis thaliana (wild-type and the two photosynthetic mutants ndf4 and pgr5) on the composition of phyllosphere microbiota. Our results show that species abundance varied significantly between the three genotypes at different growth stages, whereas species richness and evenness varied only for ndf4. The leaf surface shared a core microbiota dominated by Proteobacteria, Actinobacteria, Bacteroidetes, and Firmicutes in all tested growth stages and genotypes. Phyllosphere specificity varied more with respect to growth stage than to genotype. In summary, both the growth stage and genotype of A. thaliana are crucial in shaping phyllosphere bacterial composition, with the former being a stronger driver. Our findings provide a novel for investigating whether the host properties influence the phyllosphere community and favor healthy development of plants.

Citing Articles

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Host selection is not a universal driver of phyllosphere community assembly among ecologically similar native New Zealand plant species.

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Roles of Phyllosphere Microbes in Rice Health and Productivity.

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Biocontrol agents transform the stability and functional characteristics of the grape phyllosphere microenvironment.

He T, Yang M, Du H, Du R, He Y, Wang S Front Plant Sci. 2024; 15:1439776.

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Diversity and potential functional role of phyllosphere-associated actinomycetota isolated from cupuassu (Theobroma grandiflorum) leaves: implications for ecosystem dynamics and plant defense strategies.

de Matos J, Ribeiro D, da Silva A, de Paula C, Cordeiro I, de Carvalho Lemes C Mol Genet Genomics. 2024; 299(1):73.

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