Microbial Drivers of Plant Performance during Drought Depend upon Community Composition and the Greater Soil Environment

Eric R. Moore, Kelsey R. Carter, John P. Heneghan, Christina R. Steadman, Abigael C. Nachtsheim, Christine Anderson-Cook, L. Turin Dickman, Brent D. Newman, John Dunbar, Sanna Sevanto, Michaeline B.N. Albright

Research output: Contribution to journalArticlepeer-review

8 Scopus citations

Abstract

The increasing occurrence of drought is a global challenge that threatens food security through direct impacts to both plants and their interacting soil microorganisms. Plant growth promoting microbes are increasingly being harnessed to improve plant performance under stress. However, the magnitude of microbiome impacts on both structural and physiological plant traits under water limited and water replete conditions are not well-characterized. Using two microbiomes sourced from a ponderosa pine forest and an agricultural field, we performed a greenhouse experiment that used a crossed design to test the individual and combined effects of the water availability and the soil microbiome composition on plant performance. Specifically, we studied the structural and leaf functional traits of maize that are relevant to drought tolerance. We further examined how microbial relationships with plant phenotypes varied under different combinations of microbial composition and water availability. We found that water availability and microbial composition affected plant structural traits. Surprisingly, they did not alter leaf function. Maize grown in the forest-soil microbiome produced larger plants under well-watered and water-limited conditions, compared to an agricultural soil community. Although leaf functional traits were not significantly different between the watering and microbiome treatments, the bacterial composition and abundance explained significant variability in both plant structure and leaf function within individual treatments, especially water-limited plants. Our results suggest that bacteria-plant interactions that promote plant performance under stress depend upon the greater community composition and the abiotic environment. IMPORTANCE Globally, drought is an increasingly common and severe stress that causes significant damage to agricultural and wild plants, thereby threatening food security. Despite growing evidence of the potential benefits of soil microorganisms on plant performance under stress, decoupling the effects of the microbiome composition versus the water availability on plant growth and performance remains a challenge. We used a highly controlled and replicated greenhouse experiment to understand the impacts of microbial community composition and water limitation on corn growth and drought-relevant functions. We found that both factors affected corn growth, and, interestingly, that individual microbial relationships with corn growth and leaf function were unique to specific watering/microbiome treatment combinations. This finding may help explain the inconsistent success of previously identified microbial inocula in improving plant performance in the face of drought, outside controlled environments.

Original languageEnglish
Article number01476-22
JournalMicrobiology Spectrum
Volume11
Issue number2
DOIs
StatePublished - Mar 2023
Externally publishedYes

Funding

We thank Dea Musa, Tony Sabella, Chris Yeager, Anastasiia Kim, Nick Lubbers, Sangeeta Negi, Scott Twary, Louise Comas, Jason Gans, and Jeff Heikoop for their contributions to the experiment, and the USDA National Plant Germplasm System for providing the B73 maize seeds used in this study. Funding for this work was provided by the Laboratory Directed Research and Development program of Los Alamos National Laboratory (Project Number 20200109DR).

FundersFunder number
USDA National Plant Germplasm System
Laboratory Directed Research and Development
Los Alamos National Laboratory20200109DR

    Keywords

    • Plant microbiome
    • drought
    • microbial composition
    • plant growth
    • plant-microbe interactions
    • soil ecology

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