Litcius/Paper detail

Soil as an extended composite phenotype of the microbial metagenome

Andrew L. Neal, Aurélie Bacq-Labreuil, Xiaoxian Zhang, Ian M. Clark, K. Coleman, Sacha J. Mooney, Karl Ritz, John W. Crawford

2020Scientific Reports90 citationsDOIOpen Access PDF

Abstract

We use a unique set of terrestrial experiments to demonstrate how soil management practises result in emergence of distinct associations between physical structure and biological functions. These associations have a significant effect on the flux, resilience and efficiency of nutrient delivery to plants (including water). Physical structure, determining the air-water balance in soil as well as transport rates, is influenced by nutrient and physical interventions. Contrasting emergent soil structures exert selective pressures upon the microbiome metagenome. These selective pressures are associated with the quality of organic carbon inputs, the prevalence of anaerobic microsites and delivery of nutrients to microorganisms attached to soil surfaces. This variety results in distinctive gene assemblages characterising each state. The nature of the interactions provide evidence that soil behaves as an extended composite phenotype of the resident microbiome, responsive to the input and turnover of plant-derived organic carbon. We provide new evidence supporting the theory that soil-microbe systems are self-organising states with organic carbon acting as a critical determining parameter. This perspective leads us to propose carbon flux, rather than soil organic carbon content as the critical factor in soil systems, and we present evidence to support this view.

Topics & Concepts

Environmental scienceMetagenomicsSoil carbonNutrientCarbon fibersSoil organic matterEcologySoil waterBiologySoil scienceComputer scienceComposite numberGeneBiochemistryAlgorithmSoil Carbon and Nitrogen DynamicsMicrobial Community Ecology and PhysiologyGut microbiota and health
Soil as an extended composite phenotype of the microbial metagenome | Litcius