Abstract
While individual tree genotypes are known to differ in their impacts on local soil development, the spatial genetic influence of surrounding neighboring trees is largely unknown. We examine the hypothesis that fine root dynamics of a focal tree is based on the genetics of the focal tree as well as the genetics of neighbor trees that together define litter inputs to soils of the focal tree. We used a common garden environment with clonal replicates of individual tree genotypes to analyze fine root production, turnover and allocation with respect to modeled neighborhood: 1) foliar mass, 2) foliar condensed tannins (CT), 3) genetic identity of trees, and 4) genetic dissimilarity of neighbors. In support of our central hypothesis, we found that the presence of genetically dissimilar trees and high leaf CT contributions to the soil predicted increased fine root production. In fact, the modeled effects of neighbors accounted for ~90% of the explanatory weight of all models predicting root production. Nevertheless, the ultimate fate of those roots in soil (turnover) and the balance of fine roots relative to aboveground tree mass were still more predictable based on the genetics of the individual focal trees (explaining 99% of the variation accounted for by models). Our data provide support for a method allowing a comparison of the relative effects of individuals versus spatial neighborhood effects on soils in a genetic context. Such comparisons are important for placing plant-soil feedbacks in a genetic and evolutionary framework since neighbors can decouple feedbacks between an individual and the surrounding environment.
Highlights
Fine roots represent a fundamentally important component of ecosystem carbon (C) and nutrient cycles (Norby and Jackson, 2000; Litton et al, 2007)
Based on the above logic, we address the central hypothesis that the genetic and phenotypic neighborhood has a significant impact on fine root dynamics through leaf-litter input to soils
In support of our central hypothesis that plant genetic and phenotypic neighborhoods should affect ecosystem function, the best two models predicting fine root production were: (1) a model based on neighbor genetic dissimilarity, where fine root production increased as neighbors were on average genetically more dissimilar to the focal tree; and (2) a model where fine root production increased as neighbor foliar condensed tannins (CT) inputs to soils increased
Summary
Fine roots represent a fundamentally important component of ecosystem carbon (C) and nutrient cycles (Norby and Jackson, 2000; Litton et al, 2007). Many studies examine the effects of neighbors on individual plant growth, facilitation, and competition (Aerts, 1999; Callaway, 2002; Maina et al, 2002; Cahill et al, 2010), and it is wellunderstood that individual plant effects on soils and plant-soil feedbacks have major effects on ecosystem function (Freschet et al, 2012; Bardgett and van der Putten, 2014; Waring et al, 2015) In combination, such studies placed within a genetics framework may allow researchers to evaluate plant-soil feedbacks within the context of evolution and spatially complex biotic environments
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