Professor University of Toronto Toronto, Ontario, Canada
Abstract: An organism's phenotypes and fitness often depend on interactive effects of its genome (Ghost), microbiome (Gmicrobe), and environment (E). These GxG, GxE, and GxGxE effects fundamentally shape host-microbiome interactions and may be widespread, but are rarely compared within a single experiment. We collected and cultured Lemna minor (duckweed) and its associated microbiome from 10 sites across an urban-to-rural ecotone. We factorially manipulated host genotype and microbiome in two environments (low and high zinc, an urban aquatic stressor) in a laboratory microcosm experiment with 200 treatments: 10 host genotypes X 10 microbiomes X 2 environments. Host genotype explained the most variation in L. minor fitness and traits, while microbiome effects often depended on host genotype (GxG). Microbiome composition predicted GxG effects: when compared in more similar microbiomes, duckweed genotypes had more similar effects on traits. Further, hosts fitness increased and microbes grew faster when applied microbiomes more closely matched the host's field microbiome, suggesting some local adaptation between hosts and microbiota. Finally, selection on and heritability of host traits shifted across microbiomes and zinc exposure. Thus, we found that microbiomes impact host fitness, trait expression, and heritability, with implications for host-microbiome evolution and microbiome breeding.
