Abstract
Plant roots co-inhabit the soil with a diverse consortium of microbes of which a number attempt to enter symbiosis with the plant. These microbes may be pathogenic, mutualistic, or commensal. Hence, the health and survival of plants is heavily reliant on their ability to perceive different microbial lifestyles and respond appropriately. Emerging research suggests that there is a pivotal role for plant root secondary metabolites in responding to microbial colonization. However, it is largely unknown if plants are able to differentiate between microbes of different lifestyles and respond differently during the earliest stages of pre-symbiosis (i.e., prior to physical contact). In studying plant responses to a range of microbial isolates, we questioned: (1) if individual microbes of different lifestyles and species caused alterations to the plant root metabolome during pre-symbiosis, and (2) if these early metabolite responses correlate with the outcome of the symbiotic interaction in later phases of colonization. We compared the changes of the root tip metabolite profile of the model tree Eucalyptus grandis during pre-symbiosis with two isolates of a pathogenic fungus (Armillaria luteobubalina), one isolate of a pathogenic oomycete (Phytophthora cinnamomi), two isolates of an incompatible mutualistic fungus (Suillus granulatus), and six isolates of a compatible mutualistic fungus (Pisolithus microcarpus). Untargeted metabolite profiling revealed predominantly positive root metabolite responses at the pre-symbiosis stage, prior to any observable phenotypical changes of the root tips. Metabolite responses in the host tissue that were specific to each microbial species were identified. A deeper analysis of the root metabolomic profiles during pre-symbiotic contact with six strains of P. microcarpus showed a connection between these early metabolite responses in the root with later colonization success. Further investigation using isotopic tracing revealed a portion of metabolites found in root tips originated from the fungus. RNA-sequencing also showed that the plant roots undergo complementary transcriptomic reprogramming in response to the fungal stimuli. Taken together, our results demonstrate that the early metabolite responses of plant roots are partially selective toward the lifestyle of the interacting microbe, and that these responses can be crucial in determining the outcome of the interaction.
Highlights
The rhizosphere is a narrow zone of soil adjacent to plant roots where soil microbes interact with, and influence, plant physiology (Hartmann et al, 2008, 2009)
P. microcarpus and S. granulatus isolates were cultured on the halfstrength modified Melin-Norkrans (MMN) media, while Ph. cinnamomi and A. luteobubalina were cultured on V8 agar media (30mM CaCO3, 15 g/L agar, 20% (v/v) V8 juice in de-ionized water, pH 7.2 ± 0.2) and potato dextrose agar (PDA) media (39 g/L PDA powder (Sigma-Aldrich) in de-ionized water), respectively, for 14 days prior to setting up the pre-symbiosis interaction
Using liquid chromatogram coupledmass spectrometry (LC-MS)-based untargeted metabolite profiling, a total of 1,868 and 2,226 molecular features were identified in 48 E. grandis root tip samples across all treatments in the ESI+ and ESI− mode, respectively (Supplementary Tables 1, 2)
Summary
The rhizosphere is a narrow zone of soil adjacent to plant roots where soil microbes interact with, and influence, plant physiology (Hartmann et al, 2008, 2009). Interactions occurring at this interface significantly impact the soil microbial community structure (Baudoin et al, 2003; Broeckling et al, 2008). This root-microbe interaction is mainly mediated by the exchange of chemical signals as demonstrated by identification of metabolites in root exudates that can attract or defend against certain microbes (Steinkellner et al, 2007; Badri and Vivanco, 2009; Baetz and Martinoia, 2014). A recent comparative study has demonstrated significant differences in the responsiveness of roots interacting with the rhizobia of different species, impacting compatibility at an early stage of interaction (i.e., 1–3 days; Kelly et al, 2018). We are currently lacking a comprehensive study of how the global metabolic profile of plant roots changes in response to different microbial lifestyles and to different microbial isolates within one species
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