Adaptive zinc tolerance is supported by extensive gene multiplication and differences in cis-regulation of a CDF transporter in an ectomycorrhizal fungus

Autor: Jan V. Colpaert, Michiel Op De Beeck, Joske Ruytinx, Natascha Arnauts, Laura Coninx, Francois Rineau
Rok vydání: 2019
Předmět:
Popis: SummaryAbiotic changes due to anthropogenic activities affect selection regimes for organisms. How trees and their mycorrhizal symbionts adapt to altered environments in heterogeneous landscapes is of great interest. With a global distribution and multiple adaptive phenotypes available,Suillus luteusis an excellent ectomycorrhizal model to study evolutionary dynamics of local adaptation. We assessed pathways of homeostasis and detoxification inS. luteusisolates, displaying contrasting Zn tolerance phenotypes to identify mechanisms underlying adaptive Zn tolerance. Using 30 randomly selected isolates sampled at metal contaminated and control sites, we documented Zn tolerance phenotypes, assessed the link with identified candidate genes and explored its genetic basis via targeted amplicon sequencing and qPCR. Zn tolerance phenotypes covering a continuum from Zn sensitive to hypertolerant were identified and inversely correlate with cellular Zn accumulation. Gene expression ofSlZnT2, encoding a putative Zn transporter explains 72% of the observed phenotypic variation.SlZnT2copy number varies among isolates and different promotor genotypes were identified. Rapid adaptation in this species is supported by the cumulative effect of gene copy number variation and differences in cis-regulation and might be triggered by environmental stress rather than being the result of standing variation.Originality - significance statementTo the best of our knowledge, this is the first study linking genotypes to adaptive phenotypes in mycorrhizal fungi. It is unique in the way it combines evolutionary and functional genetics to allow a significant advance in the understanding of responses to environmental stress factors in general and, to soil metal pollution in particular. A better understanding of adaptive tolerance mechanisms in keystone symbiotic fungi is paramount for developing impactful phyto and mycoremediation strategies for metal polluted waste land and to predict the impact of future environmental change on mycorrhizal diversity and ecosystem functioning.
Databáze: OpenAIRE