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A two-step adaptive walk rewires nutrient transport in a challenging edaphic environment

Emmanuel Tergemina, Ahmed F. Elfarargi, Paulina Flis, Andrea Fulgione, Mehmet Göktay, Célia Neto, Marleen Scholle, Pádraic J. Flood, Sophie-Asako Xerri, Johan Zicola, Nina Döring, Herculano Dinis, Ute Krämer, David E. Salt, Angela M. Hancock

2022Science Advances29 citationsDOIOpen Access PDF

Abstract

Most well-characterized cases of adaptation involve single genetic loci. Theory suggests that multilocus adaptive walks should be common, but these are challenging to identify in natural populations. Here, we combine trait mapping with population genetic modeling to show that a two-step process rewired nutrient homeostasis in a population of Arabidopsis as it colonized the base of an active stratovolcano characterized by extremely low soil manganese (Mn). First, a variant that disrupted the primary iron (Fe) uptake transporter gene ( IRT1 ) swept quickly to fixation in a hard selective sweep, increasing Mn but limiting Fe in the leaves. Second, multiple independent tandem duplications occurred at NRAMP1 and together rose to near fixation in the island population, compensating the loss of IRT1 by improving Fe homeostasis. This study provides a clear case of a multilocus adaptive walk and reveals how genetic variants reshaped a phenotype and spread over space and time.

Topics & Concepts

BiologyPopulationEdaphicFixation (population genetics)ArabidopsisAdaptation (eye)Evolutionary biologyGeneticsGeneEcologyMutantNeuroscienceDemographySociologySoil waterPlant Micronutrient Interactions and EffectsPlant nutrient uptake and metabolismPlant Stress Responses and Tolerance
A two-step adaptive walk rewires nutrient transport in a challenging edaphic environment | Litcius