Domestication and Lowland Adaptation of Coastal Preceramic Maize from Paredones, Peru

Overview

Journal Elife

Specialty Biology

Date 2023 Apr 18

PMID 37070964

Authors

Miguel Vallebueno-Estrada

Guillermo G Hernandez-Robles

Eduardo Gonzalez-Orozco

Ivan Lopez-Valdivia

Teresa Rosales Tham

Victor Vasquez Sanchez

Kelly Swarts

Tom D Dillehay

Jean-Philippe Vielle-Calzada

Rafael Montiel

Affiliations

Soon will be listed here.

Abstract

Archaeological cobs from Paredones and Huaca Prieta (Peru) represent some of the oldest maize known to date, yet they present relevant phenotypic traits corresponding to domesticated maize. This contrasts with the earliest Mexican macro-specimens from Guila Naquitz and San Marcos, which are phenotypically intermediate for these traits, even though they date more recently in time. To gain insights into the origins of ancient Peruvian maize, we sequenced DNA from three Paredones specimens dating ~6700-5000 calibrated years before present (BP), conducting comparative analyses with two teosinte subspecies ( ssp. and ) and extant maize, that include highland and lowland landraces from Mesoamerica and South America. We show that Paredones maize originated from the same domestication event as Mexican maize and was domesticated by ~6700 BP, implying rapid dispersal followed by improvement. Paredones maize shows no relevant gene flow from , smaller than that observed in teosinte . Thus, Paredones samples represent the only maize without confounding variation found to date. It also harbors significantly fewer alleles previously found to be adaptive to highlands, but not of alleles adaptive to lowlands, supporting a lowland migration route. Our overall results imply that Paredones maize originated in Mesoamerica, arrived in Peru without introgression through a rapid lowland migration route, and underwent improvements in both Mesoamerica and South America.

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