Heritable Variation in Thermal Profiles is Associated with Reproductive Success in the World's Largest Bird

Overview

Journal Evol Lett

Publisher Oxford University Press

Specialty Biology

Date 2024 Mar 25

PMID 38525029

Authors

Erik I Svensson

Mads F Schou

Julian Melgar

John Waller

Anel Engelbrecht

Zanell Brand

Schalk Cloete

Charlie K Cornwallis

Affiliations

Soon will be listed here.

Abstract

Organisms inhabiting extreme thermal environments, such as desert birds, have evolved spectacular adaptations to thermoregulate during hot and cold conditions. However, our knowledge of selection for thermoregulation and the potential for evolutionary responses is limited, particularly for large organisms experiencing extreme temperature fluctuations. Here we use thermal imaging to quantify selection and genetic variation in thermoregulation in ostriches (), the world's largest bird species that is experiencing increasingly volatile temperatures. We found that females who are better at regulating their head temperatures ("thermoregulatory capacity") had higher egg-laying rates under hotter conditions. Thermoregulatory capacity was both heritable and showed signatures of local adaptation: females originating from more unpredictable climates were better at regulating their head temperatures in response to temperature fluctuations. Together these results reveal that past and present evolutionary processes have shaped genetic variation in thermoregulatory capacity, which appears to protect critical organs, such as the brain, from extreme temperatures during reproduction.

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