Mechanistic basis of temperature-adaptation in microtubule dynamics across frog species

Abstract

SUMMARYCellular processes are remarkably effective across diverse temperature ranges, even with highly conserved proteins. In the context of the microtubule cytoskeleton, which is critically involved in a wide range of cellular activities, this is particularly striking as tubulin is one of the most conserved proteins while microtubule dynamic instability is highly temperature sensitive. We thus lack a mechanistic framework that links functional adaptability with environmental pressures. Here, we leverage the diversity of natural tubulin variants from three closely related frog species that live at different temperatures: we combinein vitroreconstitution assays, quantitative biochemistry, and cryogenic electron microscopy to show how a small number of primary sequence changes influences the energy landscape of tubulin interactions and thereby mediates cold-adaptation and microtubule stability. This study thus broadens our conceptual framework for understanding microtubule dynamics and provides insights into how conserved cellular processes are tailored to different ecological niches.