Blowing in the wind: Experimental assessment of clinging performance and behaviour in Anolis lizards during hurricane‐force winds

摘要

Abstract Extreme weather events, such as hurricanes, can be ecologically devastating and cause widespread mortality. Recent studies in Anolis lizards report hurricane‐induced phenotypic shifts and selection favouring morphological variation related to clinging performance. Although it is difficult to observe organismal responses during extreme events in nature, we can experimentally simulate the high‐speed winds associated with hurricanes to evaluate the putative mechanism underlying observed patterns of natural selection. In this study, we used two laboratory experiments to better understand the clinging performance and behaviour of Anolis lizards when experiencing hurricane‐force winds. We assessed the physical ability of lizards when using the combined function of their claws, limbs, toepads and other traits to resist forces pulling them off a perch. We also evaluated the combination of this physical clinging ability of lizards and their behavioural responses to avoid being blown off a perch during high winds. We assessed behaviour that could decrease exposure of lizards to wind and increase their clinging ability. Clinging force measurements revealed variation in performance among species and substrates not reflected in clinging times for lizards experiencing hurricane‐force winds, revealing the importance of behaviour when experiencing high winds. The most arboreal species (A. carolinensis) had substantially longer clinging times on rough substrates compared with the other species, presumably due to its larger toepads for increased clinging as well as its shorter limbs that reduced drag. Under high‐speed winds, lizards commonly shifted to the more protected leeward side of dowels, especially on broad and rough substrates, presumably to reduce exposure. This reveals how behaviour can mediate factors influencing clinging ability during hurricanes and, in conjunction with ecologically relevant variation in morphology and substrate properties, contribute to clinging performance. Our experiments reveal that behaviour strongly influences clinging performance during high winds beyond that predicted by physical traits alone. Thus, microhabitat selection of perches and the position of a lizard on its perch during a hurricane will likely have important consequences for clinging performance. This may alter how selection acts on morphological traits and influence the susceptibility of different species to these extreme weather events. Read the free Plain Language Summary for this article on the Journal blog.