Tempo and mode of performance evolution across multiple independent origins of adhesive toe pads in lizards

Hagey, Travis J.; Uyeda, Josef C.; Crandell, Kristen E.; Cheney, Jorn A.; Autumn, Kellar; Harmon, Luke J.

doi:10.1111/evo.13318

Cited by 25 publications

(25 citation statements)

References 88 publications

(200 reference statements)

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“…A large body of work has shown that geckos exhibit sophisticated climbing behaviors and morphological specializations, such as toe‐peeling, a unique tendon structure, and other toepad modifications (e.g., blood‐filled sinuses and fat pads; Russell, ; Autumn et al, ). These behaviors and modifications result in gecko adhesive abilities that are more proficient than other toe pad‐bearing lizards of similar size (Hagey et al, ; Irschick et al, ). How these functional advantages are potentially translated into the use of a wider range of habitats remains an open question.…”

Section: Discussionmentioning

confidence: 99%

The relationship between habitat use and body shape in geckos

Kulyomina

Moen

Irschick

2019

Journal of Morphology

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Geckos are a highly diverse group of lizards, with more than 1,700 species that exhibit a wide range of behaviors, ecologies, and sizes. However, no study has examined links between habitat use and body shape in pad-bearing geckos. We set out to answer a basic question using a data set of padbearing geckos (112 species, 103 pad-bearing, 9 padless, 42 genera): Do geckos that occur in different habitats also differ in body shape? Overall, we found that body shape was surprisingly similar among our sample of pad-bearing species, with the exception of the genus Uroplatus, which was clearly distinct from other geckos due to its depressed body and long limbs. However, the padless geckos differed in body shape from the pad-bearing geckos by having longer arms and legs and less rotund bodies. We found that about half of the pad-bearing species primarily inhabit trees, with the other half, divided approximately equally among rocks, the ground, and mixed habitats. We found no significant links between habitat use and body shape, nor any propensity for larger species to occupy different habitats than smaller species. Padless species tend to inhabit rock and ground substrates. Our results indicate that pad-bearing geckos have a relatively uniform body form, which contrasts with to their diversity in color, size, and behavior. Indeed, our data show that the general gecko body shape is suitable for a wide range of habitats, ranging from arboreal to terrestrial. This pattern is a departure from other ecomorphological studies and suggests that geckos may not easily fit into the mold of adaptive radiation, as suggested by prior studies. K E Y W O R D S morphology, toepads, Gekkota, phylogenetic comparative method, principal components

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Section: Discussionmentioning

confidence: 99%

The relationship between habitat use and body shape in geckos

Kulyomina

Moen

Irschick

2019

Journal of Morphology

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“…Fields of microfibrillar setae adhere to contacted surfaces through van der Waals forces (Autumn, Dittmore, Santos, Spenko, & Cutkosky, ; Autumn et al, ; Tian et al, ). The ability to cling to substrates by means of subdigital pads has long been a topic of research (Collette, ; Delannoy, ; Elstrott & Irschick, ; Ernst & Ruibal, ; Gamble et al, ; Hagey, Puthoff, Holbrook, Harmon, & Autumn, ; Ruibal & Ernst, ), and several studies have aimed to determine factors that allow geckos to adhere to and detach from the substrates they move across, examining the locomotory substrate characteristics (Gillies et al, ; Meine, Kloss, Schneider, & Spaltmann, ; Persson & Gorb, ; Pugno & Lepore, ; Spolenak, Gorb, Gao, & Arzt, ), the mechanisms of adhesion (Autumn et al, ; Autumn, Niewiarowski, & Puthoff, ; Gao, Wang, Yao, Gorb, & Arzt, ; Irschick, Herrel, & Vanhooydonck, ; Mahendra, ; Tian et al, ), and variation in adhesion among species (Bergmann & Irschick, ; Garner, Stark, Thomas, & Niewiarowski, ; Hagey et al, , ; Irschick et al, ; Stark, Klittich, Sitti, Niewiarowski, & Dhinojwala, ; Stark et al, ).…”

Section: Introductionmentioning

confidence: 99%

“…The gekkotan adhesive system has evolved to enable the exploitation of inclined and inverted surfaces on rocks, or vegetation, with recent expansions onto man‐made structures by some species (Glossip & Losos, ; Gamble et al, ; Hagey et al, ; Ruibal & Ernst, ). The mechanism and dynamics of adhesion, however, have almost exclusively been examined using a variety of smooth (Autumn et al, ; Gillies & Fearing, ; Irschick et al, ; Peressadko & Gorb, ; Russell & Johnson, ; Stewart & Higham, ) and very fine‐grained man‐made surfaces (i.e., glass, Teflon, variations of polyethylene, polyvinyl chloride, aluminum bonding wire, acrylic, and acetate sheets; Campolo, Jones, & Fearing, ; Gillies & Fearing, ; Huber, Gorb, Hosoda, Spolenak, & Arzt, ; Meine et al, ; Persson, ; Persson & Gorb, ; Pugno & Lepore, ; Vanhooydonck, Andronescu, Herrel, & Irschick, ; Winchell, Reynolds, Prado‐Irwin, Puente‐Rolón, & Revell, ), most of them not encountered by geckos under natural conditions.…”

Section: Introductionmentioning

confidence: 99%

Nonlinear variation in clinging performance with surface roughness in geckos

Pillai

Nordberg

Riedel

et al. 2020

Ecology and Evolution

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Understanding the challenges faced by organisms moving within their environment is essential to comprehending the evolution of locomotor morphology and habitat use. Geckos have developed adhesive toe pads that enable exploitation of a wide range of microhabitats. These toe pads, and their adhesive mechanisms, have typically been studied using a range of artificial substrates, usually significantly smoother than those available in nature. Although these studies have been fundamental in understanding the mechanisms of attachment in geckos, it is unclear whether gecko attachment simply gradually declines with increased roughness as some researchers have suggested, or whether the interaction between the gekkotan adhesive system and surface roughness produces nonlinear relationships. To understand ecological challenges faced in their natural habitats, it is essential to use test surfaces that are more like surfaces used by geckos in nature. We tested gecko shear force (i.e., frictional force) generation as a measure of clinging performance on three artificial substrates. We selected substrates that exhibit microtopographies with peak‐to‐valley heights similar to those of substrates used in nature, to investigate performance on a range of smooth surfaces (glass), and fine‐grained (fine sandpaper) to rough (coarse sandpaper). We found that shear force did not decline monotonically with roughness, but varied nonlinearly among substrates. Clinging performance was greater on glass and coarse sandpaper than on fine sandpaper, and clinging performance was not significantly different between glass and coarse sandpaper. Our results demonstrate that performance on different substrates varies, probably depending on the underlying mechanisms of the adhesive apparatus in geckos.

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“…With more than 1,714 species in 124 genera inhabiting all warm continental land masses and thousands of intervening continental and oceanic islands, geckos are one of the most species‐rich, abundant, and widely distributed of all squamate lineages (Gamble et al., ; Pincheira‐Donoso, Bauer, Meiri, & Uetz, ; Uetz, Freed, & Hošek, ). Geckos are also very well known by the extraordinary climbing abilities of some of the groups, enabled by complex digital adhesive mechanisms whose evolution seems to be absent of substantial selective constraints, allowing them to adapt and interact with their environment in many different ways compared with other lizards (Gamble, Greenbaum, Jackman, Russell, & Bauer, ; Hagey et al., ). Another important trait of geckos is their ancestral nocturnal habits, still present in more than 70% of the species and with several independent transitions to diurnality and some secondary transitions back to nocturnality (Gamble, Greenbaum, Jackman, & Bauer, ).…”

Section: Introductionmentioning

confidence: 99%

Systematics of the Saharo‐Arabian clade of the Palearctic naked‐toed geckos with the description of a new species ofTropiocolotesendemic to Oman

Machado

Šmı́d

Mazuch³

et al. 2018

J Zool Syst Evol Res

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Geckos are one of the most species‐rich, abundant, and widely distributed of all Squamata lineages and present several characteristics that have made them favorite model organisms for biogeographical, ecological, physiological, and evolutionary studies. One of the key aspects of any comparative study is to have a robust, comprehensive phylogeny, and an updated taxonomy. Recently, the Infraorder Gekkota has been the subject of several phylogenetic analyses and taxonomic revisions at different levels. Despite all these phylogenetic and taxonomic advances, there are still some groups whose systematics and taxonomy remain highly problematic. Maybe one of the most poorly resolved groups in spite of decades of intensive research by many herpetologists are the so‐called Palearctic naked‐toed geckos of the family Gekkonidae. This group of nocturnal geckos distributed from Mauritania across North Africa, Arabia, southwestern and central Asia to northern India, western China and southern Mongolia is characterized by the synapomorphy of lack of adhesive subdigital pads. Within the Palearctic naked‐toed geckos, the Saharo‐Arabian clade comprised by the genera Pseudoceramodactylus, Stenodactylus, and Tropiocolotes is the clade with the largest distribution range. At the same time, it is one of the problematic groups, presenting poorly supported phylogenetic relationships, with the genus Tropiocolotes being recovered non‐monophyletic in all analyses despite its morphological uniformity. To reassess the phylogeny of the Palearctic naked‐toed geckos with a special interest in the systematics of Tropiocolotes, we assembled a dataset comprising 298 gecko specimens from 283 different species (including all Tropiocolotes species but one) belonging to 122 of a total of 124 described gecko genera. This dataset included the nuclear c‐mos, ACM4, RAG1, RAG2, and PDC and the mitochondrial ND2 gene. To further investigate the relationships within Tropiocolotes and to revise the systematics of the south Arabian endemic species Tropiocolotes scorteccii, we used an integrative approach including information from the nuclear MC1R and c‐mos, the mitochondrial 12S, 16S, cytb genes, and morphological data from nine of the 10 described Tropiocolotes species. The phylogenetic analyses of the Gekkota dataset recovered a similar topology for the Palearctic naked‐toed geckos to previous studies, but in this case, Tropiocolotes was recovered monophyletic in all analyses, with high support in two of them. The results of the analyses of three datasets specifically assembled to test the effect of both gene sampling and taxon sampling in the monophyly of Tropiocolotes, and the internal relationships of the Palearctic naked‐toed geckos clearly showed that both the number and kind of characters (nuclear or mitochondrial data) and the number of taxa played a fundamental role in recovering the correct phylogenetic relationships. The phylogenetic analyses within Tropiocolotes suggested the existence of high levels of undescribed diversity in the south ...

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Tempo and mode of performance evolution across multiple independent origins of adhesive toe pads in lizards

Cited by 25 publications

References 88 publications

The relationship between habitat use and body shape in geckos

The relationship between habitat use and body shape in geckos

Nonlinear variation in clinging performance with surface roughness in geckos

Systematics of the Saharo‐Arabian clade of the Palearctic naked‐toed geckos with the description of a new species ofTropiocolotesendemic to Oman

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