from the Wildlife Society:

Florida towns facilitate spread of knight anoles

March 2, 2026

News, Wildlife News

by Joshua Rapp Learn

Giant Cuban anoles have found footholds in habitats across Florida thanks to expanding human development over the past decades.

Or, “Prey depletion by a predator guild suggests spatial differences in competitive ability, but not prey partitioning, consistent with functional trade‐offs.”

Anole biologists may take for granted that anoles compete. We have plenty of evidence, after all, for the phenomenon of interspecific competition — when comparing populations in sympatry vs. allopatry, we often see reductions in fitness, shifts in resource use, or trait evolution to minimize resource use overlap. It may surprise you, then, that we actually have relatively little insight into the mechanisms of competition in Anolis: what resources do anoles actually compete for (e.g. food or space), and how (e.g. exploitation or interference)? If you don’t believe me, pull out your copy of Lizards in an Evolutionary Tree and read page 229¹.

Understanding mechanisms is important because it allows us to make predictions for the outcomes of species interactions in different contexts. I have long wanted to know whether green anoles (Anolis carolinensis) are likely to persist in Hawaii following the introduction of brown anoles (Anolis sagrei) and gold dust day geckos (Phelsuma laticauda). My initial work in this system was directly out of the classic Anolis playbook: enclosure experiments looking at traits, resource use, and fitness under controlled resource availability in allopatry vs. sympatry^2,3. In other words, I was focused mainly on documenting the phenomenon of competition. At some point it clicked that in order to answer the question I cared about the most — the potential for long-term coexistence — I needed to identify the mechanisms of competition, and how species differences in competitive ability may translate into coexistence in this system.

Our latest experiment was grounded in mechanistic theory for consumer-resource interactions developed by Tilman⁴, R* theory. The key insights from this body of theory are that exploitation competition comes down to who can suppress shared limiting resources to the lowest levels under different conditions, and that the ability to suppress resources should be predictable from consumer traits. Designing experiments from this perspective caused me to shift from measuring resource use overlap (i.e. diet, perch height, body temperature), to measuring prey populations, lizard demographics, and lizard foraging rates.

While R* theory is foundational, general, and from the golden age of ecology — when there was great optimism about the potential for simple theory to explain community dynamics — empirical tests of R* predictions have previously been limited to microbes, microfauna, and grassland plants. This is probably because it is a ton of work to collect the necessary data, and we only had a chance at success in a system of vertebrate, mobile predators because of the many decades of work on anoles. Our core field team (myself, Spencer Alascio, and Jose Carranza), aided by a large cast of volunteers, spent multiple days in the field every single week for over a year. 29,000 arthropods measured⁵, 3,000+ mark-recaptures of lizards⁶, and over a 100 hours of focal lizard observations later⁷, we got our answer.

We previously found that the species differ in their clinging ability on rough vs. smooth substrates, and here we found that this results in different species being better at catching prey in different microhabitats (ground vs. vegetation). We all like to do what we’re good at, and indeed brown anoles and day geckos each had the highest prey capture rates in the microhabitat where they cling the best. These differences in microhabitat-specific performance led to spatial differences in competitive ability: brown anoles drove prey densities on the ground down to lower levels than any other species, and day geckos drove prey densities in the vegetation down to lower levels than any other species. Even though green anoles had similarly high capture rates to brown anoles on the ground, and to day geckos in the vegetation, they did not suppress prey the most in either microhabitat because they are the worst at converting prey into new offspring. As a result, green anoles achieve densities only half as high as the other two species under the same environmental conditions and in the absence of interspecific competition. This insight underscores the value of rooting empirical work in theory—we would have never measured conversion rates without the guidance of a theoretical framework.

In addition to helping us design an effective experiment, the models allow us to achieve my ultimate goal: predicting whether green anoles can persist long-term. By using our empirical data to parameterize consumer resource models for mobile predators a la Vincent et al.⁸, co-author Kyle Edwards was able to generate testable predictions for species coexistence under different ratios of ground and vegetation habitat. What we found, by graphical analysis of zero net growth isoclines, is that while any two of the species can coexist under some conditions, green anoles cannot persist on the landscape in the presence of both of the other species under any habitat ratios. As all three species are now distributed island-wide⁹, our models predict that green anoles will go extinct. This prediction is of course specific to the context in which we collected the empirical data to parameterize these models. I look forward to testing these predictions in the next enclosure experiment, and in the natural experiment playing out in real time on the landscape.

Overall, our results support the idea that trade-offs in the ability to suppress prey across different microhabitats, which we refer to as spatial heterogeneity in competitive ability, is a likely coexistence mechanism in this system.

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The rediscovery of Anolis laevis is one of those stories that seem written to remind us why biological exploration remains indispensable. Described in 1876 from a single specimen, holotype ANSP 11368, and then lost to science for a century and a half, this small anole with a strange proboscis on its snout became a myth of the montane forests of northeastern Peru. For more than a decade, herpetologist Pablo Venegas conducted repeated and systematic surveys throughout the region, from 2003 to 2018, intensively searching the same montane forests without finding a single trace of the elusive Swordsman anole, reinforcing its reputation as a species that might have vanished forever.

The work reported in our recent paper began quietly in 2008, when two adult females were collected in Laguna Negra, in the department of San Martín, Peru, without anyone knowing at the time that they held the key to solving a historical enigma. Ten years later, in 2018, two adult males appeared in Posic and Nuevo Chirimoto, confirming that the “swordsman anole” was still alive. It was at that moment that a systematic investigation began which, after years of comparing morphology, reviewing historical collections, and documenting living individuals, succeeded in bringing to light a species that had remained in the shadows for generations.

The process was as captivating as it was rigorous. Researchers compared every detail of the new specimens with the 19th-century holotype, a specimen that is deteriorated but still retains the diagnostic characteristics that define the species. The male’s small rostral proboscis and dorsal crest formed by triangular scales are still visible, features that match precisely with the rediscovered animals, dispelling fears that this was a different cryptic species. The study also revealed a surprising sexual dimorphism: the females, unknown until now, completely lack a proboscis but have a black gular fold with white scales, while the males have a pink gular fold with a bluish border. This revelation not only completed the portrait of A. laevis, but also provided an essential piece of the puzzle for understanding how sexual selection and visual signaling operate in these Andean anoles.

The work condenses decades of uncertainty into a powerful visual sequence. The holotype allows us to observe, from dorsal, lateral, and ventral views, that even after 150 years of preservation, the key features are still there, anchoring the species’ identity to the present. The photographs reveal a lichen-colored lizard, almost camouflaged among moss and damp leaves, and show the female with her dark dewlap deployed for the first time. Comparison with other proboscis anoles, such as A. phyllorhinus from Brazil and A. proboscis from Ecuador, highlights a fascinating evolutionary truth: although these “big-nosed” lizards look alike, they belong to different lineages.

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Like anoles, geckos are famous for their adhesive toepads, enabling astonishing climbing abilities. Since adhesive toepads evolved independently in geckos and anoles, these two rather distantly related lizard clades have become the poster-children of convergent evolution in climbing. But, astonishingly, how such a complex system actually evolves has until recently garnered little attention. And while anoles have long been celebrated for their sticky pads, the literature tends to treat the spectacular adhesive system in a binary fashion as either being present (full pads) or absent (pad‑less) in geckos– despite the fact that earlier research already indicated that this might not be the case.

The genus Cyrtodactylus (~ 400 species) is an excellent vehicle for studying the transition from a pad‑less ancestor to a fully adhesive foot because its members occupy a dizzying array of habitats — from ground‑dwelling leaf‑litter specialists to tree‑crown acrobats — quite comparable to Anolis lizards in this regard. And not only that, but our previous work has revealed that Cyrtodactylus displays a continuum of sub‑digital scale shapes ranging from tiny round scales to broadened, lamella‑like “incipient toepads” (Riedel et al. 2024).

So, building on these previous studies, we embarked on a project to look at the sub-digital microstructures of Cyrtodactylus geckos as the logical next step. The dry‑adhesive systems of geckos and anoles rely on arrays of microscopic filaments called setae (Fig. 2). In geckos four filament types have been described (Garner & Russell 2021): spinules, spines, prongs, and setae (Fig. 2). While spines ancestrally cover most parts of the skin of geckos and anoles alike, and likely evolved for self-cleaning purposes (lotus effect), spines and prongs have been hypothesized to be “pre‑adhesive” adaptations that improve traction on rough surfaces. Only setae have been proven to generate sufficient van‑der‑Waals forces capable of generating adhesive forces of sufficient magnitude to support the entire animal.

The actual study, building upon a hypothesis formulated 50 years ago (Russell, 1976), began with checking museum specimens for the presence of subdigital microstructures using light microscopy, since the outer skin layer is often lost in specimens stored in ethanol for long time periods. Of the 86 specimens examined, spanning 30 species from four museum collections, 53 specimens belonging to 27 species were suitable for examination with the scanning electron microscope (SEM), which is the standard tool for studying integumentary microstructures in reptiles. Although representing only a small fraction of the 400 species of Cyrtodactylus, this sample constituted a sufficiently broad phylogenetic coverage across the genus. It also incorporated representative stages in the sub-digital scale shape continuum and species representing multiple habitat preferences (ecotypes). SEM imaging was used to first categorize microstructures into the four known types (Fig. 2) and then to quantify various parameters, such as filament length, diameter, and density, which are known to vary across species and microstructure types, all of which are related to the function of these structures. From these measurements, effective bending stiffness – a measurement of flexibility, which is particularly important for setal function – could be calculated. We then applied different modelling approaches to test for correlations of both microstructure types and measurements with ecotypes and reconstructed their evolutionary history to compare their evolution with the evolution of scale shapes as reconstructed in our previous study.

We found that spines are likely the ancestral condition for the genus at large and that prongs evolved three times independently from spines, while setae evolved two times – once in the intertidal species C. seribuatensis and once in a large crown group including many but not all arboreal or saxicoline (rock-dwelling) lineages (Fig. 3). This indicates that microstructure types are phylogenetically constrained. Interestingly, the two arboreal clades with strongly expressed incipient toepads (lamella-like subdigital scales) are nested within the setae-bearing crown group, indicating that the evolution of setae preceded the evolution of lamella-like scales in these lineages. Thus, our results suggest that adhesive competence may arise before the classic “lamella” morphology. However, C. consobrinus (a trunk species) shows the incipient toe pad gross morphology of its subdigital scales but lacks setae—its microstructures are spines, indicating the converse may also be the case.

The ecotype (e.g., cave, crown, granite, karst) of a species does not predict whether a species has spines, prongs, or setae. However, specific filament traits (e.g., apical diameter, effective bending stiffness) differ significantly among ecotypes—crown‑dwelling species have the smallest apical diameters and the most flexible filaments (lowest effective bending stiffness). Thus, it appears that phylogeny determines what filament type a species has, while micro‑habitat fine‑tunes how those filaments are built.

Overall, our study provides important insight into the evolution of toepads, in that we show that setae (indicative of adhesive competency) can evolve without the expression of obvious macro‑scale pads, and that multiple independent origins of setae have occurred within a single genus. These findings highlight the evolvability of the adhesive system and establishes that the genus Cyrtodactylus offers a living laboratory for the study of the stepwise evolution of complex adhesive systems (thus providing an excellent platform for comparative studies with anoles and other climbing squamates).

If you want to read more, check out our open-access paper:

Ginal, P., Y. Ecker, T. Higham, L. L. Grismer, B. Wipfler, D. Rödder, A. P. Russell, & J. Riedel (2026): Subdigital integumentary microstructure in Cyrtodactylus (Squamata: Gekkota): do those lineages with incipiently expressed toepads exclusively exhibit adhesive setae? Beilstein Journal of Nanotechnology 17: 38–56. https://doi.org/10.3762/bjnano.17.4

 

Further references:

Riedel, J., K. Eisle, M. Gabelaia, T. Higham, J. Wu, Q. H. Do, T. Q. Nguyen, C. G. Meneses, R. Brown, T. Ziegler, L. L. Grismer, A. P. Russell, & D. Rödder. 2024: Ecologically-related variation of digit morphology in Cyrtodactylus (Gekkota, Squamata) reveals repeated origins of incipient adhesive toepads. Functional Ecology 38: 1630–1648. https://doi.org/10.1111/1365-2435.14597

Garner, A.M. & A.P. Russell, 2021: Revisiting the classification of squamate adhesive setae: historical, morphological and functional perspectives. Royal Society Open Science 8, 202039. https://doi.org/10.1098/rsos.202039

Russel, A. P. (1976): Some comments concerning interrelationships amongst gekkonine geckos. In: D’Bellairs, A., Cox, C. (Eds.), Morphology and Biology of Reptiles. Academic Press, London, pp. 217–244.

Happy ending: they both lived to see another day thanks to the screen between them! Thanks to Miriam Lipsky for the photo from Miami.

JUST PUBLISHED: Understanding Animal Behaviour is a non-fiction graphic novel featuring anoles and other lizards. This isn’t a kid’s book or comic. It is written for adult readers interested in understanding why animals do what they do and how researchers go about studying behaviour.

And its FREE.

Here’s a taster from Chapter 4 on the challenges anoles face when trying to advertise territory ownership in natural environments.

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Ok, not actually breaking news–occurred almost eight years ago, but somehow word never reached Anole Annals. People magazine tells the story:

Tulane University reports:

Study: Invasive lizards’ tempers flare with the heat

Turns out those New Orleans lizards with record levels of lead in their blood are also picking more fights — but heat, not heavy metal, may be driving their aggression.A new Tulane University study published in the Journal of Thermal Biology finds that invasive brown anoles become more aggressive toward native green anoles as temperatures rise, suggesting that warming conditions could tip the competitive balance between the two species.

Earlier Tulane research revealed record-high levels of lead in brown anoles collected in New Orleans, prompting questions about whether lead exposure could explain their feisty tendencies. While the team can’t rule out a connection, the evidence so far points elsewhere, said senior study author Alex Gunderson, assistant professor of ecology and evolutionary biology in Tulane’s School of Science and Engineering.  

“We don’t yet know whether lead contributes to the brown anoles’ aggressive behavior,” Gunderson said. “But since we haven’t seen lead affecting them in other ways, my guess is that it’s probably not the cause. What we can say for certain is that their aggression increases with warmer temperatures.”

The research, led by Gunderson and PhD student Julie Rej, examined how temperature influences aggression between the two species, which compete for the same habitat in the southeastern United States. The invasive brown anoles displace the native green anoles from their preferred habitats in the wild, and behavioral aggression is one potential reason.

“Invasive species cause a lot of ecological and economic damage, so biologists are really interested in understanding what makes these species so successful,” Rej said.

The team found that brown anoles are consistently more aggressive than green anoles, and that their aggression increases as temperatures rise.

To measure aggression, Rej placed pairs of brown and green anoles together in controlled enclosures set to simulate different seasonal temperature ranges – from cool spring days to hotter summer conditions expected in the future. Across all tests, brown anoles displayed higher levels of aggression, and while rising temperature increased the aggression of green anoles somewhat, the gap between the two species’ aggression widened as the temperature increased.

The findings suggest that as the climate continues to warm, invasive brown anoles may become even more dominant competitors, further displacing native green anoles from their preferred habitats.

“Climate change can make invasive species more potent, and this study shows that heat-driven aggression could help explain why in some cases,” Gunderson said.

The study contributes to growing evidence that behavioral responses to temperature are an important, and often overlooked, factor in how species will interact and compete as global temperatures rise.

The research was supported by Tulane University and conducted at the Gunderson Lab, which studies how animals respond and adapt to environmental stressors such as temperature changes.