Review of Poe’s Guide to the Anolis Lizards (Anoles) of Mainland Central and South America

A Guide to the Anolis Lizards (Anoles) of Mainland Central and South America

I received a copy of Steven Poe’s “guide” to the mainland anoles. The book includes summaries of 240 species, copious photographs, range maps, and chapters on anole biology and identifying and catching anoles. The 400+ page tome is not entirely devoid of value. Many of the photos are excellent, the maps are useful, and the book’s thickness encourages functionality as a step stool (although its heft precludes frequent usage in this capacity). Unfortunately, the self-satisfied prose of the author fails to distract sufficiently from the book’s considerable inadequacies, an exhaustive list of which might exceed the length of Poe’s long-winded exposition itself. Settling on the most salient among the myriad deficiencies in Poe’s treatment is a challenge akin to finding a live Anolis roosevelti during daytime while jacked on Bufotenin (Figure 1). Herewith I make my attempt.

First of all, who made Poe judge and jury of Anolis taxonomy? Just because Anolis osa has no diagnostic characters save for continuously varying hemipenial traits, freely interbreeds with A. polylepis, appears externally identical to A. polylepis, is mitochondrially nonmonophyletic relative to A. polylepis, and is found syntopically with A. polylepis, doesn’t mean we shouldn’t recognize A. osa as valid. Even though A. ibague, described from external characters, looks exactly like A. sulcifrons doesn’t mean it might not be an Ibague-area endemic. And no, Poe’s addition of an appendix with detailed point-by-point refutation of each of the species names he fails to recognize does not absolve such cavalier taxonomic behavior. Somebody must do the work before we make such rash decisions! Somebody needs to examine Type specimens!

         Second, do we really need the tone of a wannabe cross between Bill Simmons and Hunter S. Thompson in the text of a field guide? Seriously: A reference to Land of the Lost? (P. 367; does anyone under age 70 know what this is?); telling us Linnaeus was “cool” with herps? (P. 367); describing one’s difficulty to identify a specimen as being “screwed”? (P. 37); mocking E. O. Wilson’s ineptitude in identifying anoles? (P. 369; OK, upon rereading maybe Wilson deserved that). Author Poe, drop the cheekiness and just tell us how to identify the anoles, please. Realize, dear Poe: not everybody enjoys your writing as much as you do.

Third, what’s with the imperialist gall of offering a guide to all mainland anoles (Figure 2) ? Señor Poe, have you traveled to all of the neotropics and seen all the pertinent anoles in life? Have you caught mirus, proboscis, fungosus, lamari, brooksi, alvarezdeltoroi? Have you visited Adrian Nieto’s anole collection in Mexico or James Aparicio’s in La Paz? I’ll trust Ayala-Varela in Ecuador; Velasco and Moreno-Arias and Daza and Calderon and Castro-Herrera in Colombia; Rivas and Barros in Venezuela; Chaves and Köhler (R.I.P.) in Costa Rica; Ibañez in Panama; Yañez-Miranda and Venegas in Peru; Rodrigues and Prates in Brazil; Nieto Montes de Oca in Mexico; thank you. Newsflash to Poe: We. Don’t. Need. You. Go back to your adobe tower at UNM, drop the toploftical anole schtick, and stick to phylogenetic computer games and data cooption. You want another anole named after you? How about Anolis whiteprivilegei?

And finally, ahem, the photos and the maps? Oh, you know, those subtly credited triflings that constitute essentially ALL THAT IS OF VALUE IN THE BOOK? How about making Tom Kennedy, Chris Anderson, and Joseph Barnett coauthors? Do you think you could have produced this book without Torres-Carvajal’s PUCE website? Without the maps by Barnett? Without iNaturalist anole leader Kennedy’s photos? Without Savage (2002), McCranie and Kohler (2015), Arteaga et al. (2023), Moreno-Arias et al. (2021), Castro-Herrera and Ayala (unpublished Saurios de Colombia), and Ernest Williams’ unpublished notes? It is one thing to produce an arrogantly broad taxonomic treatise. But to do so as the sole author? Child, please. Ernest Williams could have written this book, except good. You, Senhor Poe, are no Ernest Williams.

I could go on and on and on and on and on describing the countless and multifaceted defects in Poe’s treatment, but the time commitment required for even a tally of such failings strains the credible limits of scientific service. The retraction of this book in its entirety from Princeton University Press is warranted and should be advocated on grounds that the book fails to reach even the most base standards of scholarship. The thing reads like a children’s joke book that is not funny even to children.

However. If you can tolerate the author’s smug tone, his authoritarian taxonomic tendencies, his bumptious claim to be an expert on all mainland anoles, and his anti-conservationist approach to conservation; if you are comfortable with pop-culture references in a field guide, an overwritten chapter that presents guidelines for finding and catching anoles in nauseating detail, and natural history accounts that focus on sleeping behavior (of all things); if you can stomach footnotes upon footnotes that offer little beyond exemplary demonstration of the author’s singular talent for herpetological inanity; well, you might find some serviceableness in Poe’s treatment of mainland anoles.

But I doubt it.

Pete Snove

Adjunct Assistant Administrative Faculty, Eastern New Mexico State Seminary College of the Southwest, Clovis Satellite Branch at Yerba, New Mexico, USA.

 

Blue Shed Skin of Green Anole

Photo by Gary Owen Dick.

Reader Gary Owen Dick (see also this post on a yellow anole he found) writes from near Dallas: Took some pics the other day of a female green anole shedding.  What intrigues me is the blue coloration on the inner side of the backlit pieces of the loose stratum corneum seen at these angles.  Is this a structural thing, or a camera illusion?

Invaders Don’t Come Alone: Rethinking Biological Invasions Through Co-invasion

Male green anole (Anolis carolinensis) positioned in front of a black-jack flower (Bidens pilosa)

Species invasions are usually studied one at a time, but ecosystems rarely have that luxury. This project began with a simple frustration: while reading about invasive predators, invasive competitors, and pollinator declines, I kept noticing that these processes were usually treated separately—even though accelerating global trade is increasingly causing ecosystems to experience multiple invasions simultaneously. This is especially true on islands, which are highly connected through the constant movement of goods and supplies. Species rarely arrive alone. That raised a bigger question for me: what happens when multiple invaders arrive together and begin reshaping ecological networks at the same time? Do their effects simply add up, or can they fundamentally reorganize pollination systems in ways we have been overlooking?

The Ogasawara Islands are one of those places that make you feel you are exactly where you should be. Their natural beauty is breathtaking, and the local people live in remarkable harmony with the island. You instantly want to become part of that network of connections among species, to blend into it and stay.

Yet what stayed with me most was not what I saw—it was what I did not see.

Walking through the forest, you begin to notice what is missing, and what has been added. At first, everything appears intact. Then, gradually, the details emerge. Honey bees buzz among non-native flowers. Introduced green anoles wait patiently on blossoms for unsuspecting prey. And slowly you realize that something else should be there. The native bees that once pollinated these forests have disappeared from two of the islands. Younger generations may never have the chance to encounter them. What remains is an ecological network that still functions, but not in the same way as before.

That realization became the emotional starting point for this study. The urgency to respond to pollinator declines led many people to point directly at the green anole as the culprit, triggering eradication efforts before any quantitative, community-level assessment had been carried out.

Perhaps it is simply because I am a community ecologist and tend to view ecosystems as interconnected wholes, but I kept asking myself: could the impact really be driven by a single species? That is when co-invasion became the central question. If we wanted to understand changes in the pollination network, it was impossible to focus only on the predator of pollinators. We also needed to consider competitors such as the honey bee and the role of non-native flowering plants. To investigate this, we conducted three field campaigns in 2021, sampling pollination networks through direct observations with binoculars across four islands. Two islands had already been invaded and had lost their native bees, while two remained uninvaded and still supported native bee populations. We also surveyed the other invasive species that could potentially alter pollination networks, such as plant and pollinators competitors, and their associated ecological interactions.

Even after collecting the data, one of the biggest challenges was resisting the temptation to simplify invasions into isolated events. Modelling simultaneous invasions quickly became complicated because predator introductions, competitive interactions, and pollination rewiring can all interact in unexpected ways. Yet this complexity turned out to be one of the most fascinating aspects of the study. We found that the role of honey bees changed depending on the status of native pollinators on each island. In places where native bees had disappeared, honey bees often became the primary pollinators of many plant species. At the same time, their preference for non-native plants suggests that these invaders may facilitate each other’s spread and establishment. One of the most surprising findings was how consistently top-down effects cascaded through trophic networks. The green anole’s impact did not stop with pollinators; it ultimately reached plants by altering pollinator communities and their interactions, effectively crossing trophic levels and influencing plant reproduction. However, the final impacts were a complex combination that depends on all species involved.

What this project ultimately taught me is that invasions are not just about which species arrive, but about how multiple newcomers interact with one another once they do. Co-invasions can affect ecological communities far beyond what single-species approaches predict, particularly on islands where ecological balances are already fragile. That realization makes prevention feel even more urgent: by the time eradication becomes politically or ethically feasible, much of the ecological rewiring may already be underway. For me, this work reinforced the idea that biosecurity is not simply about stopping invaders and protecting threatened species—it is about preserving the invisible interactions that hold biodiversity together.

Quitián, M., Planas‐Sitjà, I., Morooka, M., Traveset, A., Tierney, S.M. and Cronin, A.L., 2026. Coinvasional disruptions to island pollinator networks. Conservation Biology, p.e70304.

Why Green Anoles Change Color by Whit Gibbons

Whit Gibbons

From the pages of  Tuscaloosa News:

You’ve likely seen this common lizard. Why it changes color | ECOVIEWS

Whit Gibbons
Contributor
May 1, 2026, 3:45 a.m. CT

One of the most commonly seen lizards in the Southern states is the green anole, also known as the North American green anole or Carolina anole. (Its scientific name is Anolis carolinensis.) Although more than 400 species of anoles are known to science, the green anole is the only one native to the United States. Most people appreciate seeing them in their yards.

Q. A type of lizard we have in Birmingham, Alabama, is sometimes green and sometimes brown. I know it is not two different lizards because I have watched one change from brown to green. Are these a type of chameleon that can change skin color to match their surroundings?

A. No. Anoles are in a different family of lizards from Old World chameleons. Those are the ones famous for being able to change skin color based on the background, thus creating a true camouflage. In green anoles color change is a response to external factors, such as temperature and humidity. It may also be influenced by hormonal changes.

Whether lizards experience emotions comparable to humans remains a mystery. Researchers continue to investigate why anoles change color, as well as what purpose that change serves for the individual lizard. Most anoles found hidden under bark or leaves on cool days will be brown. If you pick up a brown one and hold it, it will usually turn green.

To learn more, I contacted Tom Jenssen, an expert on the subject of color-changing behavior in green anoles.

During his career as a professor at Virginia Tech, Tom observed thousands of green anoles while conducting research on the species. His observations confirmed categorically that the color of a green anole has nothing to do with what the lizard is standing on. One on a green leaf can be brown; one on dark soil can be green.

He indicated that factors causing a green anole to exhibit the brown color phase are not completely understood but he explained the biological mechanism.

A male green anole flashes its dewlap in a territorial display. Males flaunt the red throat fan to challenge other males.

“Color-shifting comes from melanophore activity over a subdermal layer whose structure reflects green wave lengths.” In other words, the concentration of black or brown pigment cells determines the color exhibited. If the pigment cells are large, they obscure a lower level in the skin that reflects green light. When the cells are concentrated, the lizard looks dark brown, mottled brown or even like a bad bruise of blotchy brown and olive-green. If the pigment cells contract in size, the lower level is exposed, and the lizard appears green.

He further noted that the activity of pigment cells and their concentration are controlled by the endocrine system, the glands that affect hormones and mood changes for many animals. The remaining biological mystery: What triggers the endocrine system to cause the pigment cells to contract or expand? Body color in anoles is highly complex, with no simple answer for why an individual is a particular color at any given time.

Social interactions with other lizards may be responsible in some cases. Brown coloration could possibly result in faster warming of the body on a cool sunny day.

Q. Why do these lizards that can change from brown to green sometimes have a bright red throat?

A. Male green anoles use the vivid red throat fan, or dewlap, to challenge other male anoles and sometimes even other animals. The dewlap display is often accompanied by push-ups and head-bobbing. An invasive species from Cuba, the brown anole, now found in Florida, Georgia and Alabama, has an orange dewlap.

Next time you see a green anole displaying a red throat, take a moment to watch its performance. Who is its audience? Is it another anole in the vicinity — or is it you?

Native green anoles are completely harmless and offer fun outdoor entertainment. Enjoy watching them stalk bugs and interact with each other. They are indicative of a healthy environment and deserve our appreciation wherever we find them.

Whit Gibbons is professor of zoology and senior biologist at the University of Georgia’s Savannah River Ecology Laboratory. If you have an environmental question or comment, email ecoviews@gmail.com.

Want to Know More about Animal Behaviour, in Spanish?

For those of you fascinated by animal behaviour—of your pets, backyard visitors and other wildlife, or perhaps anoles in particular—the non-fiction graphic novel Understanding Animal Behaviour is for you. And it’s free—all 175 pages of it.

Learn everything there is to know about the science of animal behaviour. Find out more about how Anolis lizards have cracked open the way natural selection works in nature. Discover just how complex anole behaviour really is, from establishing territories to elaborate ways of communicating with one another.

The complete book is available for download in English, but many chapters are now becoming available in Spanish because of the superhero, Dr Janire Castellano Bueno. Janire has devoted what little spare time she has to progressively translating Entendiendo el Comportamiento Animal. Again, entirely for free.

ABOVE: The amazing Janire, a genuine collaborator and supporter of inclusive open access.

Here’s a taster…

New translations of Entendiendo el Comportamiento Animal are coming online every month. Other resources are available as well, including self-guided practicals, crosswords, and other study aids.

Regardless of who you are, this graphic novel is for you. If you’re a scientist, general reader, or school student – read it, learn from it, have fun with it!

Anole T-Shirts

New model organism t-shirts available from the Society for Developmental Biology.

Are Red Chili Pepper Anoles a Real Thing?

 

From Cold Blooded Kingdom’s website

AA reader Steve Hopman writes:

My question is on genetics of the “Red Chili Pepper” anole being sold on Underground Reptiles.

Are they A. sagrei or a cross with another species?
How is the red transferred to offspring? Dominant or recessive trait or ?.

Red Chili Pepper Anoles For Sale - Underground Reptiles

And here’s one from Underground Reptiles.

Spring Time and the Green Anoles Are Back in Georgia

From the pages of Vanguard, the student newspaper of the University of North Georgia:

The Green Anole is Back in Georgia

Despite being misunderstood, Green Anoles remain adaptable and present in North Georgia. Photo by Riley Hansen.

Despite being misunderstood, Green Anoles remain adaptable and present in North Georgia. Photo by Riley Hansen.

With spring weather on the rise, green anoles, a small lizard species native to the southern portion of the United States, are returning to Georgia in large numbers.  Anolis Carolinensis is known as a “trunk-crown ecomorph,” meaning they can change colors from shades of brown and green depending on their temperature and stress level.

Lily Grace Smith, a UNG freshman with a concentration in sustainability, said, “I have experience with green anoles because they like to hide in my house a lot.  I live near a creek in a forested area, so I come into contact with them frequently.  They are seen as scary because they like to jump around a lot to try to escape, but if you hold them by softly holding right under their head, you can release them.

Lily Grace Smith, a  holding a green anole she caught.  Photo by Lily Grace Smith.

The Green Anole also faces many challenges through deforestation and predation.  Green anoles originally inhabited the low-level brush of forests and gardens but were pushed into the higher topiary region by their invasive neighboring species, the brown anole, a non-native species native to the Caribbean that was introduced in the late 1800s.

“I’m glad I’m seeing them around because they regulate the insect population and also keep their predators around,” Smith said. “I wish people would save them and, if possible, make tiny habitats for them (keeping leaf litter, brushes, vertical spaces for them to bask on).” – Lily Grace Smith, UNG Freshmen Environmental Spatial Analysis Major

With limited research on the specific predators impacting the green anole populations, researchers are studying specific instances of predation that have appeared due to the introduction of other non-native species such as carnivorous plants.

In a publication from Herpetological Review,  authors Daniel A. Warner and Patrick Thompson of Auburn University said, “Although Interactions between these two species are probably rare, the native ranges of ‘A. carolinensis and D. muscipula overlap in areas of North Carolina and South Carolina, USA, suggesting that A. carolinensis is a potential source of nutrients for this carnivorous plant.  In addition, the small size of the D. muscipula restricts prey to relatively small individuals, and its small native range restricts the impact of this predator to a limited area.”

Despite these challenges, the green anoles’ adaptability and rapid evolution have assured their return to houses, schools and communities of the south this spring.

 

Anole Chocolate to Save Nature!

Mashpi Chocolate sustainability farms chocolate to help preserve nature in Ecuador. And anoles are doing their part. As they say on their website: “All the ingredients we use in Mashpi Chocolate are grown in an agroecological and regenerative way, next to cocoa trees and within edible forests….We created this chocolate to preserve a native forest reserve, restore degraded areas and generate opportunities in the magical territory of the Andean Chocó….The beauty of coffee is that it is planted under the shade of other trees, providing a habitat for many other species. We use high-altitude coffee as it has a special set of aromas and a characteristic taste that makes me want more!”

As for anoles, decide for yourself which species! Perhaps the fabulous Reptiles of Ecuador‘s Anolis webpage can help!

And many thanks to the Missouri Botanical Garden’s Carmen Ulloa Ulloa for not only tipping AA off to this, but providing a delicious sample!

Dinámicas Evolutivas y de Diversificación en Regiones Montañosas Tropicales

Anolis heterodermus. ¡Esta especie andina puede vivir hasta 3700 metros sobre el nivel del mar! Foto por Jhan C. Salazar.

Al igual que cuando era estudiante de pregrado, me demoré un buen rato en decidir qué hacer para mi tesis doctoral, ya que tuve que replantear la mayor parte debido a la pandemia de COVID. Meses antes de mi propuesta, encontré un artículo muy interesante de alguien de mi ciudad natal (Cali), Julián A. Velasco (Velasco et al. 2020). En este trabajo, Velasco y sus colegas trataron de responder dos preguntas: primero, si el calor y la disponibilidad de alimento explican por qué el tamaño de los animales varía geográficamente; y segundo, qué tan rápido cambiaron esos tamaños a medida que el planeta se enfriaba durante los últimos 66 millones de años. Para esto, utilizaron una base de datos masiva con información georreferenciada de 379 especies de Anolis.

Cuando llegó el momento de escribir y presentar mi propuesta en 2021, uno de mis capítulos se basaba en los datos de Julián. Sin embargo, no conocía a Julián en ese momento, ni tenía la base de datos original de casi 25,000 individuos georreferenciados. Por suerte, al año siguiente, 2022, se llevó a cabo el Congreso Colombiano de Herpetología en mi alma mater en Cali, la Universidad Icesi, y Julián era conferencista invitado. Así que le envié un correo electrónico unos meses antes del congreso para agendar una reunión y discutir el proyecto que tenía en mente.

Aunque el artículo del que estoy escribiendo hoy está relacionado con ese estudio original, en realidad surgió de un comentario de otro colaborador, Adam Algar. Durante una revisión, preguntó: “¿Vale la pena pensar en qué procesos han contribuido a la diversidad o especiación de los Anolis de montaña?”.

Ahora, hablemos de los Anolis de montaña y la diversificación. Para este estudio, utilicé los registros georreferenciados para extraer dos tipos de datos de mapas (rasters) de acceso público de complejidad topográfica (medida como rugosidad) y velocidad del cambio climático pasado (que captura la rapidez de los cambios locales en temperatura y precipitación). Nuestro estudio fue recientemente publicado en Global Ecology and Biogeography; Salazar et al. 2026. Utilizamos estos datos para probar dos hipótesis:

  1. Si entornos de gran altitud promueven tasas de especiación más altas.
  2. Si una mayor complejidad topográfica y la estabilidad climática (baja velocidad de cambio climático pasado) influyen positivamente en la especiación.

Realizamos tres análisis principales utilizando esos datos:

  • CoMET: Para evaluar si la señal observada podía explicarse por cambios en las tasas de diversificación a lo largo de la filogenia de las especies actuales.
  • GeoHiSSE: Para probar si los hábitats de gran altitud actúan como “bombas de especies”.
  • PGLS: Para evaluar la relación entre la complejidad topográfica, la velocidad del cambio climático pasado y la tasa de diversificación.

En total, analizamos 303 especies. Un desafío importante fue definir el límite entre “tierras altas” (highland) y “tierras bajas” (lowland), ya que no existe un umbral de elevación exacto. Establecimos los 700m como nuestro criterio principal, basándonos en el recambio significativo de especies en los Anolis del Caribe (Frishkoff et al. 2022), aunque también probamos umbrales de 300m y 1500m para comparar.

Descubrimos que el ritmo de aparición de nuevas especies en realidad disminuyó a medida que nos acercábamos al presente (análisis CoMET). Esta desaceleración ocurrió justo cuando Centroamérica comenzó a activarse tectónicamente y continuó cayendo hasta que los Andes terminaron de elevarse, momento en el que las cosas finalmente se estabilizaron, especialmente después de un gran cambio en el Mioceno hace unos 7 millones de años.

Para el GeoHiSSE, encontramos que el ancestro de Anolis era una especie “generalista” (Figura 1) con una alta tasa de diversificación neta. El análisis también infirió que la mayoría de las transiciones hacia hábitats de montaña ocurrieron durante el Eoceno tardío y el Oligoceno (Figura 1b). Además, en cuanto a la tasa de especiación y la diversificación neta, encontramos que las especies de tierras bajas tenían tasas de especiación y diversificación neta más altas en comparación con sus contrapartes de montaña (Figura 1c).

Figura 1. (a; arriba) Tasas de diversificación en todo el árbol a lo largo del tiempo, según lo inferido por el análisis CoMET. La línea de morada representa la tasa de diversificación estimada (con la media y la densidad posterior más alta al 95%) basada en la filogenia de los Anolis mostrada en (b). (a; abajo) Evidencia del Factor de Bayes (BF) para un cambio en las tasas de especiación a lo largo del árbol. La línea discontinua marca el umbral de apoyo “positivo” (Kass y Raftery, 1995). (b) Reconstrucción del área ancestral de los resultados de GeoHiSSE. Los contornos de las ramas están coloreados según las tasas de diversificación neta, donde el blanco indica tasas bajas y el rojo tasas altas. Las partes internas de las ramas están coloreadas según los estados ancestrales reconstruidos: especies de tierras bajas (verde), especies de tierras altas (amarillo) y especies de amplia distribución (marrón). También se muestran diferentes clados de Anolis. (c) Estimaciones de diversificación neta (arriba) y especiación (abajo) en áreas de tierras altas frente a tierras bajas.

Por último, no encontramos ninguna correlación significativa entre la complejidad topográfica o la velocidad del cambio climático pasado y la tasa de diversificación (Figura 3a, 3b). Sin embargo, al separar nuestras 303 especies en cinco clados, encontramos que para las especies del clado Draconura sí existe una correlación significativa entre la complejidad topográfica y la velocidad del cambio climático pasado con la tasa de especiación (Figura 3c, 3d).

Figura 2. Relaciones entre la tasa media de especiación (MeanDR) con la complejidad topográfica y la velocidad del cambio climático, para todas las especies de Anolis (a, b), y para las especies del clado Draconura (c, d). La línea de regresión negra representa los resultados de los mínimos cuadrados generalizados filogenéticos (PGLS). Los puntos representan especies individuales. Los puntos amarillos representan las especies de altas elevaciones, mientras que los puntos verdes representan especies de bajas elevaciones.

Para responder a nuestras dos preguntas:

  1. ¿Actúan los entornos de gran altitud como motores para una especiación más rápida?No, encontramos que las especies de tierras bajas tienen tasas de especiación más altas en comparación con las especies de tierras altas.
  2. ¿Conduce la combinación de una topografía accidentada y un clima estable y predecible a mayores tasas de formación de nuevas especies?No, las tasas de especiación no están relacionadas con una mayor complejidad topográfica, la velocidad del cambio climático pasado o la temperatura media anual.

Nuestros resultados desafían las suposiciones sobre el papel directo de la complejidad topográfica en la especiación, destacando la necesidad de considerar factores ecológicos y biogeográficos multifacéticos que impulsan los procesos evolutivos. Al desentrañar las contribuciones relativas de la estabilidad climática (es decir, una menor velocidad de cambio climático pasado) y la heterogeneidad topográfica, este estudio subraya las complejas dinámicas que moldean la biodiversidad en las montañas tropicales y hace un llamado a enfoques integradores adicionales para comprender la diversificación de las especies frente al cambio climático y geológico.

En nuestro estudio, tratamos a todas las montañas neotropicales como uniformes. De ahora en adelante, futuros estudios deberían enfocar en encontrar umbrales de elevación que reflejen las realidades regionales en lugar de números arbitrarios, teniendo en cuenta las variaciones locales en el clima y la topografía. Un enfoque holístico, que integre la estabilidad climática con la complejidad topográfica, es esencial para comprender cómo evolucionan y se adaptan las especies montanas. Al refinar estos límites, podremos predecir mejor cómo el cambio climático global alterará las trayectorias evolutivas y priorizar la conservación en estos paisajes complejos.

References

  • Frishkoff, L. O., Lertzman-Lepofsky, G., & Mahler, D. L. (2022). Evolutionary opportunity and the limits of community similarity in replicate radiations of island lizards. Ecology Letters, 25(11), 2384–2396.
  • Kass, R. E., & Raftery, A. E. (1995). Bayes factors. Journal of the American Statistical Association, 90(430), 773–795.
  • Salazar, J. C., Algar, A. C., Poe, S., Losos, J. B., & Velasco, J. A. (2026). Diversification and evolutionary dynamic in tropical montane regions. Global Ecology and Biogeography. DOI: 10.1111/geb.70218.
  • Velasco, J. A., Villalobos, F., Diniz-Filho, J. A. F., Poe, S., & Flores-Villela, O. (2020). Macroecology and macroevolution of body size in Anolis lizards. Ecography, 43(6), 812-822.

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