Information Wanted On Three-Legged Lizards

3 legged marsh harbour 2013 clinging dataPeriodically, AA has featured reports on finding three-legged lizards in nature (1,2). And here’s another one, briefly detained on a recent field trip to Abaco. Loss of her hindfoot doesn’t seem to be troubling her too much; heck, she’s even gravid!

Turns out that three-legged lizards pop up all the time. I’ve decided to put together a compilation of the little tricyclers. If you have any information on a three-legged lizard–a photo or more, such as measurements of mass, survival, or sprint performance–I’d love to know about it. Please contact me at

Anole Window Decal


Be the first in your town have this on your cruiser.

Be the first in your town have this on your cruiser.

decal2xHow’s this for a nifty anole decal? A gift from AA contributor and photographer extraordinaire Joe Burgess, the window dressing is the handiwork of Floridian Gary Swenk, who has this to say about himself and his unusual trade: “I am a retired law enforcement officer now doing vinyl graphics from home. I attached a catalog that I use and I also can convert pics, images etc. to vector graphics for making the decals. Black and white or pics with good contrast work best (not all pics, images are able to convert but it is easy for me to test them). I have a lot of different colors available. They can be made in many sizes ( 3″ up to 11″ is a good size). I can customize a graphic with names etc., using numerous fonts. Price is based upon size and single colors would run $2 to $5 for the sizes mentioned plus actual shipping cost which would be minimal. My cell is 904-540-3879.” And his emai is

Part of Gary Swenk's lizard catalogue.

Part of Gary Swenk’s lizard catalogue.

The Effect Of Hurricane Sandy On Abaco, Bahamas Anole Experiments

Did the lizards on this island survive Hurricane Sandy?

Did the lizards on this island survive Hurricane Sandy?

Long time AA readers will recall that every year, a team of researchers go to the Marsh Harbour, Abaco, Bahamas to study how curly-tailed lizards affect brown anoles and, in turn, how the presence of brown anoles affect the rest of the ecosystem on tiny islands. This research, initiated by Tom Schoener and Dave Spiller in the 1980s, has been long-lasting and has produced many interesting discoveries about anoles, ecology and evolution.

But in the last few years, the research has been bedeviled by hurricanes. In 1998 and then again in 2004, studies on the effects of curly-tails on brown anoles were terminated prematurely by hurricanes. We did learn a lot about how hurricanes affect ecosystems, including lizards, but it wasn’t so helpful with regard to understanding how brown anoles evolve in response to predation pressure. After waiting several years for the islands and lizard populations to recover, we re-initiated the experiment again in 2008. At the same time, we started a second experiment by introducing a single pair of lizards to each of seven islands, creating a replicated experiment on the effects of founder events on evolutionary adaptation.

Both experiments were moving along nicely when—what else?—another hurricane hit, Irene in 2011. As everyone recalls, Irene was a big one, and we feared the worst, but by good fortune, its effects were less than catastrophic because it hit at low tide—minimizing the extent of the storm surge—and from a direction that tended to minimize the storm surge on the particular islands we were studying. The result was that some—though not all—island populations were hit hard, but very few were demolished. In fact, I speculated that studying the effect of a population bottleneck on populations created by founder events might be particularly interesting, because some theories suggest that it takes multiple population crashes to lead to great evolutionary changes.

Hurricane Irene ripping its way through the Bahamas. Abaco is the island to the right of the arrow labelled “Freeport.”

So along comes 2012 and… another direct hit on our islands, this time by the infamous Hurricane Sandy. Although initially quite large, by the time Sandy hit Abaco, its wind speeds were less than Irene, giving  us hope. But, on the other hand, Sandy slowed to a crawl, meaning that it remained over Abaco for a long time, not just at low tide, and also from a more threatening direction than Irene’s. All dangerous portents.

dave on founder island

Photo by Jason Kolbe

Thus, with great trepidation, we returned to Abaco earlier this month, anxious to learn how our island buddies had fared. A trip to Abaco last December—admittedly, not the best anole time, even in the Bahamas—had indicated that a number of the lowest lying islands seemed lizardless. And our visit confirmed that finding. The seven islands in our founder effect study are all small and low-lying, and the lizard populations on five of them were wiped out (one of them had a female last December, but she’s apparently gone). One of the remaining islands contains but three anoles—a male and two females—and it will be interesting to observe the effect of this population bottleneck. That population—like all in this experiment—was founded by two individuals and quickly grew in size. Will it rebound again, and just as quickly? Continue reading

The Evolution Of Caribbean Anole Neuroendocrine Systems


What’s going on inside their heads? The four anole species of South Bimini, The Bahamas.

Whenever I stand in the forest on South Bimini in the Bahamas, I’m always struck by the similarity of these anoles to those I’ve worked with elsewhere in the Greater Antilles. Yes, that’s the whole idea behind the ecomorph concept, but as many have pointed out recently, habitat use and morphological convergence are only part of the story. Along with the classic divergence and convergence in body size and shape, the ecomorphs also show intriguing convergence in sexual size dimorphism and social behavior. It’s this latter aspect of the Caribbean anoles that interests me. How has this convergence in behavior, though it’s not perfect, happened? Have the proximate mechanisms that are responsible for anole behavior evolved in the same way on the various islands in the various ecomorphs? From a larger perspective we are asking, how do neuroendocrine systems evolve? That’s what my students and I are trying to figure out, and that’s why we’re in the Bahamas right now.

A few years back, Matt Lovern and I started a project examining circulating steroid hormone levels in four anole assemblages (The Bahamas, Puerto Rico, Dominican Republic, and Jamaica). Based on a plethora of work in a variety of vertebrate species and their testosterone-behavior relationships, we predicted that we would find consistent intra-island differences among ecomorphs in testosterone (and corticosterone), with the ever-charismatic trunk-ground anoles showing the highest levels. Boy, were we in for a surprise. We did find species differences, and we even found consistent ecomorph differences, but not like we expected. Unlike the mainland green anole (Anolis carolinensis) and the introduced brown anole (Anolis sagrei) on the mainland (yes, the apparent difference in testosterone levels  between mainland and Caribbean brown anoles is probably a separate, interesting story!), trunk-ground anoles in the Caribbean have very low baseline testosterone levels. Twig anoles, on the other hand, are super-juiced with testosterone. I won’t give the whole story away, as we are working on getting it published, but the take-home message is that hormones are only part of the story, and testosterone likely plays very different roles in the behavior of the various species and ecomorphs. While this may not sound surprising to some, in some ways it is, because typically people only focus on circulating hormone levels to explain behavior, and testosterone levels tend to be pretty good predictors at a large scale. Although many proclaim that it’s not the hormones but the receptors, nobody has examined hormone receptor distributions in target tissues across a large number of closely related species. Again, that’s what we’re trying to do here in the Bahamas (and elsewhere).

We’ve been spending our time here on Bimini collecting brains for analysis of several potential regulators of social behavior in multiple brain regions known to be important in anole aggression and courtship behavior. My student Allison, who is here with me now, got some funding to spend the rest of the summer back in Minnesota sectioning and staining brains from the four ecomorphs here on Bimini. We’ve also been conducting “GnRH challenges” on these species to determine whether the baseline levels of testosterone that we’ve measured are as high as they can go. That is, when we physiologically stimulate the hypothalamus-pituitary-gonad axis to produce more testosterone, is it capable of doing so, and are there differences among species in that response? I’ll be spending the rest of my summer running those samples to find out. This will complement the social challenges that Matt Lovern and I conducted in the Dominican Republic last year on Anolis cybotes and Anolis coelestinus, examining whether social challenges result in increased testosterone. Stay tuned to see what we find!

Anole Nook Farm

Imagine my surprise to stumble onto a farm that specializes on goatsmilk soap named Anole Nook Farm. I contacted the proprietor, Hannah Shumaker, who kindly explained:

“I named my farm/business after counting 27 anoles sunning themselves on the front of my house one morning.  I’ve since moved, and while my current farm is not quite as much of an anole haven as the first, I still see them regularly.  I’m a North Carolina native and have always been fond of the little fellows.  I’m still keeping an eye out for the elusive blue anole.

My business is locally/sustainably grown soaps.  I use the goatsmilk from my farm and locally grown ingredients in my soaps.  Right now that’s sheep or beef tallow, rapeseed oil, honey, and local botanical additives.  Here are links to a little page about my business and my poorly maintained facebook page.

That’s me and my anole connection, in a nutshell.  Anoles are awesome!”

A Little Giant’s Dewlap… Why Do They Need One?

Anolis ricordii. Photo by Miguel Landestoy.

Anolis ricordii. Photo by Miguel Landestoy.

If a juvenile anole has a dewlap since birth, there must be a reason for it, but what is it?  Juvenile hispaniolan crown giants do have them and here is a video of one using it. This Anolis ricordii was only 52.10 mm in SVL and was showing his stuff while a colleague was taking photos of it. We placed it in the tree and left it for about 10 minutes without disturbing it, after which it started dewlapping and bobbing the head. At one point, the dewlap was fully extended, but by the time I got my “pocket” camera ready, this was all it gave.

Later on, another individual, which was somewhat smaller, was found on the ground on a rainy day. There must be intraspecific spatial niche partitioning, when your parents are higher up and could eat you, it must be safer to stay away. Would a dewlap also be useful mainly for “pushing” away potential competitors/predators, as A. cybotes?

More Horny Lizards: Sri Lankan Ceratophora

Here at AA, we’re a bit obsessed with lizards with things on their noses, technically called “rostral appendages,” and sometimes, depending on shape, “horns.” A lot of this interest comes Anolis proboscis, the horned anole of Ecuador, about which we’ve written much before.

Almost as cool as horned anoles (really, that’s an unfair standard) is the Sri Lankan lizard genus Ceratophora, which contains three species with rostral (or nasal) appendages, and two other species that are appendage-less. In a recent paper in Journal of Zoology, Johnston et al. discuss the evolution of these appendages. It’s long been debated whether the appendages evolved independently in each species or once in the ancestral Ceratophora, followed by loss in the two nasally-naked species. By combining analyses of phylogeny (which produces somewhat inconclusive reconstructions of ancestral phenotype), morphology and allometry, the authors conclude that the appendages most likely evolved independently in each of the three species. Moreover, they suggest the blob-like appendage of C. tennenti (bottom photo) may have evolved for crypsis, but the more horn-like appendages of the other two species probably resulted from sexual selection.

While on the topic of nasal horns, I decided to see if there are any new photos of the other horned anole, A. phyllorhinus, on the web, and indeed there are. See below. The natural history of this species, which likely evolved its horn independently of A. proboscis, awaits further study.



Northern House Gecko Eats Biscuit: Video Clips

Northern House Gecko eats biscuit !

The Northern House Gecko (Hemidactylus flaviviridis) is a widespread species found in human-modified habitats throughout northern and eastern India. This is probably the most common house-dwelling gecko in Kolkata, the eastern capital of India. This species is primarily insectivorous and often observed to hunt on various insects like ants, mosquitoes or cockroaches. As an altered behavior, it is also not very uncommon to find this species extending it’s food items to available edible human food products! However, there have not been many reported incidents where Northern House Geckos specialized on a certain type of human food.

The video clips here show an individual gecko that ‘waits’ for biscuits everyday almost at the same time in the evening at my home in Kolkata. This individual shows extraordinary ‘pet’ behavior and sometimes eats from my hand. This has been happening since 2011 until very recently.Sometimes the gecko goes missing for a couple of months, but reappears again when we find it waiting for a biscuit near the TV-table, its usual refuge. Though not marked,I assume it to be the same individual as it has very distinctive behavior.

The Anole Bunch-Munch Frenzy

_MG_4001 copyAfter an early afternoon rain in western Cordillera Central of the Dominican Republic, a swarm of “flying ants” emerged from a nest on ground, most of them gathering at top of this antenna pole, attracting the attention of the neighboring community of anoles. Approximately a “platoon” of 2 dozen of A. chlorocyanus started climbing up the 7-8 meter tall pole, a few A. cybotes stayed low, and at least one A. distichus joined the feast. The lizards came from two small wooden buildings and used the wire (seen near top, at right side) and roof-to-nearest bushes jumps to access the pole. Many more came and went. Certainly, there were several males, and dewlap displays were made once in a while, but there was no time (or no real need?) for a fight this time. Some male chlorocyanus live very close to each other in those buildings (along with several females), and show notorious scars over their faces.

Editor’s Note: Here’s another video that Miguel mentioned in a comment (below):

Taxonomic Splitting And The Meteoric Rise In The Number Of Reptile Species

The rise in number of recognized reptile species through the years.

The rise in number of recognized reptile species through the years.

The number of described species of reptiles has increased extraordinarily in recent times. In a fascinating recent article, Pincheira-Donoso and colleagues have catalogued this increase, as well as describing the taxonomic distribution of present-day reptile diversity. They report that since 2000, the number of described species of lizards has increased by 1164, a remarkable increase of 26%. They also point out that reptile diversity among clades is right-skewed, with most genera containing relatively few species and a few containing a lot. And, of course, they highlight everyone’s favorite genus, Anolis, as one of the largest outliers.

Speaking of anoles, AA wondered how anole diversity has changed since 2000. Daniel Pincheira-Donoso kindly provided the answer, with information provided by co-author Peter Uetz. Since 2000, 42 species have been described, bringing the total in March 2012 (when data were compiled) to 384 (the list of new species from 2000 til the present appears below). That’s only a 12% increase, lagging behind lizards in general, but more on par with the description rate for snakes, which has increased 16% over that period. As AA readers are well aware, however, new anole species are being described at a high rate (e.g., 1,2) and, indeed, Uetz’s Reptile DataBase now puts the number at 391.

What’s behind this incredible burst of species description, both in anoles and more broadly? Some of it is the result of exploration and discovery of truly new, previously unknown, lizards. But most of the increase—in my humble estimation—is the result of the taxonomic splitting of previously widespread species into multiple species. Systematics goes through phases of “lumping” and “splitting” and the field in general seems to be experiencing a massive phase of splitting at the moment. In some cases, this is the result of taxa being differentiated on the basis of morphological characters. However, most is the result of the discovery of genetic differentiation among populations. A naysayer might be prompted to say that this has gone to far, that species are sometimes being described on the basis of minor, insubstantial differentiation. It will be interesting to see if and how much the pendulum swings back.

Are these really the same species?

Are these really the same species?

Regardless, one of the reasons that anole diversity has not increased as much as that in other taxa is that anole systematists—to date—have been restrained in their splitting, particularly in the West Indies. Substantial genetic diversity has been found among populations in many anole species, differentiation so great that many would have described four, six, or eight species from single widespread Caribbean taxa. This, of course, may change in the future, and the diversity of Caribbean anoles may skyrocket.


Below are the abstract of the Pincheira-Donoso paper and then the list of new anoles described from 2000-2012. And when you’re done reading those, check out Daniel Pincheira-Donoso’s website, with much information on Daniel and his work on Liolaemus.


Reptiles are one of the most ecologically and evolutionarily remarkable groups of living organisms, having successfully colonized most of the planet, including the oceans and some of the harshest and more environmentally unstable ecosystems on earth. Here, based on a complete dataset of all the world’s diversity of living reptiles, we analyse lineage taxonomic richness both within and among clades, at different levels of the phylogenetic hierarchy. We also analyse the historical tendencies in the descriptions of new reptile species from Linnaeus to March 2012. Although (non-avian) reptiles are the second most species-rich group of amniotes after birds, most of their diversity (96.3%) is concentrated in squamates (59% lizards, 35% snakes, and 2% amphisbaenians). In strong contrast, turtles (3.4%), crocodilians (0.3%), and tuataras (0.01%) are far less diverse. In terms of species discoveries, most turtles and crocodilians were described early, while descriptions of lizards, snakes and amphisbaenians are multimodal with respect to time. Lizard descriptions, in particular, have reached unprecedented levels during the last decade. Finally, despite such remarkably asymmetric distributions of reptile taxonomic diversity among groups, we found that the distributions of lineage richness are consistently right-skewed, with most clades (monophyletic families and genera) containing few lineages (monophyletic genera and species, respectively), while only a few have radiated greatly (notably the families Colubridae and Scincidae, and the lizard genera Anolis and Liolaemus). Therefore, such consistency in the frequency distribution of richness among clades and among phylogenetic levels suggests that the nature of reptile biodiversity is fundamentally fractal (i.e., it is scale invariant). We then compared current reptile diversity with the global reptile diversity and taxonomy known in 1980. Despite substantial differences in the taxonomies (relative to 2012), the patterns of lineage richness remain qualitatively identical, hence reinforcing our conclusions about the fractal nature of reptile biodiversity.

New Anole Species:

Anolis cusuco (MCCRANIE, KÖHLER & WILSON 2000)

Anolis kreutzi (MCCRANIE, KÖHLER & WILSON 2000)

Anolis toldo FONG & GARRIDO 2000

Anolis hobartsmithi (NIETO-MONTES DE OCA 2001)

Anolis ocelloscapularis (KÖHLER, MCCRANIE & WILSON 2001)

Anolis oporinus GARRIDO & HEDGES 2001

Anolis roatanensis (KÖHLER & MCCRANIE 2001)

Anolis terueli NAVARRO, FERNANDEZ & GARRIDO 2001

Anolis wampuensis (MCCRANIE & KÖHLER 2001)

Anolis yoroensis (MCCRANIE, NICHOLSON & KÖHLER 2001)

Anolis zeus (KÖHLER & MCCRANIE 2001)

Anolis ruibali NAVARRO & GARRIDO 2004

Anolis paravertebralis (BERNAL-CARLO & ROZE 2005)

Anolis umbrivagus (BERNAL-CARLO & ROZE 2005)


Anolis datzorum (KÖHLER, PONCE, SUNYER & BATISTA 2007)

Anolis gruuo (KÖHLER, PONCE, SUNYER & BATISTA 2007)

Anolis kunayalae (HULEBAK, POE, IBÁNEZ & WILLIAMS 2007)

Anolis magnaphallus (POE & IBÁNEZ 2007)

Anolis pseudokemptoni (KÖHLER, PONCE, SUNYER & BATISTA 2007)

Anolis pseudopachypus (KÖHLER, PONCE, SUNYER & BATISTA 2007)

Anolis williamsmittermeierorum POE & YAÑEZ-MIRANDA 2007

Anolis apletophallus (KÖHLER & SUNYER 2008)

Anolis campbelli (KÖHLER & SMITH 2008)

Anolis cryptolimifrons (KÖHLER & SUNYER 2008)

Anolis cuscoensis (POE, YAÑEZ-MIRANDA & LEHR 2008)

Anolis soinii (POE & YAÑEZ-MIRANDA 2008)

Anolis anchicayae (POE, VELASCO, MIYATA & WILLIAMS 2009)

Anolis ibanezi (POE, LATELLA, RYAN & SCHAAD 2009)

Anolis lyra (POE, VELASCO, MIYATA & WILLIAMS 2009)

Anolis monteverde (KÖHLER 2009)

Anolis morazani (TOWNSEND & WILSON 2009)

Anolis anoriensis (VELASCO, GUTIÉRREZ-CÁRDENAS & QUINTERO-ANGEL 2010) Anolis charlesmyersi (KÖHLER 2010)

Anolis osa (KÖHLER, DEHLING & KÖHLER 2010)

Anolis otongae (AYALA-VARELA & VELASCO 2010)

Anolis podocarpus (AYALA-VARELA & TORRES-CARVAJAL 2010)

Anolis unilobatus (KÖHLER & VESELY 2010)

Anolis benedikti (LOTZKAT, BIENENTREU, HERTZ & KÖHLER 2011)

Anolis tenorioensis (KÖHLER 2011)

Anolis sierramaestrae (HOLÁŇOVÁ, REHÁK & FRYNTA 2012)

Anolis ginaelisae (LOTZKAT, HERTZ, BIENENTREU & KÖHLER 2013)


Program For Upcoming Evolution Conference Released

Screen Shot 2013-05-17 at 1.27.18 PMAcademic conferences are important venues for researchers to learn what is new and exciting in science and to present our more recent work. The annual meetings for the Society of Integrative and Comparative Biology (SICB) is one major conference drawing over 2,000 scientists from around the world. This conference is always held in January and usually features an embarrassment of anoles. The 2012 SICB conference in Charleston, South Carolina featured many interesting talks on anoles, ranging from discussions on new eve-devo resources in this emerging model system to studies of behavioral ecology and thermal physiology (1, 2). SICB 2013 was recently held in San Francisco, and those of us following research in Anolis lizards had plenty to see and learn as there were 18 talks and posters featuring anoles. I attended many of these and summarized the findings as best I could in several AA posts this past January (1, 2, 3, 4).

As it turns out, SICB is not the only conference where anole biologists congregate in large numbers. Another major venue for learning what’s new in Anolis research is the joint meeting of the Society for Systematic Biology (SSB), Society for the Study of Evolution (SSE), and the American Society of Naturalists (ASN). This meeting is generally referred to as the Evolution conference, for short.

This year the Evolution conference will be held in Snowbird, Utah in the last week of June. Two days ago the organizers released the online program for the conference. A quick search using “Anolis” or “anole” as keywords revealed seven talks about these lizards. I’ll be attending this conference (and speaking!), and I’ll be getting updates on each of these studies onto the Anole Annals as much as I can, so stay tuned for more! In the meanwhile, here are titles for all the talks I found about Anolis. If there are more out there that I missed, please let me know!

(1) Title: Natural selection, developmental trajectories, and quantitative genetics underlying intraspecific variation in sexual dimorphism in an island lizard.
Authors: Cox, Robert; Daugherty, Christopher; Price, Jennifer; McGlothlin, Joel.

(2) Title: Extreme sex differences in the development of body size and sexual signals are mediated by hormonal pleiotropy in a dimorphic lizard.
Authors: Cox, Christian L.; Hanninen , Amanda F; Cox, Robert M.

(3) Title: Genomics of local adaptation and colorful pigmentation in Anolis lizards.
Authors: Crawford, Nicholas; McGreevy, Jr., Thomas; Mullen, Sean; Schneider, Christopher.

(4) Title: Identification of sex specific molecular markers from reduced-representation genome sequencing.
Authors: Gamble, Tony; Zarkower, David.

(5) Title: Natural selection on the thermal performance curve of Anolis sagrei.
Authors: Logan, Michael L; Cox, Robert M; Calsbeek, Ryan G.

(6) Title: Testing for simultaneous divergence and gene flow in sister-pairs of physiologically divergent Anolis lizards from Puerto Rico.
Author: McElroy, Matthew.

(7) Title: Divergence in coloration and the evolution of reproductive isolation in the Anolis marmoratus species complex.
Authors: Muñoz, Martha; Crawford, Nicholas; McGreevy, Jr., Thomas; Schneider, Christopher.

Green Anole Creeping And Displaying:The Video

Here’s a nice video clip of a green anole (A. carolinensis) creeping along a branch and displaying. To me, it’s a nice reminder that the different ecomorphs not only live in different places, but interact with their environment in very different ways. You’d rarely see a trunk-ground anole, such as A. sagrei, behaving in this manner, but it’s quite typical for trunk-crown anoles.

Another Bad Boy Anole-Eating Lizard Gaining Ground In Florida

Red headed agama in Florida. Photo by John Rahn.

Red headed agama in Florida. Photo by John Rahn.

Anole correspondent John Rahn, of Big Kahuna fame, reports that red-headed agamas are becoming established well beyond Miami. Here’s what he has to say after re-spotting an individual in a Starbucks parking lot that he had previously seen last fall: “I don’t know what he’s eating in that parking lot, but he is HUGE now. My girl at Starbucks says these are all over the place in Jupiter now. He’s survived the fairly cold weather we’ve had, this winter. He is a beauty! Saw another one, same shape, but smaller and very little color.”

AA recently discussed these guys at the Fairchild Botanical Gardens in Miami, and James Stroud suggested that they may have a big and negative effect on anoles, similar to that of curly-tailed lizards. Curlies are also in Jupiter and areas north of Miami–I wonder how these two sun-loving species get along.

Divergence and Speciation in the Lesser Antilles

Fig. 1 from Muñoz et al.: Anolis marmoratus subspecies on Basse Terre (left) and Grande Terre (right)

Fig. 1 from Muñoz et al. (2013) Anolis marmoratus subspecies on Basse Terre (left) and Grande Terre (right)

Unlike the extensive within-island speciation that anoles have undergone in the Greater Antilles, we have no evidence that the same has occurred in the Lesser Antilles. Rather, Lesser Antillean islands that contain two species are thought to be the result of dispersal events rather than in situ cladogenesis. Despite such low species diversity, however, phenotypic diversity on many of these islands certainly is not lacking. Some Lesser Antillean anoles exhibit spectacular geographic variation in head, body and dewlap colouration and pattern, as well as body size and scalation, that appears to be adaptive to different environments. So, while this variation has not led to complete speciation in any Lesser Antillean anole, is there some evidence that these phenotypically divergent populations are at some stage of the speciation process? Also, how does phenotypic divergence occur on these smaller islands when there seems to be little opportunity for geographical isolation?

AA contributor, Martha Muñoz and colleagues tackle these very questions in a recent paper in Molecular Ecology. Muñoz et al. focus on the stunning phenotypic diversity of the Anolis marmoratus complex on Guadeloupe, which has been categorised into 12 subspecies. On Grande Terre, in particular, two subspecies can be found: A. m. speciosus inhabits mesic habitats in the southwest and A. m. inornatus inhabits the xeric lowlands of the north and east. Males share a yellow-orange coloured dewlap but differ in head, body and eye ring colouration, while females and juveniles of the two subspecies are similarly drab in colour. Continue reading