How did lizard species with similar body types evolve on different islands?

TEACHER’S ANSWER KEY

PART I. INTRODUCTION1) Where are the Greater Antilles?They are islands located south of Florida.Which Islands make up the Greater Antilles?They are made up of Cuba, Hispaniola, Puerto Rico, and Jamaica.2) What is the goal of this research?To use data, such as body shape and habitat to make hypotheses about how different species of Anolis lizards are related then to test these hypotheses using a phylogenetic tree.

PART II. LOOKING FOR PATTERNS

3) What type of information does the data table show?Identification number, name of lizard species found, island each lizard was found, its habitat, and body shape.4) Describe the six different types of body shapes that the lizards have.slender body, very long tailshort body, slender legs and taillarge toe pads, can change colorlarge body, large toe padsstocky body, long hind limbslong fore limbs, flattened body5) What patterns do you see between the type of body shape a lizard has and the habitat it lives in?• Lizards with similar body shape live in similar habitats. For example, all slender body, very long tail lizards live in grasses and bushes.• There are more lizards on the larger islands. For example, Jamaica only has four species of lizard, where as Cuba has all six species.• Students may suggest patterns that relate to how the different body shapes may be adapted for the habitat that it lives in. For example, the lizards that live on twigs have short bodies and slender legs and tails. The smaller, lighter body may be advantageous when living on fragile vegetation.6) Does this pattern exist on all islands? Explain.Yes, however not all islands have all of the species of lizards. For example, Jamaica has only four species and Puerto Rico has only five.7) Which lizards do you think are more closely related; those that live on the same island but in different habitats, or those that live on different islands but have the same body features and live in the same type of habitat? Explain.Answers will vary.8) Write two alternative hypotheses about how these lizards might have speciated/evolved on and between these islands.Answers will vary.9) How could you test your hypotheses?Answers will vary. Students may suggest looking at fossils, using DNA, using other observations to determine how they are related to each other.PART III. TESTING YOUR HYPOTHESES10) Explain the different patterns that you see in the phylogenetic tree. Look at their body shape, habitat, and the island on which they are found. Write down as many observations as you can.Answers will vary.11) Based on the phylogenetic tree, which lizards do you think are more closely related: those that live on the same island but in different habitats, or those that live on different islands but have the same body shape and live in the same type of habitat? Explain using specific examples.Answers may vary, but in general students should recognize that lizards on the same island are more closely related to each other than lizards that have similar body shapes and live in the same type of habitat.12) Look back at your original hypotheses (question 8). Explain how these new data support or do not support your hypotheses about how these lizards might have speciated/evolved.Answers will vary.13) How could you further test your hypotheses? What type of information would you want to have?Answers will vary. It would be possible to use fossil data, or create a new phylogenetic tree based on different features.14) How could fossil evidence help you test your hypotheses?Fossils could suggest which body type existed the earliest to most recent, suggesting which lizards may have inhabited the islands first. A comparison with fossils from lizards on the mainland may also help us understand how the group evolved and speciated.15) How do you think the lizards could have gotten from one island to another?Answers will vary. They may have swam, floated on natural rafts, the islands may have been connected at one point. This Anole lizardfrom the Dominican Republic lives among tree trunks and boulders. Unrelated but identical Anole varieties are found in Cuba, Jamaica and Puerto Rico as well.Miguel Landestoy

Visit the Caribbean islands and you'll find the Anoles lizards hard to miss. You might run into one variety — the neon-green, crested, tree-top climbers — in Jamaica or Puerto Rico, but find them once again Hispaniola and Cuba, that look so similar you'd swear they were the same species.

They're not. But it's not just coincidence that the lizards look so similar. It's evolution, say researchers.

Whether evolution can turn out the same kinds of creature more than once has been a question that has been challenging ecologists and thinkers for decades. Say we rewound time, and took the history of our planet back some million years. When we hit play, would we end up with the same kind of species and diversity that we have today? If we went back to the extinction of the dinosaurs, would mammals and humans have evolved again?

Giant tree crown lizards in Puerto Rico (left) and Jamaica (right) evolved to look stunningly similar, with crests reaching down to their tails from their big heads and toes with thick pads to climb on smooth surfaces.Jonathan Losos / Luke Mahler

One group, led by Stephen Jay Gould, trusts the caprice and unpredictability of evolutionary events. Evolution can't direct a scene the same way more than once, they say. The opposing camp will tell you that faced with a certain set of environmental conditions, animals will evolve similar tricks.

The family of Anoles lizards in the Caribbean islands are proof that evolution can produce the same kind of peculiarities in body forms. In fact, in each of the four islands of the Greater Antilles, evolution has repeated itself four different times.

In the July 18 issue of Science, Jonathan Losos, an ecologist at Harvard University, and his colleagues show is that each time the lizards encountered one of the four islands, they grew longer legs or stickier toes or skinnier tails to conquer stony rock faces, low grassy habitats or high leafy ones. Each time, they say, evolution produced the same result.

"What's great about these islands is that they're a natural experiment," Losos told NBC News. "You're not restarting the clock, but you're starting it four times."

In fact, "if you drop a lizard on one of these islands millions of years ago, you would get a very similar outcome every time you did it," he said. He’d bet that if a fifth island magically appeared in the sea near the four, a couple of lizards dropped on it would multiply and diversify into the very same kinds of varieties that were seen on the other islands. Give them a few million years.

Twig dwellers from Cuba (left) and Puerto Rico (right) independently arrived at the same twig-like body plan. They have long slender bodies, short tails, and short legs that don't let them run too fast.Luke Mahler

In the new paper, Losos and his colleagues match up statistical analysis of the similarities of body plans of the lizards — tail lengths, body widths, skin shades — to a DNA-based charting of the lizards' ancestry.

They show that unrelated lizards, stranded separately on four of the islands, independently evolved the same characteristics. Twig-dwellers grew long and slender bodies and short legs and tails. Bark dwellers on four islands grew out patchy, mottled coats and muscular legs that allow them to bolt after prey and out of danger.

For favorable habitats, "the environment has given the Anoles a small number of options," Dolph Schluter, an ecologist at the University of British Columbia in Vancouver, told NBC News. "But they're really great options — and [the lizards] take them again and again and again."

And it wasn't just happenstance or coincidence, Losos' numbers show — the similarity is greater than plain ol' chance could have managed.

These trunk and ground-dwellers from Hispaniola (left) and Jamaica (right) dash around and jump on stocky muscular legs.B. Falk / Luke Mahler

"They have a very robust statistical framework" that leads to "the conclusion is that evolution is repeatable," David Reznick, a biologist at the University of California, Riverside, who was not involved with the work, told NBC News. "There are elements that happened on the islands of the Greater Antilles that happened again and again."

The Anole lizards arrived in the Caribbean from South America about 40 million years ago. They likely landed first on Hispaniola or Cuba. Perhaps they floated in on a drifting tree stump, Losos doesn't know for sure.

Not all flavors of lizards are found on all the islands. An Anole that looks like a chameleon and eats snails is native only to Cuba. A spindly-legged Anole that climbs rock walls is also found nowhere else. Only in Hispaniola will you find the Anole that changed its color and body shape to make its home among the leaf litter.

Reznick pointed out that Losos had made a case for the similar body plans of lizards across islands about 20 years ago. But this time, he considered the unique lizards found on only one island too, and was still able to demonstrate statistically that evolution had favored the same bag of tricks more than once.

Since the islands are close by, and have a similar range of habitats, this is a special study case, a localized one. While neither Reznick nor Losos are opposed to the idea that convergent evolution can take place on a more global scale — that unrelated species in different continents evolved similar body plans — they agree that fashioning such experiments, or finding examples to study, will be much harder.

The authors of "Exceptional Convergence on the Macroevolutionary Landscape in Island Lizard Radiations" include Luke Mahler, Travis Ingram and Liam Revell in addition to Jonathan Losos.

How have lizards evolved over time?

Which is the best explanation for why the same types of lizards evolved on each island?

Why are lizards on the same island generally more closely related to one another than to similar looking lizards from other islands?

Why have different lizard species evolved to occupy different parts of the habitats?