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As part of another study to find out how many generations it takes for slender anole lizards (Anolis apletophallus) to adapt to climate change, a research team led by Christian Cox, a visiting scientist at STRI from Florida International University, and Mike Logan from the University of Nevada, Reno, transplanted lizards from the tropical forest on the mainland to the islands, which tend to be hotter and drier. Before the transplant, they did a general health check of the lizards that included counting the number of parasites (mites) on their bodies.

When they came back several times during the next two years to see how the lizards were doing in their new habitats, they recounted the number of mites.

"We found that on the islands with no resident species of anole lizard, the slender anole lizards that were transplanted to the islands lost their mites within a single generation, and the mites are still gone several generations later (up until the present)," Cox said. "Indeed, individual founding lizards that had mites during the initial transplant had no mites when they were later recaptured. In contrast, anole lizards that were transplanted to an island with another resident (native) species of anole lizard kept their mites for three generations, and some of the founders on the two-species island never lost their mites."

"Our study turned out to be a large-scale experimental test of the enemy release hypothesis," said Logan, who did this work as a three-year STRI/Tupper postdoctoral fellow. "Often, when an invasive animal shows up in a new place, all of its pathogens and parasites are left behind or do not survive, giving it an extra survival advantage in the new place: thus the term enemy release."

The team also found that the two-species island had lower density and lower biomass per unit area of the invasive lizard species, indicating that the continued presence of the mites may be keeping their populations under control.

"Our study is a clear example of something that conservationists have been trying to communicate to the public for some time," Logan said. "Diverse native communities sometimes function as 'enemy reservoirs' for parasites and diseases the keep down the numbers of invaders."

Funding for this study was provided by the Smithsonian Institution, Georgia Southern University, the Theodore Roosevelt Memorial Foundation and the American Museum of Natural History.

Story Source:

Materials provided by Smithsonian Tropical Research Institute. Note: Content may be edited for style and length.

Journal Reference:

1. Christian L. Cox, Sean Alexander, Brianna Casement, Albert K. Chung, John David Curlis, Zachariah Degon, Madeline Dubois, Cleo Falvey, Zackary A. Graham, Edita Folfas, Maria A. Gallegos Koyner, Lauren K. Neel, Daniel J. Nicholson, Dylan J. Padilla Perez, Xochitl Ortiz-Ross, Adam A. Rosso, Quinn Taylor, Timothy J. Thurman, Claire E. Williams, W. Owen McMillan, Michael L. Logan. Ectoparasite extinction in simplified lizard assemblages during experimental island invasion. Biology Letters, 2020; 16 (8): 20200474 DOI: 10.1098/rsbl.2020.0474

As part of another study to find out how many generations it takes for slender anole lizards (Anolis apletophallus) to adapt to climate change, a research team led by Christian Cox, a visiting scientist at STRI from Florida International University, and Mike Logan from the University of Nevada, Reno, transplanted lizards from the tropical forest on the mainland to the islands, which tend to be hotter and drier. Before the transplant, they did a general health check of the lizards that included counting the number of parasites (mites) on their bodies.

When they came back several times during the next two years to see how the lizards were doing in their new habitats, they recounted the number of mites.

"We found that on the islands with no resident species of anole lizard, the slender anole lizards that were transplanted to the islands lost their mites within a single generation, and the mites are still gone several generations later (up until the present)," Cox said. "Indeed, individual founding lizards that had mites during the initial transplant had no mites when they were later recaptured. In contrast, anole lizards that were transplanted to an island with another resident (native) species of anole lizard kept their mites for three generations, and some of the founders on the two-species island never lost their mites."

"Our study turned out to be a large-scale experimental test of the enemy release hypothesis," said Logan, who did this work as a three-year STRI/Tupper postdoctoral fellow. "Often, when an invasive animal shows up in a new place, all of its pathogens and parasites are left behind or do not survive, giving it an extra survival advantage in the new place: thus the term enemy release."

The team also found that the two-species island had lower density and lower biomass per unit area of the invasive lizard species, indicating that the continued presence of the mites may be keeping their populations under control.

"Our study is a clear example of something that conservationists have been trying to communicate to the public for some time," Logan said. "Diverse native communities sometimes function as 'enemy reservoirs' for parasites and diseases the keep down the numbers of invaders."

Funding for this study was provided by the Smithsonian Institution, Georgia Southern University, the Theodore Roosevelt Memorial Foundation and the American Museum of Natural History.

Story Source:

Materials provided by Smithsonian Tropical Research Institute. Note: Content may be edited for style and length.

Journal Reference:

1. Christian L. Cox, Sean Alexander, Brianna Casement, Albert K. Chung, John David Curlis, Zachariah Degon, Madeline Dubois, Cleo Falvey, Zackary A. Graham, Edita Folfas, Maria A. Gallegos Koyner, Lauren K. Neel, Daniel J. Nicholson, Dylan J. Padilla Perez, Xochitl Ortiz-Ross, Adam A. Rosso, Quinn Taylor, Timothy J. Thurman, Claire E. Williams, W. Owen McMillan, Michael L. Logan. Ectoparasite extinction in simplified lizard assemblages during experimental island invasion. Biology Letters, 2020; 16 (8): 20200474 DOI: 10.1098/rsbl.2020.0474