Research Reports from Life Science Freshmen Research Scholars

To gain knowledge about animals and repopulate declining species, researchers often conduct husbandry programs that involve housing wild-caught animals in laboratories. Housing animals in labs for long periods may affect their behavioral flexibility, or their ability to change their behavior to adapt to changes in their environment. We measured and compared the behavioral flexibilities of wild-caught Blanchard’s cricket frogs, or Acris blanchardi, which spent a long time (40 days) and a short time in the lab (13 days). To measure behavioral flexibility, we taught frogs to go to one end of a two-arm maze. Once the frogs learned this, we switched which door was correct and measured how quickly the frogs could learn to go to the newly correct door in a process called serial reversal learning. We switched which door was correct three times. We found that frogs that spent more time in the lab before testing were better at learning the maze and showed some evidence of behavioral flexibility. Frogs that spent little time in the lab showed no evidence of behavioral flexibility. Frogs that spent more time in the lab before testing may have been more habituated to lab conditions and thus less stressed when placed in the maze. Keeping wild-caught frogs in the lab for a longer time before release may increase their chances of survival upon reintroduction to the wild, since they will have enough time to overcome the initial stress of being in a new environment and have better behavioral flexibility when released.

Beauclerc, K. B., B. Johnson, and B. N. White. 2010. Distinctiveness of declining northern populations of Blanchard’s Cricket Frog (Acris blanchardi) justifies recovery efforts. Canadian Journal of Zoology 88:553-566.

Bond, A. B. K., Alan C.; Balda, Russell P. 2007. Serial reversal learning and the evolution of behavioral flexibility in three species of North American corvids (Gymnorhinus cyanocephalus, Nucifraga columbiana, Aphelocoma californica). Journal of Comparative Psychology 121:372-379.

Daszak, P., A. A. Cunningham, and A. D. Hyatt. 2003. Infectious disease and amphibian population declines. Diversity and Distributions 9:141-150.

Day, L. B., D. Crews, and W. Wilczynski. 1999. Spatial and reversal learning in congeneric lizards with different foraging strategies. Animal Behaviour 57:393-407.

Gamble, T., P. B. Berendzen, H. Bradley Shaffer, D. E. Starkey, and A. M. Simons. 2008. Species limits and phylogeography of North American cricket frogs (Acris: Hylidae). Molecular Phylogenetics and Evolution 48:112-125.

Ghahremani, D. G., J. Monterosso, J. D. Jentsch, R. M. Bilder, and R. A. Poldrack. 2010. Neural components underlying behavioral flexibility in human reversal learning. Cerebral Cortex 20:1843-1852.

Irwin, J. T., J. P. Costanzo, and J. R. E. Lee. 1999. Terrestrial hibernation in the northern cricket frog, Acris crepitans. Canadian Journal of Zoology 77:1240-1246.

Jones, C. B. 2005. Behavioral Flexibility: Interpretations and Prospects. Pages 123-138 Behavioral Flexibility in Primates: Causes and Consequences. Springer US, Boston, MA.

Kiesecker, J. M., A. R. Blaustein, and L. K. Belden. 2001. Complex causes of amphibian population declines. Nature 410:681-684.

Lehtinen, R. M., and A. A. Skinner. 2006. The enigmatic decline of Blanchard's cricket frog (Acris crepitans blanchardi): A test of the habitat acidification hypothesis. Copeia 2006:159-167.

Liu, Y., L. B. Day, K. Summers, and S. S. Burmeister. 2016. Learning to learn: advanced behavioural flexibility in a poison frog. Animal Behaviour 111:167-172.

McCallum, M. L. 2010. Future climate change spells catastrophe for Blanchard’s cricket frog, Acris blanchardi (Amphibia: Anura: Hylidae).

Pounds, J. A., M. P. L. Fogden, and J. H. Campbell. 1999. Biological response to climate change on a tropical mountain. Nature 398:611-615.

Simon N. Stuart, J. S. C., Neil A. Cox, Bruce E. Young, Ana S. L. Rodrigues, Debra L. Fischman, Robert W. Waller. 2004. Status and Trends of Amphibian Declines and Extinctions Worldwide. Science 306:1783-1786.