- Gupta S., Alluri RK, Rose GJ, Bee MA. Neural Basis of Acoustic Species Recognition in a Cryptic Species Complex. J Exp Biol (2021) 224 (23): jeb243405. Published, 08/2021.
- Alluri RK, Rose GJ, Leary CJ, Palaparthi A, Hanson JL, Graham JA, Vasquez-Opazo GA (2021) How auditory selectivity for sound timing arises: multiple mechanisms for decoding long-intervals. Prog. In Neurobiology 199: 101962. Published, 08/2021.
- Rose GJ, Leary CJ, Bee MA (2020) Anuran auditory systems as models for understanding sensory processing and the evolution of communication. In: The Senses. Eds: B. Fritsch, B. Grothe. Published, 07/2020.
- Alluri RK, Rose GJ, Leary CJ, Palaparthi A, Hanson JL, Graham JA, Vasquez-Opazo GA (2020) How auditory selectivity for sound timing arises: multiple mechanisms for decoding long-intervals. Prog. In Neurobiology 101962, published online. Published, 01/2020.
- Price SM, Kyphuong Luong, Bell R, Rose GJ (2018) Latency of facultative expression of male-typical courtship behaviour in female bluehead wrasses: The ‘priming and gating’ hypothesis J. Exp. Biol. 221:1-8. Published, 11/2018.
- Rose GJ (2018). The numerical abilities of anurans and their neural correlates: insights from neuroethological studies of acoustic communication. Philosophical transactions of the Royal Society of London. Series B, Biological sciences. Vol. 373. Published, 07/01/2018.
- Alluri RK, Rose GJ, Hanson JL, Leary CJ, Graham JA, Vasquez-Opazo GA (2016) Delayed, phasic excitation and sustained inhibition underlie neural selectivity for short-duration sounds. Published, 03/29/2016.
- Naud R, Houtman D, Rose GJ, Longtin A (2015) Counting on dis-inhibition: a circuit motif for interval counting and selectivity in the anuran auditory system. J. Neurophysiol. 114(5):2804-2815. Published, 09/2015.
- Rose GJ, Hanson JL, Leary CJ, Graham JA, Alluri RK, Vasquez-Opazo GA (2015) Species-specificity of temporal processing in the auditory midbrain of gray treefrogs: Interval-counting neurons. J. Comp. Physiol. 201:485-503. Published, 03/2015.
We study animal behavior at both 'proximate' and 'ultimate' levels. At the proximate level, we investigate how neural circuits in fish and anuran amphibians control natural behaviors. At the ultimate level, we study the adaptive significance and evolution of these behaviors. Our research methodology, therefore, ranges from neurophysiological analysis of single neuron function to behavioral studies in the lab and field. Behavioral studies allow us to generate testable hypotheses concerning neural control. Conversely, neurophysiological experiments provide clues as to the evolution of behaviors. Specific research programs are described below.