Acoustic behaviors including orientation and social communication depend on neural integration of information across the sound spectrum. In many species, spectral integration is performed by combination-sensitive neurons, responding best when distinct spectral elements in sounds are combined. These are generally considered a feature of information processing in the auditory forebrain. In the mustached bat's inferior colliculus (IC), they are common in frequency representations associated with sonar signals but have not been reported elsewhere in this bat's IC or the IC of other species. We examined the presence of combination-sensitive neurons in frequency representations of the mustached bat's IC not associated with biosonar. Seventyfive single-unit responses were recorded with the best frequencies in 10-23 or 32-47 kHz bands. Twenty-six displayed single excitatory tuning curves in one band with no additional responsiveness to a second signal in another band. The remaining 49 responded to sounds in both 10-23 and 32-47 kHz bands, but response types varied. Sounds in the higher band were usually excitatory, whereas sounds in the lower band either facilitated or inhibited responses to the higher frequency signal. Interactions were usually strongest when the higher and lower frequency stimuli were presented simultaneously, but the strength of interactions varied. Over one-third of the neurons formed a distinct subset; they responded most sensitively to bandpass noise, and all were combination sensitive. We suggest that these combination-sensitive interactions are activated by elements of mustached bat social vocalizations. If so, neuronal integration characterizing analysis of social vocalizations in many species occurs in the IC.
Key words: auditory pathways; bat; combination sensitive; complex sounds; frequency integration; inferior colliculus; mustached bat; spectral integrationAcoustically guided behavior requires analyses of spectrally and temporally complex signals. The auditory system first decomposes sounds into their spectral components at the cochlea and then transmits the results of these analyses through frequency-tuned neurons of the auditory nerve. Further information processing of complex sounds uses the reverse of this spectral analysis, involving neuronal integration across spectral elements in sounds. For complex vocal signals, such neuronal integration is characterized by temporally sensitive facilitatory or inhibitory interactions between responses to distinct spectral elements. Sometimes called combination sensitive, these responses have been described in a variety of vertebrates from frogs to birds to mammals and are thought to contribute to selective responses to complex vocalizations (Suga et al