Auditory cortex of bats and primates: managing species-specific calls for social communication

Jagmeet, S. Kanwal

doi:10.2741/2413

Cited by 55 publications

(42 citation statements)

References 98 publications

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“…Evidence in this direction comes from the observation that both the IC and the MGB are sensitive to basic spectral features and their variations over time (Nelken, 2008;Baumann et al, 2011), as well as to specific combinations of spectral features (Kanwal and Rauschecker, 2007). Furthermore, the MGB is responsive to complex sounds (Wenstrup, 1999), and its activity is modulated by the task (e.g.…”

Section: Medial Geniculate Bodymentioning

confidence: 99%

Subcortical processing in auditory communication

2015

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a b s t r a c tThe voice is a rich source of information, which the human brain has evolved to decode and interpret. Empirical observations have shown that the human auditory system is especially sensitive to the human voice, and that activity within the voice-sensitive regions of the primary and secondary auditory cortex is modulated by the emotional quality of the vocal signal, and may therefore subserve, with frontal regions, the cognitive ability to correctly identify the speaker's affective state. So far, the network involved in the processing of vocal affect has been mainly characterised at the cortical level. However, anatomical and functional evidence suggests that acoustic information relevant to the affective quality of the auditory signal might be processed prior to the auditory cortex.Here we review the animal and human literature on the main subcortical structures along the auditory pathway, and propose a model whereby the distinction between different types of vocal affect in auditory communication begins at very early stages of auditory processing, and relies on the analysis of individual acoustic features of the sound signal. We further suggest that this early feature-based decoding occurs at a subcortical level along the ascending auditory pathway, and provides a preliminary coarse (but fast) characterisation of the affective quality of the auditory signal before the more refined (but slower) cortical processing is completed.

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Section: Medial Geniculate Bodymentioning

confidence: 99%

Subcortical processing in auditory communication

2015

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“…Common neural substrates that have emerged as being crucial for social recognition in passerines in the auditory forebrain regions are referred to as the caudomedial nidopallium (NCM) and the caudomedial mesopallium (CMM), regions that are homologous to the mammalian auditory cortex (Jarvis et al, 2005). Just as the auditory cortex is vital to perceptual processing of auditory information in mammals (Kanwal and Rauschecker, 2007), the NCM and CMM are vital to social perception and recognition in songbirds, and exhibit selective responses to biologically meaningful auditory stimuli (Mello et al, 2004). Studies of activity-dependent gene induction, such as expression of immediate-early genes (IEGs), demonstrate that the NCM and CMM exhibit specific neural responses to conspecific songs as opposed to heterospecific songs in both parental (Mello et al, 1992) and brood parasitic songbirds (Louder et al, 2016), attractive conspecific songs as opposed to less attractive songs (Leitner et al, 2005;Monbureau et al, 2015), recently experienced songs as opposed to novel songs (Sockman et al, 2002), songs that include the birds' local dialect as opposed to a foreign dialect (Maney et al, 2003), as well as non-learned calls versus silence (Gobes et al, 2009).…”

Section: Introductionmentioning

confidence: 99%

A neural basis for password-based species recognition in an avian brood parasite

Lynch

Tyler

et al. 2017

Journal of Experimental Biology

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Obligate avian brood parasites are raised by heterospecific hosts and, therefore, lack crucial early exposure to relatives and other conspecifics. Yet, young brood parasites readily recognize and affiliate with others of their own species upon independence. One solution to this social recognition paradox is the ontogenetic 'password' mechanism used by obligate parasitic brown-headed cowbirds (Molothrus ater), whereby conspecific identification is initially mediated through the cowbird chatter: a non-learned vocal cue. We explored the neural basis of such password-based species recognition in juvenile and adult male cowbirds. We found that cowbird auditory forebrain regions express greater densities of the protein product of the immediate-early gene ZENK in response to the password chatter call relative to control sounds of mourning dove (Zenaida macroura) coos. The chatter-selective induction of ZENK expression occurs in both the caudal medial nidopallium (NCM) and the caudal medial mesopallium (CMM) in adults, but only within the NCM in juveniles. In contrast, we discovered that juvenile cowbirds exhibit neural selectivity to presentations of either conspecific or heterospecific songs, but only in CMM and only after recent experience. Juvenile cowbirds that did not have previous experience with the song type they were exposed to during the test period exhibited significantly lower activity-dependent gene expression. Thus, in juvenile male cowbirds, there is early onset of species-specific selective neural representation of non-learned calls in NCM and recently experienced song in CMM. These results suggest that NCM is evolutionarily co-opted in parasitic cowbirds to selectively recognize the password chatter, allowing juvenile cowbirds to identify adult conspecifics and avoid mis-imprinting upon unrelated host species. These ontogenetic comparisons reveal novel insights into the neural basis of species recognition in brood parasitic species.

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“…Multifunctional neurons within its AC respond to constant frequencies (CFs) and FMs that are present not only in echolocation signals but also in the rich variety of communication sounds (or social calls) emitted by this species (Esser et al 1997;Kanwal et al 1994Kanwal et al , 1999Washington and Kanwal 2008). CFs and FMs in social calls of bats and other mammalian species are acoustically analogous to formants and formant transitions in human speech (Kanwal and Rauschecker 2007;Liberman et al 1956;Rauschecker and Scott 2009;Suga 1992). Therefore, understanding the auditory processing of combinations of FMs and CFs can provide important clues about common mechanisms that direct hemispheric specializations for processing spectrotemporal information within simple syllabic calls of bats analogous to that of phonemes, the spectrotemporal unit of speech.…”

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confidence: 99%

Sex-dependent hemispheric asymmetries for processing frequency-modulated sounds in the primary auditory cortex of the mustached bat

Washington

2012

Journal of Neurophysiology

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Washington SD, Kanwal JS. Sex-dependent hemispheric asymmetries for processing frequency-modulated sounds in the primary auditory cortex of the mustached bat. J Neurophysiol 108: 1548 -1566, 2012. First published May 30, 2012 doi:10.1152/jn.00952.2011.-Species-specific vocalizations of mammals, including humans, contain slow and fast frequency modulations (FMs) as well as tone and noise bursts. In this study, we established sex-specific hemispheric differences in the tonal and FM response characteristics of neurons in the Doppler-shifted constant-frequency processing area in the mustached bat's primary auditory cortex (A1). We recorded single-unit cortical activity from the right and left A1 in awake bats in response to the presentation of tone bursts and linear FM sweeps that are contained within their echolocation and/or communication sounds. Peak response latencies to neurons' preferred or best FMs were significantly longer on the right compared with the left in both sexes, and in males this right-left difference was also present for the most excitatory tone burst. Based on peak response magnitudes, right hemispheric A1 neurons in males preferred low-rate, narrowband FMs, whereas those on the left were less selective, responding to FMs with a variety of rates and bandwidths. The distributions of parameters for best FMs in females were similar on the two sides. Together, our data provide the first strong physiological support of a sex-specific, spectrotemporal hemispheric asymmetry for the representation of tones and FMs in a nonhuman mammal. Specifically, our results demonstrate a left hemispheric bias in males for the representation of a diverse array of FMs differing in rate and bandwidth. We propose that these asymmetries underlie lateralized processing of communication sounds and are common to species as divergent as bats and humans.

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Auditory cortex of bats and primates: managing species-specific calls for social communication

Cited by 55 publications

References 98 publications

Subcortical processing in auditory communication

Subcortical processing in auditory communication

A neural basis for password-based species recognition in an avian brood parasite

Sex-dependent hemispheric asymmetries for processing frequency-modulated sounds in the primary auditory cortex of the mustached bat

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