Past social experience and current social context shape the responses of animals to social signals. The serotonergic system is one potential mechanism by which both experiential and contextual factors could be conveyed to sensory systems, such as the auditory system, for multiple reasons. 1) Many features of the serotonergic system are sensitive to social experience. 2) Elevations in serotonergic activity are triggered by social partners, and variations in socially triggered serotonergic responses reflect behavioral differences among social encounters. 3) Serotonin is an auditory neuromodulator, altering how auditory neurons respond to sounds including conspecific vocalizations. In this study, we tested how social experience influences the socially triggered serotonergic response in the inferior colliculus, an auditory midbrain region with an important role in vocalization processing. We used carbon fiber voltammetry to measure serotonin during social interactions of male mice ( Mus musculus) from different social backgrounds: 4 weeks of grouped or individual housing. When paired with an unfamiliar male, both group-housed and individually housed males demonstrated elevations in serotonin; however, individually housed males exhibited socially triggered serotonergic responses with delayed time courses compared with the group-housed males. Furthermore, group-housed males displayed previously described correlations between the socially triggered serotonergic response and behaviors such as social investigation. In contrast, individually housed males did not show these serotonin-behavior relationships. These results suggest that social experience gained via social housing may shape the ability of the central serotonergic system to encode social context in sensory regions. NEW & NOTEWORTHY We demonstrate that past social experience influences the fidelity with which the serotonergic system represents social context in an auditory region. Social experience altered the time course of socially triggered serotonergic responses and changed how the serotonergic system reflects behavioral variations among social encounters of the same context. These findings are significant to the study of communication, suggesting that centralized neuromodulatory systems potentially convey integrated information regarding past experience and current context to primary sensory regions.
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Sound‐induced monoaminergic turnover in the auditory forebrain depends on endocrine state in a seasonally‐breeding songbird
Sensory responses to courtship signals can be altered by reproductive hormones. In seasonally‐breeding female songbirds, for example, sound‐induced immediate early gene expression in the auditory pathway is selective for male song over behaviourally irrelevant sounds only when plasma oestradiol reaches breeding‐like levels. This selectivity has been hypothesised to be mediated by the release of monoaminergic neuromodulators in the auditory pathway. We previously showed that in oestrogen‐primed female white‐throated sparrows, exposure to male song induced dopamine and serotonin release in auditory regions. To mediate hormone‐dependent selectivity, this release must be (i) selective for song and (ii) modulated by endocrine state. Therefore, in the present study, we addressed both questions by conducting playbacks of song or a control sound to females in a breeding‐like or a nonbreeding endocrine state. We then used high‐performance liquid chromatography to measure turnover of dopamine, norepinephrine and serotonin in the auditory midbrain and forebrain. We found that sound‐induced turnover of dopamine and serotonin depended on endocrine state; hearing sound increased turnover in the auditory forebrain only in the birds in a breeding‐like endocrine state. Contrary to our expectations, these increases occurred in response to either song or artificial tones; in other words, they were not selective for song. The selectivity of sound‐induced monoamine release was thus strikingly different from that of immediate early gene responses described in previous studies. We did, however, find that constitutive monoamine release was altered by endocrine state; irrespective of whether the birds heard sound or not, turnover of serotonin in the auditory forebrain was higher in a breeding‐like state than in a nonbreeding endocrine state. The results of the present study suggest that dopaminergic and serotonergic responses to song and other sounds, as well as serotonergic tone in auditory areas, could be seasonally modulated.
more » « less- NSF-PAR ID:
- 10061521
- Publisher / Repository:
- Wiley-Blackwell
- Date Published:
- Journal Name:
- Journal of Neuroendocrinology
- Volume:
- 30
- Issue:
- 6
- ISSN:
- 0953-8194
- Format(s):
- Medium: X
- Sponsoring Org:
- National Science Foundation
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The plainfin midshipman, Porichthys notatus, is a seasonally breeding vocal fish that relies on acoustic communication to mediate nocturnal reproductive behaviors. Reproductive females use their auditory senses to detect and localize “singing” males that produce multiharmonic advertisement (mate) calls during the breeding season. Previous work showed that the midshipman saccule, which is considered the primary end organ used for hearing in midshipman and most other fishes, exhibits reproductive state and hormone-dependent changes that enhance saccular auditory sensitivity. In contrast, the utricle was previously posited to serve primarily a vestibular function, but recent evidence in midshipman and related toadfish suggests that it may also serve an auditory function and aid in the detection of behaviorally relevant acoustic stimuli. Here, we characterized the auditory-evoked potentials recorded from utricular hair cells in reproductive and nonreproductive female midshipman in response to underwater sound to test the hypothesis that variation in reproductive state affects utricular auditory sensitivity. We show that utricular hair cells in reproductive females exhibit up to a sixfold increase in the utricular potential magnitude and have thresholds based on measures of particle acceleration (re: 1 ms −2 ) that are 7–10 dB lower than nonreproductive females across a broad range of frequencies, which include the dominant harmonics of male advertisement calls. This enhanced auditory sensitivity of the utricle likely plays an essential role in facilitating midshipman social and reproductive acoustic communication. NEW & NOTEWORTHY In many animals, vocal-acoustic communication is fundamental for facilitating social behaviors. For the vocal plainfin midshipman fish, the detection and localization of social acoustic signals are critical to the species’ reproductive success. Here, we show that the utricle, an inner ear end organ often thought to primarily serve a vestibular function, serves an auditory function that is seasonally plastic and modulated by the animal’s reproductive state effectively enhancing auditory sensitivity to courting male advertisement calls.more » « less
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