Contextual Modulation of Vocal Behavior in Mouse: Newly Identified 12 kHz "Mid-Frequency" Vocalization Emitted during Restraint.
mouse; context; isolation; restraint; stress; vocalization
While several studies have investigated mouse ultrasonic vocalizations (USVs) emitted by isolated pups or by males in mating contexts, studies of behavioral contexts other than mating and vocalization categories other than USVs have been limited. By improving our understanding of the vocalizations emitted by mice across behavioral contexts, we will better understand the natural vocal behavior of mice and better interpret vocalizations from mouse models of disease. Hypothesizing that mouse vocal behavior would differ depending on behavioral context, we recorded vocalizations from male CBA/CaJ mice across three behavioral contexts including mating, isolation, and restraint. We found that brief restraint elevated blood corticosterone levels of mice, indicating increased stress relative to isolation. Further, after 3 days of brief restraint, mice displayed behavioral changes indicative of stress. These persisted for at least 2 days after restraint. Contextual differences in mouse vocal behavior were striking and robust across animals. Thus, while USVs were the most common vocalization type across contexts, the spectrotemporal features of USVs were context-dependent. Compared to the mating context, vocalizations during isolation and restraint displayed a broader frequency range, with a greater emphasis on frequencies below 50 kHz. These contexts also included more non-USV vocal categories and different vocal patterns. We identified a new Mid-Frequency Vocalization, a tonal vocalization with fundamental frequencies below 18 kHz, which was almost exclusively emitted by mice undergoing restraint stress. These differences combine to form vocal behavior that is grossly different among behavioral contexts and may reflect the level of anxiety in these contexts.
Grimsley Jasmine M S; Sheth Saloni; Vallabh Neil; Grimsley Calum A; Bhattal Jyoti; Latsko Maeson; Jasnow Aaron; Wenstrup Jeffrey J
Frontiers in behavioral neuroscience
2016
1905-07
Article information provided for research and reference use only. All rights are retained by the journal listed under publisher and/or the creator(s).
<a href="http://doi.org/10.3389/fnbeh.2016.00038" target="_blank" rel="noreferrer noopener">10.3389/fnbeh.2016.00038</a>
Postnatal developmental changes in the medial nucleus of the trapezoid body in a mouse model of auditory pathology.
*Disease Models; AHL; Animal; Animals; Auditory brainstem responses; Auditory Pathways/*growth & development/*pathology; Auditory system; DBA/2; Hearing Loss/*pathology; Inbred CBA; Inbred DBA; Mice; MNTB; Newborn; Olivary Nucleus/*growth & development/*pathology; Organ Culture Techniques
Age-related hearing loss (AHL) is a multifactorial disorder characterized by a decline in peripheral and central auditory function. Here, we examined synaptic transmission in DBA/2 mice, which carry the AHL8 gene, at the identifiable glutamatergic synapse in the medial nucleus of the trapezoid body (MNTB), a nucleus in the superior olivary complex critical for acoustic timing. Mice exhibited raised auditory brainstem thresholds by P14, soon after hearing onset. Excitatory postsynaptic currents were prolonged; however, postsynaptic excitability was normal. By P18, high-frequency hearing loss was evident. Coincident with the onset of hearing loss, MNTB principal neurons displayed changes in intrinsic firing properties. These results suggest that changes in transmission in the superior olivary complex are associated with early onset hearing loss.
Grimsley Calum A; Sivaramakrishnan Shobhana
Neuroscience letters
2014
2014-01
Article information provided for research and reference use only. All rights are retained by the journal listed under publisher and/or the creator(s).
<a href="http://doi.org/10.1016/j.neulet.2013.11.051" target="_blank" rel="noreferrer noopener">10.1016/j.neulet.2013.11.051</a>
An improved approach to separating startle data from noise.
*Electronic Data Processing; *Noise; Acoustic startle reflex; Acoustic Stimulation/methods; Analysis of Variance; Animal locomotion; Animals; Auditory/*physiology; Automated classification; Evoked Potentials; Inbred CBA; Male; Mice; Reflex; Startle waveform analysis; Startle/*physiology; Time Factors; Video Recording
BACKGROUND: The acoustic startle reflex (ASR) is a rapid, involuntary movement to sound, found in many species. The ASR can be modulated by external stimuli and internal state, making it a useful tool in many disciplines. ASR data collection and interpretation varies greatly across laboratories making comparisons a challenge. NEW METHOD: Here we investigate the animal movement associated with a startle in mouse (CBA/CaJ). Movements were simultaneously captured with high-speed video and a piezoelectric startle plate. We also use simple mathematical extrapolations to convert startle data (force) into center of mass displacement ("height"), which incorporates the animal's mass. RESULTS: Startle plate force data revealed a stereotype waveform associated with a startle that contained three distinct peaks. This waveform allowed researchers to separate trials into 'startles' and 'no-startles' (termed 'manual classification). Fleiss' kappa and Krippendorff"s alpha (0.865 for both) indicate very good levels of agreement between researchers. Further work uses this waveform to develop an automated startle classifier. The automated classifier compares favorably with manual classification. A two-way ANOVA reveals no significant difference in the magnitude of the 3 peaks as classified by the manual and automated methods (P1: p=0.526, N1: p=0.488, P2: p=0.529). COMPARISON WITH EXISTING METHOD(S): The ability of the automated classifier was compared with three other commonly used classification methods; the automated classifier far outperformed these methods. CONCLUSIONS: The improvements made allow researchers to automatically separate startle data from noise, and normalize for an individual animal's mass. These steps ease inter-animal and inter-laboratory comparisons of startle data.
Grimsley Calum A; Longenecker Ryan J; Rosen Merri J; Young Jesse W; Grimsley Jasmine M S; Galazyuk Alexander V
Journal of neuroscience methods
2015
2015-09
Article information provided for research and reference use only. All rights are retained by the journal listed under publisher and/or the creator(s).
<a href="http://doi.org/10.1016/j.jneumeth.2015.07.001" target="_blank" rel="noreferrer noopener">10.1016/j.jneumeth.2015.07.001</a>