ABSTRACT
Throughout the brain, neurons exhibit a remarkable capacity to maintain stable firing rates despite large perturbations in afferent activity levels. As an exception, homeostatic regulation of neural activity often fails in the adult auditory system after hearing loss. Cochlear deafferentation caused by aging or noise exposure triggers widespread neural hyperactivity, particularly in the auditory cortex (ACtx), which underlies perceptual disorders including tinnitus and hyperacusis. Here, we show that mice with noise-induced damage of the high-frequency cochlear base were behaviorally hypersensitive to spared mid-frequency tones and to direct optogenetic stimulation of auditory thalamocortical neurons. Chronic 2-photon calcium imaging from ACtx pyramidal neurons (PyrNs) revealed an initial stage of diffuse hyperactivity, hypercorrelation, and hyperresponsivity that consolidated around deafferented map regions three or more days after acoustic trauma.
Deafferented PyrN ensembles displayed hypersensitive decoding of spared mid-frequency tones, mirroring behavioral hypersensitivity. At the level of individual PyrNs, some exhibited stable, homeostatic gain control after acoustic trauma, while others showed non-homeostatic excess gain. Interestingly, factors such as baseline spontaneous activity levels and sound level encoding could account for 40% of the variability in PyrN gain regulation after acoustic trauma. These findings suggest that non-homeostatic regulation of cortical sound intensity coding following sensorineural loss may underlie the well-established clinical phenomenon of loudness hypersensitivity. Further, while cortical gain changes are triggered by reduced bottom-up afferent input, their subsequent stabilization is also shaped by their local circuit milieu, where baseline response features can identify neurons with the greatest propensity for developing pathological hyperactivity following sensorineural hearing loss.
Competing Interest Statement
The authors have declared no competing interest.
Footnotes
↵+ Lead contact: mmcgill{at}harvard.edu