Effect of unilateral tympanotomy on auditory induced c-fos expression in cochlear nuclei

Immediate early gene expression invoked by electrical intracochlear stimulation in some but not all types of neurons in the rat auditory brainstem

Specific patterns of sensory activity may induce plastic remodeling of neurons and the communication network they form in the adult mammalian brain. Among the indicators for the initiation of neuronal remodeling is the expression of immediate early genes (IEGs). The IEGs c-fos and egr-1 encode transcription factors. Following spectrally and temporally precisely defined unilateral electrical intracochlear stimulation (EIS) that corresponded in strength to physiological acoustic stimuli and lasted for 2 h under anesthesia, we characterized those neuronal cell types in ventral (VCN) and dorsal cochlear nucleus (DCN), lateral superior olive (LSO) and central nucleus of the inferior colliculus (CIC) of the rat brain that expressed IEGs. We found that EIS affected only specific types of neurons. Whereas sub-populations of glutamatergic and glycinergic cells responded in all four regions, GABAergic neurons failed to do so except in DCN. Combining immunocytochemistry with axonal tracing, neurons participating in major ascending pathways, commissural cells of VCN and certain types of neurons of the descending auditory system were seen to respond to EIS with IEG expression. By contrast, principal LSO cells projecting to the contralateral CIC as well as collicular efferents of the DCN did not. In total, less than 50% of the identified neurons turned up expression of the IEGs studied. The pattern of IEG expression caused by unilateral EIS led us to suggest that dominant sensory activity may quickly initiate a facilitation of central pathways serving the active ear at the expense of those serving the unstimulated ear.

Acute audiogenic stress-induced activation of CRH neurons in the hypothalamic paraventricular nucleus and catecholaminergic neurons in the medulla oblongata

Strong c-fos expression was induced in neuronal cells of several brain nuclei and the auditory cortex by a short duration auditory stimulation (white noise) in rats. By double immunostaining, Fos-immunoreactive cell nuclei appeared in corticotropin-releasing hormone (CRH)-containing neurons in the hypothalamic paraventricular nucleus, but not in CRH neurons elsewhere in the brain including the central nucleus of the amygdala. Among brain catecholaminergic neurons, only cells in the medulla oblongata (in the A1/C1and A2/C2 cell groups) established double immunostaining for Fos and tyrosine hydroxylase. Sound stimulus in rats with unilateral tympanotomy and plugging the airways resulted in side differences of Fos immunoreactivity in neurons of the auditory pathways and the auditory cortex, but the effect was bilateral in hypothalamic and amygdaloid nuclei. The present data provide evidence for the participation of CRH-synthesizing neurons in hypothalamus and medullary catecholaminergic neurons in the central organization of responses to audiogenic stress stimuli.

Central tinnitus

Tinnitus is likely initiated by a discontinuity in the spontaneous or low-level-stimulus induced neural activity across auditory nerve fibers with different characteristic frequency (CF). This discontinuity may be caused by functional loss of outer hair cells in those regions where inner hair cells are preserved. The reduced spontaneous activity for nerve fibers with CFs in the hearing loss range may result in a reduction of lateral inhibition at more central levels. This reduced lateral inhibition of neurons with CFs close to the edge frequency of the audiogram induces hypersensitivity and hyperactivity in these neurons. Persistent changes in lateral inhibition result in increased numbers of neurons that are tuned to a limited range of frequencies at the edge of the cochlear lesion. Thus, the frequency map in auditory cortex, the tonotopic map, becomes reorganized as it reflects these changes. The spontaneous neuronal firings in the auditory cortex after insults that cause tinnitus show increased synchrony, thereby mimicking one aspect of the responses to normal sound stimulation. All long-standing tinnitus may thus be called central tinnitus, despite the fact that it is initiated by cochlear hearing loss or is localized to the hearing loss ear.

Transcription factor modulation and expression in the rat auditory brainstem following electrical intracochlear stimulation

Neuronal activity in sensory organs elicited by adequate or electrical stimulation not only invokes fast electrical responses but may also trigger complex molecular changes inside central neurons. Following electrical intracochlear stimulation with a cochlear implant under urethane anesthesia, we observed changes in the phosphorylation state of the cAMP response element binding protein (CREB) and the expression of the immediate-early genes c-fos and egr-1, molecules known to act as transcription factors, in a tonotopically precise pattern in central auditory neurons. These neurons resided in the posteroventral and anteroventral cochlear nucleus, the dorsal cochlear nucleus, the lateral superior olive, the medial nucleus of the trapezoid body, the dorsal and ventral nucleus of the lateral lemniscus, and the central nucleus of the inferior colliculus. Moreover, effects of electrical stimulation were identified in the medial vestibular nucleus and the lateral parabrachial nucleus. Regionally, CREB was dephosphorylated wherever immediate-early gene expression went up. These massive stimulation-dependent modulations of transcription factors in the ascending auditory system are indicative of ongoing changes that modify the chemistry and structure of the affected cells and, consequently, their response characteristics to subsequent stimulation of the inner ear.

Inner ear lesion alters acoustically induced c-Fos expression in the rat auditory rhomboencephalic brainstem

The pattern of c-Fos expression was mapped in the adult rat's brain following unilateral cochlear lesions. In normal and cochlear lesioned rats, c-Fos expression was induced with sound stimuli. Acoustic stimulation consisted of pulses of four tones. An additional control group consisted of non-stimulated rats. In the cochlear nuclei (CN), c-Fos activation was scarce in isolated rats and increased strongly following sound stimulation. Following unilateral cochlear lesion, acoustically driven expression was decreased in all CN in both the lesioned and the untreated sides. The ventromedial periolivary nucleus and the rostral periolivary nucleus showed c-Fos activation in isolated conditions and were strongly activated following sound stimulation. The rest of the superior olivary complex showed no c-Fos activation in isolated rats and a weak activation following sound stimulation. Following unilateral cochlear lesions, acoustically driven expression was decreased in some, but not all superior olivary nuclei in both the lesioned and the untreated sides. In the lateral lemniscus complex, c-Fos activation was scarce in isolated rats and increased strongly after stimulation. Following unilateral cochlear lesion, acoustically driven expression decreased bilaterally in all nuclei. We have found that unilateral inner ear lesions lead to bilateral impairment of the capability of acoustic pathway neurons, to being c-Fos-activated following sound stimulation.

Evaluating the protective role of the olivocochlear bundle against acoustic overexposure in rats by using Fos immunohistochemistry

Efferent inhibition on the cochlea is suggested as a possible function of the olivocochlear bundle (OCB). Substantial evidence supports the finding that the OCB may protect the inner ear from noise-induced damage. However, there is relatively less known about the effects of noise on the central auditory transmission compared to the effects on the periphery. In the present animal study, two experimental paradigms were designed to analyze the influence of OCB lesion on the central auditory transmission following acoustic overexposure. In order to evaluate the animal's auditory function, its hearing threshold and the tone-evoked Fos expression shown in auditory nuclei were examined. Fos is a protein product of proto-oncogene c-fos. Via appropriate acoustic stimulation, Fos expression reveals the activated neuronal elements along the ascending auditory pathway. Thus, in experiment 1, no exposure sound was introduced and therefore no significant differences were shown in hearing thresholds and Fos expression among all rats, regardless of the status of their OCB. This result indicates that, without acoustic overexposure, OCB lesion caused no significant effect on brainstem auditory transmission. In contrast, in experiment 2, rats were exposed to continuous 8 kHz tones at 85 dB sound pressure level (SPL). A significantly increasing threshold was observed in rats with OCB lesion following an exposure period of 5 or 10 days. In addition, Fos expression was invisible first in rats with OCB lesion following 5-day exposure and almost no Fos expression could be examined in all rats after 10-day exposure. Taken together, the present data demonstrate that damaging the OCB renders an animal more easily vulnerable to acoustic damage than that of rat with intact OCB, and then reduces its cochlear activities, which eventually leads to increasing difficulty to induce tone-evoked Fos expression along the ascending auditory pathway.

c-fos gene expression parallels auditory adaptation in the adult rat

This study investigated the pattern of c-fos gene expression corresponding with auditory adaptation to novel sound. Using six groups of adult rats (naive control, 1 h, and 1, 2, 3, and 4 days of continuous stimulation), we quantified c-fos expressing cells in the dorsal and ventral cochlear nuclei and found a 54 fold increase in 1 h following novel sound stimuli. The number of reactive cells decreased sharply within 24 h and nearly disappeared by 96 h. Our results reveal that c-fos gene expression in the adult rat is attenuated in parallel with the expected auditory adaptation to novel sounds indicating an association with auditory learning and memory.

Cochlear ablation alters acoustically induced c-fos mRNA expression in the adult rat auditory brainstem

Expression of c-fos mRNA was studied in the adult rat brain following cochlear ablations by using in situ hybridization. In normal animals, expression was produced by acoustic stimulation and was found to be tonotopically distributed in many auditory nuclei. Following unilateral cochlear ablation, acoustically driven expression was eliminated or decreased in areas normally activated by the ablated ear, e.g., the ipsilateral dorsal and ventral cochlear nuclei, dorsal periolivary nuclei, and lateral nucleus of the trapezoid body and the contralateral medial and ventral nuclei of the trapezoid body, lateral lemniscal nuclei, and inferior colliculus. These deficits did not recover, even after long survivals up to 6 months. Results also indicated that neurons in the dorsal cochlear nucleus could be activated by contralateral stimulation in the absence of ipsilateral cochlear input and that the influence of the contralateral ear was tonotopically organized. Results also indicated that c-fos expression rose rapidly and persisted for up to 6 months in neurons in the rostral part of the contralateral medial nucleus of the trapezoid body following a cochlear ablation, even in the absence of acoustic stimulation. This response may reflect a release of constitutive excitatory inputs normally suppressed by missing afferent input or changes in homeostatic gene expression related to sensory deprivation. Instances of transient, surgery-dependent increases in c-fos mRNA expression in the absence of acoustic stimulation were observed in the superficial dorsal cochlear nucleus and the cochlear nerve root on the ablated side.

Attenuation of Fos expression to airpuff startle stimuli following tympanic membrane rupture

The airpuff startle stimulus consists of two modalities, tactile and acoustic. Tympanic membrane rupture (TMR) effectively deafens a rat, thus preventing it from perceiving the acoustic component of the airpuff and permitting study of the tactile component in isolation. Previous studies have shown that the tactile modality is sufficient to drive the cardiovascular response to the airpuff, but cannot elicit the full behavioral startle response. In the present study Fos protein was used as a marker of neuronal activation to identify brain regions activated by the airpuff in both intact and TMR rats. Results show an attenuation of Fos expression following TMR in the dorsal and ventral cochlear nuclei, ventral nucleus of the lateral lemniscus and medial geniculate nucleus. In contrast, Fos expression following TMR was unchanged in the locus coeruleus, the laterodorsal tegmental nucleus, the supramammilary nucleus, and the ventromedial hypothalamic nucleus. Analysis of behavioral data confirmed that the startle response to the airpuff was diminished following TMR. These data are the first of which we know to employ an immediate early gene approach to discriminate between brain regions activated by the tactile and acoustic startle stimulus modalities. The results are discussed in terms of the classical acoustic startle circuit, and the central autonomic pathways activated by the tactile component of the airpuff.