Objective

Voltage-gated Ca2+ channels are key players in regulating cellular Ca2+ homeostasis. Only few Ca2+ channels have been functionally related to auditory information processing including Cav1.3 L-type Ca2+ channels, the ablation of which results in congenital deafness. Recent animal studies suggested that Cav3.2 T-type Ca2+ channels might play a role in age- and noise-induced hearing loss as ablation of the channel seemed to protect from sensorineural hearing loss. On the other hand, Cav3.2 Ca2+ channels were reported to exhibit increased expression with age in the inner ear/spiral ganglion neurons pointing to an important functional role in the auditory system. Interestingly, no auditory profiling of Cav3.2+/− and Cav3.2−/− mice had been performed to unravel the physiological involvement of Cav3.2 in the peripheral and ascending auditor tract. To do so, we carried out click and tone burst evoked auditory brainstem response (ABR) recordings from Cav3.2+/+, Cav3.2+/− and Cav3.2−/− mice from both genders. Monaural recording results in all three lines were analyzed for threshold alterations and differences in peak amplitudes and peak latencies and submitted elsewhere. Raw ABR data were exported as txt.-files to provide free access and to enable researchers to carry out their own ABR data analysis, including further investigation of binaural recordings or application of additional manual and/or automatic analytical tools (Table 1).

Table 1 Overview of data files/data sets [2]
Full size table

Data description

Experimental animals

Cav3.2 transgenic mice [1] from Mutant Mouse Resource and Research Centers (MMRRC: 009979-MU; strain name: B6.129-Cacna1htm1Kcam/Mmmh) were maintained in the C57Bl/6J background. For subsequent ABR recordings, Cav3.2+/+ controls, heterozygous Cav3.2+/− and homozygous null mutant Cav3.2−/− mice (55 animals in total) were used from both age-matched genders with the following characteristics: Males: Cav3.2+/+: n = 11 (♂), weight 32.82 ± 0.58 g; Cav3.2+/−: n = 7 (♂), weight 33.11 ± 0.81 g; Cav3.2−/−: n = 9 (♂), weight 29.09 ± 0.75 g. Females: Cav3.2+/+: n = 12 (♀), weight 24.09 ± 0.41 g; Cav3.2+/−: n = 8 (♀), weight 23.50 ± 0.41 g; Cav3.2−/−: n = 8 (♀), weight 22.10 ± 0.43 g.

ABR recording procedure

For recording of monaural bioelectrical auditory potentials, subdermal stainless steel electrodes were inserted at the vertex, axial the pinnae [(+) electrode] and ventrolateral of the right pinna [(−) electrode]. The ground electrode was positioned at the hip of the animal. To verify proper electrode positioning/conductivity, impedance measurements of all electrodes (< 5 kΩ) were carried out prior to each recording [Lundt A, Seidel, Robin, Soos J, Henseler C, Müller R, Bakki M, Arshaad IM, Ehninger D, Hescheler J, Sachinidis A, Broich K, Wormuth C, Papazoglou A, Weiergräber M. Cav3.2 T-type calcium channels are physiologically mandatory for the auditory system despite their devastating role in sensorineural hearing loss. Neuroscience, unpublished].

All ABR recordings were performed under free field conditions using a single loudspeaker (MF1 Multi-Function Speaker, TDT, USA) which was positioned 10 cm opposite to the rostrum of the animals.

The SigGenRZ software (TDT) was used to program stimulus protocols for click and tone bursts. The bioelectrical ABR signals recorded from the subdermal electrodes were transferred to a head stage (RA4LI, TDT) and forwarded to the preamplifier (RA4PA, TDT) with 20-fold amplification.

ABR data acquisition was carried out at a sampling rate of 24.4 kHz and signals were bandpass filtered (high pass 300 Hz, low pass 5 kHz) using a 6-pole Butterworth filter. The individual ABR data acquisition time was 25 ms starting with a 5 ms baseline period prior to the individual acoustic stimulus onset (pre ABR baseline) and exceeding the 10 ms ABR section by another 10 ms baseline (post ABR baseline) [Lundt et al., unpublished].

Two types of acoustic stimuli were applied for ABR recordings using the SigGenRZ software (TDT) and applied via the TDT BioSigRZ platform. The first stimulus entity was a click of 100 µs duration, with alternating polarity (switching between condensation and rarefaction).

The second stimulus entity was a 4.5 ms tone burst (transient sinusoidal plus) of alternating polarity with Hann envelope rise and fall times of 1.5 ms duration. The frequency range covers 1–42 kHz in 6 kHz steps. All acoustic stimuli were applied 300 times at a rate of 20 Hz for averaging.

Sound pressure levels (SPL) were increased in 5 dB steps for clicks and 10 dB steps for tone bursts, starting from 0 dB up to 90 dB (increasing SPL mode). Sound pressure levels for tone bursts within the range of 1–42 kHz were calibrated each day prior to recording [Lundt et al., unpublished].

Limitations

ABR data presented here were performed under standard free field conditions. Data were recorded from age-matched animals of ~ 20 weeks. We did not record from animals of different age.