Precisely timed inhibition facilitates action potential firing for spatial coding in the auditory brainstem

Beiderbeck, Barbara; Myoga, Michael H.; Müller, Nicolas I. C.; Callan, Alexander R.; Friauf, Eckhard; Grothe, Benedikt; Pecka, Michael

doi:10.1038/s41467-018-04210-y

Cited by 84 publications

(73 citation statements)

References 64 publications

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“…In vivo and at physiological temperatures, the inhibitory window is probably shorter and falls in the sub‐millisecond range, as suggested by recent in vivo recordings in gerbils (Beiderbeck et al . ). We showed with voltage clamp measurements that the inhibitory conductance needed to be ∼2‐fold larger than the excitatory one to guarantee suppression of AP firing driven by bushy cell inputs (Fig.…”

Section: Discussionmentioning

confidence: 97%

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Specific synaptic input strengths determine the computational properties of excitation–inhibition integration in a sound localization circuit

Gjoni

Zenke

Bouhours

et al. 2018

The Journal of Physiology

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The lateral superior olive (LSO) is a binaural nucleus in the auditory brainstem in which excitation from the ipsilateral ear is integrated with inhibition from the contralateral ear. It is unknown whether the strength of the unitary inhibitory and excitatory inputs is adapted to allow for optimal tuning curves of LSO neuron action potential (AP) firing. Using electrical and optogenetic stimulation of afferent synapses, we found that the strength of unitary inhibitory inputs to a given LSO neuron can vary over a ∼10-fold range, follows a roughly log-normal distribution, and, on average, causes a large conductance (9 nS). Conversely, unitary excitatory inputs, stimulated optogenetically under the bushy-cell specific promoter Math5, were numerous, and each caused a small conductance change (0.7 nS). Approximately five to seven bushy cell inputs had to be active simultaneously to bring an LSO neuron to fire. In double stimulation experiments, the effective inhibition window caused by IPSPs was short (1-3 ms) and its length depended on the inhibitory conductance; an ∼2-fold stronger inhibition than excitation was needed to suppress AP firing. Computational modelling suggests that few, but strong, unitary IPSPs create a tuning curve of LSO neuron firing with an appropriate slope and midpoint. Furthermore, weak but numerous excitatory inputs reduce the spontaneous AP firing that LSO neurons would otherwise inherit from their upstream auditory neurons. Thus, the specific connectivity and strength of unitary excitatory and inhibitory inputs to LSO neurons is optimized for the computations performed by these binaural neurons.

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Section: Discussionmentioning

confidence: 97%

“…) and also with recent in vivo findings (Beiderbeck et al . ). In our simulations with a simple integrate‐and‐fire model, the difference between large constant unitary ISPCs and the more realistically large unitary IPSCs with variable amplitudes was not large (Fig.…”

Section: Discussionmentioning

confidence: 97%

Specific synaptic input strengths determine the computational properties of excitation–inhibition integration in a sound localization circuit

Gjoni

Zenke

Bouhours

et al. 2018

The Journal of Physiology

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“…) is involved in sound source localization by detecting interaural level differences (ILDs) upon precise integration of cochlear nucleus‐mediated excitation and MNTB‐mediated inhibition (Tollin, ; Yin & Kuwada, ; Beiderbeck et al . ; Friauf et al . ).…”

Section: Introductionmentioning

confidence: 96%

“…In the mammalian auditory brainstem, a glycinergic projection from the MNTB to the LSO (Fischer et al 2019) is involved in sound source localization by detecting interaural level differences (ILDs) upon precise integration of cochlear nucleus-mediated excitation and MNTB-mediated inhibition (Tollin, 2003;Yin & Kuwada, 2010;Beiderbeck et al 2018;Friauf et al 2019). The MNTB-LSO circuit is functionally refined during the first two postnatal weeks in rats and mice (Kim & Kandler, 2003;Hirtz et al 2012;Clause et al 2014), and refinement coincides with the presence of spontaneous prehearing activity.…”

Section: Introductionmentioning

confidence: 99%

Topographic map refinement and synaptic strengthening of a sound localization circuit require spontaneous peripheral activity

Müller

Sonntag

Maraslioglu

et al. 2019

The Journal of Physiology

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Key points Loss of the calcium sensor otoferlin disrupts neurotransmission from inner hair cells. Central auditory nuclei are functionally denervated in otoferlin knockout mice (Otof KOs) via gene ablation confined to the periphery. We employed juvenile and young adult Otof KO mice (postnatal days (P)10–12 and P27–49) as a model for lacking spontaneous activity and deafness, respectively. We studied the impact of peripheral activity on synaptic refinement in the sound localization circuit from the medial nucleus of the trapezoid body (MNTB) to the lateral superior olive (LSO). MNTB in vivo recordings demonstrated drastically reduced spontaneous spiking and deafness in Otof KOs. Juvenile KOs showed impaired synapse elimination and strengthening, manifested by broader MNTB–LSO inputs, imprecise MNTB–LSO topography and weaker MNTB–LSO fibres. The impairments persisted into young adulthood. Further functional refinement after hearing onset was undetected in young adult wild‐types. Collectively, activity deprivation confined to peripheral protein loss impairs functional MNTB–LSO refinement during a critical prehearing period. Abstract Circuit refinement is critical for the developing sound localization pathways in the auditory brainstem. In prehearing mice (hearing onset around postnatal day (P)12), spontaneous activity propagates from the periphery to central auditory nuclei. At the glycinergic projection from the medial nucleus of the trapezoid body (MNTB) to the lateral superior olive (LSO) of neonatal mice, super‐numerous MNTB fibres innervate a given LSO neuron. Between P4 and P9, MNTB fibres are functionally eliminated, whereas the remaining fibres are strengthened. Little is known about MNTB–LSO circuit refinement after P20. Moreover, MNTB–LSO refinement upon activity deprivation confined to the periphery is largely unexplored. This leaves a considerable knowledge gap, as deprivation often occurs in patients with congenital deafness, e.g. upon mutations in the otoferlin gene (OTOF). Here, we analysed juvenile (P10–12) and young adult (P27–49) otoferlin knockout (Otof KO) mice with respect to MNTB–LSO refinement. MNTB in vivo recordings revealed drastically reduced spontaneous activity and deafness in knockouts (KOs), confirming deprivation. As RNA sequencing revealed Otof absence in the MNTB and LSO of wild‐types, Otof loss in KOs is specific to the periphery. Functional denervation impaired MNTB–LSO synapse elimination and strengthening, which was assessed by glutamate uncaging and electrical stimulation. Impaired elimination led to imprecise MNTB–LSO topography. Impaired strengthening was associated with lower quantal content per MNTB fibre. In young adult KOs, the MNTB–LSO circuit remained unrefined. Further functional refinement after P12 appeared absent in wild‐types. Collectively, we provide novel insights into functional MNTB–LSO circuit maturation governed by a cochlea‐specific protein. The central malfunctions in Otof KOs may have implications for patients with sensorineuronal hearing loss.

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“…This possibility seems particularly plausible given that immunohistochemical studies have shown that the tonotopic organization is degraded [15,16] and that stimulation-induced molecular, morphological, and electrophysiolological plasticity is altered in neonatally deafened rats compared to CI-stimulated rats with normal auditory development [15][16][17][18][19]. Furthermore, it has been shown that early acoustic experience shapes ITD tuning curves in key brainstem nuclei of gerbils [20], probably by shaping the precise timing of inhibitory inputs into superior olivary nuclei [20,21]. However, it is also possible that the unstimulated auditory pathway may retain the ability to encode ITDs during a period of early deafness, and may only lose it as a result of maladaptive plasticity after a period of CI stimulation which conveys no useful ITD information.…”

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confidence: 99%

Microsecond Interaural Time Difference Discrimination Restored by Cochlear Implants After Neonatal Deafness

Roßkothen-Kuhl

Buck

et al. 2018

Preprint

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Cochlear implants (CIs) can restore a high degree of functional hearing in deaf patients but enable only poor spatial hearing or hearing in noise. Early deaf CI users are essentially completely insensitive to interaural time differences (ITDs). A dearth of binaural experience during an early critical period is often blamed for these shortcomings. However, here we show that neonatally deafened rats which are fitted with binaural CIs in early adulthood are highly sensitive to ITDs immediately after implantation. Under binaural synchronized stimulation they can be trained to localize ITDs with essentially normal behavioral thresholds near 50 μs. This suggests that the deficits seen in human patients are unlikely to be caused by lack of experience during their period of deafness. It may instead be due to months or years of CI stimulation with inappropriate binaural parameters provided by CI processors which do not provide sub-millisecond temporal fine structure of sounds . 3 33 34 35 36 37 38 39 40 41 42 43 44 45 The World Health Organization reports that about 466 million people suffer from disabling hearing loss, making it the most common sensory impairment of our age. For people with severe to profound sensorineural hearing loss, cochlear implants (CIs) can be enormously beneficial, quite routinely allowing near normal spoken language acquisition, particularly when CI implantation takes place early in life [1]. Never the less the performance of CI users remains variable, and even in the best cases falls short of natural hearing.Good speech understanding in multi-sound environment requires the ability to separate speech from background, which relies in part on a phenomenon known as "spatial release from masking". This relies on the brain's ability to process binaural spatial cues, including interaural level and interaural time differences (ILDs/ITDs) [2]. To benefit from binaural cues in everyday life, bilateral cochlear implantation is becoming increasingly common for deaf patients [3][4][5] . However, even binaural CI patients perform much below the level of normal listeners in sound localization or auditory scene analysis tasks, particularly when multiple sound sources are present [6,7]. The parameters that would allow CI patients to derive maximum benefits from binaural spatial cues are still only partially understood. A number of technical problems (see [8], chapter 6) limit the fidelity with which CIs can encode binaural cues, particularly ITDs. The fact that contemporary CI speech processors were originally designed for monaural, rather than binaural, hearing likely contributes the observed deficits in ITD performance of bilateral CI users [3]. Standard CI processors provide pulsatile stimulation which is not locked to the temporal fine structure of the incoming sounds, and the timing of the electrical pulses is not synchronized between both ears, which makes these devices fundamentally incapable of encoding sub-millisecond binaural time structure. To be useful, ITDs as small as a few tens ...

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Precisely timed inhibition facilitates action potential firing for spatial coding in the auditory brainstem

Cited by 84 publications

References 64 publications

Specific synaptic input strengths determine the computational properties of excitation–inhibition integration in a sound localization circuit

Specific synaptic input strengths determine the computational properties of excitation–inhibition integration in a sound localization circuit

Topographic map refinement and synaptic strengthening of a sound localization circuit require spontaneous peripheral activity

Microsecond Interaural Time Difference Discrimination Restored by Cochlear Implants After Neonatal Deafness

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