Inhibition does not affect the timing code for vocalizations in the mouse auditory midbrain

Dimitrov, Alexander G.; Cummins, Graham I.; Mayko, Zachary M.; Portfors, Christine V.

doi:10.3389/fphys.2014.00140

Front. Physiol.

2014

DOI: 10.3389/fphys.2014.00140

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Inhibition does not affect the timing code for vocalizations in the mouse auditory midbrain

Alexander G. Dimitrov

Graham I. Cummins

Zachary M. Mayko

et al.

Abstract: Many animals use a diverse repertoire of complex acoustic signals to convey different types of information to other animals. The information in each vocalization therefore must be coded by neurons in the auditory system. One way in which the auditory system may discriminate among different vocalizations is by having highly selective neurons, where only one or two different vocalizations evoke a strong response from a single neuron. Another strategy is to have specific spike timing patterns for particular vocal… Show more

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Cited by 3 publications

References 65 publications

(101 reference statements)

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The effect of inhibition on stimulus-specific adaptation in the inferior colliculus

Ayala

Malmierca

2017

Brain Struct Funct

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The inferior colliculus is a center of convergence for inhibitory and excitatory synaptic inputs that may be activated simultaneously by sound stimulation. Stimulus repetition may generate response habituation by changing the efficacy of neuron's synaptic inputs. Specialized IC neurons reduce their response to repetitive tones, but restore their firing when a different and infrequent tone occurs, a phenomenon known as stimulus specific adaptation. Here, using the microiontophoresis technique, we determined the role of GABA-, GABA-, and glycinergic receptors in stimulus-specific adaptation (SSA). We found that blockade of postsynaptic GABA receptors selectively modulated response adaptation to repetitive sounds, whereas blockade of presynaptic GABA receptors exerted a gain control effect on neuron excitability. Adaptation decreased when postsynaptic GABA receptors were blocked, but increased if the blockade affected the presynaptic GABA receptors. A dual, paradoxical effect was elicited by blockade of glycinergic receptors, i.e., both increase and decrease in adaptation. Moreover, simultaneous co-application of GABA, GABA and glycinergic antagonists demonstrated that local GABA- and glycine-mediated inhibition contributes to only about 50% of SSA. Therefore, inhibition via chemical synapses dynamically modulate the strength and dynamics of stimulus-specific adaptation, but does not generate it.

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The effect of inhibition on stimulus-specific adaptation in the inferior colliculus

Ayala

Malmierca

2017

Brain Struct Funct

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PV+ Cells Enhance Temporal Population Codes but not Stimulus-Related Timing in Auditory Cortex

et al. 2017

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Spatio-temporal cortical activity patterns relative to both peripheral input and local network activity carry information about stimulus identity and context. GABAergic interneurons are reported to regulate spiking at millisecond precision in response to sensory stimulation and during gamma oscillations; their role in regulating spike timing during induced network bursts is unclear. We investigated this issue in murine auditory thalamo-cortical (TC) brain slices, in which TC afferents induced network bursts similar to previous reports in vivo. Spike timing relative to TC afferent stimulation during bursts was poor in pyramidal cells and SOM+ interneurons. It was more precise in PV+ interneurons, consistent with their reported contribution to spiking precision in pyramidal cells. Optogenetic suppression of PV+ cells unexpectedly improved afferent-locked spike timing in pyramidal cells. In contrast, our evidence suggests that PV+ cells do regulate the spatio-temporal spike pattern of pyramidal cells during network bursts, whose organization is suited to ensemble coding of stimulus information. Simulations showed that suppressing PV+ cells reduces the capacity of pyramidal cell networks to produce discriminable spike patterns. By dissociating temporal precision with respect to a stimulus versus internal cortical activity, we identified a novel role for GABAergic cells in regulating information processing in cortical networks.

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GABA_A receptors contribute more to rate than temporal coding in the IC of awake mice

Gourévitch

Mahrt

Bakay

et al. 2020

Journal of Neurophysiology

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Speech is our most important form of communication, yet we have a poor understanding of how communication sounds are processed by the brain. Mice make great model organisms to study neural processing of communication sounds because of their rich repertoire of social vocalizations and because they have brain structures analogous to humans, such as the auditory midbrain nucleus inferior colliculus (IC). Although the combined roles of GABAergic and glycinergic inhibition on vocalization selectivity in the IC have been studied to a limited degree, the discrete contributions of GABAergic inhibition have only rarely been examined. In this study, we examined how GABAergic inhibition contributes to shaping responses to pure tones as well as selectivity to complex sounds in the IC of awake mice. In our set of long-latency neurons, we found that GABAergic inhibition extends the evoked firing rate range of IC neurons by lowering the baseline firing rate but maintaining the highest probability of firing rate. GABAergic inhibition also prevented IC neurons from bursting in a spontaneous state. Finally, we found that although GABAergic inhibition shaped the spectrotemporal response to vocalizations in a nonlinear fashion, it did not affect the neural code needed to discriminate vocalizations, based either on spiking patterns or on firing rate. Overall, our results emphasize that even if GABAergic inhibition generally decreases the firing rate, it does so while maintaining or extending the abilities of neurons in the IC to code the wide variety of sounds that mammals are exposed to in their daily lives. NEW & NOTEWORTHY GABAergic inhibition adds nonlinearity to neuronal response curves. This increases the neuronal range of evoked firing rate by reducing baseline firing. GABAergic inhibition prevents bursting responses from neurons in a spontaneous state, reducing noise in the temporal coding of the neuron. This could result in improved signal transmission to the cortex.

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Inhibition does not affect the timing code for vocalizations in the mouse auditory midbrain

Cited by 3 publications

References 65 publications

The effect of inhibition on stimulus-specific adaptation in the inferior colliculus

The effect of inhibition on stimulus-specific adaptation in the inferior colliculus

PV+ Cells Enhance Temporal Population Codes but not Stimulus-Related Timing in Auditory Cortex

GABA_A receptors contribute more to rate than temporal coding in the IC of awake mice

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Inhibition does not affect the timing code for vocalizations in the mouse auditory midbrain

Cited by 3 publications

References 65 publications

The effect of inhibition on stimulus-specific adaptation in the inferior colliculus

The effect of inhibition on stimulus-specific adaptation in the inferior colliculus

PV+ Cells Enhance Temporal Population Codes but not Stimulus-Related Timing in Auditory Cortex

GABAA receptors contribute more to rate than temporal coding in the IC of awake mice

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GABA_A receptors contribute more to rate than temporal coding in the IC of awake mice