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Imaging Neural Activity in the Primary Somatosensory Cortex Using Thy1-GCaMP6s Transgenic Mice
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Enhanced Sensory Coding in Mouse Vibrissal and Visual Cortex through TRPA1.

Ehsan Kheradpezhouh1, Matthew F Tang2, Jason B Mattingley3

  • 1Eccles Institute of Neuroscience, John Curtin School of Medical Research, The Australian National University, Canberra, ACT, Australia; The Australian Research Council Centre of Excellence for Integrative Brain Function, Australia.

Cell Reports
|July 23, 2020
PubMed
Summary

This study explores how the TRPA1 ion channel influences sensory signal processing in the mouse brain. Researchers found that activating this channel boosts neuronal responses to whisker and visual stimuli in specific cortical regions. These results suggest that TRPA1 plays a role in sharpening how the brain encodes sensory information.

Keywords:
TRP ChannelsTRPA1cortexgain modulationsensory processingsomatosensorytuningvibrissaevisualwhiskercortical excitabilityion channelsneuronal gain modulationsomatosensory processing

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Area of Science:

  • Neuroscience research investigating TRPA1 channel modulation of cortical activity
  • Sensory systems biology within mammalian neurophysiology

Background:

No prior work had resolved the specific functional role of the Transient Receptor Potential Ankyrin 1 (TRPA1) channel within the mammalian cerebral cortex. While this non-selective cation channel exists throughout the body, its influence on cortical processing remains largely undefined. Prior research has shown that ion channels often regulate neuronal excitability, yet the contribution of this particular protein is unclear. That uncertainty drove this investigation into how cortical circuits respond to channel modulation. Scientists have previously documented the presence of this protein in brain tissue, but its physiological impact was unknown. This gap motivated a detailed examination of sensory information processing in mouse models. Previous studies focused on peripheral roles, leaving a significant void regarding central nervous system function. This investigation seeks to bridge that void by characterizing cortical responses to targeted channel activation.

Purpose Of The Study:

The aim of this study is to characterize how the TRPA1 channel influences sensory information processing within the mammalian cortex. Researchers sought to determine if this protein contributes to cortical function beyond its known peripheral roles. They specifically investigated the primary vibrissal somatosensory cortex and the primary visual cortex in mice. This investigation was motivated by the lack of knowledge regarding the channel's impact on central nervous system activity. The team examined whether activating this protein alters neuronal responses to sensory stimulation. They also aimed to quantify the effects of channel modulation on signal gain and selectivity. By comparing wild-type and knockout models, the authors intended to establish a clear physiological link between the protein and cortical processing. This work addresses the need to understand how non-selective cation channels shape the dynamics of sensory circuits.

Main Methods:

Review approach involved characterizing cortical responses through targeted pharmacological manipulation in mouse models. The investigators applied allyl isothiocyanate locally to activate the cation channels in specific brain regions. They performed electrophysiological recordings to monitor neuronal activity changes within the primary vibrissal somatosensory cortex. To validate these observations, the team administered the inhibitor HC-030031 to reverse the observed gain modulation. The study design incorporated TRPA1 knockout mice to confirm that the measured effects were strictly dependent on the protein. Researchers also analyzed the primary visual cortex to determine if these modulation patterns extended across different sensory systems. They utilized linear decoding techniques to assess the reliability of population activity during visual stimulation. This systematic approach allowed for a comprehensive evaluation of how channel modulation alters cortical information processing.

Main Results:

The strongest finding indicates that TRPA1 activation significantly increases the ongoing activity of neurons and their evoked responses to vibrissal stimulation. This positive gain modulation is consistently reversed by the application of the specific inhibitor HC-030031. The researchers observed that these effects are entirely absent in mice lacking the channel gene. In the primary visual cortex, activation of the protein increases the gain of direction and orientation selectivity. Linear decoding of population activity confirms that visual signals are encoded faster under these conditions. The data show that these signals are also more reliable when the channel is active. These results provide evidence that the protein enhances sensory information processing in two distinct cortical areas. The findings reveal a consistent physiological role for the channel in boosting cortical sensory signals.

Conclusions:

The authors propose that TRPA1 serves as a physiological regulator for enhancing sensory signal fidelity in the mammalian cortex. Their data suggest that local channel activation increases neuronal excitability within the primary vibrissal somatosensory cortex. The researchers report that this modulation produces a positive gain in evoked responses to whisker stimulation. They conclude that this effect is specific to the channel, as it disappears in knockout models. Synthesis and implications indicate that TRPA1 activation similarly improves direction and orientation selectivity in the primary visual cortex. The study demonstrates that linear decoding of population activity confirms more reliable visual signal encoding. These findings imply that the channel facilitates faster information processing across distinct sensory modalities. The team suggests that these mechanisms represent a broad strategy for cortical gain control.

The researchers propose that TRPA1 activation increases neuronal excitability, leading to a positive gain modulation of sensory responses. In the vibrissal cortex, this manifests as heightened evoked activity, whereas in the visual cortex, it improves the precision of direction and orientation selectivity.

The team utilized allyl isothiocyanate as a chemical agonist to trigger channel activity. To confirm specificity, they employed HC-030031 as a pharmacological inhibitor and compared results against mice lacking the gene for this protein.

The authors state that local activation is necessary to observe these effects in the primary vibrissal somatosensory cortex. This spatial restriction allows for the precise measurement of changes in ongoing neuronal activity and evoked responses to specific sensory inputs.

Linear decoding of population activity serves as the primary data type for evaluating visual signal reliability. This approach allows the researchers to quantify how channel activation alters the speed and accuracy of information representation in the primary visual cortex.

The researchers measured the gain of direction and orientation selectivity in the primary visual cortex. They observed that activating the channel results in faster and more reliable encoding of visual signals compared to baseline conditions.

The authors propose that their findings reveal a physiological role for this channel in boosting sensory signals. They suggest this mechanism provides a means for the mammalian cortex to dynamically adjust its sensitivity to external stimuli.