Small-diameter vesicular glutamate transporter 3-lineage (Vglut3 lineage) dorsal root ganglion (DRG) neurons play an important role in mechanosensation and thermal hypersensitivity; however, little is known about their intrinsic electrical properties. We therefore set out to investigate mechanisms of excitability within this population. Calcium microfluorimetry analysis of male and female mouse DRG neurons demonstrated that the cooling compound menthol selectively activates a subset of Vglut3 lineage neurons. Whole-cell recordings showed that small-diameter Vglut3 lineage DRG neurons fire menthol-evoked action potentials and exhibited robust, transient receptor potential melastatin 8 (TRPM8)-dependent discharges at room temperature. This heightened excitability was confirmed by currentclamp and action potential phase-plot analyses, which showed menthol-sensitive Vglut3 lineage neurons to have more depolarized membrane potentials, lower firing thresholds, and higher evoked firing frequencies compared with menthol-insensitive Vglut3 lineage neurons. A biophysical analysis revealed voltage-gated sodium channel (Na V) currents in menthol-sensitive Vglut3 lineage neurons were resistant to entry into slow inactivation compared with menthol-insensitive neurons. Multiplex in situ hybridization showed similar distributions of tetrodotoxin (TTX)-sensitive Na V transcripts between TRPM8-positive and-negative Vglut3 lineage neurons; however, Na V 1.8 transcripts, which encode TTX-resistant channels, were more prevalent in TRPM8-negative neurons. Conversely, pharmacological analyses identified distinct functional contributions of Na V subunits, with Na V 1.1 driving firing in menthol-sensitive neurons, whereas other small-diameter Vglut3 lineage neurons rely primarily on TTX-resistant Na V channels. Additionally, when Na V 1.1 channels were blocked, the remaining Na V current readily entered into slow inactivation in menthol-sensitive Vglut3 lineage neurons. Thus, these data demonstrate that TTX-sensitive Na V s drive action potential firing in menthol-sensitive sensory neurons and contribute to their heightened excitability.
Small-diameter vesicular glutamate transporter 3-lineage (Vglut3 lineage ) dorsal root ganglion (DRG) neurons play an important role in mechanosensation and thermal hypersensitivity; however, little is known about their intrinsic electrical properties. We therefore set out to investigate mechanisms of excitability within this population. Calcium microfluorimetry analysis of male and female mouse DRG neurons demonstrated that the cooling compound menthol selectively activates a subset of Vglut3 lineage neurons. Whole-cell recordings showed that smalldiameter Vglut3 lineage DRG neurons fire menthol-evoked action potentials and exhibited robust, transient receptor potential melastatin 8 (TRPM8)-dependent discharges at room temperature.This heightened excitability was confirmed by current-clamp and action potential phase-plot analyses, which showed menthol-sensitive Vglut3 lineage neurons to have more depolarized membrane potentials, lower firing thresholds, and higher evoked firing frequencies compared with menthol-insensitive Vglut3 lineage neurons. A biophysical analysis revealed voltage-gated sodium channel (Na V ) currents in menthol-sensitive Vglut3 lineage neurons were resistant to entry into slow inactivation compared with menthol-insensitive neurons. Multiplex in situ hybridization showed similar distributions of tetrodotoxin (TTX)-sensitive Na V s transcripts between TRPM8positive and -negative Vglut3 lineage neurons; however, Na V 1.8 transcripts, which encode TTXresistant channels, were more prevalent in TRPM8-negative neurons. Conversely, pharmacological analyses identified distinct functional contributions of Na V subunits, with Na V 1.1 driving firing in menthol-sensitive neurons, whereas other small-diameter Vglut3 lineage neurons rely primarily on TTX-resistant Na V channels. Additionally, when Na V 1.1 channels were blocked, the remaining Na V currents readily entered into slow inactivation in menthol-sensitive Vglut3 lineage neurons. Thus, these data demonstrate that TTX-sensitive Na V s drive action potential firing in menthol-sensitive sensory neurons and contribute to their heightened excitability. Significance StatementSomatosensensory neurons encode various sensory modalities including thermoreception, mechanoreception, nociception and itch. This report identifies a previously unknown requirement for tetrodotoxin-sensitive sodium channels in action potential firing in a discrete subpopulation of small-diameter sensory neurons that are activated by the cooling agent menthol. Together, our results provide a mechanistic understanding of factors that control intrinsic excitability in functionally distinct subsets of peripheral neurons. Furthermore, as menthol has been used for centuries as an analgesic and anti-pruritic, these findings support the viability of Na V 1.1 as a therapeutic target for sensory disorders.
TRAAK is a mechanosensitive two-pore domain K+ (K2P) channel found in nodes of Ranvier within myelinated axons. It displays low leak activity at rest and is activated up to one hundred-fold by increased membrane tension. Structural and functional studies have led to physical models for channel gating and mechanosensitivity, but no quantitative analysis of channel activation by tension has been reported. Here, we use simultaneous patch-clamp recording and fluorescent imaging to determine the tension response characteristics of TRAAK. TRAAK shows high sensitivity and a broad response to tension spanning nearly the entire physiologically relevant tension range. This graded response profile distinguishes TRAAK from similarly low-threshold mechanosensitive channels Piezo1 and MscS, which activate in a step-like fashion over a narrow tension range. We further use patch imaging to show that ultrasonic activation of TRAAK and MscS is due to increased membrane tension. Together, these results provide mechanistic insight into TRAAK tension gating, a framework for exploring the role of mechanosensitive K+ channels at nodes of Ranvier, and biophysical context for developing ultrasound as a mechanical stimulation technique for neuromodulation.
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