Intersectional CRISPR-Cas9 genetic targeting reveals acute role of Na _V 1.1 in proprioceptive behavior and function

Proprioceptors, a specialized subset of mechanosensory neurons that relay sensory feedback from muscles and tendons, are required for precise, goal-directed movement. Like all neurons, proprioceptors rely on voltage-gated ion channels to generate and transmit electrical signals. Investigating ion channel function in proprioceptors in vivo is technically challenging because current approaches to selectively target proprioceptors require the generation of triple transgenic models and creation of both loxP- and Frt-flanked alleles. To facilitate selective targeting of genes within proprioceptors, we employed an intersectional cell-specific gene editing approach that leverages CRISPR/Cas9 and sensory-neuron selective viral capsids. This approach combines single-guide RNA (sgRNA) delivery in sensory neuron-selective adeno-associated viral (AAV) capsids in mice with parvalbumin-driven Cas9 expression. We tested this approach by targeting the voltage-gated sodium (Na _V ) channel Na _V 1.1. Targeting Na _V 1.1 using this approach led to significant motor coordination deficits as early as 3 weeks following sgRNA delivery. Furthermore, whole-cell current clamp recordings from transduced proprioceptors revealed Na _V 1.1 is required for maintaining short-duration action potentials, which would support high-frequency firing typically observed in proprioceptors. Collectively, this study establishes a versatile platform for precise spatiotemporal gene manipulation in otherwise hard-to-access sensory neuron populations, while also providing evidence that Na _V 1.1 is essential for proprioceptor function in adulthood.