AAV-PHP.S-mediated delivery of reporters to cranial ganglion sensory neurons

Abstract

ABSTRACTBecause of their ease of use and low risk containment, Adeno-Associated Virus vectors are indispensable tools for much of neuroscience. Yet AAVs have been used relatively little to study the identities and connectivity of peripheral sensory neurons because methods to selectively target particular receptive fields or neuron types have been limited. The introduction of the AAV-PHP.S capsid with selective tropism for peripheral neurons (Chan et al., 2017) offered a solution, which we further elaborate here. We demonstrate using AAV-PHP.S with GFP or mScarlet reporters, that all cranial sensory ganglia, i.e. for cranial nerves V, VII, IX and X, are targeted. Pseudounipolar neurons of both somatic and visceral origin, but not satellite glia, are efficiently transduced rapidly and express the gene of interest within 1 week of injection. Fluorescent reporter proteins are transported into the central and peripheral axons of these sensory neurons, permitting visualization of terminals at high resolution, and/or in intact, cleared brain using light sheet microscopy. By combining a Cre-dependent reporter with the AAV-PHP.S capsid, we confirmed expression in a cell-type dependent manner for both anatomical and targeted functional analyses. The AAV-PHP.S capsid will be a powerful tool for mapping the receptive fields and circuits of molecular subtypes of many somatosensory, gustatory and visceral sensory neurons.SIGNIFICANCE STATEMENTAAV vectors have become an essential tool for visualizing, manipulating, and recoding from neurons of the central nervous system. However, the technology is not widely used for peripheral neurons because of several technical limitations. The AAV-PHP.S synthetic capsid, which targets peripheral neurons, was recently introduced (Chan et al., 2017). Here, we establish key parameters for using this virus, including which cells are transduced, the timing of expression in central and peripheral terminals, distant from neuronal somata, and the effectiveness of Cre-dependent constructs for cell type selective expression. This permits the use of AAV for constructing detailed anatomic and functional maps of the projections of molecular subtypes of peripheral sensory neurons.