Quantification of Monosynaptic Rabies Tracing Efficiency

Abstract

ABSTRACTRetrograde monosynaptic tracing using glycoprotein-deleted rabies virus is an important component of the toolkit for investigation of neural circuit structure and connectivity. It allows for the identification of first-order presynaptic connections to cell populations of interest across both the central and peripheral nervous system, helping to decipher the complex connectivity patterns of neural networks that give rise to brain function. Despite its utility, the efficiency with which genetically modified rabies virus spreads retrogradely across synapses remains uncertain. While past studies have revealed conditions that can increase or decrease the numbers of presynaptic cells labeled, it is unknown what proportion of total inputs to a starter cell of interest are labeled. It is also unknown whether synapses that are more proximal or distal to the cell body are labeled with different efficiencies. Here we use a new rabies virus construct that allows for the simultaneous labeling of pre and postsynaptic specializations to quantify efficiency of spread at the synaptic level in mouse primary visual cortex. We demonstrate that with typical conditions about 40% of first-order presynaptic excitatory inputs are labeled. We show that using matched tracing conditions there is similar efficiency of spread from excitatory or inhibitory starter cell types. Furthermore, we find no difference in the efficiency of labeling of excitatory inputs to postsynaptic sites at different subcellular locations.