In vivo single-cell gene editing using RNA electroporation reveals sequential adaptation of cortical neurons to excitatory-inhibitory imbalance
The balance between excitatory and inhibitory neurotransmission is fundamental for normal brain function, yet the adaptation of individual neurons to disrupted excitatory-inhibitory balance is not well understood. We developed highly efficient, in vivo RNA electroporation-based single-cell gene editing to investigate neuronal responses to loss of fast inhibition. Using CRISPR-Cas9 components delivered as RNA, we knocked out GABA-A receptor {beta} subunits in individual layer 2/3 cortical neurons in mouse visual cortex, eliminating fast inhibition. In vivo patch-clamp recordings revealed that cortical neurons adapted to inhibition loss through two sequential mechanisms: a transient reduction of excitatory synaptic input, followed by intrinsic membrane property changes that decreased input resistance. This sequential adaptation program ultimately prevented target neurons from contributing spikes to the cortical network. Our RNA-based single-cell gene editing approach enables investigation of cellular responses independent of network effects, providing new insights into neuronal homeostasis and gene function in individual cells in vivo.