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A Chemogenetic Tool that Enables Functional Neural Circuit Analysis

Hoai Buu Ngo, Mariana Melo, Sharon Layfield, Angela A. Connelly, Jaspreet K. Bassi, Lin Xie, Clément Menuet, Stuart J. McDougall, Ross A. D. Bathgate, Andrew M. Allen

2020Cell Reports20 citationsDOIOpen Access PDF

Abstract

Chemogenetics enables manipulation of neuronal activity in experimental animals. While providing information about the transduced neuron expressing a ligand-activated molecule, chemogenetics does not provide understanding about the antecedent circuit that drives that neuron's activity. For current approaches, this is not feasible, because the activating molecules are not genetically encoded. The insect allatostatin/allatostatin receptor system, a highly specific, powerful inhibitory chemogenetic approach, has this advantage, because the ligand, being a peptide, is genetically encoded. We developed viral vector-based systems to express biologically active allatostatin in neurons in vivo and allatostatin receptors in subpopulations of postsynaptic neurons. We demonstrate that activity-dependent release of allatostatin induces inhibition of allatostatin receptor-expressing neurons. We validate the approach in the vagal viscerosensory system where inhibitory, rather than the usual excitatory, viscerosensory input leads to sustained decreases in baroreceptor reflex sensitivity and bodyweight.

Topics & Concepts

Inhibitory postsynaptic potentialExcitatory postsynaptic potentialNeuroscienceNeuronReceptorBiologyPostsynaptic potentialPremovement neuronal activityBiochemistryNeurobiology and Insect Physiology ResearchInsect and Pesticide ResearchMosquito-borne diseases and control
A Chemogenetic Tool that Enables Functional Neural Circuit Analysis | Litcius