Novel High-throughput Screens of Odorant Receptors Reveal Candidate Behaviour-modifying Chemicals for Mosquitoes

Overview

Journal Physiol Entomol

Specialty Biology

Date 2020 Apr 8

PMID 32255891

Citations 14

Authors

David C Rinker

Patrick L Jones

R Jason Pitts

Michael Rutzler

Gray Camp

Lujuan Sun

Pingxi Xu

David Weaver

Laurence J Zwiebel

Affiliations

Soon will be listed here.

Abstract

Despite many decades of multilateral global efforts, a significant portion of the world population continues to be plagued with one or more mosquito-vectored diseases. These include malaria and filariasis as well as numerous arboviral-associated illnesses including Dengue and Yellow fevers. The dynamics of disease transmission by mosquitoes is complex, and involves both vector competence and vectorial capacity. One area of intensive effort is the study of chemosensory-driven behaviours in the malaria vector mosquito Giles, the modulation of which are likely to provide opportunities for disease reduction. In this context recent studies have characterized a large divergent family of odorant receptors (AgORs) that play critical roles in olfactory signal transduction. This work has facilitated high-throughput, cell-based calcium mobilization screens of AgOR-expressing HEK cells that have identified a large number of conventional AgOR ligands, as well as the first non-conventional Orco (olfactory receptor co-receptor) family agonist. As such, ligand-mediated modulation serves as a proof-of-concept demonstration that AgORs represent viable targets for high-throughput screening and for the eventual development of behaviour-modifying olfactory compounds. Such attractants or repellents could foster malaria reduction programmes.

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