Comparative pharmacological characterization of D1-like dopamine receptors from Anopheles gambiae, Aedes aegypti and Culex quinquefasciatus suggests pleiotropic signaling in mosquito vector lineages.

Catherine A Hill,Val J Watts,Karin F K Ejendal,Jason M Meyer,Andrew B Nuss,Trevor Doyle

doi:10.1186/s13071-016-1477-6

Abstract

BackgroundSmall molecule antagonists of mosquito dopamine receptors (DARs) are under investigation as a new class of vector-selective insecticides. Antagonists that inhibit the D1-like DARs AaDOP2 and CqDOP2 from the mosquitoes Aedes aegypti L. and Culex quinquefasciatus Say, respectively, also cause larval mortality in bioassays. Here, we report on the orthologous DAR, AgDOP2, from the malaria mosquito Anopheles gambiae Giles that was cloned and pharmacologically characterized in HEK293 cells. Larval bioassays were then conducted to examine the potential of DAR antagonist insecticides against Anopheles vectors.FindingsPrevious in vitro cAMP accumulation assays demonstrated Gαs coupling for AaDOP2 and CqDOP2 and dose-dependent inhibition by DAR antagonists. We observed a negligible response of AgDOP2 in the cAMP assay, which prompted an investigation of alternative coupling for mosquito DARs. In an in vitro IP-One Gαq second messenger assay of calcium signaling, dopamine stimulation increased IP1 accumulation in AaDOP2-, CqDOP2- and AgDOP2-expressing cells, and DAR antagonists inhibited IP1 signaling in a dose-dependent manner. In larval bioassays, DAR antagonists caused considerable mortality of An. gambiae larvae within 24 h post-exposure.ConclusionsIn vitro data reveal pleiotropic coupling of AaDOP2 and CqDOP2 to Gαq and Gαs. In contrast, AgDOP2 appeared to selectively couple to Gαq signaling. In vitro antagonist studies revealed general conservation in pharmacology between mosquito DARs. In vivo data suggest potential for DAR antagonist insecticides against An. gambiae. Sequence conservation among the DOP2 receptors from 15 Anopheles species indicates utility of antagonists to control residual malaria transmission. AgDOP2 Gαq-dependent signaling could be exploited for An. gambiae control via pathway specific antagonists.Electronic supplementary materialThe online version of this article (doi:10.1186/s13071-016-1477-6) contains supplementary material, which is available to authorized users.

Highlights

Small molecule antagonists of mosquito dopamine receptors (DARs) are under investigation as a new class of vector-selective insecticides
In vivo data suggest potential for DAR antagonist insecticides against An. gambiae
Anopheles gambiae dopamine receptor 2 (AgDOP2) G protein subunit that stimulates phospholipase C (Gαq)-dependent signaling could be exploited for An. gambiae control via pathway specific antagonists

Summary

Conclusions

We present evidence of pleiotropic coupling via Gαs and Gαq among the mosquito DARs, AaDOP2 and CqDOP2. Asenapine was the most potent and selective AgDOP2 antagonist in vitro and caused mortality of An. gambiae larvae This and other antagonists offer “probes” for further pharmacological investigations. Abbreviations AaDOP2: Aedes aegypti dopamine receptor 2; AgDOP2: Anopheles gambiae dopamine receptor 2; cAMP: cyclic adenosine monophosphate; CqDOP2: Culex quinquefasciatus dopamine receptor 2; DAR: dopamine receptor; EC: effective concentration; EL: extracellular loop; Gαs: G protein subunit that stimulates adenylyl cyclase; Gαq: G protein subunit that stimulates phospholipase C; GPCR: G protein-coupled receptor; HEK: human embryonic kidney cells; hD1: human D1-like dopamine receptor; HTRF: homogenous time resolved fluorescence; IC50: inhibitory concentration; IL: intracellular loop; IP1: inositol monophosphate; IRS: indoor residual spray; LC50: lethal concentration; LLIN: long lasting insecticide treated net; MoA: mode of action; PLC: phospholipase C; TM: transmembrane domain.

Background

Findings