Abstract
BackgroundNeuropeptides exert their activity through binding to G protein-coupled receptors (GPCRs). GPCRs are well-known drug targets in the pharmaceutical industry and are currently discussed as targets to control pest insects. Here, we investigate the neuropeptide adipokinetic hormone (AKH) system of the desert locust Schistocerca gregaria. The desert locust is known for its high reproduction, and for forming devastating swarms consisting of billions of individual insects. It is also known that S. gregaria produces three different AKHs as ligands but has only one AKH receptor (AKHR). The AKH system is known to be essential for metabolic regulation, which is necessary for reproduction and flight activity.MethodsNuclear magnetic resonance techniques (NMR) in a dodecylphosphocholin (DPC) micelle solution were used to determine the structure of the three AKHs. The primary sequence of the S. gregaria AKHR was used to construct a 3D molecular model. Next, the three AKHs were individually docked to the receptor, and dynamic simulation of the whole ligand–receptor complex in a model membrane was performed.ResultsAlthough the three endogenous AKHs of S. gregaria have quite different amino acids sequences and chain length (two octa- and one decapeptide), NMR experiments assigned a turn structure in DPC micelle solution for all. The GPCR-ModSim program identified human kappa opioid receptor to be the best template after which the S. gregaria AKHR was modeled. All three AKHs were found to have the same binding site on this receptor, interact with similar residues of the receptor and have comparable binding constants. Molecular switches were also identified; the movement of the receptor could be visually shown when ligands (AKHs) were docked and the receptor was activated.ConclusionsThe study proposes a model of binding of the three endogenous ligands to the one existing AKHR in the desert locust and paves the way to use such a model for the design of peptide analogs and finally, peptide mimetics, in the search for novel species-specific insecticides based on receptor–ligand interaction.
Highlights
In 1976 the primary structure of the first metabolic insect neuropeptide was published (Stone et al, 1976)
We have shown that the putative receptor, Schgr-AKH receptor (AKHR), is a member of the Class A superfamily of G proteincoupled receptors (GPCRs)
Schgr-AKHR has a number of molecular switch motifs, which are a feature of class A GPCRs
Summary
In 1976 the primary structure of the first metabolic insect neuropeptide was published (Stone et al, 1976). The decapeptide was isolated from the retrocerebral glands (corpora cardiaca) of the migratory (Locusta migratoria) and desert (Schistocerca gregaria) locusts This neuropeptide was functionally paramount in mobilizing lipids, especially during flight episodes and, was classified as an adipokinetic hormone (AKH). Genome data mining lead to the discovery of a putative fourth AKH in the migratory locust (Veenstra, 2014) The sequence of this octapeptide was identical to an AKH, Aedae-AKH, previously cloned from the yellow fever mosquito, Aedes aegypti (Kaufmann, Merzendorfer & Gade, 2009). It was found in the corpora cardiaca of the alderfly, Sialis lutaria (Gade, Simek & Marco, 2009) and the desert locust (Marchal et al, 2018). Conclusions: The study proposes a model of binding of the three endogenous ligands to the one existing AKHR in the desert locust and paves the way to use such a
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