A novel receptor target for old anthelmintic drugs evaluated in the nematode Caenorhabditis elegans

RODRIGUEZ ARAUJO, N.; HERNANDO, G.S.; CORRADI, J.; BOUZAT, C.

Congreso Virtual

Congreso; XLIX Reunión Anual de la Sociedad Argentina de Biofísica; 2021

Ivermectin (IVM) and piperazine (PZE), which are agonists of Glutamate-gated chloride channels and GABAA receptors, respectively, are marketed drugs used in anthelmintic therapy. Here we discovered a novel target of these drugs by evaluating their effects on the free-living nematode C. elegans. Nematodes contain a homomeric 5HT-gated chloride channel, MOD-1, that modulates locomotor behavior. Due to its absence in vertebrates, MOD-1 emerges as an attractive anthelmintic drug target. By electrophysiological recordings from cells expressing MOD-1, we deciphered its pharmacological properties and searched for novel ligands. Macroscopic currents activated by 5-HT showed that MOD-1 desensitizes slowly and recovers from desensitization in about 1 s. Dose-response curves revealed an EC50 for 5-HT of approximately 1 µM, similar to that of 5-HT3A receptors. The partial agonists tryptamine and 2-Me-5HT showed very different efficacies between MOD-1 and 5-HT3A receptors. IVM and PZE did not activate MOD-1 but acted as noncompetitive antagonists. IVM produced a slight and irreversible inhibition whereas PZE led to a profound and reversible inhibition, indicating that MOD-1 may be involved in their anthelmintic effects. Also, the specific GABAA receptor agonists, muscimol and isoguvacine, inhibited MOD-1 currents. We performed locomotor activity assays of wild- type (WT) and mutant strains to establish MOD-1 as a novel anthelmintic target. We found that 5-HT produced a rapid paralysis of WT worms while the MOD-1 mutant strain was resistant, thus confirming MOD-1 as the functional target of 5-HT. The exposure of worms to 5-HT combined with IVM or PZE at concentrations at which they do not act at their canonical receptors reduced the 5-HT paralyzing effect, thus supporting the negative modulation of MOD-1 detected in electrophysiological recordings. This study contributes to our understanding of the action of drugs to treat parasitic diseases and to guide future drug discovery efforts.