Repositioning of moxidectin: a promising approach in cutaneous leishmaniasis therapy

Repositioning of moxidectin: a promising approach in cutaneous leishmaniasis therapy

Cutaneous leishmaniasis presents a significant challenge to public health due to its diverse clinical manifestations, resistance development, and treatment-related adverse effects. Here, we examined the efficacy of ivermectin, moxidectin (MOX), afoxolaner, and permethrin against all stages of Leishm...

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Main Authors: Al Samra Lynn, El Nahas Mohamad, Mneimneh Ilham, Tokajian Sima, Nemer Georges, Sinno Aia, Rahy Kelven, Thoumi Sergio, Zibara Zahraa, El Khatib Ahmad, Sabbagh Dalal, Guillot Jacques, Karam Louna, Ali Lazo, Baghdadi Ruqaya, Al Khoury Charbel
Format: Article
Language:English
Published: EDP Sciences 2025-01-01
Series:Parasite
Subjects:
leishmania
leishmaniasis
moxidectin
drug repurposing
rna-seq
drug resistance
Online Access:https://www.parasite-journal.org/articles/parasite/full_html/2025/01/parasite240197/parasite240197.html
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Summary:Cutaneous leishmaniasis presents a significant challenge to public health due to its diverse clinical manifestations, resistance development, and treatment-related adverse effects. Here, we examined the efficacy of ivermectin, moxidectin (MOX), afoxolaner, and permethrin against all stages of Leishmania tropica and THP-1 cells. We also assessed the potential for resistance acquisition after 15 rounds of artificial selection. To elucidate the mode of action of MOX, we employed RNA sequencing, molecular dynamics simulation, and chloride flux assays. Additionally, we evaluated the therapeutic index of MOX using the Galleria mellonella infection model. MOX demonstrated the highest selectivity index against leishmaniasis (promastigotes: 0.58 μM; amastigotes: 0.96 μM; host cells: 60.29 μM). Moreover, MOX exhibited the lowest resistance acquisition in both promastigotes and intracellular amastigotes after 15 rounds of artificial selection, with resistance ratios of 17.23 and 4.59, respectively. Post-exposure to MOX, differential gene expression profiles showed both stage-specific and stage-unspecific enrichment of gene families involved in crucial biological processes. Moreover, molecular dynamics simulations revealed a potential neutralizing effect of MOX on the chloride channel of L. tropica. Specifically, MOX binds to the selectivity filter, potentially disrupting the osmotic equilibrium and thereby killing the parasite. The in vivo introduction of MOX significantly inhibited the growth of L. tropica in G. mellonella larvae, resulting in decreased rates of mortality and melanization. These findings indicate that MOX is a promising candidate for the treatment of L. tropica infections, warranting further investigation and potential consideration for clinical use.
ISSN:1776-1042

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