Abstract
INTRODUCTION: Drug repurposing is a promising strategy for identifying new treatments against neglected tropical diseases such as leishmaniases, which are endemic in Asia, Africa, the Americas, and Southern Europe, offering the advantages of reduced development time and cost. In this context, computational and biochemical investigation of therapeutic targets plays a key role in guiding the selection of effective drug candidates. METHODS: In this study, we investigated Leishmania infantum 5'-methylthioadenosine phosphorylase (LiMTAP) as a potential drug target by evaluating criteria defining such targets, including assayability, biochemical properties, and structural features enabling inhibitor selection. Trimeric 3D models of LiMTAP were generated, followed by virtual screening and docking of FDA-approved drugs. A robust miniaturized robotic assay was developed for recombinant LiMTAP to enable biochemical validation. Seven predicted drug candidates were subsequently tested in enzymatic and biological assays. RESULTS: Two compounds-Labetalol and Halofuginone-inhibited LiMTAP activity with IC₅₀ values ranging from 200-400 µg/mL. The antileishmanial activity of all seven compounds was evaluated on extracellular promastigotes; four compounds (Dobutamine, Halofuginone, Labetalol, and Pentamidine) showed activity. Pentamidine and Dobutamine did not inhibit LiMTAP despite their anti-promastigote effects. Labetalol exhibited an IC(50) of 29.67 µg/mL against extracellular promastigotes and showed no significant toxicity on THP-1 macrophages at effective doses (CC(50) = 98.29 µg/mL). When tested on intracellular amastigotes, Labetalol demonstrated an IC(50) value of 19.10 µg/mL. DISCUSSION: This study confirms the in silico predictions through in vitro validation and highlights repurposed drugs as promising anti-Leishmania candidates.