A single amino acid substitution (H451Y) in Leishmania calcium-dependent kinase SCAMK confers high tolerance and resistance to antimony.

BACKGROUND: For almost a century, antimonials have remained the first-line drugs for the treatment of leishmaniasis. However, little is known about their mode of action and clinical resistance mechanisms. OBJECTIVES: We have previously shown that Leishmania nicotinamidase (PNC1) is an essential enzyme for parasite NAD+ homeostasis and virulence in vivo. Here, we found that parasites lacking the pnc1 gene (Δpnc1) are hypersusceptible to the active form of antimony (SbIII) and used these mutant parasites to better understand antimony's mode of action and the mechanisms leading to resistance. METHODS: SbIII-resistant WT and Δpnc1 parasites were selected in vitro by a stepwise selection method. NAD(H)/NADP(H) dosages and quantitative RT-PCR experiments were performed to explain the susceptibility differences observed between strains. WGS and a marker-free CRISPR/Cas9 base-editing approach were used to identify and validate the role of a new resistance mutation. RESULTS: NAD+-depleted Δpnc1 parasites were highly susceptible to SbIII and this phenotype could be rescued by NAD+ precursor or trypanothione precursor supplementation. Δpnc1 parasites could become resistant to SbIII by an unknown mechanism. WGS revealed a unique amino acid substitution (H451Y) in an EF-hand domain of an orphan calcium-dependent kinase, recently named SCAMK. When introduced into a WT reference strain by base editing, the H451Y mutation allowed Leishmania parasites to survive at extreme concentrations of SbIII, potentiating the rapid emergence of resistant parasites. CONCLUSIONS: These results establish that Leishmania SCAMK is a new central hub of antimony's mode of action and resistance development, and uncover the importance of drug tolerance mutations in the evolution of parasite drug resistance.

In vitro activity of nicotinamide/antileishmanial drug combinations.

To improve the management of leishmaniasis, new drugs and/or alternative therapeutic strategies are required. Combination therapy of antileishmanial drugs is currently considered as one of the most rational approaches to lower treatment failure rate and limit drug resistance spreading. Nicotinamide (NAm), also known as vitamin B3 that is already is used in human therapy, exerts in vitro antileishmanial activity. Drug combination studies, performed on L. infantum axenic amastigotes, revealed that NAm significantly improves the antileishmanial activity of trivalent antimony in a synergistic manner while it shows additive activity with amphotericin B and slightly antagonizes pentamidine activity. NAm also significantly increases the toxicity of pentavalent antimony against the intracellular forms of L. infantum, L. amazonensis and L. braziliensis. The potential of NAm to be used as adjuvant during leishmaniasis chemotherapy is further discussed.