Abstract
Copper (Cu) is essential for all life forms; however, in excess, it becomes toxic. Toxic properties of Cu are known to be utilized by host species against various pathogenic invasions. Leishmania, in both free-living and intracellular forms, exhibits appreciable tolerance toward Cu stress. While determining the mechanism of Cu-stress evasion employed by Leishmania, we identified and characterized a hitherto unknown Cu-ATPase in Leishmania major and established its role in parasite survival in host macrophages. This novel L. major Cu-ATPase, LmATP7, exhibits homology with its orthologs at multiple motifs. In promastigotes, LmATP7 primarily localized at the plasma membrane. We also show that LmATP7 exhibits Cu-dependent expression patterns and complements Cu transport in a Cu-ATPase-deficient yeast strain. Promastigotes overexpressing LmATP7 exhibited higher survival upon Cu stress, indicating efficacious Cu export compared with Wt and heterozygous LmATP7 knockout parasites. We further explored macrophage–Leishmania interactions with respect to Cu stress. We found that Leishmania infection triggers upregulation of major mammalian Cu exporter, ATP7A, in macrophages, and trafficking of ATP7A from the trans-Golgi network to endolysosomes in macrophages harboring amastigotes. Simultaneously, in Leishmania, we observed a multifold increase in LmATP7 transcripts as the promastigote becomes established in macrophages and morphs to the amastigote form. Finally, overexpressing LmATP7 in parasites increases amastigote survivability within macrophages, whereas knocking it down reduces survivability drastically. Mice injected in their footpads with an LmATP7-overexpressing strain showed significantly larger lesions and higher amastigote loads as compared with controls and knockouts. These data establish the role of LmATP7 in parasite infectivity and intramacrophagic survivability.
Highlights
Leishmania is a digenetic protozoan belonging to the trypanosomatid group that alternates between sandfly vector and mammalian hosts
To explore if lethality could be induced in Leishmania parasites, we tested survivability of the parasite in growth media supplemented with copper (Cu) in a range between 0-500μM at 24, 48 and 72 hrs post-incubation
Using the well-established macrophageLeishmania infection model system, we found that there is a reciprocal interaction between the copper ATPases of the host and the parasite that determines the fate of parasite survivability and well-being of the antagonistic pair
Summary
Leishmania is a digenetic protozoan belonging to the trypanosomatid group that alternates between sandfly vector and mammalian hosts. They continue to proliferate until the cell bursts, leading to the spread of the infection [5] Inside this compartment, Leishmania has to withstand a variety of host-induced stress factors including free radicals, lysosomal hydrolases and low pH [6,7]. Copper channelization to the phagosomal compartment of macrophage during Mycobacterium avium and E.coli infection indicated how hosts tend to utilize copper to fight off intracellular pathogens [22,23]. In the present study, using cell-based and mouse models, we have functionally characterized the copper transporting ATPase (LmATP7) of L. major and determined its role in leishmanial survivability in host macrophage. We establish that intracellular amastigotes combat host-induced copper stress in lysosomes using LmATP7 that plays a key role in determining its pathogenicity, establishment in the host and successful manifestation of infection
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