Shai-anne Nalder scite author profile

The mitochondrial electron transport chain (ETC) ofPlasmodiummalaria parasites is a major antimalarial drug target, but critical cytochrome functions remain unstudied and enigmatic. Parasites express two distinct cyt c homologs (c and c-2) with unusually sparse sequence identity and uncertain fitness contributions.P. falciparumcyt c-2 is the most divergent eukaryotic cyt c homolog currently known and has sequence features predicted to be incompatible with canonical ETC function. We tagged both cyt c homologs and the related cyt c1 for inducible knockdown. Translational repression of cyt c and cyt c1 was lethal to parasites, which died from ETC dysfunction and impaired ubiquinone recycling. In contrast, cyt c-2 knockdown or knock-out had little impact on blood-stage growth, indicating that parasites rely fully on the more conserved cyt c for ETC function. Biochemical and structural studies revealed that both cyt c and c-2 are hemylated by holocytochrome c synthase, but UV-vis absorbance and EPR spectra strongly suggest that cyt c-2 has an unusually open active site in which heme is stably coordinated by only a single axial amino-acid ligand and can bind exogenous small molecules. These studies provide a direct dissection of cytochrome functions in the ETC of malaria parasites and identify a highly divergentPlasmodiumcytochrome c with molecular adaptations that defy a conserved role in eukaryotic evolution.

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Direct tests of cytochrome c and c ₁ functions in the electron transport chain of malaria parasites

Espino-Sanchez

Wienkers

Marvin

et al. 2023

Proc. Natl. Acad. Sci. U.S.A.

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The mitochondrial electron transport chain (ETC) of Plasmodium malaria parasites is a major antimalarial drug target, but critical cytochrome (cyt) functions remain unstudied and enigmatic. Parasites express two distinct cyt c homologs ( c and c -2) with unusually sparse sequence identity and uncertain fitness contributions. P. falciparum cyt c -2 is the most divergent eukaryotic cyt c homolog currently known and has sequence features predicted to be incompatible with canonical ETC function. We tagged both cyt c homologs and the related cyt c 1 for inducible knockdown. Translational repression of cyt c and cyt c 1 was lethal to parasites, which died from ETC dysfunction and impaired ubiquinone recycling. In contrast, cyt c -2 knockdown or knockout had little impact on blood-stage growth, indicating that parasites rely fully on the more conserved cyt c for ETC function. Biochemical and structural studies revealed that both cyt c and c -2 are hemylated by holocytochrome c synthase, but UV-vis absorbance and EPR spectra strongly suggest that cyt c -2 has an unusually open active site in which heme is stably coordinated by only a single axial amino acid ligand and can bind exogenous small molecules. These studies provide a direct dissection of cytochrome functions in the ETC of malaria parasites and identify a highly divergent Plasmodium cytochrome c with molecular adaptations that defy a conserved role in eukaryotic evolution.

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Doxycycline has distinct apicoplast-specific mechanisms of antimalarial activity

Okada

Guo

Nalder

et al. 2020

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Doxycycline (DOX) is a key antimalarial drug thought to kill Plasmodium parasites by blocking protein translation in the essential apicoplast organelle. Clinical use is primarily limited to prophylaxis due to delayed second-cycle parasite death at 1-3 µM serum concentrations. DOX concentrations >5 µM kill parasites with first-cycle activity but have been ascribed to off-target mechanisms outside the apicoplast. We report that 10 µM DOX blocks apicoplast biogenesis in the first cycle and is rescued by isopentenyl pyrophosphate, an essential apicoplast product, confirming an apicoplast-specific mechanism. Exogenous iron rescues parasites and apicoplast biogenesis from first- but not second-cycle effects of 10 µM DOX, revealing that first-cycle activity involves a metal-dependent mechanism distinct from the delayed-death mechanism. These results critically expand the paradigm for understanding the fundamental antiparasitic mechanisms of DOX and suggest repurposing DOX as a faster-acting antimalarial at higher dosing whose multiple mechanisms would be expected to limit parasite resistance.

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Doxycycline has Distinct Apicoplast-Specific Mechanisms of Antimalarial Activity

Guo

Nalder

Okada

et al. 2020

Preprint

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Doxycycline (DOX) is a key antimalarial drug that is thought to kill Plasmodium falciparum parasites by blocking protein translation in the essential apicoplast organelle. Although parasite resistance to DOX has not emerged, clinical use is primarily limited to prophylaxis due to delayed second-cycle parasite death at 1-3 μM, the DOX concentration readily achieved in human plasma at current dosing. Slow antiparasitic activity is thought to be a fundamental limitation of DOX and other antibiotics that target apicoplast maintenance. We report that slightly higher 8-10 μM DOX concentrations kill parasites with first-cycle activity that blocks apicoplast biogenesis. This faster activity is rescued by exogenous isopentenyl pyrophosphate, an essential apicoplast product, confirming an apicoplast-specific target. Exogenous iron rescues first- but not second-cycle activity by 1 or 10 μM DOX, revealing that first-cycle activity involves a metal-dependent mechanism that is distinct from the canonical delayed-death mechanism. These results provide a new paradigm for understanding fundamental antiparasitic mechanisms of DOX and suggest the possibility of repurposing DOX as a faster-acting antimalarial at higher dosing, which remains well tolerated. Multiple mechanisms of DOX activity would be expected to limit parasite resistance.

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Author response: Doxycycline has distinct apicoplast-specific mechanisms of antimalarial activity

Okada

Guo

Nalder

et al. 2020

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Shai-anne Nalder

Direct Tests of Cytochrome Function in the Electron Transport Chain of Malaria Parasites

Direct tests of cytochrome c and c ₁ functions in the electron transport chain of malaria parasites

Doxycycline has distinct apicoplast-specific mechanisms of antimalarial activity

Doxycycline has Distinct Apicoplast-Specific Mechanisms of Antimalarial Activity

Author response: Doxycycline has distinct apicoplast-specific mechanisms of antimalarial activity

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Shai-anne Nalder

Direct Tests of Cytochrome Function in the Electron Transport Chain of Malaria Parasites

Direct tests of cytochrome c and c 1 functions in the electron transport chain of malaria parasites

Doxycycline has distinct apicoplast-specific mechanisms of antimalarial activity

Doxycycline has Distinct Apicoplast-Specific Mechanisms of Antimalarial Activity

Author response: Doxycycline has distinct apicoplast-specific mechanisms of antimalarial activity

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Direct tests of cytochrome c and c ₁ functions in the electron transport chain of malaria parasites