Malaria-causing parasites from the Plasmodium genus possess a mitochondrion that is essential across all life-cycle stages and highly divergent from its hosts, making it a suitable drug target. Transport of metabolites across the inner membrane of this metabolically active organelle is mediated by mitochondrial carrier (MC) proteins. Among these, the apicomplexan-specific MC1 (AMC1) stands out due to its likely essential function and limited conservation even within the Apicomplexa phylum. Bioinformatics and structural predictions reveal that P. falciparum AMC1 (PfAMC1) lacks canonical gating residues and shows a distorted membrane barrel, suggesting it may not function as a transporter. Using two independent mutant parasite lines, we demonstrate that PfAMC1 localises to the periphery of mitochondria, which exhibit increased dispersion and rounding during male gametogenesis, when the C-terminus is modified. Additionally, we identify the mammalian MTCH2, the function of which is still debated, as a potential structural homologue of PfAMC1, opening new avenues for research. Our findings emphasize the unique role of PfAMC1 in mitochondrial dynamics and lay the groundwork for further exploration of its molecular mechanism.
Toward terminological clarity in digital biomarker research
Digital biomarker research has generated thousands of publications demonstrating associations between sensor-derived measures and clinical conditions, yet clinical adoption remains negligible. We identify a foundational