Malaria remains one of the greatest public health challenges worldwide, particularly in sub-Saharan Africa. The clinical outcome of individuals infected with Plasmodium falciparum parasites depends on many factors including host systemic inflammatory responses, parasite sequestration in tissues and vascular dysfunction. Production of pro-inflammatory cytokines and chemokines promotes endothelial activation as well as recruitment and infiltration of inflammatory cells, which in turn triggers further endothelial cell activation and parasite sequestration. Inflammatory responses are triggered in part by bioactive parasite products such as hemozoin and infected red blood cell-derived extracellular vesicles (iRBC-derived EVs). Here we demonstrate that such EVs contain functional miRNA-Argonaute 2 complexes that are derived from the host RBC. Moreover, we show that EVs are efficiently internalized by endothelial cells, where the miRNA-Argonaute 2 complexes modulate target gene expression and barrier properties. Altogether, these findings provide a mechanistic link between EVs and vascular dysfunction during malaria infection.
How the pore-forming protein perforin delivers apoptosis-inducing granzymes to the cytosol of target cells is uncertain. Perforin induces a transient Ca2+ flux in the target, which triggers a damaged cell membrane repair process. As a consequence, both perforin and granzymes are endocytosed into enlarged endosomes, called gigantosomes. Here we show that perforin forms pores in the gigantosome membrane, allowing endosomal cargo, including granzymes, to be gradually released. After about 15 minutes, gigantosomes rupture, releasing their remaining content. Thus, perforin delivers granzymes by a two-step process that first involves transient pores in the cell membrane that trigger granzyme and perforin endocytosis and then pore formation in endosomes to trigger cytosolic release.
Summary
When killer lymphocytes recognize infected cells, perforin delivers cytotoxic proteases (granzymes) into the target cell to trigger apoptosis. What happens to intracellular bacteria during this process is unclear. Human, but not rodent, cytotoxic granules also contain granulysin, an antimicrobial peptide. Here we show that granulysin delivers granzymes into bacteria to kill diverse bacterial strains. In E. coli, granzymes cleave electron transport chain complex I and oxidative stress defense proteins, generating ROS that rapidly kill bacteria. ROS scavengers and bacterial antioxidant protein overexpression inhibit bacterial death. Bacteria overexpressing a GzmB-uncleavable mutant of the complex I subunit nuoF or strains that lack complex I still die, but more slowly, suggesting that granzymes disrupt multiple vital bacterial pathways. Mice expressing transgenic granulysin are better able to clear L. monocytogenes. Thus killer cells play an unexpected role in bacterial defense.
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