Abstract
The fungal pathogen Candida glabrata has risen from an innocuous commensal to a major human pathogen that causes life-threatening infections with an associated mortality rate of up to 50%. The dramatic rise in the number of immunocompromised individuals from HIV infection, tuberculosis, and as a result of immunosuppressive regimens in cancer treatment and transplant interventions have created a new and hitherto unchartered niche for the proliferation of C. glabrata. Iron acquisition is a known microbial virulence determinant and human diseases of iron overload have been found to correlate with increased bacterial burden. Given that more than 2 billion people worldwide suffer from iron deficiency and that iron overload is one of the most common single-gene inherited diseases, it is important to understand whether host iron status may influence C. glabrata infectious disease progression. Here we identify Sit1 as the sole siderophore-iron transporter in C. glabrata and demonstrate that siderophore-mediated iron acquisition is critical for enhancing C. glabrata survival to the microbicidal activities of macrophages. Within the Sit1 transporter, we identify a conserved extracellular SIderophore Transporter Domain (SITD) that is critical for siderophore-mediated ability of C. glabrata to resist macrophage killing. Using macrophage models of human iron overload disease, we demonstrate that C. glabrata senses altered iron levels within the phagosomal compartment. Moreover, Sit1 functions as a determinant for C. glabrata to survive macrophage killing in a manner that is dependent on macrophage iron status. These studies suggest that host iron status is a modifier of infectious disease that modulates the dependence on distinct mechanisms of microbial Fe acquisition.
Highlights
Candida glabrata has emerged as an opportunistic fungal pathogen that causes life-threatening infectious disease in humans [1]
Through the generation of macrophage models of human iron overload disease we demonstrate that ingested C. glabrata cells sense altered macrophage iron levels, and that the Sit1 siderophore-iron transporter functions as a critical determinant in the ability of C. glabrata to survive macrophage killing in a manner that is dependent on macrophage iron status
Our results reveal a role for siderophore-iron as a source of iron during C. glabrata infection, suggest additional therapeutic intervention strategies, and support a pivotal contribution for a common human iron overload disease in the mechanisms used for Fe acquisition in C. glabrata
Summary
Candida glabrata has emerged as an opportunistic fungal pathogen that causes life-threatening infectious disease in humans [1]. While Candida species account for over 10% of all bloodstream infections [2], the poor susceptibility of C. glabrata to antifungal therapeutics is in great part responsible for the high mortality rate of up to 50% associated with C. glabrata candidemia [3,4]. The limited knowledge of virulence factors that contribute to the pathogenesis of C. glabrata demands insights into the biology of this opportunistic pathogen that contribute towards the successful colonization of the mammalian host. Fe2+ has the potential to generate damaging reactive oxygen species (ROS) via Fenton/Haber Weiss chemistry [5] and, as a consequence, organisms have evolved sophisticated homeostatic mechanisms to tightly regulate the acquisition, utilization, storage and mobilization of Fe [6,7]
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