Abstract
ABSTRACTAspergillus fumigatus is the most prevalent airborne fungal pathogen that causes invasive fungal infections in immunosuppressed individuals. Adaptation to iron limited conditions is crucial for A. fumigatus virulence. To identify novel genes that play roles in adaptation to low iron conditions we performed an insertional mutagenesis screen in A. fumigatus. Using this approach, we identified the tptA gene in A. fumigatus, which shares homology with the Saccharomyces cerevisiae thiamine pyrophosphate (ThPP) transporter encoding gene tpc1. Heterologous expression of tpc1 in the tptA deletion mutant completely restored the ThPP auxotrophy phenotype, suggesting that Tpc1 and TptA are functional orthologues. Importantly, TptA was required for adaptation to low iron conditions in A. fumigatus. The ΔtptA mutant had decreased resistance to the iron chelator bathophenanthroline disulfonate (BPS) with severe growth defects. Moreover, loss of tptA decreased the expression of hapX, which is a major transcription factor indispensable for adaptation to iron starvation in A. fumigatus. Overexpression of hapX in the ΔtptA strain greatly rescued the growth defect and siderophore production by A. fumigatus in iron-depleted conditions. Mutagenesis experiments demonstrated that the conserved residues related to ThPP uptake in TptA were also required for low iron adaptation. Furthermore, TptA-mediated adaptation to low iron conditions was found to be dependent on carbon sources. Finally, loss of tptA resulted in the attenuation of virulence in a murine model of aspergillosis. Taken together, this study demonstrated that the mitochondrial ThPP transporter TptA promotes low iron adaptation and virulence in A. fumigatus.
Highlights
The unique chemical properties of iron underlie its broad utility as a cofactor for essential cellular processes
To identify novel genes involved in adaptation to low iron conditions, a T-DNA insertional mutagenesis library containing 5,000 A. fumigatus transformants was constructed
Transformants were screened for their ability to grow and/or conidiate on minimal media (MM) in the presence of the iron chelator bathophenanthroline disulfonate (BPS)
Summary
The unique chemical properties of iron underlie its broad utility as a cofactor for essential cellular processes. Iron is highly abundant in the earth’s crust, the bioavailability of iron is very low due to its oxidation into sparingly soluble ferric (Fe3+) hydroxides by atmospheric oxygen (below 10−9 M at neutral pH) [1,2]. Control over access to iron is one of the central battlefields during infection, as pathogens typically face low iron levels in the host (~10−24 M free Fe3+ in bloodstream) [3,4,5,6]. Excess iron has the potential to catalyze the formation of cell-damaging reactive oxygen species [7]. Virtually all organisms, especially pathogens have evolved precise mechanisms to adapt to both low and high iron conditions.
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