Abstract
Treatment of Aspergillus fumigatus with echinocandins such as caspofungin inhibits the synthesis of cell wall β-1,3-glucan, which triggers a compensatory stimulation of chitin synthesis. Activation of chitin synthesis can occur in response to sub-MICs of caspofungin and to CaCl2 and calcofluor white (CFW), agonists of the protein kinase C (PKC), and Ca2+-calcineurin signaling pathways. A. fumigatus mutants with the chs gene (encoding chitin synthase) deleted (ΔAfchs) were tested for their response to these agonists to determine the chitin synthase enzymes that were required for the compensatory upregulation of chitin synthesis. Only the ΔAfchsG mutant was hypersensitive to caspofungin, and all other ΔAfchs mutants tested remained capable of increasing their chitin content in response to treatment with CaCl2 and CFW and caspofungin. The resulting increase in cell wall chitin content correlated with reduced susceptibility to caspofungin in the wild type and all ΔAfchs mutants tested, with the exception of the ΔAfchsG mutant, which remained sensitive to caspofungin. In vitro exposure to the chitin synthase inhibitor, nikkomycin Z, along with caspofungin demonstrated synergistic efficacy that was again AfChsG dependent. Dynamic imaging using microfluidic perfusion chambers demonstrated that treatment with sub-MIC caspofungin resulted initially in hyphal tip lysis. However, thickened hyphae emerged that formed aberrant microcolonies in the continued presence of caspofungin. In addition, intrahyphal hyphae were formed in response to echinocandin treatment. These in vitro data demonstrate that A. fumigatus has the potential to survive echinocandin treatment in vivo by AfChsG-dependent upregulation of chitin synthesis. Chitin-rich cells may, therefore, persist in human tissues and act as the focus for breakthrough infections.
Highlights
Cases of invasive aspergillosis are associated with high mortality rates of around 70% to 90% in immunocompromised patients [1]
The A. fumigatus cell wall is comprised of 20% chitin, which is synthesized by eight Chs enzymes: A. fumigatus ChsA (AfChsA), AfChsB, AfChsC, AfChsD, AfCsmA (AfChsE), AfChsF, AfChsG, and AfCsmB [2, 3, 26,27,28,29], which by sequence homology fall into different classes and have been characterized extensively via the analysis of single and multiple mutants
The effect of caspofungin on the morphology of single germlings of A. fumigatus that had been pretreated with CaCl2 and calcofluor white (CFW) (Fig. 1B) compared to its effect on sham-treated controls was examined in real time using a microfluidics system (Fig. 1A)
Summary
Cases of invasive aspergillosis are associated with high mortality rates of around 70% to 90% in immunocompromised patients [1]. In C. albicans, the protein kinase C (PKC), high-osmolarity glycerol (HOG), and Ca2ϩ-calcineurin signaling pathways all contribute to the regulation of transcriptional activation of chitin synthesis [23] In this organism, there are only four Chs enzymes: Chs and Chs (class I), Chs (class II), and Chs (class IV). Disruption of single chitin synthase genes to create ⌬AfchsA (class I), ⌬AfchsB (class II), and ⌬AfchsC (class III) mutants resulted in mild or no phenotypic growth effects compared to the wild type [26, 29,30,31]. The double class III/class V ⌬AfchsG ⌬AfchsE mutant had a 50% reduction in chitin content compared to wild-type cells and a 95% reduction in chitin synthase enzyme activity [31]. The data demonstrate that hyphae with high chitin could survive caspofungin treatment and that this response was strongly AfCHSG dependent
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