AI Article Synopsis
- Calcium is crucial for cell signaling in eukaryotes, but must be kept low in resting cells to prevent toxicity; in fungi, excess calcium is stored in vacuoles through pumps like Vcx1p and Pmc1p.
- The study investigated the roles of these calcium pumps in a human fungal pathogen's ability to grow, form biofilms, and cause disease, finding that Pmc1p is essential for these processes.
- Pmc1p also impacts the pathogen's resistance to antifungals, indicating that maintaining calcium balance is vital for fungal survival and virulence, and could lead to new treatment strategies.
Article Abstract
Calcium is a critically important secondary messenger of intracellular signal transduction in eukaryotes but must be maintained at low levels in the cytoplasm of resting cells to avoid toxicity. This is achieved by several pumps that actively transport excess cytoplasmic Ca out of the cell across the plasma membrane and into other intracellular compartments. In fungi, the vacuole serves as the major storage site for excess Ca, with two systems actively transporting cytoplasmic calcium ions into the vacuole. The H/Ca exchanger, Vcx1p, harnesses the proton-motive force across the vacuolar membrane (generated by the V-ATPase) to drive Ca transport, while the P-type ATPase Pmc1p uses ATP hydrolysis to translocate Ca into the vacuole. Ca-dependent signaling is required for the prevalent human fungal pathogen to endure exposure to the azole antifungals and to cause disease within the mammalian host. The purpose of this study was to determine if the Pmc1p or Vcx1p Ca pumps are required for pathogenicity and if these pumps impact antifungal resistance. Our results indicate that Pmc1p is required by to transition from yeast to hyphal growth, to form biofilms , and to cause disease in a mouse model of disseminated infection. Moreover, loss of Pmc1p function appears to enhance azole tolerance in a temperature-dependent manner. Maintenance of Ca homeostasis is important for fungal cells to respond to a multitude of stresses, as well as antifungal treatment, and for virulence in animal models. Here, we demonstrate that a P-type ATPase, Pmc1p, is required for to respond to a variety of stresses, affects azole susceptibility, and is required to sustain tissue invasive hyphal growth and to cause disease in a mouse model of disseminated infection. Defining the mechanisms responsible for maintaining proper Ca homeostasis in this important human pathogen can ultimately provide opportunities to devise new chemotherapeutic interventions that dysregulate intracellular signaling and induce Ca toxicity.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC6365616 | PMC |
| http://dx.doi.org/10.1128/mSphere.00715-18 | DOI Listing |
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