Candida albicans VMA3 Is Necessary for V-ATPase Assembly and Function and Contributes to Secretion and Filamentation

Abstract: The vacuolar membrane ATPase (V-ATPase) is a protein complex that utilizes ATP hydrolysis to drive protons from the cytosol into the vacuolar lumen, acidifying the vacuole and modulating several key cellular response systems in Saccharomyces cerevisiae. To study the contribution of V-ATPase to the biology and virulence attributes of the opportunistic fungal pathogen Candida albicans, we created a conditional mutant in which VMA3 was placed under the control of a tetracycline-regulated promoter (tetR-VMA3 strai… Show more

“…Our initial attempt to disrupt C. albicans VMA2 by generating a vma2⌬ homozygous null mutant on acidic media was unsuccessful; after screening over 150 transformants from three separate lineages of heterozygous null mutants, a homozygous null mutant was not recovered. These results are consistent with previous attempts to disrupt V-ATPase genes in C. albicans (4). Therefore, we constructed the strain tetR-VMA2, a tetracycline-regulatable VMA2 mutant in which the VMA2 gene is repressed upon the addition of DOX (18).…”

“…Vacuolar acidification assays. Quinacrine staining was performed to visualize acidified vacuoles as described previously (27), with modifications as indicated previously (4). Briefly, cells were grown for 24 h in unbuffered YPD with or without DOX and then reset in fresh unbuffered YPD with or without DOX and grown to early log phase.…”

“…In addition to its requirement for intraorganellar pH homeostasis, V-ATPase function has been implicated in cytosolic and extracellular pH homeostasis (1,(8)(9)(10)(11), underscoring the far-reaching importance of this pump to overall cellular homeostasis. V-ATPase inhibition also interferes with virulence-related traits in C. albicans, including the secretion of degradative enzymes and yeast-to-hypha transitioning (3,4,12,13). Notably, V-ATPase previously has been shown to be important for in vivo virulence in C. albicans (3, 13); however, the requirement of acidic environmental pH for the growth of VATPase mutants complicates the interpretation of these studies due to the growth-limiting alkaline pH in the bloodstream of the murine host.…”

“…The acidification of these organelles has several important functions: first, the protons pumped into the compartment by V-ATPase energize multiple secondary transporter systems, such as those involved in metal ion homeostasis, and second, the acidic pH created by V-ATPase is necessary for the activity of degradative enzymes. Accordingly, in both Saccharomyces cerevisiae and C. albicans, mutations in VATPase lead to the Vma Ϫ phenotype, which is characterized by poor growth at alkaline pH as well as defective metal sequestration, glycerol metabolism, and other responses to environmental stress conditions (1,(3)(4)(5)(6). V-ATPase mutants are also impaired in vacuolar biogenesis due to defects in both vacuolar membrane fusion and fission (7).…”

“…Studies of S. cerevisiae have shown that disruption of VMA2 completely inhibits both ATPase activity and proton transport by the V-ATPase (14). We have previously investigated the contribution of several subunits of C. albicans VATPase to cell biology and virulence-related traits (4,12). This is the first study analyzing a subunit of the catalytic hexamer in the V 1 domain of V-ATPase in C. albicans.…”

The Contribution of Candida albicans Vacuolar ATPase Subunit V ₁ B, Encoded by VMA2 , to Stress Response, Autophagy, and Virulence Is Independent of Environmental pH

“…Our initial attempt to disrupt C. albicans VMA2 by generating a vma2⌬ homozygous null mutant on acidic media was unsuccessful; after screening over 150 transformants from three separate lineages of heterozygous null mutants, a homozygous null mutant was not recovered. These results are consistent with previous attempts to disrupt V-ATPase genes in C. albicans (4). Therefore, we constructed the strain tetR-VMA2, a tetracycline-regulatable VMA2 mutant in which the VMA2 gene is repressed upon the addition of DOX (18).…”

“…Vacuolar acidification assays. Quinacrine staining was performed to visualize acidified vacuoles as described previously (27), with modifications as indicated previously (4). Briefly, cells were grown for 24 h in unbuffered YPD with or without DOX and then reset in fresh unbuffered YPD with or without DOX and grown to early log phase.…”

“…In addition to its requirement for intraorganellar pH homeostasis, V-ATPase function has been implicated in cytosolic and extracellular pH homeostasis (1,(8)(9)(10)(11), underscoring the far-reaching importance of this pump to overall cellular homeostasis. V-ATPase inhibition also interferes with virulence-related traits in C. albicans, including the secretion of degradative enzymes and yeast-to-hypha transitioning (3,4,12,13). Notably, V-ATPase previously has been shown to be important for in vivo virulence in C. albicans (3, 13); however, the requirement of acidic environmental pH for the growth of VATPase mutants complicates the interpretation of these studies due to the growth-limiting alkaline pH in the bloodstream of the murine host.…”

“…The acidification of these organelles has several important functions: first, the protons pumped into the compartment by V-ATPase energize multiple secondary transporter systems, such as those involved in metal ion homeostasis, and second, the acidic pH created by V-ATPase is necessary for the activity of degradative enzymes. Accordingly, in both Saccharomyces cerevisiae and C. albicans, mutations in VATPase lead to the Vma Ϫ phenotype, which is characterized by poor growth at alkaline pH as well as defective metal sequestration, glycerol metabolism, and other responses to environmental stress conditions (1,(3)(4)(5)(6). V-ATPase mutants are also impaired in vacuolar biogenesis due to defects in both vacuolar membrane fusion and fission (7).…”

“…Studies of S. cerevisiae have shown that disruption of VMA2 completely inhibits both ATPase activity and proton transport by the V-ATPase (14). We have previously investigated the contribution of several subunits of C. albicans VATPase to cell biology and virulence-related traits (4,12). This is the first study analyzing a subunit of the catalytic hexamer in the V 1 domain of V-ATPase in C. albicans.…”

The Contribution of Candida albicans Vacuolar ATPase Subunit V ₁ B, Encoded by VMA2 , to Stress Response, Autophagy, and Virulence Is Independent of Environmental pH

Emerging insights on the role of V‐ATPase in human diseases: Therapeutic challenges and opportunities

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