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- Title
Nickel tolerance is channeled through C-4 methyl sterol oxidase Erg25 in the sterol biosynthesis pathway.
- Authors
Matha, Amber R.; Xie, Xiaofeng; Maier, Robert J.; Lin, Xiaorong
- Abstract
Nickel (Ni) is an abundant element on Earth and it can be toxic to all forms of life. Unlike our knowledge of other metals, little is known about the biochemical response to Ni overload. Previous studies in mammals have shown that Ni induces various physiological changes including redox stress, hypoxic responses, as well as cancer progression pathways. However, the primary cellular targets of nickel toxicity are unknown. Here, we used the environmental fungus Cryptococcus neoformans as a model organism to elucidate the cellular response to exogenous Ni. We discovered that Ni causes alterations in ergosterol (the fungal equivalent of mammalian cholesterol) and lipid biosynthesis, and that the Sterol Regulatory Element-Binding transcription factor Sre1 is required for Ni tolerance. Interestingly, overexpression of the C-4 methyl sterol oxidase gene ERG25, but not other genes in the ergosterol biosynthesis pathway tested, increases Ni tolerance in both the wild type and the sre1Δ mutant. Overexpression of ERG25 with mutations in the predicted binding pocket to a metal cation cofactor sensitizes Cryptococcus to nickel and abolishes its ability to rescue the Ni-induced growth defect of sre1Δ. As overexpression of a known nickel-binding protein Ure7 or Erg3 with a metal binding pocket similar to Erg7 does not impact on nickel tolerance, Erg25 does not appear to simply act as a nickel sink. Furthermore, nickel induces more profound and specific transcriptome changes in ergosterol biosynthetic genes compared to hypoxia. We conclude that Ni targets the sterol biosynthesis pathway primarily through Erg25 in fungi. Similar to the observation in C. neoformans, Ni exposure reduces sterols in human A549 lung epithelial cells, indicating that nickel toxicity on sterol biosynthesis is conserved. Author summary: Nickel is commonly known as an allergen and toxin for humans, but the way in which nickel causes adverse effects is unknown. We sought to use C. neoformans as a model to investigate the primary targets of nickel and how cells tolerate this commonly occurring metal. We found that in both mammalian cells and fungal cells, exposure to nickel causes sterol deficiency. We discovered that Erg25, an essential enzyme key to the production of ergosterol (fungal equivalent of cholesterol), was critical for cryptococcal cells to tolerate nickel. Cells unable to increase production of this enzyme in response to nickel exposure, such as the sre1Δ mutant with the Sterol Regulatory Element-Binding regulator disrupted, were incapable of growing in the presence of nickel. Therefore, it appears that both cells react to nickel through upregulating a conserved biochemical pathway and particularly the Erg25 enzyme. This work could guide future investigations into novel approaches to manage nickel toxicity.
- Publication
PLoS Genetics, 2024, Vol 20, Issue 9, p1
- ISSN
1553-7390
- Publication type
Article
- DOI
10.1371/journal.pgen.1011413