Absence of farnesol salvage in
            <i>Candida albicans</i>
            and probably in other fungi

Voshall, Adam; Gutzmann, Daniel J.; Verdaguer, Ignasi Bofill; Crispim, Marcell; Boone, Cory H.T.; Atkin, Audrey L.; Nickerson, Kenneth W.

doi:10.1128/aem.00874-24

Cited by 2 publications

References 53 publications

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Validation of DXS as an attractive drug target in mycobacteria

Maila,

Nicolaai,

Mbau

et al. 2024

Preprint

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A rapid emergence in the incidences of Tuberculosis (TB) drug resistance undermines efforts to eradicate the disease and strengthens calls for development of new drugs with novel mechanisms of action. In drug discovery, finding an attractive drug target is as important as finding a good drug candidate. Hence more efforts are made to identify, validate and prioritize drug targets in TB drug discovery. Here, using CRISPRi technology, we showed that dxs1 transcriptional knockdown attenuated growth of both Mycobacterium smegmatis and Mycobacterium tuberculosis cultures, and the effect was more profound in the latter. Chemical supplementation of the growth medium with 10 uM of isoprenoid pyrophosphates, thiamine and thiamine pyrophosphate failed to rescue growth of M. smegmatis cultures, while partial rescue was observed with addition of menatetrenone, a menaquinone derivative with four isoprenyl groups. Similarly, culture growth could not be rescued by the addition of prenol and isoprenol, which suggested the lack of isoprenoid salvage pathway in mycobacteria. Importantly, and in the context of drug discovery, dxs1 depleted mutants displayed four-fold more sensitive towards a mixture of isoniazid, rifampicin and ethambutol, suggesting that inhibitors of DXS1 or other MEP pathway enzymes could potentiate antimycobacterial effect of the first-line TB drugs. Additionally, dxs1 depletion increased growth retardation of the mutant in acidic pH and under oxidative stress, conditions that are encountered in activated macrophage compartments. Taken together, our results validated DXS1 as an attractive drug target that should be prioritized for developments on new antitubercular agents.

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Validation of DXS as an attractive drug target in mycobacteria

Maila,

Nicolaai,

Mbau

et al. 2024

Preprint

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The role of serum albumin in Candida albicans filamentation, germ tube formation, and farnesol sequestration

Gutzmann,

Toomey,

Atkin

et al. 2024

Appl Environ Microbiol

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Candida albicans is an opportunistic pathogen and colonizer of the human gut and mucosal membranes. C. albicans exhibits morphological plasticity, which is crucial for its fitness within the host and virulence. Morphogenesis in C. albicans is regulated, in part, by its production of farnesol, an autoregulatory molecule that inhibits filamentation. Morphogenesis is also regulated in response to external cues, such as serum, which stimulates hyphal formation by C. albicans . The precise mechanism by which serum stimulates hyphal formation is unknown. The most abundant serum protein is albumin. The binding affinity of albumin for nonpolar, fatty-acid-like molecules suggests that it may interact directly with exogenous farnesol and influence morphogenesis through sequestration of free farnesol. To test this hypothesis, we assessed whether albumin and albumin devoid of fatty acids (i) stimulated farnesol secretion and (ii) influenced the farnesol threshold required to inhibit filamentation. We found that albumin promoted farnesol secretion and filamentation, and the extent of its ability to do so was based on the presence or absence of bound fatty acids. We hypothesize that albumin not bound to fatty acids has the capacity to bind to farnesol and sequester it from C. albicans , encouraging filamentation. IMPORTANCE For at least 50 years, researchers have wondered about the mechanisms by which serum stimulates germ tube formation (GTF) and hyphal growth in C. albicans . Here, we tested a model (Nickerson et al., Microbiol Mol Biol Rev 88:e00081-22, 2024, https://doi.org/10.1128/mmbr.00081-22 ) that serum promotes GTF and farnesol synthesis in part by extracting internal farnesol (F i ) from the cells toward the excess binding capacity of the albumins. The data presented here suggests that albumin not bound by fatty acids sequesters free farnesol thereby modulating filamentation and farnesol secretion by altering the equilibrium of internal vs external farnesol. We expect that the influence of secreted farnesol on cell morphology will differ during pathogenesis depending on location within the body, but sequestration of farnesol in the blood could mediate immune cell recruitment and promote hyphal formation.

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Absence of farnesol salvage in Candida albicans and probably in other fungi

Cited by 2 publications

References 53 publications

Validation of DXS as an attractive drug target in mycobacteria

Validation of DXS as an attractive drug target in mycobacteria

The role of serum albumin in Candida albicans filamentation, germ tube formation, and farnesol sequestration

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