Luana Rossato scite author profile

Candida auris has emerged globally as a multidrug-resistant (MDR) medical care-associated fungal pathogen. Recent reports have demonstrated that C. auris usually expresses fewer virulence factors than does Candida albicans. However, the tendency of C. auris transmission within and between healthcare facilities is unique among Candida spp. and is possibly promoted by virulence and pathogenicity factors that facilitate skin colonization and environmental persistence. To understand the ability of this yeast to cause disease, we herein discuss several virulence and pathogenicity aspects of C. auris.

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Fungicide effects on human fungal pathogens: Cross-resistance to medical drugs and beyond

Bastos

Rossato

Goldman

et al. 2021

PLoS Pathog

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Fungal infections are underestimated threats that affect over 1 billion people, and Candida spp., Cryptococcus spp., and Aspergillus spp. are the 3 most fatal fungi. The treatment of these infections is performed with a limited arsenal of antifungal drugs, and the class of the azoles is the most used. Although these drugs present low toxicity for the host, there is an emergence of therapeutic failure due to azole resistance. Drug resistance normally develops in patients undergoing azole long-term therapy, when the fungus in contact with the drug can adapt and survive. Conversely, several reports have been showing that resistant isolates are also recovered from patients with no prior history of azole therapy, suggesting that other routes might be driving antifungal resistance. Intriguingly, antifungal resistance also happens in the environment since resistant strains have been isolated from plant materials, soil, decomposing matter, and compost, where important human fungal pathogens live. As the resistant fungi can be isolated from the environment, in places where agrochemicals are extensively used in agriculture and wood industry, the hypothesis that fungicides could be driving and selecting resistance mechanism in nature, before the contact of the fungus with the host, has gained more attention. The effects of fungicide exposure on fungal resistance have been extensively studied in Aspergillus fumigatus and less investigated in other human fungal pathogens. Here, we discuss not only classic and recent studies showing that environmental azole exposure selects cross-resistance to medical azoles in A. fumigatus, but also how this phenomenon affects Candida and Cryptococcus, other 2 important human fungal pathogens found in the environment. We also examine data showing that fungicide exposure can select relevant changes in the morphophysiology and virulence of those pathogens, suggesting that its effect goes beyond the cross-resistance.

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Potential of Gallium as an Antifungal Agent

Bastos¹,

Rossato²,

Valero³

et al. 2019

Front. Cell. Infect. Microbiol.

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There are only few drugs available to treat fungal infections, and the lack of new antifungals, along with the emergence of drug-resistant strains, results in millions of deaths/year. An unconventional approach to fight microbial infection is to exploit nutritional vulnerabilities of microorganism metabolism. The metal gallium can disrupt iron metabolism in bacteria and cancer cells, but it has not been tested against fungal pathogens such as Aspergillus and Candida. Here, we investigate in vitro activity of gallium nitrate III [Ga(NO 3) 3 ] against these human pathogens, to reveal the gallium mechanism of action and understand the interaction between gallium and clinical antifungal drugs. Ga(NO 3) 3 presented a fungistatic effect against azole-sensitive and-resistant A. fumigatus strains (MIC 50/90 = 32.0 mg/L) and also had a synergistic effect with caspofungin, but not with azoles and amphotericin B. Its antifungal activity seems to be reliant on iron-limiting conditions, as the presence of iron increases its MIC value and because we observed a synergistic interaction between gallium and iron chelators against A. fumigatus. We also show that an A. fumigatus mutant (hapX) unable to grow in the absence of iron is more susceptible to gallium, reinforcing that gallium could act by disrupting iron homeostasis. Furthermore, we demonstrate that gallium has a fungistatic effect against different species of Candida ranging from 16.0 to 256.0 mg/L, including multidrug-resistant Candida auris, C. haemulonii, C. duobushaemulonii, and C. glabrata. Our findings indicate that gallium can inhibit fungal pathogens in vitro under iron-limiting conditions, showing that Ga(NO 3) 3 could be a potential therapy not only against bacteria but also as an antifungal drug.

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Origin and distribution of Sporothrix globosa causing sapronoses in Asia

Moussa

Kadasa

Zahrani

et al. 2017

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Evaluation of ischemia-modified albumin in myocardial infarction and prostatic diseases

Mastella

Moresco

Silva

et al. 2009

Biomedicine & Pharmacotherapy

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Could the COVID-19 pandemic aggravate antimicrobial resistance?

Rossato

Negrão

Simionatto

2020

American Journal of Infection Control

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Miltefosine as an alternative strategy in the treatment of the emerging fungus Candida auris

Barreto

Rossato

Freitas

et al. 2020

International Journal of Antimicrobial Agents

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In vitro activity of essential oils extracted from condiments against fluconazole-resistant and -sensitive Candida glabrata

Soares

Loreto

Rossato

et al. 2015

Journal de Mycologie Médicale

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Luana Rossato

Candida auris: What Have We Learned About Its Mechanisms of Pathogenicity?

Fungicide effects on human fungal pathogens: Cross-resistance to medical drugs and beyond

Potential of Gallium as an Antifungal Agent

Origin and distribution of Sporothrix globosa causing sapronoses in Asia

Evaluation of ischemia-modified albumin in myocardial infarction and prostatic diseases

Could the COVID-19 pandemic aggravate antimicrobial resistance?

Miltefosine as an alternative strategy in the treatment of the emerging fungus Candida auris

In vitro activity of essential oils extracted from condiments against fluconazole-resistant and -sensitive Candida glabrata

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