Prevalent mutator genotype identified in fungal pathogen Candida glabrata promotes multi-drug resistance

Kelley R. Healey; Yanan Zhao; Winder B. Perez; Shawn R. Lockhart; Jack D. Sobel; Dimitrios Farmakiotis; Dimitrios P. Kontoyiannis; Dominique Sanglard; Saad J. Taj-Aldeen; Barbara D. Alexander; Cristina Jimenez-Ortigosa; Erika Shor; David S. Perlin

doi:10.1038/ncomms11128

Prevalent mutator genotype identified in fungal pathogen Candida glabrata promotes multi-drug resistance

Kelley R. Healey
, Yanan Zhao
, Winder B. Perez
, Shawn R. Lockhart
, Jack D. Sobel
, Dimitrios Farmakiotis
, Dimitrios P. Kontoyiannis
, Dominique Sanglard
, Saad J. Taj-Aldeen
, Barbara D. Alexander
, Cristina Jimenez-Ortigosa
, Erika Shor
, David S. Perlin

Pharmacy

Public Health Research Institute, New York
Centers for Disease Control and Prevention
Wayne State University
University of Texas MD Anderson Cancer Center
Brown University
University of Lausanne
Hamad Medical Corporation
Duke University

Research output: Contribution to journal › Article › peer-review

234 Scopus citations

Abstract

The fungal pathogen Candida glabrata has emerged as a major health threat since it readily acquires resistance to multiple drug classes, including triazoles and/or echinocandins. Thus far, cellular mechanisms promoting the emergence of resistance to multiple drug classes have not been described in this organism. Here we demonstrate that a mutator phenotype caused by a mismatch repair defect is prevalent in C. glabrata clinical isolates. Strains carrying alterations in mismatch repair gene MSH2 exhibit a higher propensity to breakthrough antifungal treatment in vitro and in mouse models of colonization, and are recovered at a high rate (55% of all C. glabrata recovered) from patients. This genetic mechanism promotes the acquisition of resistance to multiple antifungals, at least partially explaining the elevated rates of triazole and multi-drug resistance associated with C. glabrata. We anticipate that identifying MSH2 defects in infecting strains may influence the management of patients on antifungal drug therapy.

Original language	English
Article number	11128
Journal	Nature Communications
Volume	7
DOIs	https://doi.org/10.1038/ncomms11128
State	Published - Mar 29 2016

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Healey, K. R., Zhao, Y., Perez, W. B., Lockhart, S. R., Sobel, J. D., Farmakiotis, D., Kontoyiannis, D. P., Sanglard, D., Taj-Aldeen, S. J., Alexander, B. D., Jimenez-Ortigosa, C., Shor, E., & Perlin, D. S. (2016). Prevalent mutator genotype identified in fungal pathogen Candida glabrata promotes multi-drug resistance. Nature Communications, 7, Article 11128. https://doi.org/10.1038/ncomms11128

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title = "Prevalent mutator genotype identified in fungal pathogen Candida glabrata promotes multi-drug resistance",

abstract = "The fungal pathogen Candida glabrata has emerged as a major health threat since it readily acquires resistance to multiple drug classes, including triazoles and/or echinocandins. Thus far, cellular mechanisms promoting the emergence of resistance to multiple drug classes have not been described in this organism. Here we demonstrate that a mutator phenotype caused by a mismatch repair defect is prevalent in C. glabrata clinical isolates. Strains carrying alterations in mismatch repair gene MSH2 exhibit a higher propensity to breakthrough antifungal treatment in vitro and in mouse models of colonization, and are recovered at a high rate (55\% of all C. glabrata recovered) from patients. This genetic mechanism promotes the acquisition of resistance to multiple antifungals, at least partially explaining the elevated rates of triazole and multi-drug resistance associated with C. glabrata. We anticipate that identifying MSH2 defects in infecting strains may influence the management of patients on antifungal drug therapy.",

author = "Healey, \{Kelley R.\} and Yanan Zhao and Perez, \{Winder B.\} and Lockhart, \{Shawn R.\} and Sobel, \{Jack D.\} and Dimitrios Farmakiotis and Kontoyiannis, \{Dimitrios P.\} and Dominique Sanglard and Taj-Aldeen, \{Saad J.\} and Alexander, \{Barbara D.\} and Cristina Jimenez-Ortigosa and Erika Shor and Perlin, \{David S.\}",

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AU - Healey, Kelley R.

AU - Zhao, Yanan

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AU - Lockhart, Shawn R.

AU - Sobel, Jack D.

AU - Farmakiotis, Dimitrios

AU - Kontoyiannis, Dimitrios P.

AU - Sanglard, Dominique

AU - Taj-Aldeen, Saad J.

AU - Alexander, Barbara D.

AU - Jimenez-Ortigosa, Cristina

AU - Shor, Erika

AU - Perlin, David S.

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AB - The fungal pathogen Candida glabrata has emerged as a major health threat since it readily acquires resistance to multiple drug classes, including triazoles and/or echinocandins. Thus far, cellular mechanisms promoting the emergence of resistance to multiple drug classes have not been described in this organism. Here we demonstrate that a mutator phenotype caused by a mismatch repair defect is prevalent in C. glabrata clinical isolates. Strains carrying alterations in mismatch repair gene MSH2 exhibit a higher propensity to breakthrough antifungal treatment in vitro and in mouse models of colonization, and are recovered at a high rate (55% of all C. glabrata recovered) from patients. This genetic mechanism promotes the acquisition of resistance to multiple antifungals, at least partially explaining the elevated rates of triazole and multi-drug resistance associated with C. glabrata. We anticipate that identifying MSH2 defects in infecting strains may influence the management of patients on antifungal drug therapy.

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Prevalent mutator genotype identified in fungal pathogen Candida glabrata promotes multi-drug resistance

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