Comparative genomic and transcriptomic analyses unveil novel features of azole resistance and adaptation to the human host in Candida glabrata

Salazar, Sara B.; Wang, Can; Münsterkötter, Martin; Okamoto, Michiyo; Takahashi‐Nakaguchi, Azusa; Chibana, Hiroji; Lopes, Maria Manuel; Güldener, Ulrich; Butler, Geraldine; Mira, Nuno P.

doi:10.1093/femsyr/fox079

Cited by 28 publications

(38 citation statements)

References 38 publications

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“…The presence of a PDR1 mutation appears to increase the ability of C. glabrata to adapt to other stressors, including echinocandin exposure. Specific PDR1 mutations in C. glabrata not only confer azole resistance, but can also enhance adhesion to epithelial cells through increased expression of the epithelial adhesin gene EPA1 [61][62][63][64]. The genome of C. glabrata carries a large number of EPA (epithelial adhesin) genes that encode for adhesin proteins [65][66][67].…”

Section: Micmentioning

confidence: 99%

Fungal resistance to echinocandins and the MDR phenomenon in Candida glabrata

Healey¹,

Perlin²

2018

Preprint

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Candida glabrata has thoroughly adapted to successfully colonize human mucosal membranes and survive in vivo pressures prior to and during antifungal treatment. Out of all the medically relevant Candida species, C. glabrata has emerged as a leading cause of azole, echinocandin, and multidrug (MDR: azole + echinocandin) adaptive resistance. Neither mechanism of resistance is intrinsic to C. glabrata, since stable genetic resistance depends on mutation of drug target genes, FKS1 and FKS2 (echinocandin resistance), and a transcription factor, PDR1, which controls expression of major drug transporters, such as CDR1 (azole resistance). However, another hallmark of C. glabrata is the ability to withstand drug pressure both in vitro and in vivo prior to stable ‘genetic escape’. Additionally, these resistance events can arise within individual patients, which underscores the importance of understanding how this fungus is adapting to its environment and to drug exposure in vivo. Here, we explore the evolution of echinocandin resistance as a multistep model that includes general cell stress, drug adaptation (tolerance), and genetic escape. The extensive genetic diversity reported in C. glabrata will be highlighted.

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Section: Micmentioning

confidence: 99%

Fungal resistance to echinocandins and the MDR phenomenon in Candida glabrata

Healey¹,

Perlin²

2018

Preprint

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“…The overexpression of drug-efflux pump-encoding genes results, in many cases, from the occurrence of activating mutations in the coding sequence of the corresponding regulators [41,45,78,82,[85][86][87][88][89]. This type of mechanism has been documented for CgPdr1 in C. glabrata; for CaTac1, CaMrr1 and CaUpc2 in C. albicans and for CpMrr1 and CpTac1 in C. parapsilosis [41,45,78,82,85,88].…”

Section: Azolesmentioning

confidence: 98%

“…It thus seems that specialization of the cells to improve azole stress at the expense of CaTac1 hyper-activation results in reduced capacity to handle unrelated stresses. In the same line, the expression of CgPdr1 gain-of-function alleles were also hypothesized to be linked with a reduced tolerance of C. glabrata to organic acids [51,68,89,91].…”

Section: Azolesmentioning

confidence: 99%

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An Overview on Conventional and Non-Conventional Therapeutic Approaches for the Treatment of Candidiasis and Underlying Resistance Mechanisms in Clinical Strains

Salazar

Simões

Pedro

et al. 2020

JoF

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Fungal infections and, in particular, those caused by species of the Candida genus, are growing at an alarming rate and have high associated rates of mortality and morbidity. These infections, generally referred as candidiasis, range from common superficial rushes caused by an overgrowth of the yeasts in mucosal surfaces to life-threatening disseminated mycoses. The success of currently used antifungal drugs to treat candidiasis is being endangered by the continuous emergence of resistant strains, specially among non-albicans Candida species. In this review article, the mechanisms of action of currently used antifungals, with emphasis on the mechanisms of resistance reported in clinical isolates, are reviewed. Novel approaches being taken to successfully inhibit growth of pathogenic Candida species, in particular those based on the exploration of natural or synthetic chemicals or on the activity of live probiotics, are also reviewed. It is expected that these novel approaches, either used alone or in combination with traditional antifungals, may contribute to foster the identification of novel anti-Candida therapies.

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“…Systematic surveys of genetic diversity of fungal pathogens have revealed extensive variability in the strength of virulence among genotypes of isolates from the same species (e.g., (7)). Other traits like antifungal resistance, and ability to survive different environmental conditions also show extensive variation (8–10). Understanding the magnitude and sources of variation among these traits is a crucial aspect of understanding why some pathogens are more effective at spreading and causing disease than others.…”

Section: Introductionmentioning

confidence: 99%

Strong population structure in Venezuelan populations ofCoccidioides posadasii

Teixeira

Alvarado

Roe

et al. 2019

Preprint

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28Coccidioides posadasii is a pathogenic fungus that causes coccidioidomycosis in many arid regions of 29 the Americas. One of these regions is bordered by the Caribbean Sea, and the surrounding 30 landscape may play an important role in the dispersion of C. posadasii across South America 31 through southeastern Mexico, Honduras, Guatemala and Venezuela. Comparative phylogenomic 32 analyses of C. posadasii reveal that clinical strains from Venezuela are genetically distinct from the 33 North American populations found in Arizona (AZ), Texas, Mexico, and the rest of South America 34 (TX/MX/SA). We find evidence for admixture between the Venezuela and the North American 35 populations of C. posadasii in Central America. As expected, the proportion of Venezuelan alleles in 36 the admixed population decreases as latitude (and distance from Venezuela) increases. Our results 37 indicate that the population in Venezuela may have been subjected to a recent bottleneck, and 38shows strong population structure. This analysis provides insight into potential for Coccidioides 39 spp. to invade new regions. 40

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Comparative genomic and transcriptomic analyses unveil novel features of azole resistance and adaptation to the human host in Candida glabrata

Cited by 28 publications

References 38 publications

Fungal resistance to echinocandins and the MDR phenomenon in Candida glabrata

Fungal resistance to echinocandins and the MDR phenomenon in Candida glabrata

An Overview on Conventional and Non-Conventional Therapeutic Approaches for the Treatment of Candidiasis and Underlying Resistance Mechanisms in Clinical Strains

Strong population structure in Venezuelan populations ofCoccidioides posadasii

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