Identification of an Aminothiazole with Antifungal Activity against Intracellular Histoplasma capsulatum

Edwards, Jessica A.; Kemski, Megan M.; Rappleye, Chad A.

doi:10.1128/aac.00459-13

Cited by 26 publications

(30 citation statements)

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“…It is hoped that these standardized methods will provide for more reliable profiling of clinical isolates of Histoplasma as well as accelerate high-throughput screening of compounds for new antifungals active against the pathogenic phase of Histoplasma (22).…”

Section: Discussionmentioning

confidence: 99%

“…This study was motivated by the inadequacy of CLSI-defined yeast culture procedures for the growth of Histoplasma yeasts, the clinical form of Histoplasma. In some previous studies, the CLSI M27-A2 and -A3 standards have been adapted for Histoplasma yeast (22)(23)(24)(25), but no consensus methods or optimization of assay parameters have been detailed. Here, we optimize the inoculum size and assay duration to maximize the dynamic range of a microdilution assay for Histoplasma.…”

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confidence: 99%

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Quantitative Microplate-Based Growth Assay for Determination of Antifungal Susceptibility of Histoplasma capsulatum Yeasts

2015

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bStandardized methodologies for determining the antifungal susceptibility of fungal pathogens is central to the clinical management of invasive fungal disease. Yeast-form fungi can be tested using broth macrodilution and microdilution assays. Reference procedures exist for Candida species and Cryptococcus yeasts; however, no standardized methods have been developed for testing the antifungal susceptibility of yeast forms of the dimorphic systemic fungal pathogens. For the dimorphic fungal pathogen Histoplasma capsulatum, susceptibility to echinocandins differs for the yeast and the filamentous forms, which highlights the need to employ Histoplasma yeasts, not hyphae, in antifungal susceptibility tests. To address this, we developed and optimized methodology for the 96-well microtiter plate-based measurement of Histoplasma yeast growth in vitro. Using optical density, the assay is quantitative for fungal growth with a dynamic range greater than 30-fold. Concentration and assay reaction time parameters were also optimized for colorimetric (MTT [3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide] reduction) and fluorescent (resazurin reduction) indicators of fungal vitality. We employed this microtiter-based assay to determine the antifungal susceptibility patterns of multiple clinical isolates of Histoplasma representing different phylogenetic groups. This methodology fulfills a critical need for the ability to monitor the effectiveness of antifungals on Histoplasma yeasts, the morphological form present in mammalian hosts and, thus, the form most relevant to disease.T he increasing incidence of fungal disease necessitates adequate and timely assessment of antifungal susceptibility to guide the selection and implementation of antifungal therapies. Consequently, the Clinical and Laboratory Standards Institute (CLSI) and the European Committee on Antimicrobial Susceptibility Testing (EUCAST) have established reference test methods for susceptibility to the major classes of antifungals, which include the polyenes, azoles, and the recently developed echinocandins (1, 2). These standards utilize broth macrodilution or microdilution assays for testing yeasts (M27-A3 [3] and E.DEF 7.1 [4]) and filamentous fungi (M38-A2 [5] and E.DEF 9.1 [6]). Procedures, including inoculum preparation, media, assay duration, and endpoint definitions, have now been established for testing some of the more commonly encountered yeast-form pathogenic fungi (i.e., Candida species and Cryptococcus). However, notably missing from the M27-A3 and E.DEF 7.1 standards for testing of yeasts are methods for testing the yeast forms of the dimorphic fungi.The dimorphic fungi that cause systemic disease are characterized by distinct yeast and filamentous morphological states (7,8). Temperature is the principal morphology-determining factor, with yeast forms characterizing infections in mammals (9). Histoplasma capsulatum is the most common clinically encountered dimorphic fungal pathogen in the United States, with an estimated 10,000 to 20,000...

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Quantitative Microplate-Based Growth Assay for Determination of Antifungal Susceptibility of Histoplasma capsulatum Yeasts

2015

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“…The top hit aminothiazole (41F5) was effective against yeasts in culture (MIC 2-4 mM) and effectively inhibited proliferation of yeasts resident within macrophages. 98 Importantly, the aminothiazole compound had low toxicity to cultured mammalian cells, including macrophages. Unfortunately, the aminothiazole was not active against Blastomyces yeasts despite the very close phylogenetic relationship between Histoplasma and Blastomyces.…”

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“…To enable rapid quantitative screening of yeast growth, yeasts were engineered to express a red-fluorescent protein, which could be used as a surrogate indicator of the number of yeast cells. 98 Furthermore, fluorescence-based growth analysis facilitated efficient monitoring of Histoplasma within macrophages, and thus the determination of the effectiveness of compounds on inhibition of Histoplasma within its host cell environment. The top hit aminothiazole (41F5) was effective against yeasts in culture (MIC 2-4 mM) and effectively inhibited proliferation of yeasts resident within macrophages.…”

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Antifungal therapeutics for dimorphic fungal pathogens

Goughenour

Rappleye

2016

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Dimorphic fungi cause several endemic mycoses which range from subclinical respiratory infections to life-threatening systemic disease. Pathogenic-phase cells of Histoplasma, Blastomyces, Paracoccidioides and Coccidioides escape elimination by the innate immune response with control ultimately requiring activation of cell-mediated immunity. Clinical management of disease relies primarily on antifungal compounds; however, dimorphic fungal pathogens create a number of challenges for antifungal drug therapy. In addition to the drug toxicity issues known for current antifungals, barriers to efficient drug treatment of dimorphic fungal infections include natural resistance to the echinocandins, residence of fungal cells within immune cells, the requirement for systemic delivery of drugs, prolonged treatment times, potential for latent infections, and lack of optimized standardized methodology for in vitro testing of drug susceptibilities. This review will highlight recent advances, current therapeutic options, and new compounds on the horizon for treating infections by dimorphic fungal pathogens.

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“…Cell Wall Sensitivity Assays-Yeast cells were grown in 96-well microtiter plates (38) with graded concentrations of antifungal compounds (fluconazole (Glenmark Generics); caspofungin (Merck); and nikkomycin Z (gift from John Galgiani)) and cell wall-destabilizing compounds (Calcofluor White (Sigma); Congo red (MP Biomedicals); SDS; and Uvitex) (39). Growth after 4 days was measured by optical density at 595 nm and compared with the turbidity of wells lacking inhibitors.…”

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Eng1 and Exg8 Are the Major α-Glucanases Secreted by the Fungal Pathogen Histoplasma capsulatum

Garfoot

Dearing

VanSchoiack

et al. 2017

Journal of Biological Chemistry

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Edited by Gerald W. HartFungal cell walls contain ␤-glucan polysaccharides that stimulate immune responses when recognized by host immune cells. The fungal pathogen Histoplasma capsulatum minimizes detection of ␤-glucan by host cells through at least two mechanisms: concealment of ␤-glucans beneath ␣-glucans and enzymatic removal of any exposed ␤-glucan polysaccharides by the secreted glucanase Eng1. Histoplasma yeasts also secrete the putative glucanase Exg8, which may serve a similar role as Eng1 in removing exposed ␤-glucans from the yeast cell surface. Here, we characterize the enzymatic specificity of the Eng1 and Exg8 proteins and show that Exg8 is an exo-␤1,3-glucanase and Eng1 is an endo-␤1,3-glucanase. Together, Eng1 and Exg8 account for nearly all of the total secreted glucanase activity of Histoplasma yeasts. Both Eng1 and Exg8 proteins are secreted through a conventional secretion signal and are modified posttranslationally by O-linked glycosylation. Both glucanases have near maximal activity at temperature and pH conditions experienced during infection of host cells, supporting roles in Histoplasma pathogenesis. Exg8 has a higher specific activity than Eng1 for ␤1,3-glucans; yet despite this, Exg8 does not reduce detection of yeasts by the host ␤-glucan receptor Dectin-1. Exg8 is largely dispensable for virulence in vivo, in contrast to Eng1. These results show that Histoplasma yeasts secrete two ␤1,3-glucanases and that Eng1 endoglucanase activity is the predominant factor responsible for removal of exposed cell wall ␤-glucans to minimize host detection of Histoplasma yeasts.

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Identification of an Aminothiazole with Antifungal Activity against Intracellular Histoplasma capsulatum

Cited by 26 publications

References 50 publications

Quantitative Microplate-Based Growth Assay for Determination of Antifungal Susceptibility of Histoplasma capsulatum Yeasts

Quantitative Microplate-Based Growth Assay for Determination of Antifungal Susceptibility of Histoplasma capsulatum Yeasts

Antifungal therapeutics for dimorphic fungal pathogens

Eng1 and Exg8 Are the Major α-Glucanases Secreted by the Fungal Pathogen Histoplasma capsulatum

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