Dafna Ben Yaakov1, Yana Shadkchan1, Nathaniel Albert2, Dimitrios P Kontoyiannis2, Nir Osherov1. 1. Department of Clinical Microbiology and Immunology, Sackler School of Medicine, Tel-Aviv University, Tel-Aviv, Israel. 2. Department of Infectious Diseases, Infection Control and Employee Health, University of Texas MD Anderson Cancer Center, Houston, TX, USA.
Abstract
Objectives: Over the last 30 years, the number of invasive fungal infections among immunosuppressed patients has increased significantly, while the number of effective systemic antifungal drugs remains low. The aim of this study was to identify and characterize antifungal compounds that inhibit fungus-specific metabolic pathways not conserved in humans. Methods: We screened a diverse compound library for antifungal activity in the pathogenic mould Aspergillus fumigatus . We determined the in vitro activity of bromoquinol by MIC determination against a panel of fungi, bacteria and cell lines. The mode of action of bromoquinol was determined by screening an Aspergillus nidulans overexpression genomic library for resistance-conferring genes and by RNAseq analysis in A. fumigatus . In vivo efficacy was tested in Galleria mellonella and murine models of A. fumigatus infection. Results: Screening of a diverse chemical library identified three compounds interfering with fungal iron utilization. The most potent, bromoquinol, shows potent wide-spectrum antifungal activity that was blocked in the presence of exogenous iron. Mode-of-action analysis revealed that overexpression of the dba secondary metabolite cluster gene dbaD , encoding a metabolite transporter, confers bromoquinol resistance in A. nidulans , possibly by efflux. RNAseq analysis and subsequent experimental validation revealed that bromoquinol induces oxidative stress and apoptosis in A. fumigatus . Bromoquinol significantly reduced mortality rates of G. mellonella infected with A. fumigatus , but was ineffective in a murine model of infection. Conclusions: Bromoquinol is a promising antifungal candidate with a unique mode of action. Its activity is potentiated by iron starvation, as occurs during in vivo growth.
Objectives: Over the last 30 years, the number of invasive fungal infections among immunosuppressed patients has increased significantly, while the number of effective systemic antifungal drugs remains low. The aim of this study was to identify and characterize antifungal compounds that inhibit fungus-specific metabolic pathways not conserved in humans. Methods: We screened a diverse compound library for antifungal activity in the pathogenic mould Aspergillus fumigatus . We determined the in vitro activity of bromoquinol by MIC determination against a panel of fungi, bacteria and cell lines. The mode of action of bromoquinol was determined by screening an Aspergillus nidulans overexpression genomic library for resistance-conferring genes and by RNAseq analysis in A. fumigatus . In vivo efficacy was tested in Galleria mellonella and murine models of A. fumigatusinfection. Results: Screening of a diverse chemical library identified three compounds interfering with fungal iron utilization. The most potent, bromoquinol, shows potent wide-spectrum antifungal activity that was blocked in the presence of exogenous iron. Mode-of-action analysis revealed that overexpression of the dba secondary metabolite cluster gene dbaD , encoding a metabolite transporter, confers bromoquinol resistance in A. nidulans , possibly by efflux. RNAseq analysis and subsequent experimental validation revealed that bromoquinol induces oxidative stress and apoptosis in A. fumigatus . Bromoquinol significantly reduced mortality rates of G. mellonella infected with A. fumigatus , but was ineffective in a murine model of infection. Conclusions: Bromoquinol is a promising antifungal candidate with a unique mode of action. Its activity is potentiated by iron starvation, as occurs during in vivo growth.
Authors: Yu-Shan Cheng; Jose Santinni Roma; Min Shen; Caroline Mota Fernandes; Patricia S Tsang; He Eun Forbes; Helena Boshoff; Cristina Lazzarini; Maurizio Del Poeta; Wei Zheng; Peter R Williamson Journal: Antimicrob Agents Chemother Date: 2021-03-18 Impact factor: 5.191
Authors: Patrick Van Dijck; Jelmer Sjollema; Bruno P Cammue; Katrien Lagrou; Judith Berman; Christophe d'Enfert; David R Andes; Maiken C Arendrup; Axel A Brakhage; Richard Calderone; Emilia Cantón; Tom Coenye; Paul Cos; Leah E Cowen; Mira Edgerton; Ana Espinel-Ingroff; Scott G Filler; Mahmoud Ghannoum; Neil A R Gow; Hubertus Haas; Mary Ann Jabra-Rizk; Elizabeth M Johnson; Shawn R Lockhart; Jose L Lopez-Ribot; Johan Maertens; Carol A Munro; Jeniel E Nett; Clarissa J Nobile; Michael A Pfaller; Gordon Ramage; Dominique Sanglard; Maurizio Sanguinetti; Isabel Spriet; Paul E Verweij; Adilia Warris; Joost Wauters; Michael R Yeaman; Sebastian A J Zaat; Karin Thevissen Journal: Microb Cell Date: 2018-06-14