The burden of fungal infections for humans, animals and plants is widely underestimated and comprises deadly infections as well as great economic costs. Despite that, antifungal drugs are scarce and emergence of resistance in fungal strains contributes to a high mortality. To overcome this shortage, we propose toxic intermediates and their controlling enzymes in metabolic pathways as a resource for new targets and provide a web-service, FunTox-Networks to explore the landscape of toxic intermediates in the metabolic networks of fungal pathogens. The toxicity of metabolites is predicted by a new random forest regression model and is available for over one hundred fungal species. Further, for major fungal pathogens, metabolic networks from the KEGG database were enriched with data of toxicity and regulatory effort for each enzyme to support identification of targets. We determined several toxic intermediates in fungal-specific pathways like amino acid synthesis, nitrogen and sulfur assimilation, and the glyoxylate bypass. For the latter, we show experimentally that growth of the pathogen Candida albicans is inhibited when the detoxifying enzymes Mls1 and Hbr2 are deleted and toxic glyoxylate accumulates in the cell. Thus, toxic pathway intermediates and their controlling enzymes represent an untapped resource of antifungal targets.
%0 Unpublished Work
%1 Ewald2021-fk
%A Ewald, Jan
%A Jansen, Paul Mathias
%A Brunke, Sascha
%A Hiller, Davina
%A Luther, Christian H
%A González-D\'ıaz, Humbert
%A Dittrich, Marcus T
%A Fleißner, André
%A Hube, Bernhard
%A Schuster, Stefan
%A Kaleta, Christoph
%D 2021
%J bioRxiv
%K
%T The landscape of toxic intermediates in the metabolic networks of pathogenic fungi reveals targets for antifungal drugs
%X The burden of fungal infections for humans, animals and plants is widely underestimated and comprises deadly infections as well as great economic costs. Despite that, antifungal drugs are scarce and emergence of resistance in fungal strains contributes to a high mortality. To overcome this shortage, we propose toxic intermediates and their controlling enzymes in metabolic pathways as a resource for new targets and provide a web-service, FunTox-Networks to explore the landscape of toxic intermediates in the metabolic networks of fungal pathogens. The toxicity of metabolites is predicted by a new random forest regression model and is available for over one hundred fungal species. Further, for major fungal pathogens, metabolic networks from the KEGG database were enriched with data of toxicity and regulatory effort for each enzyme to support identification of targets. We determined several toxic intermediates in fungal-specific pathways like amino acid synthesis, nitrogen and sulfur assimilation, and the glyoxylate bypass. For the latter, we show experimentally that growth of the pathogen Candida albicans is inhibited when the detoxifying enzymes Mls1 and Hbr2 are deleted and toxic glyoxylate accumulates in the cell. Thus, toxic pathway intermediates and their controlling enzymes represent an untapped resource of antifungal targets.
@unpublished{Ewald2021-fk,
abstract = {The burden of fungal infections for humans, animals and plants is widely underestimated and comprises deadly infections as well as great economic costs. Despite that, antifungal drugs are scarce and emergence of resistance in fungal strains contributes to a high mortality. To overcome this shortage, we propose toxic intermediates and their controlling enzymes in metabolic pathways as a resource for new targets and provide a web-service, FunTox-Networks to explore the landscape of toxic intermediates in the metabolic networks of fungal pathogens. The toxicity of metabolites is predicted by a new random forest regression model and is available for over one hundred fungal species. Further, for major fungal pathogens, metabolic networks from the KEGG database were enriched with data of toxicity and regulatory effort for each enzyme to support identification of targets. We determined several toxic intermediates in fungal-specific pathways like amino acid synthesis, nitrogen and sulfur assimilation, and the glyoxylate bypass. For the latter, we show experimentally that growth of the pathogen Candida albicans is inhibited when the detoxifying enzymes Mls1 and Hbr2 are deleted and toxic glyoxylate accumulates in the cell. Thus, toxic pathway intermediates and their controlling enzymes represent an untapped resource of antifungal targets.},
added-at = {2024-09-10T11:56:37.000+0200},
author = {Ewald, Jan and Jansen, Paul Mathias and Brunke, Sascha and Hiller, Davina and Luther, Christian H and Gonz{\'a}lez-D{\'\i}az, Humbert and Dittrich, Marcus T and Flei{\ss}ner, Andr{\'e} and Hube, Bernhard and Schuster, Stefan and Kaleta, Christoph},
biburl = {https://puma.scadsai.uni-leipzig.de/bibtex/26030c5396a5405c3443d5d95a5a7ba46/scadsfct},
interhash = {3e8d07b729c17752d935fc310d2b1d2f},
intrahash = {6030c5396a5405c3443d5d95a5a7ba46},
journal = {bioRxiv},
keywords = {},
month = sep,
timestamp = {2024-09-10T15:15:57.000+0200},
title = {The landscape of toxic intermediates in the metabolic networks of pathogenic fungi reveals targets for antifungal drugs},
year = 2021
}