A Multidimensional Assessment of In-host Fitness Costs of Drug Resistance in the Opportunistic Fungal Pathogen Candida Glabrata

Overview

Journal FEMS Yeast Res

Publisher Oxford University Press

Specialty Microbiology

Date 2024 Nov 15

PMID 39545363

Authors

Amir Arastehfar

Farnaz Daneshnia

Hrant Hovhannisyan

Nathaly Cabrera

Macit Ilkit

Jigar V Desai

Toni Gabaldon

Erika Shor

David S Perlin

Affiliations

Soon will be listed here.

Abstract

Drug-resistant microbes typically carry mutations in genes involved in critical cellular functions and may therefore be less fit under drug-free conditions than susceptible strains. Candida glabrata is a prevalent opportunistic yeast pathogen with a high rate of fluconazole resistance (FLZR), echinocandin resistance (ECR), and multidrug resistance (MDR) relative to other Candida. However, the fitness of C. glabrata MDR isolates, particularly in the host, is poorly characterized, and studies of FLZR isolate fitness have produced contradictory findings. Two important host niches for C. glabrata are macrophages, in which it survives and proliferates, and the gut. Herein, we used a collection of clinical and lab-derived C. glabrata isolates to show that FLZR C. glabrata isolates are less fit inside macrophages than susceptible isolates and that this fitness cost is reversed by acquiring ECR mutations. Interestingly, dual-RNAseq revealed that macrophages infected with drug-resistant isolates mount an inflammatory response whereas intracellular drug-resistant cells downregulate processes required for in-host adaptation. Furthermore, drug-resistant isolates were outcompeted by their susceptible counterparts during gut colonization and in infected kidneys, while showing comparable fitness in the spleen. Collectively, our study shows that macrophage-rich organs, such as the spleen, favor the retention of MDR isolates of C. glabrata.

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