Raman Study of Pathogenic : Imaging Metabolic Machineries in Reaction to Antifungal Drugs

Overview

Journal Front Microbiol

Specialty Microbiology

Date 2022 Jun 13

PMID 35694304

Authors

Giuseppe Pezzotti

Miyuki Kobara

Tamaki Nakaya

Hayata Imamura

Tenma Asai

Nao Miyamoto

Tetsuya Adachi

Toshiro Yamamoto

Narisato Kanamura

Eriko Ohgitani

Elia Marin

Wenliang Zhu

Ichiro Nishimura

Osam Mazda

Tetsuo Nakata

Koichi Makimura

Affiliations

Soon will be listed here.

Abstract

The multidrug-resistant often defies treatments and presently represents a worldwide public health threat. Currently, the ergosterol-targeting Amphotericin B (AmB) and the DNA/RNA-synthesis inhibitor 5-flucytosine (5-FC) are the two main drugs available for first-line defense against life-threatening infections. However, important aspects of their mechanisms of action require further clarification, especially regarding metabolic reactions of yeast cells. Here, we applied Raman spectroscopy empowered with specifically tailored machine-learning algorithms to monitor and to image the susceptibility of two clades to different antifungal drugs (LSEM 0643 or JCM15448T, belonging to the East Asian Clade II; and, LSEM 3673 belonging to the South African Clade III). Raman characterizations provided new details on the mechanisms of action against Clades II and III, while also unfolding differences in their metabolic reactions to different drugs. AmB treatment induced biofilm formation in both clades, but the formed biofilms showed different structures: a dense and continuous biofilm structure in Clade II, and an extra-cellular matrix with a "fluffy" and discontinuous structure in Clade III. Treatment with 5-FC caused no biofilm formation but yeast-to-hyphal or pseudo-hyphal morphogenesis in both clades. Clade III showed a superior capacity in reducing membrane permeability to the drug through chemically tailoring chitin structure with a high degree of acetylation and fatty acids networks with significantly elongated chains. This study shows the suitability of the Raman method in characterizing susceptibility and stress response of different clades to antifungal drugs, thus opening a path to identifying novel clinical solutions counteracting the spread of these alarming pathogens.

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