了解对氟康唑的适应性：对白色念珠菌和热带念珠菌耐受性及耐药性的比较性见解。

Understanding adaptation to fluconazole: comparative insights into tolerance and resistance in and .

作者信息

Zheng Lijun, Dong Yubo, Wang Jing, Jia Yonghui, Wang Weifang, Xu Yi, Guo Liangsheng

机构信息

Department of Ultrasound Medicine, The Second Affiliated Hospital of Soochow University, Suzhou, China.

Department of Pharmacy, The 960th Hospital of PLA, Jinan, China.

出版信息

Front Cell Infect Microbiol. 2025 May 5;15:1519323. doi: 10.3389/fcimb.2025.1519323. eCollection 2025.

DOI:10.3389/fcimb.2025.1519323

PMID:40391048

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC12086170/

Abstract

INTRODUCTION

Antifungal resistance and tolerance are distinct responses exhibited by fungi when exposed to drugs. While considerable research has focused on azole tolerance in the human pathogen , studies in other fungal species remain limited.

OBJECTIVE

This study aims to conduct a comparative investigation of the adaptation of the model organism and to fluconazole .

METHODS

We performed experiments using laboratory strains of and to evaluate their fluconazole tolerance and resistance under varying temperature conditions. High concentrations of fluconazole were administered, and subsequent changes in fungal phenotypes were analyzed through techniques such as transcriptome analysis and monitoring of petite formation.

RESULTS

Our results revealed that fluconazole tolerance is present in wild-type strains of and is influenced by temperature, albeit in a manner opposite to that observed in . Importantly, when subjected to high concentrations of fluconazole, strains developed resistance without displaying tolerance; all resistant adaptors identified were petites. Chemical induction of petite formation led to an increase in resistance accompanied by a decrease in tolerance.

CONCLUSION

Transcriptome analysis indicated that petites up-regulated efflux mechanisms while down-regulating most genes. This suggests that, unlike petite-negative , petite-positive swiftly transitions to a petite phenotype upon exposure to fluconazole, resulting in enhanced resistance but diminished tolerance. This evolutionary divergence emphasizes the need for additional studies on fluconazole tolerance in other pathogenic fungi.

摘要

引言

抗真菌耐药性和耐受性是真菌在接触药物时表现出的不同反应。虽然大量研究聚焦于人类病原体中的唑类耐受性，但对其他真菌物种的研究仍然有限。

目的

本研究旨在对模式生物[具体物种1]和[具体物种2]对氟康唑的适应性进行比较研究。

方法

我们使用[具体物种1]和[具体物种2]的实验室菌株进行实验，以评估它们在不同温度条件下对氟康唑的耐受性和耐药性。给予高浓度的氟康唑，随后通过转录组分析和小菌落形成监测等技术分析真菌表型的变化。

结果

我们的结果表明，[具体物种1]的野生型菌株存在氟康唑耐受性，且受温度影响，尽管其方式与[具体物种2]中观察到的相反。重要的是，当[具体物种1]菌株暴露于高浓度氟康唑时，它们产生了耐药性但未表现出耐受性；所有鉴定出的耐药适应株都是小菌落。化学诱导小菌落形成导致耐药性增加，同时耐受性降低。

结论

转录组分析表明，小菌落上调了外排机制，同时下调了大多数[相关基因]。这表明，与小菌落阴性的[具体物种2]不同，小菌落阳性的[具体物种1]在接触氟康唑后迅速转变为小菌落表型，导致耐药性增强但耐受性降低。这种进化差异强调了对其他致病真菌中氟康唑耐受性进行更多研究的必要性。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/c4ff/12086170/04edd7f45eaf/fcimb-15-1519323-g001.jpg

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了解对氟康唑的适应性：对白色念珠菌和热带念珠菌耐受性及耐药性的比较性见解。

Understanding adaptation to fluconazole: comparative insights into tolerance and resistance in and .

作者信息

Zheng Lijun, Dong Yubo, Wang Jing, Jia Yonghui, Wang Weifang, Xu Yi, Guo Liangsheng

机构信息

Department of Ultrasound Medicine, The Second Affiliated Hospital of Soochow University, Suzhou, China.

Department of Pharmacy, The 960th Hospital of PLA, Jinan, China.