Determinants of fluconazole resistance and the efficacy of fluconazole and milbemycin oxim combination against Candida parapsilosis clinical isolates from Brazil and Turkey.

IF 2.1 Q3 MYCOLOGY
Frontiers in fungal biology Pub Date : 2022-07-28 eCollection Date: 2022-01-01 DOI:10.3389/ffunb.2022.906681
Farnaz Daneshnia, Süleyha Hilmioğlu Polat, Macit Ilkit, Erika Shor, João Nobrega de Almeida Júnior, Larissa M Favarello, Arnaldo Lopes Colombo, Amir Arastehfar, David S Perlin
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引用次数: 2

Abstract

Fluconazole-resistant Candida parapsilosis (FLZR-CP) outbreaks are a growing public health concern and have been reported in numerous countries. Patients infected with FLZR-CP isolates show fluconazole therapeutic failure and have a significantly increased mortality rate. Because fluconazole is the most widely used antifungal agent in most regions with outbreaks, it is paramount to restore its antifungal activity. Milbemycin oxim (MOX), a well-known canine endectocide, is a potent efflux pump inhibitor that significantly potentiates the activity of fluconazole against FLZR C. glabrata and C. albicans. However, the FLZ-MOX combination has not been tested against FLZR-CP isolates, nor is it known whether MOX may also potentiate the activity of echinocandins, a different class of antifungal drugs. Furthermore, the extent of involvement of efflux pumps CDR1 and MDR1 and ergosterol biosynthesis enzyme ERG11 and their link with gain-of-function (GOF) mutations in their transcription regulators (TAC1, MRR1, and UPC2) are poorly characterized among FLZR-CP isolates. We analyzed 25 C. parapsilosis isolates collected from outbreaks in Turkey and Brazil by determining the expression levels of CDR1, MDR1, and ERG11, examining the presence of potential GOF mutations in their transcriptional regulators, and assessing the antifungal activity of FLZ-MOX and micafungin-MOX against FLZR and multidrug-resistant (MDR) C. parapsilosis isolates. ERG11 was found to be universally induced by fluconazole in all isolates, while expression of MDR1 was unchanged. Whereas mutations in MRR1 and UPC2 were not detected, CDR1 was overexpressed in three Brazilian FLZR-CP isolates, which also carried a novel TAC1L518F mutation. Of these three isolates, one showed increased basal expression of CDR1, while the other two overexpressed CDR1 only in the presence of fluconazole. Interestingly, MOX showed promising antifungal activity against FLZR isolates, reducing the FLZ MIC 8- to 32-fold. However, the MOX and micafungin combination did not exert activity against an MDR C. parapsilosis isolate. Collectively, our study documents that the mechanisms underpinning FLZR are region specific, where ERG11 mutations were the sole mechanism of FLZR in Turkish FLZR-CP isolates, while simultaneous overexpression of CDR1 was observed in some Brazilian counterparts. Moreover, MOX and fluconazole showed potent synergistic activity, while the MOX-micafungin combination showed no synergy.

Abstract Image

氟康唑耐药性的决定因素以及氟康唑和米尔贝霉素-奥辛联合用药对巴西和土耳其副psilosis念珠菌临床分离株的疗效。
氟康唑耐药性副psilosis念珠菌(FLZR-CP)疫情是一个日益严重的公共卫生问题,在许多国家都有报道。感染FLZR-CP分离株的患者表现出氟康唑治疗失败,死亡率显著增加。由于氟康唑是大多数疫情暴发地区使用最广泛的抗真菌药物,因此恢复其抗真菌活性至关重要。Milbemycin oxim(MOX)是一种著名的犬类杀虫剂,是一种有效的外排泵抑制剂,可显著增强氟康唑对光滑念珠菌和白色念珠菌的活性。然而,FLZ-MOX组合尚未针对FLZR-CP分离株进行测试,也不知道MOX是否也可以增强棘白菌素(一种不同类型的抗真菌药物)的活性。此外,在FLZR-CP分离株中,外排泵CDR1和MDR1以及麦角甾醇生物合成酶ERG11的参与程度及其与转录调节因子(TAC1、MRR1和UPC2)中的功能获得(GOF)突变的联系特征较差。我们通过测定CDR1、MDR1和ERG11的表达水平,检测其转录调控因子中潜在GOF突变的存在,并评估FLZ-MOX和米卡芬菌素MOX对FLZR和耐多药(MDR)副psilosis分离株的抗真菌活性,分析了从土耳其和巴西疫情中收集的25个副psilossis分离株。ERG11在所有分离株中均被氟康唑普遍诱导,而MDR1的表达没有变化。虽然没有检测到MRR1和UPC2的突变,但CDR1在三个巴西FLZR-CP分离株中过表达,该分离株也携带新的TAC1L518F突变。在这三个分离株中,一个显示CDR1的基础表达增加,而另外两个仅在氟康唑存在下过表达CDR1。有趣的是,MOX对FLZR分离株显示出良好的抗真菌活性,将FLZ MIC降低了8至32倍。然而,MOX和米卡芬净的组合对耐多药的副psilosis分离株没有发挥活性。总之,我们的研究表明,支持FLZR的机制是区域特异性的,其中ERG11突变是土耳其FLZR-CP分离株中FLZR唯一的机制,而在一些巴西分离株中观察到CDR1同时过表达。此外,MOX和氟康唑显示出强大的协同活性,而MOX-米卡芬净组合没有显示出协同作用。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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