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首页> 外文期刊>Antimicrobial agents and chemotherapy. >Fungal Zn(II)(2)Cys(6) Transcription Factor ADS-1 Regulates Drug Efflux and Ergosterol Metabolism under Antifungal Azole Stress
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Fungal Zn(II)(2)Cys(6) Transcription Factor ADS-1 Regulates Drug Efflux and Ergosterol Metabolism under Antifungal Azole Stress

机译:真菌Zn(ii)(2)Cys(6)转录因子ADS-1调节抗真菌唑胁迫下的药物流渗和埃尔格瑟醇代谢

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Antifungal azoles are the most widely used antifungal drugs in clinical and agricultural practice. Fungi can mount adaptive responses to azole stress by modifying the transcript levels of many genes, and the responsive mechanisms to azoles are the basis for fungi to develop azole resistance. In this study, we identified a new Zn(II)(2)Cys(6) transcription factor, ADS-1, with a positive regulatory function in transcriptional responses to azole stress in the model filamentous fungal species Neurospora crassa. Under ketoconazole (KTC) stress, the ads-1 transcript level was significantly increased in N. crassa. Deletion of ads-1 increased susceptibility to different azoles, while its overexpression increased resistance to these azoles. The cdr4 gene, which encodes the key azole efflux pump, was positively regulated by ADS-1. Deletion of ads-1 reduced the transcriptional response by cdr4 to KTC stress and increased cellular KTC accumulation under KTC stress, while ads-1 overexpression had the opposite effect. ADS-1 also positively regulated the transcriptional response by erg11, which encodes the azole target lanosterol 14 alpha- demethylase for ergosterol biosynthesis, to KTC stress. After KTC treatment, the ads-1 deletion mutant had less ergosterol but accumulated more lanosterol than the wild type, while ads-1 overexpression had the opposite effect. Homologs of ADS-1 are widely present in filamentous fungal species of Ascomycota but not in yeasts. Deletion of the gene encoding an ADS-1 homolog in Aspergillus flavus also increased susceptibility to KTC and itraconazole (ITZ). Besides, deletion of A. flavus ads-1 (Afads-1) significantly reduced the transcriptional responses by genes encoding homologs of CDR4 and ERG11 in A. flavus to KTC stress, and the deletion mutant accumulated more KTC but less ergosterol. Taken together, these findings demonstrate that the function and regulatory mechanism of ADS-1 homologs among different fungal species in azole responses and the basal resistance of azoles are highly conserved.
机译:抗真菌唑类药物是临床和农业实践中应用最广泛的抗真菌药物。真菌可以通过改变许多基因的转录水平对唑类药物产生适应性反应,对唑类药物的反应机制是真菌产生唑类药物抗性的基础。在本研究中,我们鉴定了一种新的Zn(II)(2)Cys(6)转录因子ADS-1,在模式丝状真菌粗糙脉孢菌对唑胁迫的转录反应中具有正调节功能。在酮康唑(KTC)胁迫下,粗糙褐飞虱的ads-1转录水平显著升高。ads-1的缺失增加了对不同唑类药物的敏感性,而其过度表达增加了对这些唑类药物的耐药性。编码关键唑外排泵的cdr4基因受到ADS-1的正调控。ads-1的缺失降低了cdr4对KTC胁迫的转录反应,并增加了KTC胁迫下的细胞KTC积累,而ads-1的过度表达则具有相反的效果。ADS-1还积极调节erg11对KTC胁迫的转录反应,erg11编码用于麦角甾醇生物合成的唑靶羊毛甾醇14α-去甲基酶。KTC处理后,ads-1缺失突变体的麦角甾醇含量低于野生型,但积累了更多的羊毛甾醇,而ads-1过表达则产生相反的效果。ADS-1的同系物广泛存在于子囊菌纲的丝状真菌物种中,但不存在于酵母中。黄曲霉中编码ADS-1同源物的基因缺失也增加了对KTC和伊曲康唑(ITZ)的易感性。此外,黄曲霉ads-1(Afads-1)的缺失显著降低了黄曲霉CDR4和ERG11同源基因对KTC胁迫的转录反应,缺失突变体积累了更多的KTC,但麦角甾醇较少。综上所述,这些研究结果表明,不同真菌物种之间的ADS-1同源物在唑类药物应答中的功能和调节机制以及唑类药物的基本耐药性是高度保守的。

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