Ansell Brendan R E, Baker Louise, Emery Samantha J, McConville Malcolm J, Svärd Staffan G, Gasser Robin B, Jex Aaron R
Faculty of Veterinary and Agricultural Sciences, The University of Melbourne Melbourne, VIC, Australia.
Population Health and Immunity Division, Walter and Eliza Hall Institute of Medical Research Melbourne, VIC, Australia.
Front Microbiol. 2017 Mar 17;8:398. doi: 10.3389/fmicb.2017.00398. eCollection 2017.
is an intestinal parasite that causes 200-300 million episodes of diarrhoea annually. Metronidazole (Mtz) is a front-line anti-giardial, but treatment failure is common and clinical resistance has been demonstrated. Mtz is thought to be activated within the parasite by oxidoreductase enzymes, and to kill by causing oxidative damage. In , Mtz resistance involves active and passive mechanisms. Relatively low activity of iron-sulfur binding proteins, namely pyruvate:ferredoxin oxidoreductase (PFOR), ferredoxins, and nitroreductase-1, enable resistant cells to passively avoid Mtz activation. Additionally, low expression of oxygen-detoxification enzymes can allow passive (non-enzymatic) Mtz detoxification via futile redox cycling. In contrast, active resistance mechanisms include complete enzymatic detoxification of the pro-drug by nitroreductase-2 and enhanced repair of oxidized biomolecules via thioredoxin-dependent antioxidant enzymes. Molecular resistance mechanisms may be largely founded on reversible transcriptional changes, as some resistant lines revert to drug sensitivity during drug-free culture , or passage through the life cycle. To comprehensively characterize these changes, we undertook strand-specific RNA sequencing of three laboratory-derived Mtz-resistant lines, 106-2ID, 713-M3, and WB-M3, and compared transcription relative to their susceptible parents. Common up-regulated genes encoded variant-specific surface proteins (VSPs), a high cysteine membrane protein, calcium and zinc channels, a Mad-2 cell cycle regulator and a putative fatty acid α-oxidase. Down-regulated genes included nitroreductase-1, putative chromate and quinone reductases, and numerous genes that act proximal to PFOR. Transcriptional changes in 106-2ID diverged from those in 713-r and WB-r ( ≤ 0.2), which were more similar to each other ( = 0.47). In 106-2ID, a nonsense mutation in nitroreductase-1 transcripts could enhance passive resistance whereas increased transcription of nitroreductase-2, and a MATE transmembrane pump system, suggest active drug detoxification and efflux, respectively. By contrast, transcriptional changes in 713-M3 and WB-M3 indicated a higher oxidative stress load, attributed to Mtz- and oxygen-derived radicals, respectively. Quantitative comparisons of orthologous gene transcription between Mtz-resistant and , a closely related parasite, revealed changes in transcripts encoding peroxidases, heat shock proteins, and FMN-binding oxidoreductases, as prominent correlates of resistance. This work provides deep insight into Mtz-resistant , and illuminates resistance-associated features across parasitic species.
是一种肠道寄生虫,每年导致2亿至3亿次腹泻发作。甲硝唑(Mtz)是一线抗贾第虫药物,但治疗失败很常见,并且已证实存在临床耐药性。Mtz被认为在寄生虫体内由氧化还原酶激活,并通过造成氧化损伤来杀死寄生虫。在贾第虫中,Mtz耐药涉及主动和被动机制。铁硫结合蛋白,即丙酮酸:铁氧化还原蛋白氧化还原酶(PFOR)、铁氧化还原蛋白和硝基还原酶-1的活性相对较低,使耐药细胞能够被动避免Mtz激活。此外,氧解毒酶的低表达可通过无效的氧化还原循环实现被动(非酶促)Mtz解毒。相比之下,主动耐药机制包括硝基还原酶-2对前药的完全酶促解毒,以及通过硫氧还蛋白依赖性抗氧化酶增强对氧化生物分子的修复。分子耐药机制可能主要基于可逆的转录变化,因为一些耐药株在无药培养或通过生命周期时会恢复对药物的敏感性。为了全面表征这些变化,我们对三个实验室衍生的Mtz耐药株系106-2ID、713-M3和WB-M3进行了链特异性RNA测序,并将转录情况与其敏感亲本进行了比较。共同上调的基因编码变异特异性表面蛋白(VSPs)、一种高半胱氨酸膜蛋白、钙和锌通道、一种Mad-2细胞周期调节因子和一种假定的脂肪酸α-氧化酶。下调的基因包括硝基还原酶-1、假定的铬酸盐和醌还原酶,以及许多在PFOR近端起作用的基因。106-2ID中的转录变化与713-r和WB-r中的不同(≤0.2),而713-r和WB-r彼此更相似(=0.47)。在106-2ID中,硝基还原酶-1转录本中的无义突变可增强被动耐药性,而硝基还原酶-2转录增加以及一个多药和毒素排出(MATE)跨膜泵系统分别表明存在主动药物解毒和外排。相比之下,713-M3和WB-M3中的转录变化表明氧化应激负荷较高,分别归因于Mtz衍生的自由基和氧衍生的自由基。对Mtz耐药的贾第虫与密切相关的寄生虫进行直系同源基因转录的定量比较,揭示了编码过氧化物酶、热休克蛋白和FMN结合氧化还原酶的转录本变化,这些是耐药性的突出相关因素。这项工作深入洞察了Mtz耐药的贾第虫,并阐明了跨寄生虫物种的耐药相关特征。
