Metarhizium spp. encode an ochratoxin cluster and a high efficiency ochratoxin-degrading amidohydrolase revealed by genomic analysis.

Gang Wang, Wenqing Wu, Nancy P Keller, Xu Guo, Erfeng Li, Junning Ma, Fuguo Xing
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Abstract

Introduction: Ochratoxins (OTs) are worldwide regulated mycotoxins contaminating a variety of food-environment and agro-environment. Several Aspergillus and Pencillium species synthesize OTs from a six-gene biosynthetic gene cluster (BGC) to produce the highly toxic final product OTA. Although many studies on OTA-degrading enzymes were performed, high efficiency enzymes with strong stability are extremely needed, and the OTA degrading mechanism is poorly understood.

Objectives: The study aimed to explore the OT-degradation enzyme and investigate its degradation mechanisms in Metarhizium, which contain an OT biosynthetic gene cluster.

Methods: Phylogenomic relationship combined with RNA expression analysis were used to explore the distribution of OT BGC in fungi. Bioactivity-guided isolation and protein mass spectrometry were conducted to trace the degrading enzymes in Metarhizium spp., and the enzymes were heterologously expressed in E. coli and verified by in vitro assays. Structure prediction and point mutation were performed to reveal the catalytic mechanism of MbAmh1.

Results: Beyond Aspergillus and Pencillium species, three species of the distant phylogenetic taxon Metarhizium contain an expressed OT-like BGC but lack an otaD gene. Unexpectedly, no OT BGC products were found in some Metarhizium species. Instead, Metarhizium metabolized both OTA and OTB to their non-toxic degradation products. This activity of M. brunneum was attributed to an intracellular hydrolase MbAmh1, which was tracked by bioactivity-guided proteomic analysis combined with in vitro reaction. Recombinant MbAmh1 (5 μg/mL) completely degraded 1 μg/mL OTA within 3 min, demonstrating a strong degrading ability towards OTA. Additionally, MbAmh1 showed considerable temperature adaptability ranging from 30 to 70 °C and acidic pH stability ranging from 4.0 to 7.0. Identification of active sites supported the crucial role of metal iron for this enzymatic reaction.

Conclusion: These findings reveal different patterns of OT synthesis in fungi and provide a potential OTA degrading enzyme for industrial applications.

通过基因组分析发现,水霉菌属编码一种赭曲霉毒素簇和一种高效的赭曲霉毒素降解酰胺水解酶。
导言:赭曲霉毒素(OTs)是受世界各国管制的霉菌毒素,污染了各种食品环境和农业环境。几种曲霉和青霉菌通过六基因生物合成基因簇(BGC)合成 OTs,产生剧毒的最终产物 OTA。虽然对 OTA 降解酶进行了许多研究,但仍极需高效且稳定性强的酶,而且对 OTA 降解机制的了解也很少:本研究旨在探索含有 OT 生物合成基因簇的 Metarhizium 中的 OT 降解酶并研究其降解机制:方法:采用系统发生组学关系结合RNA表达分析,探讨OT生物合成基因簇在真菌中的分布。通过生物活性引导分离和蛋白质质谱分析,追踪 Metarhizium 属真菌中的降解酶,并在大肠杆菌中进行异源表达和体外实验验证。通过结构预测和点突变揭示了MbAmh1的催化机理:结果:除曲霉和青霉外,远源系统发育类群 Metarhizium 的三个菌种含有表达的 OT 样 BGC,但缺乏 otaD 基因。出乎意料的是,在一些 Metarhizium 物种中没有发现 OT BGC 产物。相反,梅塔利虫将 OTA 和 OTB 代谢为无毒的降解产物。布氏杆菌的这种活性归因于一种细胞内水解酶 MbAmh1,这种水解酶是通过生物活性引导的蛋白质组分析结合体外反应追踪到的。重组 MbAmh1(5 μg/mL)在 3 分钟内完全降解了 1 μg/mL OTA,显示了对 OTA 的强大降解能力。此外,MbAmh1 还表现出相当强的温度适应性(30 至 70 °C)和酸性 pH 稳定性(4.0 至 7.0)。活性位点的鉴定支持了金属铁在该酶促反应中的关键作用:这些发现揭示了真菌合成 OT 的不同模式,并为工业应用提供了一种潜在的 OTA 降解酶。
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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