Flavofun: Exploration of fungal flavoproteomes

Frontiers in catalysis Pub Date : 2022-12-14 DOI:10.3389/fctls.2022.1021691

Bianca Kerschbaumer, A. Bijelic, P. Macheroux

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Abstract

Fungi produce a plethora of natural products exhibiting a fascinating diversity of chemical structures with an enormous potential for medical applications. Despite the importance of understanding the scope of natural products and their biosynthetic pathways, a systematic analysis of the involved enzymes has not been undertaken. In our previous studies, we examined the flavoprotein encoding gene pool in archaea, eubacteria, the yeast Saccharomyces cerevisiae, Arabidopsis thaliana, and Homo sapiens. In the present survey, we have selected the model fungus Neurospora crassa as a starting point to investigate the flavoproteomes in the fungal kingdom. Our analysis showed that N. crassa harbors 201 flavoprotein-encoding genes amounting to 2% of the total protein-encoding genome. The majority of these flavoproteins (133) could be assigned to primary metabolism, termed the “core flavoproteome”, with the remainder of flavoproteins (68) serving in, as yet unidentified, reactions. The latter group of “accessory flavoproteins” is dominated by monooxygenases, berberine bridge enzyme-like enzymes, and glucose-methanol-choline-oxidoreductases. Although the exact biochemical role of most of these enzymes remains undetermined, we propose that they are involved in activities closely associated with fungi, such as the degradation of lignocellulose, the biosynthesis of natural products, and the detoxification of harmful compounds in the environment. Based on this assumption, we have analyzed the accessory flavoproteomes in the fungal kingdom using the MycoCosm database. This revealed large differences among fungal divisions, with Ascomycota, Basidiomycota, and Mucoromycota featuring the highest average number of genes encoding accessory flavoproteins. Moreover, a more detailed analysis showed a massive accumulation of accessory flavoproteins in Sordariomycetes, Agaricomycetes, and Glomeromycotina. In our view, this indicates that these fungal classes are proliferative producers of natural products and also interesting sources for flavoproteins with potentially useful catalytic properties in biocatalytic applications.

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Flavofun:真菌黄素蛋白质组的探索

真菌产生大量的天然产物，表现出迷人的化学结构多样性，具有巨大的医疗应用潜力。尽管了解天然产物的范围及其生物合成途径很重要，但尚未对相关酶进行系统分析。在我们之前的研究中，我们检测了古菌、真细菌、酿酒酵母、拟南芥和智人中编码黄素蛋白的基因库。在本次调查中，我们选择了模式真菌粗糙神经孢菌作为研究真菌界风味蛋白质组的起点。我们的分析表明，N.crassa含有201个黄蛋白编码基因，占总蛋白编码基因组的2%。这些黄蛋白中的大多数（133）可以被分配到初级代谢，称为“核心黄蛋白组”，其余的黄蛋白（68）参与尚未确定的反应。后一组“副黄素蛋白”主要由单加氧酶、黄连素桥酶样酶和葡萄糖-甲醇-胆碱氧化还原酶组成。尽管这些酶中大多数的确切生化作用尚未确定，但我们认为它们参与了与真菌密切相关的活动，如木质纤维素的降解、天然产物的生物合成以及环境中有害化合物的解毒。基于这一假设，我们使用Mycosm数据库分析了真菌王国中的附属风味蛋白质组。这揭示了真菌分支之间的巨大差异，子囊菌门、担子菌门和毛霉菌门的编码辅助黄素蛋白的基因平均数最高。此外，更详细的分析显示，副黄素蛋白在Sordariomycetes、Agaricomyces和Glomeromycotina中大量积累。在我们看来，这表明这些真菌类是天然产物的增殖生产者，也是在生物催化应用中具有潜在有用催化性能的黄素蛋白的有趣来源。

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Frontiers in catalysis

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