脱卤糖促进真菌的生物适应性

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS
Gabriela Delaqua Ribeiro, Luan de Holanda Paranhos, Elis Cristina Araujo Eleutherio
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引用次数: 0

摘要

三卤糖二糖在酵母和真菌应激生物学的多个方面发挥着至关重要的作用。在这里,我们评估了三卤糖的特性、细胞和生态生理作用、新陈代谢以及应激保护机制。我们整合了跨越这些主题的不同知识来源,并带来了有关三卤糖稳定生物大分子的机制以及如何调节三卤糖新陈代谢的新信息,从而使三卤糖在真菌中发挥多种作用,包括应激保护剂、碳水化合物储备和调节/信号分子。我们还介绍了有关三卤糖对微生物适应性的影响、微生物种群的复杂性和时空异质性的新发现,以及对应用真菌的工业流程的影响。在阐明参与三卤糖合成的酶的结构、催化机制和三卤糖合成调控的基础上,我们讨论了开发更高效杀真菌剂的前景。当前的人道主义危机,如人口过剩、全球变暖、营养不良、免疫力低下和使用免疫抑制剂等,使得人类病原体的发病率不断上升。此外,由于人类细胞和真菌细胞之间的生物化学性质相同,真菌感染很难治疗。然而巧合的是,哺乳动物并不合成树胶糖,这使得树胶糖合成成为开发新疗法的一个有趣靶点。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Trehalose promotes biological fitness of fungi
The disaccharide trehalose plays a crucial role in multiple facets of the stress biology of yeasts and fungi. Here, we evaluate the properties, cellular and ecophysiological roles, metabolism, and stress-protection mechanisms of trehalose. We integrate disparate sources of knowledge across these topics, and bring new information about the mechanisms by which trehalose stabilises biomacromolecules and how trehalose metabolism is regulated thus giving rise to its diverse roles in fungi including stress protector, carbohydrate reserve, and regulatory/signaling molecule. We also present new findings about the effect of trehalose on microbial adaptation, complexity and spatio-temporal heterogeneity of microbial populations, and implications for industrial processes that apply fungi. Based on the elucidation of the structures of enzymes involved in trehalose synthesis, their catalytic mechanisms, and the regulation of trehalose synthesis, we discuss prospects for the development of more-efficient fungicides. Current humanitarian crises, such as overpopulation, global warming, malnutrition, immunocompromised conditions, and usage of immunosuppressant drugs, are making the incidence of human pathogens increases. Furthermore, fungal infections can be difficult to treat due to the conserved biochemistry between human and fungi cells. Serendipitously, however, trehalose is not synthesised by mammals, which makes trehalose synthesis an interesting target for the development of new therapies.
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来源期刊
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
自引率
2.10%
发文量
464
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