真菌感染期间维持吞噬体完整性:生存还是死亡?

IF 4.1 3区 生物学 Q2 CELL BIOLOGY Microbial Cell Pub Date : 2020-12-03 DOI:10.15698/mic2020.12.738
Mabel Yang, Glenn F W Walpole, Johannes Westman
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引用次数: 2

摘要

专业吞噬细胞通过其特殊的进食、饮水和消化细胞外环境物质的能力,代表了先天免疫和组织稳态的关键节点。吞噬细胞的降解和杀微生物功能依赖于溶酶体与吞噬体等内体腔室的融合,导致内化猎物和碎片的消化和再循环。尽管有这些努力,一些特别危险的感染是由一类顽强的病原体引起的,它们抵抗消化,通常在吞噬体膜的范围内存活甚至增殖。其中一个例子是白色念珠菌,它是一种共生多态真菌,在50%的人群中定植,可在免疫功能低下的患者中引起危及生命的感染。白色念珠菌不仅能在吞噬体内存活,而且被巨噬细胞吞噬后,会触发酵母到菌丝的转变,促进吞噬体内的快速生长(每小时几微米),同时对真菌周围的吞噬体膜造成巨大的机械负担。保存膜的完整性对于维持吞噬体的敌对内部环境,降解酶和氧化应激的功能至关重要。然而,生物膜如吞噬体的拉伸能力有限。利用白色念珠菌作为细胞内病原体的模型,我们最近的工作揭示了吞噬体通过扩大其表面积来响应吞噬体内病原体生长的机制,从而维持吞噬体膜的完整性。我们假设这种扩张可能是由外来来源的膜与吞噬体的传递和融合促进的。一致地,巨噬细胞通过拉伸诱导的吞噬体钙释放来响应酵母到菌丝的转变,导致溶酶体的招募和插入,以适应吞噬体的扩张并保持其完整性。下面,我们将讨论溶酶体插入作为避免吞噬体破裂手段的钙依赖机制。此外,我们通过关注真菌应激反应、营养获取、炎性体激活和细胞死亡来研究膜完整性对宿主和病原体之间微妙平衡的影响。
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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Maintaining phagosome integrity during fungal infection: do or die?

Professional phagocytes represent a critical node in innate immunity and tissue homeostasis through their specialized ability to eat, drink, and digest material from the extracellular milieu. The degradative and microbicidal functions of phagocytes rely on the fusion of lysosomes with endosomal compartments such as phagosomes, resulting in the digestion and recycling of internalized prey and debris. Despite these efforts, several particularly dangerous infections result from a class of tenacious pathogens that resist digestion, often surviving and even proliferating within the confines of the phagosomal membrane. One such example, Candida albicans, is a commensal polymorphic fungus that colonizes ~50% of the population and can cause life-threatening infections in immunocompromised patients. Not only can C. albicans survive within phagosomes, but its ingestion by macropahges triggers a yeast-to-hyphal transition promoting rapid intraphagosomal growth (several microns per hour) while imposing a substantial mechanical burden on the phagosomal membrane surrounding the fungus. Preservation of membrane integrity is essential to maintain the hostile internal environment of the phagosome, a functionality of degradative enzymes and oxidative stress. Yet, biological membranes such as phagosomes have a limited capacity to stretch. Using C. albicans as a model intracellular pathogen, our recent work reveals a mechanism by which phagosomes respond to intraphagosomal growth of pathogens by expanding their surface area, and as a result, maintain the integrity of the phagosomal membrane. We hypothesized that this expansion would be facilitated by the delivery and fusion of membrane from extraneous sources with the phagosome. Consistently, macrophages respond to the yeast-to-hyphal transition through a stretch-induced release of phagosomal calcium, leading to recruitment and insertion of lysosomes that accommodate the expansion of the phagolysosome and preserve its integrity. Below, we discuss this calcium-dependent mechanism of lysosome insertion as a means of avoiding phagosomal rupture. Further, we examine the implications of membrane integrity on the delicate balance between the host and pathogen by focusing on fungal stress responses, nutrient acquisition, inflammasome activation, and cell death.

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来源期刊
Microbial Cell
Microbial Cell Multiple-
CiteScore
6.40
自引率
0.00%
发文量
32
审稿时长
12 weeks
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