酵母杀伤毒素筛选为了解a/b毒素的进入、运输和杀伤机制提供了见解。

A yeast killer toxin screen provides insights into a/b toxin entry, trafficking, and killing mechanisms.

作者信息

Carroll Susheela Y, Stirling Peter C, Stimpson Helen E M, Giesselmann Esther, Schmitt Manfred J, Drubin David G

机构信息

Department of Molecular and Cell Biology, University of California, Berkeley, 16 Barker Hall, Berkeley, CA 94720, USA.

出版信息

Dev Cell. 2009 Oct;17(4):552-60. doi: 10.1016/j.devcel.2009.08.006.

DOI:10.1016/j.devcel.2009.08.006

PMID:19853568

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2768656/

Abstract

Like Ricin, Shiga, and Cholera toxins, yeast K28 is an A/B toxin that depends on endocytosis and retrograde trafficking for toxicity. Knowledge of the specific proteins, lipids, and mechanisms required for trafficking and killing by these toxins remains incomplete. Since K28 is a model for clinically relevant toxins, we screened over 5000 yeast mutants, identifying 365 that affect K28 sensitivity. Hypersensitive mutants revealed cytoprotective pathways, including stress-activated signaling and protein degradation. Resistant mutants clustered to endocytic, lipid organization, and cell wall biogenesis pathways. Furthermore, GPI anchors and transcriptional regulation are important for K28-cell binding. Strikingly, the AP2 complex, which in metazoans links endocytic cargo to the clathrin coat, but had no assigned function in yeast, was critical for K28 toxicity. Yeast AP2 localizes to endocytic sites and has a cargo-specific function in K28 uptake. This comprehensive genetic analysis identified conserved processes important for A/B toxin trafficking and killing.

摘要

与蓖麻毒素、志贺毒素和霍乱毒素一样，酵母K28是一种A/B毒素，其毒性依赖于内吞作用和逆向运输。关于这些毒素运输和杀伤所需的特定蛋白质、脂质及机制的了解仍不完整。由于K28是临床相关毒素的模型，我们筛选了5000多个酵母突变体，鉴定出365个影响K28敏感性的突变体。超敏突变体揭示了细胞保护途径，包括应激激活信号传导和蛋白质降解。抗性突变体聚集在内吞、脂质组织和细胞壁生物合成途径。此外，糖基磷脂酰肌醇（GPI）锚定和转录调控对K28与细胞的结合很重要。引人注目的是，在多细胞动物中连接内吞货物与网格蛋白包被但在酵母中未指定功能的AP2复合物对K28毒性至关重要。酵母AP2定位于内吞位点，在K28摄取中具有货物特异性功能。这项全面的遗传分析确定了对A/B毒素运输和杀伤重要的保守过程。

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