水杨酸信号传导控制拟南芥防御蛋白加速细胞死亡6的成熟和定位。

Salicylic acid signaling controls the maturation and localization of the arabidopsis defense protein ACCELERATED CELL DEATH6.

作者信息

Zhang Zhongqin, Shrestha Jay, Tateda Chika, Greenberg Jean T

机构信息

Department of Molecular Genetics and Cell Biology, University of Chicago, 929 East 57 Street, GCIS W524, Chicago, IL 60637, USA.

出版信息

Mol Plant. 2014 Aug;7(8):1365-1383. doi: 10.1093/mp/ssu072. Epub 2014 Jun 12.

DOI:10.1093/mp/ssu072

PMID:24923602

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4168298/

Abstract

ACCELERATED CELL DEATH6 (ACD6) is a multipass membrane protein with an ankyrin domain that acts in a positive feedback loop with the defense signal salicylic acid (SA). This study implemented biochemical approaches to infer changes in ACD6 complexes and localization. In addition to forming endoplasmic reticulum (ER)- and plasma membrane (PM)-localized complexes, ACD6 forms soluble complexes, where it is bound to cytosolic HSP70, ubiquitinated, and degraded via the proteasome. Thus, ACD6 constitutively undergoes ER-associated degradation. During SA signaling, the soluble ACD6 pool decreases, whereas the PM pool increases. Similarly, ACD6-1, an activated version of ACD6 that induces SA, is present at low levels in the soluble fraction and high levels in the PM. However, ACD6 variants with amino acid substitutions in the ankyrin domain form aberrant, inactive complexes, are induced by a SA agonist, but show no PM localization. SA signaling also increases the PM pools of FLAGELLIN SENSING2 (FLS2) and BRI1-ASSOCIATED RECEPTOR KINASE 1 (BAK1). FLS2 forms complexes ACD6; both FLS2 and BAK1 require ACD6 for maximal accumulation at the PM in response to SA signaling. A plausible scenario is that SA increases the efficiency of productive folding and/or complex formation in the ER, such that ACD6, together with FLS2 and BAK1, reaches the cell surface to more effectively promote immune responses.

摘要

加速细胞死亡6（ACD6）是一种具有锚蛋白结构域的多次跨膜蛋白，它与防御信号水杨酸（SA）形成正反馈环发挥作用。本研究采用生化方法来推断ACD6复合物和定位的变化。除了形成定位于内质网（ER）和质膜（PM）的复合物外，ACD6还形成可溶性复合物，在其中它与胞质HSP70结合、泛素化并通过蛋白酶体降解。因此，ACD6持续经历内质网相关降解。在SA信号传导过程中，可溶性ACD6池减少，而质膜池增加。同样，诱导SA的ACD6激活版本ACD6-1在可溶部分中含量低，而在质膜中含量高。然而，在锚蛋白结构域中具有氨基酸取代的ACD6变体形成异常的无活性复合物，由SA激动剂诱导，但不显示质膜定位。SA信号传导还增加了鞭毛蛋白感应2（FLS2）和BRI1相关受体激酶1（BAK1）的质膜池。FLS2形成与ACD6的复合物；FLS2和BAK1都需要ACD6才能在响应SA信号时在质膜上最大程度地积累。一种合理的情况是，SA提高了内质网中有效折叠和/或复合物形成的效率，使得ACD6与FLS2和BAK1一起到达细胞表面，以更有效地促进免疫反应。

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