一种独特的分选连接蛋白通过PDZ结构域相互作用调节钾通道的运输。

A unique sorting nexin regulates trafficking of potassium channels via a PDZ domain interaction.

作者信息

Lunn Marie-Louise, Nassirpour Rounak, Arrabit Christine, Tan Joshua, McLeod Ian, Arias Carlos M, Sawchenko Paul E, Yates John R, Slesinger Paul A

机构信息

Peptide Biology Laboratory, The Salk Institute for Biological Studies, 10010 North Torrey Pines Rd., La Jolla, California 92037, USA.

出版信息

Nat Neurosci. 2007 Oct;10(10):1249-59. doi: 10.1038/nn1953. Epub 2007 Sep 2.

DOI:10.1038/nn1953

PMID:17828261

Abstract

G protein-gated potassium (Kir3) channels are important for controlling neuronal excitability in the brain. Using a proteomics approach, we have identified a unique rodent intracellular protein, sorting nexin 27 (SNX27), which regulates the trafficking of Kir3 channels. Like most sorting nexins, SNX27 possesses a functional PX domain that selectively binds the membrane phospholipid phosphatidylinositol-3-phosphate (PI3P) and is important for trafficking to the early endosome. SNX27, however, is the only sorting nexin to contain a PDZ domain. This PDZ domain discriminates between channels with similar class I PDZ-binding motifs, associating with the C-terminal end of Kir3.3 and Kir3.2c (-ESKV), but not with that of Kir2.1 (-ESEI) or Kv1.4 (-ETDV). SNX27 promotes the endosomal movement of Kir3 channels, leading to reduced surface expression, increased degradation and smaller Kir3 potassium currents. The regulation of endosomal trafficking via sorting nexins reveals a previously unknown mechanism for controlling potassium channel surface expression.

摘要

G蛋白门控钾通道（Kir3）对于控制大脑中的神经元兴奋性很重要。通过蛋白质组学方法，我们鉴定出一种独特的啮齿动物细胞内蛋白——分选连接蛋白27（SNX27），它调节Kir3通道的转运。与大多数分选连接蛋白一样，SNX27具有一个功能性PX结构域，该结构域可选择性结合膜磷脂磷脂酰肌醇-3-磷酸（PI3P），并且对于转运至早期内体很重要。然而，SNX27是唯一含有PDZ结构域的分选连接蛋白。该PDZ结构域可区分具有相似I类PDZ结合基序的通道，与Kir3.3和Kir3.2c（-ESKV）的C末端结合，但不与Kir2.1（-ESEI）或Kv1.4（-ETDV）的C末端结合。SNX27促进Kir3通道的内体移动，导致表面表达减少、降解增加以及Kir3钾电流减小。通过分选连接蛋白对内体转运的调节揭示了一种以前未知的控制钾通道表面表达的机制。

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一种独特的分选连接蛋白通过PDZ结构域相互作用调节钾通道的运输。

A unique sorting nexin regulates trafficking of potassium channels via a PDZ domain interaction.

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