膜曲率
膜
小泡
复印机
高尔基体
GTP酶
化学
两亲性
GTP'
生物物理学
生物化学
结晶学
生物
酶
分泌途径
内质网
有机化学
聚合物
共聚物
作者
Bruno Mesmin,Guillaume Drin,Sharon Levi,Moran Rawet,Dan Cassel,Joëlle Bigay,Bruno Antonny
出处
期刊:Biochemistry
[American Chemical Society]
日期:2007-01-25
卷期号:46 (7): 1779-1790
被引量:116
摘要
ArfGAP1 (Arf GTPase activating protein 1) controls the cycling of the COPI coat on Golgi membranes by catalyzing GTP hydrolysis in the small G protein Arf1. ArfGAP1 contains a central motif named ALPS (ArfGAP1 lipid-packing sensor) that adsorbs preferentially onto highly curved membranes. This motif allows coupling of the rate of GTP hydrolysis in Arf1 with membrane curvature induced by the COPI coat. Upon membrane adsorption, the ALPS motif folds into an amphipathic alpha-helix. This helix contrasts from a classical membrane-adsorbing helix in the abundance of S and T residues and the paucity of charged residues in its polar face. We show here that ArfGAP1 contains a second motif with similar physicochemical properties. This motif, ALPS2, also forms an amphipathic alpha-helix at the surface of small vesicles and contributes to the Golgi localization of ArfGAP1 in vivo. Using several quantitative assays, we determined the relative contribution of the two ALPS motifs in the recognition of liposomes of defined curvature and composition. Our results show that ALPS1 is the primary determinant of the interaction of ArfGAP1 with lipid membranes and that ALPS2 reinforces this interaction 40-fold. Furthermore, our results suggest that depending on the engagement of one or two functional ALPS motifs, ArfGAP1 can respond to a wide range of membrane curvature and can adapt to lipid membranes of various acyl chain compositions.
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