Mitra A K, McCarthy M P, Stroud R M
S-960 Department of Biochemistry and Biophysics, University of California, San Francisco 94143-0048.
J Cell Biol. 1989 Aug;109(2):755-74. doi: 10.1083/jcb.109.2.755.
The three-dimensional structure of the nicotinic acetylcholine receptor (AChR) from Torpedo californica, crystallized both before and after removal of associated proteins, most notably the main 43-kD cytoskeletal protein that interacts both with AChR and actin, is determined to a resolution of 22 A. This is the first structural analysis where the 43-kD protein has been removed from the sample before crystallization. Thus, it provides the most reliable assessment of what constitutes the structure of the minimal five subunit AChR complex, and, by comparison with the native membrane, of the location of the 43-kD cytoskeletal protein. Image reconstruction of two-dimensional crystals includes information from electron images of up to +/- 52 degrees tilted specimens of latticed AChR. Hybrid density maps that include x-ray diffraction perpendicular to the membrane to 12.5 A resolution were used and eliminate some of the distortions introduced in maps based only on electron microscopic analyses. Comparison of the difference Fourier density maps between AChR with its normal complement of associated proteins, and without them shows that the main density, assigned to the actin-binding 43-kD component is closely associated with the lipid bilayer as well as with the cytoplasmic domain of the AChR. It binds beside the AChR, not beneath it as suggested by others (C. Toyoshima and N. Unwin 1988. Nature [Lond.]. 336:237-240). There is good agreement between the volumes of density for structural components and expected volumes based on their molecular weight. Acetylcholine receptors aggregate in the absence of any cytoskeletal proteins, suggesting that the AChR alone is sufficient to encode and stabilize clustering, and perhaps to do so during synaptogenesis. The main 43-kD component may play a role in location and rate of association of AChR. We show that the disulfide bond that cross-links delta-delta chains of adjacent pentamers in about 80% of AChR, is not required to stabilize the lattice of AChR. Latticed tube structures are stable indefinitely. The lattices described here have 20% less volume of lipid than those originally obtained and characterized by J. Kistler and R. M. Stroud (1981. Proc. Natl. Acad. Sci. USA. 78:3678-3682), or those subsequently characterized by A. Brisson and P. N. T. Unwin (1984. J. Cell Biol. 99:1202-1211) and A. Brisson and P. N. T. Unwin (1985. Nature (Lond.). 315:474-477).
加州电鳐的烟碱型乙酰胆碱受体(AChR)在去除相关蛋白前后均进行了结晶,其中最显著的是与AChR和肌动蛋白都相互作用的43-kD主要细胞骨架蛋白,其三维结构已确定至22 Å的分辨率。这是首次在结晶前从样品中去除43-kD蛋白的结构分析。因此,它提供了对构成最小的五聚体AChR复合物结构的最可靠评估,并通过与天然膜比较,确定了43-kD细胞骨架蛋白的位置。二维晶体的图像重建包括来自晶格状AChR倾斜高达±52度的标本的电子图像信息。使用了包括垂直于膜至12.5 Å分辨率的X射线衍射的混合密度图,消除了仅基于电子显微镜分析的图中引入的一些畸变。比较有正常相关蛋白补充的AChR和没有这些蛋白的AChR之间的差分傅里叶密度图表明,分配给肌动蛋白结合43-kD成分的主要密度与脂质双层以及AChR的细胞质结构域紧密相关。它结合在AChR旁边,而不是像其他人所建议的那样在其下方(C. Toyoshima和N. Unwin,1988年。《自然》[伦敦]。336:237 - 240)。结构成分的密度体积与基于其分子量的预期体积之间有很好的一致性。乙酰胆碱受体在没有任何细胞骨架蛋白的情况下聚集,这表明单独的AChR足以编码和稳定聚集,也许在突触发生过程中也是如此。主要的43-kD成分可能在AChR的定位和结合速率中起作用。我们表明,在约80%的AChR中交联相邻五聚体的δ-δ链的二硫键对于稳定AChR晶格不是必需的。晶格状管状结构无限期稳定。这里描述的数据比最初由J. Kistler和R. M. Stroud(1981年。《美国国家科学院院刊》。78:3678 - 3682)获得并表征的数据,或随后由A. Brisson和P. N. T. Unwin(1984年。《细胞生物学杂志》。99:1202 - 1211)以及A. Brisson和P.N.T. Unwin(1985年。《自然》[伦敦]。315:474 - 477)表征的数据的脂质体积少20%。