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Volume 109, Issue 4, Pages (May 2002)

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1 Volume 109, Issue 4, Pages 523-535 (May 2002)
Molecular Architecture and Functional Model of the Endocytic AP2 Complex  Brett M. Collins, Airlie J. McCoy, Helen M. Kent, Philip R. Evans, David J. Owen  Cell  Volume 109, Issue 4, Pages (May 2002) DOI: /S (02)

2 Figure 1 Structure and Assembly of the AP2 Core
(A and B) Orthogonal views of the AP2 core shown in ribbon representation colored by subunit identity. α adaptin is colored from light blue (amino terminus) to dark blue (carboxyl terminus); β2 adaptin is light green (amino terminus) to dark green (carboxyl terminus) (the small C-terminal domain is colored cyan); N-terminal domain of μ2 adaptin (N-μ2) is dark purple; C-terminal domain of μ2 adaptin (C-μ2) is magenta; and σ2 is gold. D-myo-inositol-1,2,3,4,5,6-hexakisphosphate lies between α and μ2 in the crystal and is shown in sites on both subunits. The same color scheme is maintained throughout the other figures. The position of the linker between N-μ2 and C-μ2 is shown with dashed lines, and the disordered loop (223–239) of μ2 is shown dotted. The location of the Yxxφ binding site in C-μ2 is indicated by a black ellipse. (C) Individual subunits of the AP2 core. Assembly is shown by the curved arrows. Figures 1–3, 5, and 6 were created using Aesop (M.E.M. Noble, personal communication). Cell  , DOI: ( /S (02) )

3 Figure 2 Three-Dimensional Representation of the AP2 Core
(A) Stereo representation of the Cα atoms of AP2 core colored as in Figure 1, in the same orientation as Figure 1B. (B) Experimental electron density around σ2Trp19 with phases derived from MIR and MAD and improved by solvent flipping. The map includes structure factors to 2.9 Å resolution and is contoured at 0.3 e/Å3. (C) Stereo view of the IP6 binding site on the α subunit, with weighted difference electron density (mFo − DFc) calculated omitting the IP6 molecule from the model and contoured at 3σ. To reduce model bias, a small random shift (up to 0.2 Å) was applied to the coordinates, and the structure was rerefined before the map calculation. All the phosphate substituents are equatorial to the ring except the phosphate at the 2 position. Cell  , DOI: ( /S (02) )

4 Figure 3 Structural Homology of AP2 Subunits
(A) Comparison of α (blue) and β2 (green) trunk domains. The large subunits were positioned using the least squares superposition of σ2 (gold) and N-μ2 (magenta). The central parts coincide well, but α has an extra helix on the N terminus, forming the IP6 binding site, and the overall bend of the subunits is different. (B) Comparison of σ2 (gold) and N-μ2 (magenta). (C) Comparison of σ2 (gold) and Sec22p (blue). Cell  , DOI: ( /S (02) )

5 Figure 4 Subunit Interactions within the AP2 Core
(A) Surface representation of the AP2 core colored according to subunit (as in Figure 1), front (upper) and back (lower) views. (B) Surface representation of the individual AP2 subunits in the same orientations as in (A). Subunits are depicted in white, and patches where interactions occur are colored according to the subunit with which they interact. Areas that interact with α are colored blue, those that interact with β2 are green, those that interact with N-μ2 are dark purple, those that interact with C-μ2 are magenta, and those that interact with σ2 are gold. Interactions were calculated in GRASP, defined as a distance of less than 4 Å between the two molecular surfaces. Cell  , DOI: ( /S (02) )

6 Figure 5 The Structural Basis for Polyphosphatidyl Inositol Recognition (A) Schematic representation of the interactions between IP6 and side chains of α trunk from one AP2 and side chains from the μ2 subunit of another AP2 across a crystal contact. Dotted lines represent hydrogen bonds. The dashed line delineates residues from different AP2 molecules. (B) Location of the IP6 binding sites on the α trunk and on C-μ2. The viewpoints are the same as in the rest of the figure. (C and D) Binding site for IP6 at the amino terminus of α shown as a surface representation colored according to electrostatic potential (C) and showing the details of the side chain interactions between IP6 and α (D). (E and F) Binding site for IP6 on the upper surface of C-μ2 shown as a surface representation colored according to electrostatic potential (E) and showing the details of the side chain interactions between IP6 and C-μ2 (F). Cell  , DOI: ( /S (02) )

7 Figure 6 Binding Site for the Endocytic Motif Yxxφ
(A) The binding site for Yxxφ peptides (pale gray) on C-μ2 (magenta) is blocked by the portions of the β2 subunit (green). The peptide DYQRLN is drawn in the position it occupies in the complex with the isolated C-μ2 domain (Owen and Evans 1998). β2Val365 fills the pocket for the φ (L) residue of the peptide, and β2Tyr405 replaces the main chain of the Y+1 residue. (B) Details of the pocket that would bind the tyrosine side chain of the Yxxφ peptide. The position that would be assumed by the hydroxyl group of the peptide's tyrosine side chain is taken by a water molecule (red sphere) hydrogen bonded to μ2D176. (C) Structure of isolated C-μ2 (shown in ribbon representation colored in purple) bound to Yxxφ peptide for comparison (shown with carbon atoms in white). The side chains of μ2F174, μ2D176, μ2K203, and μ2R423 have moved little compared to the unliganded structure (B), indicating that this binding pocket for tyrosine is preformed. There is little electron density for μ2W421 in the unliganded structure of the AP2 core, indicating that this residue becomes ordered on Yxxφ peptide binding. Cell  , DOI: ( /S (02) )

8 Figure 7 Schematic Representation of a Model for AP2 Function
(A) The closed conformation as observed in the crystal. The semicircular face of AP2 core binds to the membrane via the phosphoinositide (PPI) site at the N terminus of α, which has been shown to be crucial for AP2 recruitment. The Yxxφ site on C-μ2 is inaccessible. The PPI site on C-μ2 is on the perpendicular face of the core and cannot interact with the membrane. (B) A conformational change triggered by phosphorylation of μ2Thr156 and the presence of the membrane allows C-μ2 to bind cargo via its Yxxφ motif, and allows both PPI sites to interact with the membrane. Cell  , DOI: ( /S (02) )

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