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PDBsum entry 1qtp
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Membrane protein
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PDB id
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1qtp
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Contents |
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* Residue conservation analysis
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DOI no:
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Proc Natl Acad Sci U S A
96:8907-8912
(1999)
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PubMed id:
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Crystal structure of the alpha appendage of AP-2 reveals a recruitment platform for clathrin-coat assembly.
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L.M.Traub,
M.A.Downs,
J.L.Westrich,
D.H.Fremont.
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ABSTRACT
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AP-2 adaptors regulate clathrin-bud formation at the cell surface by recruiting
clathrin trimers to the plasma membrane and by selecting certain membrane
proteins for inclusion within the developing clathrin-coat structure. These
functions are performed by discrete subunits of the adaptor heterotetramer. The
carboxyl-terminal appendage of the AP-2 alpha subunit appears to regulate the
translocation of several endocytic accessory proteins to the bud site. We have
determined the crystal structure of the alpha appendage at 1.4-A resolution by
multiwavelength anomalous diffraction phasing. It is composed of two distinct
structural modules, a beta-sandwich domain and a mixed alpha-beta platform
domain. Structure-based mutagenesis shows that alterations to the molecular
surface of a highly conserved region on the platform domain differentially
affect associations of the appendage with amphiphysin, eps15, epsin, and AP180,
revealing a common protein-binding interface.
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Selected figure(s)
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Figure 1.
Fig. 1. (A) Schematic illustration of the subunit
organization of the AP-2 adaptor heterotetramer. Regions of the
complex with known protein-binding functions are indicated. For
tyrosine-based internalization signals, X is any amino acid and
Ø represents a bulky hydrophobic residue (1, 3). (B)
Functional protein associations with the GST-  [C]-appendage
fusion protein. Purified GST- [C]
appendage (0-100 µg) or GST (100 µg), immobilized on
25 µl packed glutathione Sepharose, were incubated in  7.5 mg/ml rat
brain cytosol for 60 min at 4°C. The Sepharose beads were
then recovered by centrifugation, and aliquots corresponding to
1/150 of the
supernatant (S) and 1/10 of each pellet (P) were resolved by
SDS/PAGE and either stained with Coomassie blue (Left) or
transferred to nitrocellulose (Right). Portions of the blots
were probed with anti-epsin, anti-eps15, anti-amphiphysin,
anti-AP180, or anti-dynamin antibodies. The position of the
markers (kDa) is indicated on the left and only the relevant
portion of each blot is shown.
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Figure 4.
Fig. 4. [C]
appendage-partner recognition surface. (A) Glutathione Sepharose
(25 µl packed beads) containing either wild-type GST- [C]
appendage ( [C]) or
GST- [C]
appendage F837A, R905A, R905A-F837A, R916A, or R916A-F837A
mutants were incubated with rat brain cytosol for 60 min at
4°C. The Sepharose beads were then recovered by
centrifugation, and aliquots corresponding to 1/150 of the
supernatant (S) and 1/10 of each washed pellet (P) were resolved
by SDS/PAGE and either stained with Coomassie blue (Left) or
transferred to nitrocellulose (Right). Portions of the blots
were probed with anti-epsin, anti-eps15, anti-amphiphysin,
anti-AP180, or anti-dynamin antibodies. Immunoblots from assays
performed at low ( 25 µg,
L) or high ( 100 µg,
H) GST- [C] density
are indicated on the left. In the experiment performed at high
density shown, the GST- [C] F837A
mutant was not tested, and 1/40 of each supernatant was
analyzed. The position of the markers (kDa) is indicated on the
left, and only the relevant portion of each blot is shown. (B)
Ribbon diagram (32) of the platform domain viewed from the top.
Conserved residues that make up the upper surface of the
platform are colored with invariant residues shaded magenta and
conserved residues, yellow. The extended hydrogen-bonding
network is shown as small gray balls with oxygen atoms in red,
nitrogen in blue. The three highly exposed residues that have
major consequences on partner binding when mutated to Ala are
highlighted (F837, R905, R916).
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Figures were
selected
by an automated process.
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Literature references that cite this PDB file's key reference
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PubMed id
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Reference
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A.L.Marat,
and
P.S.McPherson
(2010).
The connecdenn family, Rab35 guanine nucleotide exchange factors interfacing with the clathrin machinery.
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J Biol Chem,
285,
10627-10637.
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C.M.Schwartz,
A.Cheng,
M.R.Mughal,
M.P.Mattson,
and
P.J.Yao
(2010).
Clathrin assembly proteins AP180 and CALM in the embryonic rat brain.
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J Comp Neurol,
518,
3803-3818.
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J.R.Thieman,
S.K.Mishra,
K.Ling,
B.Doray,
R.A.Anderson,
and
L.M.Traub
(2009).
Clathrin regulates the association of PIPKIgamma661 with the AP-2 adaptor beta2 appendage.
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J Biol Chem,
284,
13924-13939.
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C.J.DeRegis,
P.B.Rahl,
G.R.Hoffman,
R.A.Cerione,
and
R.N.Collins
(2008).
Mutational analysis of betaCOP (Sec26p) identifies an appendage domain critical for function.
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BMC Cell Biol,
9,
3.
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P.A.Keyel,
J.R.Thieman,
R.Roth,
E.Erkan,
E.T.Everett,
S.C.Watkins,
J.E.Heuser,
and
L.M.Traub
(2008).
The AP-2 adaptor beta2 appendage scaffolds alternate cargo endocytosis.
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Mol Biol Cell,
19,
5309-5326.
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Y.Guo,
V.Punj,
D.Sengupta,
and
A.D.Linstedt
(2008).
Coat-tether interaction in Golgi organization.
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Mol Biol Cell,
19,
2830-2843.
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B.Ritter,
A.Y.Denisov,
J.Philie,
P.D.Allaire,
V.Legendre-Guillemin,
P.Zylbergold,
K.Gehring,
and
P.S.McPherson
(2007).
The NECAP PHear domain increases clathrin accessory protein binding potential.
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EMBO J,
26,
4066-4077.
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I.G.Mills
(2007).
The interplay between clathrin-coated vesicles and cell signalling.
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Semin Cell Dev Biol,
18,
459-470.
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R.S.Petralia,
and
P.J.Yao
(2007).
AP180 and CALM in the developing hippocampus: expression at the nascent synapse and localization to trafficking organelles.
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J Comp Neurol,
504,
314-327.
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S.Liang,
F.Y.Wei,
Y.M.Wu,
K.Tanabe,
T.Abe,
Y.Oda,
Y.Yoshida,
H.Yamada,
H.Matsui,
K.Tomizawa,
and
K.Takei
(2007).
Major Cdk5-dependent phosphorylation sites of amphiphysin 1 are implicated in the regulation of the membrane binding and endocytosis.
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J Neurochem,
102,
1466-1476.
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C.Knuehl,
C.Y.Chen,
V.Manalo,
P.K.Hwang,
N.Ota,
and
F.M.Brodsky
(2006).
Novel binding sites on clathrin and adaptors regulate distinct aspects of coat assembly.
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Traffic,
7,
1688-1700.
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D.M.Kamikura,
and
J.A.Cooper
(2006).
Clathrin interaction and subcellular localization of Ce-DAB-1, an adaptor for protein secretion in Caenorhabditis elegans.
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Traffic,
7,
324-336.
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G.Ren,
P.Vajjhala,
J.S.Lee,
B.Winsor,
and
A.L.Munn
(2006).
The BAR domain proteins: molding membranes in fission, fusion, and phagy.
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Microbiol Mol Biol Rev,
70,
37.
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I.Stavrou,
and
T.J.O'Halloran
(2006).
The monomeric clathrin assembly protein, AP180, regulates contractile vacuole size in Dictyostelium discoideum.
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Mol Biol Cell,
17,
5381-5389.
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M.A.Edeling,
C.Smith,
and
D.Owen
(2006).
Life of a clathrin coat: insights from clathrin and AP structures.
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Nat Rev Mol Cell Biol,
7,
32-44.
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A.Meyerholz,
L.Hinrichsen,
S.Groos,
P.C.Esk,
G.Brandes,
and
E.J.Ungewickell
(2005).
Effect of clathrin assembly lymphoid myeloid leukemia protein depletion on clathrin coat formation.
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Traffic,
6,
1225-1234.
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L.Santambrogio,
I.Potolicchio,
S.P.Fessler,
S.H.Wong,
G.Raposo,
and
J.L.Strominger
(2005).
Involvement of caspase-cleaved and intact adaptor protein 1 complex in endosomal remodeling in maturing dendritic cells.
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Nat Immunol,
6,
1020-1028.
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X.D.Zhang,
L.L.Yin,
Y.Zheng,
L.Lu,
Z.M.Zhou,
and
J.H.Sha
(2005).
Expression of a novel beta adaptin subunit mRNA splice variant in human testes.
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Asian J Androl,
7,
179-188.
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B.Ritter,
A.Y.Denisov,
J.Philie,
C.Deprez,
E.C.Tung,
K.Gehring,
and
P.S.McPherson
(2004).
Two WXXF-based motifs in NECAPs define the specificity of accessory protein binding to AP-1 and AP-2.
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EMBO J,
23,
3701-3710.
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H.T.McMahon,
and
I.G.Mills
(2004).
COP and clathrin-coated vesicle budding: different pathways, common approaches.
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Curr Opin Cell Biol,
16,
379-391.
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P.J.Watson,
G.Frigerio,
B.M.Collins,
R.Duden,
and
D.J.Owen
(2004).
Gamma-COP appendage domain - structure and function.
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Traffic,
5,
79-88.
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PDB code:
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B.Ritter,
J.Philie,
M.Girard,
E.C.Tung,
F.Blondeau,
and
P.S.McPherson
(2003).
Identification of a family of endocytic proteins that define a new alpha-adaptin ear-binding motif.
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EMBO Rep,
4,
1089-1095.
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C.Knuehl,
and
F.M.Brodsky
(2003).
The long and short of adaptor appendages.
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Nat Struct Biol,
10,
580-582.
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G.R.Hoffman,
P.B.Rahl,
R.N.Collins,
and
R.A.Cerione
(2003).
Conserved structural motifs in intracellular trafficking pathways: structure of the gammaCOP appendage domain.
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Mol Cell,
12,
615-625.
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PDB code:
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K.Farsad,
and
P.De Camilli
(2003).
Mechanisms of membrane deformation.
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Curr Opin Cell Biol,
15,
372-381.
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K.Nakayama,
and
S.Wakatsuki
(2003).
The structure and function of GGAs, the traffic controllers at the TGN sorting crossroads.
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Cell Struct Funct,
28,
431-442.
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L.N.Kinch,
Y.Qi,
T.J.Hubbard,
and
N.V.Grishin
(2003).
CASP5 target classification.
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Proteins,
53,
340-351.
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M.C.Duncan,
G.Costaguta,
and
G.S.Payne
(2003).
Yeast epsin-related proteins required for Golgi-endosome traffic define a gamma-adaptin ear-binding motif.
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Nat Cell Biol,
5,
77-81.
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R.Mattera,
C.N.Arighi,
R.Lodge,
M.Zerial,
and
J.S.Bonifacino
(2003).
Divalent interaction of the GGAs with the Rabaptin-5-Rabex-5 complex.
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EMBO J,
22,
78-88.
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S.D.Conner,
and
S.L.Schmid
(2003).
Differential requirements for AP-2 in clathrin-mediated endocytosis.
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J Cell Biol,
162,
773-779.
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S.D.Conner,
T.Schröter,
and
S.L.Schmid
(2003).
AAK1-mediated micro2 phosphorylation is stimulated by assembled clathrin.
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Traffic,
4,
885-890.
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S.X.Cohen,
M.Moulin,
S.Hashemolhosseini,
K.Kilian,
M.Wegner,
and
C.W.Müller
(2003).
Structure of the GCM domain-DNA complex: a DNA-binding domain with a novel fold and mode of target site recognition.
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EMBO J,
22,
1835-1845.
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PDB code:
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W.W.Lui,
B.M.Collins,
J.Hirst,
A.Motley,
C.Millar,
P.Schu,
D.J.Owen,
and
M.S.Robinson
(2003).
Binding partners for the COOH-terminal appendage domains of the GGAs and gamma-adaptin.
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Mol Biol Cell,
14,
2385-2398.
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PDB code:
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B.M.Collins,
A.J.McCoy,
H.M.Kent,
P.R.Evans,
and
D.J.Owen
(2002).
Molecular architecture and functional model of the endocytic AP2 complex.
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Cell,
109,
523-535.
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PDB codes:
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B.Wendland
(2002).
Epsins: adaptors in endocytosis?
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Nat Rev Mol Cell Biol,
3,
971-977.
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D.Yao,
M.Ehrlich,
Y.I.Henis,
and
E.B.Leof
(2002).
Transforming growth factor-beta receptors interact with AP2 by direct binding to beta2 subunit.
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Mol Biol Cell,
13,
4001-4012.
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H.M.Kent,
H.T.McMahon,
P.R.Evans,
A.Benmerah,
and
D.J.Owen
(2002).
Gamma-adaptin appendage domain: structure and binding site for Eps15 and gamma-synergin.
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Structure,
10,
1139-1148.
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PDB codes:
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K.R.Henry,
K.D'Hondt,
J.Chang,
T.Newpher,
K.Huang,
R.T.Hudson,
H.Riezman,
and
S.K.Lemmon
(2002).
Scd5p and clathrin function are important for cortical actin organization, endocytosis, and localization of sla2p in yeast.
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Mol Biol Cell,
13,
2607-2625.
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S.K.Mishra,
S.C.Watkins,
and
L.M.Traub
(2002).
The autosomal recessive hypercholesterolemia (ARH) protein interfaces directly with the clathrin-coat machinery.
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Proc Natl Acad Sci U S A,
99,
16099-16104.
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T.Nogi,
Y.Shiba,
M.Kawasaki,
T.Shiba,
N.Matsugaki,
N.Igarashi,
M.Suzuki,
R.Kato,
H.Takatsu,
K.Nakayama,
and
S.Wakatsuki
(2002).
Structural basis for the accessory protein recruitment by the gamma-adaptin ear domain.
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Nat Struct Biol,
9,
527-531.
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PDB code:
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B.G.Yeung,
and
G.S.Payne
(2001).
Clathrin interactions with C-terminal regions of the yeast AP-1 beta and gamma subunits are important for AP-1 association with clathrin coats.
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Traffic,
2,
565-576.
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D.S.Rao,
J.C.Chang,
P.D.Kumar,
I.Mizukami,
G.M.Smithson,
S.V.Bradley,
A.F.Parlow,
and
T.S.Ross
(2001).
Huntingtin interacting protein 1 Is a clathrin coat binding protein required for differentiation of late spermatogenic progenitors.
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Mol Cell Biol,
21,
7796-7806.
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F.M.Brodsky,
C.Y.Chen,
C.Knuehl,
M.C.Towler,
and
D.E.Wakeham
(2001).
Biological basket weaving: formation and function of clathrin-coated vesicles.
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Annu Rev Cell Dev Biol,
17,
517-568.
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G.Costaguta,
C.J.Stefan,
E.S.Bensen,
S.D.Emr,
and
G.S.Payne
(2001).
Yeast Gga coat proteins function with clathrin in Golgi to endosome transport.
|
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Mol Biol Cell,
12,
1885-1896.
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M.Boehm,
and
J.S.Bonifacino
(2001).
Adaptins: the final recount.
|
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Mol Biol Cell,
12,
2907-2920.
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P.S.McPherson,
B.K.Kay,
and
N.K.Hussain
(2001).
Signaling on the endocytic pathway.
|
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Traffic,
2,
375-384.
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S.M.Morris,
and
J.A.Cooper
(2001).
Disabled-2 colocalizes with the LDLR in clathrin-coated pits and interacts with AP-2.
|
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Traffic,
2,
111-123.
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B.M.Pearse,
C.J.Smith,
and
D.J.Owen
(2000).
Clathrin coat construction in endocytosis.
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Curr Opin Struct Biol,
10,
220-228.
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D.E.Wakeham,
J.A.Ybe,
F.M.Brodsky,
and
P.K.Hwang
(2000).
Molecular structures of proteins involved in vesicle coat formation.
|
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Traffic,
1,
393-398.
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D.J.Owen,
and
J.P.Luzio
(2000).
Structural insights into clathrin-mediated endocytosis.
|
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Curr Opin Cell Biol,
12,
467-474.
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D.J.Owen,
Y.Vallis,
B.M.Pearse,
H.T.McMahon,
and
P.R.Evans
(2000).
The structure and function of the beta 2-adaptin appendage domain.
|
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EMBO J,
19,
4216-4227.
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PDB code:
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J.Hyman,
H.Chen,
P.P.Di Fiore,
P.De Camilli,
and
A.T.Brunger
(2000).
Epsin 1 undergoes nucleocytosolic shuttling and its eps15 interactor NH(2)-terminal homology (ENTH) domain, structurally similar to Armadillo and HEAT repeats, interacts with the transcription factor promyelocytic leukemia Zn(2)+ finger protein (PLZF).
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J Cell Biol,
149,
537-546.
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PDB code:
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Y.Rouillé,
W.Rohn,
and
B.Hoflack
(2000).
Targeting of lysosomal proteins.
|
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Semin Cell Dev Biol,
11,
165-171.
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E.Ungewickell
(1999).
Wrapping the package.
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Proc Natl Acad Sci U S A,
96,
8809-8810.
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The most recent references are shown first.
Citation data come partly from CiteXplore and partly
from an automated harvesting procedure. Note that this is likely to be
only a partial list as not all journals are covered by
either method. However, we are continually building up the citation data
so more and more references will be included with time.
Where a reference describes a PDB structure, the PDB
code is
shown on the right.
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Links
