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PDBsum entry 1b47
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Signal transduction
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PDB id
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1b47
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Contents |
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* Residue conservation analysis
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Enzyme class:
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E.C.2.3.2.27
- RING-type E3 ubiquitin transferase.
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Reaction:
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S-ubiquitinyl-[E2 ubiquitin-conjugating enzyme]-L-cysteine + [acceptor protein]-L-lysine = [E2 ubiquitin-conjugating enzyme]-L-cysteine + N6- ubiquitinyl-[acceptor protein]-L-lysine
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DOI no:
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Nature
398:84-90
(1999)
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PubMed id:
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Structure of the amino-terminal domain of Cbl complexed to its binding site on ZAP-70 kinase.
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W.Meng,
S.Sawasdikosol,
S.J.Burakoff,
M.J.Eck.
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ABSTRACT
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Cbl is an adaptor protein that functions as a negative regulator of many
signalling pathways that start from receptors at the cell surface. The
evolutionarily conserved amino-terminal region of Cbl (Cbl-N) binds to
phosphorylated tyrosine residues and has cell-transforming activity. Point
mutations in Cbl that disrupt its recognition of phosphotyrosine also interfere
with its negative regulatory function and, in the case of v-cbl, with its
oncogenic potential. In T cells, Cbl-N binds to the tyrosine-phosphorylated
inhibitory site of the protein tyrosine kinase ZAP-70. Here we describe the
crystal structure of Cbl-N, both alone and in complex with a phosphopeptide that
represents its binding site in ZAP-70. The structures show that Cbl-N is
composed of three interacting domains: a four-helix bundle (4H), an EF-hand
calcium-binding domain, and a divergent SH2 domain that was not recognizable
from the amino-acid sequence of the protein. The calcium-bound EF hand wedges
between the 4H and SH2 domains and roughly determines their relative
orientation. In the ligand-occupied structure, the 4H domain packs against the
SH2 domain and completes its phosphotyrosine-recognition pocket. Disruption of
this binding to ZAP-70 as a result of structure-based mutations in the 4H,
EF-hand and SH2 domains confirms that the three domains together form an
integrated phosphoprotein-recognition module.
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Selected figure(s)
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Figure 1.
Figure 1: Cbl domain structure and sequence comparisons. a,
Ribbon diagram of unliganded Cbl-N. The N-terminal 4H domain is
coloured yellow, the EF-hand domain green, and the SH2 domain
blue. Secondary-structure elements are labelled  A–
D
in the 4H domain and by established conventions for the
EF-hand and SH2 domains. The bound Ca^2+ ion is indicated by a
red sphere. Arginine 294 is universally conserved in SH2 domains
and participates in phosphotyrosine coordination. b, Diagram of
c-Cbl domain structure. The Cbl-N region and adjacent RING
finger domain are conserved in all Cbl homologues. The
C-terminal region, which contains proline-rich segments and
tyrosine phosphorylation sites, is more variable and is
completely absent in D-Cbl. A putative leucine zipper has been
found near the C terminus of Cbl. c, Aligned sequences of the
Cbl-N portion of human c-Cbl, human Cbl-b, Drosophila D-Cbl, and
Sli-1. Residues that are identical in at least three of the
sequences are shaded yellow. Secondary-structure elements are
shown above the sequence and are coloured as in a and b. Black
squares indicate residues that coordinate calcium. Red circles
mark residues that interact with the bound ZAP-70 peptide. d,
Structure-based sequence alignment of Cbl and Lck^23 SH2
domains. Seventy structurally equivalent residues are shaded
yellow; -carbons
of these seventy residues superimpose with an r.m.s.d. of 1.47
Å. The secondary-structure elements that are present in
Lck and other SH2 domains, but not in the Cbl SH2 domain, are
indicated by open boxes. e, Superposition of the Cbl SH2 domain
(blue) with the Lck SH2 domain (yellow). The structural elements
that are absent in the Cbl domain are red.
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Figure 3.
Figure 3: Structure of the Cbl-N / ZAP-70 pY292 complex. a,
Stereo diagram showing an -carbon
trace of the complex. The bound ZAP-70 phosphopeptide is shown
in magenta. b, Stereo diagram showing the interactions with the
ZAP-70 phosphopeptide. The bound peptide is shown in white. Red
spheres represent ordered water molecules that bridge Cbl-N and
the bound peptide. Thin blue lines represent hydrogen bonds. In
the phosphotyrosine pocket, Tyr 274 in Cbl makes an 'edge-face'
interaction with the phosphotyrosine ring, and its hydroxyl
group hydrogen-bonds to the carbonyl oxygen of Gly 291 in the
ZAP-70 peptide. An arginine residue found in this position in
most SH2 domains makes an 'amino–aromatic' interaction with
the phosphotyrosine ring and also hydrogen-bonds with the
carbonyl of the pY-1 residue of the bound peptide^8. C-terminal
to the phosphotyrosine, the proline at position pY+4 in the
ZAP-70 peptide binds in a hydrophobic cleft formed by Tyr 307,
Phe 336 and Tyr 337, and the glutamic acid residue at pY+3
hydrogen-bonds with the backbone amide of His 320. c,
Superposition of the liganded (yellow) and unliganded (blue)
Cbl-N structures reveals a shift in the position of the SH2
domain upon phosphopeptide binding. The conformation of the 4H
and EF-hand domains is essentially identical in the two
structures. In the absence of phosphopeptide, the SH2 domain
makes little contact with the 4H domain and its position is
likely to vary, as we observe slightly different conformations
among the three molecules in the asymmetric unit. Phosphopeptide
binding induces a domain 'closure', in which the SH2 domain
rotates to pack against the helical domain, completing the
phosphotyrosine-binding pocket, as in d. d, Molecular surface
representation of the Cbl-N domain, coloured by domain. The 4H
domain (yellow) forms a portion of the phosphotyrosine-binding
pocket. Residues 289–297 of the bound ZAP-70 phosphopeptide
are shown as a stick model. The three N-terminal residues in the
peptide are disordered and are not included. In the liganded
structure, about 1, 200 Å^2 of the SH2 domain is buried as
a result of interaction with the other two domains; 500
Å^2 is buried in the interface with the 4H domain, and 700
Å^2 is buried in the interface with the EF hand. The 4H
and EF-hand domains share a solvent-excluding interface of  800
Å^2.
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The above figures are
reprinted
by permission from Macmillan Publishers Ltd:
Nature
(1999,
398,
84-90)
copyright 1999.
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Figures were
selected
by the author.
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Literature references that cite this PDB file's key reference
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Google scholar
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PubMed id
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Reference
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H.Dou,
L.Buetow,
A.Hock,
G.J.Sibbet,
K.H.Vousden,
and
D.T.Huang
(2012).
Structural basis for autoinhibition and phosphorylation-dependent activation of c-Cbl.
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Nat Struct Mol Biol,
19,
184-192.
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PDB codes:
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S.C.Kales,
P.E.Ryan,
and
S.Lipkowitz
(2012).
Cbl exposes its RING finger.
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Nat Struct Mol Biol,
19,
131-133.
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J.H.Hurley,
and
H.Stenmark
(2011).
Molecular mechanisms of ubiquitin-dependent membrane traffic.
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Annu Rev Biophys,
40,
119-142.
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R.Ghassemifar,
C.B.Thien,
J.Finlayson,
D.Joske,
G.M.Cull,
B.Augustson,
and
W.Y.Langdon
(2011).
Incidence of c-Cbl mutations in human acute myeloid leukaemias in an Australian patient cohort.
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Pathology,
43,
261-265.
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A.Mehlitz,
S.Banhart,
A.P.Mäurer,
A.Kaushansky,
A.G.Gordus,
J.Zielecki,
G.Macbeath,
and
T.F.Meyer
(2010).
Tarp regulates early Chlamydia-induced host cell survival through interactions with the human adaptor protein SHC1.
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J Cell Biol,
190,
143-157.
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D.Ghosh,
and
G.C.Tsokos
(2010).
Spleen tyrosine kinase: an Src family of non-receptor kinase has multiple functions and represents a valuable therapeutic target in the treatment of autoimmune and inflammatory diseases.
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Autoimmunity,
43,
48-55.
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Q.Sun,
R.A.Jackson,
C.Ng,
G.R.Guy,
and
J.Sivaraman
(2010).
Additional serine/threonine phosphorylation reduces binding affinity but preserves interface topography of substrate proteins to the c-Cbl TKB domain.
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PLoS One,
5,
e12819.
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PDB codes:
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S.Omori,
S.Fuchigami,
M.Ikeguchi,
and
A.Kidera
(2010).
Latent dynamics of a protein molecule observed in dihedral angle space.
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J Chem Phys,
132,
115103.
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Y.H.Tan,
S.Krishnaswamy,
S.Nandi,
R.Kanteti,
S.Vora,
K.Onel,
R.Hasina,
F.Y.Lo,
E.El-Hashani,
G.Cervantes,
M.Robinson,
S.C.Kales,
S.Lipkowitz,
T.Karrison,
M.Sattler,
E.E.Vokes,
Y.C.Wang,
and
R.Salgia
(2010).
CBL is frequently altered in lung cancers: its relationship to mutations in MET and EGFR tyrosine kinases.
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PLoS One,
5,
e8972.
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A.M.Gilfillan,
and
J.Rivera
(2009).
The tyrosine kinase network regulating mast cell activation.
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Immunol Rev,
228,
149-169.
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L.Y.Hsu,
Y.X.Tan,
Z.Xiao,
M.Malissen,
and
A.Weiss
(2009).
A hypomorphic allele of ZAP-70 reveals a distinct thymic threshold for autoimmune disease versus autoimmune reactivity.
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J Exp Med,
206,
2527-2541.
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M.Shen,
and
A.Yen
(2009).
c-Cbl tyrosine kinase-binding domain mutant G306E abolishes the interaction of c-Cbl with CD38 and fails to promote retinoic acid-induced cell differentiation and G0 arrest.
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J Biol Chem,
284,
25664-25677.
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R.Nakao,
K.Hirasaka,
J.Goto,
K.Ishidoh,
C.Yamada,
A.Ohno,
Y.Okumura,
I.Nonaka,
K.Yasutomo,
K.M.Baldwin,
E.Kominami,
A.Higashibata,
K.Nagano,
K.Tanaka,
N.Yasui,
E.M.Mills,
S.Takeda,
and
T.Nikawa
(2009).
Ubiquitin ligase Cbl-b is a negative regulator for insulin-like growth factor 1 signaling during muscle atrophy caused by unloading.
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Mol Cell Biol,
29,
4798-4811.
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S.Hanke,
and
M.Mann
(2009).
The phosphotyrosine interactome of the insulin receptor family and its substrates IRS-1 and IRS-2.
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Mol Cell Proteomics,
8,
519-534.
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W.Gan,
and
B.Roux
(2009).
Binding specificity of SH2 domains: insight from free energy simulations.
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Proteins,
74,
996.
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A.Kaushansky,
A.Gordus,
B.Chang,
J.Rush,
and
G.MacBeath
(2008).
A quantitative study of the recruitment potential of all intracellular tyrosine residues on EGFR, FGFR1 and IGF1R.
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Mol Biosyst,
4,
643-653.
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C.Ng,
R.A.Jackson,
J.P.Buschdorf,
Q.Sun,
G.R.Guy,
and
J.Sivaraman
(2008).
Structural basis for a novel intrapeptidyl H-bond and reverse binding of c-Cbl-TKB domain substrates.
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EMBO J,
27,
804-816.
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PDB codes:
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D.Strickland,
K.Moffat,
and
T.R.Sosnick
(2008).
Light-activated DNA binding in a designed allosteric protein.
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Proc Natl Acad Sci U S A,
105,
10709-10714.
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T.Kurz,
Y.C.Chou,
A.R.Willems,
N.Meyer-Schaller,
M.L.Hecht,
M.Tyers,
M.Peter,
and
F.Sicheri
(2008).
Dcn1 functions as a scaffold-type E3 ligase for cullin neddylation.
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Mol Cell,
29,
23-35.
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PDB code:
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A.N.Bullock,
M.C.Rodriguez,
J.E.Debreczeni,
Z.Songyang,
and
S.Knapp
(2007).
Structure of the SOCS4-ElonginB/C complex reveals a distinct SOCS box interface and the molecular basis for SOCS-dependent EGFR degradation.
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Structure,
15,
1493-1504.
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PDB code:
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B.Pakuts,
C.Debonneville,
L.M.Liontos,
M.P.Loreto,
and
C.J.McGlade
(2007).
The Src-like adaptor protein 2 regulates colony-stimulating factor-1 receptor signaling and down-regulation.
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J Biol Chem,
282,
17953-17963.
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C.M.Wiggins,
H.Band,
and
S.J.Cook
(2007).
c-Cbl is not required for ERK1/2-dependent degradation of BimEL.
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Cell Signal,
19,
2605-2611.
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J.Saez-Rodriguez,
L.Simeoni,
J.A.Lindquist,
R.Hemenway,
U.Bommhardt,
B.Arndt,
U.U.Haus,
R.Weismantel,
E.D.Gilles,
S.Klamt,
and
B.Schraven
(2007).
A logical model provides insights into T cell receptor signaling.
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PLoS Comput Biol,
3,
e163.
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S.Loeser,
and
J.M.Penninger
(2007).
Regulation of peripheral T cell tolerance by the E3 ubiquitin ligase Cbl-b.
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Semin Immunol,
19,
206-214.
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A.Csiszár
(2006).
Structural and functional diversity of adaptor proteins involved in tyrosine kinase signalling.
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Bioessays,
28,
465-479.
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A.Sanjay,
T.Miyazaki,
C.Itzstein,
E.Purev,
W.C.Horne,
and
R.Baron
(2006).
Identification and functional characterization of an Src homology domain 3 domain-binding site on Cbl.
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FEBS J,
273,
5442-5456.
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B.A.Liu,
K.Jablonowski,
M.Raina,
M.Arcé,
T.Pawson,
and
P.D.Nash
(2006).
The human and mouse complement of SH2 domain proteins-establishing the boundaries of phosphotyrosine signaling.
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Mol Cell,
22,
851-868.
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G.Swaminathan,
and
A.Y.Tsygankov
(2006).
The Cbl family proteins: ring leaders in regulation of cell signaling.
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J Cell Physiol,
209,
21-43.
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I.W.Glaaser,
J.R.Bankston,
H.Liu,
M.Tateyama,
and
R.S.Kass
(2006).
A carboxyl-terminal hydrophobic interface is critical to sodium channel function. Relevance to inherited disorders.
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J Biol Chem,
281,
24015-24023.
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S.Kamtekar,
A.J.Berman,
J.Wang,
J.M.Lázaro,
M.de Vega,
L.Blanco,
M.Salas,
and
T.A.Steitz
(2006).
The phi29 DNA polymerase:protein-primer structure suggests a model for the initiation to elongation transition.
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EMBO J,
25,
1335-1343.
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PDB code:
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F.Huang,
and
A.Sorkin
(2005).
Growth factor receptor binding protein 2-mediated recruitment of the RING domain of Cbl to the epidermal growth factor receptor is essential and sufficient to support receptor endocytosis.
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Mol Biol Cell,
16,
1268-1281.
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J.G.Williams,
A.A.Noegel,
and
L.Eichinger
(2005).
Manifestations of multicellularity: Dictyostelium reports in.
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Trends Genet,
21,
392-398.
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J.Hu,
and
S.R.Hubbard
(2005).
Structural characterization of a novel Cbl phosphotyrosine recognition motif in the APS family of adapter proteins.
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J Biol Chem,
280,
18943-18949.
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PDB code:
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K.D.Moon,
C.B.Post,
D.L.Durden,
Q.Zhou,
P.De,
M.L.Harrison,
and
R.L.Geahlen
(2005).
Molecular basis for a direct interaction between the Syk protein-tyrosine kinase and phosphoinositide 3-kinase.
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J Biol Chem,
280,
1543-1551.
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L.Eichinger,
J.A.Pachebat,
G.Glöckner,
M.A.Rajandream,
R.Sucgang,
M.Berriman,
J.Song,
R.Olsen,
K.Szafranski,
Q.Xu,
B.Tunggal,
S.Kummerfeld,
M.Madera,
B.A.Konfortov,
F.Rivero,
A.T.Bankier,
R.Lehmann,
N.Hamlin,
R.Davies,
P.Gaudet,
P.Fey,
K.Pilcher,
G.Chen,
D.Saunders,
E.Sodergren,
P.Davis,
A.Kerhornou,
X.Nie,
N.Hall,
C.Anjard,
L.Hemphill,
N.Bason,
P.Farbrother,
B.Desany,
E.Just,
T.Morio,
R.Rost,
C.Churcher,
J.Cooper,
S.Haydock,
N.van Driessche,
A.Cronin,
I.Goodhead,
D.Muzny,
T.Mourier,
A.Pain,
M.Lu,
D.Harper,
R.Lindsay,
H.Hauser,
K.James,
M.Quiles,
M.Madan Babu,
T.Saito,
C.Buchrieser,
A.Wardroper,
M.Felder,
M.Thangavelu,
D.Johnson,
A.Knights,
H.Loulseged,
K.Mungall,
K.Oliver,
C.Price,
M.A.Quail,
H.Urushihara,
J.Hernandez,
E.Rabbinowitsch,
D.Steffen,
M.Sanders,
J.Ma,
Y.Kohara,
S.Sharp,
M.Simmonds,
S.Spiegler,
A.Tivey,
S.Sugano,
B.White,
D.Walker,
J.Woodward,
T.Winckler,
Y.Tanaka,
G.Shaulsky,
M.Schleicher,
G.Weinstock,
A.Rosenthal,
E.C.Cox,
R.L.Chisholm,
R.Gibbs,
W.F.Loomis,
M.Platzer,
R.R.Kay,
J.Williams,
P.H.Dear,
A.A.Noegel,
B.Barrell,
and
A.Kuspa
(2005).
The genome of the social amoeba Dictyostelium discoideum.
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Nature,
435,
43-57.
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T.Brdicka,
T.A.Kadlecek,
J.P.Roose,
A.W.Pastuszak,
and
A.Weiss
(2005).
Intramolecular regulatory switch in ZAP-70: analogy with receptor tyrosine kinases.
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Mol Cell Biol,
25,
4924-4933.
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A.A.de Melker,
G.van der Horst,
and
J.Borst
(2004).
Ubiquitin ligase activity of c-Cbl guides the epidermal growth factor receptor into clathrin-coated pits by two distinct modes of Eps15 recruitment.
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J Biol Chem,
279,
55465-55473.
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A.K.Ghosh,
A.L.Reddi,
N.L.Rao,
L.Duan,
V.Band,
and
H.Band
(2004).
Biochemical basis for the requirement of kinase activity for Cbl-dependent ubiquitinylation and degradation of a target tyrosine kinase.
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J Biol Chem,
279,
36132-36141.
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C.K.Kassenbrock,
and
S.M.Anderson
(2004).
Regulation of ubiquitin protein ligase activity in c-Cbl by phosphorylation-induced conformational change and constitutive activation by tyrosine to glutamate point mutations.
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J Biol Chem,
279,
28017-28027.
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L.Duan,
A.L.Reddi,
A.Ghosh,
M.Dimri,
and
H.Band
(2004).
The Cbl family and other ubiquitin ligases: destructive forces in control of antigen receptor signaling.
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Immunity,
21,
7.
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M.Halonen,
H.Kangas,
T.Rüppell,
T.Ilmarinen,
J.Ollila,
M.Kolmer,
M.Vihinen,
J.Palvimo,
J.Saarela,
I.Ulmanen,
and
P.Eskelin
(2004).
APECED-causing mutations in AIRE reveal the functional domains of the protein.
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J Biol Chem,
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J Exp Med,
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Mol Cell Biol,
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The roles of Cbl-b and c-Cbl in insulin-stimulated glucose transport.
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J Biol Chem,
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Traffic,
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c-Cbl binding and ubiquitin-dependent lysosomal degradation of membrane-associated Notch1.
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J Biol Chem,
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The N-terminal SH2 domains of Syk and ZAP-70 mediate phosphotyrosine-independent binding to integrin beta cytoplasmic domains.
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J Biol Chem,
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Mol Cell Biol,
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M.Panigada,
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J Exp Med,
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Signal Transduct,
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Cbl-b positively regulates Btk-mediated activation of phospholipase C-gamma2 in B cells.
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J Exp Med,
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Tyrosine 315 determines optimal recruitment of ZAP-70 to the T cell antigen receptor.
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Eur J Immunol,
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Hakai, a c-Cbl-like protein, ubiquitinates and induces endocytosis of the E-cadherin complex.
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Nat Cell Biol,
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T cell development and T cell responses in mice with mutations affecting tyrosines 292 or 315 of the ZAP-70 protein tyrosine kinase.
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J Exp Med,
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Proc Natl Acad Sci U S A,
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RING finger mutations that abolish c-Cbl-directed polyubiquitination and downregulation of the EGF receptor are insufficient for cell transformation.
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Mol Cell,
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Nat Rev Immunol,
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The non-receptor tyrosine kinase Syk is a target of Cbl-mediated ubiquitylation upon B-cell receptor stimulation.
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EMBO J,
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Mutation of the c-Cbl TKB domain binding site on the Met receptor tyrosine kinase converts it into a transforming protein.
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Mol Cell,
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Requirement for tyrosine residues 315 and 319 within zeta chain-associated protein 70 for T cell development.
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J Exp Med,
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The Cbl proto-oncogene product negatively regulates the Src-family tyrosine kinase Fyn by enhancing its degradation.
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Mol Cell Biol,
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C.H.Yoon,
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Requirements of multiple domains of SLI-1, a Caenorhabditis elegans homologue of c-Cbl, and an inhibitory tyrosine in LET-23 in regulating vulval differentiation.
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Mol Biol Cell,
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L.A.Norian,
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Intracellular adapter molecules.
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Curr Opin Immunol,
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Structure of the ERM protein moesin reveals the FERM domain fold masked by an extended actin binding tail domain.
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Cell,
101,
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PDB code:
|
|
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N.L.Lill,
P.Douillard,
R.A.Awwad,
S.Ota,
M.L.Lupher,
S.Miyake,
N.Meissner-Lula,
V.W.Hsu,
and
H.Band
(2000).
The evolutionarily conserved N-terminal region of Cbl is sufficient to enhance down-regulation of the epidermal growth factor receptor.
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J Biol Chem,
275,
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N.Zheng,
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(2000).
Structure of a c-Cbl-UbcH7 complex: RING domain function in ubiquitin-protein ligases.
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Cell,
102,
533-539.
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PDB code:
|
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|
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S.Ota,
K.Hazeki,
N.Rao,
M.L.Lupher,
C.E.Andoniou,
B.Druker,
and
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The RING finger domain of Cbl is essential for negative regulation of the Syk tyrosine kinase.
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J Biol Chem,
275,
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Biochim Biophys Acta,
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T.Hunter
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Signaling--2000 and beyond.
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Cell,
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C.R.Maroun,
M.Lupher,
H.Band,
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Cbl-transforming variants trigger a cascade of molecular alterations that lead to epithelial mesenchymal conversion.
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Mol Biol Cell,
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T.Shishido,
T.Akagi,
T.Ouchi,
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The kinase-deficient Src acts as a suppressor of the Abl kinase for Cbl phosphorylation.
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Proc Natl Acad Sci U S A,
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T.Tezuka,
K.Hironaka,
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(2000).
Cbl suppresses B cell receptor-mediated phospholipase C (PLC)-gamma2 activation by regulating B cell linker protein-PLC-gamma2 binding.
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J Exp Med,
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A.Ciechanover,
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Ubiquitin ligase activity and tyrosine phosphorylation underlie suppression of growth factor signaling by c-Cbl/Sli-1.
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Mol Cell,
4,
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G.Magistrelli,
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Role of the Src homology 2 domains and interdomain regions in ZAP-70 phosphorylation and enzymatic activity.
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The oncogenic 70Z Cbl mutation blocks the phosphotyrosine binding domain-dependent negative regulation of ZAP-70 by c-Cbl in Jurkat T cells.
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Mol Cell Biol,
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SLAP, a dimeric adapter protein, plays a functional role in T cell receptor signaling.
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Proc Natl Acad Sci U S A,
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(1999).
Cbl-mediated negative regulation of platelet-derived growth factor receptor-dependent cell proliferation. A critical role for Cbl tyrosine kinase-binding domain.
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J Biol Chem,
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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
codes are
shown on the right.
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|
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