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PDBsum entry 3kex
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References listed in PDB file
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Key reference
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Title
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Structural analysis of the catalytically inactive kinase domain of the human egf receptor 3.
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Authors
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N.Jura,
Y.Shan,
X.Cao,
D.E.Shaw,
J.Kuriyan.
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Ref.
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Proc Natl Acad Sci U S A, 2009,
106,
21608-21613.
[DOI no: ]
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PubMed id
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Abstract
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The kinase domain of human epidermal growth factor receptor (HER) 3/ErbB3, a
member of the EGF receptor (EGFR) family, lacks several residues that are
critical for catalysis. Because catalytic activity in EGFR family members is
switched on by an allosteric interaction between kinase domains in an asymmetric
kinase domain dimer, HER3 might be specialized to serve as an activator of other
EGFR family members. We have determined the crystal structure of the HER3 kinase
domain and show that it appears to be locked into an inactive conformation that
resembles that of EGFR and HER4. Although the crystal structure shows that the
HER3 kinase domain binds ATP, we confirm that it is catalytically inactive but
can serve as an activator of the EGFR kinase domain. The HER3 kinase domain
forms a dimer in the crystal, mediated by hydrophobic contacts between the
N-terminal lobes of the kinase domains. This N-lobe dimer closely resembles a
dimer formed by inactive HER4 kinase domains in crystal structures determined
previously, and molecular dynamics simulations suggest that the HER3 and HER4
N-lobe dimers are stable. The kinase domains of HER3 and HER4 form similar
chains in their respective crystal lattices, in which N-lobe dimers are linked
together by reciprocal exchange of C-terminal tails. The conservation of this
tiling pattern in HER3 and HER4, which is the closest evolutionary homolog of
HER3, might represent a general mechanism by which this branch of the HER
receptors restricts ligand-independent formation of active heterodimers with
other members of the EGFR family.
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Figure 4.
Analysis of the concatenated HER3 and HER4 kinase domains in
the crystal lattices. (A) Pattern of kinase monomer interactions
observed in the crystal lattices of the kinase domains of HER3
and inactive HER4 (PDB ID code 3BBW). The C-terminal tail
exchanging dimers are propagated through the N-lobe dimer
interface. JM refers to portion of the juxtamembrane segment.
(B) Detailed view of the HER3 and HER4 N-lobe dimers.
Hydrophobic residues are shown in stick representation. (C)
Empirical estimates of binding free energy of HER3 and HER4
N-lobe homodimers using conformations obtained from all-atom
molecular dynamics simulations. (D) Comparison between the
C-terminal tail interaction with the C-lobe in the HER3 kinase
domain dimer and the HER4 kinase domain dimer (PDB ID code 3BBW)
and interaction of Mig6/segment 1 with the C-lobe of the EGFR
kinase domain (PDB ID code 2RFE).
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Figure 5.
Model for oligomerization of the kinase domains of HER3 and
inactive HER4 at the plasma membrane. (A) Flexible C-terminal
tail/C-lobe interaction creates a possibility for the formation
of branched HER3 or inactive HER4 oligomers, resulting in a 2D
mesh. (B) Empirical estimates of binding free energy of the
HER3/HER4 N-lobe homodimer, calculated using conformations
obtained from an all-atom molecular dynamics simulation.
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