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PDBsum entry 4nqq
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Cell adhesion
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PDB id
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4nqq
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DOI no:
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Proc Natl Acad Sci U S A
111:E4175
(2014)
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PubMed id:
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Structural and energetic determinants of adhesive binding specificity in type I cadherins.
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J.Vendome,
K.Felsovalyi,
H.Song,
Z.Yang,
X.Jin,
J.Brasch,
O.J.Harrison,
G.Ahlsen,
F.Bahna,
A.Kaczynska,
P.S.Katsamba,
D.Edmond,
W.L.Hubbell,
L.Shapiro,
B.Honig.
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ABSTRACT
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Type I cadherin cell-adhesion proteins are similar in sequence and structure and
yet are different enough to mediate highly specific cell-cell recognition
phenomena. It has previously been shown that small differences in the homophilic
and heterophilic binding affinities of different type I family members can
account for the differential cell-sorting behavior. Here we use a combination of
X-ray crystallography, analytical ultracentrifugation, surface plasmon resonance
and double electron-electron resonance (DEER) electron paramagnetic resonance
spectroscopy to identify the molecular determinants of type I cadherin
dimerization affinities. Small changes in sequence are found to produce subtle
structural and dynamical changes that impact relative affinities, in part via
electrostatic and hydrophobic interactions, and in part through entropic effects
because of increased conformational heterogeneity in the bound states as
revealed by DEER distance mapping in the dimers. These findings highlight the
remarkable ability of evolution to exploit a wide range of molecular properties
to produce closely related members of the same protein family that have affinity
differences finely tuned to mediate their biological roles.
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