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PDBsum entry 2kum
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Signaling protein
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PDB id
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2kum
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References listed in PDB file
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Key reference
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Title
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Nmr analysis of the structure, Dynamics, And unique oligomerization properties of the chemokine ccl27.
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Authors
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A.L.Jansma,
J.P.Kirkpatrick,
A.R.Hsu,
T.M.Handel,
D.Nietlispach.
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Ref.
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J Biol Chem, 2010,
285,
14424-14437.
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PubMed id
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Note: In the PDB file this reference is
annotated as "TO BE PUBLISHED". The citation details given above have
been manually determined.
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Abstract
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Chemokines have two essential interactions in vivo, with G protein-coupled
receptors, which activate intracellular signaling pathways, and with
glycosaminoglycans (GAGs), which are involved in cell surface localization and
transport. Although it has been shown that chemokines bind and activate their
respective G protein-coupled receptors as monomers, many chemokines oligomerize
upon GAG binding, and the ability to oligomerize and bind GAGs is required for
in vivo function. In this study, we investigated the structure, dynamics, and
oligomerization behavior of cutaneous T-cell-attracting chemokine (CTACK, also
known as CCL27) by NMR. (15)N relaxation and translational self-diffusion rates
indicate that CCL27 oligomerizes, but in contrast to many other chemokines that
form relatively discrete oligomers, CCL27 transitions between monomer, dimer,
and tetramer species over a relatively narrow concentration range. A
three-dimensional structure determination was pursued under conditions where
CCL27 is primarily dimeric, revealing the standard motif for a chemokine
monomer. Analysis of chemical shift perturbations of (1)H-(15)N HSQC spectra,
relaxation-dispersion experiments, and filtered nuclear Overhauser effects
suggest that CCL27 does not adopt a discrete CXC or CC dimer motif. Instead,
CCL27 has uncommon oligomerization behavior, where several equilibria involving
relatively low affinity interactions between different interfaces seem to be
simultaneously at work. However, interaction with heparin avidly promotes
oligomerization under conditions where CCL27 is monomeric by itself. We
hypothesize that the plasticity in the oligomerization state may enable CCL27 to
adopt different oligomeric structures, depending on the nature of the GAG
binding partner, thereby providing a mechanism for increased diversity and
specificity in GAG-binding and GAG-related functions.
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