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PDBsum entry 4ndk
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Fluorescent protein, de novo protein
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PDB id
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4ndk
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References listed in PDB file
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Key reference
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Title
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Using molecular dynamics simulations as an aid in the prediction of domain swapping of computationally designed protein variants.
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Authors
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Y.Mou,
P.S.Huang,
L.M.Thomas,
S.L.Mayo.
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Ref.
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J Mol Biol, 2015,
427,
2697-2706.
[DOI no: ]
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PubMed id
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Abstract
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In standard implementations of computational protein design, a positive-design
approach is used to predict sequences that will be stable on a given backbone
structure. Possible competing states are typically not considered, primarily
because appropriate structural models are not available. One potential competing
state, the domain-swapped dimer, is especially compelling because it is often
nearly identical with its monomeric counterpart, differing by just a few
mutations in a hinge region. Molecular dynamics (MD) simulations provide a
computational method to sample different conformational states of a structure.
Here, we tested whether MD simulations could be used as a post-design screening
tool to identify sequence mutations leading to domain-swapped dimers. We
hypothesized that a successful computationally designed sequence would have
backbone structure and dynamics characteristics similar to that of the input
structure and that, in contrast, domain-swapped dimers would exhibit increased
backbone flexibility and/or altered structure in the hinge-loop region to
accommodate the large conformational change required for domain swapping. While
attempting to engineer a homodimer from a 51-amino-acid fragment of the
monomeric protein engrailed homeodomain (ENH), we had instead generated a
domain-swapped dimer (ENH_DsD). MD simulations on these proteins showed
increased B-factors derived from MD simulation in the hinge loop of the ENH_DsD
domain-swapped dimer relative to monomeric ENH. Two point mutants of ENH_DsD
designed to recover the monomeric fold were then tested with an MD simulation
protocol. The MD simulations suggested that one of these mutants would adopt the
target monomeric structure, which was subsequently confirmed by X-ray
crystallography.
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