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PDBsum entry 1n0d
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De novo protein
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PDB id
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1n0d
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References listed in PDB file
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Key reference
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Title
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Stability of cyclic beta-Hairpins: asymmetric contributions from side chains of a hydrogen-Bonded cross-Strand residue pair.
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Authors
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S.J.Russell,
T.Blandl,
N.J.Skelton,
A.G.Cochran.
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Ref.
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J Am Chem Soc, 2003,
125,
388-395.
[DOI no: ]
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PubMed id
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Abstract
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Amino acid structural propensities measured in "host-guest" model studies are
often used in protein structure prediction or to choose appropriate residues in
de novo protein design. While this concept has proven useful for helical
structures, it is more difficult to apply successfully to beta-sheets. We have
developed a cyclic beta-hairpin scaffold as a host for measurement of individual
residue contributions to hairpin structural stability. Previously, we have
characterized substitutions in non-backbone-hydrogen-bonded strand sites;
relative stability differences measured in the cyclic host are highly predictive
of changes in folding free energy for linear beta-hairpin peptides. Here, we
examine the hydrogen-bonded strand positions of our host. Surprisingly, we find
a large favorable contribution to stability from a valine (or isoleucine)
substitution immediately preceding the C-terminal cysteine of the host peptide,
but not at the cross-strand position of the host or in either strand of a folded
linear beta-hairpin (trpzip peptide). Further substitutions in the peptides and
NMR structural analysis indicate that the stabilizing effect of valine is
general for CX(8)C cyclic hairpins and cannot be explained by particular
side-chain-side-chain interactions. Instead, a localized decrease in twist of
the peptide backbone on the N-terminal side of the cysteine allows the valine
side chain to adopt a unique conformation that decreases the solvent
accessibility of the peptide backbone. The conformation differs from the highly
twisted (coiled) conformation of the trpzip hairpins and is more typical of
conformations present in multistranded beta-sheets. This unexpected structural
fine-tuning may explain why cyclic hairpins selected from phage-displayed
libraries often have valine in the same position, preceding the C-terminal
cysteine. It also emphasizes the diversity of structures accessible to
beta-strands and the importance of considering not only "beta-propensity", but
also hydrogen-bonding pattern and strand twist, when designing beta structures.
Finally, we observe correlated, cooperative stabilization from side-chain
substitutions on opposite faces of the hairpin. This suggests that cooperative
folding in beta-hairpins and other small beta-structures is driven by
cooperative strand-strand association.
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