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PDBsum entry 4i0b
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Transcription
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PDB id
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4i0b
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References listed in PDB file
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Key reference
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Title
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Modulation of global low-Frequency motions underlies allosteric regulation: demonstration in crp/fnr family transcription factors.
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Authors
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T.L.Rodgers,
P.D.Townsend,
D.Burnell,
M.L.Jones,
S.A.Richards,
T.C.Mcleish,
E.Pohl,
M.R.Wilson,
M.J.Cann.
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Ref.
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Plos Biol, 2013,
11,
e1001651.
[DOI no: ]
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PubMed id
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Abstract
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Allostery is a fundamental process by which ligand binding to a protein alters
its activity at a distinct site. There is growing evidence that allosteric
cooperativity can be communicated by modulation of protein dynamics without
conformational change. The mechanisms, however, for communicating dynamic
fluctuations between sites are debated. We provide a foundational theory for how
allostery can occur as a function of low-frequency dynamics without a change in
structure. We have generated coarse-grained models that describe the protein
backbone motions of the CRP/FNR family transcription factors, CAP of Escherichia
coli and GlxR of Corynebacterium glutamicum. The latter we demonstrate as a new
exemplar for allostery without conformation change. We observe that binding the
first molecule of cAMP ligand is correlated with modulation of the global normal
modes and negative cooperativity for binding the second cAMP ligand without a
change in mean structure. The theory makes key experimental predictions that are
tested through an analysis of variant proteins by structural biology and
isothermal calorimetry. Quantifying allostery as a free energy landscape
revealed a protein "design space" that identified the inter- and
intramolecular regulatory parameters that frame CRP/FNR family allostery.
Furthermore, through analyzing CAP variants from diverse species, we demonstrate
an evolutionary selection pressure to conserve residues crucial for allosteric
control. This finding provides a link between the position of CRP/FNR
transcription factors within the allosteric free energy landscapes and
evolutionary selection pressures. Our study therefore reveals significant
features of the mechanistic basis for allostery. Changes in low-frequency
dynamics correlate with allosteric effects on ligand binding without the
requirement for a defined spatial pathway. In addition to evolving suitable
three-dimensional structures, CRP/FNR family transcription factors have been
selected to occupy a dynamic space that fine-tunes biological activity and thus
establishes the means to engineer allosteric mechanisms driven by low-frequency
dynamics.
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