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PDBsum entry 3ogb
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Oxygen transport
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PDB id
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3ogb
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References listed in PDB file
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Key reference
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Title
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Blocking the gate to ligand entry in human hemoglobin.
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Authors
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I.Birukou,
J.Soman,
J.S.Olson.
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Ref.
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J Biol Chem, 2011,
286,
10515-10529.
[DOI no: ]
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PubMed id
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Abstract
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His(E7) to Trp replacements in HbA lead to markedly biphasic bimolecular CO
rebinding after laser photolysis. For isolated mutant subunits, the fraction of
fast phase increases with increasing [CO], suggesting a competition between
binding to an open conformation with an empty E7 channel and relaxation to
blocked or closed, slowly reacting states. The rate of conformational relaxation
of the open state is ∼18,000 s(-1) in α subunits and ∼10-fold faster in β
subunits, ∼175,000 s(-1). Crystal structures were determined for tetrameric
α(WT)β(Trp-63) HbCO, α(Trp-58)β(WT) deoxyHb, and Trp-64 deoxy- and CO-Mb as
controls. In Trp-63(E7) βCO, the indole side chain is located in the solvent
interface, blocking entry into the E7 channel. Similar blocked Trp-64(E7)
conformations are observed in the mutant Mb crystal structures. In Trp-58(E7)
deoxy-α subunits, the indole side chain fills both the channel and the distal
pocket, forming a completely closed state. The bimolecular rate constant for CO
binding, k'(CO), to the open conformations of both mutant Hb subunits is
∼80-90 μm(-1) s(-1), whereas k'(CO) for the completely closed states is
1000-fold slower, ∼0.08 μm(-1) s(-1). A transient intermediate with k'(CO)
≈ 0.7 μm(-1) s(-1) is observed after photolysis of Trp-63(E7) βCO subunits
and indicates that the indole ring blocks the entrance to the E7 channel, as
observed in the crystal structures of Trp(E7) deoxyMb and βCO subunits. Thus,
either blocking or completely filling the E7 channel dramatically slows
bimolecular binding, providing strong evidence that the E7 channel is the major
pathway (≥90%) for ligand entry in human hemoglobin.
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