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PDBsum entry 2aur
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Oxygen storage/transport
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PDB id
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2aur
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References listed in PDB file
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Key reference
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Title
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Residue f4 plays a key role in modulating oxygen affinity and cooperativity in scapharca dimeric hemoglobin.
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Authors
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J.E.Knapp,
M.A.Bonham,
Q.H.Gibson,
J.C.Nichols,
W.E.Royer.
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Ref.
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Biochemistry, 2005,
44,
14419-14430.
[DOI no: ]
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PubMed id
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Abstract
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Residue F4 (Phe 97) undergoes the most dramatic ligand-linked transition in
Scapharca dimeric hemoglobin, with its packing in the heme pocket in the
unliganded (T) state suggested to be a primary determinant of its low affinity.
Mutation of Phe 97 to Leu (previously reported), Val, and Tyr increases oxygen
affinity from 8- to 100-fold over that of the wild type. The crystal structures
of F97L and F97V show side chain packing in the heme pocket for both R and T
state structures. In contrast, in the highest-affinity mutation, F97Y, the
tyrosine side chain remains in the interface (high-affinity conformation) even
in the unliganded state. Comparison of these mutations reveals a correlation
between side chain packing in the heme pocket and oxygen affinity, indicating
that greater mass in the heme pocket lowers oxygen affinity due to impaired
movement of the heme iron into the heme plane. The results indicate that a key
hydrogen bond, previously hypothesized to have a central role in regulation of
oxygen affinity, plays at most only a small role in dictating ligand affinity.
Equivalent mutations in sperm whale myoglobin alter ligand affinity by only
5-fold. The dramatically different responses to mutations at the F4 position
result from subtle, but functionally critical, stereochemical differences. In
myoglobin, an eclipsed orientation of the proximal His relative to the A and C
pyrrole nitrogen atoms provides a significant barrier for high-affinity ligand
binding. In contrast, the staggered orientation of the proximal histidine found
in liganded HbI renders its ligand affinity much more susceptible to packing
contacts between F4 and the heme group. These results highlight very different
strategies used by cooperative hemoglobins in molluscs and mammals to control
ligand affinity by modulation of the stereochemistry on the proximal side of the
heme.
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