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PDBsum entry 1xxt
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Transport protein
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PDB id
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1xxt
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References listed in PDB file
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Key reference
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Title
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Crystallographic evidence for a new ensemble of ligand-Induced allosteric transitions in hemoglobin: the t-To-T(high) quaternary transitions.
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Authors
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J.S.Kavanaugh,
P.H.Rogers,
A.Arnone.
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Ref.
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Biochemistry, 2005,
44,
6101-6121.
[DOI no: ]
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PubMed id
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Abstract
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A detailed description of hemoglobin cooperativity requires knowledge of the
dimer-dimer interactions responsible for the low ligand affinity of the
quaternary-T tetramer, the "quaternary-T constraints", along with stereochemical
pathways that specify how ligand binding disrupts these quaternary constraints.
The recent mutagenic screen of Noble et al. [Noble, R. W., et al. (2001)
Biochemistry 40, 12357-12368] has identified the major region of quaternary
constraint to be a cluster of residues at the alpha1beta2 interface that is
centered at Trp37beta. In this paper, crystallographic studies are presented for
most of the mutant hemoglobins studied by Noble et al. These crystallographic
experiments identify structural transitions-referred to as T-to-T(High)
transitions-between the quaternary-T structure of wild-type deoxyhemoglobin and
an ensemble of related T-like quaternary structures that are induced by some
mutations in the Trp37beta cluster and/or by exposing crystals of wild-type or
mutant deoxyhemoglobins to oxygen. The T-to-T(High) quaternary transitions
consist of a rotation of the alpha1beta1 dimer relative to the alpha2beta2 dimer
as well as a coupled alphabeta dimer bending component that consists of a small
rotation of the alpha1 subunit relative to the beta1 subunit (and a symmetry
related rotation of the alpha2 subunit relative to the beta2 subunit). In
addition, differences in subunit tertiary structure associated with the
T-to-T(High) transitions suggest two stereochemical pathways (one associated
with the alpha subunits and one associated with the betasubunits) by which
ligand binding specifically disrupts quaternary constraints in the Trp37beta
cluster. In the alpha subunits, ligand binding induces a shift of the heme iron
producing tension in a chain of covalent bonds that extends from the
Fe-N(epsilon)(2)His(F8)alpha1 bond to the peptide backbone bonds of residues
His87(F8)alpha1 and Ala88(F9)alpha1. This tension induces an alpha-to-pi
transition in the COOH-terminal end of the F-helix that shifts the beta-carbon
of Ala88alpha1 by approximately 1.5 A directly into the side chain of
Tyr140alpha1 (a key residue in the Trp37beta2 cluster). Collectively these
structural changes constitute a relatively short pathway by which ligand binding
forces Tyr140alpha1 into the alpha1beta2 interface disrupting quaternary
constraints associated with the Trp37beta2 cluster. In the beta subunits, our
analysis suggests a more extended energy transduction pathway in which
ligand-induced beta1-heme movement triggers tertiary changes in the beta1
subunit that promote alpha1beta1 dimer bending that disrupts quaternary
constraints in the Trp37beta2 cluster at the alpha1beta2 interface.
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