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PDBsum entry 5t7h
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Electron transport
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PDB id
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5t7h
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References listed in PDB file
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Key reference
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Title
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Cytochrome c can form a well-Defined binding pocket for hydrocarbons.
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Authors
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L.J.Mcclelland,
H.B.Steele,
F.G.Whitby,
T.C.Mou,
D.Holley,
J.B.Ross,
S.R.Sprang,
B.E.Bowler.
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Ref.
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J Am Chem Soc, 2016,
138,
16770-16778.
[DOI no: ]
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PubMed id
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Abstract
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Cytochrome c can acquire peroxidase activity when it binds to cardiolipin in
mitochondrial membranes. The resulting oxygenation of cardiolipin by cytochrome
c provides an early signal for the onset of apoptosis. The structure of this
enzyme-substrate complex is a matter of considerable debate. We present three
structures at 1.7-2.0 Å resolution of a domain-swapped dimer of yeast
iso-1-cytochrome c with the detergents, CYMAL-5, CYMAL-6, and
ω-undecylenyl-β-d-maltopyranoside, bound in a channel that places the
hydrocarbon moieties of these detergents next to the heme. The heme is poised
for peroxidase activity with water bound in place of Met80, which serves as the
axial heme ligand when cytochrome c functions as an electron carrier. The
hydroxyl group of Tyr67 sits 3.6-4.0 Å from the nearest carbon of the
detergents, positioned to act as a relay in radical abstraction during
peroxidase activity. Docking studies with linoleic acid, the most common fatty
acid component of cardiolipin, show that C11 of linoleic acid can sit adjacent
to Tyr67 and the heme, consistent with the oxygenation pattern observed in
lipidomics studies. The well-defined hydrocarbon binding pocket provides atomic
resolution evidence for the extended lipid anchorage model for cytochrome
c/cardiolipin binding. Dimer dissociation/association kinetics for yeast versus
equine cytochrome c indicate that formation of mammalian cytochrome c dimers in
vivo would require catalysis. However, the dimer structure shows that only a
modest deformation of monomeric cytochrome c would suffice to form the
hydrocarbon binding site occupied by these detergents.
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