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J. Biol. Chem., Vol. 266, Issue 28, 18649-18654, 10, 1991
K Palczewski, A Pulvermuller, J Buczylko and KP Hofmann
Photoactivated rhodopsin is quenched upon its phosphorylation in the
reaction catalyzed by rhodopsin kinase and the subsequent binding of a
regulatory protein, arrestin. We have found that heparin and other
polyanions compete with photoactivated, phosphorylated rhodopsin to bind
arrestin (48-kDa protein, S-antigen). This is shown (a) by the suppression
of stabilized metarhodopsin II; (b) by changes in the digestion of arrestin
in the presence of heparin; and (c) by the restoration of arrestin-quenched
phosphodiesterase activity. When bound to arrestin, heparin also mimics
phosphorylated rhodopsin by similarly exposing arrestin to limited
proteolysis. We conclude that heparin and rhodopsin have similar means of
binding to arrestin, and we propose a cationic region of arrestin
(beginning with Lys163 of the bovine sequence) as the interaction site. In
agreement with previous kinetic data we interpret the results in terms of a
binding conformation of arrestin which is stabilized by rhodopsin or
heparin and is open to proteolytic attack.
Phosphorylated rhodopsin and heparin induce similar conformational changes in arrestin
R.S. Dow Neurological Sciences Institute, Good Samaritan Hospital and Medical Center, Portland, Oregon 97209.
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