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Query: EC:3.1.4.1 (
phosphodiesterase
)
18,767
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
The structural and functional properties of
arrestin
were studied by subjecting the protein to limited proteolysis. Limited proteolysis by trypsin cleaves
arrestin
(48 kDa), producing 20-25-kDa fragments. Prior to this stage of proteolysis, trypsin produced 46.6-, 45.4-, and 42-kDa fragments. Structural analysis of the proteolytic fragments demonstrated major cleavage at the carboxyl terminus, indicating that the carboxyl terminus is highly exposed. We found that forms of
arrestin
truncated at their carboxyl terminus maintained their functional properties and bound to phosphorylated rhodopsin. Native
arrestin
binds only to photoexcited phosphorylated rhodopsin, whereas the truncated
arrestin
binds to phosphorylated rhodopsin independent of its exposure to light. The truncated forms of
arrestin
were separated from native
arrestin
by a chromatographic procedure and subsequently characterized in functional studies. The binding of the truncated forms of
arrestin
to phosphorylated photoexcited rhodopsin is more tight than the binding of native
arrestin
as determined by a direct binding assay and the
phosphodiesterase
assay. We suggest that the acidic carboxyl-terminal region of
arrestin
may act as a regulator for light-dependent binding to phosphorylated rhodopsin.
...
PMID:Role of the carboxyl-terminal region of arrestin in binding to phosphorylated rhodopsin. 165 26
In vertebrate photoreceptors the soluble protein
arrestin
(45 kDa) is involved in controlling the light dependent activity of receptor proteins such as transducin or the cGMP-
phosphodiesterase
. Arrestin has further been identified as the retinal-S-antigen which is assumed to cause the autoimmune disease uveitis. In a first communication a binding of the nucleotide ATP to
arrestin
was described. In this subsequent study it is shown that
arrestin
is also able to hydrolyse ATP at a rate of (5.1 +/- 0.3) x 10(-3) U/mg.min with C1/2 = 93 +/- 5 nM and a Hill coefficient n = 1.8 +/- 0.1 at pH 7.2 and 20 degrees C. These findings suggest a new insight into the process of regulating photoreceptor activity.
...
PMID:Evidence for ATP-ase activity of arrestin from bovine photoreceptors. 182 40
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.
...
PMID:Phosphorylated rhodopsin and heparin induce similar conformational changes in arrestin. 191 88
Arrestin (also called S-antigen or 48-kDa protein) binds to photoexcited and phosphorylated rhodopsin and, thereby, blocks competitively the activation of transducin. Using Ca2+ titration in the presence of the indicator arsenazo III and 45Ca2+ autoradiography, we show that
arrestin
is a Ca2(+)-binding protein. The Ca2+ binding capacity of arresting-containing protein extracts from bovine rod outer segments is about twice as high as that of
arrestin
-depleted extracts. The difference in the Ca2+ binding of
arrestin
-containing and
arrestin
-depleted protein extracts was attributed to
arrestin
. Both, these difference-measurements of protein extracts and the measurements of purified
arrestin
yield dissociation constants for the Ca2+ binding of
arrestin
between 2 and 4 microM. The titration curves are consistent with a molar ratio of one Ca2+ binding site per
arrestin
. No Ca2+ binding in the micromolar range was found in extracts containing mainly transducin and cGMP-
phosphodiesterase
. Since
arrestin
is one of the most abundant proteins in rod photoreceptors occurring presumably up to millimolar concentrations in rod outer segments, we suggest that aside from its function to prevent the activation of transducin,
arrestin
acts probably as an intracellular Ca2+ buffer.
...
PMID:Ca2+ binding capacity of cytoplasmic proteins from rod photoreceptors is mainly due to arrestin. 216 Sep 81
Cyclic GMP is central to visual excitation in vertebrate retinal rod cells. Sodium channels in the plasma membrane of the outer segment are kept open in the dark by a high level of cGMP. Light closes these channels by activating an enzymatic cascade that leads to the rapid hydrolysis of cGMP. Photoexcited rhodopsin triggers transducin by catalyzing the exchange of GTP for bound GDP. The activated GTP-form of transducin then switches on the
phosphodiesterase
by overcoming an inhibitory constraint. The overall gain of this cascade is about 10(5). The cascade is turned off by the GTPase activity of transducin and by the action of rhodopsin kinase and
arrestin
. One of the challenges now is to delineate the interplay of cGMP, calcium ion, and phosphoinositides in excitation and adaptation. Transducin belongs to a family of signal-coupling proteins that includes the G proteins of the hormone-regulated adenylate cyclase cascade. The initial events in visual excitation in molluscs and arthropods are probably similar to those of vertebrates. The triggering of transducin by photoexcited rhodopsin is a recurring motif in visual transduction. The coming together of electrophysiology, biochemistry, and molecular genetics affords new opportunities in unraveling the molecular mechanism of visual transduction.
...
PMID:Cyclic GMP cascade of vision. 242 11
We have previously reported that the purified GDP-bound alpha-subunit of the GTP-binding protein transducin (TD), present in outer segments of retinal rod cells (ROS), serves as a high affinity substrate (Km = 1 microM) for protein kinase C (PKC) [Zick et al. (1986) Proc. natn. Acad. Sci., U.S.A. 83, 9294-9297]. In the present study we demonstrate that TD-alpha undergoes phosphorylation by PKC when present in its native form in intact ROS membranes. This phosphorylation is inhibited by GTP-gamma-S which activates TD, suggesting that it is only the inactive conformation of TD-alpha that serves as a substrate for PKC. Indeed, both vanadate and AlF4, that confer an active conformation on TD-alpha-GDP, inhibit PKC-mediated phosphorylation of purified TD-alpha-GDP. We demonstrate that the purified beta subunit of TD also serves as an in vitro substrate for PKC. Moreover, following their phosphorylation, both TD-alpha and beta form high affinity complexes with PKC. This is evident from the findings that PKC coprecipitates with both the alpha and beta subunits of TD when the latter are immunoprecipitated by their respective antibodies. PKC phosphorylates additional ROS proteins of 36, 48 and 92 kDa, tentatively identified as rhodopsin,
arrestin
and the cGMP-
phosphodiesterase
. Taken together our results strongly suggest that phosphorylation of TD is of physiological relevance and that through phosphorylation of endogenous ROS proteins, PKC could play a key role in regulating phototransduction.
...
PMID:Protein kinase C-mediated phosphorylation of retinal rod outer segment membrane proteins. 264 84
The target proteins for
arrestin
(48 kDa protein) action during the quench of cGMP phosphodiesterase (
PDE
) activation in retinal rod disk membranes were identified by the use of a cross-linking reagent. A heterobifunctional, cleavable, photo-activatable cross-linker (sulfo-SADP) was coupled to purified
arrestin
. Under precise weak visible light bleach and nucleotide conditions of quench, the cross-linker was UV flash-activated at a time when quench was well established. The target proteins covalently linked to
arrestin
by cross-linker activation were identified by immunoblotting. In the presence of ATP
arrestin
cross-linked to both
PDE
and rhodopsin during the quench phenomenon. Removal of ATP from the reaction mixture essentially abolished the cross-link with
PDE
, just as ATP omission abolishes quench, but significantly increased the cross-link to rhodopsin. The absence of a cross-link to the plentiful beta-subunit of transductin, as well as the results of competition studies employing
arrestin
without attached cross-linker, suggest that the observed cross-links are specific and reflect true binding interactions of
arrestin
during quench. The data are consistent with a model of quench in which photolyzed rhodopsin (R*) catalyzes the formation of an activated form of
arrestin
, which dissociates from R* in the presence of ATP, and binds to PDEs, thereby deactivating them.
...
PMID:Sites of arrestin action during the quench phenomenon in retinal rods. 284 5
Photoactivated rhodopsin (R) catalyses, by repetitively interacting with many copies of a guanosine nucleotide binding protein (transducin), the amplified binding of GTP to transducin molecules which then activate cyclic GMP phosphodiesterase. Electrophysiologists recently have shown that cyclic GMP keeps ion channels in the plasma membrane of the rod outer segment open in darkness, and that light-induced hydrolysis of cyclic GMP leads to closure of the channels and therefore to hyperpolarization of the rod cell. Photoactivated rhodopsin interacts not only with transducin, but with two more proteins: a protein kinase that specifically phosphorylates R (in contrast to dark-adapted rhodopsin) at multiple sites; and an abundant soluble protein of 48 KDal (called 48 K-protein, S-antigen, or
arrestin
) that specifically binds to phosphorylated R. Phosphorylation partially suppresses the ability of R to catalyze transducin-mediated
phosphodiesterase
activation even in the absence of
arrestin
. Binding of
arrestin
to the phosphorylated R potentiates this inhibitory effect, most probably because
arrestin
competes with transducin for binding on the phosphorylated R. Phosphorylation, in conjunction with
arrestin
binding, therefore appears to be a mechanism that terminates the active state of the receptor, R.
...
PMID:Deactivation of photoactivated rhodopsin by rhodopsin-kinase and arrestin. 304 Sep 78
The inactivation of excited rhodopsin in the presence of ATP, rhodopsin kinase, and/or
arrestin
has been studied from its effect on the two subsequent steps in the light-induced enzymatic cascade: metarhodopsin II catalyzed activation of G-protein and G-protein-dependent activation of cGMP phosphodiesterase. The inactivation of G-protein (from light-scattering measurements) and that of
phosphodiesterase
(from measurements of cGMP hydrolysis) have been studied and compared in reconstituted systems containing various combinations of the proteins involved (rhodopsin, G-protein,
phosphodiesterase
, kinase, and
arrestin
). Our results show that rhodopsin kinase alone can terminate the activation of G-protein and that
arrestin
speeds up the process at a relative concentration similar to that reported in the rod (half-maximal effect at 50 nM for 4.4 microM rhodopsin). Measurements of rhodopsin phosphorylation under identical conditions show that in the presence of
arrestin
total metarhodopsin II inactivation is achieved when only 0.5-1.4 phosphates are bound per bleached rhodopsin, whereas in the absence of
arrestin
it requires binding of 12-16 phosphates per bleached rhodopsin. Phosphodiesterase activity can similarly be turned off by kinase, and the process is similarly accelerated by
arrestin
.
...
PMID:Inactivation of photoexcited rhodopsin in retinal rods: the roles of rhodopsin kinase and 48-kDa protein (arrestin). 336 20
We expressed the gamma subunit of mouse rod photoreceptor cGMP phosphodiesterase (
PDE
) in the bacterial pGFX-2TK expression vector which produces a cleavable 40 kDa fusion protein. The fusion protein can be isolated in a one step procedure by affinity chromatography on glutathione beads. The yield of purified fusion protein is approximately 10 mg from 1 liter of bacterial culture, or about 3 mg of
PDE
gamma equivalent to the
PDE
gamma content of approximately 200,000 mouse retinas. Both the fusion protein and the cleaved
PDE
gamma, to which a short kinase domain remains attached, are biologically active, inhibiting activated
PDE
in a manner comparable to native
PDE
gamma. Immobilized
PDE
gamma binds transducin alpha subunit charged with GTP,
PDE
alpha and beta subunits, and, unexpectedly,
arrestin
(S-antigen).
...
PMID:Expression of mouse rod photoreceptor cGMP phosphodiesterase gamma subunit in bacteria. 838 31
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