(Received for publication, September 12, 1996, and in revised form, April 12, 1997)
From the Department of Cell Biology and Anatomy and
the § Lineberger Comprehensive Cancer Center, University of
North Carolina, Chapel Hill, North Carolina 27599-7090
Rhodopsin, the rod cell photoreceptor, undergoes rapid desensitization upon exposure to light, resulting in uncoupling of the receptor from its G protein, transducin (Gt). Phosphorylation of serine and threonine residues located in the COOH terminus of rhodopsin is the first step in this process, followed by the binding of arrestin. In this study, a series of mutants was generated in which these COOH-terminal phosphorylation substrate sites were substituted with alanines. These mutants were expressed in HEK-293 cells and analyzed for their ability to be phosphorylated by rhodopsin kinase and to bind arrestin. The results demonstrate that rhodopsin kinase can efficiently phosphorylate other serine and threonine residues in the absence of the sites reported to be the preferred substrates for rhodopsin kinase. A correlation was observed between the level of rhodopsin phosphorylation and the amount of arrestin binding to these mutants. However, mutants T340A and S343A demonstrated a significant reduction in arrestin binding even though the level of phosphorylation was similar to that of wild-type rhodopsin. Substitution of Thr-340 and Ser-343 with glutamic acid residues (T340E and S343E, respectively) was not sufficient to promote the binding of arrestin in the absence of phosphorylation by rhodopsin kinase. When S343E was phosphorylated, its ability to bind arrestin was similar to that of wild-type rhodopsin. Surprisingly, arrestin binding to phosphorylated T340E did not increase to the level observed for wild-type rhodopsin. These results suggest that 2 amino acids, Thr-340 and Ser-343, play important but distinct roles in promoting the binding of arrestin to rhodopsin.
Receptor desensitization is a critical process in the regulation of G protein-coupled receptor signaling pathways. Serine and threonine residues located either in the COOH terminus or in the third cytoplasmic loop of these receptors serve as substrates for phosphorylation by members of the G protein-coupled receptor kinase family. The G protein-coupled receptor kinases are unique serine/threonine kinases that phosphorylate only the ligand-activated form of G protein-coupled receptors (1, 2). Phosphorylation is followed by the binding of arrestin to the receptor, resulting in rapid termination of G protein activation (3-5). The physiological importance of rapid receptor desensitization has been demonstrated directly in studies of the visual signal transduction system, in which expression of a truncated form of rhodopsin missing the phosphorylation sites and a selective reduction in the levels of arrestin both lead to extended rhodopsin activity (6, 7).
Rhodopsin, the photoreceptor of the rod cell, has been used extensively as a model for investigating the regulation of G protein-coupled receptor desensitization (4). As many as 7 serines and threonines located in the COOH terminus of rhodopsin are substrates in vitro for rhodopsin kinase, the rod cell G protein-coupled receptor kinase, when rhodopsin is activated by light (8). However, several studies have suggested that only 1-2 phosphates are incorporated into rhodopsin in vivo. The binding of rod cell-specific arrestin to light-activated phosphorylated rhodopsin and the reduction of all-trans-retinal to all-trans-retinol after light exposure appear to prevent higher levels of phosphorylation (9, 10). The preferred sites of phosphorylation have been reported to be Ser-334, Ser-338, and Ser-343 depending on whether experiments were performed in vivo, in vitro, or with synthetic peptides as substrates for rhodopsin kinase (9-16). Phosphorylated rhodopsin induces a conformational change in arrestin that promotes its binding to light-activated rhodopsin, interfering with the ability of rhodopsin to activate its G protein, Gt (17, 18). However, the requirement for specific phosphorylation sites for arrestin binding has not been addressed.
In this study, site-directed mutants containing alanine substitutions for the COOH-terminal serine and threonine residues of rhodopsin were expressed in HEK-293 cells and examined for their ability to be phosphorylated and to bind arrestin. The results indicate that rhodopsin kinase can efficiently phosphorylate other serine and threonine residues in the absence of its preferred substrate residues (Ser-334, Ser-338, and Ser-343). A correlation was observed between the levels of rhodopsin phosphorylation and the amount of arrestin binding to the mutants. Two amino acids, Thr-340 and Ser-343, were found to be particularly critical for efficient arrestin binding to rhodopsin, but they may play different roles in promoting this process.
The mammalian cell expression vector pcDNA1/Amp was purchased from Invitrogen. An expression vector for SV40 T antigen (pRSV-TAg) and the cDNA for bovine opsin were gifts from Dr. Jeremy Nathans. The cDNA for bovine arrestin was a gift from Dr. Toshimichi Shinohara. 11-cis-Retinal was a gift from Hoffmann-La Roche. The monoclonal antibody R2-15N, which recognizes the NH2-terminal 15 amino acids of bovine rhodopsin (19), was kindly provided by Dr. Paul Hargrave. Frozen bovine retinas were obtained from J. A. Lawson Inc. (Lincoln, NB). HEK-293 cells were purchased from American Type Culture Collection. [32P]ATP and [35S]methionine were from Amersham Corp. The rabbit reticulocyte lysate system for in vitro synthesis of bovine arrestin was purchased from Promega. The Bio-Spin columns were from Bio-Rad.
MutagenesisThe cDNA for bovine rhodopsin (20) was inserted into the HindIII site of the vector pSelect (Promega) to generate a single-stranded DNA template for mutagenesis (21). Mutations in the COOH terminus of rhodopsin were made using a Promega Altered Sites mutagenesis kit as described previously (21). The mutants were sequenced for verification using Sequenase (Amersham Corp.) according to the manufacturer's directions.
Expression of Rhodopsin MutantsMutants were transiently expressed in HEK-293 cells using DEAE-dextran-mediated transfection as described previously (21). HEK-293 cells were cotransfected with plasmids pRSV-TAg and pcDNA1/Amp containing the rhodopsin cDNA. Approximately 65-70 h after transfection, membranes were prepared by sucrose density gradient centrifugation (22, 21). Protein concentrations were determined as described by Bradford (23). The mutants were analyzed for their ability to activate Gt and to bind 11-cis-retinal using methods described previously (21, 24).
Western Blotting and ElectrophoresisRhodopsin expressed in HEK-293 cells was analyzed by Western blotting using monoclonal antibody R2-15N. Details for immunoblotting and electrophoresis have been described previously (25). The level of rhodopsin expression was quantified using a Molecular Dynamics PhosphorImager. Because of the heterogeneity observed in the mobility of the expressed rhodopsin, due to multiple forms of glycosylation, the entire lane was measured for each sample (24). After subtraction of a background estimated from a lane of nontransfected cell membranes, the amount of rhodopsin was calculated using rod outer segment rhodopsin as a standard. A 62-kDa band was observed in Western blots of wild-type rhodopsin expressed in HEK-293 cells (21, 24, 26) and in mutants T340E/S343E, T340E, and S343E, but was reduced in the alanine-containing mutants (data not shown). This band, which accounts for ~10% of the total rhodopsin, was not phosphorylated (data not shown) and was considered to be inactive. Therefore, the amount of rhodopsin represented by this band was subtracted from the total estimated by immunoblot analysis.
Purification of Rod Outer Segment ProteinsUrea-stripped rod outer segment membranes were purified from frozen, dark-adapted bovine retinas as described previously (27). Rhodopsin kinase was prepared as a crude extract from light-exposed rod outer segment membranes (28, 29).
Phosphorylation of Rhodopsin by Rhodopsin KinasePhosphorylation of bovine rhodopsin expressed in HEK-293
cells was performed using methods similar to those described by Shi et al. (24). HEK-293 cell membranes expressing bovine
rhodopsin were reconstituted with 14 µM
11-cis-retinal for 1 h at room temperature in the dark.
The phosphorylation reaction was initiated by the addition of rod outer
segment extract containing rhodopsin kinase (~20 µl) to a 70-µl
reaction mixture consisting of the HEK-293 cell membranes, 10 mM Tris-HCl, pH 7.4, 260 mM NaCl, 5 mM MgCl2, 0.125 mM EDTA, 0.125 mM EGTA, 2 mM dithiothreitol, 500 nM okadaic acid, and 150 µM
[-32P]ATP (300 µCi/ml). The amount of rhodopsin in
each reaction was 0.33 µg unless otherwise specified. The amount of
total membrane protein in each sample was equalized by the addition of
nontransfected HEK-293 cell membranes. The reaction mixture was
incubated in the dark under Eastman Kodak No. 2 safelights or under
fluorescent room light for 8 min unless otherwise indicated in the
figure legends. The time of 8 min was chosen because the progress of the reaction is close to linear while still giving a detectable signal
(24). The reaction was terminated by placing the samples on ice for 2 min, followed by the addition of 1 ml of ice-cold buffer containing 0.1 mM Tris-HCl, pH 7.5, 50 mM NaF, and 10 mM ATP (buffered to pH 7.5 with Tris-HCl). After
centrifugation at 12,000 × g for 15 min at room
temperature, the pellets were dissolved in 10 mM Tris-HCl,
pH 7.4, and 150 mM NaCl (TBS) containing 1.5% octyl
glucoside, and the reaction mixture was centrifuged to remove insoluble
material. The rhodopsin in the supernatant was immunoprecipitated by
incubation with the R2-15N monoclonal antibody and protein A-Sepharose
beads for 1 h each at room temperature. After three washes in TBS
containing 0.1% sodium deoxycholate and 50 mM NaF, the
protein was extracted from the beads with Laemmli SDS sample buffer and
analyzed by SDS-polyacrylamide gel electrophoresis (30). The level of
phosphorylation was quantified by PhosphorImager analysis of the dried
gels. After subtraction of the amount of phosphorylation in samples
incubated in the dark from the amount obtained in samples exposed to
light, the data were normalized to the level of phosphorylation of
wild-type rhodopsin. To determine the stoichiometry of the phosphate
incorporated into wild-type rhodopsin, the lanes of the gels were cut,
and the radioactivity was measured by liquid scintillation
spectroscopy. During 8-10-min reactions, ~0.4 ± 0.2 mol (S.E.)
of phosphate/mol of wild-type rhodopsin is incorporated.
For the arrestin binding studies, HEK-293 cell membranes containing bovine rhodopsin were prephosphorylated by rhodopsin kinase in a buffer containing 20 mM Tris-HCl, pH 7.5, 2 mM EDTA, 2 mM ATP, and 6 mM MgCl2 at 30 °C for 1 h under fluorescent light or in the dark, as described for each experiment in the figure legends (31, 32). The level of phosphorylation ranged from 0.4 to 0.6 mol/mol of wild-type rhodopsin. Equal amounts of rhodopsin were used for each mutant. To correct for differences in the expression levels of the various mutants, nontransfected cell membranes were added so that the amount of total protein was also the same for each sample. After a 1-h incubation with rhodopsin kinase to phosphorylate the rhodopsin, the reaction was diluted with 1 ml of ice-cold buffer containing 20 mM Tris-HCl, pH 7.5, and 2 mM EDTA (Buffer A). The membranes phosphorylated by rhodopsin kinase were washed twice with Buffer A by centrifugation at 12,000 × g for 15 min. The rhodopsin was regenerated with 14 µM 11-cis-retinal as described above.
The cDNA for bovine arrestin (33) was inserted into pSP73 (Promega) and transcribed in vitro using T7 RNA polymerase. The synthesized arrestin RNA was translated in vitro using rabbit reticulocyte lysate at 30 °C for 1 h in the presence of 2 µl of [35S]methionine (1200 µCi/ml) in a final volume of 25 µl according to the manufacturer's instructions. The synthesized product was centrifuged through a Bio-Spin 6 chromatography column to remove unincorporated [35S]methionine and to exchange the buffer for one containing 30 mM HEPES, 2 mM MgCl2, and 150 mM potassium acetate, pH 7.5 (Buffer B). The amount of synthesized arrestin was estimated from the amount of radioactive methionine incorporated into a hot trichloroacetic acid-insoluble fraction measured by liquid scintillation spectroscopy (34). Approximately 10 fmol of arrestin was used in the arrestin binding assay unless otherwise noted.
The arrestin binding assay was performed using methods similar to those described by Gurevich and Benovic (31, 32). The radiolabeled arrestin and the membranes containing phosphorylated bovine rhodopsin regenerated with 11-cis-retinal were incubated together in Buffer B at 37 °C for 5 min under fluorescent room light. The samples contained 0.1-1.0 µg of rhodopsin as noted in the figure legends. The reaction was terminated by dilution with 200 µl of ice-cold Buffer B. The reaction mixture was layered over a 200-µl cushion of 0.2 M sucrose in Buffer B and centrifuged at 100,000 × g for 30 min at 2 °C. After washing with Buffer B, the membrane pellets containing bound arrestin were dissolved in Laemmli SDS sample buffer and chromatographed on 10% SDS-polyacrylamide gels. The amount of arrestin bound to rhodopsin was quantified by PhosphorImager analysis. The amount of arrestin bound to nonphosphorylated rhodopsin was subtracted from the amount bound to phosphorylated rhodopsin. The results were normalized to the amount of arrestin bound to wild-type rhodopsin.
Statistical and Kinetic AnalysesStatistical tests were performed using the Macintosh computer program Statview (Abacus Concepts, Inc.). Apparent Kd and apparent Bmax values (referred to below as Kd and Bmax) were determined by nonlinear regression analysis of the arrestin binding data using the computer program Prism (GraphPad Software, Inc.).
The COOH-terminal 7 serine and
threonine residues within the rhodopsin sequence Ser-334-Ser-343 have
been proposed to be substrates for rhodopsin kinase in vitro
(Fig. 1) (8). To investigate the ability of these serine
and threonine residues to be phosphorylated by rhodopsin kinase and to
evaluate their importance for arrestin binding, we compared the
phosphorylation of wild-type rhodopsin with that of phosphorylation
site mutants expressed in HEK-293 cells and examined the ability of
these mutants to bind arrestin.
An assay was developed to measure the binding of in vitro
translated arrestin to rhodopsin expressed in HEK-293 cells. Fig. 2A demonstrates that the binding of arrestin
to HEK-293 cell membranes containing light-exposed wild-type rhodopsin
is phosphorylation-dependent; the binding of arrestin to
phosphorylated rhodopsin is typically ~10 times the level of binding
to nonphosphorylated rhodopsin. Fig. 2A also shows that
arrestin does not bind significantly to membranes from nontransfected
cells. Previously, our laboratory developed an assay to measure the
light-dependent phosphorylation of rhodopsin mutants by
rhodopsin kinase (24). This assay was used to determine whether the
sites phosphorylated by rhodopsin kinase that promote arrestin binding
are restricted to the COOH terminus. The rhodopsin mutant K325stop, in
which Lys-325 is replaced by a stop codon causing a deletion of the
COOH-terminal 24 amino acids (21), was expressed in HEK-293 cells and
analyzed for its ability to be phosphorylated and to bind arrestin. The
light-dependent phosphorylation of K325stop is <2% of the
level observed for wild-type rhodopsin (Fig. 2B). This
result is consistent with previous studies in which the removal of the
COOH-terminal 21 amino acids by proteolysis abolished the
phosphorylation of rhodopsin by rhodopsin kinase (35, 36). Our
experiments also demonstrate that K325stop does not bind arrestin (Fig.
2C). Therefore, the phosphorylation sites that promote
arrestin binding to rhodopsin are restricted to these COOH-terminal 7 serine and threonine residues.
To determine whether these phosphorylation sites differ in their
ability to promote arrestin binding, a series of mutants was generated
in which the 7 serine and threonine residues were substituted with
alanines. Alanine was chosen because it is a neutral amino acid and is
less likely to disrupt protein secondary structure (37-39). Initially,
S334A/T335A/T336A, S338A/T340A, and T342A/S343A were generated to
divide the 7 serine and threonine residues into three mutants (Fig.
3). The mutants were assayed for their ability to be
phosphorylated by rhodopsin kinase and to bind arrestin. The triple
mutant S334A/T335A/T336A demonstrated only an 18% decrease in
phosphorylation, whereas phosphorylation was reduced by 40 and 33% for
mutants S338A/T340A and T342A/S343A, respectively (Fig.
4A). S334A/T335A/T336A showed an 18%
reduction in arrestin binding compared with wild-type rhodopsin (Fig.
4B). In contrast, S338A/T340A and T342A/S343A exhibited an
87% and a 68% reduction in arrestin binding, respectively, suggesting that the phosphorylation sites critical for promoting arrestin binding
to rhodopsin are located within the sequence containing Ser-338,
Thr-340, Thr-342, and Ser-343.
Based on these results, additional double amino acid mutants, S338A/S343A and T340A/S343A; the single amino acid mutants S338A, T340A, T342A, and S343A; and two mutants with five alanine substitutions, STTST and STTTT (Fig. 3), were constructed. A comparison of all of the mutants revealed that the level of phosphorylation decreased approximately in proportion to the number of remaining phosphorylation sites (Fig. 4A). The double amino acid mutants showed a greater decrease in phosphorylation than the single amino acid mutants. STTST, which is missing all of the phosphorylation sites except for Thr-340 and Ser-343, and STTTT, which is missing all of the COOH-terminal serines and threonines except for Ser-338 and Ser-343, showed the greatest reduction in phosphorylation, 60 and 64%, respectively. The single exception was the triple amino acid mutant S334A/T335A/T336A, which demonstrated a level of phosphorylation that was within the range of the single amino acid mutants.
These mutants were also tested for their ability to bind arrestin (Fig.
4B). All four mutants containing two alanine substitutions showed reduced arrestin binding compared with wild-type rhodopsin. For
the single amino acid mutants, T340A and S343A exhibited a 55% and a
30% reduction, respectively, whereas S338A and T342A showed no
significant decrease in arrestin binding. These data indicate that
Thr-340 and Ser-343 are important for the binding of arrestin to
rhodopsin. STTTT showed the greatest decrease (94%) in arrestin
binding. The level of arrestin binding was plotted against the level of
phosphorylation for each mutant to determine whether a correlation
between these two properties could be observed (Fig. 5).
Although there is variability within groups missing the same number of
phosphorylation sites, the results demonstrate that arrestin binding
increases as the level of phosphorylation increases. A Pearson
correlation coefficient of 0.83 was calculated from these data,
indicating that 69% (0.832) of the variation in arrestin
binding among the different mutants is due to differences in
phosphorylation (40). These data suggest that the level of
phosphorylation has a significant influence on the level of arrestin
binding.
The reduced binding of arrestin to T340A and S343A could be due either
to a reduced affinity for rhodopsin or to a reduction in the number of
binding sites. To distinguish between these possibilities, the amount
of arrestin bound to T340A and S343A was measured as a function of
arrestin concentration (Fig. 6). The
Kd values (means ± S.E. of five to six experiments
performed in duplicate) for T340A and S343A were 0.91 ± 0.12 and
1.0 ± 0.3 nM, respectively, similar to the value of
0.74 ± 0.11 nM for wild-type rhodopsin. Therefore,
these rhodopsin mutants display only small changes in affinity for
arrestin. In contrast, the number of binding sites (Bmax) for the mutants was dramatically reduced
for the binding of arrestin to the mutants compared with binding to
wild-type rhodopsin. For the experiment shown in Fig. 6, the
Bmax values were 7.8 and 5.9 fmol for T340A and
S343A, respectively, compared with 11.9 fmol for wild-type rhodopsin.
Although the absolute values for Bmax varied
considerably between experiments, the values for the mutants were
always significantly lower than those for wild-type rhodopsin; for
T340A and S343A, the Bmax values (±S.E.) were
50.1 ± 0.1 and 48.8 ± 0.1%, respectively, of the values
for wild-type rhodopsin. These data indicate that mutation of Thr-340 and Ser-343 to alanine results in a change in
Bmax rather than a change in affinity for
arrestin.
Phosphorylation of and Arrestin Binding to Glutamic Acid-substituted Rhodopsin Mutants
The negatively charged amino
acids glutamic acid and aspartic acid have been shown to successfully
mimic phosphorylated serine and threonine residues (41-44). To
determine whether a negative charge at Thr-340 or Ser-343 is sufficient
to promote arrestin binding, mutants T340E, S343E, and T340E/S343E were
constructed (Fig. 3). Compared with T340A/S343A, which showed a 43%
reduction in phosphorylation, T340E/S343E exhibited a level of
phosphorylation only 19% lower than that of wild-type rhodopsin (Fig.
4A). This appeared to be due to an increased rate of
phosphorylation (Fig. 7, A and B),
suggesting that negative charges at these positions enhance the ability
of rhodopsin kinase to phosphorylate the remaining serine and threonine
residues. The levels of phosphorylation for T340E and S343E were
similar to those for the corresponding alanine mutants, T340A and S343A
(Fig. 4A).
Studies of mutants T340E/S343E, S343E, and T340E demonstrated that negative charges at these positions alone are not sufficient to promote arrestin binding in the absence of phosphorylation by rhodopsin kinase (data not shown). However, after phosphorylation by rhodopsin kinase, T340E/S343E and S343E were able to bind arrestin as efficiently as wild-type rhodopsin (Fig. 4B). In contrast, arrestin binding to T340E, which was 47% lower than the binding to wild-type rhodopsin, was not significantly different from the binding to T340A. Therefore, Thr-340 may require a higher negative charge than Ser-343 to promote arrestin binding. Alternatively, the role of Thr-340 in arrestin binding may not be related to its ability to serve as a substrate for phosphorylation.
We have examined the phosphorylation of the 7 serine and threonine residues located in the COOH terminus of rhodopsin and analyzed their role in the binding of arrestin using the approach of in vitro mutagenesis. All of the mutants expressed in HEK-293 cells were able to activate Gt and displayed normal 11-cis-retinal binding (data not shown), indicating that the normal structure of rhodopsin is preserved in these mutants. Despite reports that all 7 residues can be phosphorylated in vitro (3), studies in vivo and in retinal homogenates have suggested that only 3 residues (Ser-334, Ser-338, and Ser-343) actually serve as phosphorylation sites (9, 11). In vivo and in vitro studies differ somewhat in their identification of the primary site of phosphorylation. In vivo, Ser-338 has been reported to be the primary site after a flash of light, whereas Ser-334 is the main phosphorylated residue in continuous light, possibly due to the slower rate of dephosphorylation of Ser-334 (10, 11). In vitro experiments using rod outer segment proteins also suggested that Ser-338 is the major substrate site, followed by Ser-343 (13-15). However, when synthetic peptides corresponding to the rhodopsin COOH terminus are used as phosphorylation substrates, rhodopsin kinase prefers Ser-343 (12, 16). Our results demonstrate that rhodopsin kinase can phosphorylate the COOH terminus almost as efficiently when any of these preferred residues are missing, suggesting that there is little selectivity for different substrate sites. As expected, reduced phosphorylation is observed as increasing numbers of these COOH-terminal sites are replaced with alanines. The single exception is the triple mutant S334A/T335A/T336A, which showed a smaller decrease in phosphorylation than would be expected from the substitution of 3 residues with alanines. These 3 amino acids in wild-type rhodopsin may not be phosphorylated efficiently in our assay system. Alternatively, they may be phosphorylated in a light-independent manner by a kinase such as protein kinase C during expression in HEK-293 cells. Protein kinase C has been reported to phosphorylate rhodopsin within the sequence Ser-334-Thr-335-Thr-336 (45).
In general, there appeared to be a correlation between the level of phosphorylation and the level of arrestin binding. Approximately 69% of the variability in arrestin binding was estimated by statistical analysis to be due to differences in phosphorylation. The lowest levels of arrestin binding were exhibited by mutants such as STTST and STTTT, which displayed the lowest levels of phosphorylation. Despite this correlation, the data also imply that factors other than the degree of phosphorylation influence arrestin binding. Therefore, individual serine and threonine residues may differ in their ability to promote binding. The observation of only a small decrease in arrestin binding for mutant S334A/T335A/T336A suggests that the most critical sites are in the region of the COOH terminus containing Ser-338, Thr-340, Thr-342, and Ser-343. T340A and S343A demonstrated a 48% and a 35% decrease in arrestin binding, respectively, although phosphorylation levels were similar to that of wild-type rhodopsin. These data indicate that Thr-340 and Ser-343 play important roles in arrestin binding. In fact, all of the constructs in which Thr-340 was replaced with alanine (S338A/T340A, T340A/S343A, T340A, and STTTT) showed significantly reduced arrestin binding compared with other mutants with the same number of alanine substitutions.
The binding of arrestin to T340A and S343A was examined as a function
of arrestin concentration to determine whether the observed differences
are due to a change in Kd or
Bmax. Because the active conformation of
rhodopsin, meta-rhodopsin II, decays progressively over time
(3), it is difficult to define precise Kd and
Bmax values for the interaction of rhodopsin
with other proteins. However, arrestin binding stabilizes
meta-rhodopsin II (46). Therefore, direct binding studies
can be used to obtain comparative values for the interaction of
arrestin with wild-type and mutant rhodopsin. An average
Kd of 0.74 ± 0.11 nM obtained in
our studies for the binding of rod cell-specific arrestin to wild-type
rhodopsin is similar to the Kd reported for the
binding of in vitro translated -arrestin to the
m2-muscarinic acetylcholine receptor (0.48 ± 0.04 nM) and is 11-fold lower than the Kd
reported for the binding of rod cell-specific arrestin to the
m2-muscarinic receptor (7.2 ± 1.2 nM)
(32, 47). Therefore, using similar methods, our data fall within a
range of values reported by others for the binding of arrestins to G protein-coupled receptors. Previously, a Kd of ~50
nM for the binding of rod cell-specific arrestin to
rhodopsin was reported, using light scattering techniques to measure
the ability of the arrestin to stabilize meta-rhodopsin II
(46). The reason for the lower affinity observed in these studies is
unclear, but presumably is a result of differences in the methods
employed in those experiments.
As described above, we observed that the Kd values
for T340A and S343A were similar to that for wild-type rhodopsin, despite significant differences in the level of arrestin binding. In
contrast, the Bmax was reduced in all of our
experiments by 35-50% for both mutants. Experiments using either
full-length rhodopsin or COOH-terminal synthetic peptides have shown
that the negatively charged phosphorylated residues of rhodopsin alter the conformation of arrestin, allowing it to bind to light-exposed nonphosphorylated rhodopsin (17, 18). The stable binding of this
activated arrestin is thought to involve an interaction with rhodopsin's cytoplasmic loops (18, 48, 49). This implies that the
interaction of arrestin with the rhodopsin COOH terminus converts
arrestin from a low to a high affinity form. Since our centrifugation
assay requires ~45 min to complete the separation of free from bound
arrestin, we speculate that we are not able to measure the binding of
the low affinity form. This assumption is based on calculations by
Yamamura et al. (50) demonstrating that separation times
would have to be <1.7 min to avoid a loss of >10% of a
ligand-receptor complex if the Kd is
>109 M (see also Table III-2 in Ref. 51).
Therefore, if the COOH-terminal mutations T340A and S343A weaken the
binding of the low affinity form, the resulting change in
Kd would probably not be detected in our assays.
However, as a consequence of that weaker interaction, the conversion of
arrestin to the high affinity form by the COOH terminus would be less
efficient, resulting in a reduced amount of stable arrestin binding,
therefore a reduced Bmax. An alternative
explanation might be that the mutations cause the improper folding,
aggregation, or post-translational modification of rhodopsin, thus
interfering with the binding of arrestin. We view these possibilities
as unlikely since retinal binding, light-dependent Gt activation, and light-dependent
phosphorylation by rhodopsin kinase are all normal. Nevertheless, we
cannot rule out the possibility that the mutations modify the surface
of rhodopsin in some way that partially alters its accessibility to
arrestin, resulting in a reduced Bmax.
Experiments designed to resolve this question include the use of
synthetic peptides corresponding to the phosphorylated COOH terminus of
rhodopsin. We would predict that the phosphorylated wild-type peptide
would be able to induce the binding of arrestin to the T340A and S343A
mutant rhodopsin to levels similar to that of wild-type rhodopsin. In
contrast, T340A and S343A mutant phosphorylated COOH-terminal peptides
would be expected to induce arrestin binding to wild-type rhodopsin
that demonstrates a reduced Bmax.
The Bmax values obtained in our studies are
significantly lower than one would expect, based on the assumed 1:1
stoichiometry between phosphorylated rhodopsin and arrestin. For
example, in the experiment shown in Fig. 6, an estimated 1.2 pmol of
phosphorylated rhodopsin was used. However, the
Bmax for the binding of arrestin to wild-type
rhodopsin was only 12.6 fmol. There are a number of reasons that may
contribute to these low values. First, the stoichiometry of
phosphorylation ranges from 0.4 to 0.6 mol/mol of rhodopsin in our
experiments. Since our results suggest that the level of
phosphorylation influences arrestin binding, it is possible that only a
small fraction of rhodopsin has a sufficient number of phosphates to
efficiently promote arrestin binding. A second possibility lies in the
stability of light-activated rhodopsin. Gurevich et al. (47)
observed that the binding of -arrestin to the
m2-muscarinic acetylcholine receptor was ~30% and the
binding of visual arrestin to the same receptor was only 14% of what
would be expected based on a 1:1 stoichiometry. The authors suggested
that this may be related to a lack of stability of the
agonist-receptor-arrestin complex. Similarly, the instability of
meta-rhodopsin II in our experiments could lead to lower
values for Bmax. Despite these drawbacks to
determining Bmax, our results clearly indicate
that relative Bmax values are reduced for
mutants T340A and S343A compared with that for wild-type rhodopsin.
Negative charges were introduced through the substitution of Thr-340 and Ser-343 with glutamic acids, and the results of phosphorylation and arrestin binding were compared with those of wild-type rhodopsin and the corresponding alanine mutants. None of the glutamic acid mutants was able to bind arrestin without first being phosphorylated by rhodopsin kinase. Mutant T340E/S343E showed enhanced phosphorylation compared with the equivalent alanine mutant (T340A/S343A). This result suggests that the introduction of two negative charges enhances the rate of phosphorylation of the remaining serine and threonine residues. A similar cooperativity has been observed by measuring the rate of phosphorylation of rhodopsin containing different numbers of phosphates or the phosphorylation of synthetic peptide substrates corresponding to the rhodopsin COOH terminus (8, 52-55). Glutamic acid substitution also enhanced the phosphorylation of the formyl-Met-Leu-Phe receptor by the G protein-coupled receptor kinase GRK2 (44), implying that cooperativity may be common to the phosphorylation of G protein-coupled receptors by other members of this kinase family. T340E/S343E also showed increased binding to arrestin compared with the equivalent alanine-substituted mutant, consistent with the role of phosphorylation in promoting a conformational change in arrestin that allows it to bind to other sites in rhodopsin (18, 48, 49). When Ser-343 was replaced with glutamic acid (S343E), an increase in arrestin binding to a level comparable to that of wild-type rhodopsin was observed, even though there was little change in the level of phosphorylation. In contrast, T340E showed no increase in arrestin binding compared with T340A. Interestingly, T340E/S343E binds arrestin better than the single amino acid mutant T340E. It may be that the enhanced phosphorylation observed for T340E/S343E increases the efficiency with which arrestin undergoes its conformational change and compensates for the partial loss of function at Thr-340.
It has been reported that Thr-340 is not phosphorylated in vivo under conditions where arrestin binds to rhodopsin. Therefore, the requirement for Thr-340 may not involve its ability to be phosphorylated; rather, substitution with either alanine or glutamic acid may disrupt its function. As described above, a phosphorylated synthetic peptide corresponding to the rhodopsin COOH terminus induces a conformational change in arrestin and promotes its binding to rhodopsin (18). In contrast, heparin, a negatively charged glycosaminoglycan, causes a conformational change in arrestin, but does not induce arrestin to bind to rhodopsin (17). Therefore, the COOH terminus of rhodopsin, or the corresponding synthetic peptide, appears to serve a function in addition to providing negative charges to promote the interaction of arrestin with rhodopsin. Perhaps Thr-340 plays a role in this function. Although we cannot rule out the possibility that the single negative charge of glutamic acid is not sufficient to mimic the electrostatic interactions of a phosphate in the case of T340E, a preliminary report of experiments in which all seven phosphorylation sites were mutated to glutamic acids indicated that the presence of multiple negative charges was not sufficient to promote arrestin-mediated inhibition of Gt activation (56). These results are consistent with the possibility that the COOH terminus serves a function apart from providing a negatively charged environment. The elucidation of that function will aid in the understanding of the interactions between rhodopsin and arrestin.
We thank Drs. T. Kendall Harden and Richard B. Mailman for helpful discussions and Dr. Cindy Lawler for advice and assistance with the statistical analysis. We also thank Drs. Paul Hargrave, Jeremy Nathans, and Toshimichi Shinohara for the gifts of the reagents used in our studies.