Originally published In Press as doi:10.1074/jbc.M006756200 on September 19, 2000
J. Biol. Chem., Vol. 275, Issue 49, 38281-38285, December 8, 2000
Tyrosine Phosphorylation of the 
-Opioid Receptor Regulates
Agonist Efficacy*
Suzanne M.
Appleyard
§¶,
Jay P.
McLaughlin
, and
Charles
Chavkin§**
From the Department of Pharmacology and the
§ Neurobiology Program, University of Washington,
Seattle, Washington 98195-7280
Received for publication, July 27, 2000, and in revised form, September 14, 2000
 |
ABSTRACT |
To explore the role of highly conserved
tyrosine residues in the putative cytoplasmic domains of the
seven-transmembrane G protein-coupled opioid receptors, we expressed
the rat 
-opioid receptor (KOR) in Xenopus oocytes and
then activated the intrinsic insulin receptor tyrosine kinase. KOR
activation by the agonist U69593 produced a strong increase in
potassium current through coexpressed G protein-gated inwardly
rectifying potassium channels (KIR3). Brief pretreatment
with insulin caused a 60% potentiation of the KOR-activated response.
The insulin-induced increase in -opioid response was blocked by the
tyrosine kinase inhibitor genistein. In contrast, insulin had no effect
on the basal activity of KIR3, suggesting that KOR is the
target of the tyrosine kinase cascade. Mutation of tyrosine residues to
phenylalanines in either the first or second intracellular loop of KOR
to produce KOR(Y87F) and KOR(Y157F) had no effect on either the potency
or maximal effect of U69593. However, neither KOR(Y87F)- nor
KOR(Y157F)-mediated responses were potentiated by insulin treatment.
Insulin pretreatment shifted the dose-response curve for U69593
activation of KOR by increasing the maximal response without changing
the EC50 value for U69593. These results suggest that
insulin increases the efficacy of KOR activation by phosphorylating two
tyrosine residues in the first and second intracellular loops of the
receptor. Thus, tyrosine phosphorylation may provide an important
mechanism for modulation of G protein-coupled receptor signaling.
| |
INTRODUCTION |
Opioid receptors are widely expressed throughout the nervous
system, and opioid drugs affect pain perception, learning and memory,
epilepsy, and food intake, among other diverse functions (1). A common
mechanism for post-translational regulation of protein function is by
phosphorylation, and phosphorylation of opioid receptors is likely to
regulate opioid actions. For example, phosphorylation by G protein
receptor kinases following agonist treatment has been proposed to play
a role in opioid receptor desensitization and tolerance (2). Other
serine/threonine kinases such as protein kinase C and
calcium/calmodulin-dependent kinase II in some systems may also
regulate opioid receptors (3).
To date, few studies have reported any effects of tyrosine kinases on
acute opioid receptor function. Tyrosine residues in the putative
cytoplasmic domains of G protein-coupled receptors are extremely
common, and regulation of opioid receptor signaling by tyrosine kinase
cascades would provide a powerful mechanism of cellular coordination.
Indeed, a portion of the agonist-induced internalization of the
µ-opioid receptor is dependent on tyrosine kinase activation (4-6).
Opioid receptor activation has been shown to increase tyrosine kinase
activity (7, 8), and the agonist-induced internalization mediated by
tyrosine kinase could potentially involve a process that is directly
activated by opioid receptors. These findings are consistent with data
on the 
2-adrenergic receptor in which tyrosine
phosphorylation of the C-terminal tail was shown to play a role in the
desensitization and internalization of the 2-adrenergic
receptor (9). In addition to the inhibitory effects of tyrosine kinases
on G protein-coupled receptor function, Valiquette et al.
(10) reported that tyrosine phosphorylation of the
2-adrenergic receptor on the second intracellular loop potentiated 2-adrenergic receptor activation of
adenylate cyclases. Although the interactions are not yet clear, these
initial studies suggest that tyrosine kinase cascades may regulate G
protein-coupled receptors to produce either increases or decreases in functioning.
To explore these mechanisms further, we examined the effect of tyrosine
kinase activation on -opioid receptor coupling to the G
protein-activated inwardly rectifying potassium channel (KIR3).1 To do
this, we utilized the Xenopus oocyte expression system and
took advantage of the endogenously expressed insulin receptor tyrosine
kinase cascade (11).
| |
EXPERIMENTAL PROCEDURES |
Chemicals--
U69593
((+)-(5
,7,8)-N-methyl-N-[7-(1-pyrrolidinyl)-1-oxaspiro(4,5)dec-8-yl]benzeneacetamide)
was obtained from Research Biochemicals International. All other
chemicals were from Sigma.
Complementary DNA Clones and cRNA Synthesis--
The rat
-opioid receptor (KOR) was obtained from Dr. David Grandy
(GenBankTM/EBI accession number D16829). cDNAs for
KIR3.1 (GenBankTM/EBI accession number U01071)
and KIR3.2 (GenBankTM/EBI accession number
U11859) were obtained from Drs. Cesar Lebarca and Henry Lester,
respectively. Dr. John Adelman provided KIR3.4
(GenBankTM/EBI accession number X83584).
KIR3.2(S146T) was made as described previously (12). Point
mutations were made in wild-type KOR to produce KOR(Y87F) and
KOR(Y157F). Mutations were introduced by polymerase chain reaction
amplification using Pfu turbo DNA polymerase
(Stratagene) with complementary oligonucleotide primers incorporating
the desired mutation. Mutations were confirmed by DNA sequencing.
Plasmid templates for all constructs including KOR mutants were
linearized prior to cRNA synthesis, and the mMESSAGE MACHINE kit
(Ambion Inc.) was used to generate capped cRNA.
Oocyte Culture and Injection--
Defolliculated stage IV
oocytes were prepared as described (13) and incubated for 2-3 days
after injection of the cRNAs in normal oocyte saline buffer (96 mM NaCl, 2 mM KCl, 1 mM
MgCl2, 1 mM CaCl2, and 5 mM HEPES, pH 7.5) supplemented with sodium pyruvate (2.5 mM) and gentamycin (50 µg/ml). cRNAs were injected (50 nl/oocyte) with a Drummond microinjector. Each oocyte was injected with
1 ng of KOR cRNA and either 0.1 ng of KIR3.1 and
KIR3.2 wild-type potassium channel or 1 ng of
KIR3.2(S146T) pore mutant channel cRNA. A few sets of
oocytes were injected with KIR3.4 cRNA instead of
KIR3.2 as controls for direct effects of insulin-activated cascades on the channel.
Electrophysiology--
Oocytes were voltage-clamped at 
80 mV
with two electrodes filled with 3 M KCl having resistances
of 0.3-3.0 megaohms using an Axoclamp 2A unit and pCLAMP
Version 6 software (Axon Instruments, Inc.). Membrane current
traces were recorded using a chart recorder. To facilitate the
recording of inward K+ currents through the
KIR3 channels, the normal oocyte saline buffer was modified
to increase the KCl concentration to 96 mM K+.
The concentration of NaCl was correspondingly decreased to maintain osmolarity.
Data Analysis--
EC50 values and curve fitting
were determined using Nfit software (Island Products, Galveston, TX).
Confidence intervals were used for comparison of the independent means.
Student's t test was used for comparison of independent
means, with values reported as two-tailed p values.
| |
RESULTS |
Insulin Potentiates the -Opioid Activation of
KIR3--
Rat KOR was coexpressed in Xenopus
oocytes with KIR3.1 and KIR3.2 (Fig.
1). When the concentration of potassium
was increased in the extracellular recording solution, the basal
current through the inwardly rectifying potassium channel was readily
detected. Activation of KOR by the -opioid-selective agonist U69593 caused an increase in the potassium current, as has been shown previously (14, 15). Brief (12-15 min) pretreatment of the oocytes
with 8 µM insulin activated the endogenously expressed insulin receptor and potentiated the response produced by the -agonist. In contrast, insulin pretreatment had a small and variable inhibitory effect on the basal KIR3 current (Fig.
2).
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Fig. 1.
Insulin potentiates KOR activation of
KIR3 channels. Oocytes were injected with 1 ng of rat
KOR and 0.1 ng each of KIR3.1 and KIR3.2.
Representative traces are shown from an untreated oocyte and an oocyte
treated with 8 µM insulin for 12-15 min. This
concentration of insulin was found to produce a maximal effect (data
not shown). The oocyte membrane potential was clamped at 80 mV while
bathed in normal saline buffer containing 2 mM KCl as
described under "Experimental Procedures." Oocytes were then
superfused with a saline buffer in which the KCl concentration was
increased to 96 mM. This does not activate the
channel, but allows the basal inward current to flow through the
inwardly rectifying potassium channels at the 80-mV holding potential
(IBasal). After equilibration with the high
K+ buffer (hK), application of the -opioid
receptor agonist U69593 (500 nM) increased the inward
current (IU69593). The increase in inward
current through KIR3 channels caused by agonist activation
of KOR was defined by the difference evident after addition of
naloxone, an effective -receptor antagonist. Oocytes injected with
KIR3 alone did not respond to U69593, and oocytes injected
with KOR alone did not show an increase in potassium current (data not
shown).
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Fig. 2.
Insulin pretreatment produces potentiation of
the evoked current response generated by the stimulation of the
-opioid receptor. Oocytes were injected with
cRNAs for the -opioid receptor (OR) and the
KIR3.1/KIR3.2 channel (A) or
KIR3.2(S146T) (B), a variant of
KIR3.2 that more readily forms homotetrameric channels.
Data were collected from untreated control oocytes (open
bars) or oocytes pretreated with 8 µM insulin for
12-15 min prior to recording (closed bars). The HK
bars represent the channel response to addition of high potassium
buffer, a response that was not significantly changed by pretreatment
with insulin. The response evoked following stimulation of the
-opioid receptor with 500 nM U69593 (a maximally
effective concentration) is shown on the left. Insulin pretreatment
caused a significant potentiation of the U69593-induced response with
both types of channel (*, p < 0.05 compared with
untreated oocytes). The data represent summarized recordings taken from
18-22 oocytes for each bar. Differences were determined through
comparison of control and insulin-pretreated conditions by Student's
t test. Identical results were obtained using oocytes
expressing KIR3.4 in place of KIR3.2 (data not
shown).
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Insulin Does Not Significantly Affect KIR3--
The
lack of a robust effect of insulin on the basal current carried by the
KIR3.1/KIR3.2 heteromultimer was different from the strong inhibitory actions of other tyrosine kinase cascades on
potassium channel conductance. Activation of the endogenously expressed
insulin receptor had previously been shown to inhibit the basal
activity of a different inwardly rectifying potassium channel
(KIR2.1) expressed in oocytes (16). Furthermore, Rogalski et al. (12) showed that activation of the receptor tyrosine kinase TrkB by BDNF inhibited KIR3.1. To distinguish
possible effects on the channel from those on the receptor, we tested
the effects of insulin pretreatment on three different forms of the channel: KIR3.1 with KIR3.2, KIR3.1
with KIR3.4, and KIR3.2(S146T) alone. The
latter is a mutant form of KIR3.2 that allows the 3.2 subunit to function as a homomultimer (17, 18), and
KIR3.2(S146T) is insensitive to the effects of
BDNF-activated tyrosine kinase cascades (12). If insulin-activated
tyrosine kinase cascades affected the KIR3 channel in a
manner similar to the BDNF-activated TrkB cascade, the insulin-induced
effect would depend on the channel subunit composition. Insulin
pretreatment had no significant effect on the basal channel conductance
of any of the three KIR3 combinations (Fig. 2). Insulin
pretreatment consistently potentiated the effects of KOR activation of
each of the three forms of the KIR3 channel (Fig. 2). These
results suggest that the potentiation of U69593 actions is not mediated
by a direct effect on the KIR3 channel.
Insulin Effects Are Blocked by Tyrosine Kinase Inhibitors--
The
insulin receptor tyrosine kinase is known to activate a cascade of
downstream effectors, including both serine/threonine and tyrosine
kinases (19). To determine whether the effects of insulin were through
a tyrosine kinase, we used the nonspecific tyrosine kinase inhibitor
genistein (20). Although the mechanism by which genistein inhibits
insulin receptor tyrosine kinase activity is unclear (21), this
inhibitor is a commonly used to block insulin effects (22, 23). Insulin
potentiated the U69593-activated potassium current to 146 ± 12%
(n = 12) compared with controls not pretreated with
insulin. In contrast, for oocytes pretreated for 25-30 min with 100 µM genistein, insulin had no significant effect on the
KOR response (p > 0.05); the response to U69593 after
genistein/insulin treatment was 105 ± 12% (n = 11 oocytes) compared with matched controls not pretreated with
genistein/insulin. The results suggest that insulin potentiates the
opioid-activated response through tyrosine kinase activation.
Insulin Potentiation Requires Tyrosine Residues in Both the First
and Second Intracellular Loops--
As the potentiating effects of
insulin required activation of tyrosine kinases, we mutated specific
tyrosine residues in KOR to determine whether this would attenuate the
insulin effect. We substituted phenylalanine for tyrosine at two sites
within the KOR sequence, KOR(Y87F) and KOR(Y157F) (Fig.
3A), as a tyrosine residue in
the second intracellular loop was previously shown to be responsible
for the effects of insulin on the 2-adrenergic receptor
(9, 10). U69593 dose-response analysis showed that the EC50
values for activation of wild-type and mutant KORs were not
significantly different (Fig. 3B). The EC50
values (with 95% confidence intervals) were as follows: wild-type KOR,
160 () nM; KOR(Y87F), 138 () nM;
and KOR(Y157F), 76 (48-119) nM. The lack of effect on
agonist potency suggests that the mutations did not directly alter the
coupling to the channel and that the tyrosines were not required for
U69593 affinity. However, insulin did not potentiate the response to
U69593 in oocytes expressing either KOR(Y87F) or KOR(Y157F) (Fig.
4) compared with matched controls
expressing wild-type KOR. The results support the hypothesis that
insulin-induced tyrosine phosphorylation occurs at these two sites on
KOR. The levels of receptor expression were too low to obtain direct
evidence of phosphotyrosine production by Western analysis (data not
shown).
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Fig. 3.
Mutation of tyrosine residues in the KOR
sequence does not affect the response to U69593. A,
shown is a schematic of KOR indicating the residues in the first and
second intracellular loops. The specific tyrosine residues
(Tyr87 and Tyr157) mutated to phenylalanines
are indicated. B, sets of oocytes were injected with the
cRNAs for the KIR3.1/KIR3.2 channel and
wild-type KOR (OR WT;  ) or one of two
point-mutated receptors, KOR(Y87F) ( ) or KOR(Y157F) ( ). A fourth
set of oocytes was injected with the cRNAs for the
KIR3.2(S146T) pore mutant channel and wild-type KOR ( ).
Oocytes were clamped as described under "Experimental Procedures"
and superfused with high K+ buffer until the basal inward
current reached equilibration. Oocytes were then exposed to the
-opioid agonist U69593 at concentrations of 3 nM to 3 µM. Once the inward current response reached the maximal,
perfusion with the opioid receptor antagonist naloxone (1 µM) reversed U69593 activation of KOR. Averaged currents
from 5 to 10 oocytes were normalized to the maximal current for each
set and plotted against the concentration of U69593. The
EC50 values were not significantly different from each
other (as determined by 95% confidence intervals).
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Fig. 4.
Mutation of intracellular tyrosine residues
prevents insulin potentiation of the KOR response. Oocytes were
injected with the following cRNAs: 1 ng of wild-type KOR
(OR WT), KOR(Y87F), or KOR(Y157F) and 0.1 ng
of both KIR3.1 and KIR3.2. The bar
graph shows -agonist-induced responses following insulin
treatment normalized to responses of untreated oocytes.
-Agonist-induced responses were significantly increased in
insulin-treated oocytes expressing the wild-type receptor. In contrast,
no significant change in -opioid response was seen following
insulin treatment of oocytes expressing either KOR(Y87F) or KOR(Y157F).
Each bar represents the mean ± S.E. calculated from 14 to 22 separate oocytes from at least two different donors (*,
p < 0.01 compared with matching control
oocytes).
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Insulin Increases the Maximal Response to the -Agonist U69593
without Changing the Affinity for KOR--
To examine the mechanism by
which insulin caused a potentiation of the KOR response, we generated
U69593 dose-response curves either before or after insulin treatment.
There was no significant change in the EC50 value for
U69593 in oocytes pretreated with insulin compared with untreated
oocytes (p > 0.05). The control EC50 value
(with 95% confidence intervals) was 160 () nM, and
the EC50 value for U69593 was 192 () nM
in oocytes pretreated with insulin. However, the maximal response to
the -agonist was increased by insulin pretreatment at U69593 doses above 100 nM (Fig. 5). An
increase in agonist efficacy could have been caused either by a
functional increase in receptor number in the plasma membrane or by an
increase in efficiency of G protein activation.
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Fig. 5.
Dose-response curve for U69593 in oocytes
expressing wild-type KOR following pretreatment with insulin.
Oocytes were injected with the following cRNAs: 1 ng of wild-type KOR
and 0.1 ng of both KIR3.1 and KIR3.2.
Cumulative dose-response curves were generated in both control oocytes
() and oocytes treated with 8 µM insulin for 12-15
min () as described in the legend to Fig. 3. Each data
point on the curves represents the mean ± S.E. of
8-20 replicates. The dose-response curve in the presence of insulin
was significantly different from the control dose-response curve
(p < 0.01).
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| |
DISCUSSION |
The major finding of this study is that insulin treatment
potentiates the activation of the inwardly rectifying potassium channel
by the -opioid receptor. This potentiation may require tyrosine
kinase activation, as the insulin receptor is a tyrosine kinase, and
the effects in this study were blocked by genistein. Furthermore, the
regulation caused by insulin requires specific tyrosine residues in the
first and second intracellular loops of the -opioid receptor. In
addition, analysis of the dose-response curves demonstrated that the
potentiation results from an increase in -agonist efficacy. These
results indicate that the insulin potentiation of the -opioid
response is caused by a change in the phosphorylation state of the receptor.
Several possible cellular mechanisms might underlie the insulin
potentiation of the -opioid response. First, insulin receptor activation might cause a direct phosphorylation of specific tyrosine residues in KOR. Activated insulin receptors have been shown to phosphorylate other receptor proteins (24). Second, the complex cascade
activated by insulin receptors might be indirectly altering the
-opioid response by activation of a tyrosine phosphatase (25). Third, the effects of insulin on the opioid receptor could be
mediated through an auxiliary protein that requires Tyr87
and Tyr157 for its association with the -opioid
receptor. The latter alternative is least likely, as the mutations did
not cause a gross alteration in receptor conformation, evident by the
lack of U69593 affinity change. Direct measures of phosphorylation of
specific residues in KOR were not feasible; we obtained insufficient
32P incorporation into KOR expressed in oocytes to resolve
the phosphopeptide fragments derived from the immunoprecipitated
receptor. Thus, the results do not distinguish between potentiation
through an increase in phosphotyrosine or a decrease in basal tyrosine
phosphorylation. However, the data indicate that tyrosine
phosphorylation regulates KOR signaling.
Serine/threonine phosphorylation of opioid receptors has been shown to
inhibit the coupling of opioid receptors to their effectors (for
review, see Ref. 2). This is the first demonstration that regulation of
tyrosine phosphorylation of KOR modulates receptor function. A previous
study by Pak et al. (4) showed that phosphorylation of
tyrosine residues is required for a portion of agonist-induced internalization. Furthermore, tyrosine kinase inhibitors have also been
shown to inhibit agonist-induced internalization (5, 6). The effects of
insulin on the acute responses to -receptor activation seen in this
study suggest a different regulatory role for tyrosine phosphorylation
than that documented in the desensitization studies. We are studying
the effect of insulin on the initial coupling of KOR, not
agonist-dependent desensitization and internalization. In
this study, we have shown that other signaling pathways can affect
opioid receptor coupling through modulation of tyrosine residues,
illustrating a novel mechanism of cross-talk between opioid receptor
signaling and tyrosine kinase cascades.
The modulation of KOR signaling reported here is through conserved
tyrosines in the first and second intracellular loops. This supports
the emerging theory that G protein-coupled receptors may generally be
regulated by tyrosine phosphorylation. Previously, 2-adrenergic receptor coupling to adenylate cyclase was
shown to be potentiated by insulin in HEK293 cells, and this
potentiation of 2-adrenergic receptor coupling by
insulin was also attenuated by mutation of a tyrosine in the second
intracellular loop (10). However, Morris and Malbon (9) report that
insulin activation of either the insulin receptor or the insulin-like
growth factor-1 receptor inhibits 2-adrenergic receptor
signaling through modulation of tyrosine residues in the cytoplasmic
tail and second intracellular loop, respectively. Furthermore, they
showed that phosphorylation leads to interactions with Grb2 and other
proteins and to eventual internalization of the receptor (9). The basis
for the discrepancy between these two reports is not clear, but
presumably is due to the different conditions used. However, it appears
that regulation of G protein-coupled receptors through modulation of
specific tyrosine residues is likely to be found in more members of the G protein-coupled receptor superfamily.
The results of this study also show that insulin has no significant
effect on the basal channel activity of KIR3. This finding is in contrast to the reported effects of insulin on another inwardly rectifying potassium channel (KIR2.1) (16). The lack of
effect of insulin is also in contrast to the large inhibitory effect of
BDNF on KIR3 through activation of TrkB receptors (12).
These findings suggest that KIR3 maybe differentially
modulated by receptor tyrosine kinases. Another possible explanation is
the level of activation of tyrosine kinases. In this study, insulin
acted through an endogenously expressed receptor, whereas BDNF acted
through the exogenously expressed TrkB receptor. The higher levels of tyrosine kinase expression under the latter conditions could lead to a
higher kinase activity, although this was not specifically examined.
The insulin receptor is known to activate a large number of signaling
cascades (for review, see Ref. 19). Our results show that the
potentiating effect of insulin requires activation of tyrosine kinases;
however, the tyrosine kinase that directly phosphorylates KOR was not
identified. The Xenopus oocyte expresses both the insulin
receptor and the insulin-like growth factor-1 receptor, which bind and
are activated by insulin; but in our study, we did not address which of
these receptors mediates the effects of insulin (for review, see Ref.
11). However, the fact that a conservative mutation of specific
tyrosine residues to phenylalanines attenuates the effects of insulin
argues that the regulation is through direct regulation of tyrosine
phosphorylation of KOR.
The increase in KOR coupling seen here appears to be due to an increase
in efficacy and not a shift in the affinity of -ligands, as shown by
the increase in the maximal effect without a shift in the
EC50 values for the -agonist. A change in efficacy could be due to an increase in the total number of receptors or to an increase the ability of each receptor to activate its effector, in this
case, KIR3. These studies were carried out under conditions in which there were no spare -receptors (15), and we did not distinguish between these two possible mechanisms for an increase in
agonist efficacy in this study.
The critical tyrosine residues are located in the first and second
intracellular loops of KOR. This region is thought to be involved with
G protein binding along with the third intracellular loop and the
C-terminal tail (26, 27). It is possible that regulation of the
phosphorylation state of these residues alters the affinity of KOR for
the GTP-bound state of the G protein, and so more receptors are
associated with G proteins and available to activate the downstream
effectors. Interestingly, both Tyr87 and Tyr157
were required for the effect of insulin, suggesting that regulation of
both tyrosine residues is important for the changes in efficacy and
that the contribution of both residues is not additive.
The physiological relevance of these findings remains to be determined.
The insulin receptor kinase is a member of a family of receptor kinases
that include growth factor, cytokine, and insulin-like growth factor-1
receptors. It is possible that other members of this family of receptor
tyrosine kinases also could modulate opioid receptor function in the
same way. Opioid receptors are expressed along with growth factors and
cytokines in many different regions both centrally and peripherally.
This mechanism could therefore have the potential for cross-talk with
growth factors and cytokines in diverse opioid functions such as in the regulation of pain, epilepsy, and learning and memory.
In conclusion, this study shows that insulin potentiates the coupling
of KOR to KIR3. This potentiation is through activation of
a tyrosine kinase and requires specific tyrosine residues in the first
and second intracellular loops of KOR. These results suggest the
possibility of a novel mechanism of cross-talk between receptor
tyrosine kinases and opioid receptors.
| |
ACKNOWLEDGEMENTS |
We thank Jeremy Celver and Janet Lowe for
help. We thank Sherri Rogalski for providing the
KIR3.2(S146T) clone. We thank Dr. John Adelman for the
KIR3.4 cDNA, Dr. David Grandy for rat KOR, Dr. Cesar
Lebarca for the KIR3.2 clone, and Dr. Henry Lester for the
KIR3.1 clone.
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FOOTNOTES |
*
This work was supported in part by United States Public
Health Service Grant DA11672 from the National Institute on Drug Abuse.The costs of publication of this
article were defrayed in part by the
payment of page charges. The article
must therefore be hereby marked
"advertisement" in
accordance with 18 U.S.C. Section
1734 solely to indicate this fact.
¶
Present address: Vollum Inst., Oregon Health Sciences
University, Portland, OR 97201.
Supported by National Institute on Drug Abuse Institutional
Training Grant DA07278.
**
To whom correspondence should be addressed: Dept. of Pharmacology,
University of Washington, P. O. Box 357280, Seattle, WA 98195-7280. Tel.: 206-543-4266; Fax: 206-685-3822; E-mail:
cchavkin@u.washington.edu.
Published, JBC Papers in Press, September 19, 2000, DOI 10.1074/jbc.M006756200
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ABBREVIATIONS |
The abbreviations used are:
KIR3, G
protein-activated inwardly rectifying potassium channel;
KOR, -opioid receptor;
BDNF, Brain-derived neurotrophic
factor.
| |
REFERENCES |
| 1.
|
Olson, G. A.,
Olson, R. D.,
Vaccarino, A. L.,
and Kastin, A. J.
(1998)
Peptides
19,
1791-1843
|
| 2.
|
Law, P.,
Wong, Y.,
and Loh, H. H.
(2000)
Annu. Rev. Pharmacol. Toxicol.
40,
389-430
|
| 3.
|
Koch, T.,
Kroslak, T.,
Mayer, P.,
Raulf, E.,
and Hollt, V.
(1997)
J. Neurochem.
69,
1767-1770
|
| 4.
|
Pak, Y.,
O'Dowd, B. F.,
Wang, J. B.,
and George, S.
(1999)
J. Biol. Chem.
274,
27610-27616
|
| 5.
|
Polakiewicz, R. D.,
Schieferl, S. M.,
Dorner, L. F.,
Kansra, V.,
and Comb, M. J.
(1998)
J. Biol. Chem.
273,
12402-12406
|
| 6.
|
Schmidt, H.,
Schulz, S.,
Klutzny, M.,
Koch, T.,
Handel, M.,
and Hollt, V.
(2000)
J. Neurochem.
74,
414-422
|
| 7.
|
Fukuda, K.,
Kato, S.,
Morikawa, H.,
Shoda, T.,
and Mori, K.
(1996)
J. Neurochem.
67,
1309-1316
|
| 8.
|
Belcheva, M. M.,
Vogel, Z.,
Ignatova, E.,
Avidor-Reiss, T.,
Zippel, R.,
Levy, R.,
Young, E. C.,
Barg, J.,
and Coscia, C. J.
(1998)
J Neurochem.
70,
635-645
|
| 9.
|
Morris, A. J.,
and Malbon, C. C.
(1999)
Physiol. Rev.
79,
1373-1430
|
| 10.
|
Valiquette, M.,
Parent, S.,
Loisel, T. P.,
and Bouvier, M.
(1995)
EMBO J.
14,
5542-5549
|
| 11.
|
Grigorescu, F.,
Baccara, M. T.,
Rouard, M.,
and Renard, E.
(1994)
Horm. Res.
42,
55-61
|
| 12.
|
Rogalski, S. L.,
Appleyard, S. M.,
Pattillo, A.,
Terman, G. W.,
and Chavkin, C.
(2000)
J. Bio;. Chem.
275,
25082-25088
|
| 13.
|
Leonard, J. P.,
and Snutch, T. P.
(1991)
in
Molecular Neurobiology: A Practical Approach
(Chad, J.
, and Wheal, H., eds)
, pp. 161-182, Oxford University Press, New York
|
| 14.
|
Henry, D. J.,
Grandy, D. K.,
Lester, H. A.,
Davidson, N.,
and Chavkin, C.
(1995)
Mol. Pharmacol.
47,
551-557
|
| 15.
|
Appleyard, S. M.,
Celver, J.,
Pineda, V.,
Kovoor, A.,
Wayman, G. A.,
and Chavkin, C.
(1999)
J. Biol. Chem.
274,
23802-23807
|
| 16.
|
Wischmeyer, E.,
Doring, F.,
and Karschin, A.
(1998)
J. Biol. Chem.
273,
34063-34068
|
| 17.
|
Chan, K. W.,
Sui, J. L.,
Vivaudou, M.,
and Logothetis, D. E.
(1996)
Proc. Natl. Acad. Sci. U. S. A.
93,
14193-14198
|
| 18.
|
Vivaudou, M.,
Chan, K. W.,
Sui, J. L.,
Jan, L. Y.,
Reuveny, E.,
and Logothetis, D. E.
(1997)
J. Biol. Chem.
272,
31553-31560
|
| 19.
|
Nystrom, F. H.,
and Quon, M. J.
(1999)
Cell Signal.
11,
563-574
|
| 20.
|
Akiyama, T.,
Ishida, J.,
Nakagawa, S.,
Ogawara, H.,
Watanabe, S.,
Itoh, N.,
Shibuya, M.,
and Fukami, Y.
(1987)
J. Biol. Chem.
262,
5592-5595
|
| 21.
|
Abler, A.,
Smith, J. A.,
Randazzo, P. A.,
Rothenberg, P. L.,
and Jarett, L.
(1992)
J. Biol. Chem.
267,
3946-3951
|
| 22.
|
Janez, A.,
Worrall, D. S.,
Imamura, T.,
Sharma, P. M.,
and Olefsky, J. M.
(2000)
J. Biol. Chem.
275,
26870-26876
|
| 23.
|
Sajan, M. P.,
Standaert, M. L.,
Bandyopadhyay, G.,
Quon, M. J.,
Burke, T. R., Jr.,
and Farese, R. V.
(1999)
J. Biol. Chem.
274,
30495-30500
|
| 24.
|
Karoor, V.,
Wang, L.,
Wang, H. Y.,
and Malbon, C. C.
(1988)
J. Biol. Chem.
273,
33035-33041
|
| 25.
|
Taha, C.,
and Klip, A.
(1999)
J. Membr. Biol.
169,
1-12
|
| 26.
|
Georgoussi, Z.,
Merkouris, M.,
Mullaney, I.,
Megaritis, G.,
Carr, C.,
Zioudrou, C.,
and Milligan, G.
(1997)
Biochim. Biophys. Acta
1359,
263-274
|
| 27.
|
Koch, T.,
Kroslak, T.,
Averbeck, M.,
Mayer, P.,
Schroder, H.,
Raulf, E.,
and Hollt, V.
(2000)
Mol. Pharmacol.
58,
328-334
|
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