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The Journal of Neuroscience, June 15, 2000, 20(12):4555-4562
Chronic Heroin Self-Administration Desensitizes µ Opioid
Receptor-Activated G-Proteins in Specific Regions of Rat Brain
Laura J.
Sim-Selley1,
Dana E.
Selley1,
Leslie J.
Vogt2,
Steven R.
Childers2, and
Thomas J.
Martin2
1 Department of Pharmacology and Toxicology, and
Institute for Drug and Alcohol Studies, Virginia Commonwealth
University Medical College of Virginia, Richmond, Virginia 23298, and
2 Department of Physiology/Pharmacology, and Center for the
Neurobiological Investigation of Drug Abuse, Wake Forest University
School of Medicine, Winston-Salem, North Carolina 27157
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ABSTRACT |
In previous studies from our laboratory, chronic noncontingent
morphine administration decreased µ opioid receptor-activated G-proteins in specific brainstem nuclei. In the present study, µ opioid receptor binding and receptor-activated G-proteins were examined
after chronic heroin self-administration. Rats were trained to
self-administer intravenous heroin for up to 39 d, achieving heroin intake up to 366 mg · kg 1 · d1. µ opioid-stimulated [35S]GTP S and
[3H]naloxone autoradiography were performed in
adjacent brain sections. Agonist-stimulated
[35S]GTPS autoradiography also examined other
G-protein-coupled receptors, including  opioid, ORL-1,
GABAB, adenosine A1, cannabinoid, and 5-HT1A. In brains from heroin self-administering rats,
decreased µ opioid-stimulated [35S]GTPS
binding was observed in periaqueductal gray, locus coeruleus, lateral
parabrachial nucleus, and commissural nucleus tractus solitarius, as
previously observed in chronic morphine-treated animals. In addition,
decreased µ opioid-stimulated [35S]GTPS
binding was found in thalamus and amygdala after heroin self-administration. Despite this decrease in µ-activated G-proteins, [3H]naloxone binding demonstrated increased µ opioid receptor binding in several brain regions after
heroin self-administration, and there was a significant decrease in µ receptor G-protein efficiency as expressed as a ratio between
agonist-activated G-proteins and µ receptor binding. No effects on
agonist-stimulated [35S]GTPS binding were found
for any other receptor examined. The effect of chronic heroin
self-administration to decrease µ-stimulated [35S]GTPS binding varied between regions and
was highest in brainstem and lowest in the cortex and striatum. These
results not only provide potential neuronal mechanisms that may
contribute to opioid tolerance and dependence, but also may explain why
various chronic effects of opioids develop to different degrees.
Key words:
µ opioid receptor; heroin; G-protein; desensitization; opioid receptor; nociceptin/orphanin FQ receptor
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INTRODUCTION |
Chronic abuse of heroin remains a
major problem: the ability of heroin to produce high levels of
tolerance and physical dependence, combined with its reinforcing
properties, create a chronic relapsing disease with a significant
fatality rate (Goldstein and Herrera, 1995 ). The acute CNS effects of
heroin (3,6-diacetylmorphine) are primarily mediated by the binding
of its metabolites, 6-monoacetylmorphine (6-MAM) and morphine, to µ opioid receptors (Umans and Inturrisi, 1981; Inturrisi et al., 1983),
although recent evidence also suggests the potential existence of
specific receptors for heroin or its metabolites (Rossi et al., 1997;
Schuller et al., 1999). µ opioid receptors are located in brain
regions known to mediate the acute actions of opiates (Young and Kuhar,
1979; Herkenham and Pert, 1982), which include reinforcement,
analgesia, sympathetic nervous system effects, and respiratory
depression. Chronic opiate administration leads to the development of
tolerance and physical dependence on most opiate-mediated effects,
although the rate and magnitude of the development of these chronic
effects vary among different symptoms (Way et al., 1969).
Despite numerous investigations, the neuronal basis of opiate tolerance
and dependence remains unclear. Opioid receptors belong to the family
of inhibitory G-protein-coupled receptors (Evans et al., 1992; Kieffer
et al., 1992; Chen et al., 1993; Thompson et al., 1993), and chronic
opiate exposure in cultured cell lines results in desensitization
followed by receptor downregulation (Law et al., 1983; Puttfarcken and
Cox, 1989; Breivogel et al., 1997). However, previous studies in
animals have produced conflicting results regarding the effects of
chronic opiate administration on opioid receptor number (Klee and
Streaty, 1974; Tao et al., 1987; Brady et al., 1989; Yoburn et al.,
1993), and it has been suggested that many of the cellular adaptations
underlying tolerance and dependence occur at the level of the signal
transducing G-protein (Blasig et al., 1979; Tao et al., 1993) or by
compensatory mechanisms involving downstream effectors (Nestler, 1992;
Noble and Cox, 1996, 1997).
The development of agonist-stimulated
[35S]GTPS binding for opioid
receptors (Traynor and Nahorski, 1995) has provided an opportunity not
only to determine acute mechanisms of agonist efficacy (Clark et al.,
1997; Selley et al., 1997b; Alt et al., 1998; Selley et al., 1998) but
also to examine effects of chronic agonist treatment on coupling of
receptors to G-proteins (Breivogel et al., 1997; Selley et al., 1997a).
In brain, this technique has been extended by the development of
[35S]GTPS autoradiography (Sim et
al., 1995), which allows the visualization of receptor-activated
G-proteins in brain sections. Using this technique,
our laboratory (Sim et al., 1996a) showed previously that chronic
morphine administration decreased µ opioid-activated G-proteins
in specific nuclei in brainstem, but not in forebrain structures thought to contribute to the reinforcing effects of opiates
(Bozarth and Wise, 1984; Vaccarino et al., 1985). These results
suggested that although µ opioid receptor desensitization occurs
after chronic morphine administration, cellular adaptations may depend
on the brain region examined. The present study was designed to extend
those results by determining the effects of heroin self-administration
on opioid receptors and receptor-activated G-proteins in brain.
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MATERIALS AND METHODS |
Materials. Male Fischer 344 rats (250-300 gm) were
purchased from Harlan Laboratories (Indianapolis, IN).
[35S]GTPS (1250 Ci/mmol) and
[3H]naloxone (48 Ci/mmol) were purchased
from New England Nuclear (Boston, MA).
[D-Ala2,N-Me-Phe4,Gly5-ol]-enkephalin
(DAMGO) was obtained from Peninsula Laboratories (Belmont, CA).
R(+)-baclofen HCl, R(+)-WIN 55,212-2 mesylate, 5-carboxamidotryptamine
maleate (5-CT), and R( )N6-(2-phenylisopropyl)adenosine (PIA) were
purchased from Research Biochemicals International (Natick, MA).
Adenosine deaminase,
p-Cl-[D-penicillamine2,5,
p-Cl-Phe4]enkephalin
(p-Cl-DPDPE), and GDP were obtained from Sigma (St. Louis, MO). The nociceptin/orphanin FQ (N/OFQ) peptide was synthesized in the Protein Core Laboratory of the Cancer Center at Wake Forest University. Reflections autoradiography film was purchased from New
England Nuclear. Heroin hydrochloride was provided by Research Triangle
Institute (Research Triangle Park, NC) through the Drug Supply Program
of the National Institute on Drug Abuse. All doses are reported in
terms of the free base of heroin. Pentobarbital (Nembutal) was
purchased from Abbott Laboratories (North Chicago, IL) in a vehicle of
10:40:50 ethanol/propylene glycol/water at a concentration of 50 mg/ml.
Atropine sulfate was purchased from Sigma, and heparin was purchased
from Elkins-Sinn (Cherry Hill, NJ). All other reagent grade chemicals
were obtained from Sigma or Fisher Scientific (Pittsburgh, PA).
Heroin self-administration. Male Fischer 344 rats were
implanted with chronic indwelling catheters for intravenous
administration of drugs as described previously (Martin et al., 1995).
Control rats were subjected to the same surgery and catheters as
drug-treated rats. After recovery from surgery, animals were trained to
self-administer intravenous infusions of 0.06 mg/kg heroin during daily
4 hr sessions on a fixed-ratio 10 schedule of reinforcement
(Martin et al., 1995). Once drug intake was stable (~1
mg · kg1 · d1), this
dose of heroin was made available for self-administration 24 hr/d. The
schedule for increasing heroin doses, determined from the rate of drug
self-administration until the final infusion rate (6 mg/kg) produced
intakes of up to 366 mg · kg1 · d1, is
presented in Results. The rats were maintained on this schedule of
increasing heroin doses for 29-39 d. Animals were killed after 5 d of self-administration of 6 mg/kg of heroin, during which time total
heroin intake did not vary by >10% of the mean for each animal.
Rats were decapitated, and brains were removed and frozen in isopentane
at 35°. Coronal sections (20 µ m) were cut throughout the
rostral-caudal extent of the brain on a cryostat maintained at 20°,
mounted on gelatin-subbed slides, and stored at 80° until processed
as described below.
Agonist-stimulated [35S]GTPS
autoradiography in brain sections. Agonist-stimulated
[35S]GTPS autoradiography was
performed as described previously (Sim et al., 1995). Sections were
rinsed in TME buffer (50 mM Tris-HCl, 3 mM
MgCl2, 0.2 mM EGTA, 100 mM NaCl, pH 7.4) at 25° for 10 min, followed by a 15 min
preincubation in TME buffer containing 2 mM GDP and
adenosine deaminase (9.5 mU/ml) at 25°. Sections were then incubated
in TME buffer with GDP, adenosine deaminase, 0.04 nM
[35S]GTPS, and appropriate agonist at
25° for 2 hr. The following agonists were used: 10 µ M
DAMGO (µ opioid), 10 µ M p-Cl-DPDPE ( opioid), 3 µ M N/OFQ, 10 µ M WIN 55212-2 (cannabinoid), 300 µ M baclofen (GABAB), 1 µ M PIA (adenosine A1), or 2 µ M 5-CT (5HT1A).
Sections incubated with N/OFQ contained protease inhibitors, and those
incubated with WIN 55,212-2 contained bovine serum albumin, as
described previously (Sim et al., 1995, 1996c). Slides were rinsed
twice for 2 min each in cold Tris buffer (50 mM
Tris-HCl, pH 7.4) and once in deionized H2O.
Slides were dried overnight and exposed to film for 48 hr in film
cassettes containing [14C] microscales
(Amersham, Arlington Heights, IL) for densitometric analysis.
[3H]Naloxone autoradiography. Sections
were equilibrated in TME buffer for 15 min at 25°. Slides were then
incubated in 2 nM [3H]naloxone in TME buffer containing 1 µ M p-Cl-DPDPE (to block receptors) for 1 hr at 25°. Slides were rinsed three times for 2 min each in 50 mM Tris buffer at 4°C, then briefly in
deionized H2O at 4°. Nonspecific binding was
assessed in the presence of 10 µ M
levallorphan. Slides were dried under a cool stream of air and exposed
to Hyperfilm-3H for ~8 weeks. All film
cassettes included a [3H] microscale
(Amersham) for calibration of results.
Analysis of data. Films were digitized with a Sony XC-77
video camera and analyzed densitometrically using the NIH IMAGE program for Macintosh computers. For
[35S]GTPS autoradiography, resulting
values were expressed as nanocuries of
[35S]per gram of tissue and were
corrected for [35S] from
[14C] standards based on incorporation
of [35S] into sections of frozen brain
paste, as described previously (Sim et al., 1997). Net
agonist-stimulated [35S]GTPS binding
was calculated by subtracting basal binding (obtained in the absence of
agonist) from agonist-stimulated binding. For [3H]naloxone binding, nonspecific
binding was densitometrically subtracted from total binding before
analysis, and resulting values represent specific nanocuries per gram
of [3H]naloxone binding. Data are
reported as mean values ± SE of triplicate sections of brains
from eight treated and seven control animals. Statistical comparison
between control and heroin self-administering rats was performed by
ANOVA followed by post hoc analysis using the two-tailed
non-paired Student's t test.
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RESULTS |
Heroin self-administration
To produce opiate tolerance and dependence using a
procedure that parallels the behavior of chronic opiate use in humans, the current study established a paradigm of heroin self-administration in rats. The results of this procedure are illustrated in Figure 1, which shows daily heroin
intake for self-administering animals over the course of the study. In
daily 4 hr sessions, animals were trained to self-administer
intravenous infusions of 0.06 mg/kg heroin on a fixed-ratio 10 schedule of reinforcement (Martin et al., 1995). The dose of heroin was
increased as drug intake escalated across several days, thereby
allowing the animals to maintain high levels of daily heroin intake and
still have time for feeding and sleeping. Beginning with a dose of 0.06 mg/kg per infusion, heroin intake increased from an average of 1.8 ± 0.33 mg · kg1 · d1
to 5.1 ± 1.6 mg · kg1 · d1 over
the next 7.6 ± 1.1 d. The dose of heroin was subsequently increased to 0.3 mg/kg per infusion. Animals compensated for the dose
increase by taking fewer infusions; however, daily heroin intake again
increased from 5.6 ± 0.93 mg · kg1 · d1 to
16.9 ± 3.7 mg · kg1 · d1 over an
average of 6.9 ± 1.1 d. The dose of heroin was then
increased to 1.2 mg/kg per infusion, and daily drug intake subsequently increased from 16.2 ± 2.8 mg ·kg1 · d1 to
81.4 ± 17.0 mg · kg1 · d1 over
8.8 ± 1.8 d. The dose of heroin was finally increased to 6 mg/kg per infusion, and daily heroin intake reached a maximum of 366 mg · kg1 · d1, with
animals maintaining self-administration for 29-39 d. The tolerance
produced by this paradigm is illustrated by the fact that this daily
heroin intake was lethal in drug-naive animals. Moreover, these animals
were also highly dependent, because interruption of drug intake
produced significant withdrawal symptoms (ptosis, diarrhea,
vocalization) soon after drug cessation in five animals that were not
included in the autoradiographic studies (data not shown).
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Figure 1.
Heroin intake in self-administering animals. Rats
were initially trained to self-administer intravenous infusions of 0.06 mg/kg heroin during daily 4 hr sessions on a fixed-ratio 10 schedule of
reinforcement. As drug intake became stable and began to increase, the
dose of heroin was gradually increased to 6 mg · kg1 · d1 as
described in Results. Data are mean values ± SEM of daily heroin
intake in eight rats.
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Autoradiography of µ opioid-stimulated
[35S]GTPS binding and
[3H]naloxone binding
Coronal sections from several brain levels were processed for
DAMGO-stimulated [35S]GTPS binding
and [3H]naloxone binding to examine µ opioid-activated G-proteins and µ receptors, respectively. The use of
[3H]naloxone along with DAMGO-stimulated
[35S]GTPS autoradiography allows both
parameters to be determined under similar assay conditions and provides
direct comparison between receptor binding and activation of
G-proteins. Representative sections of DAMGO-stimulated
[35S]GTPS binding from control and
chronic heroin self-administering rats are shown in Figure
2. Figure 2, A and
B, shows autoradiograms at the level of locus coeruleus
(A) and periaqueductal gray/interpeduncular nucleus
(B), regions in which decreased DAMGO-stimulated
[35S]GTPS binding was evident in our
previous study of chronic morphine-treated rats (Sim et
al., 1996a). In sections from control rats, high levels of µ receptor-activated G-proteins were observed in these brainstem nuclei.
However, in sections from chronic heroin self-administering rats, µ receptor-stimulated G-protein activity was visibly reduced in these
regions. Figure 2C shows autoradiograms of thalamus, amygdala, and hypothalamus, where decreases in DAMGO-stimulated [35S]GTPS binding in sections from
heroin self-administering rats were particularly evident in
the medial thalamus and amygdala, with a magnitude of decrease similar
to that observed in brainstem. These data are in contrast to the
previous study using chronic morphine-treated rats, where none of these
regions displayed any decrease in µ-stimulated
[35S]GTPS binding after chronic
morphine treatment (Sim et al., 1996a). On the other hand, only a small
decrease was seen in caudate putamen, cingulate cortex, and nucleus
accumbens from heroin self-administering rats (Fig.
2D).
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Figure 2.
Representative autoradiograms showing µ opioid-stimulated [35S]GTPS binding in coronal
brain sections from control and heroin self-administering rats.
Decreases in DAMGO-stimulated [35S]GTPS binding
are evident in nuclei in sections from heroin-treated rats, including
locus coeruleus (A), periaqueductal
gray/interpeduncular nucleus (B), and
thalamus/amygdala (C), but not caudate
putamen/nucleus accumbens/cingulate cortex
(D).
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The anatomical distribution of
[3H]naloxone binding was the same as
that seen for DAMGO-stimulated
[35S]GTPS binding. Representative
sections in Figure 3 (which
show adjacent sections from the same animals presented in Fig. 2) show an increase in [3H]naloxone binding in
several regions of heroin self-administration versus control brains;
these regions include locus coeruleus (Fig. 3A),
periaqueductal gray/interpeduncular nucleus (Fig. 3B), and hypothalamus (Fig. 3C). Little visible change was apparent
was in the amygdala, thalamus (Fig. 3C), caudate putamen, or
cingulate cortex (Fig. 3D) from heroin self-administering
rats.
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Figure 3.
Representative autoradiograms showing
[3H]naloxone binding in control and heroin
self-administering rats. Sections are at the same levels and from the
same animals as those in Figure 2. Increases in
[3H]naloxone binding are evident in sections from
heroin-treated rats in regions including locus coeruleus
(A), periaqueductal gray/interpeduncular nucleus
(B), and hypothalamus (C)
but not thalamus/amygdala (C) or caudate putamen
(D).
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Quantification of basal and agonist-stimulated
[35S]GTPS binding, and specific
[3H]naloxone binding, was obtained by
measuring optical density in autoradiograms of regions of interest.
Basal [35S]GTPS binding was generally
unaffected by chronic heroin self-administration (data not shown),
except in the interpeduncular nucleus and locus coeruleus, where heroin
self-administration significantly decreased basal
[35S]GTPS binding by 18 and 20%,
respectively (p < 0.05). This finding confirms
previous observations of decreased basal
[35S]GTPS binding in the locus
coeruleus of chronic morphine-treated rats (Sim et al., 1996a; Selley
et al., 1997a).
Table 1 shows the analysis of
net DAMGO-stimulated [35S]GTPS
binding and specific
[3H]naloxone binding from both groups of
animals. Results showed that the effect of chronic heroin
self-administration in decreasing µ receptor-stimulated
[35S]GTPS binding varied across brain
regions. The largest decreases were observed in brainstem, with
25-39% reductions in heroin self-administering rats compared with
controls. Decreases in µ-stimulated
[35S]GTPS binding were also observed
in medial thalamus (28%) and amygdala (32%). DAMGO-stimulated
[35S]GTPS binding also appeared to be
reduced in hypothalamus (17% decrease), but this effect did not reach
the level of statistical significance (p > 0.05). Although trends of decreased DAMGO-stimulated [35S]GTPS binding were observed in
other regions, there were no significant decreases observed in caudate
putamen, nucleus accumbens, cingulate cortex, and prefrontal cortex in
brains from heroin self-administering rats, with the exception of the
rostral pole of the nucleus accumbens (p < 0.005). Similar results were obtained whether the nucleus accumbens was
analyzed as a whole or separated into shell and core regions.
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Table 1.
Effect of chronic heroin self-administration on µ opioid-stimulated [35S]GTPS binding and
[3H] naloxone binding in rat brain
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In contrast to the inhibitory effects of chronic heroin
self-administration on µ opioid receptor-activated G-proteins,
increased [3H]naloxone binding was
observed in several brain regions after chronic heroin
self-administration (Table 1). Although the increase in
[3H]naloxone binding in forebrain was
generally small, in some of these areas this increase (~10%) was
significant (i.e., prefrontal and cingulate cortices, nucleus
accumbens, hippocampus). A greater increase (27%) was seen in
hypothalamus, an effect comparable to the increases measured in
brainstem nuclei. With the exception of the lateral parabrachial
nucleus, increased [3H]naloxone binding
was found in all of the brainstem nuclei analyzed. In general, the
magnitude of the increases in
[3H]naloxone binding in brainstem
(20-35%) was greater than those measured in the forebrain.
Table 1 shows that eight of the nine regions with significant decreased
µ-stimulated [35S]GTPS binding
after chronic heroin self-administration also demonstrated increased
[3H]naloxone binding. This finding
suggests that decreased µ receptor activation of G-proteins after
chronic heroin self-administration occurred despite a significant
increase of µ receptors, indicating a loss in receptor-G-protein
coupling efficiency after chronic heroin exposure. To further explore
this concept, data from Table 1 were expressed as the ratios between
µ-stimulated [35S]GTPS binding and
[3H]naloxone binding (G/R ratios) in
each region, in both control and chronic heroin animals. Results (Fig.
4) show that the decrease in µ receptor
activation of G-proteins after chronic heroin self-administration was
even more evident when expressed in this manner, with significant decreases in G/R ratios in every region except prefrontal cortex and
hippocampus. For example, chronic heroin self-administration produced
35% decreases in the G/R ratio in medial thalamus and amygdala and
40-50% decreases in brainstem nuclei. These results indicate a
significant decline in the efficiency of µ receptor-G-protein coupling in these regions after chronic heroin self-administration.
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Figure 4.
Ratios of DAMGO-stimulated
[35S]GTPS binding to
[3H]naloxone binding (G/R ratios) in regions from
control and heroin self-administering rats, expressed as percentage of
values in control animals. Data from both autoradiographic assays
(nanocuries per gram for [35S] and
[3H]) were obtained from Table 1, and ratios of
[35S] to [3H] were calculated
in both control and heroin-treated animals. Ratios (which varied from
0.25 to 1.4) were separately obtained in sections from each animal, and
data are expressed as mean values ± SEM. PFC,
Prefrontal cortex; rNAC, nucleus accumbens rostral pole;
NAC, nucleus accumbens; CCtx, cingulate
cortex; CPu, caudate putamen; Hip,
hippocampus; Amyg, amygdala; Thal, medial
thalamus; MDT, medial dorsal thalamus;
Hyp, hypothalamus; PAG, periaqueductal
gray; IPn, interpeduncular nucleus; PBn,
lateral parabrachial nucleus; LC, locus coeruleus;
NTS, commissural nucleus tractus solitarius.
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Agonist-stimulated [35S]GTPS
autoradiography for other receptors
Receptor-coupled G-protein activity for several other
G-protein-coupled receptors was examined in control and heroin
self-administration brains to determine whether other
Gi/Go-coupled receptors
were affected by heroin treatment. opioid-stimulated
[35S]GTPS binding was of particular
interest, because at relatively high concentrations heroin metabolites
also bind to opioid receptors. However, no significant differences
in opioid-stimulated [35S]GTPS
binding were found in forebrain regions, including amygdala, nucleus
accumbens, caudate putamen, cingulate cortex, and prefrontal cortex
(Table 2). There was a trend toward a
decrease in -stimulated [35S]GTPS
binding observed in amygdala, but the variability precluded any
significant differences. Nevertheless, the possibility of concerted
changes in µ and receptors in amygdala represents an intriguing
possibility, especially considering the recent evidence of opioid
receptor heterodimers (Jordan and Devi, 1999). Data from
brainstem nuclei were not included in the analysis because the level of
p-Cl-DPDPE-stimulated
[35S]GTPS binding was too low in
these regions to be accurately quantified. Several other
G-protein-coupled receptors were also examined using agonist-stimulated
[35S]GTPS binding to determine
whether the activity of other receptor types was affected by chronic
heroin self-administration. However, none of these receptors, including
ORL-1, GABAB, adenosine A1, or cannabinoid receptors, showed any changes in G-protein activation (Table 2). In addition, 5-HT1A-stimulated
[35S]GTPS binding was examined in
dorsal raphe nucleus and hippocampus, but no significant changes were
found (data not shown). These data suggest that the desensitization
produced by uncoupling µ opioid receptors from G-proteins in brain is
homologous in nature.
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DISCUSSION |
The current study used heroin self-administration for 29-39 d to
assess the effect of chronic opiate exposure on µ receptors. The
effects of chronic opiate administration have typically been studied
using scheduled injections or subcutaneously implanted morphine
pellets. The choice of dose, dosing frequency, and route of
administration is usually made for practical considerations, rather
than behavioral or pharmacological measures made during the dosing
regimen. Although these paradigms efficiently produce opiate tolerance
and physical dependence, they may not necessarily mimic the gradual
development of tolerance and physical dependence that occurs with
illicit heroin use in humans, where doses are escalated for subjective
effects. In the present study, a paradigm that incorporates this
behavior-driven dose escalation has been applied to heroin
self-administration in rats.
Desensitization of µ receptor-activated G-proteins in heroin
self-administering rats was observed in brain areas crucial in mediating many of the acute and chronic actions of opiates. These include analgesia (periaqueductal gray, thalamus), respiratory depression and cardiovascular effects [parabrachial nucleus,
commissural nucleus tractus solitarius (cNTS)], sympathetic symptoms
of withdrawal (locus coeruleus), and emotional responses (amygdala). In
contrast, nucleus accumbens, which mediates reinforcing effects of
several psychoactive drugs including opiates, displayed less
desensitization in heroin self-administering rats compared with areas
like thalamus, amygdala, and brainstem nuclei. The effect of chronic
heroin self-administration in caudate putamen, which mediates some of
the motor effects of opiates, was not significant. The decreases found
in agonist-stimulated [35S]GTPS
binding after heroin self-administration could be caused by a decrease
in either agonist potency or efficacy; preliminary results from
amygdala membranes suggest that the primary effect of chronic heroin
treatment is to decrease agonist efficacy (C. Maher, T. Martin, and S. Childers, unpublished observations).
An important consideration in any study of chronic agonist treatment is
whether residual drug remains bound to tissue and affects results in an
artifactual manner. This possibility is unlikely for several reasons.
First, brain sections were incubated in buffers containing sodium and
GDP, which increase agonist dissociation from receptors (Childers and
Snyder, 1980) and remove endogenous and exogenous agonists from
membranes. Second, residual agonist in sections would increase basal
[35S]GTPS binding. In fact,
heroin self-administration had no effect on basal
[35S]GTPS binding except in two
regions, locus coeruleus and interpeduncular nucleus, where basal
binding was decreased. Finally, no decreases were seen in
[3H]naloxone binding in any region.
These results, coupled with the fact that the effect of chronic heroin
self-administration varied across brain regions, indicate that these
effects were not caused by residual heroin in brain sections.
These studies in heroin self-administering rats confirm previous
results from rats treated noncontingently with morphine for 12 d
(Sim et al., 1996a). In that study, desensitization of DAMGO-stimulated [35S]GTPS binding was observed only
in specific brainstem nuclei, including periaqueductal gray, dorsal
raphe nucleus, parabrachial nucleus, locus coeruleus, and cNTS. The
present study confirms these effects and shows that heroin
self-administration produces the highest level of µ opioid
desensitization in these areas. This confirmation is important, because
it was accomplished using a different drug, dose, and administration
paradigm. Therefore, these effects on µ opioid activation of
G-proteins appear to be a fundamental response of neurons in these
regions to chronic opioid agonist exposure. Interestingly, in the
previous study, no effects of chronic morphine treatment were observed
in forebrain regions. The finding that chronic heroin
self-administration produced µ receptor desensitization in thalamus
and amygdala may be the result of several differences between the two
studies, including administration of different opiates (heroin vs
morphine) and a longer treatment duration (39 d of heroin vs 12 d
of morphine). Indeed, the brain levels of total opioid are
significantly higher after intravenous administration of heroin
compared with morphine, and peak levels are reached more rapidly (Way
et al., 1965). There may also be a difference of drug
self-administration versus noncontingent administration (Smith et al.,
1980).
Another goal of this study was to use
[3H]naloxone autoradiography under
the same assay conditions as
[35S]GTPS autoradiography to
determine whether changes in µ receptors accompanied the decrease in
receptor-G-protein coupling. A radiolabeled antagonist was used to
avoid any changes in agonist high-affinity states that might accompany
receptor-G-protein uncoupling. Most regions with decreased
DAMGO-stimulated [35S]GTPS binding
demonstrated significant increases in
[3H]naloxone binding. This change
in [3H]naloxone binding may be the
result of changes in binding kinetics; however, this would produce
changes in [3H]naloxone
KD values, which has not been
observed in cell culture studies with chronic agonist treatment
(Breivogel et al., 1997).
The G/R ratio between agonist-activated G-proteins and receptors showed
a greater decrease after chronic heroin self-administration than
µ-stimulated [35S]GTPS binding by
itself. Although these results suggest that efficiency of µ receptor-G-protein coupling was reduced after chronic heroin
self-administration, the G/R ratio should be interpreted with caution:
because it does not determine Bmax of
receptors or agonist-activated G-proteins, it is not equivalent to the
amplification factor (Sim et al., 1996b). Indeed, without a precise
measure of Bmax values, true receptor
efficiency cannot be calculated, and the apparent increase in binding
observed in the present studies may be produced by changes in receptor
affinity. On the other hand, this G/R ratio is a relevant measure of
efficiency between µ receptors and activated G-proteins because (1)
[3H]naloxone, as an antagonist, does not
vary in its KD value at µ receptors
across brain regions (Maher et al., 2000), and (2) DAMGO-stimulated [35S]GTPS binding
was determined with saturating concentrations of agonist. The fact that
almost all regions with decreased µ-stimulated G-proteins also
displayed increased µ receptor binding may indicate an important
response of this system to chronic agonist exposure. It is possible
that the initial event of receptor-G-protein uncoupling could be
accompanied by later increases in receptor synthesis to compensate for
receptor desensitization, as described previously for  -adrenergic
receptors (Lefkowitz et al., 1992).
The relationship between changes in µ receptor binding and
development of tolerance/dependence is not clear. Previous studies provided conflicting results regarding the effect of chronic opioid treatment on opioid receptor number, and the data are difficult to
interpret because different paradigms were used. Moreover, previous
findings of decreased receptor binding in brain after chronic agonist
treatment (Yoburn et al., 1993) may in fact be consistent with the
present findings: because most previous studies were accomplished with
[3H]agonist binding, desensitization
caused by receptor-G-protein uncoupling would result in a decrease in
high-affinity agonist binding with no actual decrease in total receptor
number. Interestingly, a previous study using chronic morphine
administration with [3H]DAMGO
autoradiography also reported an increase in µ receptor binding
(Brady et al., 1989). Although data from cell lines indicate that
chronic opioid treatment decreases receptor number along with G-protein uncoupling (Puttfarcken et al., 1988; Breivogel et al.,
1997), other studies have shown that different opiate agonists have
differential effects on receptor phosphorylation (Chakrabarti et al.,
1997; Keith et al., 1998) and that morphine (a
major metabolite of heroin) does not promote µ receptor
internalization (Keith et al., 1998).
The desensitization in µ-activated G-proteins after chronic heroin
self-administration was homologous, because no changes in other
receptors coupling to G-proteins were observed. Moreover, less µ opioid receptor desensitization was found in forebrain regions that may
mediate reinforcing behaviors, particularly the nucleus accumbens
(Vaccarino et al., 1985). The small magnitude of the effect on µ opioid-activated G-proteins in these areas may explain why although it
is clear that tolerance develops to effects of opiates such as
analgesia and respiratory depression, there is controversy regarding
the degree of tolerance that develops to the reinforcing and
discriminative stimulus effects of opiates (Colpaert, 1995; Contarino
et al., 1997).
Chronic heroin self-administration is a complex interplay of a number
of effects of opioid agonists, including tolerance, physical
dependence, and reinforcement. The large increase in the daily intake
of heroin in self-administering animals reflects the dramatic tolerance
that develops to this drug, as well as its potent reinforcing
properties. Opiate addiction results from both the positive reinforcing
effects of opiates as well as avoidance of the negative effects of
physical dependence (Schulteis and Koob, 1996). Certainly, the animals
in the current study were highly physically dependent, because they
experienced withdrawal symptoms if not allowed free access to heroin.
Therefore, an important question is which of these facets of chronic
opiate effects (tolerance or physical dependence) are mediated by µ opioid receptor desensitization in specific brain nuclei. The issue of
tolerance cannot be addressed at the current time without a careful a
time course study. However, the present results may have important
implications regarding the development of physical dependence. A number
of studies (Kogan et al., 1992) suggest that withdrawal may be
associated with increased excitatory tone in specific brain regions,
and µ opioid receptors are predominantly inhibitory in nature
(Christie et al., 1987). If µ receptors are desensitized during
chronic agonist exposure, the resulting loss in inhibitory tone may
increase excitatory neuronal function in specific brain nuclei and thus
contribute to the development of physical dependence. These results
suggest that regionally specific adaptations in inhibitory signal
transduction may underlie the differential development of opiate dependence.
| |
FOOTNOTES |
Received Nov. 15, 1999; revised March 8, 2000; accepted March 29, 2000.
This work was supported by Public Health Service Grants DA-00287
(L.J.S.), DA-10770 (D.E.S.), DA-06634 (S.R.C.), and DA-00247 (T.J.M.)
from the National Institute on Drug Abuse. C. Todd Hairston and Ruoyu
Xiao provided technical assistance.
Correspondence should be addressed to Dr. Steven R. Childers, Center
for Investigative Neuroscience, Wake Forest University School of
Medicine, Medical Center Boulevard, Winston-Salem, NC 27157. E-mail:
childers{at}wfubmc.edu.
| |
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INTRODUCTION
