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Vol. 282, Issue 3, 1408-1417, 1997
Department of Pharmacology (C.A.F., G.L.W.), Graduate Program in Neuroscience (G.L.W.), University of Minnesota, Minneapolis, Minnesota
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Abstract |
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 Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References
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The mechanistic similarity between acutely and chronically induced morphine tolerance has been previously proposed but remains largely unexplored. Our experiments examined the modulation of acutely induced tolerance to spinally administered morphine by agonists that affect the N-methyl-D-aspartate receptor and nitric oxide synthase systems. Antinociception was detected via the hot water (52.5°C) tail flick test in mice. Intrathecal pretreatment with morphine (40 nmol) produced a 9.6-fold rightward shift in the morphine dose-response curve. This shift confirmed the induction of acute spinal morphine tolerance. Intrathecal copretreatment with the receptor antagonists (competitive and noncompetitive, respectively) dizolcipine (MK801, 3 nmol) or LY235959 (4 pmol) and morphine [40 nmol, intrathecally (i.t.)] attenuated acute tolerance to morphine measured 8 hr later. A 60-min pretreatment of 7-nitroindazole (6 nmol, i.t.), a selective neuronal NOS inhibitor, followed by administration of morphine (40 nmol, i.t.) blocked the induction of morphine tolerance. Intrathecal copretreatment with morphine (40 nmol, i.t.) and agmatine (4 nmol, i.t.), an imidazoline1 receptor agonist and putative nitric oxide synthase inhibitor, almost completely abolished acute spinal morphine tolerance. The results of these experiments agree with previous reports using models of chronically induced morphine tolerance. This evidence supports the proposal that the mechanisms responsible for acute morphine tolerance parallel those underlying chronic morphine tolerance. This study attests to the powerful predictive value of acute induction as a model for morphine tolerance.
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Introduction |
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Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References
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The
mechanism by which morphine tolerance develops has yet to be
definitively described and continues to be intensely investigated. Comparison of results across studies is difficult due to profound differences in study design. These include, for example, route of
administration (e.g., spinal vs. systemic),
method of induction (e.g., acute vs. chronic),
test subject species (e.g., mouse vs. rat),
measure of opioid action (e.g., tail flick vs.
hot plate), strain differences within species (Rady et al.,
1991
), and source differences within strains (Clark and Proudfit,
1992).
The induction of morphine tolerance appears to have two phases: an
acute component and a chronic state (Rosenfeld and Burks, 1977). Acute
tolerance develops within hours after a single bolus dose of opioid
agonist (Yano and Takemori, 1977) and persists at least 48 hr
(Huidobro-Toro et al., 1978). The majority of morphine tolerance studies investigate chronic tolerance, which typically requires administration of agonist for 3 to 7 days. However, current chronic induction methods carry notable drawbacks that may limit interpretation. In many studies opioid agonists have been administered by repeated injection either systemically or directly into the central
nervous system over a period of 3 to 7 days. Under these conditions,
maintaining a constant plasma or cerebrospinal fluid drug concentration
can be difficult or impossible to achieve; the animals may enter
withdrawal states repeatedly when agonist levels fall between
injections (Sparber et al., 1979, 1978; Stevens, 1994).
Repeated injections have also been associated with a learning or
associative component that may present difficulties in the interpretation of the results (Ben-Eliyahu et al., 1992;
Siegel, 1988).
A second commonly used method of chronic morphine tolerance induction
requires morphine pellet implantation. This technique may be
accompanied by systemic illness and stress (Sparber et al.,
1979); furthermore differences in pellet hardness and absorbability (Meyer and Sparber, 1976), pellet composition and drug release kinetics
(Blasig et al., 1973) and fibrous encapsulation (Stevens, 1994) may confound comparisons between results from different laboratories. A third method, chronic intrathecal infusion, may minimize chronic side effects such as systemic illness, motor dysfunction and stress, but can be confounded by displaced (Wiesenfeld and Gustafsson, 1982) or encapsulated (Sabbe et al., 1988)
catheters. Encapsulation may result in diffusion barriers preventing
the agonist reaching its intended spinal site of action (Coombs
et al., 1985; Samuelsson et al., 1987).
Additionally, chronic i.t. catheterization may induce neurochemical
changes in the central nervous system (Millan et al., 1989;
Rovati et al., 1988).
Opioid-releasing cell implantation models (Wu et al., 1994)
and adrenal medullary tissue implant models (Wang and Sagen, 1994) have
recently been developed to address some of these problems but are
accompanied by uncertainty as to which released agents (
-endorphin,
nicotine, ACTH or growth factors) may induce or alter the development
of tolerance. Finally, some pharmacological agents useful in isolating
the mechanisms of tolerance induction may be found to induce toxicity,
contraindicating their use in chronic tolerance studies. For example,
the protein kinase inhibitors H7 and H8 are reported to be toxic in
chronic dosing schedules (Bilsky et al., 1996a). A second
example of toxicity-limited tools includes protein synthesis
inhibitors, which induce metabolic disturbances when administered
chronically (Young et al., 1963). Conditions such as these
are likely to confound the interpretation of results and lead us to
consider alternatives for the study of tolerance.
Comparatively fewer studies have employed acute or single-dose
tolerance (Cox et al., 1968; Huidobro-Toro and Way, 1978;
Kissin et al., 1991ab; Narita et al., 1995;
Nielsen and Sparber, 1985; Song and Takemori, 1992; Vaught et
al., 1981). Acute tolerance mitigates many of the limitations
present in chronic induction schedules. Potency changes, revealed by
significant rightward shifts of the probe morphine dose-response curve,
persisting for as long as 48 hr (Huidobro-Toro and Way, 1978),
demonstrate the robust development of acute tolerance. Full agonist
efficacy remains attainable at higher doses after toleragen
(tolerance-inducing agent, i.e., morphine) administration,
distinguishing acute tolerance from tachyphylaxis which involves
reduced efficacy as well. The method of induction remains simple
whether the route of administration is systemic or i.t. Subject animals
do not present symptoms of illness or disability. The investigator
maintains substantially improved control of drug dose and the time
course characteristics are more specifically and accurately observed.
Studies selectively examining the spinal mechanisms of opioid action
represent a small subset of the substantial tolerance literature.
However, there exists a critical clinical need to understand fully the
spinal mechanism of morphine tolerance. A variety of clinical
techniques (epidural and spinal catheterization; implantable pump) use
direct spinal administration of opiates in an attempt to treat
intractable cancer pain (Behar et al., 1979; Coombs et
al., 1985; Cousins et al., 1979; Onofrio et
al., 1981; Samuelsson et al., 1995; Wang et
al., 1979). Clinical practice, therefore, underscores the need for
continued and expanded experimental exploration of the mechanisms
governing spinal opioid tolerance. Techniques such as spinal
catheterization of the subarachnoid space (Yaksh and Rudy, 1976) and
intrathecal injection (Hylden and Wilcox, 1980) permit the isolation of
the spinal site of opioid action in conscious animals. This isolation
provides the means to determine the sites of opioid agonist action
within the central nervous system: that is, to differentiate how
opioids act in spinal cord vs. supraspinal sites and which descending
tracts may modulate such action. Subsequent studies using these
techniques clearly implicated spinal cord as a critical site in the
development of morphine tolerance (DeLander et al., 1984;
Delander and Takemori, 1983; Yaksh et al., 1977).
Many behavioral studies of spinal morphine tolerance use the rat as a
model; one rationale for this choice has been that the rat's larger
size facilitates implantation of infusion catheters. However, chronic
catheter studies remain impractical in mice. Species selection becomes
an important issue in view of the recent introduction of mutant,
gene-targeted mouse lines that present expanded opportunities for the
study of mechanism in vivo. This advance calls for the
establishment of a reliable murine model for the investigation of
mechanisms of spinal morphine tolerance; the acute tolerance paradigm
serves this need effectively. Elucidation of the similarities and
differences between acute and chronic spinal morphine tolerance may
advance our understanding of the fundamental mechanisms underlying
morphine tolerance (Mucha and Kalant, 1980). Toward this end, we
applied a mouse model of acute induction of tolerance to spinally
administered morphine by intrathecal injection.
To test the generalizability of acute morphine tolerance to chronic
morphine tolerance, we elected to test a series of agents known to
modulate chronic morphine tolerance. The prevention of the development
of chronic morphine tolerance and/or dependence by NMDA receptor
antagonists (Ben-Eliyahu et al., 1992; Elliott et
al., 1994a, b; Marek et al., 1991; Tiseo et
al., 1994; Tiseo and Inturissi, 1993; Trujillo and Akil, 1991) and
NOS inhibitors (Elliott et al., 1994b; Kolesnikov et
al., 1992, 1993; Majeed et al., 1994; Vaupel et
al., 1995a) is well-established in the literature. Recent evidence
demonstrates that NMDA receptor antagonist-mediated modulation of
opioid tolerance may be selective to morphine induction and not
observed with induction by other opioid ligands (Bilsky et
al., 1996c). Therefore, these modulators are well-suited for investigating the parallels between acute morphine tolerance and chronic morphine tolerance.
The present experiments demonstrate the ability of NMDA receptor antagonists and NOS inhibitors to attenuate or abolish the induction of acute tolerance to spinally administered morphine. These experiments consistently reveal results similar to those reported in chronic systemic induction models. These observations suggest that information about mechanism obtained through acute morphine tolerance studies will correlate closely with comparable information from studies of chronic morphine tolerance.
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Materials and Methods |
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Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References
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Animals. All experimental subjects were 20 to 25 g male ICR mice (Harlan Sprague Dawley, Indianapolis, IN). These experiments were approved by the Institutional Animal Care and Use Committee. All animals were housed in groups of 10 in a temperature- and humidity-controlled environment for 4 to 5 days before experimentation. All animals were maintained on a 12-hr light/dark cycle and had free access to food and water. Each animal was used only once.
Chemicals. Morphine sulfate was a gift of Dr. R. P. Elde (University of MN), dizocilpine (a noncompetitive NMDA receptor antagonist, MK801) was a gift of Merck Chemical Co. (Rahway, NJ); LY235959 (a competitive NMDA antagonist) was a gift of Eli Lilly Co. (Indianapolis, IN); agmatine sulfate (an imidazoline1 receptor agonist) and peanut oil were from Sigma Chemical Co. (St. Louis, MO); 7-nitroindazole (7-NI, a NOS inhibitor) was from Tocris Cookson (St. Louis, MO) and was dissolved in peanut oil (Faraci and Brain, 1995). Moxonidine HCl was a gift of Kali-Chemie Pharma GmbH (Hannover, Germany) and was dissolved in 0.9% saline acidified (pH 3.5). All other drugs were dissolved in 0.9% saline.
Antinociceptive testing.
Nonciceptive responsiveness was
determined using the warm water (52.5°C) immersion tail flick test.
The latency to the first rapid tail flick represented the behavioral
endpoint (Janssen et al., 1963). Baseline measurements of
tail-flick latencies were collected on all subjects (for a sample of
n = 817, x = 4.0, S.D. = 1.3). Mice that failed to
respond within 5 sec to baseline tests were excluded from analysis
(18%). The % MPE was determined according to the following formula:
% MPE = (postdrug latency-predrug latency)/(cutoff-predrug latency) × 100%. To avoid tissue injury, a maximum score of 100% was
assigned to those animals not responding within 12 sec. Drugs were
injected i.t. by direct lumbar puncture (Hylden and Wilcox, 1980).
Acute tolerance induction.
Mice were made acutely tolerant
to morphine by a single intrathecal injection of morphine, in most
cases at a dose of 40 nmol except as noted. All injections were
administered between 06:00 and 09:00 hr. Approximately 8 hr after the
injection, tail-flick latencies were collected on all subjects to
determine that the tail flick latencies had returned to baseline levels
(for a sample of n = 251, x = 3.1, S.D. = 0.9). Those
animals that failed to respond within 5 sec to the tail flick test were
excluded from analysis (4%). Subjects were then challenged with
varying doses of morphine (0.2, 0.6, 2, 8, 15, 20 nmol, i.t.). The tail
flick test was performed 10 min after this probe morphine injection. Dose-response curves were generated and ED50 values and
confidence limits were calculated according to the method of Tallarida
and Murray (1987). Groups of 7 to 10 animals were used for each dose and/or each pretreatment.
NMDA receptor antagonist modulation of acute spinal morphine tolerance. Dizolcipine (MK801, 3 nmol, i.t.) and LY235959 (4 pmol, i.t.) were each coadministered with morphine (0.2, 0.6, 2, 8 nmol, i.t.) to test for possible modulatory effects on the acute antinociceptive effects of morphine. Dose-response curves for the antinociceptive effects of these coadministered agents were generated. To test for the NMDA receptor antagonists' modulatory effect on the induction of acute tolerance to spinally administered morphine, mice were either copretreated with morphine (40 nmol, i.t.) together with the NMDA receptor antagonist dizocilpine (MK801, 3 nmol, i.t.) or LY235959 (4 pmol, i.t.). Approximately 8 hr later, animals were challenged with varying doses of morphine (MK801: 0.2, 0.6, 2, 8 nmol morphine, i.t.; LY235959: 0.8, 2, 5, 8 nmol morphine, i.t.). The tail flick test was performed before and 10 min after this probe morphine injection, and morphine probe antinociceptive dose-response curves generated.
NOS inhibitor 7-NI modulation of acute spinal morphine
tolerance.
Vehicle (peanut oil) and 7-NI (6 nmol, i.t.) dissolved
in vehicle were each coadministered with morphine (0.2, 0.6, 2, 8 nmol, i.t.) to test for possible modulatory effects on the acute
antinociceptive effects of morphine in the tail flick test.
Dose-response curves to the antinociceptive effects of these
coadministered agents were generated. To test for the modulatory effect
of 7-NI on the induction of acute tolerance to spinally administered
morphine, mice were copretreated with morphine (40 nmol, i.t.) together with 7-NI (6 nmol, i.t.), a dose sufficiently high to block the NMDA-induced hyperalgesia (data not shown) observed previously (Kitto
et al., 1992). Approximately 8 hr later, animals were
challenged with varying doses of morphine (0.2, 0.6, 2, 8 nmol
morphine, i.t.). The tail flick test was performed before and 10 min
after this probe morphine injection and morphine probe antinociceptive dose-response curves were generated.
Agmatine modulation of acute spinal morphine tolerance. Agmatine (0.2, 0.6, 2, 8, 20, 30, 100 nmol, i.t.) was tested for possible antinociceptive effects in the tail flick test. Agmatine (4 nmol, i.t.) coadministered with morphine (0.2, 0.6, 2, 8 nmol, i.t.) was tested for possible modulatory effects on the acute antinociceptive effects of morphine in the tail flick test. Mice were copretreated with morphine (40 nmol, i.t.) together with agmatine (4 nmol, i.t.) and morphine probe antinociceptive dose-response curves were generated. This experiment was replicated twice, once unblinded and once blinded; both experiments yielded similar results. As a control for agmatine's activity at the putative imidazoline receptor, mice were copretreated with morphine (40 nmol, i.t.) together with moxonidine (1 nmol, i.t.) and a morphine probe antinociceptive dose-response curve was generated.
Modulatory agent's effect on the induction of tolerance to morphine. To test whether each modulatory agent could induce "tolerance" in the absence of morphine toleragen (40 nmol, i.t.), single groups of mice (n = 9-10) received i.t. injections with each agent (MK801, 3 nmol; LY235959, 4 pmol; 7-NI, 6 nmol; agmatine, 4 nmol; moxonidine, 1 nmol; peanut oil, 5 µl; saline; or morphine, 40 nmol). Approximately 8 hr later, animals were challenged with a single probe dose of morphine (8 nmol, i.t.). The tail flick test was performed before and 10 min after this probe morphine injection. The means of the maximum possible effect (% MPE) values of the groups that received the modulatory agent or vehicle were tested for significance using ANOVA and statistical differences between the groups were further analyzed with Dunnett's test for multiple comparisons to a control (saline group).
Statistical analysis.
Data describing antinociception are
expressed as means of percent maximal possible effect (% MPE) with
S.E.M. For experiments testing responses to a single probe dose,
statistical significance was evaluated using Student's t
test (significance set at P < .05). Potency changes are presented
as ED50 value dose ratios between the ED50
values of different dose-response curves. However, statistical
comparisons of potencies are based on the confidence limits of the
ED50 values. The ED50 values and confidence
limits were calculated according to the method of Tallarida and Murray (1987). Groups of 7 to 10 animals were used for each dose and/or each
pretreatment.
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Results |
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Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References
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Confirmation of the induction of acute tolerance to
i.t.-administered morphine.
To characterize the dose-response
relationships present in acute spinal tolerance, we initially
determined dose-response curves for the antinociceptive effects of
morphine in the tail flick test in naive, saline-pretreated and
morphine-pretreated (10 and 40 nmol, i.t.) mice. Morphine dose-response
curves did not differ between naive or saline-pretreated mice (fig.
1A). Data from two naive and one
saline-pretreated dose-response curves were pooled to generate a
nontolerant dose-response curve (fig. 1B, ED50: 1.2 nmol,
0.9-1.7). Dose points included in the pooled curves represent groups
with more than 10 subjects. Morphine pretreatment increased the
ED50 value in a dose-dependent manner (fig. 1A). Pretreatment with 10 nmol morphine (i.t.) produced a 3-fold rightward shift in the morphine dose-response curve (ED50: 3.7, 2.0-6.6) (fig. 1A). This ED50 value was calculated from
the doses included in the monotonic portion of the dose-response curve.
Data from three morphine-pretreated (40 nmol) dose-response curves
(fig. 1A) were pooled and are represented in figure 1B. Pretreatment with 40 nmol morphine produced a 9.6-fold rightward shift in the morphine dose-response curve (ED50: 12 nmol, 8.4-16). This
dramatic rightward shift confirms the induction of morphine tolerance
in this acute model. Acute spinal morphine tolerance demonstrates reliable replicability in this model (fig. 1A).
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Attenuation of acute spinal tolerance by NMDA receptor
antagonists.
The attenuation of chronically induced opioid
tolerance by NMDA receptor antagonists has been well established
(Ben-Eliyahu et al., 1992; Elliott et al., 1994b;
Marek et al., 1991; Tiseo et al., 1994; Tiseo and
Inturissi, 1993; Trujillo and Akil, 1991). We tested the modulatory
effects of two NMDA receptor antagonists on acute spinal morphine
tolerance. Morphine (0.2, 0.6, 2, 8 nmol, i.t.) administered to mice
copretreated with morphine (40 nmol, i.t.) together with dizolcipine
(MK801, 3 nmol) produced an antinociceptive dose-response curve with an
ED50 value of 2.1 nmol (1.0-4.9) (fig. 2B). This ED50 value differs
substantially from that of the morphine-pretreated dose-response curve
(ED50: 12 nmol (8.4-16). This demonstrates that
dizolcipine effectively attenuates the development of acutely induced
tolerance to spinally administered morphine. Morphine (0.8, 2, 5, 8 nmol, i.t.) administered to mice copretreated with morphine (40 nmol,
i.t.) together with LY235959 (4 pmol) produced a 4.6-fold rightward
shift in the antinociceptive dose-response curve with an
ED50 value of 5.5 nmol (3.1-9.5) (fig.
3B) which differs significantly from that
of morphine pretreatment group (ED50: 12 nmol, 8.4-16).
This difference demonstrates that LY235959 effectively attenuates the
development of acutely induced tolerance to spinally administered
morphine. Coadministration of morphine (0.2, 0.6, 2, 8 nmol, i.t.) in
the presence of dizolcipine (MK801, 3 nmol, i.t.) or LY235959 (4 pmol,
i.t.) in naive animals produced no potency shift compared to morphine
administered alone to naive/saline-pretreated animals (figs. 2A and
3A). This demonstrates that these antagonists do not modulate acute
morphine antinociception. An 8-hr pretreatment with either dizolcipine
(3 nmol, i.t.) or LY235959 (4 pmol, i.t.) did not effect a difference
in the efficacy of morphine (8 nmol, i.t.) when compared to
saline-pretreated control group (p < .05 in both cases, data not
shown).
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Prevention of acute spinal tolerance by 7-NI, an NO synthase
inhibitor.
The attenuation of chronically-induced morphine
tolerance by NOS inhibitors has been demonstrated previously (Bhargava,
1995; Elliott et al., 1994; Kolesnikov et al.,
1993; Kolesnikov et al., 1992; Majeed et al.,
1994). We tested 7-NI for its ability to block acutely induced
tolerance to spinally administered morphine. Morphine (0.2, 0.6, 2, 8 nmol, i.t.) administered to mice pretreated with 7-NI (6 nmol, i.t.) 1 hr before the tolerance-inducing pretreatment with morphine (40 nmol,
i.t.) produced an antinociceptive dose-response curve with an
ED50 value of 0.3 nmol (0.1-0.8) (fig. 4B). This ED50 value represents a 4-fold leftward shift in the
morphine dose-response curve from that of naive/saline-pretreatment
group (ED50: 1.2 nmol (0.9-1.7)). This demonstrates that
7-NI pretreatment effectively blocks the development of acutely induced
tolerance to spinally administered morphine. Administration of morphine (0.2, 0.6, 2, 8 nmol, i.t.) after a 1-hr pretreatment with either vehicle or 7-NI dissolved in vehicle in naive animals produced no
potency shift compared to morphine administered alone to
naive/saline-pretreated animals (fig.
4A). This result demonstrates that this
NOS inhibitor does not modulate acute morphine antinociception. An 8-hr
pretreatment with vehicle (peanut oil) or 7-NI (6 nmol, i.t.) dissolved
in vehicle did not effect a difference in the efficacy of morphine (8 nmol, i.t.) when compared to saline-pretreated control group (P < .05, data not shown).
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Blockade of acute spinal tolerance by agmatine.
Kolesnikov and
colleagues (1996) reported that systemically administered agmatine
prevented the development of µ opioid (morphine, s.c) and 
opioid
(DPDPE, i.t.) chronically induced tolerance. We tested agmatine for its
ability to block acutely induced tolerance to intrathecal morphine.
First, we tested agmatine for potential antinociceptive effects. We
also tested agmatine for a possible modulatory effect on acute morphine
antinociception. Agmatine at varying doses (2, 4, 6, 8, 20, 100 nmol,
i.t.) produced no antinociceptive effect in the tail flick test (data
not shown). Agmatine (4 nmol, i.t.) did not modulate acute effects of
morphine antinociception (0.2, 0.6, 2, 8 nmol, i.t.) on tail flick
latency (ED50 1.7 nmol, 1.0-2.9) (fig.
5A). At a higher dose of agmatine (100 nmol, i.t.), antinociception induced by a single dose of morphine (8 nmol, i.t.) was not different between those animals coadministered
morphine with agmatine (100 nmol, i.t.) and those administered morphine
alone (data not shown). An 8-hr pretreatment with agmatine (4 nmol,
i.t.) did not effect a difference in the efficacy of morphine (8 nmol,
i.t.) when compared to saline-pretreated control group (P < .05, data not shown). Agmatine (4 nmol, i.t.) administered as a
copretreatment with morphine toleragen (40 nmol, i.t.) attenuated the
development of morphine tolerance (fig. 5B). The probe morphine
dose-response curve (0.6, 2, 8 nmol, i.t.) was shifted 2.1-fold to the
right (ED50: 2.6 nmol, 1.4-4.6) relative to that of
saline-pretreated subjects. This ED50 value significantly differs from that of morphine pretreatment group (ED50: 12 nmol, 8.4-16) and demonstrates that agmatine robustly attenuates
acutely induced tolerance to spinally administered morphine.
Moxonidine, a putative imidazoline1 receptor-selective
agonist with known central nervous system activity (Fairbanks and
Wilcox, 1996; Haxhiu et al., 1994) was tested in this model
to control for agmatine's potential activity at the
imidazoline1 receptor. Moxonidine (1 nmol, i.t.)
administered as a copretreatment with morphine toleragen (40 nmol,
i.t.) did not modulate the development of morphine tolerance (fig. 5C).
Probe administration of morphine (0.2, 0.6, 2, 8, 15, 20 nmol, i.t.) in
animals copretreated with moxonidine (1 nmol, i.t.) and morphine (40 nmol, i.t.) produced an ED50 of 19 nmol (8.1-45)
comparable to that of subjects pretreated with morphine (40 nmol, i.t.)
only (ED50: 12 nmol, (8.4-16). An 8-hr pretreatment with
moxonidine (1 nmol, i.t.) did not show a difference in the efficacy of
morphine (8 nmol, i.t.) when compared to saline-pretreated control
(P < .05, data not shown). These results suggest that the ability
of agmatine to block the development of morphine tolerance is not
mediated through imidazoline1 receptor activation.
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Discussion |
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Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References
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Tolerance may be defined as a decrease in agonist effect over time
and/or a significant rightward shift in the agonist dose-response curve
(Stevens, 1996). Acute tolerance appears within hours of agonist
administration and lasts at least 2 days (Huidobro-Toro and Way, 1978).
In our model, a single i.t. bolus dose of morphine produced a
statistically significant and dose-related rightward shift of the
morphine dose-response curve (fig. 1). This result confirms the
induction of acute tolerance by this route of administration, which has
been previously implemented in other studies (Narita et al.,
1995). Our study explored the modulatory effects on acute tolerance to
intrathecally administered morphine of four agents implicated in the
modulation of the NMDA receptor/NOS cascade. These experiments yielded
results comparable to those reported in chronic induction models. Taken
collectively, these observations strongly support the hypothesis that
acute tolerance is mechanistically comparable to chronic tolerance.
NMDA receptor antagonist modulation of acute spinal morphine
tolerance.
Trujillo and Akil (1991) demonstrated that rats made
tolerant to morphine through repeated injections (b.i.d., s.c.) for up to 9 days became tolerant to the antinociceptive effects of morphine in
the tail flick assay. However chronic pretreatment by repeated injection (i.p.) with MK801, a noncompetitive NMDA receptor antagonist, dose-dependently attenuated morphine tolerance. Tiseo and Inturissi (1993) extended this investigation to LY274614, a competitive NMDA
receptor antagonist that does not induce the PCP-like side effects seen
with MK801 (Rasmussen et al., 1991). In their study, pretreatment with LY275414 prevented the development of morphine tolerance and reversed preexisting morphine tolerance. LY275414 (24 mg/kg/24 hr) was administered by continuous infusion (s.c.) to rats,
morphine antinociception was measured by the hot plate test, and
morphine tolerance was induced by repeated injection (10 mg/kg b.i.d.,
s.c.) for 7 days. Animals treated with LY275414 showed a full
antinociceptive response to morphine (10 mg/kg) on days 3 and 6 although tolerance to morphine (10 mg/kg, s.c.) was already evident by
the third day in control subjects. Elliott and colleagues (1994b)
extended this investigation to mice; MK801 (i.p.) and LY275414 (i.p.,
s.c.) attenuated the chronic induction of morphine tolerance (repeated
injection once daily, s.c.) as determined by the tail-flick method on
day 5. Ben-Eliyahu and colleagues (1992) tested the ability of MK801 to
attenuate tolerance to morphine induced by a single injection of a
sustained release preparation (s.c.) in rats. By this method of
induction, MK801 attenuated the development of tolerance to probe
morphine by 24 hr. This blockade was significantly measurable as long
as 12 days postinjection. The present experiments demonstrate that
blockade of the NMDA receptor at the PCP site by MK801 and the
glutamate recognition site by LY235959 results in the attenuation of
the development of acutely induced tolerance to spinally administered morphine in mice (figs. 2B and 3B). These findings concur with and
extend those observations reported in the chronic studies described
above.
Abatement of acute spinal tolerance by NOS modulators.
The
attenuation of chronically induced morphine effects by NOS inhibitors
has been well described. Systemic administration of NO2Arg
prevents morphine tolerance (Elliott et al., 1994b; Kolesnikov et al., 1992, 1993; Majeed et al.,
1994) and signs of morphine dependence (Kolesnikov et al.,
1993; Majeed et al., 1994) in mice systemically administered
morphine over 3 to 5 days to several weeks. NO2Arg also
reverses preexisting morphine tolerance and dependence (Kolesnikov
et al., 1993). Two additional NOS inhibitors, L-NAME (Majeed
et al., 1994) as well as NMMA (Bhargava, 1995), have also
proven to be effective in preventing the development of tolerance and
signs of dependence to morphine administered systemically over 3 to 5 days. 7-NI is a relatively novel inhibitor of NOS that is proposed to
be advantageous over other NOS inhibitors for its neuronal NOS
selectivity and lack of cardiovascular side effects (Moore et
al., 1993). Vaupel and colleagues (1995a) demonstrated that 7-NI
effectively attenuated withdrawal behaviors (weight loss, diarrhea, wet
dog shakes and grooming) in rats after morphine pellet implantation
lasting 3 days. Our study presents the first report that 7-NI robustly
attenuates acutely induced tolerance to spinally administered morphine
(fig. 4A and B). This finding corroborates reports from the chronic
morphine tolerance studies using L-NNA, NO2Arg and L-NAME
as tolerance attenuators and complements the chronic dependence
evidence that 7-NI diminishes the effects of morphine withdrawal. 7-NI
may prove suitable for clinical modulation of opioid withdrawal or
tolerance due to its neuronal selectivity and apparent lack of
hypertensive effects (Moore et al., 1993; Vaupel et
al., 1995b).
opioid (DPDPE, i.t.) tolerance.
Agmatine also potentiated morphine antinociception in naive mice
producing a 5-fold leftward shift in the morphine ED50
value. Interestingly, our experiments reveal that i.t. administered agmatine does not appear to affect acute morphine (i.t.)
antinociception in naive mice (fig. 5A) but clearly prevents the
development of acutely induced spinal tolerance (fig. 5B). This
suggests that agmatine may modulate opioid tolerance directly at a
spinal site, rather than through a descending pathway. The specific
mechanism by which agmatine exerts this effect remains to be defined.
Agmatine has been implicated in the inhibition of NOS (Auguet et
al., 1995; Galea et al., 1996), and therefore NOS
modulation would appear to be a likely mechanism for agmatine's
action. However, agmatine has also been shown to block the NMDA
receptor (Yang and Reis, 1996) in rat hippocampal neurons.
Identification of the specific pathway by which agmatine exerts this
effect may lead to novel directions in clinical coadministration of
tolerance-modifying agents with opioid agonists. Current
coadministration schedules that capitalize on receptor blockade by the
NMDA receptor antagonists may be limited by toxic side effects (Vaupel
et al., 1995b). As an endogenous ligand, agmatine may not
present those disadvantages. Consistent with this hypothesis, in our
study, mice intrathecally injected with agmatine at doses up to 100 nmol did not show overt signs of toxicity such as hindlimb paralysis,
hyperlocomotion or sedation. Regardless of the mechanistic source of
its action, our study demonstrates that intrathecally administered
agmatine robustly attenuates the induction of acute morphine tolerance. This finding confirms the first report of agmatine's ability to prevent the development of chronic tolerance to systemically
administered morphine (Kolesnikov et al., 1996) and extends
this previous result to include a spinal site of action.
Our study is composed of four experiments using two NMDA receptor
antagonists (MK801, LY235959), one accepted modulator of NOS (7-NI) and
one agent (agmatine) that may affect NOS. The observations presented
consistently implicate the NMDA receptor/NOS cascade in the development
of acute tolerance to intrathecally administered morphine. Each of
these experiments produced results comparable to those reported
previously using chronic models of morphine tolerance. That the
outcomes of our studies examining acute tolerance correlate with
outcomes from comparable studies of chronic morphine tolerance suggests
that these two phases of tolerance share underlying mechanisms. This is
the case for those agents that modulate the NMDA receptor/NOS cascade
in both morphine and ethanol tolerance (Khanna et al., 1992,
1993, 1994; Rafi-Tari et al., 1996; Wu et al.,
1993) and may hold true for other receptor systems that participate in
the development of tolerance. If so, the acute tolerance paradigm carries powerful predictive experimental value.
We propose that acutely induced spinal tolerance offers several
advantages for future studies of the mechanisms of opioid tolerance.
The acute tolerance paradigm reflects improvements in experimental
design including reduced toleragen level at time of probe test,
improved general health of the animal, increased potential for data
collection due to simplified animal protocols, decreased variability
between subjects and decreased experimental time. Acute tolerance also
favors mice as subjects because mice are the most appropriate subjects
for acute spinal injection. Quantitative pharmacological investigations
of receptor/effector mechanisms in vivo require large
numbers of experimental subjects for which mice are economically
practical. Furthermore, gene-targeted mouse lines, engineered to
selectively disrupt the expression or function of individual receptor
subtypes or signal transduction systems, present excellent systems for
determining the molecular mechanisms of spinal tolerance. Current lines
potentially useful for studies of opioid antinociception include
gene-targeted mice with altered 
2A receptors (MacMillan
et al., 1996), absent 2B or 2C
adrenergic receptors (Link et al., 1996), absent PKC
(Abeliovich et al., 1993), absent neuronal NOS (Huang
et al., 1994) and absent transcription factor CREB
(Maldonado et al., 1996). However, a frequently mentioned
concern about the application gene-targeted animals to studies of
mechanism in vivo is the potential for compensatory changes
during development; these are difficult to identify and may limit
interpretation of the data. A complementary technique recently applied
to studies of antinociception is the central administration of
antisense oligodeoxynucleotides to selectively disrupt expression of
specific receptor subtypes (Bilsky et al., 1996b; Lai
et al., 1996; Standifer et al., 1994). The
repeated i.t. administration of oligodeoxynucleotides implicit in these experiments would likely confound the interpretation of chronic tolerance studies. However multiple oligodeoxynucleotide pretreatments preceding a single injection acute tolerance study may prove very effective. We propose that use of the acute spinal tolerance induction method in gene-targeted mouse lines and in antisense-pretreated mice
will facilitate investigations of tolerance at a molecular level at
minimal cost and with limited experimental confounds. Acute tolerance
is also advantageous because the brevity of agonist exposure permits
evaluation of the critical time points in tolerance induction,
i.e., the upslope, peak and downslope. Therefore, the opportunity arises to explore temporal characteristics of induction of
tolerance, which may not be resolvable with chronic models. Finally,
incorporation of the acute tolerance paradigm can improve the design of
electrophysiological studies, enabling comparisons within the same
neuron between the nontolerant and tolerant states, each cell serving
as its own control. In vitro electrophysiological evidence
supports the proposal that acute tolerance parallels chronic tolerance
(Fiorillo and Williams, 1996).
Although there exist a substantial number of investigations using the
acute tolerance paradigm, a very limited number of studies compare
characteristics of acute morphine tolerance to those observed in
similarly designed chronic studies. Several groups have observed comparable results between acutely and chronically induced morphine tolerance (Huidobro-Toro and Way, 1978; Narita et al., 1995;
Yano and Takemori, 1977). Interestingly, comparable results have also been observed in models investigating acute and chronic ethanol tolerance, specifically when the tolerance induction is accompanied by
repeated synaptic activation (Le et al., 1992). The fact
that opioid receptor activation can lead to activation of PKC and
facilitation of NMDA receptor function (Chen and Huang, 1992) provides
a possible substrate for such a pairing of opioid receptor occupation
and repeated synaptic activation. In agreement with this idea, our study has demonstrated that, with respect to the NMDA receptor/NOS cascade, acute morphine tolerance can be manipulated similarly and
yield results comparable to those of previous studies of chronically induced morphine tolerance.
This report is not the first to suggest that acute and chronic morphine
tolerance may be mechanistically similar. Schmidt and Livingston
(1933a, b, c) reported that the induction of acute systemic tolerance
to the vasodilatory and convulsant effects of morphine in dogs
paralleled results from their similarly implemented chronic studies.
Based on their findings, Schmidt and Livingston (1933a, b, c)
speculated that the cellular mechanisms underlying both phenomena may
be closely related. Subsequent work (Huidobro-Toro and Way, 1978)
agreed with but did not fully explore that proposal. Our study
reexamines that question in terms of spinal analgesic systems and
during a time when technological advances facilitate higher resolution
investigations.
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Acknowledgments |
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The authors appreciate the critique and commentary provided by Dr. Craig W. Stevens and Dr. Frank Porreca, helpful discussions with Dr. Sheldon B. Sparber and Ms. Tinna M. Laughlin and the expert technical assistance of Mr. Kelley F. Kitto. The dizolcipine (MK801) was a generous gift of Merck, Sharpe, and Dohme. The LY235959, was a generous gift of Eli Lilly Company. The moxonidine was a generous gift of Kali-Chemi Phrma GmbH.
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Footnotes |
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Accepted for publication May 2, 1997.
Received for publication October 7, 1996.
1 This work was supported by NIH/K02-DA-00145 and NIH/R01-DA-04274 and ADAMHA training Grant T32A07234 awarded by NIDA.
Send reprint requests to: Dr. George L. Wilcox, Department of Pharmacology, 3-249 Millard Hall, 435 Delaware St. SE, Minneapolis, MN 55455.
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Abbreviations |
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ANOVA, analysis of variance; CREB, cAMP-responsive element-binding protein; I1, imidazoline1; i.t., intrathecal(ly); L-NNA, L-NG-nitro-L-arginine; L-NAME, L-NG-nitro-L-arginine methyl ester; LY, LY235959; MK801, dizolcipine; % MPE, percent maximum possible effect; NMMA, NG-monomethyl-L-arginine; NO2Arg, NG-nitro-L-arginine; NO, nitric oxide; NOS, nitric oxide synthase; 7-NI, 7-nitroindazole; NMDA, N-methyl-D-aspartate; pmol, picomoles; PKC, protein kinase C.
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References |
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Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References
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opioid receptor in vitro and in vivo.
Neurosci. Lett.
213: 205-208, 1996[Medline].
