Morphine induces hyperalgesia without involvement of µ-opioid receptor or morphine-3-glucuronide.

Opioid-induced hyperalgesia (OIH) is a paradoxical increase in pain perception that may manifest during opioid treatment. For morphine, the metabolite morphine-3-glucuronide (M3G) is commonly believed to underlie this phenomenon. Here, in three separate studies, we empirically assess the role of M3G in morphine-induced hyperalgesia. In the first study, CD-1 mice injected with morphine (15 mg/kg subcutaneously) after pretreatment with the opioid receptor antagonist naltrexone (NTX) (15 mg/kg) showed tail withdrawal latency reductions indicative of hyperalgesia (2.5 ± 0.1 s at t = 30 min, P < 0.001 versus baseline). In these mice, the morphine/M3G concentration ratios versus effect showed a negative correlation (r(p) = -0.65, P < 0.001), indicating that higher morphine relative to M3G concentrations are associated with increased OIH. In the second study, similar hyperalgesic responses were observed in mice lacking the multidrug resistance protein 3 (MRP3) transporter protein (Mrp3(-/-) mice) in the liver and their wild-type controls (FVB mice; latency reductions: 3.1 ± 0.2 s at t = 30 min, P < 0.001 versus within-strain baseline). In the final study, the pharmacokinetics of morphine and M3G were measured in Mrp3(-/-) and FVB mice. Mrp3(-/-) mice displayed a significantly reduced capacity to export M3G into the systemic circulation, with plasma M3G concentrations just 7% of those observed in FVB controls. The data confirm previous literature that morphine causes hyperalgesia in the absence of opioid receptor activation but also indicate that this hyperalgesia may occur without a significant contribution of hepatic M3G. The relevance of these data to humans has yet to be demonstrated.

Sex differences in opioid analgesia, hyperalgesia, tolerance and withdrawal: central mechanisms of action and roles of gonadal hormones.

This article reviews sex differences in opiate analgesic and related processes as part of a Special Issue in Hormones and Behavior. The research findings on sex differences are organized in the following manner: (a) systemic opioid analgesia across mu, delta and kappa opioid receptor subtypes and drug efficacy at their respective receptors, (b) effects of the activational and organizational roles of gonadal steroid hormones and estrus phase on systemic analgesic responses, (c) sex differences in spinal opioid analgesia, (d) sex differences in supraspinal opioid analgesia and gonadal hormone effects, (e) the contribution of genetic variance to analgesic sex differences, (f) sex differences in opioid-induced hyperalgesia, (g) sex differences in tolerance and withdrawal-dependence effects, and (h) implications for clinical therapies.

Sex-specific mediation of opioid-induced hyperalgesia by the melanocortin-1 receptor.

BACKGROUND: N-Methyl-D-aspartate receptor antagonists reverse hyperalgesia during morphine infusion in male mice only. Because the melanocortin-1 receptor can act as a female-specific counterpart to N-methyl-D-aspartate receptors in kappa-opioid analgesic mechanisms, the authors assessed the contribution of melanocortin-1 receptors to the sex-specific mechanisms underlying morphine hyperalgesia. METHODS: The tail-withdrawal test was used to compare the nociceptive responses of male and female C57BL/6J (B6) mice with those of C57BL/6J-Mc(1r(e/e)) mice, spontaneous mutants of the B6 background lacking functional melanocortin-1 receptors, during continuous morphine infusion (1.6 and 40.0 mgkg(-1) . 24 h(-1)). Separate groups of hyperalgesic B6 and outbred CD-1 mice were injected with MK-801 or MSG606, selective N-methyl-D-aspartate and melanocortin-1 receptor antagonists, respectively. RESULTS: Morphine infusion (40.0 mg . kg(-1) . 24 h(-1)) reduced baseline withdrawal latencies by 45-55% in B6 mice of both sexes, indicating hyperalgesia; this increased nociception was manifest in male e/e mice only. Although MK-801 reversed hyperalgesia in male mice only, increasing latencies by 72%, MSG606 increased latencies by approximately 60% exclusively in females. A lower morphine infusion dose (1.6 mg . kg(-1) . 24 h(-1)) reduced baseline withdrawal latencies by 45-52% in B6 and e/e mice of both sexes, which was reversed by MK-801, but not MSG606, in both male and female B6 mice. CONCLUSIONS: The data indicate the sex-specific mediation of high-dose morphine-induced hyperalgesia by N-methyl-d-aspartate and melanocortin-1 receptors in male and female mice, respectively, suggesting a broader relevance of this known sexual dimorphism. The data further indicate that the neural substrates contributing to hyperalgesia are morphine dose-dependent.

S(+)-ketamine effect on experimental pain and cardiac output: a population pharmacokinetic-pharmacodynamic modeling study in healthy volunteers.

BACKGROUND: Low-dose ketamine behaves as an analgesic in the treatment of acute and chronic pain. To further understand ketamine's therapeutic profile, the authors performed a population pharmacokinetic-pharmacodynamic analysis of the S(+)-ketamine analgesic and nonanalgesic effects in healthy volunteers. METHODS: Ten men and ten women received a 2-h S(+)-ketamine infusion. The infusion was increased at 40 ng/ml per 15 min to reach a maximum of 320 ng/ml. The following measurements were made: arterial plasma S(+)-ketamine and S(+)-norketamine concentrations, heat pain intensity, electrical pain tolerance, drug high, and cardiac output. The data were modeled by using sigmoid Emax models of S(+)-ketamine concentration versus effect and S(+)-ketamine + S(+)-norketamine concentrations versus effect. RESULTS: Sex differences observed were restricted to pharmacokinetic model parameters, with a 20% greater elimination clearance of S(+)-ketamine and S(+)-norketamine in women resulting in higher drug plasma concentrations in men. S(+)-ketamine produced profound drug high and analgesia with six times greater potency in the heat pain than the electrical pain test. After ketamine-infusion, analgesia rapidly dissipated; in the heat pain test but not the electrical pain test, analgesia was followed by a period of hyperalgesia. Over the dose range tested, ketamine produced a 40-50% increase in cardiac output. A significant consistent contribution of S(+)-norketamine to overall effect was detected for none of the outcome parameters. CONCLUSIONS: S(+)-ketamine displays clinically relevant sex differences in its pharmacokinetics. It is a potent analgesic at already low plasma concentrations, but it is associated with intense side effects.

Morphine-6beta-glucuronide rapidly increases pain sensitivity independently of opioid receptor activity in mice and humans.

BACKGROUND: Previous data indicate that morphine-6beta-glucuronide (M6G), a morphine metabolite with analgesic properties, can paradoxically increase pain sensitivity in mice and humans. The authors tested mice and humans for M6G hyperalgesia and assessed the contribution of N-methyl-D-aspartate receptor activity in mice. METHODS: Nociception after acute injection (10 mg/kg) and chronic infusion (1.6 mg/kg per 24 h) of M6G or saline was assayed using the tail-withdrawal test in CD-1 mice implanted with pellets containing the opioid antagonist naltrexone or placebo and in knockout mice lacking mu-, kappa-, and delta-opioid receptors and their B6129F(1) controls. In volunteers, responses to heat pain were tested after a M6G (0.4 mg/kg) injection in the presence of a continuous high naloxone (0.04-mg/kg bolus followed by 0.04 mg/kg per hour) or saline background infusion. RESULTS: Acute M6G injection evoked analgesia in CD-1 mice implanted with placebo pellets and B6129F(1) control mice, whereas it caused hyperalgesia in CD-1 mice treated concurrently with naltrexone and in knockout mice. Continuous M6G infusion produced hyperalgesia within 24 h, lasting for a minimum of 6 days, in both placebo- and naltrexone-pelleted mice. The N-methyl-D-aspartate receptor antagonist MK-801 (0.05 mg/kg) blocked and reversed hyperalgesia after the acute injection and continuous infusion of M6G, respectively. In humans, M6G increased heat pain sensitivity for at least 6 h independently of simultaneous naloxone infusion. CONCLUSIONS: These data indicate that M6G causes hyperalgesia independent of previous or concurrent opioid receptor activity or analgesia. In mice, a causal role for the N-methyl-D-aspartate receptor is also indicated.

Sex differences in hyperalgesia during morphine infusion: effect of gonadectomy and estrogen treatment.

Morphine treatment can paradoxically increase nociception (i.e. hyperalgesia). Since there are putative sex differences in nociception and morphine sensitivity, we compared nociception in male and female mice using the tail-withdrawal test during continuous infusion of two morphine doses (1.6 and 40.0 mg/kg/24 h). Both doses caused hyperalgesia in both sexes, but onset in females always preceded that of males. Although the larger dose initially evoked analgesia, naltrexone (NTX) pellets implanted prior to morphine infusion abolished analgesia but not hyperalgesia. Distinct sex differences also characterized each morphine dose. Specifically, the lower morphine dose caused hyperalgesia that dissipated after 6 days in males but persisted in females for a minimum of 14 days. Despite this difference, N-methyl-d-aspartate (NMDA) receptor antagonists reversed hyperalgesia in both sexes. In contrast, the higher morphine dose evoked hyperalgesia that resolved concurrently in both sexes, but hyperalgesia was reversed by NMDA receptor antagonists in males only. Ovariectomy (OVX), but not OVX followed by estrogen treatment, abolished both sex differences, and resulted in females exhibiting the male-typical pattern. This study thus demonstrates NTX-insensitive morphine hyperalgesia in females as previously reported for males. However, females utilized hyperalgesic mechanisms which were distinct from those employed by males. Data from females subject to OVX/estrogen replacement further indicate that females possess functional male-typical hyperalgesic mechanisms, but are diverted from their use by ovarian sex steroids. Finally, the finding that each morphine infusion dose was characterized by a unique sex difference provides additional evidence for distinct multiple hyperalgesic systems.

Acute and chronic heroin dependence in mice: contribution of opioid and excitatory amino acid receptors.

Opioid and excitatory amino acid receptors contribute to morphine dependence, but there are no studies of their role in heroin dependence. Thus, mice injected with acute or chronic heroin doses in the present study were pretreated with one of the following selective antagonists: 7-benzylidenenaltrexone (BNTX), naltriben (NTB), nor-binaltorphimine (nor-BNI; delta1, delta2, and kappa opioid receptors, respectively), MK-801, or LY293558 (NMDA and AMPA excitatory amino acid receptors, respectively). Naloxone-precipitated withdrawal jumping frequency, shown here to be a reliable index of heroin dependence magnitude, was reduced by BNTX or NTB in mice injected with both acute and chronic heroin doses. In contrast, nor-BNI did not alter jumping frequencies in mice injected with an acute heroin dose but significantly increased them in mice receiving chronic heroin injections. Continuous MK-801 or LY293558 infusion, but not injection, reduced jumping frequencies during withdrawal from acute heroin treatment. Their delivery by injection was nonetheless effective against chronic heroin dependence, suggesting mechanisms not simply attributable to NMDA or AMPA blockade. These data indicate that whereas delta1, delta2, NMDA, and AMPA receptors enable acute and chronic heroin dependence, kappa receptor activity limits the dependence liability of chronic heroin. With the exception of delta1 receptors, the apparent role of these receptors to heroin dependence is consistent with their contribution to morphine dependence, indicating that there is substantial physiological commonality underlying dependence to both heroin and morphine. The ability of kappa receptor blockade to differentially alter acute and chronic dependence supports previous assertions from studies with other opioids that acute and chronic opioid dependence are, at least in part, mechanistically distinct. Elucidating the substrates contributing to heroin dependence, and identifying their similarities and differences with those of other opioids such as morphine, may yield effective treatment strategies to the problem of heroin dependency.

A survey of acute and chronic heroin dependence in ten inbred mouse strains: evidence of genetic correlation with morphine dependence.

Heroin and morphine exposure can cause physical dependence, with symptoms manifesting during their withdrawal. Inter-individual differences in symptom frequency during morphine withdrawal are a common finding that, in rodents, is demonstrably attributable to genotype. However, it is not known whether inter-individual differences characterize heroin withdrawal, and whether such variation can be similarly influenced by genotype. Therefore, we injected mice of ten inbred strains with acute and chronic heroin doses and compared their jumping frequencies, a common index of withdrawal magnitude, during naloxone-precipitated withdrawal. The data revealed significant strain frequency differences (range after acute and chronic heroin injection: 0-104 and 0-142 jumps, respectively) and substantial heritability (h(2)=0.94 to 0.96), indicating that genetic variance is associated with heroin withdrawal. The rank order of strain sensitivity for acute and chronic heroin withdrawal jumping, and for the current heroin and previous morphine strain data, were significantly correlated (r=0.75-0.94), indicating their genetic and, ultimately, physiological commonality. These data suggest that the genetic liability to heroin dependence remains constant across a period of heroin intake, and that heroin and morphine dependence may benefit from common treatment strategies.

Sex-specific responses to opiates: animal and human studies.

It is widely reported that analgesic drugs acting at mu, kappa, and delta opioid-receptors display quantitative and qualitative differences in effect in males and females. These sex-related differences are not restricted to the analgesic/antinociceptive properties of opioids, but are also present in opioid-induced side effects, such as changes in respiration, locomotor activity, learning/memory, addiction, and changes in the cardiovascular system. An increasing number of well-controlled animal and human studies directly examining the issue of sex in the potency of opioids show that, although sex may affect opioid analgesia, the direction and magnitude of sex differences depend on many interacting variables. These include those specific to the drug itself, such as dose, pharmacology, and route and time of administration, and those particular to the subject, such as species, type of pain, genetics, age, and gonadal/hormonal status. In the current review, we systematically present these animal and human studies and discuss the data in relation to the depending variables. Although the observed sex differences in opioid effect may be clinically relevant, lack of knowledge on other factors involved in the large variability in patient opioid analgesic sensitivity should compel practitioners to customize their dosing regimens based on individual requirements.

Genetic variance contributes to naltrexone-induced inhibition of sucrose intake in inbred and outbred mouse strains.

The study of genetic variance in opioid receptor antagonism of sucrose and other forms of sweet intake has been limited to reductions in sweet intake in mice that are opioid receptor-deficient or lacking either pre-pro-enkephalin or beta-endorphin. Marked genetic variance in inbred mouse strains has been observed for sucrose intake across a wide array of concentrations in terms of sensitivity, magnitude, percentages of kilocalories consumed as sucrose and compensatory chow intake. The present study examined potential genetic variance in systemic naltrexone's dose-dependent (0.01-5 mg/kg) and time-dependent (5-120 min) ability to decrease sucrose (10%) intake in eleven inbred (A/J, AKR/J, BALB/cJ, CBA/J, C3H/HeJ, C57BL/6J, C57BL/10J, DBA/2J, SJL/J, SWR/J, 129P3/J) and one outbred (CD-1) mouse strains. A minimum criterion sucrose intake (1 ml) under vehicle treatment, designed to avoid "floor effects" of antagonist treatment was not achieved in three (A/J, AKR/J, CBA/J) inbred mouse strains. Marked genetic variance in naltrexone's ability to inhibit sucrose intake was observed in the remaining strains with the greatest sensitivity observed in the C57BL/10J and C57BL/6J strains, intermediate sensitivity in BALB/cJ, C3H/HeJ, CD-1 and DBA/2J mice, and the least sensitivity in 129P3/J, SWR/J and SJL/J strains with a 7.5-36.5 fold range of greater effects in the ID(50) of naltrexone-induced inhibition in C57BL/10J relative to the three less-sensitive strains across the time course. Naltrexone primarily affected the maintenance, rather than the initiation of intake in BALB/cJ, CD-1, C3H/HeJ, DBA/2J and SJL/J mice, but significantly reduced sucrose intake at higher doses across the time course in C57BL/6J, C57BL/10J and 129P3/J mice. Whereas SWR/J mice failed to display any significant reduction in sucrose intake at any time point following any of the naltrexone doses, naltrexone's maximal magnitude of inhibitory effects was small (35-40%) in 129P3/J and SJL/J mice, moderate ( approximately 50%) in BALB/cJ, C3H/HeJ, CD-1 and DBA2/J mice, and profound (70-80%) in C57BL/6J and C57BL/10J mice. Indeed, the latter two strains displayed significantly greater percentages of naltrexone-induced inhibition of sucrose intake than virtually all other strains. These data indicate the importance of genetic variability in opioid modulation of sucrose intake.

Genetic variance contributes to ingestive processes: a survey of eleven inbred mouse strains for fat (Intralipid) intake.

Genetic variation across inbred and outbred mouse strains have been observed for intake of sweet solutions, salts, bitter tastants and a high-fat diet. Our laboratory recently reported marked strain differences in the amounts and/or percentages of kilocalories of sucrose consumed among 11 inbred and one outbred mouse strains exposed to a wide range of nine sucrose concentrations (0.0001-5%) in two-bottle 24-h preference tests. To assess whether differences in fat intake were similarly associated with genetic variation, the present study examined intake of chow, water and an emulsified fat source (Intralipid) across nine different concentrations (0.00001-5%) in the same 11 inbred and 1 outbred mouse strains using two-bottle 24-h preference tests, which controlled for Intralipid concentration presentation effects, Intralipid and water bottle positions, and measurement of kilocalorie intake consumed as Intralipid or chow. Strains displayed differential increases in Intralipid intake relative to corresponding water with significant effects observed at the seven (BALB/cJ: 0.001% threshold sensitivity), four (AKR/J, C57BL/6J, DBA/2J, SWR/J: 0.5% threshold sensitivity), three (CD-1, C57BL/10J, SJL/J: 1% threshold sensitivity) and two (A/J, CBA/J, C3H/HeJ, 129P3/J: 2% threshold sensitivity) highest concentrations. In assessing the percentage of kilocalories consumed as Intralipid, SWR/J mice consumed significantly more at the three highest concentrations to a greater degree than BALB/cJ, C57BL/6J, CD-1, C3H/HeJ, DBA/J and 129P3/J strains which in turn consumed more than A/J, AKR/J, CBA/J, C57BL/10J and SJL/J mice. Relatively strong (h2 = 0.73-0.79) heritability estimates were obtained for weight-adjusted Intralipid intake at those concentrations (0.001-1%) that displayed the largest strain-specific effects in sensitivity to Intralipid. The identification of strains with diverging abilities to regulate kilocalorie intake when presented with high Intralipid concentrations may lead to the successful mapping of genes related to hedonics and obesity.

Morphine hyperalgesia in mice is unrelated to opioid activity, analgesia, or tolerance: evidence for multiple diverse hyperalgesic systems.

Hyperalgesia following chronic morphine treatment is thought to be a response to opioid receptor activation and analgesia and contribute to the development of analgesic tolerance. Here, the relationship between these variables was studied in mice tested for nociceptive sensitivity on the tail-withdrawal test during chronic infusion of various morphine doses. Hyperalgesic onset was preceded by dose-dependent analgesia except for the lowest morphine dose, which caused hyperalgesia 6 h after the start of infusion. Morphine ED50 values obtained at various infusion intervals demonstrated both analgesic tolerance in the absence of hyperalgesia and hyperalgesia in the absence of tolerance. Continuous opioid receptor antagonism using naltrexone pellets abolished analgesia during continuous morphine administration, transiently potentiated hyperalgesia, and revealed differences in hyperalgesic onset between morphine infusion doses. Acute injection of the N-methyl-D-aspartate (NMDA) receptor antagonist MK-801 attenuated hyperalgesia in naltrexone-treated mice, demonstrating a role for this receptor in morphine hyperalgesia unrelated to its effects upon morphine analgesia. In mice where hyperalgesia subsided after continuous infusion of the highest morphine dose (i.e., hyperalgesic adaptation), hyperalgesia was restored after infusing the lower but not higher morphine dose. In addition, acute injection of morphine-3beta-glucoronide (M3G) caused hyperalgesia that was cross-adaptive with the lower morphine dose only. The data demonstrate that morphine hyperalgesia is independent of prior or concurrent opioid receptor activity or analgesia and is unrelated to analgesic tolerance. Furthermore, the lack of hyperalgesic cross-adaptation between high and low morphine doses, and their differential cross-adaptation with M3G hyperalgesia, also suggests distinct morphine dose-dependent hyperalgesic systems.

Genetic variance contributes to ingestive processes: A survey of mercaptoacetate-induced feeding in eleven inbred and one outbred mouse strains.

The feeding response following administration of the free fatty acid oxidation inhibitor, mercaptoacetate (MA) is conceptualized as an experimental model of lipoprivation, which may contribute to the understanding of inter-individual differences in the modulation of this homeostatic response. Although variation in the intake of food, water and glucoprivation as well as intake of several nutrients is known to be associated with genetic variation, it is not known whether MA-induced feeding is similarly dependent upon genotype. The present study therefore examined MA-induced feeding in mice of 11 inbred (A/J, AKR/J, BALB/cJ, CBA/J, C3H/HeJ, C57BL6/J, C57BL10/J, DBA/2J, SJL/J, SWR/J, 129P3/J) and one outbred (CD-1) strains across a wide range of previously determined effective MA doses (5, 35, 70, 100 mg/kg) and test times (1-4 h). MA produced significant dose-dependent and strain-dependent increases in food intake with strong responses noted in DBA/2J, outbred CD-1 and AKR/J mice. More limited dose-specific increases in food intake following MA occurred in C3H/HeJ, BALB/cJ, CBA/J, SJL/J, SWR/J and C57BL/6J mice. In contrast, MA failed to significantly increase food intake in A/J, C57BL/10J and 129P/3J mice. MA-induced food intake correlated significantly across strains only following the two highest doses, and intake following only the highest MA dose correlated significantly across strains with intake following only a moderate glucoprivic dose of 2-deoxy-d-glucose. Thus, these inter-strain differences suggest that lipoprivic (e.g., MA intake) and glucoprivic (e.g., 2-deoxy-d-glucose intake) responsivity operate via only partially overlapping genetic mechanisms of action. The demonstration of genotype-dependent variability in this lipoprivic response may provide the basis for the subsequent identification of trait-relevant genes.

Genetic variance contributes to ingestive processes: a survey of 2-deoxy-D-glucose-induced feeding in eleven inbred mouse strains.

The feeding response following administration of the anti-metabolic glucose analogue, 2-deoxy-d-glucose (2DG), is conceptualized as an experimental model of glucoprivation, which may contribute to the understanding of inter-individual differences in glucose and carbohydrate intake and, ultimately, obesity. Although variation in the intake of several nutrients as well as food and water are known to be associated with genetic variation, it is not known whether 2DG-induced feeding is similarly genotype dependent. The present study therefore examined 2DG-induced feeding in mice of 11 inbred (A/J, AKR/J, BALB/cJ, CBA/J, C3H/HeJ, C57BL6/J, C57BL10/J, DBA/2J, SJL/J, SWR/J, 129P3/J) and one outbred (CD-1) strains across a wide range of previously determined effective 2-DG doses (200, 400, 600, 800 mg/kg) and test times (1-4 h). Orderly dose-dependent increases in 2DG-induced feeding occurred after all four doses in outbred CD-1 and inbred DBA/2J mice, across the three highest doses for BALB/cJ, SJL/J and 129P3/J mice, and across the two highest doses for CBA/J and AKR/J mice. Limited instances of 2DG-induced feeding were noted only at the highest dose in A/J and C3H/HeJ mice, or at a moderate dose in C57BL/6J mice. Further, the full 2DG dose range failed to alter food intake in C57BL/10J mice, and produced significant reductions in food intake in SWR/J mice. Food intake after 2DG doses of 200-600 mg/kg, but not 800 mg/kg, displayed significant cross-correlation, suggesting that large 2DG doses may recruit non-specific effects upon food intake. There was no correlation between food intake in the absence (vehicle baseline) of and presence of 2DG, suggesting that the regulation of glucose intake in non-challenged mice does not predict subsequent responses to glucoprivic challenge. The data demonstrate genotype-dependent variability in this glucoprivic response, and may provide the basis for the subsequent identification of trait-relevant genes.

Inbred mouse strain survey of sucrose intake.

Mouse strain differences for intake of sucrose and saccharin have been reported across studies, and some of these differences have been related to variants of the Tas1r3 taste receptor gene. However, several methodological concerns remain, including use of relatively few strains and/or a limited number of palatable concentrations in previous analyses. The present study examined strain differences in sucrose intake among 11 inbred (A/J, AKR/J, BALB/cJ, CBA/J, C3H/HeJ, C57BL6/J, C57BL10/J, DBA/2J, SJL/J, SWR/J, 129P3/J) and one outbred (CD-1) mouse strains across nine different sucrose concentrations (0.0001-20%) using two-bottle 24-h preference tests which controlled for sucrose concentration presentation effects, sucrose and water bottle positions, and measurement of kilocalorie intake as sucrose or chow. A/J, C57BL/6J, CD-1 and SWR/J strains consumed the greatest (11.6-22 ml) amount of sucrose, whereas the A/J, C57BL/10J, SJL/J and SWR/J strains consumed the greatest (44-56%) percentages of kilocalories as sucrose. The AKR/J, CBA/J, C3H/HeJ and DBA/2J strains consumed the least (6.9-7.9 ml) amount of sucrose, and displayed lower (20-30%) percentages of kilocalories consumed as sucrose. Whereas A/J, C57BL/6J, C57BL/10J, CD-1, SWR/J and SJL/J strains all displayed the most pronounced compensatory decreases in chow intake as the percentage of kilocalories consumed as sucrose increased, the AKR/J, C3H/HeJ and DBA/2J strains failed to significantly alter chow intake even at high sucrose concentrations. There was a paucity of significant correlations in the percentage of sucrose intake between sucrose concentrations, but percentage of sucrose intake at lower concentrations did correlate with previous descriptions of saccharin intake and variants of the Tas1r3 taste receptor gene. These data demonstrate clear mouse strain differences across a range of measures in sucrose intake across a wide range of concentrations, but caution against extrapolating between extremely high and low concentrations. The identification of strains with diverging abilities to regulate kilocalorie intake when presented with high sucrose concentrations may lead to the successful QTL mapping of this trait.

Spinal and supraspinal N-methyl-D-aspartate and melanocortin-1 receptors contribute to a qualitative sex difference in morphine-induced hyperalgesia.

Morphine elicits a paradoxical state of increased pain sensitivity, known as morphine-induced hyperalgesia (MIH), which complicates its clinical efficacy. We have previously shown that systemic injections of N-methyl-d-aspartate receptor (NMDAR) and melanocortin-1 receptor (MC1R) antagonists sex-dependently reverse MIH during morphine infusion (40mg/kg/24h) in male and female mice, respectively. This qualitative sex difference is ovarian hormone dependent, as NMDAR antagonists reverse MIH in ovariectomized females but are rendered ineffective following progesterone injection in OVX mice. Here, we utilized intrathecal and intracerebroventricular injection paradigms to assess the contribution of spinal and supraspinal receptors to this sex difference in male and female CD-1 mice. Specifically, we injected NMDAR and MC1R selective antagonists, MK-801 and MSG606 respectively, during morphine infusion. Results illustrated that both spinal and supraspinal MK-801 and MSG606 selectively reversed MIH in males and females, respectively, during morphine infusion. Furthermore, while MK-801 reversed MIH in ovariectomized (OVX) females, MSG606 was most effective in doing so in this same group following an acute subcutaneous progesterone injection. The present studies thus indicate that both spinal and supraspinal NMDARs and MC1Rs underlie the qualitative sex difference observed during morphine infusion in mice, and that the receptors in these loci are also sensitive to sex steroidal modulation.

Gender effects and central opioid analgesia.

Central morphine analgesia is significantly greater in male than in female rats. Since mu and delta opioid receptor subtypes have been implicated in supraspinal analgesia, the present study evaluated whether gender or adult gonadectomy altered (a) analgesia on the tail-flick and jump tests following central administration of the mu-selective agonist, [D-Ala2, Me-Phe4, Gly(ol)5] enkephalin (DAMGO) and the delta-selective agonist, [D-Ser2,Leu5] enkephalin-Thr6 (DSLET) and (b) mu1, mu2 and delta opioid receptor binding. Sham-operated male rats displayed significantly greater magnitudes of peak and total analgesia than sham-operated females on the tail-flick test following DAMGO, but not DSLET. Gender differences were not observed for DAMGO and DSLET analgesia on the jump test. Gonadectomy failed to consistently affect either DAMGO or DSLET analgesia. Regression analyses failed to reflect significant shifts in the dose-response functions for either agonist on either measure. Gender differences were not observed for mu1, mu2, or delta binding in hypothalamus or cortex. These data are compared with analgesic responses sensitive to gender differences.

Sex differences in the antagonism of swim stress-induced analgesia: effects of gonadectomy and estrogen replacement.

Sex differences in the neurochemical mediation of swim stress-induced analgesia (SSIA) were examined in Swiss-Webster mice. Intact and gonadectomized adult mice of both sexes were tested for their analgesic response (hot-plate test) to 3 min of forced swimming in 15 degrees C and 20 degrees C water. SSIA resulting from 15 degrees C swim was previously shown to be naloxone-insensitive (i.e., non-opioid) whereas SSIA resulting from 20 degrees C swim produced an analgesia that was partially reversible by naloxone (i.e., mixed opioid/non-opioid). The non-opioid components of these SSIA paradigms were attenuated by the N-methyl-D-aspartate (NMDA) receptor antagonist, dizocilpine (MK-801). We now report that in males, but not females, dizocilpine (0.075 mg/kg, i.p.) and naloxone (10 mg/kg, i.p.) antagonized the non-opioid and opioid components of SSIA, respectively. After ovariectomy, females displayed a pattern of antagonism similar to males such that dizocilpine attenuated non-opioid SSIA, although naloxone remained ineffective in antagonizing 20 degrees C SSIA. Thus, SSIA in intact females was neither opioid- nor NMDA-mediated, yet it was of similar magnitude to the SSIA displayed by intact males. In separate experiments, estrogen replacement (estrogen benzoate; 5.0 micrograms/day, i.p.) administered to ovariectomized mice over a 6-8 day period reinstated the dizocilpine-insensitivity of 15 degrees C SSIA characteristic of intact females. However, a similar estrogen regimen administered to both intact and castrated males did not compromise the sensitivity to dizocilpine previously noted in male mice.(ABSTRACT TRUNCATED AT 250 WORDS)

Neonatal testosterone exposure influences neurochemistry of non-opioid swim stress-induced analgesia in adult mice.

The effects of neonatal hormone manipulations on swim stress-induced analgesia (SSIA) magnitude and neurochemical quality were examined in Swiss-Webster mice of both sexes. Previous research has indicated that non-opioid SSIA mechanisms in adult Swiss-Webster mice are sexually dimorphic. Male mice exhibit non-opioid SSIA following a 3-min swim in cold (15 degrees C) water that is antagonized by the non-competitive NMDA antagonist MK-801 (dizocilpine; 0.075 mg/kg), whereas female mice do not display NMDA-mediated analgesia in the presence of estrogen. Since male and female mice show equipotent magnitudes of SSIA, it was concluded that female mice display a neurochemically distinct, estrogen-dependent SSIA mechanism specific to their gender. In the present study, female mice exposed to testosterone during the neonatal period display NMDA-mediated analgesia even in the presence of estrogen in adulthood. Thus, expression of the female-specific, estrogen-dependent SSIA mechanism previously described may be dependent on the absence of testosterone during early ontogeny.

One or two genetic loci mediate high opiate analgesia in selectively bred mice.

The analgesic responses of humans and laboratory animals are characterized by substantial individual differences. The genetic basis of this variability can be studied experimentally in rodents using a program of selective breeding. One such program selected for high (HA) and low (LA) swim stress-induced analgesia (SSIA) on the hot-plate (56 degrees C) test in Swiss-Webster mice. These lines, which have been selectively bred for more than 25 generations, display markedly divergent opioid-mediated SSIA (3-min swims in 38 degrees C water), morphine analgesia (10 mg/kg, i.p.), and analgesia to the kappa-receptor agonist, U-50,488H (30 mg/kg, i.p.). The present study investigated the mode of inheritance of these opioid analgesias in HA and LA mice, using Mendelian genetic analyses. We report that the differential sensitivity of HA and LA mice to each of these analgesic manipulations appears to be determined oligogenically, by one or at the most two major genetic loci. The loci associated with each type of analgesia do not co-segregate, however, indicating that three distinct oligogenic effects have been identified. These findings suggest that the genetic determination of analgesic mechanisms may have simple components and as such may be amenable to further analysis using molecular genetic techniques.