Role of endogenous cyclo(His-Pro) in cold-induced hypothermia in the desert rat (Mastomys natalensis).

Central administration of exogenous cyclo(His-Pro) (CHP) is known to produce hypothermia in rodents. In the present study, we examined the role of endogenous CHP in cold-induced hypothermia in the desert rat, Mastomys natalensis. The results of these studies show that a rise in hypothalamic CHP content accompanied a decrease in rectal temperature during cold exposure. Immunoneutralization of endogenous CHP resulted in a significant decline in cold-induced hypothermia. In addition, central administration of cyclo(Ala-Gly), a structural analogue of CHP, also led to a decrease in cold-induced hypothermia. The results of these studies show that changes in endogenous CHP levels may affect body temperature regulation.

Time course of the distribution of morphine in brain regions, spinal cord and serum following intravenous injection to rats of differing ages.

Previously it was demonstrated that intravenously administered morphine produced greater analgesic but lower hyperthermic responses to morphine in 24-week-old rats in comparison to 8-week-old rats. The differential pharmacological responses to morphine could not solely be attributed to the pharmacokinetic parameters, namely area under the serum morphine concentration-time curve, serum levels of morphine extrapolated to zero time, half-life, mean residence time, apparent volume of distribution at the steady state, terminal rate constant and total body clearance of morphine in serum. In order to determine whether the differences in pharmacological responses to morphine in rats from two age groups are related to differential distribution of morphine in the central nervous system, in the present study, the time course of the distribution of morphine in brain regions (hypothalamus, hippocampus, cortex, pons and medulla, amygdala, midbrain and corpus striatum), spinal cord and serum following intravenous injection of 10 mg/kg dose to 8- and 24-week-old male Sprague-Dawley rats was determined. Morphine injected intravenously produced a greater analgesic but less intense hyperthermic effect in 24-week-old rats in comparison to 8-week-old rats. In most of the brain regions and spinal cord, with few exceptions, the concentration of morphine was found to be greater in 24-week-old rats than in 8-week-old rats. Similarly, the ratio of the concentration of morphine in brain region or spinal cord to serum was significantly higher in rats from the older age group. The studies demonstrate that the altered pharmacological responses to intravenously administered morphine to rats of differing ages may be related to the higher concentration of morphine in the central nervous system of older rats, which in turn may be related to the differences in the blood-brain barrier to morphine in the two age groups.

Naltrexone-induced alterations of the distribution of morphine in brain regions and spinal cord of the rat.

The effects of naltrexone injected intravenously (i.v.) on the pharmacological actions and distribution of i.v. injected morphine in brain regions and spinal cord of male Sprague-Dawley rats were determined. Naltrexone (0.625- and 2.5-mg/kg doses) antagonized the analgesic and hyperthermic effects of morphine (10-mg/kg dose). For distribution studies, naltrexone (0.625- and 2.5-mg/kg doses) was co-administered with morphine via indwelling catheters. Rats were sacrificed at various times after drug injection and the concentration of morphine in brain regions (hypothalamus, hippocampus, cortex, pons and medulla, amygdala, midbrain and corpus striatum), spinal cord and serum was determined by radioimmunoassay. The concentration of morphine in various brain regions was found to be time dependent. Initially, at 5 min, the highest concentration of morphine was found in the hypothalamus and the lowest in the striatum. In cortex and spinal cord, the concentration of morphine was significantly higher in comparison to the other brain regions at 30- and 60-min time points. Co-administration of lower dose of naltrexone (0.625 mg/kg) did not significantly alter the distribution of morphine in brain regions and spinal cord with some exceptions. The higher dose of naltrexone (2.5 mg/kg) increased the concentration of morphine in several brain regions and spinal cord. The ratio of the concentration of morphine in brain region or spinal cord to serum was decreased by naltrexone. It is concluded that naltrexone also alters the distribution of morphine in the central nervous system.

Effects of naltrexone on pharmacodynamics and pharmacokinetics of intravenously administered morphine in the rat.

Effects of naltrexone administered intravenously on the pharmacological actions and kinetics of morphine in serum following intravenous administration of morphine were determined in male Sprague-Dawley rats. A 10 mg/kg dose of morphine produced an analgesic response as measured by the tail flick test. Morphine also produced a hyperthermic effect. Naltrexone dose (0.625-2.5 mg/kg)-dependently antagonized the analgesic and hyperthermic effects of morphine. The effect of naltrexone (0.625 and 2.5 mg/kg) on the pharmacokinetic parameters area under the serum morphine concentration time curve (AUC0-->infinity), serum levels of morphine extrapolated to zero time (Cmax), half-life (t1/2), mean residence time (MRT), total body clearance (Clt), and volume of distribution at steady state (Vss) of morphine in serum was determined. Naltrexone (0.625 mg/kg) significantly increased AUC0-->infinity, Cmax, t1/2 MRT, but decreased the Vss, elimination rate constant (k) and Clt. The higher dose of naltrexone (2.5 mg/kg) produced an increase in the Cmax value of morphine in the serum, but the other pharmacokinetic parameters were unaffected. Since increased morphine concentrations in serum produced by naltrexone cannot explain its antagonistic effects on analgesia and hyperthermia, it is concluded that naltrexone produces its effects by blocking opiate receptors at the appropriate sites. The increases in serum morphine levels by naltrexone may be related to displacement of morphine from protein binding sites and inhibition of morphine metabolism by glucuronyl transferase. This study for the first time demonstrates that in the rat, when morphine and naltrexone are given concurrently, although serum levels of morphine increase, pharmacological effects of morphine are antagonized.(ABSTRACT TRUNCATED AT 250 WORDS)

Binding of 3H-D-Pen2-D-Pen5-enkephalin to brain regions and spinal cord membranes of spontaneously hypertensive and normotensive Wistar-Kyoto rats.

The binding of 3H-D-Pen2-D-Pen5-enkephalin (DPDPE), a highly selective delta-opiate receptor agonist, to membranes of discrete brain regions and spinal cord of 10-week-old spontaneously hypertensive (SHR) and normotensive Wistar-Kyoto (WKY) rats was determined. The brain regions examined were amygdala, hippocampus, hypothalamus, pons and medulla, corpus striatum, midbrain and cortex. 3H-DPDPE bound to membranes of brain regions and spinal cord at a single high affinity site with apparent dissociation constant value of 4 nmol/l, except in cortex where the values were higher. The highest density of 3H-DPDPE binding sites were in hypothalamus and lowest in pons and medulla. The receptor density (Bmax value) and apparent dissociation constant (Kd value) of 3H-DPDPE to bind to delta-opiate receptors on the membranes of hippocampus, hypothalamus, corpus striatum, midbrain, cortex, pons and medulla and spinal cord of WKY and SHR rats did not differ. The Bmax value of 3H-DPDPE in amygdala of SHR rats was higher than in WKY rats, but the Kd values in the two strains did not differ. It is concluded that SHR rats have a higher density of delta-opiate receptors, labeled with 3H-DPDPE, in amygdala in comparison with WKY rats. Whether such a difference in the density of delta-opiate receptors is related to the elevated blood pressure of SHR rats is not clear.

Studies on the possible role of pharmacokinetics in the development of tolerance to morphine in the rat.

1. The possible role of pharmacokinetics of morphine in the development of tolerance to the analgesic and hyperthermic effects of morphine was studied in the rat. 2. Male Sprague-Dawley rats were made tolerant to morphine by implanting 6 morphine pellets each containing 75 mg of morphine base for 7 days. The assessment of the degree of tolerance to morphine and pharmacokinetic parameters were done 72 hr after pellet removal. 3. Tolerance developed to both the analgesic and hyperthermic effects of morphine as evidenced by decreased responses to morphine in morphine pellet implanted rats compared with placebo pellet implanted rats. 4. The pharmacokinetic parameters, AUC0-->infinity, Cmax, t1/2, k, MRT, Vss and Clt were determined after injecting 5 and 10 mg/kg doses of morphine intravenously to placebo and morphine pellet implanted rats and using a highly sensitive and specific RIA method to quantitate serum levels of morphine. For a 5 mg/kg dose of morphine, the AUC0-->infinity and t1/2 in morphine pellet implanted rats were significantly higher than in placebo pellet implanted rats, but the k value was lower. The other pharmacokinetic parameters for morphine in the two treatment groups did not differ. For 10 mg/kg dose, the only change was an increase in the MRT in morphine tolerant rats when compared to nontolerant rats. 5. The results establish that the development of tolerance to the analgesic and hyperthermic effects of morphine is not related to pharmacokinetics of morphine in serum but may be related to modification of receptor systems in the central nervous system.

Distribution of morphine in brain regions, spinal cord and serum following intravenous injection to morphine tolerant rats.

In order to determine the possible contribution of altered distribution of morphine in the morphine tolerance process, the distribution of morphine was studied in brain regions and spinal cord, following its intravenous administration. Male Sprague-Dawley rats were made tolerant to morphine by implanting 6 morphine pellets, each containing 75 mg of morphine base, for 7 days. Seventy-two hours after the removal of the pellets, a time when serum morphine levels were negligible or absent and yet tolerance to the pharmacological effects of morphine was present, morphine (10 mg/kg, i.v.) was injected in placebo and morphine pellet implanted rats. At various times (5, 30, 60, 120 and 360 min) after the injection of morphine, brain regions (hypothalamus, cortex, hippocampus, midbrain, pons and medulla, striatum and amygdala), spinal cord and serum were collected. The level of morphine in the tissues was determined by using a highly sensitive and specific radioimmunoassay (RIA) method. Five minutes after morphine injection, the concentration of morphine was the highest in the hypothalamus and the lowest in amygdala. The concentration of morphine in hypothalamus, pons and medulla, hippocampus and midbrain of morphine tolerant rats was smaller than in placebo pellet implanted rats. The tissue to serum ratio of morphine in the hypothalamus, hippocampus, striatum, midbrain and cortex were also smaller in morphine tolerant than in non-tolerant rats. The concentration of morphine in brain regions with time did not exhibit linearity. At other time intervals like 30 and 60 min, the concentration of morphine in several brain regions and spinal cord was significantly higher in morphine tolerant than in non-tolerant rats.(ABSTRACT TRUNCATED AT 250 WORDS)

Time course of the distribution of morphine in brain regions and spinal cord after intravenous injection to spontaneously hypertensive and normotensive Wistar-Kyoto rats.

Previous studies from this laboratory have demonstrated that the analgesic and hyperthermic effects of morphine were found to be greater in spontaneously hypertensive (SHR) rats than in normotensive Wistar-Kyoto (WKY) rats. The enhanced response to morphine could not be explained on the basis of any of the pharmacokinetic parameters of morphine in the serum. In order to determine the possible contribution of altered distribution of morphine in the central nervous system in the differences in the pharmacological response to morphine in the two strains, the time course of the distribution of morphine was determined in brain regions and spinal cord after its i.v. administration. SHR and WKY rats were injected with morphine (10 mg/kg). At various times (5, 30, 60, 120 and 360 min) after the injection of morphine, brain regions (hypothalamus, cortex, hippocampus, midbrain, pons and medulla, striatum and amygdala) and spinal cord were collected. The level of morphine in the tissues was determined by using a highly sensitive and specific radioimmunoassay method. Five minutes after morphine injection, the concentration of morphine was the highest in the spinal cord. Among the brain regions, the highest concentration of morphine was in the hypothalamus and the lowest in the amygdala. In all the brain regions and spinal cord, the concentration of morphine was significantly higher in the SHR than in the WKY rats. Similar effects were observed at 30, 60 and 120 min after morphine injection. At 360 min, the hypothalamus, cortex and spinal cord of the SHR rats had higher concentrations of morphine than the WKY rats, but the other regions did not show differences in the morphine levels.(ABSTRACT TRUNCATED AT 250 WORDS)

Down-regulation of central receptors for thyrotropin-releasing hormone in kappa opiate agonist-induced abstinence in the rat.

The effect of U-50,488H, a selective kappa opiate agonist, on tolerance-dependence and abstinence on the TRH receptors of the spinal cord and discrete regions of the brain of male Sprague-Dawley rats was determined. Rats were injected intraperitoneally twice daily with 25 mg/kg of U-50,488H for 4 days. Rats serving as controls were injected with the vehicle. On day 5, rats which were labeled as tolerant to U-50,488H were injected with U-50,488H (25 mg/kg) and sacrificed 1 hr later, whereas those labeled as abstinent were sacrificed without any injection. The above procedure has been previously shown to produce a high degree of tolerance to the analgesic and hypothermic effects of U-50,488H. The spinal cord and regions of the brain (hippocampus, cortex, midbrain, hypothalamus, corpus striatum, pons and medulla, and amygdala) were isolated for binding studies. The ligand [3H]MeTRH was used for TRH receptors. The binding constants, Bmax and Kd values, of [3H]MeTRH to bind to membranes prepared from various regions of the brain and spinal cord of rats tolerant-dependent on U-50,488H were unaffected. However, in rats abstinent to U-50,488H, the binding of [3H]MeTRH to membranes of the hypothalamus, and pons and medulla, was decreased. The decreased binding of [3H]MeTRH to hypothalamic membranes was due to changes in Bmax value, while in pons and medulla it was due to an increase in the Kd value.(ABSTRACT TRUNCATED AT 250 WORDS)

Differences in the binding of [3H][D-Ser2,Thr6]leucine-enkephalin and [3H][D-Pen2,D-Pen5]enkephalin to brain membranes of morphine tolerant-dependent rats.

The effect of morphine tolerance-dependence and abstinence on the characteristics of delta-opiate receptors was determined in male Sprague-Dawley rats. Two ligands used for characterizing the receptors were [3H][D-Ser2,Thr6]leucine-enkephalin ([3H]DSTLE) and [3H][D-Pen2,D-Pen5]enkephalin ([3H]DPDPE). Rats were implanted s.c. under light ether anesthesia with six morphine pellets (each containing 75 mg of morphine free base). Rats which served as controls were implanted similarly with placebo pellets. Two sets of rats were used. In one group of rats, the pellets were left intact (tolerant-dependent) at the time of sacrificing and in the other the pellets had been removed 18 h earlier (abstinent). The spinal cord and brain regions (amygdala, hippocampus, hypothalamus, corpus striatum, mid-brain, pons and medulla and cortex) were dissected for binding studies. The binding of [3H]DSTLE to membranes of cerebral cortex of morphine-tolerant-dependent rats was decreased in comparison to control rats, and was due to a decrease in Bmax rather than Kd value. The binding of [3H]DSTLE to other brain regions or spinal cord of morphine-tolerant-dependent and abstinent rats did not differ from their respective controls. On the other hand, the binding of [3H]DPDPE was unaffected in any brain region or the spinal cord of morphine-tolerant-dependent and abstinent rats when compared to their controls. The decrease in binding of [3H]DSTLE to cortical membranes of morphine-tolerant-dependent rats amounted to 15%. Since DSTLE also binds to mu-opiate receptors, which have earlier been shown to be decreased in cortex of morphine-tolerant-dependent rats, and the binding of a more selective delta-opiate ligand [3H]DPDPE was unaffected, it is concluded that central delta-opiate receptors do not play a role in the development of morphine-induced tolerance-dependence or abstinence processes in the rat.

Opiate antagonist binding sites in discrete brain regions of spontaneously hypertensive and normotensive Wistar-Kyoto rats.

The binding of 3H-naltrexone, an opiate receptor antagonist, to membranes of discrete brain regions and spinal cord of 10 week old spontaneously hypertensive (SHR) and normotensive Wistar-Kyoto (WKY) rats was determined. The brain regions examined were hypothalamus, amygdala, hippocampus, corpus striatum, pons and medulla, midbrain and cortex. 3H-Naltrexone bound to membranes of brain regions and spinal cord at a single high affinity site with an apparent dissociation constant value of 3 nM. The highest density of 3H-naltrexone binding sites were in hippocampus and lowest in the cerebral cortex. The receptor density (Bmax value) and apparent dissociation constant (Kd value) values of 3H-naltrexone to bind to opiate receptors on the membranes of amygdala, hippocampus, corpus striatum, pons and medulla, midbrain, cortex and spinal cord of WKY and SHR rats did not differ. The Bmax value of 3H-naltrexone binding to membranes of hypothalamus of SHR rats was 518% higher than WKY rats but the Kd values in the two strains did not differ. It is concluded that SHR rats have higher density of opiate receptors labeled with 3H-naltrexone in the hypothalamus only, in comparison with WKY rats, and that such a difference in the density of opiate receptors may be related to the elevated blood pressure in SHR rats.

Differential effects of two kappa-opiate agonists, U-50,488H and U-69,593, on the binding of 3H-(3-MeHis2) thyrotropin-releasing hormone to rat spinal cord and amygdala membranes.

The effect of delta- and kappa-opiate receptor agonists on the binding of 3H-(3-MeHis2) thyrotropin-releasing hormone (3H-MeTRH) to membranes of the spinal cord and amygdala of male Sprague-Dawley rats was determined in an effort to further understand interactions between opiates and TRH receptors. The agonists used were D-Ala2-MePhe4-Gly-ol5-enkephalin (DAMGO, mu-receptor), cyclic D-penicillamine2-D-penicillamine5-enkephalin (DPDPE, delta-receptor), cyclic D-penicillamine2-L-penicillamine5-enkephalin (DPLPE, delta-receptor), D-Ala2-D-Leu5-enkephalin (delta-receptor), U-50,488H and U-69,593 (kappa-receptor). 3H-MeTRH bound to amygdala and spinal cord membranes at a single site with Bmax values of 35.7 +/- 5.4 and 15.8 +/- 2.6 fmol/mg protein, and Kd values of 6.3 +/- 1.1 and 5.2 +/- 0.7 nmol/l, respectively. The competition experiments were carried out at a concentration of 2 nmol/l 3H-MeTRH. The concentration of opiate ranged from 10(-9) to 10(-4) mol/l. DAMGO, DPDPE and DPLPE had no effect on the binding of 3H-MeTRH to amygdala or spinal cord membranes. The two highly selective kappa-agonists differed in their interaction with TRH receptors. Whereas U-69,593 did not modify the binding of 3H-MeTRH, U-50,488H significantly inhibited the binding of 3H-MeTRH to both spinal cord and amygdala membranes. U-50,488H has been found to be 10 times more potent than U-69,593 at the central kappa-opiate receptors and may explain their differential action at the TRH receptors. It is concluded that mu- and delta-opiate agonists do not interact with brain and spinal cord TRH receptors.(ABSTRACT TRUNCATED AT 250 WORDS)

Spinal cord thyrotropin releasing hormone receptors of morphine tolerant-dependent and abstinent rats.

The effect of chronic administration of morphine and its withdrawal on the binding of 3H-[3-MeHis2]thyrotropin releasing hormone (3H-MeTRH) to membranes of the spinal cord of the rat was determined. Male Sprague-Dawley rats were implanted with either 6 placebo or 6 morphine pellets (each containing 75-mg morphine base) during a 7-day period. Two sets of animals were used. In one, the pellets were left intact at the time of sacrificing (tolerant-dependent) and in the other, the pellets were removed 16 hours prior to sacrificing (abstinent rats). In placebo-pellet-implanted rats, 3H-MeTRH bound to the spinal cord membranes at a single high affinity binding site with a Bmax of 21.3 +/- 1.6 fmol/mg protein, and an apparent dissociation constant Kd of 4.7 +/- 0.8 nM. In morphine tolerant-dependent or abstinent rats, the binding constants of 3H-MeTRH to spinal cord membranes were unaffected. Previous studies from this laboratory indicate that TRH can inhibit morphine tolerance-dependence and abstinence processes without modifying brain TRH receptors. Together with the present results, it appears that the inhibitory effect of TRH on morphine tolerance-dependence and abstinence is probably not mediated via central TRH receptors but may be due to its interaction with other neurotransmitter systems.

Reactivity of trachea, bronchi, and lung strips to histamine and carbachol in rhesus monkeys.

Responses of isolated airway smooth muscles of a subhuman primate to carbachol and histamine were investigated. Isolated lung parenchymal strips of rhesus monkeys (RM) exhibited approximately equal sensitivity (i.e., ED50) and contractility (i.e., maximum tension) to carbachol and histamine. Tracheal chains and bronchial strips responded with concentration-dependent contractions to carbachol. Trachea did not exhibit any contractile responses to histamine. Bronchial strips responded with weak contractile responses to histamine when compared with those elicited ay carbachol. Histamine-induced contractions on bronchi and lung strips were easily antagonized by pyrilamine (H1-receptor antagonist) (10(-6) to 5 X 10(-6) M). Carbachol-contracted trachea and bronchi responded with relaxations to histamine and dimaprit (H2-receptor agonist) that were antagonized by metiamide (H2-receptor antagonist) (5 X 10(-5) M). The present findings indicate 1) a differential reactivity of central and peripheral airway smooth muscles of RM to histamine and carbachol; 2) lung strips of RM appear to possess only H1 types of histamine receptors; 3) bronchial smooth muscles of RM have a small population of H1-receptors mediating bronchoconstriction; and 4) a preponderance of inhibitory H2-receptors in the tracheobronchial smooth muscles of rhesus monkeys. If these subhuman primate findings apply to the airways of man, they could aid considerably in furthering our understanding of the pathophysiology of the respiratory tract.