Gabriela Patrini

Chronic CP-55,940 alters cannabinoid receptor mRNA in the rat brain: an in situ hybridization study.

Using in situ hybridization we found that chronic treatment with CP-55,940 (0.4 mg kg-1, i.p. daily for 11 days), a synthetic cannabinoid receptor ligand, changed cannabinoid receptor mRNA levels in rat brain. CP-55,940 produced the expected tolerance: the decrease in locomotor activity (75%) caused by an acute dose was diminished to 25% after the 11 days of treatment. Thirty minutes after the last injection the animals were killed and in situ hybridization indicated that the levels of cannabinoid receptor mRNA in the caudate-putamen were reduced by 33%, with no alteration in the other brain areas. We suggest that the altered cannabinoid receptor expression is part of the adaptive changes underlying cannabinoid tolerance.

Chronic treatment with a synthetic cannabinoid CP-55,940 alters G-protein expression in the rat central nervous system

Prolonged exposure of rats to the synthetic cannabinoid receptor ligand, CP-55,940 (0.4 mg/kg, i.p. for 11 days), induced tolerance to analgesia, to the reduction in spontaneous locomotor activity and the incidence of splayed hind limbs. One hour after the last injection on day 11, the rats were killed and in situ hybridization was used to investigate the effect of treatment on G-protein alpha-subunit expression throughout the brain. Chronic cannabinoid exposure markedly reduced G alpha(s), G alpha(i) and G alpha(o) mRNA levels. The message for the alpha(s)-subunit was decreased in all the brain areas containing the basal autoradiographic signal; the decrease ranging from 25% in the thalamus to 45% in the mesencephalon. Also the basal G alpha(i) expression was reduced in tolerant rats showing the greatest decrease in the forebrain (63%) in the cerebellum (58%) and in the mesencephalon (38%). The reduction in G alpha(o) expression (25%) was more localized, being present only in the rostral portion of the brain (cortex, striatum and olfactory area). The alterations in alpha-subunits gene expression were not followed by any change in the amount of proteins. Our results indicate that, besides the receptor modification, alteration to the G-protein expression could be a molecular event associated with the development of cannabinoid tolerance.

Pertussis toxin inhibits morphine analgesia and prevents opiate dependence

Six days after intracerebroventricular pretreatment of rats with pertussis toxin (PTX 0.5 microgram/rat) there was a marked decrease in the antinociceptive effect of morphine, regardless of the route of opioid administration (into the periaqueductal gray matter, intrathecally or intraperitoneally) or the analgesic test used (tail flick and jaw opening reflex). PTX pretreatment also partially attenuated the naloxone-precipitated withdrawal syndrome in morphine-dependent rats, significantly reducing teeth chattering, rearing and grooming. These in vivo findings indicate that G-protein-dependent mechanisms are involved in morphine analgesia and dependence. The biochemical mechanism could be related to ADP ribosylation of Gi coupled to the adenylate cyclase system, but an interaction of PTX with other G-proteins linked to different second messengers or directly to ionic channels cannot be excluded.

In situ hybridization reveals specific increases in Gαs and Gαo mRNA in discrete brain regions of morphine-tolerant rats

Abstract In situ hybridization histochemistry has been used to detect the basal distribution of mRNA encoding the α subunit of G s , G o and G i2 proteins throughout the rat brain. Based on these data we investigated the effect of chronic morphine on the content of these G protein α subunits mRNA. We observed an increase in the expression of α s and α o messages of chronically morphine-treated animals, while no changes were seen in α i2 mRNA. Specifically a 30% increase in expression for α s was seen only in the paraventricular nucleus of hypothalamus and a 20% elevation for α o was detected in the claustrum and endopiriform nucleus. Immunoblotting analysis was used to correlate the changes in α s and α o messages with equivalent changes in protein levels. Chronic morphine significantly increased α s amounts in the hypothalamus (70%), and produced a minor elevation (30%) in Gα o levels in the olfactory area. Our results indicate that in discrete brain regions altered G protein expression is part of the adaptive changes underlying opiate tolerance.

REGULATION OF IMMUNE FUNCTIONS IN RAT SPLENOCYTES AFTER ACUTE AND CHRONIC IN VIVO TREATMENT WITH CP-55,940, A SYNTHETIC CANNABINOID COMPOUND

Changes in mitogen-induced splenocyte proliferation and NK activity were evaluated after acute (1 h) and chronic (6 d) in vivo treatment of rats with the synthetic cannabinoid compound CP-55,940. At a dose of 0.4 mg/kg i.p. it significantly inhibited the splenocyte proliferative response to PHA and NK activity but half this dose (0.2 mg/kg) had no effect on immune responses. Pretreatment of rats with the cannabinoid receptor CB1 antagonist SR141716A did not antagonize the CP-55,940-induced immunosuppression, excluding the activation of this receptor subtype in the mediation of this effect. When immune function studies were done on rats tolerant to CP-55,940-induced analgesia, full tolerance also developed for the inhibition of splenocyte proliferation and NK activity. The data provided indicate that CB1 cannabinoid receptors are not involved in mediating the acute and chronic effects of cannabinoids on the immune system and suggest a possible implication of CB2 receptor although other modalities of CP-55,940 action can not be ruled out.

Changes in rat spleen cannabinoid receptors after chronic CP-55,940: an autoradiographic study.

We examined whether cannabinoid receptor density changes in the rat spleen after in vivo chronic exposure to cannabinoids. Rats received daily injections of 0.4 mg/kg IP of the synthetic cannabinoid receptor ligand CP-55,940 for 11 days. One h after the last injection on day 11, the rats were killed and spleen coronal sections were processed for receptor binding autoradiography with 10 nM of [3H]CP-55,940 in the absence or presence of unlabeled CP-55,940 (10 microM). Densitometric analysis of the autoradiograms showed significant loss of [3H]CP-55,940 binding of about 42% in chronic cannabinoid-treated, tolerant rats. Our findings indicate that cannabinoid receptors basically present in immune spleen cells are down-regulated by chronic exposure to cannabinoids, suggesting a role in immune modulation and in the impairment of immune function.

Effect of chronic exposure to naltrexone and opioid selective agonists on G protein mRNA levels in the rat nervous system.

The in situ hybridization technique was used to investigate the effect on G protein alpha subunit expression throughout the brain of rats chronically infused with naltrexone (70 micrograms/microliters, 1 microliter/h), DAGO (0.5 micrograms/microliter, 1 microliter/h), DADLE (11.4 micrograms/microliters, 1 microliter/h), DPDPE (3.4 micrograms/microliters, 1 microliter/h) and U-50,488H (4 micrograms/microliters, 1 microliter/h). Prolonged exposure to naltrexone did not modify G protein alpha subunit mRNA expression, whereas DADLE and U-50,488H, respectively, increased the levels of alpha s and alpha o mRNA in specific brain regions. In particular, a 15% increase in alpha s expression was only observed in the dorsomedial hypothalamic nucleus of rats undergoing chronic DADLE infusion: a 15% increase in alpha o levels was detected in the claustrum and endopiriform nucleus of rats chronically treated with U-50,488H. These are the first in vivo data to demonstrate that only chronic stimulation with an opioid agonist (morphine and/or DADLE and U-50,488H) is capable of modifying G protein alpha subunit mRNA. The regional selectivity of these modifications is discussed, together with the receptor specificity of the opioid effects.

Pertussis toxin modifies the effect of central morphine on rat intestinal motility

To find whether the antipropulsive effect of morphine administered intracerebroventricularly (i.c.v.) depends on a G-protein-mediated mechanism, we studied the effect of i.c.v. pertussis toxin (PTX) pretreatment on morphine-induced inhibition of intestinal motility. The influence of PTX was evaluated on intestinal transit (charcoal meal test) and by monitoring of intestinal myoelectrical activity. The antitransit effect of morphine (10 micrograms/rat) was antagonized by about 70% 3, 6, 9 and 12 days after PTX pretreatment (1 microgram/rat) and it was partially restored after 25 days. I.c.v. morphine abolished the regular appearance of the myoelectric migrating complex (MMC) recorded in the rat jejunum and this effect was completely antagonized by PTX pretreatment. When morphine was injected 25 days after PTX, it significantly reduced MMC frequency, confirming the partial recovery seen in the transit experiments. The pertussis toxin-catalyzed ADP ribosylation of a 39-41 kDa substrate in membranes prepared from hypothalamus and midbrain of rats injected with toxin 6 days before was strongly reduced as compared to the controls. On the contrary, after 25 days, ADP ribosylation was the same in treated and control rats. Thus the antipropulsive effect of central morphine could be initiated at receptor sites which interact with G-protein substrates of pertussis toxin.

Morphine withdrawal syndrome and G protein expression: a study of the time course in the rat central nervous system.

We followed the changes in G protein α subunit expression and levels throughout the brain during the naltrexone‐precipitated withdrawal syndrome in morphine‐dependent rats. Intraperitoneally injected naltrexone (10 mg/kg) in rats made tolerant to morphine resulted in sustained withdrawal. Additional naltrexone doses 6, 24 and 72 h later still induced a significant abstinence syndrome. At the fifth naltrexone injection (8 days later) counted signs were completely resolved but checked ones were not. Besides the behavioural modifications, opiate withdrawal affected G protein expression in the central nervous system. In situ hybridization showed that Gαs and Gαo mRNA, whose levels are increased in tolerance, changed further during opiate withdrawal. Specifically, the αs mRNA in the hypothalamus was reduced after the first naltrexone injection and reached the control level with subsequent doses. However, αo mRNA expression in the olfactory system remained elevated after repeated naltrexone injections, declining to the control value only after the fifth dose. The amounts of Gαs and Gαo protein closely followed the time course of mRNA. The relationship between behavioural and biochemical parameters is discussed, together with the regional selectivity of the modifications.

Pertussis toxin pretreatment affects opiate/nonopiate and stress-induced analgesia differently

Intracerebroventricular injection of pertussis toxin (PTX, 1 microgram/rat) six days before the hot plate test abolished analgesia induced by central morphine. The toxin did not affect analgesia evoked by central neurotensin or ASU 1-7 eel calcitonin. PTX pretreatment also attenuated footshock-induced analgesia (FSIA) delivered to all four paws. When the shock was restricted to the front paws, PTX consistently lowered postshock tail flick latencies, but did not reduce analgesia resulting from shock delivered to the hind paws. It thus appears that PTX-sensitive G-proteins are an essential transduction step needed to initiate the molecular events underlying opiate analgesia evoked by either morphine or shock. In contrast, the signal transduction mechanism subsequent to the stimulation of neurotensin or calcitonin receptors, and to the nonopiate FSIA, appears not to involve PTX-sensitive G-proteins.