Effect of early exposure to delta-9-tetrahydrocannabinol on the levels of opioid peptides, gonadotropin-releasing hormone and substance P in the adult male rat brain

The Impact of Early Life Exposure to Cannabis: The Role of the Endocannabinoid System

Cannabis use during pregnancy has continued to rise, particularly in developed countries, as a result of the trend towards legalization and lack of consistent, evidence-based knowledge on the matter. While there is conflicting data regarding whether cannabis use during pregnancy leads to adverse outcomes such as stillbirth, preterm birth, low birthweight, or increased admission to neonatal intensive care units, investigations into long-term effects on the offspring’s health are limited. Historically, studies have focused on the neurobehavioral effects of prenatal cannabis exposure on the offspring. The effects of cannabis on other physiological aspects of the developing fetus have received less attention. Importantly, our knowledge about cannabinoid signaling in the placenta is also limited. The endocannabinoid system (ECS) is present at early stages of development and represents a potential target for exogenous cannabinoids in utero. The ECS is expressed in a broad range of tissues and influences a spectrum of cellular functions. The aim of this review is to explore the current evidence surrounding the effects of prenatal exposure to cannabinoids and the role of the ECS in the placenta and the developing fetus.

Persistent proteomic changes in glutamatergic and GABAergic signaling in the amygdala of adolescent rats exposed to chlorpyrifos as juveniles

Chlorpyrifos (CPF) remains one of the most widely used organophosphorus insecticides (OPs) despite the concerns about its developmental neurotoxicity. Developmental exposure to CPF has long-lasting negative impacts, including abnormal emotional behaviors. These negative impacts are observed at exposure levels do not cause inhibition of acetylcholinesterase, the canonical target of OPs. Exposure to CPF at these levels inhibits the endocannabinoid metabolizing enzyme fatty acid amide hydrolase (FAAH) but it is not clear what the persistent effects of this inhibition are. To investigate this, male rat pups were exposed orally to either corn oil, 0.75 mg/kg CPF, or 0.02 mg/kg PF-04457845 (PF; a specific inhibitor of FAAH) daily from postnatal day 10 (PND10) - PND16. This dosage of CPF does not inhibit brain cholinesterase activity but inhibits FAAH activity. On PND38 (adolescence), the protein expression in the amygdala was determined using a label-free shotgun proteomic approach. The analysis of control vs CPF and control vs PF led to the identification of 44 and 142 differentially regulated proteins, respectively. Gene ontology enrichment analysis revealed that most of the proteins with altered expression in both CPF and PF treatment groups were localized in the synapse-related regions, such as presynaptic membrane, postsynaptic density, and synaptic vesicle. The different biological processes affected by both treatment groups included persistent synaptic potentiation, glutamate receptor signaling, protein phosphorylation, and chemical synaptic transmission. These results also indicated disturbances in the balance between glutamatergic (↓ Glutamate AMPA receptor 2, ↓ Excitatory amino acid transporter 2, and ↑ vesicular glutamate transporter 2) and GABAergic signaling (↑ GABA transporter 3 and ↑ glutamate decarboxylase 2). This imbalance could play a role in the abnormal emotional behavior that we have previously reported. These results suggest that there is a similar pattern of expression between CPF and PF, and both these chemicals can persistently alter emotional behavior as a consequence of inhibition of FAAH.

Cannabis, mind, and mirth

In the context of the discovery of the cerebral ligand for the cannabis receptor, and the elucidation of its genetic sequence, we discuss the psychomimetic properties of Cannabis sativa, and explore the relationship between cannabis intoxication and mood. We suggest that renewed study of acute cannabis encephalopathy would be rewarding not only in deepening our understanding of consciousness in healthy adults, but also in helping us to understand the perceptual world of the child, the elderly, and some of our patients.

Cannabis and adolescent brain development

Heavy cannabis use has been frequently associated with increased rates of mental illness and cognitive impairment, particularly amongst adolescent users. However, the neurobiological processes that underlie these associations are still not well understood. In this review, we discuss the findings of studies examining the acute and chronic effects of cannabis use on the brain, with a particular focus on the impact of commencing use during adolescence. Accumulating evidence from both animal and human studies suggests that regular heavy use during this period is associated with more severe and persistent negative outcomes than use during adulthood, suggesting that the adolescent brain may be particularly vulnerable to the effects of cannabis exposure. As the endocannabinoid system plays an important role in brain development, it is plausible that prolonged use during adolescence results in a disruption in the normative neuromaturational processes that occur during this period. We identify synaptic pruning and white matter development as two processes that may be adversely impacted by cannabis exposure during adolescence. Potentially, alterations in these processes may underlie the cognitive and emotional deficits that have been associated with regular use commencing during adolescence.

Early Cannabinoid Exposure as a Source of Vulnerability to Opiate Addiction: A Model in Laboratory Rodents

Recent findings have identified an endogenous brain system mediating the actions of cannabis sativa preparations. This system includes the brain cannabinoid receptor (CB-1) and its endogenous ligands anandamide and 2-arachidonoyl-glycerol. The endogenous cannabinoid system is not only present in the adult brain, but is also active at early stages of brain development. Studies developed at our laboratory have revealed that maternal exposure to psychoactive cannabinoid results in neuro-developmental alterations. A model is proposed in which early Δ9-tetrahydrocannabinol (THC) exposure during critical developmental periods results in permanent alterations in brain function by either the stimulation of CB-1 receptors present during the development, or by the alterations in maternal glucocorticoid secretion. Those alterations will be revealed in adulthood after challenges either with drugs (i.e. opiates) or with environmental stressors (i.e. novelty). They will include a modified pattern of neuro-chemical, endocrine, and behavioral responses that might lead ultimately to inadaptation and vulnerability to opiate abuse.

Low level chlorpyrifos exposure increases anandamide accumulation in juvenile rat brain in the absence of brain cholinesterase inhibition

The prevailing dogma is that chlorpyrifos (CPF) mediates its toxicity through inhibition of cholinesterase (ChE). However, in recent years, the toxicological effects of developmental CPF exposure have been attributed to an unknown non-cholinergic mechanism of action. We hypothesize that the endocannabinoid system may be an important target because of its vital role in nervous system development. We have previously reported that repeated exposure to CPF results in greater inhibition of fatty acid amide hydrolase (FAAH), the enzyme that metabolizes the endocannabinoid anandamide (AEA), than inhibition of either forebrain ChE or monoacylglycerol lipase (MAGL), the enzyme that metabolizes the endocannabinoid 2-arachidonylglycerol (2-AG). This exposure resulted in the accumulation of 2-AG and AEA in the forebrain of juvenile rats; however, even at the lowest dosage level used (1.0mg/kg), forebrain ChE inhibition was still present. Thus, it is not clear if FAAH activity would be inhibited at dosage levels that do not inhibit ChE. To determine this, 10 day old rat pups were exposed daily for 7 days to either corn oil or 0.5mg/kg CPF by oral gavage. At 4 and 12h post-exposure on the last day of administration, the activities of serum ChE and carboxylesterase (CES) and forebrain ChE, MAGL, and FAAH were determined as well as the forebrain AEA and 2-AG levels. Significant inhibition of serum ChE and CES was present at both 4 and 12h. There was no significant inhibition of the activities of forebrain ChE or MAGL and no significant change in the amount of 2-AG at either time point. On the other hand, while no statistically significant effects were observed at 4h, FAAH activity was significantly inhibited at 12h resulting in a significant accumulation of AEA. Although it is not clear if this level of accumulation impacts brain maturation, this study demonstrates that developmental CPF exposure at a level that does not inhibit brain ChE can alter components of endocannabinoid signaling.

Behavioral alterations in cystic fibrosis mice are prevented by cannabinoid treatment in infancy

Substantial data have been accumulated regarding the molecular basis of cystic fibrosis (CF) pathogenesis, whereas the influence of biochemical impairments on brain processes has been the focus of much less attention. We have studied some behavioral parameters, such as motor activity and anxiety level, in a mice model of CF. We have assumed that functioning of the endocannabinoid system could be impaired in CF (endocannabinoids are fatty acid derivatives, and fatty acid deficiency is considered a major factor in CF etiology). We have suggested that chronic treatment with cannabinoid receptors agonist during infancy would balance cannabinoid levels and prevent CF-related behavioral alterations. Motor activity and anxiety level were studied in naïve adult CF mice (cftr-deficient mice) and compared with wild-type mice and to CF mice treated chronically with Δ9-tetrahydrocannabinol (Δ9-THC; endocannabinoid receptor agonist) during infancy (from days 7 to 28). Motor activity was tested in the tetrad, and level of anxiety in the plus maze, a month after cessation of treatment. Motor activity decrease and elevated anxiety level were found in adult naïve CF mice compared with wild-type mice. CF mice treated with THC in infancy showed normal motor activity and anxiety levels in adulthood. Motor function alteration and elevated anxiety levels in CF can result from lack of CFTR-channel in neurons and disturbed activity of various brain areas, as well as being secondary and mediated by fatty acids deficiency, altered levels of endocannabinoids and their receptors. It can be suggested that chronic treatment during infancy restores endocannabinoid function and thus prevents behavioral alterations.

Effect of developmental chlorpyrifos exposure, on endocannabinoid metabolizing enzymes, in the brain of juvenile rats

The endogenous cannabinoids 2-arachidonoylglycerol (2-AG) and arachidonoyl ethanolamide (AEA or anandamide) play vital roles during nervous system development including regulating axonal guidance and synaptogenesis. The enzymatic degradation of 2-AG and AEA is highly susceptible to inhibition by organophosphate compounds in vitro. Furthermore, acute in vivo exposure of adult animals to the agricultural insecticide chlorpyrifos (CPS) caused moderate inhibition of both 2-AG and AEA hydrolysis. However, the effects of repeated exposure to lower levels of CPS, especially during development, on endocannabinoid metabolism in the brain is not known. To examine this, rat pups were orally exposed daily from postnatal days 10-16 to either 1.0, 2.5, or 5.0 mg/kg CPS. Body weight gain was reduced by 5.0 mg/kg on all days of treatment whereas 2.5 mg/kg reduced the weight gain only on the last two days of treatment. At 4-h postexposure on day 16, forebrain cholinesterase (ChE) activity and hydrolysis of 2-AG and AEA were inhibited in a dose-related manner, and the extent of inhibition from highest to lowest level was AEA hydrolysis > ChE activity > 2-AG hydrolysis. The extent of inhibition of AEA hydrolysis was approximately twice than that of ChE activity with AEA hydrolysis being virtually eliminated by 2.5 and 5.0 mg/kg and 1.0 mg/kg causing 40% inhibition. The sensitivity of AEA hydrolysis, compared with canonical targets such as ChE activity, suggests a potential alternative developmental target for CPS. Inhibition of AEA hydrolysis could result in accumulation of endocannabinoids, which could alter normal endocannabinoid transmission during brain maturation.

Developmental consequences of perinatal cannabis exposure: behavioral and neuroendocrine effects in adult rodents

RATIONALE

Cannabis is the most commonly used illicit drug among pregnant women. Since the endocannabinoid system plays a crucial role in brain development, maternal exposure to cannabis derivatives might result in long-lasting neurobehavioral abnormalities in the exposed offspring. It is difficult to detect these effects, and their underlying neurobiological mechanisms, in clinical cohorts, because of their intrinsic methodological and interpretative issues.

OBJECTIVES

The present paper reviews relevant rodent studies examining the long-term behavioral consequences of exposure to cannabinoid compounds during pregnancy and/or lactation.

RESULTS

Maternal exposure to even low doses of cannabinoid compounds results in atypical locomotor activity, cognitive impairments, altered emotional behavior, and enhanced sensitivity to drugs of abuse in the adult rodent offspring. Some of the observed behavioral abnormalities might be related to alterations in stress hormone levels induced by maternal cannabis exposure.

CONCLUSIONS

There is increasing evidence from animal studies showing that cannabinoid drugs are neuroteratogens which induce enduring neurobehavioral abnormalities in the exposed offspring. Several preclinical findings reviewed in this paper are in line with clinical studies reporting hyperactivity, cognitive impairments and altered emotionality in humans exposed in utero to cannabis. Conversely, genetic, environmental and social factors could also influence the neurobiological effects of early cannabis exposure in humans.

Cannabis-based medicines in multiple sclerosis--a review of clinical studies

For some years a mixture of anecdotal report and data from animal models have implied a potential role for cannabis-based medicines in ameliorating a variety of symptoms of multiple sclerosis. Only recently however have large randomised controlled trials (RCTs) examined these potential effects rigorously. At present the results of RCTs have lacked a coherent message to the prescribing clinician and reasons for such heterogeneity in cannabinoid trials are discussed.

Phytocannabinoids, CNS cells and development: a dead issue?

ISSUES

Marijuana and hashish consist of at least 66 distinctive plant-derived (phyto-) cannabinoid compounds, with tetrahydrocannabinoids proving the most effective phytocannabinoid psychotropically. Despite the known pharmacological effects of phytocannabinoids, their role in controlling the cell survival/death decision in cells of the CNS continues to be unravelled.

APPROACH

In this review, we examine the influence of phytocannabinoids on neural cell fate, with particular emphasis on how the time of marijuana exposure (neonatal vs. pubertal vs. adult) might influence the neurotoxic activities of phytocannabinoid compounds.

KEY FINDINGS

Evidence in the literature indicates that exposure to phytocannabinoids during the prenatal period, in addition to the adolescent period, can alter the temporally ordered sequence of events that occur during neurotransmitter development, in addition to negatively impacting neural cell survival and maturation. Regarding the effect of marijuana consumption on brain composition in adults the evidence is contradictory.

IMPLICATIONS

Exposure to marijuana during pregnancy might impact negatively on brain structure in the first years of postnatal life. Furthermore, early-onset (before age 17) marijuana use might also have damaging effects on brain composition.

CONCLUSION

The neonatal and immature CNS is more susceptible to phytocannabinoid damage. In the adult CNS the data are conflicting and the continued development of methods to assess whether marijuana consumption results in brain atrophy or morphometric changes will determine if structural changes are occurring.

Cannabis use in pregnancy and early life and its consequences: animal models

Cannabinoid receptors and their endogenous ligands have been detected from the earliest stages of embryonic development. The endocannabinoid system appears to play essential roles in these early stages for neuronal development and cell survival, although its detailed involvement in fundamental developmental processes such as proliferation, migration and differentiation has not yet been completely understood. Therefore, it is not surprising that manipulations of the endocannabinoid system by cannabinoid exposure during early developmental stages can result in long-lasting neurobehavioural consequences. The present review will summarize the possible residual behavioural effects of cannabinoid administration during pre- and perinatal as well as early postnatal development, derived from animal studies.

Beta-endorphin and drug-induced reward and reinforcement

Although drugs of abuse have different acute mechanisms of action, their brain pathways of reward exhibit common functional effects upon both acute and chronic administration. Long known for its analgesic effect, the opioid beta-endorphin is now shown to induce euphoria, and to have rewarding and reinforcing properties. In this review, we will summarize the present neurobiological and behavioral evidences that support involvement of beta-endorphin in drug-induced reward and reinforcement. Currently, evidence supports a prominent role for beta-endorphin in the reward pathways of cocaine and alcohol. The existing information indicating the importance of beta-endorphin neurotransmission in mediating the reward pathways of nicotine and THC, is thus far circumstantial. The studies described herein employed diverse techniques, such as biochemical measurements of beta-endorphin in various brain sites and plasma, and behavioral measurements, conducted following elimination (via administration of anti-beta-endorphin antibodies or using mutant mice) or augmentation (by intracerebral administration) of beta-endorphin. We suggest that the reward pathways for different addictive drugs converge to a common pathway in which beta-endorphin is a modulating element. Beta-endorphin is involved also with distress. However, reviewing the data collected so far implies a discrete role, beyond that of a stress response, for beta-endorphin in mediating the substance of abuse reward pathway. This may occur via interacting with the mesolimbic dopaminergic system and also by its interesting effects on learning and memory. The functional meaning of beta-endorphin in the process of drug-seeking behavior is discussed.

Cannabis and the developing brain: insights from behavior

The isolation and identification, in 1964, of delta-9-tetrahydrocannabinol (THC), the primary psychoactive compound in cannabis, opened the door to a whole new field of medical research. The exploration of the therapeutic potential of THC and other natural and synthetic cannabinoid compounds was paralleled by the discovery of the endocannabinoid system, comprising cannabinoid receptors and their endogenous ligands, which offered exciting new insights into brain function. Besides its well-known involvement in specific brain functions, such as control of movement, memory and emotions, the endocannabinoid system plays an important role in fundamental developmental processes such as cell proliferation, migration and differentiation. For this reason, changes in its activity during stages of high neuronal plasticity, such as the perinatal and the adolescent period, can have long-lasting neurobehavioral consequences. Here, we summarize human and animal studies examining the behavioral and neurobiological effects of in utero and adolescent exposure to cannabis. Since cannabis preparations are widely used and abused by young people, including pregnant women, understanding how cannabinoid compounds affect the developing brain, leading to neurobehavioral alterations or neuropsychiatric disorders later in life, is a serious health issue. In addition, since the endocannabinoid system is emerging as a novel therapeutic target for the treatment of several neuropsychiatric diseases, a detailed investigation of possible adverse effects of cannabinoid compounds on the central nervous system (CNS) of immature individuals is warranted.

Bidirectional regulation of mu-opioid and CB1-cannabinoid receptor in rats self-administering heroin or WIN 55,212-2

This study examines the effect of intravenous self-administration (SA) of either heroin or the cannabinoid receptor agonist WIN 55,212-2 on levels and functionality of mu-opioid (MOR) and CB1-cannabinoid receptors (CB1R) in reward-related brain areas, such as the prefrontal cortex (PFC), nucleus accumbens (NAc), caudate putamen (CP), hippocampus (Hippo), amygdala (Amy), hypothalamus (Hypo) and ventral tegmental area (VTA). [3H]DAMGO and [3H]CP-55,940 autoradiography and agonist-stimulated [35S]GTPgammaS binding were performed on brain sections of rats firmly self-administering heroin or WIN 55,212-2. Animals failing to acquire heroin or cannabinoid SA behaviour as well as drug-naïve animals never exposed to experimental apparatus or procedure (home-control group) were used as controls. With respect to control groups, which displayed very similar values, rats SA heroin showed increased MOR binding in the NAc (+174%), CP (+165%), Hippo (+121%), VTA (+175%), an enhanced CB1R density localized in the Amy (+147%) and VTA (+37%), and a widespread increased CB1 receptor functionality in the PFC (+95%), NAc (+313%), CP (+265%), Hippo (+38%), Amy (+221%). In turn, cannabinoid SA differently modulates CB1R binding in the Amy (+47%), Hypo (+94%), Hippo (-23%), VTA (-15%), and increases MOR levels (PFC: +124%; NAc: +68%; CP: +80%; Hippo: +73%; Amy: +99%) and efficiency (Hippo: +518%; Amy: +173%; Hypo: +188%). These findings suggest that voluntary chronic intake of opioids or cannabinoids induces reciprocal but differential regulation of MORs and CB1Rs density and activity in brain structures underlying drug-taking and drug-seeking behaviour, which could represent long-term neuroadaptations contributing to the development of drug addiction and dependence.

Cannabis and neurodevelopment: implications for psychiatric disorders

The developing brain is susceptible to the effects of exogenous cannabinoids both during the perinatal period through maternal cannabis use and in young adolescent users. Emerging data from human and animal perinatal exposure studies demonstrate a subtle rather than gross effect of cannabis upon later functioning including; specific cognitive deficits especially in visuospatial function; impulsivity, inattention and hyperactivity; depressive symptoms; and substance use disorders. From animal studies motor control systems, neuroendocrine function and nociception may additionally be affected. Fetal studies indicate that these outcomes may be through cannabinoid mediated influences on the ontogeny of, especially dopamine and opioid, neurotransmitter systems. The effect of cannabinoids in the adolescent suggest long-term deleterious outcomes in cognition, depressive symptoms, schizophrenia and substance use disorders. Much of these data support a neurodevelopmental effect, however, predisposing genetic and/or environmental factors cannot be excluded from human studies. Gender specific differences have been observed in both human and animal studies implying sex hormone and related factors may interact with cannabinoids in neurodevelopment. Further understanding how cannabinoids influence neurodevelopment will inform public debate about the health effects of cannabis but also open avenues in discerning how modulation of the endocannabinoid system may assist in the development of therapeutic tools for a variety of neuropsychiatric disorders.

Effects on development

This chapter will review the effects produced on neural development by maternal consumption of cannabinoids during gestation and lactation, with emphasis in the maturation of several neurotransmitter systems (dopamine, serotonin, opioids, cannabinoids, etc.) and possible modifications in their functional expression at the behavioral or neuroendocrine levels. In addition, we have analyzed the possible existence of a sexual dimorphism in these ontogenic effects of cannabinoids, as well as the possible molecular mechanism underlying such effects. In general, the results discussed support the view that exposure to cannabinoids during critical periods of development produces marked modifications in the functional expression of diverse neuronal systems in adulthood. Furthermore, the functions of endocannabinoids in the brain are large not only in adulthood, but also in the period of prenatal and postnatal development. Thus, endocannabinoids have been reported to be present in early ages and to play a role in the process of brain development: neural proliferation and migration, axonal elongation, synaptogenesis and/or myelogenesis.

Behavioral effects in adult rats of chronic prepubertal treatment with the cannabinoid receptor agonist WIN 55,212-2

Human and animal studies provide evidence for vulnerable periods of brain development for deleterious effects of cannabinoids. We have recently shown that pubertal chronic cannabinoid treatment leads to long-lasting behavioral deficits, whereas a comparable treatment in adult rats did not affect the animals' behavior. In the present study we examined the effects of an identical chronic cannabinoid treatment in juvenile rats, just before the onset of puberty. Treatment with the synthetic cannabinoid agonist WIN 55,212-2 (WIN) (1.2 mg/kg) or vehicle was extended over 25 days throughout the prepubertal period (postnatal days 15-40) in juvenile rats. The rats received a total of 20 injections intraperitoneally. Adult rats were tested for object recognition memory, performance in a progressive ratio (PR) operant behavior task, locomotor activity and prepulse inhibition (PPI) of the acoustic startle response. Juvenile chronic WIN administration had no effect on object recognition memory, PR performance and locomotor activity in adulthood. However, a PPI deficit was observed in WIN-treated rats when tested as adults that could be reversed by the acute administration of the dopamine receptor antagonist haloperidol (0.1 mg/kg). Additionally, juvenile cannabinoid treatment reduced the number of rearings, as well as the time spent in the center of the open field in adult rats, suggesting increased anxiety. Juvenile chronic cannabinoid treatment induced behavioral disturbances in adult rats that are less severe than those observed after pubertal cannabinoid administration. However, based on the observations of sensorimotor gating deficits and increased anxiety, we conclude that the prepubertal developmental phase, in addition to puberty, also represents a vulnerable time period for persistent adverse effects of cannabinoids.

Modulation of morphine-induced Fos-immunoreactivity by the cannabinoid receptor antagonist SR 141716

A growing body of evidence suggests the existence of a functional interaction between opioid and cannabinoid systems. The present study further investigated this functional interaction by examining the combined effects of morphine and the cannabinoid receptor antagonist SR 141716 on Fos-immunoreactivity (Fos-IR), a marker for neural activation. Male albino Wistar rats were treated with SR 141716 (3 mg/kg, intraperitoneally), morphine HCl (10 mg/kg, subcutaneously), vehicle, or SR 141716 and morphine combined (n = 6 per group). Rats were injected with morphine or its vehicle 30-min after administration of SR 141716 or its vehicle and perfused 3 h later. Locomotor activity and body temperature were both increased in the morphine-treated group and SR 141716 significantly inhibited these effects. Morphine increased Fos-IR in several brain regions including the caudate-putamen (CPu), cortex (cingulate, insular and piriform), nucleus accumbens (NAS) shell, lateral septum (LS), bed nucleus of the stria terminalis (BNST), median preoptic nucleus (MnPO), medial preoptic nucleus (MPO), hypothalamus (paraventricular, dorsomedial and ventromedial), paraventricular thalamic nucleus (PV), amygdala (central and basolateral nuclei), dorsolateral periaqueductal gray, ventral tegmental area (VTA), and Edinger-Westphal nucleus. SR 141716 alone increased Fos-IR in the cortex (cingulate, insular and piriform), NAS (shell), LS, BNST, hypothalamus (paraventricular, dorsomedial and ventromedial), PV, amygdala (central, basolateral and medial nuclei), VTA, and Edinger-Westphal nucleus. SR 141716 attenuated morphine-induced Fos-IR in several regions including the CPu, cortex, NAS (shell), LS, MnPO, MPO, paraventricular and dorsomedial hypothalamus, PV, basolateral amygdala, VTA, and Edinger-Westphal nucleus (EW). These results provide further support for functional interplay between the cannabinoid and opioid systems. Possible behavioural and physiological implications of the interactive effects of SR 141716 on morphine-induced Fos-IR are discussed.

Exposure to delta-9-tetrahydrocannabinol (THC) increases subsequent heroin taking but not heroin's reinforcing efficacy: a self-administration study in rats

One concern about the widespread use of cannabis is that exposure to its active ingredient, delta-9-tetrahydrocannabinol (THC), might increase future reinforcing effects of other abused drugs such as heroin. In this study, we investigated the effects of pre-exposure to THC on subsequent intravenous self-administration of heroin by Sprague-Dawley rats. In one group of rats, we studied (1) acquisition of heroin self-administration behavior using a continuous-reinforcement (fixed-ratio (FR) 1) schedule, (2) heroin dose-response relationships using an FR1/variable-dose schedule, and (3) reinforcing efficacy of heroin using a progressive-ratio schedule. The number of rats pre-exposed to THC that subsequently learned to self-administer 50 microg/kg injections of heroin within 10 daily sessions did not differ from vehicle-pretreated controls. In contrast, rats pre-exposed to THC subsequently self-administered significantly more heroin injections per session and showed significantly shorter post-injection pauses over a range of heroin doses (12.5-100 microg/kg/injection) using the variable-dose schedule. Interestingly, the maximum effort rats would exert to receive an injection of the different doses of heroin under the progressive-ratio schedule was not altered by THC pre-exposure. In a second group of rats, we varied the 'price' of heroin (responses required/dose), by manipulating FR response requirements at different doses of heroin across sessions, to calculate demand and response output curves. Again, consumption was significantly higher in the THC-treated rats at the lowest prices of heroin (FR1/100 microg/kg and FR1/50 microg/kg) but there were no differences in the reinforcing efficacy of heroin between THC- and vehicle-pretreated rats. Altogether, these results demonstrate that pre-exposure to THC alters some pharmacological effects of heroin that determine frequency of heroin taking, but offer no support for the hypothesis that pre-exposure to THC alters heroin's efficacy as a reinforcer.

Cannabinoids and gene expression during brain development

Cannabis is the most commonly used illicit drug in western societies, in particular among young people. It is consumed even by women during pregnancy and lactation, which result in a variety of disturbances in the development of their offspring, because, like other habit-forming drugs, cannabinoids, the psychoactive ingredients of marijuana, can cross the placental barrier and be secreted in the maternal milk. Through this way, cannabinoids affect the ontogeny of various neurotransmitter systems leading to changes in different behavioral patterns. Dopamine and endogenous opioids are among the neurotransmitters that result more affected by perinatal cannabinoid exposure, which, when animals mature, produce changes in motor activity, drug-seeking behavior, nociception and other processes. These disturbances are likely originated by the capability of cannabinoids to influence the expression of key genes for both neurotransmitters, in particular, the enzyme tyrosine hydroxylase and the opioid precursor proenkephalin. In addition, cannabinoids seem to be also able to influence the expression of genes encoding for neuron-glia cell adhesion molecules, which supports a potential influence of cannabinoids on the processes of cell proliferation, neuronal migration or axonal elongation in which these proteins are involved. In support of this possibility, CB1 receptors, which represent the major targets for the action of cannabinoids, are abundantly expressed in certain brain regions, such as the subventricular areas, which have been involved in these processes during brain development. Finally, cannabinoids might also be involved in the apoptotic death that occurs during brain development, possibly by influencing the expression of Bcl-2/Bax system. Also in support of this option, CB1 receptors are transiently expressed during brain development in different group of neurons which do not contain these receptors in the adult brain. This paper will review all evidence relating cannabinoids to the expression of key genes for neural development, trying to establish the future research addressed to elucidate the mechanisms involved in the epigenetic action of cannabinoids during brain development.

Prenatal cannabinoid and gene expression for neural adhesion molecule L1 in the fetal rat brain

The consumption by women of cannabis derivatives during pregnancy and/or lactation affects the development of their offspring because like other psychoactive drugs, cannabinoids, the psychoactive ingredients of marijuana, can cross the placental barrier and be secreted into the maternal milk. Through this way, cannabinoids are able to affect the expression of key genes for neural developmental leading to neurotransmitter and behavioral disturbances. In this present study, we wanted to explore the influence of prenatal cannabinoid exposure on the gene expression of a key protein for brain development, the neural adhesion molecule L1, which plays an important role in processes of cell proliferation and migration, neuritic elongation and guidance, and synaptogenesis. To this end, pregnant rats were daily treated with delta9-tetrahydrocannabinol (delta9-THC) since the 5th day of gestation up to the day before birth (GD21), day at which rats were killed and their pups removed for analysis of L1-mRNA levels in different brain structures. Our results confirmed that the levels of L1 transcripts were significantly increased after prenatal delta9-THC exposure in several regions such as the fimbria, stria terminalis, stria medullaris and corpus callosum, which share the properties of being white matter regions and containing, exclusively during development, an abundant population of cannabinoid CB1 receptors, the major targets for the action of plant-derived cannabinoids. L1-mRNA levels were also increased in grey matter structures such as the septum nuclei and the habenula, but remained unchanged in most of the grey matter structures analyzed (cerebral cortex, basolateral amygdaloid nucleus, hippocampus, thalamic and hypothalamic nuclei, basal ganglia and subventricular zones) and also in a few white matter structures (fornix and fasciculus retroflexus). An important aspect of these observations is that the increase in L1-mRNA levels reached statistical significance only in the case of delta9-THC-exposed males but not in the case of delta9-THC-exposed females where only trends or no effects were detected, this supporting previous evidence on a sexual dimorphism, with greater effects in male fetuses, for the action of cannabinoids in the developing brain. In summary, cannabinoids seem to influence the expression of L1 in specific brain structures during the prenatal period, which, considering the role played by this protein in different events related to neural development, might explain the neurotransmitter and behavioral disturbances reported after prenatal consumption of marijuana.

Chronic treatment with CP 55,940 during the peri-adolescent period differentially affects the behavioural responses of male and female rats in adulthood

RATIONALE

Despite the increasing use of cannabis among adolescents, there is scarce information about the long-term effects of cannabinoid receptor agonists in appropriate animal models.

OBJECTIVES

We aimed to investigate the behavioural features of adult male and female Wistar rats that had been exposed to a chronic treatment with the cannabinoid receptor agonist CP 55,940 (CP) during the juvenile period.

METHODS

CP (0.4 mg/kg i.p.) or its corresponding vehicle was administered once daily, from day 35 to day 45. In adulthood, the animals were tested in the holeboard, the open field and the elevated plus-maze, under different stress (illumination) conditions. After a resting period, the serum corticosterone levels (radioimmunoassay) of the animals were measured. The effects of CP on food intake and somatic growth were monitored throughout the experimental period.

RESULTS

The CP treatment induced significant sex-dependent effects on holeboard activity, as well as a decrease in the level of emotionality/anxiety in the open field and in the plus-maze. The animals receiving CP also showed diminished food intake and body weights during the treatment period, but both parameters recovered normal values during the period after treatment. No significant effect of the CP treatment on corticosterone levels was found.

CONCLUSIONS

The results demonstrate that chronic administration of CP during the peri-adolescent period resulted in marked behavioural effects in adulthood. The nature of these effects depended on the sex of the animals and on the specific behavioural test. The possible neurobiological substrates underlying the effects of CP are discussed.

Effects of perinatal exposure to delta 9-tetrahydrocannabinol on operant morphine-reinforced behavior

The present study examined the effects of Delta(9)-tetrahydrocannabinol (Delta(9)-THC) when administered during the perinatal period on morphine self-administration in adulthood. To this end, pregnant Wistar rats were daily exposed to Delta(9)-THC from the fifth day of gestation up to pup weaning, when they were separated by gender and left to mature to be used for analyses of operant food- and morphine-reinforced behavior in a progressive ratio (PR) schedule. We also analyzed dopaminergic activity (DOPAC/DA) in reward-related structures during specific phases of the behavioral study. In both reinforcement paradigms, food and morphine, females always reached higher patterns of self-administration than males, but this occurred for the two treatment groups, Delta(9)-THC or vehicle. These higher patterns measured in females corresponded with a higher DOPAC/DA in the nucleus accumbens prior to the onset of morphine self-administration in comparison to males. Interestingly, DOPAC/DA was lower in Delta(9)-THC-exposed females compared to oil-exposed females and similar to oil- and Delta(9)-THC-exposed males. In addition, Delta(9)-THC-exposed females also exhibited a reduction in DOPAC/DA in the ventral tegmental area, which did not exist in males. All these changes, however, disappeared after 15 days of morphine self-administration and they did not reappear after 15 additional days of extinction of this response. Our data suggest that females are more vulnerable than males in a PR schedule for operant food and morphine self-administration; perinatal Delta(9)-THC exposure is not a factor influencing this vulnerability. The neurochemical analysis revealed that the activity of limbic dopaminergic neurons prior to morphine self-administration was higher in females than males, as well as that the perinatal Delta(9)-THC treatment reduced the activity of these neurons only in females, although this had no influence on morphine vulnerability in these animals.

Influence of ovarian sex steroids on spinal methionine-enkephalin release: comparison with dynorphin reveals asymmetrical regulation

The concomitant activation of spinal kappa- and delta-opioid systems is a prerequisite for the antinociception of gestation and its hormonal simulation [via 17 beta-estradiol and progesterone administration; hormone-simulated pregnancy (HSP)]. However, it is not known whether the release of kappa- and delta-opioids is also concomitantly regulated. This study investigates whether the release of methionine-enkephalin and modulation thereof is altered during HSP, as has been reported for dynorphin. K+-stimulated release of spinal methionine-enkephalin from lumbar spinal tissue obtained from control animals is negatively modulated by nociceptin (orphanin FQ; N/OFQ) in a dose-dependent manner, but not by opioids. Conversely, selective blockade of spinal N/OFQ, but not opioid receptors, augments the K+-induced increase in methionine-enkephalin release, indicating that endogenous N/OFQ also functions as a negative modulator of methionine-enkephalin release. The magnitude of K+-evoked methionine-enkephalin release from spinal tissue obtained from ovarian steroid-treated animals remains unchanged, consistent with the insensitivity of its modulation by N/OFQ to the ovarian sex steroid milieu. These characteristics of methionine-enkephalin release stand in sharp contrast to those previously reported for the evoked release of spinal dynorphin. Dynorphin release is subject to negative modulation by opioid (predominantly delta) as well as N/OFQ, both of which are offset during HSP, resulting in an approximately 2-fold increase in the magnitude of its release. These observations reveal that regulation of spinal dynorphin/kappa- and methionine-enkephalin/delta-spinal opioid antinociceptive systems is independent, divergent, and not symmetrical and support the formulation that spinal methionine-enkephalin/delta-opioid tone acts in a permissive/facilitative capacity to accentuate spinal dynorphin/kappa-activity.

Exposure to cannabinoids in the development of endogenous cannabinoid system

New data strengthen the idea of a prominent role for endocannabinoids in the modulation of a wide variety of neurobiological functions. Among these, two functions, control of movement and antinociception, have attracted the maximal interest because of the possibility that cannabinoids and related compounds might be used with a therapeutic purpose. However, the functions of endocannabinoids in the brain, and also in the periphery, are large and involve, not only the adulthood, but also the period of prenatal and postnatal development, when endocannabinoids have been reported to be significantly present and to play a role in processes of brain development as neuronal proliferation and migration, axonal elongation, synaptogenesis and/or myelinogenesis. The present review article will summarize the different studies carried out on this topic and will suggest future lines of research to clarify the role of endocannabinoids and their receptors in the development.

Changes in prodynorphin and POMC gene expression in several brain regions of rat fetuses prenatally exposed to Delta(9)-tetrahydrocannabinol

Recently, we demonstrated that prenatal Delta(9)-tetrahydrocannabinol (Delta(9)-THC) exposure alters proenkephalin mRNA levels in several brain regions of rat fetuses. In the present study, we analyzed mRNA levels of the two other opioid peptide precursors, prodynorphin and pro-opiomelanocortin (POMC), in several brain nuclei of rat fetuses which were exposed daily to Delta(9)-THC from day 5 of gestation. Prenatal Delta(9)-THC exposure altered POMC and prodynorphin mRNA levels in most of the brain areas studied at different fetal ages, but the effects were sex-dependent. Thus, POMC mRNA levels increased in Delta(9)-THC-exposed females, but decreased in Delta(9)-THC-exposed males at GD21 in the arcuate nucleus, cerebral cortex and habenular nuclei. POMC mRNA levels also increased in the arcuate nucleus and cerebral cortex of Delta(9)-THC-exposed fetuses at GD18. Prodynorphin mRNA levels were not altered by the prenatal Delta(9)-THC exposure in the striatum, cerebral cortex, hippocampus and hypothalamic structures of fetuses at GD16 and GD18, but a sexually dimorphic response was observed at GD21. Thus, prodynorphin mRNA levels increased in the cerebral cortex, hippocampus and paraventricular hypothalamic nucleus of Delta(9)-THC-exposed females, whereas no changes were observed in Delta(9)-THC-exposed males. In summary, Delta(9)-THC exposure altered the prenatal development of POMC and prodynorphin mRNA levels in several brain structures. Changes in POMC were similar to those reported previously for proenkephalin, increases in females but decreases in males, whereas changes in prodynorphin were only observed in females.

Chronic treatment with Delta(9)-tetrahydrocannabinol enhances the locomotor response to amphetamine and heroin. Implications for vulnerability to drug addiction

Cannabis sativa preparations are some of the most widely used illicit recreational drugs. In addition to their direct addictive potential, cannabinoids may influence the sensitivity to other drugs. The aim of the present study was to determine if a cross-sensitization between Delta(9)-tetrahydrocannabinol (Delta(9)-THC) and other drugs (amphetamine and heroin) could be demonstrated. We examined the effects of a chronic treatment with Delta(9)-THC (0.6, 3 and 15mg/kg, ip) on the locomotor response to amphetamine (1mg/kg, ip) and heroin (1mg/kg, ip). Chronic treatment with Delta(9)-THC resulted in tolerance to the initial hypothermic and anorexic effects. Pre-treatment with Delta(9)-THC increased the locomotor responses to amphetamine and heroin. This cross-sensitization was time-dependent as it was observed three days after the last injection of Delta(9)-THC for amphetamine, and a relatively long time after the end of chronic treatment (41 days) for heroin. Moreover, the enhanced response to amphetamine or heroin was noted in some individuals only: the high-responder rats (HR). These animals have previously been shown to be vulnerable to drug taking behaviors. It is hypothesised that repeated use of Cannabis derivates may facilitate progression to the consumption of other illicit drugs in vulnerable individuals.

Concentrations of substance P and prostaglandin E2 in synovial fluid of normal and abnormal joints of horses

OBJECTIVE

To correlate substance P content of synovial fluid with prostaglandin E2 content, radiographic evidence of joint abnormality, and anatomic location of the joint for normal and osteoarthritic joints of horses.

SAMPLE POPULATION

Synovial fluid from 46 normal joints in 21 horses and 16 osteoarthritic joints in 10 horses.

PROCEDURE

Normal and osteoarthritic joints were identified by clinical and radiographic examination, by response to nerve blocks, during scintigraphy or surgery, or by clinicopathologic evaluation. Substance P and prostaglandin E2 contents of synovial fluid were determined by radioimmunoassay. Radio-graphs of joints were assigned a numeric score reflecting severity of lesions. Joints were assigned a numeric score reflecting anatomic location.

RESULTS

Median concentrations of substance P and prostaglandin E2 were significantly increased in osteoarthritic joints, compared with normal joints. A significant correlation was found between concentrations of substance P and prostaglandin E2 in synovial fluid, but a correlation was not detected between substance P concentration in synovial fluid and anatomic location of the joint or between radiographic scores of osteoarthritic joints and concentrations of substance P or prostaglandin E2.

CONCLUSIONS AND CLINICAL RELEVANCE

A correlation existed between concentrations of substance P and prostaglandin E2 in synovial fluid obtained from normal and osteoarthritic joints. However, content of substance P in synovial fluid cannot be predicted by the radiographic appearance of the joint or its anatomic location. Substance P and prostaglandin E2 may share an important and related role in the etiopathogenesis of osteoarthritis, lending credence to the importance of neurogenic inflammation in horses.

Prenatal Delta(9)-tetrahydrocannabinol exposure modifies proenkephalin gene expression in the fetal rat brain: sex-dependent differences

Perinatal Delta(9)-tetrahydrocannabinol (Delta(9)-THC) exposure in rats resulted in enhanced morphine self-administration behavior, naloxone-precipitated withdrawal signs or changes in pain sensitivity, which have been related to changes in micro-opioid receptor binding and/or proenkephalin mRNA levels in several brain regions. However, despite exposure of these animals to Delta(9)-THC from fetal ages, the effects were studied only when animals matured, whereas there is no study on possible changes caused by this cannabinoid during the prenatal ontogeny of opioidergic neurons. The purpose of the present study was to examine the changes in proenkephalin mRNA levels, measured by using in situ hybridization, in several brain nuclei of rat fetuses that had been daily exposed to Delta(9)-THC from the 5th day of gestation. Results were as follows. Prenatal Delta(9)-THC exposure altered proenkephalin mRNA levels in most of the brain areas studied at different fetal ages, but the effects were different between sexes. Thus, proenkephalin mRNA levels increased in females, but decreased in males that had been prenatally exposed to Delta(9)-THC. This was observed in the caudate-putamen, hypothalamic paraventricular and ventromedial nuclei and cerebral cortex. No changes were observed, however, in the subventricular zones of the caudate-putamen, neocortex and nucleus accumbens. In summary, prenatal Delta(9)-THC exposure produced a sex-dependent effect in proenkephalin mRNA levels in several brain structures of rat fetuses.

Maternal exposure to the synthetic cannabinoid HU-210: effects on the endocrine and immune systems of the adult male offspring

Natural and synthetic cannabinoid receptor agonists have been described to exert profound effects on both the neuroendocrine integration and the functional responses of the immune system. In the present study, Wistar rats were exposed to the highly potent cannabinoid agonist HU-210 (1, 5 and 25 microg/kg) during gestation and lactation and the ensuing effects on several endocrine and immune parameters of the adult male offspring were analyzed. Perinatal exposure to HU-210 partially affected the distribution of lymphocyte subpopulations in the spleen and peripheral blood. The major changes observed occur after maternal exposure to the 25 microg/kg dose of HU-210. There was a reduction in the T-helper subpopulation in the spleen and a dose-related decrease in the rate of T(helper)/T(cytotoxic) in peripheral blood lymphocytes. Concanavalin-A and lipopolysaccharide-induced proliferation were normal in all the groups tested. In the same animals, perinatal exposure to HU-210 did not affect basal levels of growth hormone, IGF-1, prolactin, or follicle-stimulating hormone. Basal values of luteinizing hormone were elevated in animals given the 1 microg/kg dose of HU-210. Corticosterone levels were reduced in the animals exposed to the higher dose of HU-210 during gestation and lactation. These animals exhibited a decreased responsiveness of the hypothalamo-pituitary-adrenal (HPA) axis to the stimulation with a single injection of HU-210 (20 microg/kg, i.v.) at adult ages, which may reflect the onset of long-lasting tolerance to the HPA-activating properties of cannabinoids. The opposite pattern of response was found in the animals given the 1 microg/kg dose, in which a sensitization of the corticosterone response to acute HU-210 was observed. The present work reveals that maternal exposure to cannabinoids results in minor changes in the development of the immune system, but may induce long-lasting alterations in the functional status of the HPA axis.

Regional distribution of gonadotropin-releasing hormone-like, beta-endorphin-like, and methionine-enkephalin-like immunoreactivities in the central nervous system of the goat

Regional distribution of gonadotropin-releasing hormone (GnRH)-like-, beta-endorphin (beta-end)-like-, and methionine-enkephalin (met-enk)-like-immunoreactivity was quantified across various regions of the central nervous system (CNS) of male and female goats by using highly specific radioimmunoassays. All the animals were sacrificed during the months of March through June (non-breeding season). Although the distribution of these three neuropeptides was similar to other mammalian species, species-specific gender differences in the levels of neuropeptides were noticed in the goat CNS. Highest levels of GnRH-like immunoreactivities were found in the hypothalamus. The hypothalamus of male goats exhibited significantly higher levels of GnRH-like immunoreactivities compared to female goats. Other regions exhibiting GnRH-like immunoreactivities included olfactory bulbs, preoptic and supraoptic regions, and mamillary bodies. Both beta-end- and met-enk immunoreactivities were detected in all selected regions of goat CNS, but highest levels of these opioid peptide-like immunoreactivities were limited to the forebrain regions of the goat. The supraoptic area of the female goats contained significantly higher levels of beta-end-like immunoreactivities than that of the male goats. Met-enk-peptide-like immunoreactivity also exhibited gender-specific differences in its content in some regions of the CNS. The male goats exhibited significantly higher levels of met-enk-like immunoreactivity in both the striatal and hypothalamic regions of the brain.

The endogenous cannabinoid system and brain development

Cannabinoid receptors and their endogenous ligands constitute a novel modulatory system that is involved in specific brain functions, such as nociception, control of movement, memory and neuroendocrine regulation. Recently, it has also been suggested that this system is involved in brain development. Studies have used a variety of techniques to elucidate the effects of cannabinoids during development, as well as to characterize the presence of elements of the endogenous cannabinoid system (receptors and ligands) in the developing brain. Collectively, they suggest that endocannabinoids participate in brain development through the activation of second-messenger-coupled cannabinoid receptors.

The neurobiology of cannabinoid dependence: sex differences and potential interactions between cannabinoid and opioid systems

Cannabis is the most widely used illicit drug in many western countries. Its psychoactive ingredient, delta9-tetrahydrocannabinol (THC), produces a variety of effects in animals and humans that are probably mediated by specific cannabinoid receptors in the brain and interactions with several neurotransmitter and neuromodulator systems. For instance, recent research has revealed an important mutual functional relationship between cannabinoids and endogenous opioid systems in mediating the pharmacological and behavioral actions produced by these agents, including their reinforcing effects. Perinatal exposure to and interactions between cannabinoids and opioids might also have long-term behavioral consequences lasting into adulthood. In this work, we present preliminary evidence examining the potential effects of maternal exposure to THC on the motivational properties of morphine in male and female adult rats, as measured by an intravenous opiate self-administration paradigm.

Cannabinoids as potential new analgesics

Among other pharmacological properties analgesia is one of the important features of cannabinoids with therapeutical prospects. Cannabinoids have been shown to produce antinociception in experimental animals and humans. Recently a new system of neuromodulation based upon the existence of cannabinoid receptors and their endogenous agonists has emerged. This has been proposed as another of the endogenous pain control systems. Current evidence indicate an interaction between cannabinoid and opioid systems, the latter being of known relevance in nociception. The fact that either exogenous or endogenous opioids enhanced cannabinoid-induced antinociception suggests simultaneous activation of both opioid and cannabinoid receptors by drugs as a new analgesic strategy.

Role of endocannabinoids in brain development

In addition to those functions that have been extensively addressed in this special issue, such as nociception, motor activity, neuroendocrine regulation, immune function and others, the endogenous cannabinoid system seems to play also a role in neural development. This view is based on a three-fold evidence. A first evidence emerges from neurotoxicological studies that showed that synthetic and plant-derived cannabinoids, when administered to pregnant rats, produced a variety of changes in the maturation of several neurotransmitters and their associated-behaviors in their pups, changes that were evident at different stages of brain development. A second evidence comes from studies that demonstrated the early appearance of elements of the endogenous cannabinoid system (receptors and ligands) during the brain development. The atypical location of these elements during fetal and early postnatal periods favours the notion that this system may play a role in specific molecular events related to neural development. Finally, a third evidence derives from studies using cultures of fetal glial or neuronal cells. Cannabinoid receptors are present in some of these cultured cells and their activation produced a set of cellular effects consistent with a role of this system in the process of neural development. All this likely supports that endocannabinoids, early synthesized in nervous cells, play a role in events related to development, by acting through the activation of second messenger-coupled cannabinoid receptors.

Pharmacological and biochemical interactions between opioids and cannabinoids

Opioids and cannabinoids are among the most widely consumed drugs of abuse in humans. A number of studies have shown that both types of drugs share several pharmacological properties, including hypothermia, sedation, hypotension, inhibition of both intestinal motility and locomotor activity and, in particular, antinociception. Moreover, phenomena of cross-tolerance or mutual potentiation of some of these pharmacological effects have been reported. In recent years, these phenomena have supported the possible existence of functional links in the mechanisms of action of both types of drugs. The present review addresses the recent advances in the study of pharmacological interactions between opioids and cannabinoids, focusing on two aspects: antinociception and drug addiction. The potential biochemical mechanisms involved in these pharmacological interactions are also discussed together with possible therapeutic implications of opioid-cannabinoid interactions.

Cannabinoid receptor binding and mRNA levels in several brain regions of adult male and female rats perinatally exposed to delta9-tetrahydrocannabinol

The present study was designed to elucidate whether perinatal delta9-tetrahydrocannabinol (delta9-THC) exposure results in changes in cannabinoid receptor binding and mRNA levels in adulthood. Most of the brain areas studied, including the basal ganglia, the cerebellum, the limbic structures, and most of the hippocampal regions exhibited no changes in cannabinoid receptor binding and mRNA levels in adulthood as a consequence of the perinatal delta9-THC exposure. However, some subtle changes could be appreciated in specific regions, although their physiological relevance seems uncertain. For example, delta9-THC-exposed males exhibited a small decrease in binding in the superficial layer of the cerebral cortex, an effect that was not seen in delta9-THC-exposed females and in mRNA levels for both males and females. In the CA2 layer of the Ammon's horn, there was an increase in mRNA levels of delta9-THC-exposed animals, although this was statistically significant only in males. However, the more marked and probably relevant changes were seen in the arcuate nucleus, where delta9-THC-exposed males exhibited an increase in binding, whereas this tended to decrease in delta9-THC-exposed females. In an additional experiment, we analyzed the motor response of these animals to a challenge with SR141716, a specific antagonist for cannabinoid receptors. The delta9-THC-exposed animals tended to show a higher response to SR141716 challenge, with changes apparently more marked in delta9-THC-exposed females, although they did not reach statistical significance. In summary, perinatal cannabinoid exposure does not appear to significantly alter cannabinoid receptor binding and mRNA expression in the brain of adult rats, as well as the motor response caused by the blockade of these receptors with a specific antagonist. There were some changes in the status of cannabinoid receptors but they were very small and, hence, of debatable physiological relevance. The most significant of these effects was the increase in binding observed in the arcuate nucleus of delta9-THC-exposed males.

Perinatal delta9-tetrahydrocannabinol exposure augmented the magnitude of motor inhibition caused by GABA(B), but not GABA(A), receptor agonists in adult rats

We have extensively reported that delta9-tetrahydrocannabinol (delta9-THC) exposure results in changes in the adult functionality of dopaminergic neurons, in particular, mesotelencephalic pathways, although some changes are evident only after pharmacological challenges. In the present study, we have examined whether similar changes might be observed in gamma-aminobutyric acid (GABA) activity, in particular, in those regions where cannabinoid receptors have been reported to be located in GABA-containing neurons. To this end, we first examined GABA content and glutamic acid decarboxylase (GAD) activity in several brain regions of adult male and female rats that had been perinatally exposed to delta9-THC or oil. Delta9-THC exposure did not modify either GAD activity or GABA content in the ventral-tegmental area, nucleus accumbens, substantia nigra, caudate-putamen, and globus pallidus, thus suggesting no changes in the basal presynaptic activity of GABA-containing neurons. Second, we tested the motor response in the open-field test of these animals after a single injection of muscimol, a GABA(A) receptor agonist, baclofen, a GABA(B) receptor agonist, or vehicle. We observed that the motor inhibition caused by baclofen, in terms of decreased ambulation and stereotypy and increased inactivity, was more marked in magnitude in delta9-THC-exposed males and females. This was not observed for the GABA(A) receptor agonist, muscimol, indicating a receptor specificity. To extend this observation, we also examined whether the potential differences in the behavioral response found in the above experiment might be due to changes at the level of the efficiency of the activation of these receptors by measuring basal and baclofen-stimulated [35S]-guanylyl-5'-O-(gamma-thio)-triphosphate ([35S]-GTPgammaS) binding in adult male and female rats that had been perinatally exposed to delta9-THC or oil. However, our results were negative, because perinatal delta9-THC exposure did not increase baclofen-stimulated [35S]-GTPgammaS binding in the areas studied; in particular, in the substantia nigra, an area of interest for the interactions GABA(B) receptor/cannabinoid receptor. Collectively, the present results indicate that although perinatal delta9-THC did not produce any changes in GABA content and GAD activity in limbic and motor areas in adulthood, it did increase the behavioral response to GABA(B) receptor agonists. However, this increase was not due to changes in GABA(B) receptor activation of signal transduction mechanisms, as revealed the analysis of the percentage of stimulation by baclofen of [35S]-GTPgammaS binding in the substantia nigra and other structures of males and females perinatally exposed to delta9-THC.

Time-dependent differences of repeated administration with Delta9-tetrahydrocannabinol in proenkephalin and cannabinoid receptor gene expression and G-protein activation by mu-opioid and CB1-cannabinoid receptors in the caudate-putamen

The purpose of the present study was to examine the time-related effects of repeated administration of Delta9-tetrahydrocannabinol during 1, 3, 7 and 14 days on cannabinoid and mu-opioid receptor agonist-stimulated [35S]GTPgammaS binding, and CB1 cannabinoid receptor and proenkephalin gene expression in the caudate-putamen. Repeated administration with Delta9-tetrahydrocannabinol produced a time-related reduction in cannabinoid receptor synthesis and activation of signal transduction mechanisms in the caudate-putamen. Indeed, WIN-55,212-2-stimulated [35S]GTPgammaS binding decreased 24% on day 1 and then progressively decreased finding a 42% decrease on day 14. Similarly, CB1 cannabinoid receptor mRNA levels decreased (22%) on day 3, reaching 50% reduction on day 7. In contrast, a pronounced increase is detected in DAMGO-stimulated [35S]GTPgammaS binding and proenkephalin mRNA levels in the caudate-putamen. The highest degree of increase was reached on day 7 of the treatment (35% of proenkephalin mRNA levels and 62% of DAMGO-stimulated [35S]GTPgammaS binding) and then values slightly decreased on day 14. Taken together, the results of the present study indicate that, in the caudate-putamen, repeated administration with Delta9-tetrahydrocannabinol produces a time-related increase in proenkephalin gene expression and mu-opioid receptor activation of G-proteins, and a time-related decrease in CB1 cannabinoid receptor gene expression and reduction in CB1 cannabinoid receptor activation of G-proteins. These results also suggest a possible interaction between the cannabinoid and opioid systems in the caudate-putamen which may be potentially relevant in the understanding of the alterations of motor behavior that occur after prolonged exposure to cannabinoids.

Cannabinoid transmission and reward-related events

The reward/reinforcement circuitry of the mammalian brain consists of synaptically interconnected neurons associated with the medial forebrain bundle, linking the ventral tegmental area, nucleus accumbens, and ventral pallidum. Electrical stimulation of this circuit supports intense self-stimulation in animals and, in humans, produces intense pleasure or euphoria. This circuit is strongly implicated in the neural substrates of drug addiction and in such addiction-related phenomena as withdrawal dysphoria and craving. This circuit is also implicated in the pleasures produced by natural rewards (e.g., food, sex). Cannabinoids are euphorigenic in humans and have addictive liability in vulnerable persons, but were long considered "anomalous" drugs of abuse, lacking pharmacological interaction with these brain reward substrates. It is now clear, however, that cannabinoids activate these brain substrates and influence reward-related behaviors. From these actions, presumably, derive both the abuse potential of cannabinoids and the possible clinical efficacy in dysphoric states.

Maternal exposure to delta9-tetrahydrocannabinol facilitates morphine self-administration behavior and changes regional binding to central mu opioid receptors in adult offspring female rats

Opiates and cannabinoids are among the most widely consumed habit-forming drugs in humans. Several studies have demonstrated the existence of interactions between both kind of drugs in a variety of effects and experimental models. The present study has been focused to determine whether perinatal delta9-tetrahydrocannabinol (Delta9-THC) exposure affects the susceptibility to reinforcing effects of morphine in adulthood and whether these potential changes were accompanied by variations in mu opioid receptor binding in brain regions related to drug reinforcement. Adult female rats born from mothers that were daily treated with delta9-THC during gestation and lactation periods, exhibited a statistically significant increase in the rate of acquisition of intravenous morphine self-administration behavior when compared with females born from vehicle-exposed mothers, an effect that did not exist in delta9-THC-exposed male offspring. This increase was significantly greater on the last day of acquisition period. There were not significant differences when the subjects were lever pressing for food. In parallel, we have also examined the density of mu opioid receptors in the brain of adult male and female offspring that were exposed to Delta9-THC during the perinatal period. Collectively, perinatal exposure to delta9-THC produced changes in mu opioid receptor binding that differed regionally and that were mostly different as a function of sex. Thus, delta9-THC-exposed males exhibited a lower density for these receptors than their respective oil-exposed controls in the caudate-putamen area as well as in the amygdala (posteromedial cortical nucleus). On the contrary, delta9-THC-exposed females exhibited higher density of these receptors than their respective oil-exposed controls in the prefrontal cortex, the hippocampus (CA3 area), the amygdala (posteromedial cortical nucleus), the ventral tegmental area and the periaqueductal grey matter, whereas the binding was lower than control females only in the lateral amygdala. These results support the notion that perinatal delta9-THC exposure alters the susceptibility to morphine reinforcing effects in adult female offspring, in parallel with changes in mu opioid receptor binding in several brain regions.

Perinatal delta9-tetrahydrocannabinol exposure reduces proenkephalin gene expression in the caudate-putamen of adult female rats

Perinatal delta9-tetrahydrocannabinol (delta9-THC) exposure in rats affects several behavioral responses, such as opiate self-administration behavior or pain sensitivity, that can be directly related to changes in opioidergic neurotransmission. In addition, we have recently reported that the administration of naloxone to animals perinatally exposed to delta9-THC produced withdrawal responses, that resemble those observed in opiate-dependent rats. The purpose of the present study was to examine the basal opioid activity in the brain of adult male and female rats that had been perinatally exposed to delta9-THC. To this aim, proenkephalin mRNA levels were measured, by using in situ hybridization histochemistry, in the caudate-putamen, nucleus accumbens, central amygdala and prefrontal cingulate cortex. The results showed a marked reduction in proenkephalin mRNA levels in the caudate-putamen of delta9-THC-exposed females as compared to oil-exposed females, whereas no changes were observed between delta9-THC- and oil-exposed males. There were no differences in proenkephalin mRNA levels in the nucleus accumbens, central amygdala and prefrontal cingulate cortex between males and females perinatally exposed to delta9-THC and their respective controls, although a certain trend to decrease was observed in delta9-THC-exposed females. In summary, perinatal exposure to delta9-THC exposure decreased proenkephalin gene expression in the caudate-putamen of adult rats, although this effect exhibited a marked sexual dimorphism since it was only seen in females. This result is in agreement with a previous observation from our laboratory that females, but not males, that had been perinatally exposed to delta9-THC, self-administered more morphine in adulthood. This suggests that low levels of proenkephalin mRNA may be used as a predictor of greater vulnerability to opiates.

Localization of mRNA expression and activation of signal transduction mechanisms for cannabinoid receptor in rat brain during fetal development

In the present work, we analyzed cannabinoid receptor mRNA expression, binding and activation of signal transduction mechanisms in the fetal rat brain or in cultures of fetal neuronal or glial cells. Cannabinoid receptor binding and mRNA expression were already measurable at GD14, but they were only located in discrete regions at GD16. Among these, the hippocampus, the cerebellum and the caudate-putamen area, three regions that contain a marked signal for both binding and mRNA in the adult brain. Significant levels of binding and, in particular, of mRNA transcripts were also detected at GD16 in the cerebral cortex, midbrain and brainstem. These structures contain relatively low levels of binding and mRNA in the adult brain, suggesting that cannabinoid receptor gene is transiently expressed in atypical areas during the fetal period. The signal for cannabinoid receptor mRNA in the hippocampus, caudate-putamen and cerebral cortex progressively increased from GD16 up to GD21. At GD18 and GD21, mRNA transcripts could be measured in discrete nuclei, such as septum nuclei, ventromedial hypothalamic nucleus and others. The cerebral cortex exhibited the highest mRNA levels at GD21, although this was not accompanied by a parallel increase in binding. An important aspect is that binding measured at these ages represent binding to functional receptors because their activation by WIN-55,212-2 increased [35S]GTPgammaS binding in the same areas. This increase was reversed by a specific antagonist, SR141716. The areas where the stimulation was more marked were the midbrain and brainstem. Using cell cultures, we have observed that cannabinoid receptor mRNA is present in cortical and hippocampal neuronal cells, but not in the glial cells. However, WIN-55,212-2 was capable of stimulating [35S]GTPgammaS binding in membrane fractions obtained from cortical glial cells and this stimulation was reversed by SR141716. This was not seen with hippocampal glial cell cultures, but occurred in hippocampal and cortical neurons. In addition, the activation of these receptors with Delta9-tetrahydrocannabinol significantly reduced forskolin-stimulated cAMP production in cortical neuronal or glial cell cultures and this effect was reversed by SR141716. In summary, we have detected cannabinoid receptor binding, mRNA expression and activation of signal transduction mechanisms in the fetal rat brain (GD14-GD21), which support the view that the system constituted by these receptors and their putative endogenous ligands might play a role in specific molecular events of the brain development. Of relevance is that binding and mRNA expression appear atypically distributed in the fetal brain as compared with the adult brain, even, that their presence in white-matter-enriched areas might presumably indicate their location in non-neuronal cells. These studies with cell cultures suggest that CB1 receptor subtype is located in neuronal cells obtained from fetal brain, although preliminary evidence is provided of the existence of another receptor subtype operative in glial cells obtained from the cerebral cortex.

Autoradiographic analysis of cannabinoid receptor binding and cannabinoid agonist-stimulated [35S]GTP gamma S binding in morphine-dependent mice

The present study was designed to test the possible existence of changes in brain cannabinoid receptors in morphine-dependent mice. To this end, we compared cannabinoid receptor binding and WIN 55,212-2-stimulated [35S]guanylyl-5'-O-(gamma-thio)-triphosphate ([35S]GTP gamma S) binding in several brain regions of mice chronically exposed to morphine or saline. The existence of opiate dependence in morphine-injected mice was assessed by analyzing the well-known jumping behavior induced by the blockade of opioid receptors with naloxone, whereas these animals were unresponsive to the blockade of cannabinoid receptors with SR141716. The different structures analyzed exhibited similar cannabinoid receptor binding levels in morphine-dependent and control mice, with the only exception of the globus pallidus, which exhibited a very small, but statistically significant, increase. In addition, the activation of cannabinoid receptors with WIN 55,212-2 increased [35S]GTP gamma S binding in most of the structures examined. The increase was of similar magnitude in morphine-dependent and control mice, except in the substantia nigra, where morphine-dependent mice exhibited lesser [35S]GTP gamma S binding levels in basal conditions, although a significantly higher WIN 55,212-2-stimulated binding. Other structures, such as the central gray substance, where there was a poor agonist-induced stimulation in control mice, exhibited, however, higher levels of WIN 55,212-2-stimulated [35S]GTP gamma S binding in morphine-dependent mice, whereas these animals tended to exhibit a higher [35S]GTP gamma S binding levels in basal conditions, although a lesser and not statistically significant WIN 55,22-2-stimulated binding, in the deep layers of the cerebral cortex. Thus, the data support the potential existence of a specific effect of morphine in the coupling of cannabinoid receptors to GTP-binding proteins, rather than on receptor binding, although this was observed only in the substantia nigra and central gray substance.

Effects of halothane and methoxyflurane on regional brain and spinal cord substance P-like and beta-endorphin-like immunoreactivities in the rat

Effects of acute exposure (2 hr) to either 1.5% halothane or 0.5% methoxyflurane were investigated in the Sprague Dawley rat. Pituitary (PIT) and central nervous system (CNS) substance P (SP)-like and beta-endorphin (beta-end)-like immunoreactivities were evaluated immediately after anesthetic exposure (2 h), after righting reflex (4 h) or 24 hr postexposure (24 h). Only halothane significantly reduced SP-like immunoreactivity in olfactory bulbs in both the 2-h and 4-h groups. Halothane elevated SP-like immunoreactivity of hippocampus at all three time periods, and in the hypothalamus at 2 h. Both anesthetics significantly depleted thalamic concentrations of SP-like immunoreactivity. Methoxyflurane anesthesia resulted in a drastic decrease in SP-like immunoreactivity in PIT at all three time periods periods, while halothane elevated PIT concentrations of this peptide at 4 h. Both anesthetics significantly decreased beta-end-like immunoreactivity in the olfactory bulbs and thalami at 2, 4, and 24 h. However, halothane alone significantly elevated beta-end-like immunoreactivity in the spinal cord at 24 h. Halothane significantly elevated PIT beta-end-like immunoreactivity at 2 and 24 h, while methoxyflurane significantly lowered it in the 4-h group, but elevated the levels of the same in the 24-h group. Brain stem beta-end immunoreactivity were significantly reduced at 2 h by both anesthetics, and at 4 h by methoxyflurane. Results indicate that halothane and methoxyflurane may differ significantly in their actions on SP and beta-end secreting neurons in the CNS.

Modulation of enkephalin release by nociceptin (orphanin FQ)

Nociceptin (orphanin FQ) is an endogenous peptide agonist for the newly discovered receptor (opioid receptor-like 1 receptor, ORL1) that bears striking homology to opioid receptors. Initial reports claimed that this peptide had hypoalgesic effects following i.c.v. or i.t. administration. The present study demonstrates that, in the presence of opioid receptor blockade, nociceptin can substantially alter the magnitude of the stimulated release of methionine-enkephalin from the guinea pig myenteric plexus. This effect is concentration dependent. Low doses (1 or 10 nM) inhibit whereas higher concentrations (100 or 1000 nM) enhance evoked enkephalin release. In contrast, in the absence of opioid receptor blockade, a statistically significant inhibition of stimulated enkephalin release is observed in response to 1, 100 or 1000 nM nociceptin. However, the magnitude of this effect did not differ among these concentrations. Furthermore, at 10 nM nociceptin, either an inhibition or enhancement of stimulated enkephalin release is manifest. The ability of naloxone to alter the nociceptin modulation of enkephalin release suggests that a component of the nociceptin modulation of enkephalin release is mediated via opioid receptors. This is consistent with the observation that this peptide has modest affinity for opioid receptors (L > K > 8) which, under appropriate conditions, should be sufficient to permit interactions with multiple opioid receptor types. This complicates dose responsiveness for nociceptin since both the naloxone-resistant (ORL1-mediated) and naloxone-sensitive (opioid receptor-mediated) component exhibit a concentration-dependent bimodality (albeit in opposite directions). Determination of i.c.v. or i.t. nociceptin dose responsiveness over several orders of magnitude is suggested before concluding the physiological effects of this peptide.

Effect of maternal delta 9-tetrahydrocannabinol on developing serotonergic system

In this study we investigated the effects of maternal delta 9-tetrahydrocannabinol on the developing serotonergic system. A daily dose of delta 9-tetrahydrocannabinol (5 mg/kg body weight) was administered p.o. to pregnant rats from gestational day 5 to postnatal day 1. Levels of indolamines were measured in four brain areas of the offspring on the day before or after birth. Levels of indolamines depended on the cerebral area, sex and pre- or postnatal age. Maternal exposure to delta 9-tetrahydrocannabinol decreased diencephalic levels of 5-hydroxytryptamine (5-HT), males being more susceptible than females. These perinatal changes could be responsible for the long-term neurophysiological alterations produced by cannabinoids.