Sarah E. McCallum

Guidelines on nicotine dose selection for in vivo research

RationaleThis review provides insight for the judicious selection of nicotine dose ranges and routes of administration for in vivo studies. The literature is replete with reports in which a dosaging regimen chosen for a specific nicotine-mediated response was suboptimal for the species used. In many cases, such discrepancies could be attributed to the complex variables comprising species-specific in vivo responses to acute or chronic nicotine exposure.ObjectivesThis review capitalizes on the authors’ collective decades of in vivo nicotine experimentation to clarify the issues and to identify the variables to be considered in choosing a dosaging regimen. Nicotine dose ranges tolerated by humans and their animal models provide guidelines for experiments intended to extrapolate to human tobacco exposure through cigarette smoking or nicotine replacement therapies. Just as important are the nicotine dosaging regimens used to provide a mechanistic framework for acquisition of drug-taking behavior, dependence, tolerance, or withdrawal in animal models.ResultsSeven species are addressed: humans, nonhuman primates, rats, mice, Drosophila, Caenorhabditis elegans, and zebrafish. After an overview on nicotine metabolism, each section focuses on an individual species, addressing issues related to genetic background, age, acute vs chronic exposure, route of administration, and behavioral responses.ConclusionsThe selected examples of successful dosaging ranges are provided, while emphasizing the necessity of empirically determined dose–response relationships based on the precise parameters and conditions inherent to a specific hypothesis. This review provides a new, experimentally based compilation of species-specific dose selection for studies on the in vivo effects of nicotine.

Chronic Oral Nicotine Normalizes Dopaminergic Function and Synaptic Plasticity in 1-Methyl-4-Phenyl-1,2,3,6-Tetrahydropyridine-Lesioned Primates

Our recent studies show that chronic oral nicotine partially protects against striatal damage in 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP)-treated nonhuman primates. To identify the cellular changes associated with this protective action, we investigated the effects of nicotine treatment on stimulus-evoked dopamine release, dopamine turnover, and synaptic plasticity in striatum from lesioned and unlesioned animals. Monkeys were chronically (6 months) treated with nicotine in the drinking water and subsequently lesioned with the dopaminergic neurotoxin MPTP (6 months) while nicotine was continued. Nigrostriatal damage increased nicotinic acetylcholine receptor (nAChR)-mediated fractional dopamine release from residual terminals, primarily through changes in α3*/α6* nAChRs. In contrast, fractional receptor-evoked dopamine release was similar to control in unlesioned and lesioned animals with chronic oral nicotine. Long-term nicotine administration also attenuated the enhanced K+-evoked fractional dopamine release from synaptosomes of MPTP-lesioned animals, suggesting that nicotine treatment had a generalized effect on dopaminergic function. This premise was further supported by experiments showing that nicotine dosing decreased the elevated dopamine turnover that occurs after nigrostriatal damage. We next investigated changes in synaptic plasticity with lesioning and nicotine treatment. Nicotine treatment alone enhanced synaptic plasticity by lowering the threshold for long-term depression (LTD) in the corticostriatal pathway. MPTP lesioning led to a loss of LTD, a measure of short-term synaptic plasticity. In contrast, LTD was preserved in nicotine-treated lesioned animals. Thus, the present data show that the disruptions in striatal dopaminergic function after nigrostriatal damage were attenuated with chronic nicotine administration. These cellular alterations may underlie the ability of nicotine to maintain/restore normal function with nigrostriatal damage.

Null mutant analysis of responses to nicotine: Deletion of β2 nicotinic acetylcholine receptor subunit but not α7 subunit reduces sensitivity to nicotine-induced locomotor depression and hypothermia

The nicotinic acetylcholine receptor (nAChR) subtypes alpha4beta2 and alpha7 comprise the majority of brain nicotine-binding sites. Classical genetic strategies using inbred mice and their hybrids suggest that nicotines effects on locomotor activity and body temperature are influenced by alpha4beta2 but not alpha7 receptors. To evaluate directly the role of these nicotinic subtypes on responses to nicotine, beta2 and alpha7 null mutant (-/-) mice, as well as wild-type (+/+) and heterozygous (+/-) mice, were tested for baseline body temperature and locomotion and nicotine (0-1.5 mg/kg)-induced changes in these responses. Basal responses for these measures were similar for all beta2 genotypes, but baseline Y-maze activity was higher in alpha7-/- mice compared with alpha7+/+ mice. Following nicotine injection, dose-dependent decreases in body temperature and locomotor activity were observed for all three genotypes of both beta2 and alpha7 mice. Although responses in alpha7 mice did not differ among genotypes, beta2 gene deletion was found to have a gene-dependent effect on nicotines effects. beta2-/- mice were less sensitive to nicotine-induced locomotor depression and hypothermia at low nicotine doses (.25-.5 mg/kg) but were no different from beta2+/+ mice at the highest doses tested (1.0-1.5 mg/kg). Residual responses at high nicotine doses in beta2-/- mice as well as responses in all alpha7 and beta2 mouse genotypes were mediated by nicotinic receptors, since mecamylamine (1.0 mg/kg) blocked all responses following 1.0 mg/kg nicotine. This finding suggests receptors that include the beta2 nAChR subunit partially mediate nicotines effects on locomotor activity and body temperature.

Differential Regulation of Mesolimbic α3/α6β2 and α4β2 Nicotinic Acetylcholine Receptor Sites and Function after Long-Term Oral Nicotine to Monkeys

Because the mesolimbic dopamine system plays a critical role in nicotine addiction/reinforcement and because nicotinic receptors regulate dopamine release, we initiated a study to evaluate the long-term effects of nicotine (>6 months at the final dose) on nicotinic acetylcholine receptor (nAChR) sites and function in the nucleus accumbens of nonhuman primates. Nicotine was given in the drinking water as this mode of administration is long-term but intermittent, thus resembling smoking in this aspect. We determined the effects of nicotine treatment on function and binding of the α3/α6β2* and α4β2* nAChRs subtypes in nucleus accumbens, a region directly implicated in the addictive effects of nicotine. To evaluate function, we measured nicotine and K+-evoked [3H]dopamine release from nucleus accumbens synaptosomes. Changes in α4β2* and α3/α6β2* nAChRs were measured using 125I-epibatidine, [125I]A85380 [5-[125I]iodo-3(2(S)-azetidinylmethoxy) pyridine] and 125I-α-conotoxin MII autoradiography. Chronic nicotine treatment, which led to plasma nicotine levels in the range of smokers, significantly increased nucleus accumbens α4β2* nAChR sites and function compared with control. By contrast, this treatment did not significantly change α3/α6β2* nAChR sites or evoked dopamine release in this region compared with control. Thus, these data are distinct from previous results in striatum in which the same nicotine treatment paradigm decreased striatal α3/α6β2* nAChR sites and function. The finding that long-term nicotine treatment selectively modulates α4β2* and not α3/α6β2* nAChR expression in primate nucleus accumbens is consistent with the results of studies in nicotinic receptor mutant mice implicating the α4β2* nAChR subtype in nicotine-mediated addiction.

Increases in α4* but not α3*/α6* nicotinic receptor sites and function in the primate striatum following chronic oral nicotine treatment

Knowledge of the effects of chronic nicotine is critical considering its widespread use in tobacco products and smoking cessation therapies. Although nicotine is well known to up‐regulate α4* nAChR sites and function in the cortex, its actions in the striatum are uncertain because of the presence of multiple subtypes with potentially opposing effects. We therefore investigated the effect of long‐term nicotine treatment on nAChR sites and function in the primate striatum, which offers the advantage of similar proportions of α3*/α6* and α4* nAChRs. Nicotine was given in drinking water, which resembles smoking in its intermittent but chronic delivery. Plasma nicotine and cotinine levels were similar to smokers. Chronic nicotine treatment (> 6 months) enhanced α4* nAChR‐evoked [3H]dopamine release in striatal subregions, with an overall pattern of increase throughout the striatum when normalized to uptake. This increase correlated with elevated striatal α4* nAChRs. Under the same conditions, striatal α3*/α6* nAChR sites and function were decreased or unchanged. These divergent actions of chronic nicotine treatment on α4* versus α6* nAChRs, as well as effects on dopamine uptake, allow for a complex control of striatal activity to maintain dopaminergic function. Such knowledge is important for understanding nicotine dependence and the consequences of nicotine administration for the treatment of neurological disorders.

Brain regions mediating α3β4 nicotinic antagonist effects of 18-MC on nicotine self-administration.

18-Methoxycoronaridine (18-MC), a putative anti-addictive agent, has been shown to decrease the self-administration of several drugs of abuse in rats. 18-MC is a potent antagonist at α3β4 nicotinic receptors. Consistent with high densities of α3β4 nicotinic receptors being located in the medial habenula and the interpeduncular nucleus, 18-MC has been shown to act in these regions to decrease both morphine and methamphetamine self-administration. The present study was conducted to determine if 18-MCs effect on nicotine self-administration is mediated by acting in these same brain regions. Because moderate densities of α3β4 receptors occur in the dorsolateral tegmentum, ventral tegmental area, and basolateral amygdala, these brain areas were also examined as potential sites of action of 18-MC. Local administration of 18-MC into either the medial habenula, the basolateral amygdala or the dorsolateral tegmentum decreased nicotine self-administration. Surprisingly, local administration of 18-MC into the interpeduncular nucleus increased nicotine self-administration while local administration of 18-MC into the ventral tegmental area had no effect on nicotine self-administration. Similar effects were produced by local administration of either mecamylamine or conotoxin AuIB. These data are consistent with the hypothesis that 18-MC decreases nicotine self-administration by indirectly modulating the dopaminergic mesolimbic pathway via blockade of α3β4 nicotinic receptors in the medial habenula, basolateral amygdala, and dorsolateral tegmentum. The data also suggest that an action of 18-MC in the interpeduncular nucleus may attenuate aversive and/or depressive effects of nicotine.

Compensation in pre-synaptic dopaminergic function following nigrostriatal damage in primates

Clinical symptoms of Parkinsons disease only become evident after 70–80% reductions in striatal dopamine. To investigate the importance of pre‐synaptic dopaminergic mechanisms in this compensation, we determined the effect of nigrostriatal damage on dopaminergic markers and function in primates. MPTP treatment resulted in a graded dopamine loss with moderate to severe declines in ventromedial striatum (approximately 60–95%) and the greatest reductions (approximately 95–99%) in dorsolateral striatum. A somewhat less severe pattern of loss was observed for striatal nicotinic receptor, tyrosine hydroxylase and vesicular monoamine transporter expression. Declines in striatal dopamine uptake and transporter sites were also less severe than the reduction in dopamine levels, with enhanced dopamine turnover in the dorsolateral striatum after lesioning. The greatest degree of adaptation occurred for nicotine‐evoked [3H]dopamine release from striatal synaptosomes, which was relatively intact in ventromedial striatum after lesioning, despite > 50% declines in dopamine. This maintenance of evoked release was not due to compensatory alterations in nicotinic receptor characteristics. Rather, there appeared to be a generalized preservation of release processes in ventromedial striatum, with K+‐evoked release also near control levels after lesioning. These combined compensatory mechanisms help explain the finding that Parkinsons disease symptomatology develops only with major losses of striatal dopamine.

Inhibition of the mammalian target of rapamycin pathway by rapamycin blocks cocaine-induced locomotor sensitization.

Repeated cocaine exposure induces locomotor sensitization, which is mediated by adaptive changes in synaptic transmission in the mesolimbic dopamine pathway. The molecular mechanisms underlying this adaptation remain poorly understood. One pathway that may play a role is the mammalian target of rapamycin (mTOR) which is implicated in synaptic plasticity. In the present study, we found that cocaine exposure stimulates mTOR activity in rat brain. Furthermore, inhibition of mTOR by rapamycin blocked the induction as well as the expression of cocaine-induced locomotor sensitization in rats. These data elucidate a novel mechanism by which the mTOR pathway mediates cocaine-induced behavioral changes and could suggest a new interventional strategy for drug abuse.

18-Methoxycoronaridine blocks acquisition but enhances reinstatement of a cocaine place preference.

The iboga alkaloid congener, 18-methoxycoronaridine (18-MC), decreases self-administration of multiple drugs of abuse. Here, in a biased procedure, we investigated whether 18-MC would have a similar effect on the acquisition, expression and reinstatement of a cocaine conditioned place preference (CPP) in male Sprague-Dawley rats. While 18-MC attenuated acquisition of a cocaine CPP, it had no effect on CPP expression, and enhanced the reinstatement of cocaine CPP following extinction. Our results are consistent with those obtained using ibogaine, but reinforce the notion that acquisition, expression and reinstatement of a CPP likely involve separate mechanisms.

Impact of Nicotine Metabolism on Nicotine's Pharmacological Effects and Behavioral Responses: Insights from a Cyp2a(4/5)bgs-null Mouse

Nicotine metabolism is believed to affect not only nicotine’s pharmacological effects but also nicotine addiction. As a key step toward testing this hypothesis, we have studied nicotine metabolism and nicotine’s pharmacological and behavioral effects in a novel knockout mouse model [named Cyp2a(4/5)bgs-null] lacking a number of cytochrome P450 genes known to be or possibly involved in nicotine metabolism, including two Cyp2a and all Cyp2b genes. We found that, compared with wild-type mice, the Cyp2a(4/5)bgs-null mice showed >90% decreases in hepatic microsomal nicotine oxidase activity in vitro, and in rates of systemic nicotine clearance in vivo. Further comparisons of nicotine metabolism between Cyp2a(4/5)bgs-null and Cyp2a5-null mice revealed significant roles of both CYP2A5 and CYP2B enzymes in nicotine clearance. Compared with the behavioral responses in wild-type mice, the decreases in nicotine metabolism in the Cyp2a(4/5)bgs-null mice led to prolonged nicotine-induced acute pharmacological effects, in that null mice showed enhanced nicotine hypothermia and antinociception. Furthermore, we found that the Cyp2a(4/5)bgs-null mice developed a preference for nicotine in a conditioned place preference test, a commonly used test of nicotine’s rewarding effects, at a nicotine dose that was 4-fold lower than what was required by wild-type mice. Thus, CYP2A/2B-catalyzed nicotine clearance affects nicotine’s behavioral response as well as its acute pharmacological effects in mice. This result provides direct experimental support of the findings of pharmacogenetic studies that suggest linkage between rates of nicotine metabolism and smoking behavior in humans.