α4ß2 nicotinic acetylcholine receptors on dopaminergic neurons mediate nicotine reward and anxiety relief.

Nicotine is the primary psychoactive substance in tobacco, and it exerts its effects by interaction with various subtypes of nicotinic acetylcholine receptors (nAChRs) in the brain. One of the major subtypes expressed in brain, the α4ß2-nAChR, endogenously modulates neuronal excitability and thereby, modifies certain normal as well as nicotine-induced behaviors. Although α4-containing nAChRs are widely expressed across the brain, a major focus has been on their roles within midbrain dopaminergic regions involved in drug addiction, mental illness, and movement control in humans. We developed a unique model system to examine the role of α4-nAChRs within dopaminergic neurons by a targeted genetic deletion of the α4 subunit from dopaminergic neurons in mice. The loss α4 mRNA and α4ß2-nAChRs from dopaminergic neurons was confirmed, as well as selective loss of α4ß2-nAChR function from dopaminergic but not GABAergic neurons. Two behaviors central to nicotine dependence, reward and anxiety relief, were examined. α4-nAChRs specifically on dopaminergic neurons were demonstrated to be necessary for nicotine reward as measured by nicotine place preference, but not for another drug of addiction, cocaine. α4-nAChRs are necessary for the anxiolytic effects of nicotine in the elevated plus maze, and elimination of α4ß2-nAChRs specifically from dopaminergic neurons decreased sensitivity to the anxiolytic effects of nicotine. Deletion of α4-nAChRs specifically from dopaminergic neurons also increased sensitivity to nicotine-induced locomotor depression; however, nicotine-induced hypothermia was unaffected. This is the first work to develop a dopaminergic specific deletion of a nAChR subunit and examine resulting changes in nicotine-related behaviors.

Decreased anxiety-like behavior in beta3 nicotinic receptor subunit knockout mice.

Nicotine, via a family of nicotinic acetylcholine receptors, elicits many physiological responses, including alterations in anxiety. Studies suggest that the effects of nicotine on anxiety may support smoking behaviors. We reported previously that mice lacking the beta3 nicotinic receptor subunit demonstrate increased activity in the open field arena. Open field activity has been shown to be a composite of anxiety and locomotor activity, behaviors that are both altered by nicotine. We therefore sought to differentiate the role(s) of beta3-containing receptors in anxiety and locomotor activity. Anxiety behaviors were examined in the elevated plus maze, the black/white box and the mirrored chamber. Beta3 null mutant mice demonstrated decreased anxiety with more time spent on the open arm of the elevated plus maze than their wildtype littermates. No significant differences were observed with the black/white box or the mirrored chamber. Levels of the stress hormone, corticosterone, were significantly higher in the beta3 null mutant mice at baseline and following exposure to stress. Increased locomotor activity in the Y-maze was also observed for the beta3 null mutant mice, but only following exposure to stress. These findings strongly suggest that beta3-containing nicotinic receptors influence anxiety and may be critical for the continuation of smoking behaviors.

Exocytic trafficking is required for nicotine-induced up-regulation of alpha 4 beta 2 nicotinic acetylcholine receptors.

The primary target for nicotine in the brain is the neuronal nicotinic acetylcholine receptor (nAChR). It has been well documented that nAChRs respond to chronic nicotine exposure by up-regulation of receptor numbers, which may underlie some aspects of nicotine addiction. In order to investigate the mechanism of nicotine-induced nAChR up-regulation, we have developed a cell culture system to assess membrane trafficking and nicotine-induced up-regulation of surface-expressed alpha(4)beta(2) nAChRs. Previous reports have implicated stabilization of the nAChRs at the plasma membrane as the potential mechanism of up-regulation. We have found that whereas nicotine exposure results in up-regulation of surface receptors in our system, it does not alter surface receptor internalization from the plasma membrane, postendocytic trafficking, or lysosomal degradation. Instead, we find that transport of nAChRs through the secretory pathway to the plasma membrane is required for nicotine-induced up-regulation of surface receptors. Therefore, nicotine appears to regulate surface receptor levels at a step prior to initial insertion in the plasma membrane rather than by altering their endocytic trafficking or degradation rates as had been previously suggested.

Role of neuronal nicotinic receptors in the effects of nicotine and ethanol on contextual fear conditioning.

Nicotine can enhance contextual learning while ethanol impairs some forms of learning. Nicotine can overcome some of the impairing effects of ethanol when the two drugs are co-administered. The specific brain nicotinic acetylcholine receptors (nAChRs) that mediate nicotine's effects on contextual learning and whether any of ethanol's actions are mediated by nAChRs are unknown. The potential roles of nAChRs in contextual and cued fear conditioning as well as the effects of nicotine, ethanol, or co-administration of nicotine and ethanol were examined in wild type and homozygous null mutant mice from alpha7, beta2, beta3, and beta4 mouse lines at 24 h after training. Nicotine was given prior to training and testing, whereas ethanol was given only before training. Nicotine enhanced contextual learning in both alpha7 wild types and mutants when mice were trained at 0.17 mA, but not 0.35 mA. Mutants lacking the alpha7 subunit were less sensitive to the memory impairing effects of ethanol trained at 0.35 mA. beta2 Null mutants receiving saline showed a small, but significant, impairment in contextual learning compared with wild type littermates when the shock stimulus was 0.35 mA. Beta2 Null mutant mice also did not respond to the cognitive enhancing effects of nicotine alone, or after ethanol administration. beta3 and beta4 null mutants did not differ from wild types either after saline or any of drug treatments. These results show that beta2-containing nAChRs, but not beta3- or beta4-containing receptors, mediate the enhancing effects of nicotine on contextual learning and confirm previous studies implicating beta2 in other forms of learning. A new role for alpha7 nAChRs in regulating sensitivity to the cognitive disrupting effects of ethanol is proposed.

The beta3 nicotinic receptor subunit: a component of alpha-conotoxin MII-binding nicotinic acetylcholine receptors that modulate dopamine release and related behaviors.

Nigrostriatal dopaminergic neurons express many nicotinic acetylcholine receptor (nAChR) subunits capable of forming multiple nAChR subtypes. These subtypes are expressed differentially along the neuron and presumably mediate diverse responses. beta3 subunit mRNA has restricted expression but is abundant in the substantia nigra and ventral tegmental areas. To investigate the potential role(s) of nicotinic receptors containing the beta3 subunit in dopaminergic tracts, we generated mice with a null mutation in the beta3 gene. We were thereby able to identify a population of beta3-dependent alpha-conotoxin MII-binding nAChRs that modulate striatal dopamine release. Changes were also observed in locomotor activity and prepulse inhibition of acoustic startle, behaviors that are controlled, in part, by nigrostriatal and mesolimbic dopaminergic activity, respectively, suggesting that beta3-containing nAChRs modulate these behaviors.

Calcium modulation of activation and desensitization of nicotinic receptors from mouse brain.

The effects of extracellular calcium on functional properties of nicotinic receptors from mouse thalamus were investigated. Previous studies have reported that calcium modulates the function of several neuronal nicotinic receptors. A 86Rb+ ion efflux assay was developed to measure nicotinic receptor function from brain tissue, and data indicate that alpha4beta2 receptors may mediate this response. Using the 86Rb+ efflux assay, calcium effects on receptor activation, desensitization induced by high, activating and low, subactivating concentrations of agonist, and recovery from desensitization were examined. Effects of calcium on the kinetics of ligand binding were also investigated. Calcium modulated receptor activation by increasing the maximal response to nicotine in a concentration-dependent manner, without affecting the EC50 of nicotine. Barium, but not magnesium, mimicked the effects of calcium on receptor activation. The increase in receptor activation could not be explained by changes in the ratio of activatable to desensitized receptors as assessed by the kinetics of ligand binding. Desensitization following activation was unaffected by calcium. Calcium, barium, and magnesium, however, increased the potency of nicotine for desensitization induced by exposure to low, subactivating concentrations of nicotine. Recovery from desensitization was not modulated by calcium. These data suggest that calcium modulates various functional aspects of nicotinic receptors from mouse brain and may do so via different mechanisms.

Long-term ethanol treatment elicits changes in nicotinic receptor binding in only a few brain regions.

Chronic nicotine treatment will produce an upregulation of brain nicotinic receptors, and rats treated for 5 months with ethanol had increased [3H]nicotine binding in two of the three brain regions that were studied. However, studies using short-term treatment did not detect an effect of ethanol on mouse brain nicotinic receptor numbers. Therefore, LS and SS mice were force-fed ethanol (15%, v/v) in the drinking water for 6 months. The LS mice developed tolerance to ethanol as measured by Y-maze crossing and rearing activity, body temperature, and sleep time. No evidence for tolerance to ethanol was seen in the SS mice. However, the SS mice showed increases in [3H] nicotine binding in thalamus and an increase in [125I]alpha-bungarotoxin binding in the cerebellum and superior colliculus. LS mice had reduced levels of hippocampal [125I]alpha-bungarotoxin binding. Thus, long-term ethanol treatment may affect brain nicotinic receptor binding but the effect is limited to only a few brain regions and may be influenced by genetic factors.

Bioavailability of ethanol is reduced in several commonly used liquid diets.

Liquid diets are often used as a vehicle for chronically treating laboratory animals with ethanol. However, a recent report suggested that one or more components of these diets may bind ethanol which could result in a decrease in the bioavailability of ethanol. Consequently, we compared the blood ethanol concentration vs. time curves obtained following the intragastric (i.g.) administration of ethanol dissolved in water or in one of three liquid diets (Bioserv AIN-76, Sustacal, or Carnation Slender) using the long-sleep (LS) and short-sleep (SS) mouse lines. The initial rates of absorption were generally the same for the water-ethanol and diet-ethanol groups, but the diets generally produced lower peak levels and the areas under the ethanol concentration-time curves were less for all of the liquid diets than for the control, ethanol-water solution. In vitro dialysis experiments indicated that the Bioserv diet binds ethanol in a saturable manner. Therefore, it may be that the slower release of ethanol, which should occur as a result of binding, serves to increase the role of first pass metabolism in regulating ethanol concentrations following oral administration. Because the effects of the diets were seen even after pyrazole treatment, it may be that the lower blood ethanol levels arise because metabolism by gastric ADH, rather than hepatic ADH, is responsible for a major portion of ethanol metabolism as ethanol is slowly released by the diets. If so, the observation that the diet/water differences were uniformly greater in the LS mice may indicate that LS-SS differences in gastric ADH exist.(ABSTRACT TRUNCATED AT 250 WORDS)