Exposure to nicotine and ethanol in adolescent mice: effects on depressive-like behavior during exposure and withdrawal

Depression and use of addictive substances are two of the most frequent public health problems of adolescents. However, little is known about the association between depression and drug use. Considering that ethanol and nicotine are the most widely used and abused drugs by adolescents, here, we evaluated the depressive-like behavior of C57BL/6 male and female mice exposed to nicotine (NIC) and/or ethanol (ETOH) from the 30th to the 45th (PN30-45) postnatal day. Four groups were analyzed: 1) concomitant NIC (50 μg/ml in 2% saccharin to drink) and ETOH (25%, 2 g/kg i.p. injected every other day) exposure; 2) NIC exposure; 3) ETOH exposure; 4) vehicle. Immobile behavior, an animal model of depressive behavior, was assessed in the forced swimming test (FST) while the anhedonic state was assessed in the sucrose preference test (SPT) by the end of exposure (PN45-47) as well as during short- (PN50-52) and long-term (PN75-77) withdrawal. In the FST, ETOH female mice showed a reduction in immobility time by the end of exposure while, during long-term withdrawal, immobility time was increased. Short-term withdrawal elicited an increase in immobility time only in female NIC mice. In the SPT, males from both NIC and NIC + ETOH groups showed increased sucrose consumption, suggesting a reward-craving effect during short-term withdrawal. During long-term withdrawal, NIC male mice showed an anhedonic effect. Adolescent nicotine, ethanol and nicotine + ethanol combined exposures during adolescence thus elicit gender-selective effects both during exposure and withdrawal that may contribute to the increased prevalence of depression among drug users.     

Increased apoptosis and reduced neuronal and glial densities in the hippocampus due to nicotine and ethanol exposure in adolescent mice

It has been recently shown that nicotine and ethanol interact during adolescence affecting memory/learning and anxiety levels. Considering the role of the hippocampus in both anxiety and memory/learning, we investigated whether adolescent nicotine and/or ethanol administration elicit apoptotic cell death and whether this results in neuronal and/or glial density alterations in the following regions of the hippocampus: granular layer of the dentate gyrus (GrDG), molecular layer (Mol), CA1, CA2 and CA3. From the 30th to the 45th postnatal day, C57BL/6 male and female mice were exposed to nicotine free base (NIC) and/or ethanol (ETOH). Four groups were analyzed: (1) concomitant NIC (50 μg/ml in 2% saccharin to drink) and ETOH (25%, 2 g/kg i.p. injected every other day) exposure; (2) NIC exposure; (3) ETOH exposure; (4) vehicle. We evaluated cell degeneration (TUNEL assay), neuronal and glial densities (optical disector) and region thicknesses at the end of the period of exposure. Our results demonstrate that ETOH elicited an increase in TUNEL-positive cells relative to the vehicle group in all hippocampal regions. NIC elicited less severe region-dependent effects: the number of TUNEL-positive cells was significantly increased in the Mol and CA1 when compared to the vehicle group. These results were paralleled by reductions in neuronal and glial cells densities, which indicate that both cell types are sensitive to the neurotoxic effects of these drugs. There were no effects on region thicknesses. On the other hand, concomitant NIC and ETOH reduced the adverse effects of the drugs when administered separately. This ability of nicotine and ethanol co-exposure to lessen the adverse effects of nicotine and ethanol may contribute to adolescents co-use and co-abuse of tobacco and alcoholic beverages.     

Impact of adolescent nicotine exposure on adenylyl cyclase-mediated cell signaling: enzyme induction, neurotransmitter-specific effects, regional selectivities, and the role of withdrawal

Recent animal studies indicate that the adolescent brain is especially vulnerable to nicotine-induced alterations in synaptic function, echoing the increased susceptibility to nicotine dependence and withdrawal noted for adolescent smokers. We administered nicotine to adolescent rats via continuous minipump infusions from PN30 to PN47.5, using 6 mg/kg/day, a dose rate that replicates the plasma nicotine levels found in smokers, and examined the effects on cell signaling mediated through adenylyl cyclase (AC) and its response to catecholamines. Studies were conducted during nicotine administration (PN45) and in the posttreatment, withdrawal period (PN50, 60, 75). Adolescent nicotine augmented AC activity as evidenced by increased responsiveness to the direct AC stimulants, forskolin and Mn(2+). The effects on AC were equally noted in brain regions enriched (striatum) or sparse (cerebellum) in cholinergic projections, implying that the effects are secondary to activation/repression of neural circuits, rather than representing direct effects on AC mediated by nicotinic cholinergic receptors. AC responses to dopaminergic and noradrenergic stimulants were also enhanced by nicotine exposure. However, in contrast to earlier work with serotonin-mediated responses, the effects on catecholaminergic stimulation were smaller and did not display the sex-dependence noted for serotonin. An alternate administration paradigm that maximizes episodic withdrawal (twice-daily nicotine injections) induced AC more rapidly at lower nicotine doses. Our results indicate that adolescent nicotine exposure elicits lasting alterations in synaptic signaling that intensify and persist during withdrawal. These findings support the concept that the adolescent brain is especially susceptible to persistent nicotine-induced alterations.     

Separate or sequential exposure to nicotine prenatally and in adulthood: persistent effects on acetylcholine systems in rat brain regions

Nicotine is a developmental neurotoxicant but the proposed "sensitization-homeostasis" model postulates that even in adulthood nicotine permanently reprograms synaptic function. We administered nicotine to rats throughout gestation or in adulthood (postnatal days PN90-107), simulating plasma levels in smokers, with evaluations on PN105, PN110, PN120, PN130 and PN180. We assessed nicotinic acetylcholine receptor (nAChR) binding, choline acetyltransferase activity, a marker for acetylcholine (ACh) terminals, and hemicholinium-3 (HC3) binding to the choline transporter, an index of ACh presynaptic activity. Prenatal nicotine exposure elicited persistent deficits in HC3 binding in male cerebral cortex and female striatum, but little change in other parameters. Nicotine given in adulthood produced profound nAChR upregulation lasting 2 weeks after discontinuing treatment. Decrements in cerebrocortical and striatal HC3 binding emerged during withdrawal and persisted through PN180, indicative of reduced ACh synaptic activity. Prenatal nicotine did not evoke any major alterations in the response to nicotine given in adulthood. The effects seen here are substantially different from those found previously for nicotine given to adolescent rats, which showed more prolonged nAChR upregulation and profound, widespread and persistent deficits in markers of ACh synaptic function; for adolescents, prenatal nicotine exposure desensitized nAChR responses, exacerbated withdrawal-induced ACh functional deficits, and worsened the long-term outcome. Our results indicate that the effects of nicotine during prenatal or adolescent stages are indeed distinct from the effects in adults, but that even adults show persistent changes after nicotine exposure, commensurate with the sensitization-homeostasis model. These effects may contribute to lifelong vulnerability to readdiction.     

Adolescent nicotine treatment changes the response of acetylcholine systems to subsequent nicotine administration in adulthood

Nicotine alters the developmental trajectory of acetylcholine (ACh) systems in the immature brain, with vulnerability extending from fetal stages through adolescence. We administered nicotine to adolescent rats (postnatal days PN30–47) and then examined the subsequent response to nicotine given in adulthood (PN90–107), simulating plasma levels in smokers, and performing evaluations during nicotine treatment (PN105) and withdrawal (PN110, PN120 and PN130), as well as assessing persistent changes at 6 months of age (PN180). We measured nicotinic acetylcholine receptor (nAChR) binding, choline acetyltransferase (ChAT) activity, a marker for ACh terminals, and hemicholinium-3 (HC3) binding to the choline transporter, an index of ACh presynaptic activity. By itself, adolescent nicotine exposure evoked sex-selective deficits in cerebrocortical HC3 binding while elevating ChAT in young adulthood in striatum and midbrain. Nicotine given in adulthood produced profound nAChR upregulation lasting 2 weeks after discontinuing treatment, and decrements in cerebrocortical and striatal HC3 binding emerged during withdrawal, indicative of reduced ACh synaptic activity. For all three parameters, adolescent nicotine altered the responses to nicotine given in adulthood, producing both sensitization and desensitization that depended on sex and brain region, effects that parallel the disparate behavioral outcomes reported for these treatments. The interaction seen here for the impact of adolescent nicotine exposure on adult nicotine responses was substantially greater than that found previously for the effects of prenatal nicotine exposure on adult responses. Our findings thus reinforce the importance of adolescence as a critical period in which the future responsiveness to nicotine is programmed.     

The benefits and drawbacks of nicotine exposure in the cortex and hippocampus of old rats

Nicotine is the main alkaloid of tobacco and possesses well-established stimulant effects. Previous reports show that nicotine at low doses improves memory functions, while high doses impair memory. This study aims to analyze the effects of nicotine (NIC) on inhibitory avoidance task and on DNA damage, reactive oxygen species (ROS) concentration, total antioxidant capacity, and lipid peroxidation in cortex and hippocampus of old rats. Male Wistar rats of 24-26 months old (620-700g) were exposed i.p. to two doses (0.3 and 1mg/kg) of NIC daily during 9 days. The treatment NIC 0.3 enhanced long-term memory (p<0.05), whereas NIC 1 improved both short and long-term memories (p<0.05). DNA damage was observed only in hippocampus (p<0.05) after NIC 1 exposure. A similar result was obtained for ROS: higher levels were detected at NIC 1 treatment in hippocampus (p<0.05). No alterations in the total antioxidant capacity were verified after NIC exposure (0.3 and 1mg/kg) in both tissues (p>0.05). Finally, evidence of oxidative damage was observed in terms of lipid peroxides levels, being higher at NIC 1 in hippocampus (p<0.05). Overall the results indicate that deleterious effects paralleled the improved short and long-term memories at the highest NIC dose, since augmented DNA damage, ROS concentration and lipid peroxides levels were registered.     

Adolescent nicotine administration changes the responses to nicotine given subsequently in adulthood: adenylyl cyclase cell signaling in brain regions during nicotine administration and withdrawal, and lasting effects

Neurodevelopmental vulnerability to nicotine extends into adolescence, the stage at which most smokers begin using tobacco. The “sensitization-homeostasis” model postulates that nicotine treatment permanently reprogrammes neural communication, so that underlying functional changes remain present despite the apparent restoration of behavioral normality. We administered nicotine to adolescent rats (postnatal days PN30–47) or adults (postnatal days PN90–107), using regimens that reproduce plasma levels in smokers, and assessed effects on the adenylyl cyclase (AC) signaling cascade, which is involved in nicotine dependence and withdrawal but also mediates numerous other neurotransmitter responses. Evaluations were made in the cerebral cortex, brainstem and cerebellum on PN105, PN110, PN120, PN130 and PN180. Adolescent nicotine exposure elicited persistent suppression of basal AC activity and eventual compromise of responses to β-adrenergic receptor stimulation, with effects emerging in late adulthood; maximal AC activity as monitored with forskolin was elevated and in general, all the effects were more notable in males. Nicotine treatment in adulthood produced an immediate increase in AC activity in males that disappeared upon withdrawal; there were late-emerging deficits similar to, but smaller in magnitude than those seen with adolescent nicotine exposure. Adolescent treatment greatly exacerbated the response to subsequent nicotine administration in adulthood, producing profound AC deficits during withdrawal that persisted through at least 6 months of age. Our results reinforce the concept that adolescence is a critical developmental period in which nicotine disrupts neural cell signaling in a lasting manner, and provide a mechanistic framework for understanding the biological substrates that determine the relationship between adolescent nicotine exposure and life-long susceptibility to nicotine addiction.     

Chronic nicotine exposure during adolescence differentially influences calcium-binding proteins in rat anterior cingulate cortex

We have recently shown that chronic amphetamine exposure selectively up-regulates parvalbumin (PV) calcium-binding proteins in the anterior cingulate cortex (ACC). In this study, we evaluated the effects of chronic nicotine (NIC) exposure on PV, calbindin D28k (CB) and calretinin (CR) calcium-binding protein immunostaining in ACC GABAergic interneurons. Chronic NIC exposure for 3 weeks in adolescent rats, either via drinking water (the oral group) or by twice daily subcutaneous injections (the injection group), resulted in the expression of high levels of CR proteins in the ACC but not in the parietal cortex. Larger increases in the density of CR-immunoreactive (ir) neurons were noted in the NIC-injected rats at 0-day withdrawal (45% increase) compared with the oral group (26% increase). The larger increases in CR-ir neuron density in the NIC-injected rats were also reflected by prominent CR-ir processes across cortical layers. The density of PV-ir neurons was also increased (37%) at 0-day withdrawal but only in the oral NIC group and no changes in CB-ir neuron density were observed in either NIC group. Combined dual-immunofluorescence and confocal microscopy revealed that somatodendritic alpha4 nicotinic acetylcholine receptors colocalized with cortical neurons stained positively for CR, PV or CB. These results suggest that CR- and/or PV-ir-containing GABA interneurons may be involved in channeling the effects of NIC in the ACC, which is closely associated with the ventral basal ganglia circuit that is linked to brain reward function.     

Persistent and delayed behavioral changes after nicotine treatment in adolescent rats

Despite the increasing use of tobacco by adolescents, few animal studies have addressed the neurobehavioral consequences of nicotine exposure during this period. We administered nicotine to adolescent rats via continuous infusion on postnatal days (PN) 30 through 47.5, using a dosage regimen that maintains plasma levels similar to those found in smokers or in users of the transdermal nicotine patch. Behavior in a novel open field and learning a passive avoidance task were assessed during nicotine treatment and for 2 weeks post-treatment. On PN44, during nicotine exposure, female rats showed decreased grooming, an effect not seen in males; this effect is opposite to the effects of nicotine in adult rats. Two weeks after cessation of nicotine administration, females showed deficits in locomotor activity and rearing, whereas males again were unaffected; the behavioral deficits appeared at the same age at which gender-selective brain cell damage emerges. In contrast, nicotine exposure enhanced passive avoidance, with the effect intensifying and persisting throughout the post-treatment period. These results reinforce the concept that developmental vulnerability to nicotine extends into adolescence, with patterns of drug effects different from those in earlier or later periods. The correlation of neurochemical with behavioral effects strengthens the connection between adolescent nicotine exposure and persistent functional changes that may influence drug habituation, learning and memory.     

Adolescent nicotine exposure alters cardiac autonomic responsiveness: beta-adrenergic and m2-muscarinic receptors and their linkage to adenylyl cyclase

Recent work indicates that adolescent smokers have an abnormally high incidence of heart rate irregularities. In the current study, adolescent rats received nicotine by continuous infusion from postnatal days (PN) 30-47.5, using a regimen designed to produce plasma levels found in smokers. We then assessed the levels of cardiac beta-adrenergic and m2-muscarinic cholinergic receptor binding, and receptor linkages to adenylyl cyclase activity, during nicotine exposure and for 1 month afterwards. In the nicotine-exposed group, m2-receptors showed a significant reduction that persisted through PN75, 1 month after the termination of treatment. beta-Receptors showed a tendency toward initial suppression and subsequent elevation. The receptor changes were accompanied by corresponding alterations in the response of adenylyl cyclase to carbachol and isoproterenol: the inhibitory muscarinic response was reduced, so that the net response to combined treatment with carbachol and isoproterenol was enhanced. There were additional changes in basal and forskolin-Mn(2+)-stimulated adenylyl cyclase activity suggestive of shifts in enzymatic catalytic properties. The effects of adolescent nicotine exposure were distinct from those seen previously with fetal nicotine treatment. In light of the worldwide increase in tobacco use by teenagers, these studies raise concern that cardiovascular function may be especially vulnerable during this critical period.     

Lasting effects of adolescent nicotine exposure on the electroencephalogram,event related potentials,and locomotor activity in the rat

Tobacco smoking initiated during adolescence is often associated with rapid onset of dependence and difficulty in maintaining abstinence. Animal models have demonstrated that adolescent nicotine exposure causes cell death and altered neurochemistry in the cortex and hippocampus; however, little is known about the neurophysiological consequences of adolescent nicotine exposure in the adult. The primary objective of this study was to assess the consequences of adolescent nicotine exposure on the adult electroencephalogram (EEG) and event-related potentials. Male Sprague-Dawley rats were administered nicotine (5.0 mg/kg per day) for 5 days between postnatal days 35 and 40 using transdermal nicotine patches. Following 6-7 weeks of nicotine withdrawal, EEG activity and event related potentials were assessed. Motor activity and sucrose preference were also examined during the nicotine withdrawal period. Additionally, a set of rats was exposed to multiple doses of nicotine for a single day to assess nicotine and cotinine blood levels. Transdermal nicotine produced nicotine (88+/-21.5 ng/ml) and cotinine (647.6+/-123.2 ng/ml) levels comparable to those previously reported. Reduced motor activity, decreased 1-4 Hz power in the cortical electroencephalogram, and increased cortical N1 amplitude were observed in nicotine-exposed rats compared to controls. These data demonstrate that transdermal nicotine patches provide an effective and non-invasive nicotine delivery system for the adolescent rat. The combined neurophysiological and locomotor activity changes observed in nicotine-exposed rats demonstrate that adolescent nicotine exposure has lasting neurobehavioral consequences. These changes may be indicative of a lasting 'nicotine abstinence syndrome' characterized by increased arousal, anxiety, or emotionality.     

Long‐term effects of chronic nicotine on emotional and cognitive behaviors and hippocampus cell morphology in mice: comparisons of adult and adolescent nicotine exposure

Nicotine dependence is associated with increased risk for emotional, cognitive and neurological impairments later in life. This study investigated the long‐term effects of nicotine exposure during adolescence and adulthood on measures of depression, anxiety, learning and hippocampal pyramidal cell morphology. Mice (C57BL/6J) received saline or nicotine for 12 days via pumps implanted on postnatal day 32 (adolescent) or 54 (adults). Thirty days after cessation of nicotine/saline, mice were tested for learning using contextual fear conditioning, depression‐like behaviors using the forced swim test or anxiety‐like behaviors with the elevated plus maze. Brains from nicotine‐ or saline‐exposed mice were processed with Golgi stain for whole neuron reconstruction in the CA1 and CA3 regions of the hippocampus. Results demonstrate higher depression‐like responses in both adolescent and adult mice when tested during acute nicotine withdrawal. Heightened depression‐like behaviors persisted when tested after 30 days of nicotine abstinence in mice exposed as adolescents, but not adults. Adult, but not adolescent, exposure to nicotine resulted in increased open‐arm time when tested after 30 days of abstinence. Nicotine exposure during adolescence caused deficits in contextual fear learning indicated by lower levels of freezing to the context as compared with controls when tested 30 days later. In addition, reduced dendritic length and complexity in the apical CA1 branches in adult mice exposed to nicotine during adolescence were found. These results demonstrate that nicotine exposure and withdrawal can have long‐term effects on emotional and cognitive functioning, particularly when nicotine exposure occurs during the critical period of adolescence.     

Lasting effects of nicotine treatment and withdrawal on serotonergic systems and cell signaling in rat brain regions: separate or sequential exposure during fetal development and adulthood

Neurodevelopmental vulnerability to nicotine extends from fetal stages through adolescence. The recently proposed "sensitization-homeostasis" model postulates that, even in adulthood, nicotine treatment permanently reprograms synaptic activity. We administered nicotine to rats throughout gestation or in adulthood (postnatal days PN90-107), using regimens that reproduce plasma levels in smokers, assessing effects on serotonin (5HT) receptors, the 5HT transporter and responses mediated through adenylyl cyclase (AC). Evaluations were then made on PN105, PN110, PN120 and PN180. Prenatal nicotine exposure elicited persistent suppression of 5HT1A receptors and upregulation of 5HT2 receptors, effects that were selective for males and that first emerged in young adulthood. In addition, AC activity was reduced and there was uncoupling of receptor-mediated responses. With nicotine exposure restricted to adulthood, there were few changes in 5HT synaptic proteins during treatment or in the first 2 weeks post-treatment, distinctly different from the robust alterations seen earlier with similar nicotine regimens given in adolescence. Nevertheless, there was long-term upregulation of the proteins in males at 6 months of age; females were unaffected. Exposure to prenatal nicotine followed by adult nicotine overcame the protection of females, so that they, too showed long-term effects not seen with either treatment alone; the effects in males were exacerbated in an additive manner. Our results indicate that the effects of nicotine during prenatal or adolescent stages are indeed distinct from the effects in adults, but that even adults show persistent changes after nicotine exposure, commensurate with the sensitization-homeostasis model. These effects may contribute to lifelong vulnerability to readdiction.     

Gestational nicotine exposure reduces nicotinic cholinergic receptor (nAChR) expression in dopaminergic brain regions of adolescent rats

Children of women who smoked during pregnancy are at increased risk of dependence when smoking is initiated during adolescence. We previously reported that gestational nicotine exposure attenuated dopamine release induced by nicotine delivered during adolescence. In this study, we determined the effects of gestational nicotine exposure on nicotinic cholinergic receptor (nAChR) expression. Timed pregnant rats received nicotine (2 mg/kg/day) or vehicle via mini-osmotic pumps during gestation. Treatments continued in pups via maternal nursing during postnatal days (PN) 2-14 (equivalent to the human in utero third trimester). On PN35, 125I-epibatidine binding to nAChR was measured. The Bmax values (fmol/mg) in prefrontal cortex (PFC), nucleus accumbens (NAcc), substantia nigra (SN) and ventral tegmental area (VTA) were reduced by 26.6% (P<0.05), 32.6% (P<0.01), 23.0% (P<0.01) and 27.6% (P<0.05), respectively. In addition, gender differences were found in vehicle-treated groups; in SN and VTA, females were 79.3% (P<0.005) and 82.9% (P=0.08) of males, respectively. The expression of nAChR subunit mRNAs was measured using real-time RT-PCR on laser-capture microdissected tissues. In adolescent VTA, gestational nicotine exposure reduced (P<0.05) nAChR subunit mRNAs encoding alpha3 (53.0%), alpha4 (23.9%), alpha5 (46.7%) and beta4 (61.4%). In NAcc core, the treatment increased alpha3 mRNA (75.8%). In addition, the number of neurons in VTA was reduced by 15.0% (P<0.001). These studies indicate that gestational exposure to nicotine induces long-lasting changes in nAChR expression that may underlie the vulnerability of adolescents to dependence on nicotine.     

Adolescent nicotine administration alters serotonin receptors and cell signaling mediated through adenylyl cyclase

Nicotine is a neuroteratogen that targets synaptic function during critical developmental stages and recent studies indicate that CNS vulnerability extends into adolescence, the age at which smoking typically commences. We administered nicotine to adolescent rats via continuous minipump infusions from PN30 to PN47.5, using 6 mg/kg/day, a dose rate that replicates the plasma nicotine levels found in smokers, and examined 5HT receptors and related cell signaling during nicotine administration (PN45) and in the post-treatment period (PN50, 60, 75). Adolescent nicotine decreased 5HT(2) receptor binding in brain regions containing 5HT projections (hippocampus and cerebral cortex), with selectivity for females in the cerebral cortex; regions containing 5HT cell bodies showed either an increase (midbrain in males) or no change (brainstem). In contrast, there were no significant changes in 5HT(1A) receptors; however, the ability of the receptors to signal through adenylyl cyclase (AC) showed a switch from stimulatory to inhibitory effects in females during the post-treatment period. There were also transient alterations in AC responses to beta-adrenergic receptor stimulation, as well as pronounced induction of the AC response to the non-receptor-mediated stimulant, forskolin. Our results indicate that adolescent nicotine exposure alters the concentrations and functions of postsynaptic 5HT receptors in a manner commensurate with impaired 5HT synaptic function. The direction of change, emergence of defects after the cessation of nicotine administration, and sex-preference for effects in females, all support a relationship of impaired 5HT function to the higher incidence of depression seen in adolescent smokers.     

Adolescent nicotine: deficits in immune function.

Maternal cigarette smoking during pregnancy is known to alter immune function in the offspring and recent studies with animals indicate that prenatal nicotine exposure leads to lasting deficiencies in T-lymphocyte mitogenic responses, likely through excessive cholinergic stimulation during a critical stage of development. The current study was conducted to determine if the vulnerable period for nicotine-induced mis-programming of immune responses extends into adolescence, the stage at which most smokers begin tobacco use. Adolescent rats were given nicotine via osmotic minipump infusions on postnatal days (PN) 30-47.5, using a regimen that produces plasma levels (25 ng/ml) of nicotine similar to those in smokers or in users of transdermal nicotine patches. Toward the end of the infusion period (PN45) and 1 month after termination of nicotine exposure (PN80), we examined the mitogenic responses of splenocytes to Concanavalin A. Although no deficiencies were seen on PN45, there were robust decreases in mitogenic responses on PN80, with deficits apparent at both suboptimal and optimal concentrations of Concanavalin A. These results indicate that the adolescent immune system is vulnerable to nicotine-induced disruption of T-cell function.     

Effects of smoking and smoking abstinence on cognition in adolescent tobacco smokers.

BACKGROUND: In adult animals and humans, nicotine can produce short-term cognitive enhancement and, in some cases, neuroprotection. Recent work in animals, however, suggests that exposure to nicotine during adolescence might be neurotoxic. We tested for evidence of acute and chronic effects of tobacco smoking on cognition in adolescents who smoked tobacco daily and were compared with adolescent nonsmokers. METHODS: Verbal working memory, verbal learning and memory, selective, divided, sustained attention, mood, symptoms of nicotine withdrawal, and tobacco craving were examined in 41 adolescent daily smokers and 32 nonsmokers who were similar in age, gender, and education. Analyses were controlled for general intelligence, reading achievement, parental educational attainment, baseline affective symptoms, and lifetime exposure to alcohol and cannabis. RESULTS: In adolescent smokers, cessation of tobacco use increased tobacco craving, symptoms of nicotine withdrawal, and depressed mood. Adolescent smokers were found to have impairments in accuracy of working memory performance irrespective of recency of smoking. Performance decrements were more severe with earlier age of onset of smoking. Adolescent smokers experienced further disruption of working memory and verbal memory during smoking cessation. As a group, male smokers initiated smoking at an earlier age than female smokers and were significantly more impaired during tests of selective and divided attention than female smokers and nonsmokers. CONCLUSIONS: Adolescent daily tobacco smokers experience acute impairments of verbal memory and working memory after smoking cessation, along with chronic decrements in cognitive performance that are consistent with preclinical evidence that neurotoxic effects of nicotine are more severe when exposure to nicotine occurs at earlier periods in development.     

Anxiety-like behavior during nicotine withdrawal predict subsequent nicotine consumption in adolescent C57BL/6 mice

We have previously demonstrated that anxiety-like behavior assessed in the elevated plus maze does not predict subsequent nicotine consumption in naïve adolescent mice. However, an association between anxiety and relapse to drug use has been suggested. In the present study, we investigated whether anxiety levels during nicotine withdrawal predict subsequent nicotine consumption in adolescent mice. C57BL/6 mice were either exposed to (−)-nicotine-free base (nicotine, 50 μg/ml) or tap water (water) from postnatal day 30 to 45 (PN30–PN45, priming period). By the end of PN48, all animals were submitted to the elevated plus maze and classified as either having high (HiAnx) or low (LoAnx) levels of anxiety. Immediately after finishing the test, all animals were returned to their home cages and were given a free choice (from PN49 to PN55, free-choice period) between two bottles, one containing a nicotine solution (10 μg/ml) and the other tap water. Nicotine consumption during the free-choice period was affected by the priming treatment (nicotine or water) in a way that was dependent on the anxiety level (HiAnx or LoAnx): the nicotine HiAnx group had lower nicotine consumption than the other groups. No differences were observed between the nicotine LoAnx, water HiAnx and water LoAnx groups. The present study provides experimental evidence for the role of anxiety on the regulation of drug consumption. Specifically, our results suggest that the anxiety-like behavior during nicotine withdrawal is associated with subsequent nicotine self-administration.     

A ten fold reduction of nicotine yield in tobacco smoke does not spare the central cholinergic system in adolescent mice

The tobacco industry has gradually decreased nicotine content in cigarette smoke but the impact of this reduction on health is still controversial. Since the central cholinergic system is the primary site of action of nicotine, here, we investigated the effects of exposure of adolescent mice to tobacco smoke containing either high or low levels of nicotine on the central cholinergic system and the effects associated with cessation of exposure. From postnatal day (PN) 30 to 45, male and female Swiss mice were exposed to tobacco smoke (whole body exposure, 8 h/day, 7 days/week) generated from 2R1F (HighNic group: 1.74 mg nicotine/cigarette) or 4A1 (LowNic group: 0.14 mg nicotine/cigarette) research cigarettes, whereas control mice were exposed to ambient air. Cholinergic biomarkers were assessed in the cerebral cortex and midbrain by the end of exposure (PN45), at short- (PN50) and long-term (PN75) deprivation. In the cortex, nicotinic cholinergic receptor upregulation was observed with either type of cigarette. In the midbrain, upregulation was detected only in HighNic mice and remained significant in females at short-term deprivation. The high-affinity choline transporter was reduced in the cortex: of HighNic mice by the end of exposure; of both HighNic and LowNic females at short-term deprivation; of LowNic mice at long-term deprivation. These decrements were separable from effects on choline acetyltransferase and acetylcholinesterase activities, suggesting cholinergic synaptic impairment. Here, we demonstrated central cholinergic alterations in an animal model of tobacco smoke exposure during adolescence. This system was sensitive even to tobacco smoke with very low nicotine content.     

Adolescent nicotine exposure produces immediate and long-term changes in CNS noradrenergic and dopaminergic function

Animal studies have only recently begun to address whether nicotine evokes unique or persistent effects on brain structure or function during adolescence, the period in which smokers typically begin their habit. In the current study, we examined the impact of adolescent nicotine treatment on catecholaminergic synaptic function in rats infused with nicotine on postnatal days 30-47.5, using a paradigm that reproduces the plasma levels of nicotine found in smokers. We assessed norepinephrine and dopamine content, turnover (an index of neural activity), and the response to an acute challenge dose of nicotine. In the midbrain, the region most closely associated with addiction, both norepinephrine and dopamine turnover were activated during the infusion period, an effect not seen in any other region for norepinephrine, and only in the striatum for dopamine. In the immediate post-infusion period (PN50-60), there was a decrement in midbrain catecholamine turnover restricted to males, whereas there was a later-emerging (PN80) activation of these pathways. Again, this pattern was not observed in any other region: the cerebral cortex showed post-treatment increases in turnover without gender selectivity, the striatum showed late-emerging deficits in dopamine turnover and the hippocampus displayed a profound deficit in noradrenergic activity that was limited to females. We also assessed the catecholaminergic response to an acute challenge with nicotine (0.3 mg/kg s.c.). The midbrain once more displayed unique properties; there was initial suppression of responses followed by post-treatment rebound elevations that were more prominent in males and eventual deficits that, in the case of dopamine, were selective for males. With the exception of the cerebellum, other regions showed the initial loss of response during the infusion period but no persistent changes in responsiveness. The current results indicate that adolescent nicotine produces immediate and long-term changes in CNS catecholaminergic systems, with regional targeting and gender selectivity corresponding to the changes seen previously in nicotinic receptor upregulation or indices of cell damage. These effects may underlie long-term behavioral changes associated with adolescent nicotine exposure.