Sex differences in cognitive performance and alcohol consumption in High Alcohol-Drinking (HAD-1) rats.

Excessive alcohol (ethanol) consumption negatively impacts social, emotional, as well as cognitive function and well-being. Thus, identifying behavioral and/or biological predictors of excessive ethanol consumption is important for developing prevention and treatment strategies against alcohol use disorders (AUDs). Sex differences in alcohol consumption patterns are observed in humans, primates, and rodents. Selectively bred high alcohol-drinking rat lines, such as the "HAD-1" lines are recognized animal models of alcoholism. The present work examined sex differences in alcohol consumption, object recognition, and exploratory behavior in male and female HAD-1 rats. Naïve male and female HAD-1 rats were tested in an object recognition test (ORT) prior to a chronic 24 h intermittent ethanol access procedure for five weeks. Object recognition parameters measured included exploratory behavior, object investigation, and time spent near objects. During the initial training trial, rearing, active object investigation and amount of time spent in the object-containing section was significantly greater in female HAD-1 rats compared to their male counterparts. During the subsequent testing trial, time spent in the object-containing section was greater in female, compared to male, rats; but active object investigation and rearing did not statistically differ between females and males. In addition, female HAD-1 rats consumed significantly more ethanol than their male counterparts, replicating previous findings. Moreover, across all animals there was a significant positive correlation between exploratory behavior in ORT and ethanol consumption level. These results indicate there are significant sex differences in cognitive performance and alcohol consumption in HAD-1 rats, which suggests neurobiological differences as well.

Sex-specific ultrasonic vocalization patterns and alcohol consumption in high alcohol-drinking (HAD-1) rats.

Ultrasonic vocalizations (USVs) have been established as an animal model of emotional status and are often utilized in drug abuse studies as motivational and emotional indices. Further USV functionality has been demonstrated in our recent work showing accurate identification of selectively-bred high versus low alcohol-consuming male rats ascertained exclusively from 22 to 28kHz and 50-55kHz FM USV acoustic parameters. With the hypothesis that alcohol-sensitive sex differences could be revealed through USV acoustic parameters, the present study examined USVs and alcohol consumption in male and female selectively bred high-alcohol drinking (HAD-1) rats. For the current study, we examined USV data collected during a 12-week experiment in male and female HAD-1 rats. Experimental phases included Baseline (2weeks), 4-h EtOH Access (4weeks), 24-h EtOH Access (4weeks) and Abstinence (2weeks). Findings showed that both male and female HAD-1 rats spontaneously emitted a large number of 22-28kHz and 50-55kHz FM USVs and that females drank significantly more alcohol compared to males over the entire course of the experiment. Analyses of USV acoustic characteristics (i.e. mean frequency, duration, bandwidth and power) revealed distinct sex-specific phenotypes in both 50-55kHz FM and 22-28kHz USV transmission that were modulated by ethanol exposure. Moreover, by using a linear combination of these acoustic characteristics, we were able to develop binomial logistic regression models able to discriminate between male and female HAD-1 rats with high accuracy. Together these results highlight unique emotional phenotypes in male and female HAD-1 rats that are differentially modulated by alcohol experience.

The shell of the nucleus accumbens has a higher dopamine response compared with the core after non-contingent intravenous ethanol administration.

Dopamine increases in the nucleus accumbens after ethanol administration in rats, but the contributions of the core and shell subregions to this response are unclear. The goal of this study was to determine the effect of various doses of i.v. ethanol infusions on dopamine in these two subregions of the nucleus accumbens. Male Long-Evans rats were infused with either acute i.v. ethanol (0.5, 1.0, 1.5 g/kg), repeated i.v. ethanol (four 1.0 g/kg infusions resulting in a cumulative dose of 4.0 g/kg), or saline as a control for each condition. Dopamine and ethanol were measured in dialysate samples from each experiment. The in vivo extraction fraction for ethanol of probes was determined using i.v. 4-methylpyrazole, and was used to estimate peak brain ethanol concentrations after the infusions. The peak brain ethanol concentrations after the 0.5, 1.0 and 1.5 g/kg ethanol infusions were estimated to be 20, 49 and 57 mM, respectively. A significant dopamine increase was observed for the 0.5 g/kg ethanol group when collapsed across subregions. However, both the 1.0 g/kg and 1.5 g/kg ethanol infusions produced significant increases in dopamine levels in the shell that were significantly higher than those in the core. An ethanol dose-response effect on dopamine in the shell was observed when saline controls, 0.5, 1.0, and 1.5 g/kg groups were compared. For the cumulative-dosing study, the first, second, and fourth infusions resulted in significant increases in dopamine in the shell. However, these responses were not significantly different from one another. The results of this study show that the shell has a stronger response than the core to i.v. ethanol, that dopamine in the shell increases in a dose-dependent manner between 0.5-1.0 g/kg doses, but that the response to higher ethanol doses reaches a plateau.

Cholinergic interneurons of the nucleus accumbens and dorsal striatum are activated by the self-administration of cocaine.

The nucleus accumbens, a major component of the ventral striatum, and the dorsal striatum are primary targets of the mesolimbic dopamine pathway, which is a pathway that plays a critical role in reward and addiction. The shell compartment of the nucleus accumbens and the ventromedial striatum, in particular, receive extensive afferent projections from the ventral tegmental area, which is the major afferent source of the mesolimbic pathway [Prog Brain Res 99 (1993) 209; J Neurosci 7 (1987) 3915]. The present study focused on striatal cholinergic interneurons as potential key neurons involved in the neural basis of drug reinforcement. The main finding of this study is that cholinergic interneurons located in the shell compartment of the nucleus accumbens and the ventromedial striatum were activated, as measured by Fos labeling, following a 1 h session of the self-administration of cocaine in rats. A direct correlation existed between the percent of cholinergic interneurons that were activated and the amount of cocaine that was self-administered. The greatest amount of administered cocaine (approximately 10 mg/kg) resulted in the activation of approximately 80% of the cholinergic neurons. No such correlation existed in the group of animals that self-administered saline. In addition, activation was not found in the core compartment of the nucleus accumbens or the dorsolateral striatum, which receive extensive innervation from the substantia nigra and thus are more closely tied to the motor effects of the drug. In conclusion, cocaine-driven neuronal activation was specific to the shell compartment of the nucleus accumbens (R(2)=0.9365) and the ventromedial striatum (R(2)=0.9059). These findings demonstrate that cholinergic interneurons are involved in the initial stage of cocaine intake and that these neurons are located in areas of the nucleus accumbens and dorsal striatum that are more closely tied to the rewarding and hedonic effects rather than the motor effects of cocaine intake.

Intra-prefrontal cortex injections of SCH 23390 influence nucleus accumbens dopamine levels 24 h post-infusion.

The dopaminergic pathway from the ventral tegmental area (VTA) to the nucleus accumbens (NAcc) is well known to be involved in the reinforcing properties of many drugs of abuse. The medial prefrontal cortex (mPFC) has been shown to exhibit significant influence over activity in this pathway, and has also been implicated in drug abuse. The present experiment investigated the ability of D1 activity in the mPFC to influence accumbal dopamine levels. NAcc dopamine (DA) was monitored before, immediately after, and 24 h following mPFC infusion of a D1 agonist (SKF 38393), D1 antagonist (SCH 23390), or a vehicle solution. Immediately following infusion of dopaminergic agents or vehicle, no significant changes in accumbal DA were observed. However, 24 h following infusion of the antagonist but not the agonist, significant elevations of accumbal DA were observed. Since elevated NAcc DA was only observed 24 h after treatment, these results provide evidence that long-term neural adaptations can be induced by transient neuropharmacological treatment.

Effects of cocaine context on NAcc dopamine and behavioral activity after repeated intravenous cocaine administration.

In two conditioning experiments, identical procedures (previously shown to produce place preferences for a cocaine-paired environment) were used to assess dopaminergic and behavioral activity correlates of cocaine reward conditioning and sensitization. In these experiments, animals received repeated injections of intravenous cocaine (4.2 mg/kgx6) or saline (0.2 mlx6) on alternating days. One group in each of these experiments ('Cocaine Cues') occupied a consistent distinctive environment during cocaine treatments and testing sessions. For the other conditioned group ('Novel'), all procedures were the same, except that the last cocaine injection was administered while animals were occupying a novel environment. During day 1 and day 6 of the cocaine treatment, behavioral activity was assessed in experiment 1 and in vivo microdialysis procedures were conducted in experiment 2. Over the course of the conditioning sessions, cocaine-induced behavioral activity (locomotion and rearing) increased significantly in the Cocaine Cues group, but not in the Novel group. In addition, cocaine-induced increases in NAcc dopamine levels were significantly greater when cocaine-experienced animals were tested in a cocaine-paired environment compared to equally experienced and cocaine-naive animals tested in a novel environment. Context-dependent behavioral sensitization is a well-documented phenomenon. The observation of a corresponding enhancement of dopamine efflux in lieu of a lengthy withdrawal period is uncommon, but can be attributed to methodological differences across studies. The present study uniquely demonstrates concurrent context-dependent potentiation of behavioral and dopaminergic responses to cocaine occurring in conjunction with cocaine reward.

Conditioned increases in behavioral activity and accumbens dopamine levels produced by intravenous cocaine.

In vivo microdialysis, behavioral activity assessments, and a conditioned place preference (CPP) test were used to investigate dopaminergic correlates of cocaine-conditioned behaviors. Over 12 days, rats were given either intravenous cocaine (4.2 mg/kg) or saline (6 cocaine and 6 saline infusions) daily in distinctively different environments. The following day, rats were tested in the cocaine- and saline-paired environments; 48 hr later, CPP was determined. The cocaine-associated environment elicited greater nucleus accumbens dopamine (NAcc DA) levels, hyperactivity, and place preference, though the emergence of DA increases was not in synchrony with peak behavioral activation. Although conditioned behavioral effects after repeated cocaine are well documented, direct evidence of increased NAcc DA in response to a cocaine-paired environment has not been previously reported. Discrepancies with previous work are attributed to a number of methodological differences.

Prefrontal cortex infusions of SCH 23390 cause immediate and delayed effects on ventral tegmental area stimulation reward.

A reward-relevant relationship between dopamine projection regions of the ventral tegmental area (VTA) was investigated through the use of brain stimulation reward (BSR) thresholds. Using a rate-free method, changes in VTA BSR thresholds were determined after intracranial injections of the dopamine D1 antagonist, SCH 23390 into the prefrontal cortex (PFC), or the nucleus accumbens (NAcc). Reward thresholds assessed immediately after the infusion of SCH 23390 into the NAcc (0.5 microgram/0.5 microliter/side) were significantly higher than those assessed just after saline infusions, indicating a drug-induced attenuation of the rewarding effects of the brain stimulation. The effects of this dose subsided when tested 24 h later. Conversely, intra-PFC infusions of SCH 23390 at the same dose (0.5 microgram/0.5 microliter/side) resulted in lowered BSR thresholds when rats were tested immediately after infusion. In addition, animals tested 24 h after receiving the lowest dose (0.125 microgram/0.5 microliter/side) demonstrated a robust delayed threshold-lowering effect. These immediate and delayed effects of the intra-PFC dopamine antagonist demonstrate a facilitation of VTA BSR and are consistent with the view that PFC dopamine serves a modulatory role over important reward elements within the NAcc. The deferred effects of intra-prefrontal cortex DA receptor blockade on brain stimulation reward thresholds may reflect adaptive responses of subcortical structures to changes in PFC dopamine neurotransmission. It has been suggested that neural adjustments of this type may underlie long term changes in central nervous system functioning brought about by disease, drug use or behavioral conditioning.

The synergistic effects of combining cocaine and heroin ("speedball") using a progressive-ratio schedule of drug reinforcement.

The relative reinforcing value of cocaine/heroin combination ("speedball") was compared in the rat using a progressive-ratio (PR) reinforcement schedule. The initial training for all rats was a combined dose of 18 microg/kg/inj of heroin (H) plus 300 microg/kg/inj of cocaine (C). Break points for the training dose and individual component doses were determined for half and double the training dose. Of the three doses of each treatment, only C yielded the expected monotonic increase in break point as a function of dose. Also, break points for C (300 and 600 microg/kg/inj) was greater than for the combination of C and H (18 H/300 C and 36 H/600 C microg/kg/inj), suggesting a greater reward value for C alone. The doses for these three drug treatments that produced saline level break points were then determined. At these lower doses, significant break points were obtained with the H/C combination at which the respective doses of H or C had break points identical to those of saline. These lower dose results indicate that the combination is clearly synergistic and that the discrepancy with doses at the opposite end of the dose response curve suggest that the PR schedule is vulnerable to drug-induced motor effects.

DAMGO and DPDPE facilitation of brain stimulation reward thresholds is blocked by the dopamine antagonist cis-flupenthixol.

The role of dopamine neurotransmission in opioid reward was investigated using a rate-independent measure for determining brain stimulation reward (BSR) thresholds. Intra-accumbens infusions of the mu- and delta-specific peptides, D-Ala2, N-Me-Phe4, Gly-ol5-Enkephalin and D-Pen2, D-Pen5-Enkephalin caused significant lowering of BSR thresholds. The dopamine D1/D2 antagonist, cis-flupenthixol, blocked these effects at a dose that did not significantly alter thresholds when given alone. These data suggest both mu- and delta-opioid potentiation of BSR is dopamine dependent.

Involvement of delta- and mu-opioid receptors in the potentiation of brain-stimulation reward.

A rate-free method of determining brain-stimulation reward thresholds was used to identify the rewarding effects of the delta-opioid receptor and mu-opioid receptor agonist peptides, [D-Pen2, D-Pen5]enkephalin (DPDPE) and [D-Ala2-MePhe4-Gly(o1)5]enkephalin (DAMGO). The nucleus accumbens-delivered opioid receptor agonists produced marked lowering of the threshold for ventral tegmental area brain-stimulation reward. No change in baseline thresholds was seen after peripheral administration of the nonpeptide delta-opioid receptor antagonist, naltrindole. However, an unexpected finding was that naltrindole blocked the threshold-lowering effects of both DPDPE and DAMGO. These data demonstrate nucleus accumbens activation of delta- and mu-opioid receptors and ventral tegmental area brain-stimulation reward share common brain substrates. In addition, the interference of both delta- and mu-opioid receptor mediated reward by naltrindole may have implications for therapeutic use.

The use of a biopsy punch in surgical preparation of drug self-administering animals.

This report describes a simple surgical method of exiting an implanted intravenous catheter through the skin via a nonsutured site. The preparation, which makes use of a biopsy punch, avoids placing the catheter exiting point through the incision used for subcutaneously fixing the catheter platform on the back of the animal.

Pimozide prevents the development of conditioned place preferences induced by rewarding locus coeruleus stimulation.

Electrical stimulation in the vicinity of the cell bodies of the locus coeruleus (LC) has been shown to support self-stimulation behaviors in rats. In the present study, a Conditioned Place Test, sensitive to both rewarding and aversive qualities of brain stimulation, was employed to determine (a) whether rewarding locus coeruleus stimulation would result in place preferences and (b) if so, whether dopamine receptor antagonism would affect the development of such place preferences. Animals were pretreated with pimozide (0.0, 0.5 or 1.0 mg/kg) prior to exposure to two distinctive environments only one of which was paired with locus coeruleus stimulation. Rats that received vehicle injections prior to stimulation/place pairings developed strong preferences for the stimulation-paired environment while those animals pretreated with 0.5 mg/kg pimozide showed no reliable shift in preference from baseline performance. Additionally, animals injected with the 1.0 mg/kg dose of pimozide exhibited mild place aversions to the stimulation-paired environment. It is hypothesized that dopamine neurotransmission is important for the rewarding effects of locus coeruleus stimulation without which such stimulation appears to be aversive.

Opposite effects of prefrontal cortex and nucleus accumbens infusions of flupenthixol on stimulant-induced locomotion and brain stimulation reward.

Ventral tegmental area (VTA) stimulation produced conditioned place preferences for stimulation-paired environments the magnitudes of which were dose-dependently reduced by systemic application of the dopamine antagonist, haloperidol (0.0, 0.15, 0.3 mg/kg). Bilateral microinjections of cis-flupenthixol (FLU) into the nucleus accumbens (0.0, 1.0, 5.0 or 10.0 micrograms) also resulted in reductions in the size of stimulation-induced place preferences as well as reductions in the magnitude of the hyperlocomotor response to 1.5 mg/kg (s.c.) D-amphetamine. Comparable microinjections of FLU into the medial prefrontal cortex (PFC) produced diametrically opposite effects: the size of VTA stimulation-induced place preferences was either unaffected (1.0 and 5.0 microgram groups) or slightly increased (10 micrograms group) and amphetamine-stimulated hyperlocomotion was dose-dependently potentiated. These behavioral findings suggest a dopamine-mediated modulatory role for the PFC over reward relevant elements within the nucleus accumbens.

Haloperidol attenuates conditioned place preferences produced by electrical stimulation of the medial prefrontal cortex.

A Conditioned Place Preference test procedure [Ettenberg and Duvauchelle (13)] was used to investigate the effects of dopamine antagonist challenge on the rewarding properties of medial prefrontal cortex (MPFC) electrical stimulation. Rats exhibited strong preferences for the side of a two-compartment test apparatus in which they experienced sessions of experimenter-administered 0.5-s trains of MPFC sine-wave 60-Hz stimulation. Pretreatment with the neuroleptic dopamine antagonist drug, haloperidol (0.0, 0.15, or 0.3 mg/kg IP), resulted in a dose-dependent reduction in the magnitude of observed place preferences. Preference tests were conducted 24 hours after drug-conditioning trials and, hence, were not subject to motoric or other nonspecific actions of the neuroleptic treatments. In a control experiment, haloperidol did not block the place aversions produced by dorsomedial tegmental stimulation. Animals can, therefore, recall place-associations formed in the presence of haloperidol, a result which challenges "state-dependent learning" explanations of the drug's actions. Together, these results are consistent with the view that dopamine neurotransmission is involved in the rewarding consequences of electrical stimulation in the medial prefrontal cortex.

Haloperidol blocks the conditioned place preferences induced by rewarding brain stimulation.

The conditioned place preference test was employed to investigate the effects of neuroleptic challenge on the rewarding properties of lateral hypothalamic stimulation. Conditioning took place during a single day and consisted of five 5-min exposures to each of two environments (differing in color and floor texture). Twenty-four hours later, when provided a choice between the two environments, rats showed strong preferences for the environment in which they had experienced sessions of rewarding brain stimulation. These stimulation-produced place preferences were prevented by pretreatment with the neuroleptic drug, haloperidol (0.3 but not 0.15 mg/kg, ip). On the basis of these results, it was concluded that (a) the conditioned place preference test can provide a rate-free index of brain stimulation reward and (b) dopamine receptor antagonism can result in an attenuation of the rewarding properties of lateral hypothalamic stimulation.