Increased Excitability of Layer 2 Cortical Pyramidal Neurons in the Supplementary Motor Cortex Underlies High Cocaine-Seeking Behaviors.

BACKGROUND: Most efforts in addiction research have focused on the involvement of the medial prefrontal cortex, including the infralimbic, prelimbic, and anterior cingulate cortical areas, in cocaine-seeking behaviors. However, no effective prevention or treatment for drug relapse is available. METHODS: We focused instead on the motor cortex, including both the primary and supplementary motor areas (M1 and M2, respectively). Addiction risk was evaluated by testing cocaine seeking after intravenous self-administration (IVSA) of cocaine in Sprague Dawley rats. The causal relationship between the excitability of cortical pyramidal neurons (CPNs) in M1/M2 and addiction risk was explored by ex vivo whole-cell patch clamp recordings and in vivo pharmacological or chemogenetic manipulation. RESULTS: Our recordings showed that on withdrawal day 45 (WD45) after IVSA, cocaine, but not saline, increased the excitability of CPNs in the cortical superficial layers (primarily layer 2, denoted L2) but not in layer 5 (L5) in M2. Bilateral microinjection of the GABAA (gamma-aminobutyric acid A) receptor agonist muscimol to the M2 area attenuated cocaine seeking on WD45. More specifically, chemogenetic inhibition of CPN excitability in L2 of M2 (denoted M2-L2) by the DREADD (designer receptor exclusively activated by designer drugs) agonist compound 21 prevented drug seeking on WD45 after cocaine IVSA. This chemogenetic inhibition of M2-L2 CPNs had no effects on sucrose seeking. In addition, neither pharmacological nor chemogenetic inhibition manipulations altered general locomotor activity. CONCLUSIONS: Our results indicate that cocaine IVSA induces hyperexcitability in the motor cortex on WD45. Importantly, the increased excitability in M2, particularly in L2, could be a novel target for preventing drug relapse during withdrawal.

Limited versus extended cocaine intravenous self-administration: Behavioral effects and electrophysiological changes in insular cortex.

AIMS: Limited vs extended drug exposure has been proposed as one of the key factors in determining the risk of relapse, which is the primary characteristic of addiction behaviors. The current studies were designed to explore the related behavioral effects and neuronal alterations in the insular cortex (IC), an important brain region involved in addiction. METHODS: Experiments started with rats at the age of 35 days, a typical adolescent stage when initial drug exposure occurs often in humans. The drug-seeking/taking behaviors, and membrane properties and intrinsic excitability of IC pyramidal neurons were measured on withdrawal day (WD) 1 and WD 45-48 after limited vs extended cocaine intravenous self-administration (IVSA). RESULTS: We found higher cocaine-taking behaviors at the late withdrawal period after limited vs extended cocaine IVSA. We also found minor but significant effects of limited but not extended cocaine exposure on the kinetics and amplitude of action potentials on WD 45, in IC pyramidal neurons. CONCLUSION: Our results indicate potential high risks of relapse in young rats with limited but not extended drug exposure, although the adaptations detected in the IC may not be sufficient to explain the neural changes of higher drug-taking behaviors induced by limited cocaine IVSA.

Contrasting effects of adolescent and early-adult ethanol exposure on prelimbic cortical pyramidal neurons.

BACKGROUND: Adolescence and early-adulthood are vulnerable developmental periods during which binge drinking can have long-lasting effects on brain function. However, little is known about the effects of binge drinking on the pyramidal cells of the prelimbic cortex (PrL) during early and protracted withdrawal periods. METHODS: In the present study, we performed whole-cell patch clamp recordings and dendritic spine staining to examine the intrinsic excitability, spontaneous excitatory post-synaptic currents (sEPSCs), and spine morphology of pyramidal cells in the PrL from rats exposed to chronic intermittent ethanol (CIE) during adolescence or early-adulthood. RESULTS: Compared to chronic intermittent water (CIW)-treated controls, the excitability of PrL-L5 pyramidal neurons was significantly increased 21 days after adolescent CIE but decreased 21 days after early-adult CIE. No changes of excitability in PrL Layer (L) 5 were detected 2 days after either adolescent or early-adulthood CIE. Interestingly, decreases in sEPSC amplitude and increases in thin spines ratio were detected 2 days after adolescent CIE. Furthermore, decreased frequency and amplitude of sEPSCs, accompanied by a decrease in the density of total spines and non-thin spines were observed 21 days after adolescent CIE. In contrast, increased frequency and amplitude of sEPSCs, accompanied by increased densities of total spines and non-thin spines were found 21 days after early adult CIE. CONCLUSION: CIE produced prolonged neuronal and synaptic alterations in PrL-L5, and the developmental stage, i.e., adolescence vs. early-adulthood when subjects receive CIE, is a key factor in determining the direction of these changes.

Prenatal alcohol exposure reduces posterior dorsomedial striatum excitability and motivation in a sex- and age-dependent fashion.

Prenatal alcohol exposure (PAE)-induced clinical symptoms have been widely reported but effective treatments are not yet available due to our limited knowledge of the neuronal mechanisms underlying behavioral outputs. Operant behaviors, including both goal-directed and habitual actions, are essential for everyday life. The dorsomedial striatum (DMS) and the dorsolateral striatum (DLS) have been identified as mediating each type of instrumental behavior, respectively. The current studies were designed to evaluate the effects of PAE (i.e., 3 g/kg, twice a day on gestational days 17-20) on goal-directed vs. habitual behaviors in both females and males during their adolescent and adult stages. We found that PAE-treated adult, but not adolescent, males display similar habitual oral sucrose self-administration but reduced goal-directed sucrose self-administration, compared to those treated by prenatal control (water) exposure (PCE). There were no differences in either habitual or goal-directed sucrose taking between PCE- vs. PAE-treated adolescent and adult females. These results indicate sex- and age-specific effects of PAE on operant behaviors. Further, whole-cell patch clamp recordings showed that the excitability of medium-sized spiny neurons (MSNs) in the posterior DMS (pDMS), but not the anterior DMS (aDMS), was significantly decreased in PAE-treated adult male rats. Notably, chemogenetic enhancement of MSN excitability in the pDMS by the DREADD agonist, compound 21, rescued the motivation of PAE-treated male adult rats. These data suggest that the pDMS may be a key neuronal substrate mediating the PAE-induced low motivation in male adults.

Acquisition and expression of fat-conditioned flavor preferences are differentially affected by NMDA receptor antagonism in BALB/c and SWR mice.

Conditioned flavor preferences are elicited by fat (Intralipid) in inbred mouse strains with BALB/c and SWR mice displaying among the most robust preferences. Dopamine D1 and opioid receptor antagonism differentially reduces the acquisition (learning) and expression (maintenance) of fat-conditioned flavor preferences in these two strains. Because noncompetitive NMDA receptor antagonism with MK-801 differentially altered sugar-conditioned flavor preferences in these strains, and because NMDA receptors are involved in fat intake, the present study examined whether MK-801 differentially altered expression and acquisition of fat (Intralipid)-conditioned flavor preferences in BALB/c and SWR mice. In expression studies, food-restricted male mice alternately consumed a flavored (CS+, e.g., cherry, 5 sessions) 5% Intralipid solution and a differently-flavored (CS-, e.g., grape, 5 sessions) 0.5% Intralipid solution. Two-bottle CS choice tests occurred following vehicle or MK-801 (100, 200µg/kg). MK-801 blocked expression of Intralipid-CFP at both doses in BALB/c mice, but only at the 100µg/kg dose in SWR mice. In acquisition studies, groups of BALB/c (0, 100µg/kg) and SWR (0, 100µg/kg) male mice were treated prior to the ten acquisition training sessions followed by six 2-bottle CS choice tests without injections. MK-801 eliminated acquisition of Intralipid-conditioned flavor preferences in BALB/c mice, and actually changed the preference to an avoidance response in SWR mice. Thus, NMDA receptor signaling appears essential especially for the learning of fat-conditioned flavor preferences in both mouse strains.

NMDA receptor antagonism differentially reduces acquisition and expression of sucrose- and fructose-conditioned flavor preferences in BALB/c and SWR mice.

Conditioned flavor preferences (CFP) are elicited by sucrose and fructose relative to saccharin in rats and inbred mice. Whereas dopamine, but not opioid receptor antagonists interfere with the acquisition (learning) and expression (maintenance) of sugar-CFP in rats, these antagonists differentially affect acquisition and expression of sucrose- and fructose-CFP in BALB/c and SWR inbred mice. Given that NMDA receptor antagonism with MK-801 blocks acquisition, but not expression of fructose-CFP in rats, the present study examined whether MK-801 altered the expression and acquisition of sucrose- and fructose-CFP in BALB/c and SWR mice. In expression experiments, food-restricted mice alternately consumed a flavored (CS+, e.g., cherry, 5 sessions) 16% sucrose or 8% fructose+0.2% saccharin solution and a differently-flavored (CS-, e.g., grape, 5 sessions) 0.2% saccharin solution. 2-Bottle CS choice tests occurred following vehicle or MK-801 at doses of 100 or 200µg/kg. MK-801 mildly reduced the magnitude of the expression of sucrose- and fructose-CFP in BALB/c mice, and blocked the expression of fructose-, but not sucrose-CFP at the high dose in SWR mice. In acquisition experiments, groups of BALB/c (0, 100µg/kg) and SWR (0, 100, 200µg/kg) mice were treated prior to acquisition training sessions that was followed by 2-bottle CS choice tests without injections. MK-801 (100µg/kg) eliminated acquisition of sucrose- and fructose-CFP in BALB/c, but not SWR mice. The 200µg/kg MK-801 dose eliminated acquisition of sucrose- and fructose-CFP in SWR mice. Thus, NMDA receptor signaling is essential for the learning of both forms of sugar-CFP in both strains with BALB/c mice more sensitive to MK-801 dose effects.

BALB/c and SWR inbred mice differ in post-oral fructose appetition as revealed by sugar versus non-nutritive sweetener tests.

Recent studies indicate that C57BL/6J (B6) and FVB inbred mouse strains differ in post-oral fructose conditioning. This was demonstrated by their differential flavor conditioning response to intragastric fructose and their preference for fructose versus a non-nutritive sweetener. The present study extended this analysis to SWR and BALB/c inbred strains which are of interest because they both show robust flavor conditioning responses to fructose. In the first experiment, ad-libitum fed mice were given a series of 2-day, two-bottle preference tests between 8% fructose and a more preferred, but non-nutritive 0.1% sucralose +0.1% saccharin (S+S) solution (tests 1 & 4), and fructose or S+S versus water (tests 2 and 3). In test 1, SWR mice preferred S+S to fructose, and in tests 2 and 3, they preferred both sweeteners to water. In test 4, SWR mice switched their preference and consumed more fructose than S+S. In contrast, ad-libitum fed BALB/c mice strongly preferred S+S to fructose in both tests 1 and 4, although they preferred both sweeteners to water in tests 2 and 3. Food-restricted BALB/c mice also preferred the non-nutritive S+S to fructose in tests 1 and 4. The experience-induced fructose preference reversal observed in SWR, but not BALB/c mice indicates that fructose has a post-oral reinforcing effect in SWR mice as in FVB mice. Because B6 and FVB mice prefer glucose to fructose based on the post-oral actions of the two sugars, the second experiment compared the preferences of SWR and BALB/c mice for 8% glucose and fructose solutions. Ad-libitum fed and food-restricted SWR mice strongly preferred glucose to fructose. In contrast, ad-libitum fed BALB/c mice were indifferent to the sugars, perhaps because of their overall low intakes. Food-restricted BALB/c mice, however, strongly preferred glucose. These findings indicate that SWR and BALB/c mice differ in their preference response to the post-oral actions of fructose.

Dopamine D1 and opioid receptor antagonists differentially reduce the acquisition and expression of fructose-conditioned flavor preferences in BALB/c and SWR mice.

Sugar appetite is influenced by unlearned and learned preferences in rodents. The present study examined whether dopamine (DA) D1 (SCH23390: SCH) and opioid (naltrexone: NTX) receptor antagonists differentially altered the expression and acquisition of fructose-conditioned flavor preferences (CFPs) in BALB/c and SWR mice. In expression experiments, food-restricted mice alternately (10 sessions, 1h) consumed a flavored (e.g., cherry) 8% fructose+0.2% saccharin solution (CS+) and a differently-flavored (e.g., grape) 0.2% saccharin solution (CS-). Two-bottle CS choice tests (1h) occurred 0.5h following vehicle: SCH (200 or 800 nmol/kg) or NTX (1 or 5mg/kg). SCH, but not NTX significantly reduced CS+ preference in both strains. In acquisition experiments, 0.5h prior to 10 acquisition training sessions, vehicle, SCH (50 nmol/kg), NTX (1 mg/kg) or Limited Control vehicle treatments were administered, followed by two-bottle CS choice tests without injections. SCH and NTX reduced training intakes in both strains. BALB/c mice displayed hastened extinction of the fructose-CFP following training with SCH, but not NTX. SCH eliminated fructose-CFP acquisition in SWR mice, whereas NTX hastened extinction of the CFP. These results are compared to previous drug findings obtained with sucrose-CFPs in SWR and BALB/c mice, and are discussed in terms of differential effects of these sugars on oral and post-oral conditioning.

Dopamine D1 and opioid receptor antagonist-induced reductions of fructose and saccharin intake in BALB/c and SWR inbred mice.

Sugar and fat intake in rodents are mediated in part by brain dopamine (DA) and opioid neurotransmitter systems although important strain differences exist. Thus, whereas sucrose intake of BALB/c and SWR mice was reduced by DA D1 (SCH23390: SCH) receptor antagonism, opioid (naltrexone: NTX) receptor antagonism reduced intake only in BALB/c mice. Both SCH and NTX reduced fat (Intralipid) intake in SWR, but not BALB/c mice. The present study extended this pharmacological analysis to caloric and non-caloric sweeteners by examining whether fructose (8%) or saccharin (0.2%) intakes were differentially suppressed in BALB/c and SWR mice by SCH (50-1600nmol/kg) or NTX (0.01-5mg/kg) over a 5- to 120-min time course. SCH significantly reduced fructose (200-1600nmol/kg) and saccharin (50-1600nmol/kg) intakes in both strains as did NTX (0.1-5mg/kg). Antagonist ID40 potencies were <50nmol/kg for SCH and 0.9mg/kg for NTX in inhibiting saccharin intake, and 1234nmol/kg for SCH and 5mg/kg for NTX in inhibiting fructose intake in BALB/c mice. For SWR mice, the ID40 potencies were <50nmol/kg for SCH and 0.02mg/kg for NTX in inhibiting saccharin intake, and 298nmol/kg for SCH and 2.6mg/kg for NTX in inhibiting fructose intake. Thus, saccharin intake was similarly reduced by SCH and NTX in BALB/c and SWR mice, but greater potencies of opioid (1.9-fold) and DA D1 (4-fold) receptor antagonism of fructose intake were observed in SWR relative to BALB/c mice, indicating strong strain differences.

Pleasure and pain: teaching neuroscientific principles of hedonism in a large general education undergraduate course.

In a large (250 registrants) general education lecture course, neuroscience principles were taught by two professors as co-instructors, starting with simple brain anatomy, chemistry, and function, proceeding to basic brain circuits of pleasure and pain, and progressing with fellow expert professors covering relevant philosophical, artistic, marketing, and anthropological issues. With this as a base, the course wove between fields of high relevance to psychology and neuroscience, such as food addiction and preferences, drug seeking and craving, analgesic pain-inhibitory systems activated by opiates and stress, neuroeconomics, unconscious decision-making, empathy, and modern neuroscientific techniques (functional magnetic resonance imaging and event-related potentials) presented by the co-instructors and other Psychology professors. With no formal assigned textbook, all lectures were PowerPoint-based, containing links to supplemental public-domain material. PowerPoints were available on Blackboard several days before the lecture. All lectures were also video-recorded and posted that evening. The course had a Facebook page for after-class conversation and one of the co-instructors communicated directly with students on Twitter in real time during lecture to provide momentary clarification and comment. In addition to graduate student Teaching Assistants (TAs), to allow for small group discussion, ten undergraduate students who performed well in a previous class were selected to serve as discussion leaders. The Discussion Leaders met four times at strategic points over the semester with groups of 20-25 current students, and received one credit of Independent Study, thus creating a course within a course. The course grade was based on weighted scores from two multiple-choice exams and a five-page writing assignment in which each student reviewed three unique, but brief original peer-review research articles (one page each) combined with expository writing on the first and last pages. A draft of the first page, collected early in the term, was returned to each student by graduate TAs to provide individual feedback on scientific writing. Overall the course has run three times at ful or near enrollment capacity despite being held at an 8:00 AM time slot. Student-generated teaching evaluations place it well within the normal range, while this format importantly contributes to budget efficiency permitting the teaching of more required small-format courses (e.g., freshman writing). The demographics of the course have changed to one in which the vast majority of the students are now outside the disciplines of neuroscience or psychology and are taking the course to fulfill a General Education requirement. This pattern allows the wide dissemination of basic neuroscientific knowledge to a general college audience.

Dopamine D1 and opioid receptor antagonism effects on the acquisition and expression of fat-conditioned flavor preferences in BALB/c and SWR mice.

Sugar and fat appetites are influenced by unlearned and learned responses to orosensory and post-ingestive properties which are mediated by dopamine (DA) and opioid transmitter systems. In BALB and SWR mice, acquisition and expression of sucrose conditioned flavor preferences (CFP) are differentially affected by systemic DA D1 (SCH23390: SCH) and opioid (naltrexone: NTX) antagonism. The present study examined whether fat-CFP occurred in these strains using preferred (5%) and less preferred (0.5%) Intralipid solutions, and how SCH and NTX altered its expression and acquisition. Food-restricted mice drank flavored (CS+, e.g., cherry) 5% and flavored (CS-, e.g., grape) 0.5% Intralipid solutions in alternate 1 h/day sessions. Six two-bottle tests with both CS flavors presented in 0.5% Intralipid occurred. Robust and comparable fat-CFP was observed in both strains. In Experiment 2, vehicle (Veh), SCH (50-800 nmol/kg) or NTX (1-5 mg/kg) were administered prior to two-bottle testing in an identical paradigm. Expression of fat-CFP was significantly reduced by SCH and NTX in BALB mice, and only by SCH in SWR mice. NTX produced significantly greater inhibition of fat-CFP expression in BALB versus SWR mice. In Experiment 3, separate groups of BALB and SWR mice received Veh, SCH (50 nmol/kg) or NTX (1 mg/kg) injections prior to daily one-bottle CS+ and CS- training sessions to assess acquisition effects. Six two-bottle CS+ vs. CS- choice tests were then conducted. Fat-CFP acquisition was significantly reduced in SWR mice by SCH, but not NTX, and was only mildly affected by both antagonists in BALB mice. SCH produced significantly greater inhibition of fat-CFP acquisition in SWR versus BALB mice. The pattern of SCH effects upon the expression and acquisition of fat-CFP in BALB and SWR mice was quite similar to that observed for sucrose-CFP, suggesting similar DA D1 receptor involvement in sugar- and fat-CFP in these mouse strains.