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Prenatal ethanol exposure (PE) causes Fetal Alcohol Spectrum Disorders (FASD), characterized by cognitive, behavioral, and emotional deficits, including anxiety and depression. PE-induced alteration in the function of dorsal raphe nucleus (DRN) serotonin (5-HT) neurons is thought to be major contributing factor for increased anxiety. However, the precise neuronal circuits involved are unknown. Using electrophysiology, optogenetics, chemogenetics, and behavioral approaches, we find that PE preferentially potentiates medial prefrontal cortex (mPFC) glutamatergic inputs, but not lateral habenula (LHb), to DRN 5-HT neurons projecting to mPFC. Additionally, PE also increases the strength of LHb but not mPFC excitatory inputs to DRN 5-HT neurons projecting to central amygdala (Ce). This input and target selective effect of PE was mediated by a circuit-specific increase in nitric oxide (NO) signaling. Importantly, chemogenetic inhibition of mPFC-DRN neuronal circuit blunted anxiety-like behaviors in PE rats. As such, our results unraveled the DRN neuronal circuitries affected by PE, which gate FASD-induced anxiety-like behaviors.

Prenatal ethanol exposure (PE) causes Fetal Alcohol Spectrum Disorders (FASD), characterized by cognitive, behavioral, and emotional deficits, including anxiety and depression. PE-induced alteration in the function of dorsal raphe nucleus (DRN) serotonin (5-HT) neurons is thought to be major contributing factor for increased anxiety. However, the precise neuronal circuits involved are unknown. Using electrophysiology, optogenetics, chemogenetics, and behavioral approaches, we find that PE preferentially potentiates medial prefrontal cortex (mPFC) glutamatergic inputs, but not lateral habenula (LHb), to DRN 5-HT neurons projecting to mPFC. Additionally, PE also increases the strength of LHb but not mPFC excitatory inputs to DRN 5-HT neurons projecting to central amygdala (Ce). This input and target selective effect of PE was mediated by a circuit-specific increase in nitric oxide (NO) signaling. Importantly, chemogenetic inhibition of mPFC-DRN neuronal circuit blunted anxiety-like behaviors in PE rats. As such, our results unraveled the DRN neuronal circuitries affected by PE, which gate FASD-induced anxiety-like behaviors.

The unclear mechanisms of ethanol metabolism in the brain highlight the need for a deeper understanding of its metabolic pathways. This study used in vivo microdialysis to simultaneously sample ethanol and its metabolites, acetaldehyde and acetate, in the rat striatum following self-administration of ethanol, emphasizing the natural oral exposure route. To enhance the self-administration, rats underwent two-bottle-choice and limited access training. Dialysate samples, collected every 10 min for 2.5 h, were analyzed using gas chromatography with flame ionization detection (GC-FID). The measured time courses of dialysate concentrations of ethanol, acetaldehyde, and acetate provided insights into dynamics of ethanol metabolism. Notably, in a subject with low ethanol consumption (0.29 g/kg), the concentration of acetaldehyde remained below the limit of detection throughout the experiment. However, the acetate concentration was clearly increased after ethanol consumption in this subject and was comparable to that of other rats with higher ethanol consumption. Compared with focusing only on peak values in the time-courses of concentrations of ethanol and its metabolites, calculating areas under curves provided better models of the relationships between ethanol intake and individual ethanol metabolites, as indicated by the R-square values for the linear regressions. This approach of using the area under the curve accounts for both the amplitude and duration of the concentration profiles, reducing the impact of variations in individual drinking patterns. In vivo microdialysis enables concurrent sampling of brain metabolites during oral ethanol administration, contributing insights into metabolite dynamics. To our knowledge, this paper is the first to report measurement of all three analytes in the brain following self-administration of ethanol. Future studies will explore regional variations and dynamics post-ethanol dependence, further advancing our understanding of ethanol metabolism in the brain.

The unclear mechanisms of ethanol metabolism in the brain highlight the need for a deeper understanding of its metabolic pathways. This study used in vivo microdialysis to simultaneously sample ethanol and its metabolites, acetaldehyde and acetate, in the rat striatum following self-administration of ethanol, emphasizing the natural oral exposure route. To enhance the self-administration, rats underwent two-bottle-choice and limited access training. Dialysate samples, collected every 10 min for 2.5 h, were analyzed using gas chromatography with flame ionization detection (GC-FID). The measured time courses of dialysate concentrations of ethanol, acetaldehyde, and acetate provided insights into dynamics of ethanol metabolism. Notably, in a subject with low ethanol consumption (0.29 g/kg), the concentration of acetaldehyde remained below the limit of detection throughout the experiment. However, the acetate concentration was clearly increased after ethanol consumption in this subject and was comparable to that of other rats with higher ethanol consumption. Compared with focusing only on peak values in the time-courses of concentrations of ethanol and its metabolites, calculating areas under curves provided better models of the relationships between ethanol intake and individual ethanol metabolites, as indicated by the R-square values for the linear regressions. This approach of using the area under the curve accounts for both the amplitude and duration of the concentration profiles, reducing the impact of variations in individual drinking patterns. In vivo microdialysis enables concurrent sampling of brain metabolites during oral ethanol administration, contributing insights into metabolite dynamics. To our knowledge, this paper is the first to report measurement of all three analytes in the brain following self-administration of ethanol. Future studies will explore regional variations and dynamics post-ethanol dependence, further advancing our understanding of ethanol metabolism in the brain.

Heavy alcohol use during adolescence has a significant impact on cognitive functions, such as episodic memory, even after detoxification. However, in animal models, defects in episodic memory by adolescent alcohol exposure have not been consistently replicated, and thus, the brain regions and systems that are involved remain to be elucidated. Here, we show that adolescent alcohol exposure impairs episodic memory through the impairment of the dopamine system in the prelimbic region (PrL) of the medial prefrontal cortex in both females and males. Using mice as a model, we first show that adolescent alcohol exposure disrupts episodic-like memory in female and male adult mice. We then show that adolescent alcohol exposure decreases dopaminergic presynaptic terminals in the PrL in female and male mice. This decrease persists into adulthood. Finally, we show that the adult application of a D1 dopamine receptor agonist into the PrL of adolescent alcohol-exposed mice rescues episodic-like memory in female and male mice. Together, our results identify that dopaminergic synapses in the PrL play critical roles in the effects of adolescent alcohol use on episodic memory and provide a potential strategy to reverse memory deficits caused by adolescent alcohol use in both sexes.

Heavy alcohol use during adolescence has a significant impact on cognitive functions, such as episodic memory, even after detoxification. However, in animal models, defects in episodic memory by adolescent alcohol exposure have not been consistently replicated, and thus, the brain regions and systems that are involved remain to be elucidated. Here, we show that adolescent alcohol exposure impairs episodic memory through the impairment of the dopamine system in the prelimbic region (PrL) of the medial prefrontal cortex in both females and males. Using mice as a model, we first show that adolescent alcohol exposure disrupts episodic-like memory in female and male adult mice. We then show that adolescent alcohol exposure decreases dopaminergic presynaptic terminals in the PrL in female and male mice. This decrease persists into adulthood. Finally, we show that the adult application of a D1 dopamine receptor agonist into the PrL of adolescent alcohol-exposed mice rescues episodic-like memory in female and male mice. Together, our results identify that dopaminergic synapses in the PrL play critical roles in the effects of adolescent alcohol use on episodic memory and provide a potential strategy to reverse memory deficits caused by adolescent alcohol use in both sexes.

IntroductionConsidering sex as a biological variable (SABV) in preclinical research can enhance understanding of the neurobiology of alcohol use disorder (AUD). However, the behavioral and neural mechanisms underlying sex-specific differences remain unclear. This study aims to elucidate SABV in ethanol (EtOH) consumption by evaluating its reinforcing effects and regulation by glutamate AMPA receptor activity in male and female mice.MethodsC57BL/6J mice (male and female) were assessed for EtOH intake under continuous and limited access conditions in the home cage. Acute sensitivity to EtOH sedation and blood clearance were evaluated as potential modifying factors. Motivation to consume EtOH was measured using operant self-administration procedures. Sex-specific differences in neural regulation of EtOH reinforcement were examined by testing the effects of a glutamate AMPA receptor antagonist on operant EtOH self-administration.ResultsFemale C57BL/6J mice exhibited a time-dependent escalation in EtOH intake under both continuous and limited access conditions. They were less sensitive to EtOH sedation and had lower blood levels post-EtOH administration (4 g/kg) despite similar clearance rates. Females also showed increased operant EtOH self-administration and progressive ratio performance over a 30-day baseline period compared to males. The AMPAR antagonist GYKI 52466 (0–10 mg/kg, IP) dose-dependently reduced EtOH-reinforced lever pressing in both sexes, with no differences in potency or efficacy.DiscussionThese findings confirm that female C57BL/6J mice consume more EtOH than males in home-cage conditions and exhibit reduced acute sedation, potentially contributing to higher EtOH intake. Females demonstrated increased operant EtOH self-administration and motivation, indicating higher reinforcing efficacy. The lack of sex differences in the relative effects of GYKI 52466 suggests that AMPAR activity is equally required for EtOH reinforcement in both sexes.

IntroductionConsidering sex as a biological variable (SABV) in preclinical research can enhance understanding of the neurobiology of alcohol use disorder (AUD). However, the behavioral and neural mechanisms underlying sex-specific differences remain unclear. This study aims to elucidate SABV in ethanol (EtOH) consumption by evaluating its reinforcing effects and regulation by glutamate AMPA receptor activity in male and female mice.MethodsC57BL/6J mice (male and female) were assessed for EtOH intake under continuous and limited access conditions in the home cage. Acute sensitivity to EtOH sedation and blood clearance were evaluated as potential modifying factors. Motivation to consume EtOH was measured using operant self-administration procedures. Sex-specific differences in neural regulation of EtOH reinforcement were examined by testing the effects of a glutamate AMPA receptor antagonist on operant EtOH self-administration.ResultsFemale C57BL/6J mice exhibited a time-dependent escalation in EtOH intake under both continuous and limited access conditions. They were less sensitive to EtOH sedation and had lower blood levels post-EtOH administration (4 g/kg) despite similar clearance rates. Females also showed increased operant EtOH self-administration and progressive ratio performance over a 30-day baseline period compared to males. The AMPAR antagonist GYKI 52466 (0–10 mg/kg, IP) dose-dependently reduced EtOH-reinforced lever pressing in both sexes, with no differences in potency or efficacy.DiscussionThese findings confirm that female C57BL/6J mice consume more EtOH than males in home-cage conditions and exhibit reduced acute sedation, potentially contributing to higher EtOH intake. Females demonstrated increased operant EtOH self-administration and motivation, indicating higher reinforcing efficacy. The lack of sex differences in the relative effects of GYKI 52466 suggests that AMPAR activity is equally required for EtOH reinforcement in both sexes.