Browsing by Author "Lei, Kelly"

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    Differential importance of nucleus accumbens Ox1Rs and AMPARs for female and male mouse binge alcohol drinking
    (Springer Nature, 2021-01-08) Kwok, Claudina; Lei, Kelly; Pedrozo, Vincent; Anderson, Lexy; Ghotra, Shahbaj; Walsh, Margaret; Li, Laura; Yu, JiHwan; Hopf, Frederic Woodward; Psychiatry, School of Medicine
    Alcohol use disorder exhausts substantial social and economic costs, with recent dramatic increases in female problem drinking. Thus, it is critically important to understand signaling differences underlying alcohol consumption across the sexes. Orexin-1 receptors (Ox1Rs) can strongly promote motivated behavior, and we previously identified Ox1Rs within nucleus accumbens shell (shell) as crucial for driving binge intake in higher-drinking male mice. Here, shell Ox1R inhibition did not alter female mouse alcohol drinking, unlike in males. Also, lower dose systemic Ox1R inhibition reduced compulsion-like alcohol intake in both sexes, indicating that female Ox1Rs can drive some aspects of pathological consumption, and higher doses of systemic Ox1R inhibition (which might have more off-target effects) reduced binge drinking in both sexes. In contrast to shell Ox1Rs, inhibiting shell calcium-permeable AMPA receptors (CP-AMPARs) strongly reduced alcohol drinking in both sexes, which was specific to alcohol since this did not reduce saccharin intake in either sex. Our results together suggest that the shell critically regulates binge drinking in both sexes, with shell CP-AMPARs supporting intake in both sexes, while shell Ox1Rs drove drinking only in males. Our findings provide important new information about sex-specific and -general mechanisms that promote binge alcohol intake and possible targeted therapeutic interventions.
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    Nucleus Accumbens Shell Orexin-1 Receptors Are Not Needed For Single-Bottle Limited Daily Access Alcohol Intake in C57BL/6 mice
    (Elsevier, 2020-12) Lei, Kelly; Kwok, Claudina; Hopf, Frederic W.; Psychiatry, School of Medicine
    Excessive, binge drinking is a major contributor to the great harm and cost of alcohol use disorder. We recently showed, using both limited and intermittent-access two-bottle-choice models, that inhibiting nucleus accumbens shell (Shell) orexin-1-receptors (Ox1Rs) reduces alcohol intake in higher-drinking male C57BL/6 mice (Lei et al., 2019). Other studies implicate Ox1Rs, tested systemically, for several higher-drinking models, including the single-bottle, Rhodes Drinking-in-the-Dark paradigm. Here, we report studies examining whether Shell Ox1Rs contribute to alcohol intake in male mice using a single-bottle Limited Daily Access (LDA) drinking model modified from drinking-in-the-dark paradigms (2-h access starting 3 h into the dark cycle, 5 days per week). In addition, some previous work has suggested possible differences in circuitry for one- versus two-choice behaviors, and thus other mice first drank under a single-bottle schedule, and then an additional water bottle was included 2 days a week starting in week 3. Surprisingly, at the same time we were determining Ox1R importance for two-bottle-choice models, parallel studies found that inhibiting Shell Ox1Rs had no impact on drinking using the single-bottle LDA model, or when a second bottle containing water was added later during drinking. Furthermore, we have related Shell Ox1R regulation of intake to basal consumption, but no such pattern was observed with single-bottle LDA drinking. Thus, unlike our previous work showing the importance of Shell Ox1Rs for male alcohol drinking under several two-bottle-choice models, Shell Ox1Rs were not required under a single-bottle paradigm, even if a second water-containing bottle was later added. These results raise the speculations that different mechanisms could promote intake under single- versus two-bottle access conditions, and that the conditions under which an animal learns to drink can impact circuitry driving future intake.
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    The role of anterior insula-brainstem projections and alpha-1 noradrenergic receptors for compulsion-like and alcohol-only drinking
    (Springer Nature, 2021) De Oliveira Sergio, Thatiane; Lei, Kelly; Kwok, Claudina; Ghotra, Shahbaj; Wegner, Scott A.; Walsh, Margaret; Waal, Jaclyn; Darevsky, David; Hopf, Frederic W.; Psychiatry, School of Medicine
    Compulsion-like alcohol drinking (CLAD), where consumption continues despite negative consequences, is a major obstacle to treating alcohol use disorder. The locus coeruleus area in the brainstem and norepinephrine receptor (NER) signaling in forebrain cortical regions have been implicated in adaptive responding under stress, which is conceptually similar to compulsion-like responding (adaptive responding despite the presence of stress or conflict). Thus, we examined whether anterior insula (aINS)-to-brainstem connections and alpha-1 NERs regulated compulsion-like intake and alcohol-only drinking (AOD). Halorhodopsin inhibition of aINS-brainstem significantly reduced CLAD, with no effect on alcohol-only or saccharin intake, suggesting a specific aINS-brainstem role in aversion-resistant drinking. In contrast, prazosin inhibition of alpha-1 NERs systemically reduced both CLAD and AOD. Similar to systemic inhibition, intra-aINS alpha-1-NER antagonism reduced both CLAD and AOD. Global aINS inhibition with GABAR agonists also strongly reduced both CLAD and AOD, without impacting saccharin intake or locomotion, while aINS inhibition of calcium-permeable AMPARs (with NASPM) reduced CLAD without impacting AOD. Finally, prazosin inhibition of CLAD and AOD was not correlated with each other, systemically or within aINS, suggesting the possibility that different aINS pathways regulate CLAD versus AOD, which will require further study to definitively address. Together, our results provide important new information showing that some aINS pathways (aINS-brainstem and NASPM-sensitive) specifically regulate compulsion-like alcohol consumption, while aINS more generally may contain parallel pathways promoting CLAD versus AOD. These findings also support the importance of the adaptive stress response system for multiple forms of alcohol drinking.