BACKGROUND
Chronic exposure to stress or alcohol can drive neuroadaptations that alter cognition. Alterations in cognition may contribute to alcohol use disorders by reducing cognitive control over drinking and maintenance of abstinence. Here we examined effects of combined ethanol and stress exposure on prefrontal cortex (PFC)-dependent cognition.
METHODS
Adult male C57BL/6J mice were trained to drink ethanol (15%, v/v) on a 1hr/day 1-bottle schedule. Once stable, mice were exposed to cycles of chronic intermittent ethanol (CIE) or air-control vapor exposure (Air), followed by test cycles of 1hr/day ethanol drinking. During test drinking mice received no-stress (NS) or 10 minutes of forced swim stress (FSS) 4 hours before each test. This schedule produced four experimental groups: control, Air/NS; ethanol-dependent no stress, CIE/NS; non-dependent stress, Air/FSS; or ethanol-dependent stress, CIE/FSS. After two cycles of CIE and FSS exposure we assessed PFC-dependent cognition using object/context recognition and attentional set-shifting. At the end of the study mice were perfused and brains collected for measurement of c-Fos activity in PFC and locus coeruleus (LC).
RESULTS
CIE/FSS mice escalated ethanol intake faster than CIE/NS and consumed more ethanol than Air/NS across all test cycles. After two cycles of CIE/FSS, mice showed impairments in contextual learning and extra-dimensional set shifting relative to other groups. In addition to cognitive dysfunction, CIE/FSS mice demonstrated widespread reductions in c-Fos activity within prelimbic and infralimbic PFC as well as LC.
CONCLUSION
Together, these findings show that interactions between ethanol and stress exposure rapidly lead to disruptions in signaling across cognitive networks and impairments in PFC-dependent cognitive function.
Rodent premotor cortex (M2) integrates information from sensory and cognitive networks for action selection and planning during goal-directed decision making. M2 function is regulated by cortical inputs and ascending neuromodulators, including norepinephrine (NE) released from the locus coeruleus (LC). LC-NE has been shown to modulate the signal to noise ratio of neural representations in target regions prior to decision execution, to increase the salience of relevant stimuli. Using rats performing a two-alternative forced choice task after administration of an adrenergic antagonist (propranolol), we show that action planning in M2 is mediated by adrenergic signaling. Loss of adrenergic signaling results in failure to suppress irrelevant action plans in M2 that disrupts decoding of cue related information, delays decision times, and increases trial omissions, particularly in females. Furthermore, we identify a potential mechanism for the sex bias in behavioral and neural changes after propranolol administration via differential expression of receptors across sexes, particularly on local inhibitory neurons. Overall, we show a critical role for adrenergic signaling in M2 during decision making by suppressing irrelevant information to enable efficient action planning and decision execution.
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