Lateral hypothalamic galanin neurons are activated by stress and blunt anxiety-like behavior in mice

Despite the prevalence of anxiety disorders, the molecular identity of neural circuits underlying anxiety remains unclear. The lateral hypothalamus (LH) is one brain region implicated in the regulation of anxiety, and our recent data found that chemogenetic activation of LH galanin neurons attenuate...

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Published in:Behavioural brain research 2022-04, Vol.423, p.113773-113773, Article 113773
Main Authors: Owens-French, Joshua, Li, Shi-Bin, Francois, Marie, Leigh Townsend, R., Daniel, Mischael, Soulier, Heather, Turner, Amy, de Lecea, Luis, Münzberg, Heike, Morrison, Christopher, Qualls-Creekmore, Emily
Format: Article
Language:English
Subjects:
Animals
Anxiety
Anxiety - metabolism
Behavior, Animal - physiology
Conditioning, Classical - physiology
Disease Models, Animal
DREADD
Fear - physiology
Fiber photometry
Galanin
Galanin - metabolism
Hypothalamic Area, Lateral - metabolism
Lateral hypothalamus
Mice
Mice, Inbred C57BL
Neurons - metabolism
Stress
Stress, Psychological - metabolism
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Summary:Despite the prevalence of anxiety disorders, the molecular identity of neural circuits underlying anxiety remains unclear. The lateral hypothalamus (LH) is one brain region implicated in the regulation of anxiety, and our recent data found that chemogenetic activation of LH galanin neurons attenuated the stress response to a novel environment as measured by the marble burying test. Thus, we hypothesize that LH galanin neurons may contribute to anxiety-related behavior. We used chemogenetics and fiber photometry to test the ability of LH galanin neurons to influence anxiety and stress-related behavior. Chemogenetic activation of LH galanin neurons significantly decreased anxiety-like behavior in the elevated plus maze, open field test, and light dark test. However, LH galanin activation did not alter restraint stress induced HPA activation or freezing behavior in the fear conditioning paradigm. In vivo calcium monitoring by fiber photometry indicated that LH galanin neurons were activated by anxiogenic and/or stressful stimuli including tail suspension, novel mouse interaction, and predator odor. Further, in a fear conditioning task, calcium transients strongly increased during foot shock, but were not affected by the unconditioned stimulus tone. These data indicate that LH galanin neurons both respond to and modulate anxiety, with no influence on stress induced HPA activation or fear behaviors. Further investigation of LH galanin circuitry and functional mediators of behavioral output may offer a more refined pharmacological target as an alternative to first-line broad pharmacotherapies such as benzodiazepines.
ISSN:0166-4328
1872-7549
DOI:10.1016/j.bbr.2022.113773