AgRP neurons coordinate the mitigation of activity-based anorexia.
Ames K Sutton HickeySean C DuaneLaura E MickelsenEva O KarolczakAhmed M ShammaAnna SkillingsChia LiMichael J KrashesPublished in: Molecular psychiatry (2022)
Anorexia nervosa (AN) is a debilitating and deadly disease characterized by low body mass index due to diminished food intake, and oftentimes concurrent hyperactivity. A high percentage of AN behavioral and metabolic phenotypes can be replicated in rodents given access to a voluntary running wheel and subject to food restriction, termed activity-based anorexia (ABA). Despite the well-documented bodyweight loss observed in AN human patients and ABA rodents, much less is understood regarding the neurobiological underpinnings of these maladaptive behaviors. Hunger-promoting hypothalamic agouti-related peptide (AgRP) neurons have been well characterized in their ability to regulate appetite, yet much less is known regarding their activity and function in the mediation of food intake during ABA. Here, feeding microstructure analysis revealed ABA mice decreased food intake due to increased interpellet interval retrieval and diminished meal number. Longitudinal activity recordings of AgRP neurons in ABA animals exhibited a maladaptive inhibitory response to food, independent of basal activity changes. We then demonstrated that ABA development or progression can be mitigated by chemogenetic AgRP activation through the reprioritization of food intake (increased meal number) over hyperactivity, but only during periods of food availability. These results elucidate a potential neural target for the amelioration of behavioral maladaptations present in AN patients.
Keyphrases
- transcription factor
- arabidopsis thaliana
- body mass index
- end stage renal disease
- ejection fraction
- newly diagnosed
- spinal cord
- peritoneal dialysis
- anorexia nervosa
- prognostic factors
- squamous cell carcinoma
- physical activity
- endothelial cells
- climate change
- type diabetes
- patient reported outcomes
- spinal cord injury
- human health
- risk assessment
- multiple sclerosis
- white matter
- single cell
- adipose tissue
- weight gain
- weight loss
- high intensity
- cross sectional
- patient reported