Abstract
ObjectiveThe vagus nerve provides a direct line of communication between the gut and the brain for proper regulation of energy balance and glucose homeostasis. Short-chain fatty acids (SCFAs) produced via gut microbiota fermentation of dietary fiber have been proposed to regulate host metabolism and feeding behavior via the vagus nerve, but the molecular mechanisms have not yet been elucidated. We sought to identify the G-protein-coupled receptors within vagal neurons that mediate the physiological and therapeutic benefits of SCFAs. MethodsSCFA, particularly propionate, signaling occurs via free fatty acid receptor 3 (FFAR3), that we found expressed in vagal sensory neurons innervating throughout the gut. The lack of cell-specific animal models has impeded our understanding of gut/brain communication; therefore, we generated a mouse model for cre-recombinase-driven deletion of Ffar3. We comprehensively characterized the feeding behavior of control and vagal-FFAR3 knockout (KO) mice in response to various conditions including fasting/refeeding, western diet (WD) feeding, and propionate supplementation. We also utilized ex vivo organotypic vagal cultures to investigate the signaling pathways downstream of propionate FFAR3 activation. ResultsVagal-FFAR3KO led to increased meal size in males and females, and increased food intake during fasting/refeeding and WD challenges. In addition, the anorectic effect of propionate supplementation was lost in vagal-FFAR3KO mice. Sequencing approaches combining ex vivo and in vivo experiments revealed that the cross-talk of FFAR3 signaling with cholecystokinin (CCK) and leptin receptor pathways leads to alterations in food intake. ConclusionAltogether, our data demonstrate that FFAR3 expressed in vagal neurons regulates feeding behavior and mediates propionate-induced decrease in food intake.
Highlights
Rates of obesity and the associated metabolic diseases/disorders continue to rise, and new treatment strategies and dietary interventions are needed to combat this epidemic [1,2]
Sequencing approaches combining ex vivo and in vivo experiments revealed that the cross-talk of free fatty acid receptor 3 (FFAR3) signaling with cholecystokinin (CCK) and leptin receptor pathways leads to alterations in food intake
We show for the first time that vagal neuron expression of Ffar3 is necessary for normal feeding behavior, and genetic deletion of this short-chain fatty acids (SCFAs)-binding receptor eliminates the positive benefits of propionate supplementation on energy balance
Summary
Rates of obesity and the associated metabolic diseases/disorders continue to rise, and new treatment strategies and dietary interventions are needed to combat this epidemic [1,2]. Gutmicrobiota fermentation of dietary fiber produces short-chain fatty acids (SCFAs), which have been proposed to improve host metabolic health through various mechanisms [6,7], including lowering food intake via the vagus nerve [8,9]. The vagus nerve (cranial X) connects the brain and the visceral organs, providing a bidirectional line of communication to control homeostatic functions, including feeding [13]. The majority of vagal neurons are sensory (afferents), with cell bodies located in the nodose ganglia (NG). Vagal sensing of meal size, caloric content, gastrointestinal (GI) hormones, and nutrient composition fine-tunes an appropriate physiological and behavioral response to a meal [14e16].
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