5-HT NEURONS INTEGRATE NEURAL INPUTS TO REGULATE FOOD INTAKE
Baylor College Of Medicine, Houston TX
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Abstract
Obesity is a major risk factor for type II diabetes and metabolic syndromes. Increased understanding of food intake and body weight regulation may lead to effective strategies to combat obesity and diabetes. Serotonin (5-HT) neurons in the dorsal Raphe nucleus (DRN) play an essential role in regulating feeding behavior. Enhanced brain 5-HT actions robustly inhibit food intake and body weight but little is known about how firing activity of 5-HTDRN neurons is regulated. Based on pilot observations, the Xu and Tong labs put forward a general hypothesis that 5-HTDRN neurons integrate dopamine (DA) and GABA inputs to promote food intake. The first objective is to determine whether DA released by neurons in the ventral tegmental area inhibits 5-HTDRN neurons to promote food intake. In vivo optogenetic studies will be carried out to determine whether photostimulation of the DAÃDRN circuit increases food intake while photoinhibition of the same circuit inhibits eating; a DA receptor (DRD2) will be deleted in 5-HT neurons to test whether this deletion decreases food intake and body weight and block effects of DAÃDRN activation in mice. The second objective is to determine whether GABA released by neurons in the lateral hypothalamus inhibits 5-HTDRN neurons to promote food intake. Similar optogenetic studies will be carried out to determine whether photostimulation of the GABAÃDRN circuit increases food intake while photoinhibition of the same circuit inhibits eating; a GABA receptor (È2) will be deleted in 5-HT neurons to test whether this deletion decreases food intake and body weight and block effects of GABAÃDRN activation in mice. The third objective is to determine whether DA and GABA signals converge on the same or distinct subsets of 5-HTDRN neurons and whether stimulation of both DA and GABA-originated circuits produce redundant or synergistic effects on food intake. Thus, accomplishment of these experiments may advance our understanding about the physiological roles of brain 5-HT system in the regulation of feeding and energy balance, we may also identify novel targets (e.g. DRD2 and È) for therapeutic development of human diseases, e.g. obesity.
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