Abstract

A neural mechanism may underlie the divergent weight gain patterns of rats fed a high-energy diet; half develop diet-induced obesity (DIO), whereas the rest are diet resistant (DR). Male rats were fed chow (n = 14) or a high-energy diet for 3 mo with the development of DIO (n = 11) or DR (n = 12). DIO rats had 159-219% heavier retroperitoneal fat pads and 158% higher plasma insulin levels than chow-fed and DR rats, but plasma glucose levels were equal. Rats were trained to drink glucose after an overnight fast and were tested for local cerebral glucose utilization using 2-deoxy-D-[14C]glucose autoradiography in the presence or absence of 0.15% saccharin substituted for glucose. Saccharin intake increased 2-deoxyglucose uptake in the rostral nucleus tractus solitarius of DR but not DIO or chow-fed rats. Also, DIO rats had reduced basal 2-deoxyglucose uptake in the central amygdaloid nucleus. High-energy diet intake was associated with saccharin-induced depression of 2-deoxyglucose uptake in the inferior olive and increased utilization in the medial amygdaloid nucleus of both DR and DIO rats. Thus DIO rats have diminished basal and food-related neuronal activity in certain brain areas involved in food intake and autonomic function. Furthermore, dietary content affects glucose utilization in areas not usually associated with these functions.

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