Neuropeptide Y Signaling in the Lateral Hypothalamus Modulates Diet Component Selection and is Dysregulated in a Model of Diet-Induced Obesity.

The preclinical multicomponent free-choice high-fat high-sucrose (fcHFHS) diet has strong validity to model diet-induced obesity (DIO) and associated maladaptive molecular changes in the central nervous system. fcHFHS-induced obese rats demonstrate increased sensitivity to intracerebroventricular infusion of the orexigenic Neuropeptide Y (NPY). The brain region-specific effects of NPY signaling on fcHFHS diet component selection are not completely understood. For example, fcHFHS-fed rats have increased intake of chow and fat following intracerebroventricular NPY infusion, whereas NPY administration in the nucleus accumbens, a key hub of the reward circuitry, specifically increases fat intake. Here, we investigated whether NPY infusion in the lateral hypothalamic area (LHA), which is crucially involved in the regulation of intake, regulates fcHFHS component selection, and if LHA NPY receptor subtypes 1 or 5 (NPYR1/5) are involved. Male Wistar rats were fed a chow or fcHFHS diet for at least seven days, and received intra-LHA vehicle or NPY infusions in a cross-over design. Diet component intake was measured two hours later. Separate experimental designs were used to test the efficacy of NPY1R- or NPY5R antagonism to prevent the orexigenic effects of intra-LHA NPY. Intra-LHA NPY increased caloric intake in chow- and fcHFHS-fed rats. This effect was mediated specifically by chow intake in fcHFHS-fed rats. The orexigenic effects of intra-LHA NPY were prevented by NPY1R and NPY5R antagonism in chow-fed rats, but only by NPY5R antagonism in fcHFHS-fed rats. Thus, NPY signaling has brain region-specific effects on fcHFHS component selection and LHA NPYR sensitivity is dysregulated during consumption of a fcHFHS diet.

Neuropeptide Y and leptin sensitivity is dependent on diet composition.

Rats on different free-choice (fc) diets for 1 week of either chow, saturated fat and liquid sugar (fcHFHS), chow and saturated fat (fcHF), or chow and liquid sugar (fcHS) have differential levels of neuropeptide Y (NPY) mRNA in the arcuate nucleus. Because these differences were not explained by plasma leptin levels but did predict subsequent feeding behaviour, in the present study, we first examined whether leptin sensitivity could explain these differences. Second, we focused on the role of NPY on feeding behaviour, and measured NPY mRNA levels and sensitivity to NPY after 4 weeks on the different choice diets. To determine leptin sensitivity, we measured food intake after i.p. leptin or vehicle injections in male Wistar rats subjected to the fcHFHS, fcHS, fcHF or Chow diets for 7 days. Next, we measured levels of arcuate nucleus NPY mRNA with in situ hybridisation in rats subjected to the choice diets for 4 weeks. Finally, we studied NPY sensitivity in rats subjected to the fcHFHS, fcHS, fcHF or Chow diet for 4 weeks by measuring food intake after administration of NPY or vehicle in the lateral ventricle. Leptin decreased caloric intake in rats on Chow, fcHS and fcHF but not in rats on the fcHFHS diet. After 4 weeks, rats on the fcHFHS diet remained hyperphagic, whereas fcHS and fcHF rats decreased caloric intake to levels similar to rats on Chow. By contrast to 1 week, after 4 weeks, levels of NPY mRNA were not different between the diet groups. Lateral ventricle administration of NPY resulted in higher caloric intake in fcHFHS rats compared to rats on the other choice diets or rats on Chow. Our data show that consuming a combination of saturated fat and liquid sugar results in leptin resistance and increased NPY sensitivity that is associated with persistent hyperphagia.