A fundamental bimodal role for neuropeptide Y1 receptor in the immune system

Psychological conditions, including stress, compromise immune defenses. Although this concept is not novel, the molecular mechanism behind it remains unclear. Neuropeptide Y (NPY) in the central nervous system is a major regulator of numerous physiological functions, including stress. Postganglionic sympathetic nerves innervating lymphoid organs release NPY, which together with other peptides activate five Y receptors (Y1, Y2, Y4, Y5, and y6). Using Y1-deficient (Y1−/−) mice, we showed that Y1−/− T cells are hyperresponsive to activation and trigger severe colitis after transfer into lymphopenic mice. Thus, signaling through Y1 receptor on T cells inhibits T cell activation and controls the magnitude of T cell responses. Paradoxically, Y1−/− mice were resistant to T helper type 1 (Th1) cell–mediated inflammatory responses and showed reduced levels of the Th1 cell–promoting cytokine interleukin 12 and reduced interferon γ production. This defect was due to functionally impaired antigen-presenting cells (APCs), and consequently, Y1−/− mice had reduced numbers of effector T cells. These results demonstrate a fundamental bimodal role for the Y1 receptor in the immune system, serving as a strong negative regulator on T cells as well as a key activator of APC function. Our findings uncover a sophisticated molecular mechanism regulating immune cell functions that can lead to stress-induced immunosuppression

The role of PYY in regulating energy balance and glucose homeostasis

Peptide YY (PYY) is a gut-derived hormone that is renowned for its effects on satiety. Reduced satiety in obese people has been attributed to low fasting and postprandial PYY levels. However, it has not been determined whether low PYY levels are the cause or the outcome of obesity. Moreover, the long-term role of PYY in regulating energy balance is unclear.Results presented in this thesis, using PYY-deficient mice (PYY-/-) and PYY transgenic mice (PYYtg) highlight that PYY indeed has an important role in regulating energy balance and glucose homeostasis in vivo. PYY knockout mice became obese with ageing or high-fat feeding linked to a hyperinsulinemic phenotype associated with hypersecretion of insulin from isolated pancreatic islets. These findings suggested that PYY deficiency may be a predisposing factor for the development of obesity and type 2 diabetes. On the other hand, PYYtg mice exhibited decreased adiposity and increased metabolism under high-fat feeding. Furthermore, PYYtg/ob mice had improved glucose tolerance and decreased adiposity. These latter studies suggested that high circulating PYY levels may protect against the development of obesity and type 2 diabetes. Interestingly, both animal models support PYY as an important regulator of the somatotropic axis. These preliminary findings prompted investigations in understanding whether low PYY levels may be a predisposing factor for the development of obesity and type 2 diabetes in human subjects. In a population of healthy human subjects that had a predisposition to the development of type 2 diabetes and obesity, fasting PYY levels were lower than in normal subjects. Moreover, low fasting PYY levels strongly correlated with decreased insulin sensitivity and high levels of fasting insulin. Collectively, these findings suggest that low circulating levels of PYY could contribute to increased adiposity, insulin resistance and type 2 diabetes. Therefore determination of PYY levels may be a method of detecting whether people are predisposed to becoming obese and insulin resistant. This work also suggests that treatments that enhance circulating PYY levels may be protective in the development of obesity and type 2 diabetes

Y2Y4 receptor double knockout protects against obesity due to a high-fat diet or Y1 receptor deficiency in mice

Neuropeptide Y receptors are critical regulators of energy homeostasis, but the functional interactions and relative contributions of Y receptors and the environment in this process are unknown. We measured the effects of an ad libitum diet of normal or high-fat food on energy balance in mice with single, double, or triple deficiencies of Y1, Y2, or Y4 receptors. Whereas wild-type mice developed diet-induced obesity, Y2Y4 double knockouts did not. In contrast, Y1 knockout or Y1Y2 or Y1Y4 receptor double knockout mice developed an exacerbated diet-induced obesity syndrome. Remarkably, the antiobesity effect of Y2Y4 deficiency was stronger than the obesogenic effect of Y1 deficiency, since Y1Y2Y4 triple knockouts did not develop obesity on the high-fat diet. Resistance to diet-induced obesity in Y2Y4 knockouts was associated with reduced food intake and improved glucose tolerance in the absence of changes in total physical activity. Fecal concentration of free fatty acids was significantly increased in Y2Y4 knockouts in association with a significantly reduced bile acid pool and marked alterations in intestinal morphology. In addition, hypothalamic proopiomelanocortin expression was decreased in diet-induced obesity (in both wild-type and Y1 receptor knockout mice) but not in obesity-resistant Y2Y4 receptor knockout mice fed a high-fat diet. Therefore, deletion of Y2 and Y4 receptors synergistically protects against diet-induced obesity, at least partially via changes in food intake and hypothalamic proopiomelanocortin expression