Even after accounting for lack of physical activity and genetic susceptibility, excessive food energy intake remains, probably, the most common cause of overweight and obesity in western countries. Unfortunately, the expanding adipose tissue experiences an abnormal infiltration of circulating leukocytes, a phenomenon that occurs in the microcirculation and it is associated with adipose tissue inflammation and insulin resistance. The precise cellular and molecular mechanisms that initiate and govern leukocyte extravasation in the microcirculation of expanding adipose depots remain undefined. Consequently, whether leukocyte infiltration is the cause or the effect of adipocyte dysfunction remains largely unknown, which hinders therapeutic interventions in the ever-growing obese population of the USA. Emerging information in the literature and new preliminary data presented in this application demonstrate that nutrients overload causes a postprandial infiltration of neutrophils in visceral fat depots. Obviously, this acute response to dietary nutrients occurs well before weight gain and insulin resistance. Accordingly, we propose to test the hypothesis that nutrients overload acutely activates leukocyte-endothelium interactions in the microcirculation of the visceral fat and that this process initiates adipocyte dysfunction. The overall goals of this projet are to study: a) the mechanisms by which nutrients overload triggers this rapid activation of neutrophils in the adipose tissue microcirculation; b) the cellular and molecular determinants that make the microcirculation of visceral fat depots highly responsive to nutrients overload; c) the impact of this phenomenon on adipocyte homeostasis. To implement these studies, we will utilize knockout and transgenic mouse technology along with the following biochemistry and physiology techniques: western blot analysis, immunohistochemistry and immunofluorescence, cells and tissue isolation techniques, intravital microscopy, nitric oxide measurements. We hope that the results of this work will advance our understanding of the integrated mechanisms that initiate and maintain adipose tissue inflammation and related metabolic disorders.
Obesity has become a major health challenge facing the US population. Obesity is associated with infiltration of circulating leukocytes cells into visceral ft depots. The inflamed adipose tissue becomes dysfunctional, produced cytokines, and contributes to insulin resistance, diabetes, cardiovascular disease, cancer and arthritis, whose incidence is gaining. All of these complications of obesity have been widely linked to inflammation. Even after accounting for lack of physical activity and genetic susceptibility, excessive food energy intake remains probably, the most common cause of obesity in western countries. This proposal focuses on newly discovered evidence indicating that consumption of obesogenic high-fat food rapidly activates primary inflammatory responses in the microcirculation of the visceral fat, a process that might provide new insights into the mechanisms that cause adipose tissue inflammation and related complications in obesity. Overall, this research will uncover novel mechanisms of adipose tissue inflammation in obesity and it will provide a framework for developing new therapeutic strategies to avert complications in the obese population of the USA.
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