Investigating the Role Intestinal-Specific FXR and SHP in Regulating Lipid Metabolism in Mice

Abstract

Dysregulation of lipid metabolism is a causal factor that can lead to a variety of disorders, such as obesity and metabolic syndrome. Dietary fats are digested in the small intestine by the physiological detergents known as bile acids. They emulsify the fats and break them down into smaller molecules in order for the enterocytes to absorb the nutrients through simple diffusion or through the utilization of specific lipid transporters. Interestingly, the nuclear receptors farnesoid X receptor (FXR) and small heterodimer partner (SHP) not only regulates bile acid synthesis and circulation, but also lipid metabolism. Although many studies have examined the role of FXR in hepatic and intestinal lipid metabolism, studies investigating the role of SHP in the intestine are still lacking. Although FXR and SHP cooperate to regulate many metabolic pathways, FXR or SHP knockout models exhibit different lipid phenotypes. These data indicate there are FXR-dependent and -independent pathways of SHP that controls lipid metabolism. To delineate these two interconnecting yet separate pathways, we will utilize intestine-specific Shp knockout (IShpKO) and intestine-specific Fxr knockout (IFxrKO) mice model and place them on high fat diet to investigate their intestinal intestinal absorption and transportation of lipids. We will also monitor the bile acid pool in the intestine, serum, and liver in these knockouts to evaluate the consequence of intestinal deletion of Fxr as well as Shp on bile acid homeostasis and how this may affect lipid absorption. These experiments will identify how FXR and/or SHP regulates intestinal fat digestion and absorption and if this is secondary to the alterations in bile acid concentration and lipid transporters. In addition, we will also investigate the intestinal Fxr-Shp double knockout (IDKO) mice model to determine their combined contribution in intestinal lipid metabolism. Overall, the results obtained from this research will elucidate if intestinal FXR and SHP cooperate or can independently regulate lipid metabolism and homeostasis.