Abstract
The nuclear receptor FXR acts as an intracellular bile salt sensor that regulates synthesis and transport of bile salts within their enterohepatic circulation. In addition, FXR is involved in control of a variety of crucial metabolic pathways. Four FXR splice variants are known, i.e. FXRα1-4. Although these isoforms show differences in spatial and temporal expression patterns as well as in transcriptional activity, the physiological relevance hereof has remained elusive. We have evaluated specific roles of hepatic FXRα2 and FXRα4 by stably expressing these isoforms using liver-specific self-complementary adeno-associated viral vectors in total body FXR knock-out mice. The hepatic gene expression profile of the FXR knock-out mice was largely normalized by both isoforms. Yet, differential effects were also apparent; FXRα2 was more effective in reducing elevated HDL levels and transrepressed hepatic expression of Cyp8b1, the regulator of cholate synthesis. The latter coincided with a switch in hydrophobicity of the bile salt pool. Furthermore, FXRα2-transduction caused an increased neutral sterol excretion compared to FXRα4 without affecting intestinal cholesterol absorption. Our data show, for the first time, that hepatic FXRα2 and FXRα4 differentially modulate bile salt and lipoprotein metabolism in mice.
Highlights
Bile salts are synthesized from cholesterol by well-characterized biosynthetic pathways
Compared to PBS-injected controls, plasma aspartate aminotransferase (ASAT) and alanine aminotransferase (ALAT) levels were unchanged in particle-injected mice, implying that stable Self-complementary AAV (scAAV) transduction did not negatively impact on liver cell integrity (Fig. 1C/D)
Our data demonstrate that FXRa2 and FXRa4 differentially affect transcriptional control of bile salt and lipoprotein metabolism in mice
Summary
Bile salts are synthesized from cholesterol by well-characterized biosynthetic pathways (see [1] for review). The chemical diversity of bile salts is further expanded by conjugation to either taurine or glycine and by the actions of intestinal bacteria via deconjugation, oxidation of hydroxyl groups and dehydroxylation, creating a bile salt pool with specific physiochemical properties. In addition to their wellestablished functions in generation of bile formation by the liver and absorption of dietary fats and fat-soluble vitamins from the intestine, bile salts are recognized to act as ‘integrators of metabolism’ [1, 2]
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