The regulation of tissue-specific farnesoid X receptor on genes and diseases involved in bile acid homeostasis - 11/11/23
Abstract |
Bile acids (BAs) facilitate the absorption of dietary lipids and vitamins and have also been identified as signaling molecules involved in regulating their own metabolism, glucose and lipid metabolism, as well as immunity. Disturbances in BA homeostasis are associated with various enterohepatic and metabolic diseases, such as cholestasis, nonalcoholic steatohepatitis, inflammatory bowel disease, and obesity. As a key regulator, the nuclear orphan receptor farnesoid X receptor (FXR, NR1H4) precisely regulates BA homeostasis by transcriptional regulation of genes involved in BA synthesis, metabolism, and enterohepatic circulation. FXR is widely regarded as the most potential therapeutic target. Obeticholic acid is the only FXR agonist approved to treat patients with primary biliary cholangitis, but its non-specific activation of systemic FXR also causes high-frequency side effects. In recent years, developing tissue-specific FXR-targeting drugs has become a research highlight. This article provides a comprehensive overview of the role of tissue-specific intestine/liver FXR in regulating genes involved in BA homeostasis and briefly discusses tissue-specific FXR as a therapeutic target for treating diseases. These findings provide the basis for the development of tissue-specific FXR modulators for the treatment of enterohepatic and metabolic diseases associated with BA dysfunction.
Le texte complet de cet article est disponible en PDF.Graphical Abstract |
Highlights |
• | FXR is essential for BA homeostasis by regulating genes involved in BA synthesis, metabolism, and transport. |
• | Both liver and intestine FXR modulate the inhibition of hepatic BA synthesis. |
• | FXR regulates BA metabolism mediated by host enzymes and microbiome in the liver and gut. |
• | FXR modulates BA enterohepatic transport by regulating gut-liver BA transporters. |
• | Tissue-specific FXR could be a therapeutic target for precision therapy. |
Abbreviations : AABAs, ALD, ASBT, BA, BAAT, BACS, BDL, BSEP, BRIC, BSH, CA, CAR, CDCA, CRC, CYP3A4, CYP27a1, CYP7a1, CYP7b1, CYP8b1, DCA, EGFR, ERK, FGF19/15, FGFR4, FTF, FXR, FXRE, HNF4α, JNK, IBABP, IBD, ICP, IR-1, LRH-1, LCA, MAFG, MCA, MRP2–4, NAFLD, NASH, NTCP, OATPs, OCA, OSTα/β, PBC, PFIC-2, PXR, RAR, RXR, SHP, SOCS3, STAT3, SULT2A1, TαMCA, TβMCA, UDCA, UGT2B4, TGR5, VDR, ZFP36L1
Keywords : Farnesoid X receptor, Bile acids, Tissue-specific, Synthesis, Metabolism, Transporters
Plan
Vol 168
Article 115606- décembre 2023 Retour au numéro
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