Rifaximin stimulates nitrogen detoxification by PXR‐independent mechanisms in human small intestinal organoids

Background and Aims Recurrent hepatic encephalopathy (HE) is characterized by hyperammonaemia in combination with neuropsychiatric abnormalities and is treated with lactulose and rifaximin. Rifaximin is a pregnane X receptor (PXR) agonist with low systemic and high intestinal bioavailability. The me...

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Bibliographic Details
Published in:Liver international 2023-03, Vol.43 (3), p.649-659
Main Authors: de Wit, Koos, Beuers, Ulrich, Mukha, Anna, Stigter, Edwin C. A., Gulersonmez, M. Can, Ramos Pittol, Jose M., Middendorp, Sabine, Takkenberg, R. Bart, van Mil, Saskia W. C.
Format: Article
Language:English
Subjects:
Abnormalities
Amino Acids
Ammonia
Asparagine
Aspartate-ammonia ligase
Bioavailability
Biotransformation
Detoxification
Enterocytes
Epithelium
Gene expression
Gene sequencing
Glutaminase
Glutamine
gut–liver axis
Hepatic Encephalopathy
Humans
Intracellular
Lactulose
Metabolism
Metabolomics
Microbiomes
Nitrogen
Organoids
Pregnane X Receptor
Receptors, Steroid - genetics
Receptors, Steroid - metabolism
Rifampin
Rifamycins
Rifaximin
Scavenging
Small intestine
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Summary:Background and Aims Recurrent hepatic encephalopathy (HE) is characterized by hyperammonaemia in combination with neuropsychiatric abnormalities and is treated with lactulose and rifaximin. Rifaximin is a pregnane X receptor (PXR) agonist with low systemic and high intestinal bioavailability. The mechanisms by which it alleviates HE are unclear. We used human small intestinal (hSI) organoids to study whether rifaximin, via PXR activation, affects the epithelial biotransformation machinery, and to gain understanding of its low systemic availability. Methods We generated PXR knockdown hSI organoids via lentiviral delivery of short hairpin RNAs. Organoids were cultured for 24 h with rifaximin or rifampicin. RNA‐sequencing and metabolomics were performed to analyse gene expression and amino acid metabolism. Luminal rifaximin was quantified by photospectrometry. Results Treatment of wild‐type hSI organoids with rifaximin resulted in >twofold differential expression of 131 genes compared to DMSO. These effects were largely PXR independent and related to amino acid metabolism. Rifaximin decreased expression of glutaminase‐2 and increased expression of asparagine synthetase and solute carrier 7A11, thereby increasing intracellular glutamine and asparagine concentrations, indicating active ammonia detoxification. Rifaximin was apically excreted into the lumen in an ATP binding cassette B1 (ABCB1)‐dependent manner. Conclusions Rifaximin—after uptake into enterocytes—stimulates intracellular nitrogen detoxification by PXR‐independent mechanisms. Active apical excretion of rifaximin by ABCB1 into the intestinal lumen explains its low systemic bioavailability. Our study implies that rifaximin, next to modulation of the microbiome, has direct effects on ammonia scavenging in the human small intestinal epithelium.
ISSN:1478-3223
1478-3231
DOI:10.1111/liv.15491