A gut-restricted lithocholic acid analog as an inhibitor of gut bacterial bile salt hydrolases

Adhikari, Arijit A.; Ramachandran, Deepti; Chaudhari, Snehal N.; Powell, Chelsea E.; McCurry, Megan D.; Banks, Alexander S.; Devlin, A. Sloan

doi:10.1101/2021.03.15.435552

2021

DOI: 10.1101/2021.03.15.435552

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A gut-restricted lithocholic acid analog as an inhibitor of gut bacterial bile salt hydrolases

Arijit A. Adhikari

Deepti Ramachandran

Snehal N. Chaudhari

et al.

Abstract: Bile acids play crucial roles in host physiology by acting as both detergents that aid in digestion and as signaling molecules that bind to host receptors. Gut bacterial bile salt hydrolase (BSH) enzymes perform the gateway reaction leading to the conversion of host-produced primary bile acids into bacterially modified secondary bile acids. Small molecule probes that target BSHs will help elucidate the causal roles of these metabolites in host physiology. We previously reported the development of a covalent BS… Show more

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Cited by 2 publications

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Inhibition of microbial deconjugation of micellar bile acids protects against intestinal permeability and liver injury

Sojoodi

et al. 2021

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Background & Aims: While altered host-microbe interactions are implicated in non-alcoholic fatty liver disease/non-alcoholic steatohepatitis (NAFLD/NASH), specific contributions of microbially derived metabolites remain obscure. We investigated the impact of altered bile acid (BA) populations on intestinal and hepatic phenotypes in a rodent model of NAFLD/NASH. Methods: Wistar rats fed a choline-deficient high-fat diet (CDAHFD) were assessed for altered intestinal permeability after dietary intervention. Cecal and portal venous BA composition were assessed via mass spectrometry. BA-mediated effects on epithelial permeability were assessed using Caco2 epithelial monolayers. Micelle formation was assessed using fluorescent probes and electron microscopy. Bile salt hydrolase (BSH) activity was inhibited with a gut-restricted small molecule in CDAHFD-fed rats and intestinal and hepatic phenotypes were assessed. Results: Increased intestinal permeability and reduced intestinal conjugated BAs were early phenotypes of CDAHFD-fed rats preceding hepatic disease development. Similar intestinal BA pool changes were observed in rats and human NAFLD/NASH patients with progressive disease. Conjugated BAs protected epithelial layers from unconjugated BA-induced damage via mixed micelle formation. The decrease in intestinal conjugated BAs was mediated by increased activity of bacterial BSHs and inhibition of BSH activity prevented the development of pathologic intestinal permeability and hepatic inflammation in the NAFLD/NASH model. Conclusions: Conjugated BAs are important for the maintenance of intestinal barrier function by sequestering unconjugated BAs in mixed micelles. Increased BSH activity reduces intestinal conjugated BA abundance, in turn increasing intestinal permeability and susceptibility to the development of NAFLD/NASH. These findings suggest that interventions that shift the intestinal bile acid pool toward conjugated BAs could be developed as therapies for NAFLD/NASH.

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Inhibition of microbial deconjugation of micellar bile acids protects against intestinal permeability and liver injury

Sojoodi

et al. 2021

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Phenotypic high-throughput screening identifies modulators of gut microbial choline metabolism

Woo,

Sandoval–Espinola,

Bollenbach

et al. 2024

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Anaerobic metabolism of dietary choline to trimethylamine (TMA) by the human gut microbiome is a disease-associated pathway. The host's impaired ability to oxidize TMA to trimethylamine-N-oxide (TMAO) results in trimethylaminuria (TMAU), while elevated serum TMAO levels have been positively correlated with cardiometabolic disease. Small molecule inhibition of gut bacterial choline metabolism attenuates the development of disease in mice, highlighting the therapeutic potential of modulating this metabolism. Inhibitors previously developed to target this pathway are often designed to mimic choline, the substrate of the key TMA-generating enzyme choline–trimethylamine lyase (CutC). Here, we use a growth-based phenotypic high-throughput screen and medicinal chemistry to identify distinct chemical scaffolds that can modulate anaerobic microbial choline metabolism and lower TMAO levels in vivo. These results illustrate the potential of using phenotypic screening to rapidly discover new inhibitors of gut microbial metabolic activities.

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A gut-restricted lithocholic acid analog as an inhibitor of gut bacterial bile salt hydrolases

Cited by 2 publications

References 42 publications

Inhibition of microbial deconjugation of micellar bile acids protects against intestinal permeability and liver injury

Inhibition of microbial deconjugation of micellar bile acids protects against intestinal permeability and liver injury

Phenotypic high-throughput screening identifies modulators of gut microbial choline metabolism

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