N-acetyl-phenylalanine induces hepatic steatosis in MASLD by disrupting ER-mitochondria calcium coupling and mitochondrial lipid oxidation

  1. Rémy Lefebvre
  2. Théo Rousseaux
  3. Nadia Bendridi
  4. Stéphanie Chanon
  5. Delphine Arquier
  6. Alexandre Humbert
  7. Nicolas Bertocchini
  8. Bruno Pillot
  9. Emmanuelle Meugnier
  10. Aurélie Vieille-Marchiset
  11. Margaux Nawrot
  12. Claudie Pinteur
  13. Sophie Ayciriex
  14. Rohit Loomba
  15. Jennifer Rieusset
  16. Cyrielle Caussy
Read the full article See related articles

Discuss this preprint

Start a discussion What are Sciety discussions?

Listed in

This article is not in any list yet, why not save it to one of your lists.
Log in to save this article

Abstract

Background & Aims

The gut-liver axis and hepatic ER-mitochondria miscommunication (at contact sites called MAMs) are involved in the development of metabolic dysfunction-associated steatotic liver disease (MASLD). We investigated the role of circulating aromatic amino acids (AAA) derived from phenylalanine and tyrosine in MASLD potentially through MAM alterations.

Methods

We analyzed AAA metabolomic profiles in individuals with and without MASLD and validated findings in a biopsy-proven cohort. The pro-steatogenic effect of MASLD-associated AAAs was validated in vitro using lipid labeling, MAM structural/functional assays, and palmitate-induced respiration. In vivo effects were tested in mice fed with candidate AAAs, and MAM involvement was confirmed by expressing a specific organelle linker in vitro and in vivo .

Results

N-acetyl-phenylalanine (NAPA) was strongly associated with hepatic steatosis and correlated with specific gut microbes. In vitro , NAPA promoted lipid accumulation by impairing ER-mitochondria calcium exchange via a LAT1-dependent electrogenic mechanism, reducing mitochondrial lipid oxidation. Chronic NAPA administration in mice induced steatosis and MAM disruption. Notably, enhancing ER-mitochondria contacts with an organelle linker prevented NAPA-induced steatosis in vitro and in vivo . Additionally, other phenylalanine- and tyrosine-derived AAAs reproduced NAPA’s effects, suggesting a class-dependent mechanism.

Conclusion

NAPA emerges as a MASLD-promoting metabolite, contributing to hepatic steatosis by disrupting ER-mitochondria calcium coupling and mitochondrial lipid oxidation.

Lay Summary

The gut-liver axis is a key component of the development of MASLD, and circulating gut-derived metabolites, notably AAAs derived from phenylalanine and tyrosine metabolism, have been associated with MASLD. However, the specific causal mechanisms of these AAA metabolites in MASLD development remain unexplored. Here, we identified NAPA, a gut microbiome linked metabolite elevated in MASLD patients, as a causal driver of hepatic steatosis both in vitro and in vivo. Mechanistically, NAPA alters ER-mitochondria calcium coupling leading to reduced mitochondrial lipid oxidation, highlighting a new mechanism with potential therapeutic implications.

HIGHLIGHTS

  • - Circulating NAPA levels are increased in MASLD patients and correlate with hepatic steatosis.

  • - NAPA levels result from a complex host-microbiota interplay

  • - NAPA induces lipid accumulation by dampening ER-mitochondria calcium coupling and mitochondrial lipid oxidation.

  • - NAPA disrupts MAMs by a LAT1-mediated electrogenic mechanism.

  • - Other Phe- and Tyr-mediated metabolites have the same pro-steatogenic effect than NAPA pointing to a class-dependent effect.

    • Article activity feed

    1. Version published to 10.1101/2025.09.24.678188 on bioRxiv