Monoacylglycerol Lipase Reprograms Hepatocytes and Macrophages to Promote Liver Regeneration

Overview

Journal JHEP Rep

Specialty Gastroenterology

Date 2023 Jul 31

PMID 37520673

Authors

Manon Allaire

Rola Al Sayegh

Morgane Mabire

Adel Hammoutene

Matthieu Siebert

Charles Caer

Mathilde Cadoux

JingHong Wan

Aida Habib

Maude Le Gall

Pierre De La Grange

Herve Guillou

Catherine Postic

Valerie Paradis

Sophie Lotersztajn

Helene Gilgenkrantz

Affiliations

Soon will be listed here.

Abstract

Background & Aims: Liver regeneration is a repair process in which metabolic reprogramming of parenchymal and inflammatory cells plays a major role. Monoacylglycerol lipase (MAGL) is an ubiquitous enzyme at the crossroad between lipid metabolism and inflammation. It converts monoacylglycerols into free fatty acids and metabolises 2-arachidonoylglycerol into arachidonic acid, being thus the major source of pro-inflammatory prostaglandins in the liver. In this study, we investigated the role of MAGL in liver regeneration.

Methods: Hepatocyte proliferation was studied in hepatoma cell lines and in precision-cut human liver slices. Liver regeneration was investigated in mice treated with a pharmacological MAGL inhibitor, MJN110, as well as in animals globally invalidated for MAGL (MAGL) and specifically invalidated in hepatocytes (MAGL) or myeloid cells (MAGL). Two models of liver regeneration were used: acute toxic carbon tetrachloride injection and two-thirds partial hepatectomy. MAGL liver macrophages profiling was analysed by RNA sequencing. A rescue experiment was performed by administration of interferon receptor antibody in MAGL mice.

Results: Precision-cut human liver slices from patients with chronic liver disease and human hepatocyte cell lines exposed to MJN110 showed reduced hepatocyte proliferation. Mice with global invalidation or mice treated with MJN110 showed blunted liver regeneration. Moreover, mice with specific deletion of MAGL in either hepatocytes or myeloid cells displayed delayed liver regeneration. Mechanistically, MAGL mice showed reduced liver eicosanoid production, in particular prostaglandin E that negatively impacts on hepatocyte proliferation. MAGL inhibition in macrophages resulted in the induction of the type I interferon pathway. Importantly, neutralising the type I interferon pathway restored liver regeneration of MAGL mice.

Conclusions: Our data demonstrate that MAGL promotes liver regeneration by hepatocyte and macrophage reprogramming.

Impact And Implications: By using human liver samples and mouse models of global or specific cell type invalidation, we show that the monoacylglycerol pathway plays an essential role in liver regeneration. We unveil the mechanisms by which MAGL expressed in both hepatocytes and macrophages impacts the liver regeneration process, via eicosanoid production by hepatocytes and the modulation of the macrophage interferon pathway profile that restrains hepatocyte proliferation.

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