MTARC1 inhibition may reduce cirrhosis and hepatocellular carcinoma risk in metabolic dysfunction-associated steatotic liver disease

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medRxiv Published June 6, 2026 Medically reviewed June 6, 2026 Study authors: Gobeil, E.; Bourgault, J.; Enault, M.; Cote, V.; Mitchell, P. L.; Ruel, L.-J.; Girard, A. S.; Vohl, … DOI ↗ By Dr. Amelia Tan, PhD · Internal Medicine & Chronic Disease

Key Takeaway

Note that MTARC1 inhibition may reduce cirrhosis and hepatocellular carcinoma risk in MASLD.

This meta-analysis utilized data from 504 liver biopsies from the Quebec Obesity Biobank, comprising 16,532 MASLD cases and 1,240,188 controls. The study employed integrated proteogenomic analysis, mass spectrometry, RNA sequencing, genome-wide genotyping, Mendelian randomization, and genetic colocalization analyses to evaluate protein-disease relationships. Mendelian randomization and genetic colocalization analyses revealed that most proteins differentially expressed across MASLD stages were not causally implicated in disease risk, whereas several genetically predicted liver proteins showed evidence of causal effects.

Higher hepatic levels of the MTARC1 protein were causally associated with MASLD risk and hepatic fat accumulation. In contrast, MTARC1 inhibition may reduce the risk of cirrhosis, hepatocellular carcinoma, and cholelithiasis. Additionally, MTARC1 inhibition may improve lipid profiles. The analysis also found that eQTLs and pQTLs at other loci such as GCKR showed opposite effects on MASLD risk.

The study did not report adverse events, discontinuations, or specific follow-up durations. While the findings suggest potential therapeutic targets, the authors emphasize that these are observational associations derived from genetic data. Further clinical trials are needed to confirm these effects in human patients before changes to practice can be recommended.

Study Details

Study typeMeta analysis

EvidenceLevel 1

PublishedJun 2026

View Original Abstract ↓

Metabolic dysfunction-associated steatotic liver disease (MASLD) is rapidly increasing worldwide, yet effective targeted therapies remain limited. To better understand the molecular mechanisms underlying MASLD, we performed an integrated proteogenomic analysis of human liver tissue. Using mass spectrometry, we quantified 2,744 proteins in 504 liver biopsies from the Quebec Obesity Biobank and examined changes across disease stages. To investigate causality, we integrated liver proteomics with RNA sequencing and genome-wide genotyping to map thousands of protein quantitative trait loci (pQTLs) and expression quantitative trait loci (eQTLs). These molecular data were combined with summary statistics from a meta-analysis of genome-wide association studies including 16,532 MASLD cases and 1,240,188 controls. Mendelian randomization and genetic colocalization analyses revealed that most proteins differentially expressed across MASLD stages were not causally implicated in disease risk, whereas several genetically predicted liver proteins showed evidence of causal effects. Among these, higher hepatic levels of the MTARC1 protein were causally associated with MASLD and hepatic fat accumulation. Phenome-wide analyses suggested that MTARC1 inhibition may reduce the risk of cirrhosis, hepatocellular carcinoma, and cholelithiasis while improving lipid profiles. Notably, the causal MTARC1 variant influenced liver protein levels but not gene expression. Genetic analyses also identified ERLIN1 and HSD17B13 as potential therapeutic targets. In contrast, eQTLs and pQTLs at other loci such as GCKR showed opposite effects on MASLD risk. These findings highlight the importance of integrating tissue proteomics with human genetics to distinguish biomarkers from causal drivers and to identify promising therapeutic targets for MASLD.