ACMSD inhibition corrects fibrosis, inflammation, and DNA damage in MASLD/MASH.
Details
Serval ID
serval:BIB_438655938954
Type
Article: article from journal or magazin.
Collection
Publications
Institution
Title
ACMSD inhibition corrects fibrosis, inflammation, and DNA damage in MASLD/MASH.
Journal
Journal of hepatology
ISSN
1600-0641 (Electronic)
ISSN-L
0168-8278
Publication state
In Press
Peer-reviewed
Oui
Language
english
Notes
Publication types: Journal Article
Publication Status: aheadofprint
Publication Status: aheadofprint
Abstract
Recent findings reveal the importance of tryptophan-initiated de novo nicotinamide adenine dinucleotide (NAD <sup>+</sup> ) synthesis in the liver, a process previously considered secondary to biosynthesis from nicotinamide. The enzyme α-amino-β-carboxymuconate-ε-semialdehyde decarboxylase (ACMSD), primarily expressed in liver and kidney, acts as a modulator of de novo NAD <sup>+</sup> synthesis. Boosting NAD <sup>+</sup> levels has previously demonstrated remarkable metabolic benefits in mouse models. In this study, we aimed to investigate the therapeutic implications of ACMSD inhibition in the treatment of metabolic dysfunction-associated steatotic liver disease/steatohepatitis (MASLD/MASH).
In vitro experiments were conducted in primary rodent hepatocytes, Huh7 human liver carcinoma cells and iPSC-derived human liver organoids (HLOs). C57BL/6J male mice were fed a western-style diet and housed at thermoneutrality to recapitulate key aspects of MASLD/MASH. Pharmacological ACMSD inhibition was given therapeutically, following disease onset. Steatohepatitis HLO models were used to assess the DNA damage responses by ACMSD inhibition in human contexts.
Inhibiting ACMSD with a novel specific pharmacological inhibitor promotes de novo NAD <sup>+</sup> synthesis and reduces DNA damage ex vivo, in vivo, and in HLO models. In mouse models of MASLD/MASH, de novo NAD <sup>+</sup> biosynthesis is suppressed, and transcriptomic DNA damage signatures correlate with disease severity; in humans, Mendelian randomization-based genetic analysis suggests a notable impact of genomic stress on liver disease susceptibility. Therapeutic inhibition of ACMSD in mice increases liver NAD <sup>+</sup> and reverses MASLD/MASH, mitigating fibrosis, inflammation, and DNA damage, as were observed in HLO models of steatohepatitis.
Our findings highlight the benefits of ACMSD inhibition to enhance hepatic NAD <sup>+</sup> levels and enable genomic protection, underscoring its therapeutic potential in MASLD/MASH.
Enhancing NAD <sup>+</sup> levels has shown remarkable health benefits in mouse models of MASLD/MASH, yet liver-specific NAD <sup>+</sup> boosting strategies remain underexplored. Here, we present a novel pharmacological approach to enhance liver NAD <sup>+</sup> de novo synthesis by inhibiting ACMSD, an enzyme highly expressed in the liver. Inhibiting ACMSD increases NAD <sup>+</sup> levels, enhances mitochondrial respiration, and maintains genomic stability in hepatocytes ex vivo and in vivo. These molecular benefits prevent disease progression in both mouse and human liver organoid models of steatohepatitis. Our preclinical study identifies ACMSD as a promising target for MASLD/MASH management and lays the groundwork for developing ACMSD inhibitors as a clinical treatment.
In vitro experiments were conducted in primary rodent hepatocytes, Huh7 human liver carcinoma cells and iPSC-derived human liver organoids (HLOs). C57BL/6J male mice were fed a western-style diet and housed at thermoneutrality to recapitulate key aspects of MASLD/MASH. Pharmacological ACMSD inhibition was given therapeutically, following disease onset. Steatohepatitis HLO models were used to assess the DNA damage responses by ACMSD inhibition in human contexts.
Inhibiting ACMSD with a novel specific pharmacological inhibitor promotes de novo NAD <sup>+</sup> synthesis and reduces DNA damage ex vivo, in vivo, and in HLO models. In mouse models of MASLD/MASH, de novo NAD <sup>+</sup> biosynthesis is suppressed, and transcriptomic DNA damage signatures correlate with disease severity; in humans, Mendelian randomization-based genetic analysis suggests a notable impact of genomic stress on liver disease susceptibility. Therapeutic inhibition of ACMSD in mice increases liver NAD <sup>+</sup> and reverses MASLD/MASH, mitigating fibrosis, inflammation, and DNA damage, as were observed in HLO models of steatohepatitis.
Our findings highlight the benefits of ACMSD inhibition to enhance hepatic NAD <sup>+</sup> levels and enable genomic protection, underscoring its therapeutic potential in MASLD/MASH.
Enhancing NAD <sup>+</sup> levels has shown remarkable health benefits in mouse models of MASLD/MASH, yet liver-specific NAD <sup>+</sup> boosting strategies remain underexplored. Here, we present a novel pharmacological approach to enhance liver NAD <sup>+</sup> de novo synthesis by inhibiting ACMSD, an enzyme highly expressed in the liver. Inhibiting ACMSD increases NAD <sup>+</sup> levels, enhances mitochondrial respiration, and maintains genomic stability in hepatocytes ex vivo and in vivo. These molecular benefits prevent disease progression in both mouse and human liver organoid models of steatohepatitis. Our preclinical study identifies ACMSD as a promising target for MASLD/MASH management and lays the groundwork for developing ACMSD inhibitors as a clinical treatment.
Keywords
Acmsd, DNA repair, Masld/mash, Mendelian randomization, Nad(+), human liver organoids, ACMSD, MASLD/MASH, NAD(+)
Pubmed
Open Access
Yes
Create date
30/08/2024 15:18
Last modification date
05/09/2024 9:02