Project description:Alcoholic liver disease (ALD) encompasses conditions ranging from simple steatosis to cirrhosis and even liver cancer. It has gained significant global attention in recent years. Despite this, effective pharmacological treatments for ALD remain elusive, and the core mechanisms underlying the disease are not yet fully comprehended. S100A16, a newly identified calcium-binding protein, is linked to lipid metabolism. Our research has discovered elevated levels of the S100A16 protein in both serum and liver tissue of ALD patients. A similar surge in hepatic S100A16 expression was noted in a Gao-binge alcohol feeding mouse model. S100a16 knockdown alleviated ethanol-induced liver injury, steatosis and inflammation. Conversely, S100a16 transgenic mice showed aggravating phenomenon. Mechanistically, we identify mesencephalic astrocyte-derived neurotrophic factor (MANF) as a regulated entity downstream of S100a16 deletion. MANF inhibited ER-stress signal transduction induced by alcohol stimulation. Meanwhile, MANF silencing suppressed the inhibition effect of S100a16 knockout on ethanol-induced lipid droplets accumulation in primary hepatocytes. Our data suggested that S100a16 deletion protects mice against alcoholic liver lipid accumulation and inflammation dependent on upregulating MANF and inhibiting ER stress. This offers a potential therapeutic avenue for ALD treatment.

Project description:Alcoholic liver disease, which varies in severity from mild steatosis to cirrhosis and hepatitis, is one of the most prevalent chronic liver diseases worldwide. Excessive alcohol consumption remains the leading cause of ALD and alcohol-related complications and deaths. However, no medications have been developed to treat this disease and its pathogenesis remains elusive. Here, to understand alcohol-induced AhR activation in more detail, transcriptomic data was conducted using livers from mice subjected to either control or Lieber-DeCarli alcohol diets.

Project description:Alcohol is metabolized in the liver, and chronic consumption can lead to inflammation, scarring, and damage to liver cells. The pathogenesis of alcoholic liver disease (ALD), a complicated condition, is characterized by a succession of histopathological alterations that occur through a multistep and multifactorial process. FAF2/UBXD8/ETEA is a ubiquitin ligase adaptor protein and plays a crucial role in the ubiquitin-mediated degradation of misfolded proteins in the endoplasmic reticulum. Recent GWAS study indicated that FAF2 was associated with ALD, but the exact function of FAF2 in ALD has not been identified yet. The objective of this study was to investigate the role of FAF2 in ALD.Our study revealed a noteworthy rise in hepatic FAF2 protein expression among individuals with ALD and mice subjected to chronic-plus-single binge ethanol feeding. The suppression of FAF2 in mice liver provided protection against alcohol-induced hepatic steatosis.

Project description:Nicotinamide mononucleotide adenylyltransferase 1 (NMNAT1), an NAD+ synthetase in Preiss-Handler and salvage pathways, governs nuclear NAD+ homeostasis. This study investigated the role of NMNAT1 on alcohol-associated liver disease (ALD). Decreased NMNAT1 expression and activity were observed in the liver of alcohol-associated hepatitis patients and either liver or primary hepatocytes from ALD mice. F-box and WD repeat domain containing 7 (FBXW7)-regulated interferon regulatory factor 1 (IRF1) ubiquitination degradation contributed to alcohol-inhibited NMNAT1 transcriptional level. Hepatic NMNAT1 knockout aggravated alcohol-induced hepatic NAD+ decline and further hepatic steatosis and liver injury. Metabolomics and transcriptomics interaction revealed that cysteine sulfinic acid decarboxylase (CSAD)-regulated taurine pathway was involved in NMNAT1-disrupted hepatic lipid metabolism in ALD. Hepatic CSAD overexpression or taurine supply attenuated hepatic NMNAT1 knockout-aggravated ALD, respectively. Hepatic NMNAT1 loss inhibited NMN-protected ALD. Replenishing hepatic NMNAT1 reversed liver lipid accumulation in ALD mice. These findings identified NMNAT1 as a promising therapeutic target for ALD.

Project description:Background: Exposure to pollutants including the ubiquitous ‘forever chemical’, Perfluorooctane sulfonate (PFOS) has increasingly been associated with metabolic dysfunction-associated steatotic liver disease (MASLD). Recent epidemiological evidence has identified associations between Per- and polyfluoroalkyl substances (PFAS) exposure and increased liver injury in alcohol consumers, suggesting potential interactions between these exposures. However, the intersection of pollutant exposures and alcohol-associated liver disease (ALD) is not well studied. We hypothesize that pollutants may disrupt hepatic metabolism to modify ALD severity. Recently, we developed a two-hit (ethanol plus pollutant) mouse model, enabling testing of this hypothesis. Here, we elucidate the metabolic and disease-modifying effects of PFOS in this model. Methods: Male C57BL/6J mice were fed isocaloric control or 5% Ethanol (EtOH) Lieber-DeCarli diet for 15 days. From day 6 of feeding, mice were concurrently gavaged with 1 mg/kg PFOS or 2% tween-80 vehicle for 10 days, followed by a 5 g/kg EtOH binge dose and euthanized 5-6 hours later. Results: Approximately 60% of the administered PFOS dose accumulated in liver. PFOS exacerbated EtOH-induced hepatic steatosis and was associated by higher levels of plasma very low-density lipoprotein (vLDL) and alanine aminotransferase (ALT). PFOS upregulated hepatic ethanol-metabolizing enzymes and lowered blood alcohol levels. Ingenuity Pathway Analysis (IPA) Top Toxicity Functions/Lists associated with hepatic gene expression following PFOS co-exposure in EtOH-fed mice included: fatty acid metabolism and liver steatosis; nuclear receptor activation, cytochrome P450, and reactive oxygen species (ROS); apoptosis; liver fibrosis; and hepatocellular carcinoma (HCC). GO/KEGG analyses similarly revealed enrichment in fatty acid, xenobiotic, alcohol, or glutathione metabolic processes; and Peroxisome proliferator-activated receptor (PPAR) signaling. PFOS upregulated hepatic expression of several nuclear receptors (e.g., Pparα, Car, and Pxr) and their P450 target genes (e.g., Cyp4a10, Cyp2b10, and Cyp3a11) by RT-PCR or Western blot, confirming key IPA predictions. Conclusions: PFOS is a metabolism disrupting chemical that worsened ALD severity. PFOS activated hepatic nuclear receptors and enriched hepatic transcriptional pathways associated with steatosis, xenobiotic metabolism, oxidative stress, cell death, fibrosis, and HCC. These data demonstrate a novel mechanism whereby PFOS exacerbates ALD through coordinated dysregulation of lipid homeostasis and liver injury, potentially mediated by nuclear receptor activation. The identification of PFOS as an ALD risk modifier highlight the critical need to evaluate environmental pollutants as potential contributors to liver disease progression in vulnerable populations. More data are required on environmental pollution as a disease modifying factor in ALD.

Project description:Alcoholic liver diseases (ALDs) encompass a broad spectrum of clinical features of alcoholic fatty liver, alcoholic steatohepatitis and cirrhosis, and increased risk of hepatocellular carcinoma. While the toxic effects of alcohol likely result from complex interactions between genes and the environment, the molecular mechanisms of alcohol-induced liver damage remains undefined. Thus, a better understanding of the mechanisms regulating hepatic cell injury may lead to more effective therapeutic approaches for ALD. Here we compared the miRNA expression profile from tissues from control mice and mice receiving intragastric ethanol feeding. Four microarray hybridization studies were performed on three different pairs of liver-derived RNA from intragastric ethanol feeding and normal mice. The miRNAs differentially overexpressed in livers from ethanol fed mice.

Project description:Alcohol-related liver disease (ALD) is a leading cause of liver-related mortality worldwide, with limited treatment options beyond abstinence and liver transplantation. Chronic alcohol consumption has been linked to magnesium (Mg2+) deficiency, which can influence the liver disease progression. The mechanisms underlying Mg2+ homeostasis dysregulation in ALD remain elusive. This study aimed to investigate the role of the Mg2+ transporter Cyclin M4 (CNNM4) in ALD by analyzing its expression patterns in ALD patients and preclinical animal models. In this study, CNNM4 is upregulated in the liver of both ALD patients and animal models. CNNM4 overexpression triggers Mg²⁺ homeostasis dysregulation, linked to ALD progression. We propose a novel therapeutic approach for ALD treatment using N-acetylgalactosamine (GalNAc) silencing RNA (siRNA) technology to specifically modulate Cnnm4 expression in the liver, improving mitochondrial function and alleviating ER stress. Notably, silencing Cnnm4 restores protein isoaspartyl methyltransferase (PCMT1) activity, essential for repairing ethanol-induced protein damage. Enhancing mitochondrial activity through Cnnm4-dependent mechanisms increases SAMe levels, crucial for PCMT1 function, highlighting the interconnected roles of mitochondrial health and protein homeostasis in ALD treatment. These findings shed light on the dysregulation of Mg2+ homeostasis in ALD, providing a promising therapeutic approach targeting CNNM4. GalNAc siCnnm4 therapy boost the repair processes of ethanol damaged proteins through the upregulation of PCMT1 activity.

Project description:Aldehyde dehydrogenase 2 (ALDH2) is a key enzyme to detoxify the ethanol first metabolite acetaldehyde. Approximately 8% world population have inactive ALDH2 and have facial flushing due to high levels of acetaldehyde after alcohol consumption. Alcohol-associated liver disease (ALD) and hepatocellular carcinoma (HCC) in those with inactive ALDH2 have not been characterized. ALD pathogeneses in these individuals are likely very different from those with normal ALDH2, different diagnosis criteria and treatment are required for these two populations. Here we studied ALD in inactive Aldh2 knockin (Aldh2KI) mice with chronic ethanol feeding.

Project description:Abstinence is an important therapeutic intervention for patients with alcohol-associated liver disease (ALD). However, fibrosis improvement after cessation is not uniform and some patients do not improve. We aimed to use scATAC-seq analysis in a mouse model of ALD to define the mechanism of poor ALD resolution. We analyzed differentially accessible regions in livers from control, ALD, or 4 weeks post alcohol cessation mice and identified transcription factors activated in ALD that remained activated after alcohol withdrawal. The top hit was C/EBPβ. We found that hepatocyte specific Cebpb knockout prevented ALD development, while knockout at the time of alcohol cessation promoted fibrosis resolution.

Project description:Dysregulation of lipid homeostasis is a feature of alcohol-associated liver disease (ALD). A-kinase anchoring protein 12 (AKAP12) is a scaffolding partner of the cAMP-dependent protein kinase, PKA that controls its spatiotemporal localization. Activation of PKA by cAMP inhibits lipogenesis and facilitates fatty acid oxidation (FAO). We examined how AKAP12’ could regulate alcohol-associated steatosis. Alcohol exposure reduced AKAP12’s interaction with PKA and suppressed PKA activation. Forced expression of AKAP12 overcame the suppression of PKA activity in human hepatocytes and in livers of mice exposed to alcohol. This led to a decrease in hepatic steatosis. Disrupting the scaffold of AKAP12 and PKA by CRISPR editing increased steatosis and inflammation. RNA sequencing analysis of hepatocytes from alchol fed mice and normal mice demonstrated key lipogenic and inflammatory pathways regulated by AKAP12 overexpression. RNA sequencing of total liver from mice with AKAP12-PKA binding site CRISPR editing or AKAP12 overexpression confirmed regulation of lipogenic and inflammatory pathways by AKAP12