Reversing Epigenetic Alterations Caused by Alcohol: A Promising Therapeutic Direction for Alcoholic Liver Disease

Lin, Xiuxian; Lian, Guanghui; Peng, Shifang; Zhao, Qing; Xu, Ying; Ouyang, Dongsheng; Zhang, Wei; Chen, Y.

doi:10.1111/acer.13863

Cited by 10 publications

(12 citation statements)

References 101 publications

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“…It has been reported that chromatin remodeling is involved in COX-2-induced cellular events, as evidenced by a recent study that demonstrates the DNA methylation of specific oncogenes in COX-2-overexpressing mice ( Chen et al, 2017 ). While recent studies suggesting that histone and mitochondrial protein acetylation in a high fat diet evoke protein hyper-acetylation are controversial ( Carrer et al, 2017 ; Choi & Friso, 2010 ; Meyer et al, 2018 ; Peterson et al, 2018 ), the contribution to the hyper-acetylation status from the ethanol diet is more widely accepted ( Choi & Friso, 2010 ; Jung & Metzger, 2015 ; Kriss et al, 2018 ; Lin et al, 2018 ; Zhong et al, 2010 ; Zhong & Lemasters, 2018 ). A recent approach using 13 C-labeled ethanol together with mass spectrometry in an ethanol binge drinking mouse model provided the quantitative evidence of histone hyper-acetylation status ( Kriss et al, 2018 ), and we would like to employ this method in our future studies to significantly improve our understanding of the critical steps in nutritional rerouting in dietary stress.…”

Section: Discussionmentioning

confidence: 99%

Hepatic COX-2 expression protects mice from an alcohol-high fat diet-induced metabolic disorder by involving protein acetylation related energy metabolism

Chen

Sun

Wei

et al. 2021

Alcohol

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Purpose: A diet high in fat and ethanol often results in chronic metabolic disorder, hepatic steatosis, and liver inflammation. Constitutive hepatic cyclooxygenase-2 (COX-2) expression could protect from high fat-induced metabolism disturbance in a murine model. In this study, we explored the influence of hCOX-2 transgenic [TG] to high fat with ethanol-induced metabolic disorder and liver injury using a mouse animal model. Methods: 12-week-old male hepatic hCOX-2 transgenic (TG) or wild type mice (WT) were fed either a high fat and ethanol liquid diet (HF+Eth) or a regular control diet (RCD) for 5 weeks (four groups: RCD/WT, RCD/TG; HF+Eth/TG, HF+Eth/WT). We assessed metabolic biomarkers, cytokine profiles, histomorphology, and gene expression to study the impact of persistent hepatic COX-2 expression on diet-induced liver injury. Results: In the HF+Eth diet, constitutively hepatic human COX-2 expression protects mice from body weight gain and white adipose tissue accumulation, accompanied by improved IPGTT response, serum triglyceride/cholesterol levels, and lower levels of serum and liver inflammatory cytokines. Histologically, hCOX-2 mice showed decreased hepatic lipid droplets accumulation, decreased hepatocyte ballooning, and improved steatosis scores. Hepatic hCOX-2 overexpression enhanced AKT insulin signaling and increased fatty acid synthesis in both RCD and HF+Eth diet groups. The anti-lipogenic effect of hCOX-2 TG in the HF+Eth diet animals was mediated by increasing lipid disposal through enhanced β-oxidation via elevations in the expression of PPARa and PPARg, and increased hepatic autophagy as assessed by the ratio of autophagy markers LC3 II/I in hepatic tissue. Various protein acetylation pathway components, including HAT, HDAC1, SIRT1, and SNAIL1, were modulated in hCOX-2 TG mice in either RCD or HF+Eth diet. Conclusions: Hepatic human COX-2 expression protected mice from the metabolic disorder and liver injury induced by a high fat and ethanol diet by enhancing hepatic lipid expenditure. Epigenetic reprogramming of diverse metabolic genes might be involved in the anti-lipogenic effect of COX-2.

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Section: Discussionmentioning

confidence: 99%

Hepatic COX-2 expression protects mice from an alcohol-high fat diet-induced metabolic disorder by involving protein acetylation related energy metabolism

Chen

Sun

Wei

et al. 2021

Alcohol

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“…The role of microRNA (miRNA) in the pathogenesis of ARLD has been reviewed extensively over the years. [14,35,[160][161][162][163][164]. Dysregulation of miRNAs in ARLD is linked to the development of steatosis (yellow circle), inflammation via recruitment of inflammatory cells (blue circle), fibrosis (blue lines) and HCC (green circle).…”

Section: Figure Legendmentioning

confidence: 99%

Epigenetics of alcohol-related liver diseases

et al. 2022

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“…In addition to the deacetylation function, SIRT1 promotes the conversion of the metabolite of ethanol acetic acid into acetyl-CoA, which acetylates histones under the catalysis of HATs (Sahar et al, 2014;Lin et al, 2018). Therefore, SIRT1 may be involved in the balance of gene silencing and activation in ALD via acetylation of histones.…”

Section: Histone Acetylation In Aldmentioning

confidence: 99%

“…However, acetaldehyde is rapidly oxidized to acetate under the catalysis of aldehyde dehydrogenase 2 (ALDH2) inside mitochondria, accompanied with NAD+ consumption and NADH production ( Osna et al, 2017 ). The pathogenesis of ALD is quite complex and results from the interaction of multiple mechanisms ( Lin et al, 2018 ; Sehrawat et al, 2020 ). The metabolism of ethanol in the liver produces abundant reactive oxygen species (ROS) and alters the balance between lipogenesis and fatty acid metabolism, leading to hepatic steatosis ( Xu et al, 2017 ).…”

Section: Histone Modifications In Cldsmentioning

confidence: 99%

“…Besides, many studies have demonstrated that the expression of HDAC is inhibited and is associated with increased hepatic histone acetylation after alcohol exposure ( Yeung et al, 2004 ; You et al, 2008 ; Kirpich et al, 2012 ). In addition to the deacetylation function, SIRT1 promotes the conversion of the metabolite of ethanol acetic acid into acetyl-CoA, which acetylates histones under the catalysis of HATs ( Sahar et al, 2014 ; Lin et al, 2018 ). Therefore, SIRT1 may be involved in the balance of gene silencing and activation in ALD via acetylation of histones.…”

Section: Histone Modifications In Cldsmentioning

confidence: 99%

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Mechanism and Therapeutic Opportunities of Histone Modifications in Chronic Liver Disease

et al. 2021

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Chronic liver disease (CLD) represents a global health problem, accounting for the heavy burden of disability and increased health care utilization. Epigenome alterations play an important role in the occurrence and progression of CLD. Histone modifications, which include acetylation, methylation, and phosphorylation, represent an essential part of epigenetic modifications that affect the transcriptional activity of genes. Different from genetic mutations, histone modifications are plastic and reversible. They can be modulated pharmacologically without changing the DNA sequence. Thus, there might be chances to establish interventional solutions by targeting histone modifications to reverse CLD. Here we summarized the roles of histone modifications in the context of alcoholic liver disease (ALD), metabolic associated fatty liver disease (MAFLD), viral hepatitis, autoimmune liver disease, drug-induced liver injury (DILI), and liver fibrosis or cirrhosis. The potential targets of histone modifications for translation into therapeutics were also investigated. In prospect, high efficacy and low toxicity drugs that are selectively targeting histone modifications are required to completely reverse CLD and prevent the development of liver cirrhosis and malignancy.

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Reversing Epigenetic Alterations Caused by Alcohol: A Promising Therapeutic Direction for Alcoholic Liver Disease

Cited by 10 publications

References 101 publications

Hepatic COX-2 expression protects mice from an alcohol-high fat diet-induced metabolic disorder by involving protein acetylation related energy metabolism

Hepatic COX-2 expression protects mice from an alcohol-high fat diet-induced metabolic disorder by involving protein acetylation related energy metabolism

Epigenetics of alcohol-related liver diseases

Mechanism and Therapeutic Opportunities of Histone Modifications in Chronic Liver Disease

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