Acute pancreatitis and epigenetic regulation mechanisms
-
摘要:
急性胰腺炎是由酒精、胆结石、高脂及吸烟等多种生活环境因素诱导的胰腺局部及全身炎症反应疾病,具体发病机制仍不完全清楚。研究提示DNA甲基化、组蛋白修饰和非编码RNA等表观遗传调控机制在急性胰腺炎发生及进展中发挥重要作用。介绍了急性胰腺炎的常见诱因如酒精、胆结石、高脂、吸烟与表观遗传调控机制以及炎症反应与表观遗传调控机制,虽然急性胰腺炎的表观遗传学调控机制仍处于初步探索阶段,但仍为进一步理解急性胰腺炎的发生、发展及治疗提供了新的思路。
Abstract:Acute pancreatitis is a local pancreatic and systemic inflammatory disease due to various living and environmental factors,such as alcohol,gallstones,high lipids,and smoking,and its pathogenesis remains unclear. Studies have shown that epigenetic regulation mechanisms,such as DNA methylation,histone modification,and non-coding RNA,play an important role in the development and progression of acute pancreatitis. This article introduces the association between the common causes of acute pancreatitis(including alcohol,gallstones,high lipids,and smoking) and epigenetic regulation mechanisms,as well as the association between inflammatory response and epigenetic regulation mechanisms. The preliminary exploration of epigenetic regulation mechanisms in acute pancreatitis provides new thoughts for further understanding the development,progression,and treatment of acute pancreatitis.
-
Key words:
- pancreatitis /
- DNA methylation /
- histone code /
- RNA,long noncoding
-
[1] LEE PJ,PAPACHRISTOU GI. New insights into acute pancreatitis[J]. Nat Rev Gastroenterol Hepatol,2019,16(8):479-496. [2] GARBER A,FRAKES C,ARORA Z,et al. Mechanisms and management of acute pancreatitis[J]. Gastroenterol Res Pract,2018,2018:6218798. [3] ZHANG N,ZHANG HY,GUO XH,et al. Changes of etiology in acute pancreatitis in recent 10 years in China:Meta-analysis[J/CD]. Chin J Digest Med Imageol(Electronic Edition),2016,6(2):71-75.(in Chinese)张娜,张海燕,郭晓红,等.中国近十年急性胰腺炎病因变化特点的Meta分析[J/CD].中华消化病与影像杂志(电子版),2016,6(2):71-75. [4] PERERA B,FAULK C,SVOBODA LK,et al. The role of environmental exposures and the epigenome in health and disease[J]. Environ Mol Mutagen,2019.[Epub ahead of print] [5] DOR Y,CEDAR H. Principles of DNA methylation and their implications for biology and medicine[J]. Lancet,2018,392(10149):777-786. [6] FISCHLE W,MOOTZ HD,SCHWARZER D. Synthetic histone code[J]. Curr Opin Chem Biol,2015,28:131-140. [7] KANWAL F,LU C. A review on native and denaturing purification methods for non-coding RNA(ncRNA)[J]. J Chromatogr B Analyt Technol Biomed Life Sci,2019,1120:71-79. [8] CLEMENS DL,SCHNEIDER KJ,ARKFELD CK,et al. Alcoholic pancreatitis:New insights into the pathogenesis and treatment[J]. World J Gastrointest Pathophysiol,2016,7(1):48-58. [9] HU JF,LU LG. Research advances in the epidemiological features,pathogenesis,and diagnosis and treatment of alcoholic pancreatitis[J]. J Clin Hepatol,2019,35(2):448-450.(in Chinese)胡江峰,陆伦根.酒精性胰腺炎的流行病学特征、发病机制及诊疗进展[J].临床肝胆病杂志,2019,35(2):448-450. [10] DERIKX MH,KOVACS P,SCHOLZ M,et al. Polymorphisms at PRSS1-PRSS2 and CLDN2-MORC4 loci associate with alcoholic and non-alcoholic chronic pancreatitis in a European replication study[J]. Gut,2015,64(9):1426-33. [11] WHITCOMB DC,LARUSCH J,KRASINSKAS AM,et al. Common genetic variants in the CLDN2 and PRSS1-PRSS2 loci alter risk for alcohol-related and sporadic pancreatitis[J]. Nat Genet,2012,44(12):1349-1354. [12] ZHANG H,GELERNTER J. Review:DNA methylation and alcohol use disorders:Progress and challenges[J]. Am J Addict,2017,26(5):502-515. [13] ZAKHARI S. Alcohol metabolism and epigenetics changes[J]. Alcohol Res,2013,35(1):6-16. [14] FOGEL EL,SHERMAN S. ERCP for gallstone pancreatitis[J].N Engl J Med,2014,370(2):150-157. [15] DI CIAULA A,WANG DQ,PORTINCASA P. An update on the pathogenesis of cholesterol gallstone disease[J]. Curr Opin Gastroenterol,2018,34(2):71-80. [16] CHUANG SC,HSI E,LEE KT. Mucin genes in gallstone disease[J]. Clin Chim Acta,2012,413(19-20):1466-1471. [17] DI CIAULA A,WANG DQ,BONFRATE L,et al. Current views on genetics and epigenetics of cholesterol gallstone disease[J]. Cholesterol,2013,2013:298421. [18] KATSIKA D,MAGNUSSON P,KRAWCZYK M,et al. Gallstone disease in Swedish twins:Risk is associated with ABCG8D19H genotype[J]. J Intern Med,2010,268(3):279-285. [19] CONG R,JIA Y,LI R,et al. Maternal low-protein diet causes epigenetic deregulation of HMGCR and CYP7α1 in the liver of weaning piglets[J]. J Nutr Biochem,2012,23(12):1647-1654. [20] YANG B,LIU B,BI P,et al. An integrated analysis of differential miRNA and mRNA expressions in human gallstones[J].Mol Biosyst,2015,11(4):1004-1011. [21] SONG YX,ZHU HY,DU YQ,et al. Advances in research of pathogenesis and treatment of hyperlipidemic acute pancreatitis[J]. World Chin J Dig,2019,27(2):45-49.(in Chinese)宋英晓,朱惠云,杜奕奇.高脂血症性急性胰腺炎发病机制及治疗的研究进展[J].世界华人消化杂志,2019,27(2):45-49. [22] STEFANUTTI C,LABBADIA G,MOROZZI C. Severe hypertriglyceridemia-related acute pancreatitis[J]. Ther Apher Dial,2013,17(2):130-137. [23] CHANG YT,CHANG MC,SU TC,et al. Association of cystic fibrosis transmembrane conductance regulator(CFTR)mutation/variant/haplotype and tumor necrosis factor(TNF)promoter polymorphism in hyperlipidemic pancreatitis[J]. Clin Chem,2008,54(1):131-138. [24] CHARLESWORTH A,STEGER A,CROOK MA. Hyperlipidemic acute pancreatitis and the apolipoprotein E4 allele[J]. Pancreas,2017,46(1):e3-e4. [25] FERRARI A,FIORINO E,GIUDICI M,et al. Linking epigenetics to lipid metabolism:Focus on histone deacetylases[J].Mol Membr Biol,2012,29(7):257-266. [26] SUGII S,EVANS RM. Epigenetic codes of PPARγin metabolic disease[J]. FEBS Lett,2011,585(13):2121-2128. [27] WANG L,XU S,LEE JE,et al. Histone H3K9 methyltransferase G9a represses PPARγexpression and adipogenesis[J]. EMBO J,2013,32(1):45-59. [28] KALKAN R,BECER E. RANK/RANKL/OPG pathway is an important for the epigenetic regulation of obesity[J]. Mol Biol Rep,2019,46(5):5425-5432. [29] SHEN L,TAN Z,GAN M,et al. tRNA-derived small noncoding RNAs as novel epigenetic molecules regulating adipogenesis[J]. Biomolecules,2019,9(7):e274. [30] YUHARA H,OGAWA M,KAWAGUCHI Y,et al. Smoking and risk for acute pancreatitis:A systematic review and metaanalysis[J]. Pancreas,2014,43(8):1201-1207. [31] ALAHMARI AA,SREEKUMAR B,Patel V,et al. Cigarette toxin 4-(methylnitrosamino)-1-(3-pyridyl)-1-butanone(NNK)induces experimental pancreatitis throughα7 nicotinic acetylcholine receptors(n AChRs)in mice[J]. PLo S One,2018,13(6):e0197362. [32] KAUR G,BEGUM R,THOTA S,et al. A systematic review of smoking-related epigenetic alterations[J]. Arch Toxicol,2019,93(10):2715-2740. [33] BESINGI W,JOHANSSON A. Smoke-related DNA methylation changes in the etiology of human disease[J]. Hum Mol Genet,2014,23(9):2290-2297. [34] CHEN D,FANG L,LI H,et al. Cigarette smoke component acrolein modulates chromatin assembly by inhibiting histone acetylation[J]. J Biol Chem,2013,288(30):21678-21687. [35] SRINIVASAN P,SUBRAMANIAN VS,SAID HM. Effect of the cigarette smoke component,4-(methylnitrosamino)-1-(3-pyridyl)-1-butanone(NNK),on physiological and molecular parameters of thiamin uptake by pancreatic acinar cells[J]. PLo S One,2013,8(11):e78853. [36] JIANG XL,TONG CX,SONG YH. Immunopathogenesis of acute pancreatitis[J]. Chin J Immun,2019,35(4):496-499,504.(in Chinese)姜晓玲,童晨曦,宋银宏.急性胰腺炎的免疫发病机制[J].中国免疫学杂志,2019,35(4):496-499,504. [37] SANDOVAL J,PEREDA J,PREZ S,et al. Epigenetic regulation of early-and late-response genes in acute pancreatitis[J]. J Immunol,2016,197(10):4137-4150. [38] BAYARSAIHAN D. Epigenetic mechanisms involved in modulation of inflammatory diseases[J]. Curr Opin Clin Nutr Metab Care,2016,19(4):263-269. [39] SUN SC. The non-canonical NF-κB pathway in immunity and inflammation[J]. Nat Rev Immunol,2017,17(9):545-558. [40] SCHAFER C,GODER A,BEYER M,et al. Class I histone deacetylases regulate p53/NF-κB crosstalk in cancer cells[J]. Cell Signal,2017,29:218-225. [41] HARTMAN H,WETTERHOLM E,THORLACIUS H,et al. Histone deacetylase regulates trypsin activation, inflammation,and tissue damage in acute pancreatitis in mice[J]. Dig Dis Sci,2015,60(5):1284-1289. [42] CARADONNA F,CRUCIATA I,SCHIFANO I,et al. Methylation of cytokines gene promoters in IL-1β-treated human intestinal epithelial cells[J]. Inflamm Res,2018,67(4):327-337. [43] MURPHY TM,O’Donovan a,mullins N,et al. Anxiety is associated with higher levels of global DNA methylation and altered expression of epigenetic and interleukin-6 genes[J]. Psychiatr Genet,2015,25(2):71-78. [44] SANDOVAL J,PEREDA J,RODRIGUEZ JL,et al. Ordered transcriptional factor recruitment and epigenetic regulation of tnf-alpha in necrotizing acute pancreatitis[J]. Cell Mol Life Sci,2010,67(10):1687-1697. [45] ESCOBAR J,PEREDA J,LOPEZ-RODAS G,et al. Redox signaling and histone acetylation in acute pancreatitis[J].Free Radic Biol Med,2012,52(5):819-837.
计量
- 文章访问数: 1232
- HTML全文浏览量: 33
- PDF下载量: 227
- 被引次数: 0