Survey
* Your assessment is very important for improving the workof artificial intelligence, which forms the content of this project
* Your assessment is very important for improving the workof artificial intelligence, which forms the content of this project
ATVB in Focus Smooth Muscle Cells Series Editor: Giulio Gabbiani Previous Brief Reviews in this Series: • Hillebrands J-L, Klatter FA, Rozing J. Origin of vascular smooth muscle cells and the role of circulating stem cells in transplant arteriosclerosis. 2003;23:380 –387. • Iso T, Hamamori Y, Kedes L. Notch signaling in vascular development. 2003;23:543–553. • Kumar MS, Owens GK. Combinatorial control of smooth muscle-specific gene expression. 2003;23:737–747. • Schaper W, Scholz D. Factors regulating arteriogenesis. 2003;23:1143–1151. • Hao H, Gabbiani G, Bochaton-Piallat M-L. Arterial smooth muscle cell heterogeneity: Implications for atherosclerosis and restenosis development 2003;23:1510 –1520. Downloaded from http://atvb.ahajournals.org/ by guest on April 28, 2017 DNA Methylation, Smooth Muscle Cells, and Atherogenesis Mikko O. Hiltunen, Seppo Ylä-Herttuala Abstract—DNA methylation is a form of epigenetic modification of the genome that can regulate gene expression. Hypermethylation of CpG islands in the promoter areas leads to decreased gene expression, whereas promoters of actively transcribed genes remain nonmethylated. Because of cellular proliferation and monoclonality of at least some of the lesion cells, atherosclerotic lesions have been compared with benign vascular tumors.1,2 However, although genetic and epigenetic background favors neoplastic transformation, atherosclerotic plaques never develop to malignant tumors. Among cancer cells, common features are genome-wide hypomethylation, which correlates with transformation and tumor progression. Recent studies have shown that DNA methylation changes occur also during atherogenesis and may contribute to the lesion development. (Arterioscler Thromb Vasc Biol. 2003;23:1750-1753.) Key Words: atherogenesis 䡲 DNA methylation 䡲 5-methylcytosine 䡲 epigenetic gene regulation 䡲 gene expression N studies, phenotypic transition is initiated by various factors or injuries, eg, balloon denudation. The proliferative state of the SMC requires profound changes in gene expression and protein synthesis. We have shown that only a few rounds of replication of contractile medial SMCs are required to develop a significant hypomethylation of the SMC genome.6 Consequences of this phenomenon on gene expression are discussed later in this review. It has been shown that some intimal synthetic SMCs are of monoclonal origin,1 which implicates that some clones of medial SMCs have developed at least a transient growth advantage. The situation is somewhat similar to carcinogenesis, where the tumor has gained a growth advantage. Injury to the arterial wall, such as angioplasty, induces endothelial dysfunction and stimulates SMC migration and proliferation. The highest proliferative activity of SMCs umerous factors in plasma (eg, lipoproteins, growth factors, and monocytes) and arterial wall (eg, smooth muscle cells [SMCs], matrix, and endothelium) contribute to atherogenesis. The pathogenesis of atherosclerosis involves mainly changes in the expression and function of genes rather than mutations. Atherosclerosis begins with eccentric thickening of the intima, leading to complex lesions over several decades.3 Intimal thickening forms in response to almost any imaginable injury, including circulating factors and mechanical injury. Neointima is composed of SMCs, mesenchymal intimal cells, and inflammatory cells.4 Before SMCs can migrate into intima, a transition in their phenotype is required.5 Medial nonproliferating SMCs have a contractile phenotype that enables them to regulate vascular tone. When SMCs proliferate, they acquire a synthetic phenotype. As learned from animal Received August 11, 2003; accepted August 11, 2003. From the A.I. Virtanen Institute (M.O.H., S.Y.-H.) and Department of Medicine (S.Y.-H.), University of Kuopio, and Gene Therapy Unit (S.Y.-H.), Kuopio University Hospital, Kuopio, Finland. Correspondence to Seppo Ylä-Herttuala, MD, PhD, Department of Molecular Medicine, A.I. Virtanen Institute, University of Kuopio, PO Box 1627, FIN-70211, Kuopio, Finland. E-mail [email protected] © 2003 American Heart Association, Inc. Arterioscler Thromb Vasc Biol. is available at http://www.atvbaha.org 1750 DOI: 10.1161/01.ATV.0000092871.30563.41 Hiltunen and Ylä-Herttuala DNA Methylation, SMCs, and Atherogenesis 1751 Examples of Genes Implicated in Atherogenesis That Are at Least Partially Regulated by DNA Methylation Gene IFN-␥38 PDGF-A39 MMP-240 MMP-740 MMP-940 TIMP-341 ICAM-142 Estrogen receptor-␣24 EC-SOD21 p5343 IFN indicates interferon; PDGF, platelet-derived growth factor; MMP, matrix metalloproteinase; TIMP, tissue inhibitor of metalloproteinase; ICAM, intracellular adhesion molecule; EC-SOD, extracellular superoxide dismutase. Downloaded from http://atvb.ahajournals.org/ by guest on April 28, 2017 Figure 1. Hypomethylation in atherosclerotic lesions. A, 5-methylcytosine content of genomic DNA extracted from human arteries at different stages of atherosclerosis. Statistically significant (*P⬍0.05) difference was observed when normal aortas (N; n⫽3) and fatty streaks (FS; n⫽23) were compared with advanced lesions (AL; n⫽29) (ANOVA and modified t test). B, 5-methylcytosine content of genomic DNA extracted from atherosclerotic lesions induced by Western diet in ApoE knockout mice. Normal control arteries were from ApoE⫺/⫺ mice fed with a regular chow (*P⬍0.05; t test). C, Genomic 5-methylcytosine contents of media and intima after denudation in normocholesterolemic NZW rabbits (media, n⫽2; intima, n⫽2) and in cholesterol-fed NZW rabbits (media, n⫽6; intima, n⫽6). Asterisks indicate statistical differences between intima and media (*P⬍0.01; **P⬍0.005; t test). 5-methylcytosine analyses were done by HPLC. Reprinted with permission from Reference 6. occurs a few days after the injury, followed by matrix formation from 1 week onwards, and may continue for months, occluding the lumen and compromising the blood flow.7 DNA Methylation Changes in SMCs DNA methylation (ie, formation of 5-methylcytosines from cytosine residues within CpG doublet by methyltransferases) has a major role as a regulator of gene expression in embryogenesis, X-chromosome inactivation in females, genomic imprinting, and carcinogenesis.8 –10 DNA methylation is a form of epigenetic gene regulation that together with altered binding profile of transcription factors commonly leads to suppression of gene expression when occurring in a regulatory region.11 According to current knowledge, 3 methyltransferases are responsible for genomic methylation. Dnmt3a and Dnmt3b are responsible for de novo methylation patterns, which are then maintained by Dnmt1.12 Although elusive, there must also be some demethylase activity, because in the fertilized mouse eggs, the paternal genome is rapidly demethylated before the replication of the paternal pronucleus.13 During early development, certain chromosomal regions become methylated (de novo methylation), controlling expression of genes that regulate cell differentiation. During early stages of human carcinogenesis, genomic hypomethylation is a common phenomenon that is linked to transformation, tumor progression, and oncogene expression.14 –17 In addition, it has been recently shown that hypomethylation plays a causal role in tumor formation, possibly by inducing chromosomal instability.18 The opposite situation, regional DNA hypermethylation, is present in later stages of carcinogenesis and may lead to inactivation of tumor suppressor genes.8,11,14 –17 Thus, changes in genomic methylation status can lead to a selective growth advantage. Most of our knowledge about the significance of DNA methylation comes from developmental biology, cancer biology, and studies with targeted deletions of mouse Dnmt genes.19 DNA hypomethylation in cancer cells occurs in highly and moderately repeated DNA sequences. These include heterochromatic DNA repeats, dispersed retrotransposons, and endogenous retroviral elements.20 In addition to cancer, we have shown recently that genomic hypomethylation is present in advanced human atherosclerotic lesions, lesions of apolipoprotein E (ApoE) knockout mice, and neointima of balloon-denuded New Zealand White (NZW) rabbit aortas (Figure 1).6 We have also shown that significant genomic hypomethylation develops during the first replications of aortic SMCs in vitro and that hypomethylation occurs in some specific genes, such as 15-lipoxygenase and extracellular superoxide dismutase.6,21 The Table shows examples of genes that may be important for atherogenesis and are at least partially regulated by DNA methylation. Because arterial SMCs are terminally differentiated, replication does not normally occur and methylation machinery is probably minimally active. It is possible that DNA hypomethylation is associated with changes in gene expression during the lesion development. This may result from a direct regulatory effect of the hypomethylation on the gene expression or be a 1752 Arterioscler Thromb Vasc Biol. October 2003 operative. It is possible that de novo methylation activity that would be required to increase genomic methylation level is not induced during SMC proliferation. Circumstantial evidence from in situ hybridization analysis of the expression of Dnmt1 supports the conclusion that increased Dnmt1 expression is associated with increased cellular proliferation in atherosclerotic lesions.6 Other Cancer Biomarkers and Atherosclerosis Downloaded from http://atvb.ahajournals.org/ by guest on April 28, 2017 Figure 2. Schematic representation of the possible role of genomic methylation in SMC proliferation. secondary effect by affecting DNA integrity and function. It has also been shown that regional hypermethylation occurs in atherosclerosis. Estrogen receptor-␣ gene was found to have an increased methylation level in atheromas compared with normal aorta.22,23 Estrogen receptor-␣ gene was also shown to be methylated in SMCs in vitro during the phenotypic switch.24 It has been reported that overexpression of platelet-derived growth factor, c-myc, and other growth regulatory genes occurs during atherogenesis and that SMC proliferation can be successfully inhibited by blocking the expression or activity of these genes.25–27 Several studies have shown that when culturing various cell lines in the presence of a methylation inhibitor, 5-azadeoxycytidine, expression of some inactive genes can be activated.28 Similar effects may be caused by hypomethylation in vivo. The fact that overexpression of Dnmt in cancer cannot reverse genomic hypomethylation could be explained by the lack of de novo methylation activity of the enzyme.8,29 A crucial question regarding hypomethylation is whether it is a consequence of SMC proliferation or whether it contributes to the increased proliferative activity. However, as learned from cancer cells, important consequences of DNA hypomethylation may be a decreased karyotypic stability and altered heterochromatic-euchromatic interactions favoring oncogenesis.20 It has been reported from cancer tissue that Dnmt activity is actually increased despite the genome-wide hypomethylation.30,31 Dnmt1 activity can be seen as a compensatory mechanism to maintain genomic methylation pattern, because only 2 rounds of replications are required for genomic hypomethylation if maintenance methylation activity provided by Dnmt or other methyl transferases is not Genomic instability (ie, chromosomal alterations and alterations in microsatellite sequences) is characteristic for human cancers, and it has been suggested that loss of mechanisms that protect genome integrity contributes to tumorigenesis.32 In normal cells, microsatellite sequence repeats are accurately maintained during replication, but in tumor cells they vary in length (ie, microsatellite instability). Although phenotypically silent, microsatellite instability indicates defects in DNA replication and maintenance machinery. These errors in the replication may lead to activation of proto-oncogenes and in turn to inactivation of tumor suppressor genes. In human atherogenesis, microsatellite instability occurs in 20% to 33% of cases and may be linked to the increased proliferation rate of SMCs.33,34 A special mechanism is required for the termini of the eukaryotic chromosomes (ie, telomere) to complete replication during cell division. To overcome the end-replication problem that produces gaps at the 5⬘ ends of the newly synthesized DNA, an enzyme called telomerase must add sequence repeats onto the preexisting 3⬘ overhangs of the chromosomes.35 Telomerase activity has been found in germ line cells and in cancer cells but not in somatic cells.36 This attrition of the telomere length leads eventually to the cessation of cell proliferation. Therefore, the actual biological age of the cells (ie, the number of cell divisions) may be determined by a biological clock that resides in the telomeres. Although there is abundant information about gene expression, cellular activation, and proliferation of SMCs, relatively little attention has been paid on the biological age of the vascular cells. It is hypothesized that the age of the vascular cells may have important effects on the response to injury and various growth stimuli.37 These responses may also be modulated by genomic methylation status of the vascular cells. Figure 2 presents possible contribution of epigenetic changes on SMC proliferation during atherogenesis. Summary It is concluded that hypomethylation occurs in atherosclerotic lesions and that it seems to be associated with an increased transcriptional activity. It is possible that alterations in DNA methylation may play an important role in atherogenesis and that interventions directed toward methylation machinery may be useful for the treatment of vascular disorders. Acknowledgments The Academy of Finland, Sigrid Juselius Foundation, and Finnish Foundation for Cardiovascular Research supported this study. The authors would like to thank Marja Poikolainen for preparing the manuscript. Hiltunen and Ylä-Herttuala DNA Methylation, SMCs, and Atherogenesis References Downloaded from http://atvb.ahajournals.org/ by guest on April 28, 2017 1. Benditt EP, Benditt JM. Evidence for a monoclonal origin of human atherosclerotic plaques. Proc Natl Acad Sci U S A. 1973;70:1753–1756. 2. Penn A, Garte SJ, Warren L, Nesta D, Mindich B. Transforming gene in human atherosclerotic plaque DNA. Proc Natl Acad Sci U S A. 1986;83: 7951–7955. 3. Ylä-Herttuala S, Nikkari T, Hirvonen J, Laaksonen H, Möttönen M, Pesonen E, Raekallio J, Åkerblom HK. Biochemical composition of coronary arteries in Finnish children. Arteriosclerosis. 1986;6:230 –236. 4. Haust MD. The natural history of human atherosclerotic lesions. In: Moore S, ed. Vascular Injury and Atherosclerosis. New York: Dekker; 1981:1–23. 5. Campbell GR, Chamley-Campbell JH. Smooth muscle phenotypic modulation: role in atherogenesis. Med Hypotheses. 1981;7:729 –735. 6. Hiltunen MO, Turunen MP, Hakkinen TP, Rutanen J, Hedman M, Makinen K, Turunen AM, Aalto-Setala K, Yla-Herttuala S. DNA hypomethylation and methyltransferase expression in atherosclerotic lesions. Vasc Med. 2002;7:5–11. 7. Nikol S, Huehns TY, Hofling B. Molecular biology and post-angioplasty restenosis. Atherosclerosis. 1996;123:17–31. 8. Bestor TH, Tycko B. Creation of genomic methylation patterns. Nat Genet. 1996;12:363–367. 9. Ramsahoye BH, Davies CS, Mills KI. DNA methylation: biology and significance. Blood Rev. 1996;10:249 –261. 10. Razin A, Shemer R. DNA methylation in early development. Hum Mol Genet. 1995;4:1751–1755. 11. Greger V, Passarge E, Hopping W, Messmer E, Horsthemke B. Epigenetic changes may contribute to the formation and spontaneous regression of retinoblastoma. Hum Genet. 1989;83:155–158. 12. Jones PA, Baylin SB. The fundamental role of epigenetic events in cancer. Nat Rev Genet. 2002;3:415– 428. 13. Mayer W, Niveleau A, Walter J, Fundele R, Haaf T. Demethylation of the zygotic paternal genome. Nature. 2000;403:501–502. 14. Goelz SE, Vogelstein B, Hamilton SR, Feinberg AP. Hypomethylation of DNA from benign and malignant human colon neoplasms. Science. 1985; 228:187–190. 15. Gama-Sosa MA, Slagel VA, Trewyn RW, Oxenhandler R, Kuo KC, Gehrke CW, Ehrlich M. The 5-methylcytosine content of DNA from human tumors. Nucleic Acids Res. 1983;11:6883– 6894. 16. Feinberg AP. Genomic imprinting and gene activation in cancer. Nat Genet. 1993;4:110 –113. 17. Counts JL, Goodman JI. Alterations in DNA methylation may play a variety of roles in carcinogenesis. Cell. 1995;83:13–15. 18. Gaudet F, Hodgson JG, Eden A, Jackson-Grusby L, Dausman J, Gray JW, Leonhardt H, Jaenisch R. Induction of tumors in mice by genomic hypomethylation. Science. 2003;300:489 – 492. 19. Laird PW. Mouse models in DNA-methylation research. Curr Top Microbiol Immunol. 2000;249:119 –134. 20. Ehrlich M. DNA methylation in cancer: too much, but also too little. Oncogene. 2002;21:5400 –5413. 21. Laukkanen MO, Mannermaa S, Hiltunen MO, Aittomaki S, Airenne K, Janne J, Yla-Herttuala S. Local hypomethylation in atherosclerosis found in rabbit ec-sod gene. Arterioscler Thromb Vasc Biol. 1999;19: 2171–2178. 22. Post WS, Goldschmidt-Clermont PJ, Wilhide CC, Heldman AW, Sussman MS, Ouyang P, Milliken EE, Issa JP. Methylation of the estrogen receptor gene is associated with aging and atherosclerosis in the cardiovascular system. Cardiovasc Res. 1999;43:985–991. 23. Dong C, Yoon W, Goldschmidt-Clermont PJ. DNA methylation and atherosclerosis. J Nutr. 2002;132:2406S–2409S. 24. Ying AK, Hassanain HH, Roos CM, Smiraglia DJ, Issa JJ, Michler RE, Caligiuri M, Plass C, Goldschmidt-Clermont PJ. Methylation of the 25. 26. 27. 28. 29. 30. 31. 32. 33. 34. 35. 36. 37. 38. 39. 40. 41. 42. 43. 1753 estrogen receptor-alpha gene promoter is selectively increased in proliferating human aortic smooth muscle cells. Cardiovasc Res. 2000;46: 172–179. Marin ML, Gordon RE, Veith FJ, Tulchin N, Panetta TF. Distribution of c-myc oncoprotein in healthy and atherosclerotic human carotid arteries. J Vasc Surg. 1993;18:170 –176. Wilcox JN, Smith KM, Williams LT, Schwartz SM, Gordon D. Plateletderived growth factor mRNA detection in human atherosclerotic plaques by in situ hybridization. J Clin Invest. 1988;82:1134 –1143. Shi Y, Hutchinson HG, Hall DJ, Zalewski A. Downregulation of c-myc expression by antisense oligonucleotides inhibits proliferation of human smooth muscle cells. Circulation. 1993;88:1190 –1195. Haaf T. The effects of 5-azacytidine and 5-azadeoxycytidine on chromosome structure and function: implications for methylation-associated cellular processes. Pharmacol Ther. 1995;65:19 – 46. Laird PW, Jaenisch R. DNA methylation and cancer. Hum Mol Genet. 1994;3:1487–1495. Lee PJ, Washer LL, Law DJ, Boland CR, Horon IL, Feinberg AP. Limited up-regulation of DNA methyltransferase in human colon cancer reflecting increased cell proliferation. Proc Natl Acad Sci U S A. 1996; 93:10366 –10370. Issa JP, Vertino PM, Wu J, Sazawal S, Celano P, Nelkin BD, Hamilton SR, Baylin SB. Increased cytosine DNA-methyltransferase activity during colon cancer progression. J Natl Cancer Inst. 1993;85:1235–1240. Hartwell L. Defects in a cell cycle checkpoint may be responsible for the genomic instability of cancer cells. Cell. 1992;71:543–546. Spandidos DA, Ergazaki M, Arvanitis D, Kiaris H. Microsatellite instability in human atherosclerotic plaques. Biochem Biophys Res Commun. 1996;220:137–140. Hatzistamou J, Kiaris H, Ergazaki M, Spandidos DA. Loss of heterozygosity and microsatellite instability in human atherosclerotic plaques. Biochem Biophys Res Commun. 1996;225:186 –190. Watson JD. Origin of concatameric T7 DNA. Nat New Biol. 1972;239: 197–201. Counter CM, Avilion AA, LeFeuvre CE, Stewart NG, Greider CW, Harley CB, Bacchetti S. Telomere shortening associated with chromosome instability is arrested in immortal cells which express telomerase activity. EMBO J. 1992;11:1921–1929. de Bono DP. Olovnikov’s clock: telomeres and vascular biology. Heart. 1998;80:110 –111. White GP, Watt PM, Holt BJ, Holt PG. Differential patterns of methylation of the IFN-gamma promoter at CpG and non-CpG sites underlie differences in IFN-gamma gene expression between human neonatal and adult CD45RO-T cells. J Immunol. 2002;168:2820 –2827. Lin XH, Guo C, Gu LJ, Deuel TF. Site-specific methylation inhibits transcriptional activity of platelet-derived growth factor A-chain promoter. J Biol Chem. 1993;268:17334 –17340. Sato N, Maehara N, Su GH, Goggins M. Effects of 5-aza-2⬘deoxycytidine on matrix metalloproteinase expression and pancreatic cancer cell invasiveness. J Natl Cancer Inst. 2003;95:327–330. Wild A, Ramaswamy A, Langer P, Celik I, Fendrich V, Chaloupka B, Simon B, Bartsch DK. Frequent methylation-associated silencing of the tissue inhibitor of metalloproteinase-3 gene in pancreatic endocrine tumors. J Clin Endocrinol Metab. 2003;88:1367–1373. Tanaka Y, Fukudome K, Hayashi M, Takagi S, Yoshie O. Induction of ICAM-1 and LFA-3 by Tax1 of human T-cell leukemia virus type 1 and mechanism of down-regulation of ICAM-1 or LFA-1 in adult-T-cellleukemia cell lines. Int J Cancer. 1995;60:554 –561. Schroeder M, Mass MJ. CpG methylation inactivates the transcriptional activity of the promoter of the human p53 tumor suppressor gene. Biochem Biophys Res Commun. 1997;235:403– 406. Downloaded from http://atvb.ahajournals.org/ by guest on April 28, 2017 DNA Methylation, Smooth Muscle Cells, and Atherogenesis Mikko O. Hiltunen and Seppo Ylä-Herttuala Arterioscler Thromb Vasc Biol. 2003;23:1750-1753; originally published online August 28, 2003; doi: 10.1161/01.ATV.0000092871.30563.41 Arteriosclerosis, Thrombosis, and Vascular Biology is published by the American Heart Association, 7272 Greenville Avenue, Dallas, TX 75231 Copyright © 2003 American Heart Association, Inc. All rights reserved. Print ISSN: 1079-5642. Online ISSN: 1524-4636 The online version of this article, along with updated information and services, is located on the World Wide Web at: http://atvb.ahajournals.org/content/23/10/1750 Permissions: Requests for permissions to reproduce figures, tables, or portions of articles originally published in Arteriosclerosis, Thrombosis, and Vascular Biology can be obtained via RightsLink, a service of the Copyright Clearance Center, not the Editorial Office. Once the online version of the published article for which permission is being requested is located, click Request Permissions in the middle column of the Web page under Services. Further information about this process is available in the Permissions and Rights Question and Answer document. Reprints: Information about reprints can be found online at: http://www.lww.com/reprints Subscriptions: Information about subscribing to Arteriosclerosis, Thrombosis, and Vascular Biology is online at: http://atvb.ahajournals.org//subscriptions/