Epigenetic Epidemiology of Common Complex Disease: Prospects for Prediction, Prevention, and Treatment
article has not abstract
Published in the journal:
. PLoS Med 7(10): e32767. doi:10.1371/journal.pmed.1000356
Category:
Research in Translation
doi:
https://doi.org/10.1371/journal.pmed.1000356
Summary
article has not abstract
Summary Points
-
The epigenome records a variety of dietary, lifestyle, behavioral, and social cues, providing an interface between the environment and the genome. Epigenetic variation, whether genetically or environmentally determined, contributes to inter-individual variation in gene expression and thus to variation in common complex disease risk.
-
Interventions based upon epigenetic agents, including DNA methyltransferase inhibitors and histone deacetylase inhibitors, have been in clinical use for many years, but their role outside treatment of specific cancers is not established.
-
Epigenetic therapies will only be fruitful if epigenetic mechanisms are causally related to the disease being treated. Evidence linking epigenetic variation to specific disease phenotypes to date is lacking.
-
Epidemiological approaches can be applied to help separate causal from non-causal associations.
-
We propose the development of a Mendelian randomization approach (“genetical epigenomics”), which could help overcome the problems of confounding and reverse causation (when an association between epigenetic patterns and disease phenotype is observed but it is unknown whether the disease is causing changes to the epigenome or epigenetic changes are causal in disease pathogenesis).
Introduction
There is considerable anticipation of future improvements in disease prevention and treatment following recent advances in genomics [1]. One aspect of genomics that is receiving considerable interest is epigenetics—the regulatory processes that control the transcription of information encoded in the DNA sequence into RNA before their translation into proteins. Programmed developmental changes and the ability of the genome to register, signal, and perpetuate environmental cues are subsumed under the epigenetic banner [2].
Genes are packaged into chromatin and dynamic chromatin remodeling processes are required for the initial step in gene expression (transcription), achieved by altering the accessibility of gene promoters and regulatory regions [3]. Epigenetic factors are responsible for this regulatory process, the major components of which are DNA methylation, histone modifications, and the action of small non-coding RNAs (Figure 1). Unlike DNA sequence, which is largely fixed throughout the lifecourse, epigenetic patterns not only vary from tissue to tissue but alter with advancing age and are sensitive to environmental exposures [4]–[7]. It is this propensity for change that makes epigenetic processes the focus of such interest, as they lie at the interface of the environment and co-ordinated transcriptional control.
In rare developmental disorders, the role of aberrant epigenetic processes is well established [8]. Our focus here, however, is on the potential role of epigenetic processes in the context of common complex disease. Tumor-specific changes in epigenetic patterns are a hallmark of numerous cancers, with analysis of the epigenetic machinery beginning to feature prominently in emerging cancer diagnostics and therapies [9]–[11].
There is an increasing body of evidence to demonstrate that epigenetic patterns are altered by environmental factors known to be associated with disease risk (e.g., diet, smoking, alcohol intake, environmental toxicants, stress) [7],[8]; however, an important question remains to be resolved in defining which epigenetic changes are a secondary outcome of either exposure or disease, and which lie on the causal pathway linking the two. Without proven causality, interventions to prevent or treat common complex diseases based upon epigenetic mechanisms will not be fruitful. Conversely, regardless of causality, defining a robust prospective relationship between epigenetic patterns and phenotypic traits may have application in diagnostics or in identifying high-risk individuals for non-epigenetic-based interventions.
Measurement of Epigenetic Patterns
Epigenetic patterns, including histone modifications, microRNA (miRNA), and DNA methylation, can be assessed in a range of tissue types. As DNA methylation assays on stored DNA samples are straightforward, this has been extensively studied [12]. Histone modification analysis requires that DNA is maintained as intact chromatin, whereas analysis of miRNA requires a source of RNA. Planned prospective collection for such analyses is necessary, and both are costly to undertake on sizable sample sets. The N-terminal tails of the four core histones (H2A, H2B, H3, and H4) commonly exhibit post-translational modifications, including acetylation, methylation, or phosphorylation [13]. These histone modifications can be analysed following precipitation of chromatin, and subsequent use of an antibody to a specific modification e.g., methylation of histone 3, lysine 9 (H3-K9). miRNA expression levels can be measured using the same principles and methods as regular trranscriptomic analysis (miRNA array or qPCR). DNA methylation can be assayed through genome-wide approaches where the investigator is interested in global changes or in identifying regions of interest [14], or targeted approaches that focus on DNA methylation at a particular locus or loci associated with genes in a specific pathway [15]. These technologies are reviewed in detail elsewhere [16].
The tissue specificity of epigenetic patterns is a well-established phenomenon, with variation between tissues within individuals being greater than variation between individuals [5]. Furthermore, epigenetic dysregulation with advancing age has been shown to be highly tissue dependent [17]. Extrapolating epigenetic information gleaned from DNA from accessible sources such as peripheral white blood or buccal cells to other tissue types is therefore problematic. The correlation between methylation patterns in different tissues is complex and locus dependent, but data that are beginning to emerge suggest that epigenetic signatures on easily accessible material such as circulating cells have potential utility as biomarkers of exposure or disease risk [18].
Epigenetic patterns are heritable across cell divisions (mitosis) [19], but undergo comprehensive but incompletely understood reprogramming during meiosis [20]. Evidence that environmental exposures can act across generations to influence epigenetic patterns in offspring exist [21], with maternal exposure to famine during the perinatal period influencing offspring DNA methylation in adulthood [22],[23]. The quantitative importance of such intergenerational epigenetic transmission remains uncertain, and may have been over-emphasized in comparison with the theoretically less challenging but probably more tractable and important intra-generational epigenetic influences [24].
Environmental Influences on Epigenetic Patterns
Several other factors beyond tissue type and age [4],[5],[17],[25],[26] are believed to influence epigenetic patterns. Nutritional factors modulate epigenetic marks in both animal models and humans (reviewed by [27]), with dietary sources of methyl groups, including folate, choline, betaine, methionine, and serine, which are required for DNA methylation [28],[29], having been most studied. In animal and human studies these modulate epigenetic patterns in disease and non-disease settings. Other dietary components with evidence for an effect on epigenetic patterns relevant to the pathogenesis of common complex diseases include the influence of a high-fat diet on DNA methylation [30] and various dietary modifiers of histone deacetylase (HDAC) activity such as isothiocyanates, butyrate, and diallyl disulfide [31],[32]. miRNA levels have also been observed to be altered following dietary modulation, with miRNA expression in human muscle being increased following a dietary challenge of essential amino acids [33].
The most widely studied lifestyle influence on epigenetic patterns is smoking. It has been associated with global hypomethylation in DNA [34] as well as gene-specific hypermethylation [35] in tumor tissues in head and neck squamous cell carcinoma (HNSCC). Animal models suggest that epigenetic changes arise in lung tissue following short-term exposure to tobacco smoke condensate [36] and precede histopathological changes. Exposure to tobacco smoke is also believed to alter expression of DNA methyltransferase (DNMT) enzymes [37],[38] and modulate histone modifications, including acetylation and methylation [39]. In addition, miRNAs have been proposed as modulators of smoking-induced changes in gene expression in human airway epithelium [40], and studies in rodent models have demonstrated that chemopreventive agents can protect the lung tissue from smoke exposure-induced changes in miRNA expression [41]. Maternal cigarette smoking during pregnancy influences DNA methylation patterns in offspring [42],[43], pointing to a vulnerability of the epigenome to environmental exposures during the intrauterine period.
Animal studies have shown that chronic alcohol consumption is associated with reduced genomic DNA methylation in the colon [44], although evidence from human studies is equivocal. Alcohol-induced shifts in DNA methylation patterns could arise through perturbation of one-carbon metabolism and interference with methyl group donation (reviewed by [45]). The molecular actions of ethanol are also thought to involve site-specific changes to histone modifications, exemplified by a recent study of alcohol exposure during adolescence [46]. Epigenetic processes could also influence patterns of alcohol drinking, with emerging evidence suggesting that alcohol-sensitive miRNAs control the development of tolerance and subsequent alcohol addiction [47]. The alcohol-related miRNA responses may in turn reflect alcohol-induced changes in DNA methylation [48].
Air pollutants such as air particulate matter and airborne benzene exposure levels have been associated with changes in DNA methylation in genes involved in inflammation and carcinogenesis [49],[50]. Endocrine disruptors (vinclozilin, bisphenol A), and various heavy metals (arsenic, mercury, cadmium) are among other compounds present in the environment that have been implicated in epigenetic changes, including altered histone methylation [21]. Most epigenetic studies of environmental toxins have focused on the potential of DNA methylation patterns as biological markers of exposure rather than establishing epigenetic mechanisms as being causally related to a specific disease. Studies have, however, suggested a role for miRNAs in mediating the effects of exposure to black carbon on disease [51].
Several infectious agents, including Helicobacter pylori [52] and Epstein-Barr virus [53], have been shown to induce epigenetic changes, either directly or secondary to inflammation. Epigenetic modulation is recognized as an aetiological component in chronic inflammatory diseases such as rheumatoid arthritis and multiple sclerosis [54]. Inflammation also plays an important role in a wide range of diseases such as cancers, obesity, and atopic disorders, and epigenetic changes may be causal in disease pathogenesis [54]. There is increasing evidence that epigenetic mechanisms contribute to the transcriptional regulation of inflammatory responses [55].
Perhaps the most widely celebrated example of the influence of environmental conditions (other than diet) on the epigenome relates to maternal postnatal nurturing and epigenetically mediated alterations to the hypothalamic-pituitary-adrenal response to stress [56]. Variations in maternal signals alter gene expression and complex behavioral phenotypes in rodent offspring through a well-defined mechanism involving the epigenetic regulation of the glucocorticoid receptor gene within the target tissue. A further example of modulation of epigenetic patterns in a target tissue is that of increased histone acetylation in human muscle biopsy tissue following exercise [57], providing evidence that chromatin remodeling might be important in mediating longer-term responses to exercise. miRNA involvement in exercise-induced changes to gene expression has also been reported [58].
Genetic Influences on Epigenetic Patterns
Twin- and family-based studies have demonstrated that variation in epigenetic patterns, including both chromatin states [59] and DNA methylation [25],[60],[61], is heritable. Much inter-individual variation in epigenetic patterns can be explained by common genetic variation [62], with a recent study estimating that 6.5% of the variance in methylation at the IGF2 (insulin-like growth factor 2) locus could be explained by five single nucleotide polymorphisms (SNPs) [63]. A genome-wide association study considering DNA methylation in human brain tissue as a quantitative trait identified both cis and trans genetic effects upon DNA methylation (cytosine guanine dinucleotide [CpG]) sites, the predominant influences being in cis, defined as SNPs influencing methylation at CpG sites within 1 Mb of themselves [64]. Similar cis effects have been reported in whole blood DNA [25]. Greater knowledge of the genetic determinants of DNA methylation, histone modifications, and miRNA activity will transform our understanding of the mechanisms involved in the establishment and maintenance of epigenetic patterns, with such genetic influences undoubtedly contributing to observed inter-individual differences in gene expression [65].
Despite the relatively large body of evidence that disease-related environmental exposures are associated with epigenetic alterations, there remains little compelling data to support the link between epigenetic variation and common complex disease phenotypes (other than cancer). Investigation of parent-of-origin effects on risk of common complex disease have suggested a role of perturbed DNA methylation [66]. Adequately powered studies relating epigenetic profiles to both exposure and disease are in their infancy, but it is highly likely that a myriad of such associations will be identified, and the major issue will be identifying meaningful and useful associations within this tsunami of data. Epigenetic measures are phenotypic, not genotypic, and as with phenotypic measures in general, non-causal associations will be the rule rather than the exception [67]. As with conventional epidemiological investigations, separating causal from non-causal associations will become an important task (Figure 2).
“Genetical Epigenomics”: Identifying Causal Relationships between Exposure, Epigenetic Patterns, and Disease
Using germ-line genetic variation as a proxy for environmental exposures provides a route to strengthening causal inference within observational data [68]–[70]. The rationale is that genetic variants are not, in general, related to the socio-economic, behavioral, and physiological factors that confound associations in conventional observational epidemiology [67], nor are they altered by disease processes and thus subject to reverse causation. The Mendelian randomization approach can be extended to the interrogation of epigenetic variation as potential mediators of the influence of a modifiable exposure on disease outcomes, and thus appropriate targets for disease prevention.
Mendelian randomization methods can be applied to many categories of environmentally modifiable exposures to help define whether their relationship with phenotype is causal. For example, with respect to behavioral factors, it has been used in a proof-of-principle manner to demonstrate associations of alcohol intake with esophageal [71] and head and neck cancers [72], as well as to considerably strengthen evidence on the associations of alcohol intake with blood pressure [73]. The method has particular promise when applied to circulating intermediate phenotypes, the manipulation of which can potentially prevent disease. Again, as proof-of-principle, an increasing number of genetic variants that are associated with low density lipoprotein-cholesterol (LDL-C) level are also associated with coronary artery disease (CAD) risk [67],[74]–[76] (Figure 3).
In a similar fashion, genetic variants related to body mass index and obesity have been shown to influence a wide variety of metabolic, cardiovascular, and bone-related traits, strengthening evidence on the causal influence of adiposity in these cases [77]–[80]. Conversely, genetic variants associated with C-reactive protein (CRP) level have not been found to predict insulin resistance [80] or coronary heart disease [81], casting doubt on the causal role of CRP with respect to these conditions.
In the field of gene expression studies, identifying causal processes within a multitude of associations is at least as problematic as in observational epidemiological studies. For example, the majority of gene expression signatures in adipose tissue, and in high proportions (up to 10%) in blood, have been found to be related to obesity [82]. Methods equivalent to the Mendelian randomization approach we propose here (sometimes called “genetical genomics” [83] in the context of gene expression studies) have been applied to separate causal transcription effects from those generated by reverse causation [82]. This is facilitated by strong cis effects on gene expression, which allows isolation of specific loci influencing transcript level. The identification of strong cis effects in a genome-wide association study analysis of methylation patterns [64] provides encouragement that these methods can be extended to investigate the causal influences of epigenetic signatures in what could be called “genetical epigenomics”.
As a hypothetical example of how this approach could be applied, we will consider alcohol intake and HNSCC. It is likely that alcohol intake would be associated with a wide range of epigenetic changes, although at least some (and probably many) of these associations could reflect confounding by the many other factors related to alcohol consumption. Similarly, HNSCC could be related to a multitude of epigenetic changes, which could arise through reverse causation (the disease influencing the epigenetic patterns) or confounding (factors associated with HNSCC risk influencing the epigenetic patterns). If the epigenetic processes are to be targeted as a component of disease prevention they must be causally associated with HNSCC, and for them to mediate the effect of alcohol intake on HNSCC risk they need to be responsive to changes in alcohol intake. Observational data demonstrating an association of alcohol intake with a particular epigenetic profile exists, but the association of this profile with HNSCC risk does not, of course, establish causality. As depicted in Figure 4, Mendelian randomization approaches could be applied to this scenario.
Epigenomic Modifiers and the Prospects for Future Treatments
It can be argued that mitotically stable changes in gene expression are very likely to underlie the development of virtually all disease (in the same way as they are an essential component in the process of the development of an organism [84]), and as definitions of epigenetics incorporate such changes, they automatically fall within the field's remit. Once epigenetic mechanisms, even if only contributory, are unequivocally implicated in disease pathogenesis, the prospect of epigenomic-based therapies becomes a realistic possibility. A wide range of pharmacological agents that target the epigenome, including DNMT inhibitors and HDAC inhibitors, are used in clinical practice, largely as anti-cancer treatments [11]. However, these agents require further development to enhance the specificity of their pleiotropic effects, and evaluation of their efficacy in a non-cancer setting is essential. Combination therapies involving DNMT inhibitors or HDACs being employed with other agents are an active avenue of inquiry. miRNAs are also emerging as a promising technology in drug development following an increasing understanding of their biogenesis and function. The links between miRNA expression and common complex disease are growing, providing a greater impetus to pursue this useful tool for the targeted modulation of gene regulation. As with other epigenetic signatures, their utility might also lie in disease diagnosis and prognosis [85].
Conclusion
Through examining the role of environmental factors in causing variation in epigenetic patterns (exposure/epigenotype) and ultimately exploring the causal impact of epigenotype on disease outcomes (epigenotype/disease) using genetical epigenomics and other methods, progress towards epigenetic interventions can be made. As genome-wide association studies and other approaches identify robust associations between genetic variants and epigenetic patterns, possibilities for elucidating causal pathways and predicting the effect of manipulation—through environmental (including lifestyle) modification or pharmacotherapeutic means—is considerable. In this way, epigenetic markers may become targets for modification as well as biomarkers for exposure and disease risk. The International Human Epigenome Consortium is poised to invest millions of dollars to map 1,000 reference epigenomes in a range of normal tissues and define the level of variation that exists between individuals [86]. The field of epigenetics in relation to common complex disease will undoubtedly continue to be the focus of much attention, and its progress, now that it has passed the starting line, will be followed with considerable interest.
Five Key Papers in the Field
-
Weaver IC, Cervoni N, Champagne FA, D'Alessio AC, Sharma S, et al. (2004) Epigenetic programming by maternal behaviour. Nat Neurosci 7: 847–854. This landmark paper demonstrated that the epigenomic state of a gene can be altered through behavioural programming and that this environmentally induced modification is potentially reversible.
-
Fraga MF, Ballestar E, Paz MF, Ropero S, Setien F, et al. (2005) Epigenetic differences arise during the lifetime of monozygotic twins. Proc Natl Acad Sci U S A 102: 10604–10609. This article describes how epigenetic patterns in monozygotic twins become more discordant with advancing age. This epigenetic drift is postulated to be invoked through differences in environmental exposures.
-
Bjornsson HT, Sigurdsson MI, Fallin MD, Irizarry RA, Aspelund T, et al. (2008) Intra-individual change over time in DNA methylation with familial clustering. JAMA 299: 2877–2883. This study showed greater than 10% methylation change over time, that individuals within families showed both gain and loss of methylation, and that this change in methylation showed familial clustering indicative of a genetic basis.
-
Lister R, Pelizzola M, Dowen RH, Hawkins RD, Hon G, et al. (2009) Human DNA methylomes at base resolution show widespread epigenomic differences. Nature 462: 315–322. This paper reports the first genome-wide, single base-pair resolution map of methylated cytosines in the mammalian genome from embryonic stem cell and fetal fibroblasts, showing widespread differences between the tissue types.
-
Zhang D, Cheng L, Badner JA, Chen C, Chen Q, Luo W, et al. (2010) Genetic control of individual differences in gene-specific methylation in human brain. Am J Hum Genet 86: 411–419. This study demonstrated that DNA methylation is a heritable trait, determined in part by common genetic variation. The vast majority of genetically determined variation was observed to be in cis (correlation within 1Mb of a CpG site) with only a handful of SNPs determining trans methylation (distant regulation effects).
Zdroje
1. FeeroWG
GuttmacherAE
CollinsFS
2010 Genomic medicine–An updated primer. New Engl J Med 362 2001 2011
2. BirdA
2007 Perceptions of epigenetics. Nature 447 396 398
3. VaissiereT
SawanC
HercegZ
2008 Epigenetic interplay between histone modifications and DNA methylation in gene silencing. Mutat Res 659 40 48
4. ListerR
PelizzolaM
DowenRH
HawkinsRD
HonG
2009 Human DNA methylaomes at base pair resolution show widespread epigenomic differences. Nature 462 315 322
5. ByunHM
SiegmundKD
PanF
WeisenbergerDJ
KanelG
2009 Epigenetic profiling of somatic tissues from human autopsy specimens identifies tissue- and individual-specific DNA methylation patterns. Hum Mol Genet 18 4808 4817
6. AguileraO
FernandezAF
MunozA
FragaMF
2010 Epigenetics and environment: a complex relationship. J Appl Physiol Apr 8 [Epub ahead of print]
7. MeaneyMJ
2010 Epigenetics and the biological definition of gene x environment interactions. Child Dev 81 41 79
8. NichollsRD
2000 The impact of genomic imprinting for neurobehavioural and developmental disorders. J Clin Invest 105 413 418
9. SharmaS
KellyTK
JonesPA
2010 Epigenetics in cancer. Carcinogenesis 31 27 36
10. LairdPW
2003 The power and the promise of DNA methylation markers. Nat Rev Cancer 3 253 266
11. PiekarzRL
BatesSE
2009 Epigenetic modifiers: Basic understanding and clinical development. Clin Cancer Res 15 3918 3926
12. BeckS
RakyanVK
2008 The methylome: approaches for global DNA methylation profiling. Trends Genet 24 231 237
13. JenuweinT
AllisCD
2001 Translating the histone code. Science 293 1074 1080
14. FeinbergAP
2009 Genome-scale approaches to the epigenetics of common human disease. Virchows Arch 456 13 21
15. CampionJ
MilagroFI
MartinezJA
2009 Individuality and epigenetics in obesity. Obes Rev 10 383 392
16. TollefsbolTO
TollefsbolTO
2004 Methods of epigenetic analysis. Epigenetics protocols Secaucus (New Jersey) Springer Science & Business Media 1 8
17. ThompsonRF
AtzmonG
GheorgheC
LiangHQ
LowesC
2010 Tissue specific dysregulation of DNA methylation in aging. Aging Cell May 22 [Epub ahead of print]
18. TalensRP
BoomsaDI
TobiEW
KremerD
JukemaJW
2010 Variation, patterns and temporal stability of DNA methylation: considerations for epigenetic epidemiology. FASEB J 9 3135 3144
19. KimJK
SamaranayakeM
PradhanS
2009 Epigenetic mechanisms in mammals. Cell Mol Life Sci 66 596 612
20. ReikW
DeanW
WalterJ
2001 Epigenetic reprogramming in mammalian development. Science 293 1089 1093
21. BollatiV
BaccarelliA
2010 Environmental epigenetics. Heredity 105 105 112
22. HeijmansBT
TobiEW
SteinAD
PutterH
BlauwGJ
2008 Persistent epigenetic differences associated with prenatal exposure to famine in humans. Proc Natl Acad Sci U S A 105 17046 17049
23. TobiEW
LumeyLH
TalensRP
KremerD
PutterH
2009 DNA methylation differences after exposure to prenatal famine are common and timing- and sex-specific. Hum Mol Genet 18 4046 4053
24. HaigD
2007 Weismann rules! OK? Epigenetics and the Lamarckian temptation. Biol Philos 22 415 428
25. BoksMP
DerksEM
WeisenbergerBJ
StrengmanE
JansonE
2009 The relationship of DNA methylation with age, gender and genotype in twins and healthy controls. PLoS ONE 4 e6767 doi:10.1371/journal.pone.0006767
26. CalvaneseV
LaraE
KahnA
FragaMF
2009 The role of epigenetics in ageing and age-related diseases. Ageing Res Rev 8 268 276
27. FergusonLR
2009 Epigenetic variation and customising nutritional intervention. Curr Pharmacogenomics Person Med 7 115 124
28. KimKC
FrisoS
ChoiSW
2009 DNA methylation, an epigenetic mechanism connecting folate to healthy embryonic development and aging. J Nutr Biochem 20 917 926
29. WaterlandRA
2006 Assessing the effects of high methionine intake on DNA methylation. J Nutr 136 6 Suppl 1706S 1710S
30. WidikerS
KarstS
WagenerA
BrockmanGA
2010 High fat diet leads to a decreased methylation of the Mc4r gene in the obese BFMI and the lean B6 mouse lines. J Appl Genet 51 193 197
31. DelageB
DashwoodRH
2008 Dietary manipulation of histone structure and function. Annu Rev Nutr 28 347 366
32. MyzakMC
DashwoodRH
2006 Histone deacetylases as targets for dietary cancer preventive agents: lessons learned with butyrate, diallyl disulfide and sulforaphane. Curr Drug Targets 7 443 452
33. DrummondMJ
GlynnEL
FryCS
DhananiS
VolpiE
2009 Essential amino acids increase miRNA-499, -208b and -23 in human skeletal muscle. J Nutr 139 2279 2284
34. HsiungDT
MarsitCJ
HousemanEA
EddyK
FurnissCS
2007 Global DNA methylation level in whole blood as a biomarker in head and neck squamous cell carcinoma. Cancer Epidemiol Biomarkers Prev 16 108 114
35. KaurJ
DemokanS
TripathiSC
MachaMA
BegumS
2010 Promoter hypermethylation in indian primary oral squamous cell carcinoma. Int J Cancer E-pub ahead of print. 5 April 2010. doi:10.1002/ijc.25377
36. PhilipsJM
GoodmanJI
2009 Inhalation of cigarette smoke induces regions of altered DNA methylation (RAMs) in SENCAR mouse lung. Toxicology 260 7 15
37. LaunayJM
Del PinoM
ChironiG
CallebertJ
Peoc'hK
2009 Smoking induces long-lasting effects through a monoamine-oxidase epigenetic regulation. PLoS ONE 4 e7959 doi:10.1371/journal.pone.0007959
38. LiuH
ZhouY
BoggsSE
BelinskySA
LiuJ
2007 Cigarette smoke induces demethylation of prometastatic oncogene synuclein-gamme in lung cancer cells by downregulation of DNMT3B. Oncogene 26 5900 5910
39. HussainM
RaoM
HumphriesAE
HongJA
LiuF
2009 Tobacco smoke induces polycomb-mediated repression of Dickkopf-1 in lung cancer cells. Cancer Res 69 3570 3578
40. SchembriF
SridharS
PerdomoC
GustafsonAM
ZhangX
2009 MicroRNAs as modulators of smoking-induced gene expression changes I human airway epithelium. Proc Natl Acad Sci U S A 106 2319 2324
41. IzzottiA
LargheroP
CartigliaC
LongobardiM
PfefferU
2010 Modulation of microRNA expression by budesonide, phenethyl isothiocyanate and cigarette smoke in mouse liver and lung. Carcinogenesis 31 894 901
42. Guerrero-PrestonR
GoldmanLR
Brebi-MievilleP
Ili-GangaC
LebronC
2010 Global hypomethylation is associated with in utero exposure to cotinine and perfluorinated alkyl compounds. Epigenetics Aug 14 [Epub haead of print]
43. BretonCV
ByunHM
WentenM
PanF
YangA
2009 Prenatal tobacco smoke exposure affects global and gene-specific DNA methylation. Am J Respir Crit Care Med 180 462 467
44. SauerJ
JangH
ZimmerlyEM
KimKC
2010 Agening, chronic alcohol consumption and folate are determinnats of genomic DNAmethylation, p16 promoter methylation and the expression of p16 in the mouse colon. Br J Nutr 104 24 30
45. SeitzHK
StickelF
2007 Molecular mechanisms of alcohol-mediated carcinogenesis. Nat Rev Cancer 7 599 612
46. PascualM
BoixJ
FelipoV
GuerriC
2009 Repeated alcohol administration during adolescence causes changes in the mesolimbic dopaminergic and glutamatergic systems and promotes alcohol intake in the adult rat. J Neurochem 108 920 31
47. MirandaRC
PietrzykowskiAZ
TangY
SathyanP
MayfieldD
2010 MicroRNAs: master regulators of ethanol abuse and toxicity? Alcohol Clin Exp Res 34 575 87
48. TarantiniL
BonziniM
ApostoliP
PegoraroV
BollatiV
2009 Effects of particulate matter on genomic DNA methylation content and iNOS promter methylation. Environ Health Perspect 117 217 222
49. BollatiV
BaccarelliA
HouL
BonziniM
FustinoniS
2007 Changes in DNA methylation patterns in subjects exposed to low-dose benzene. Cancer Res 67 876 880
50. BaccarelliA
WrightRO
BollatiV
TarantiniL
LitonjuaAA
2009 Rapid DNA methylation changes after exposure to traffic particles. Am J Respir Crit Care Med 179 572 578
51. WilkerEH
BaccarelliA
SuhH
VokonasP
WrightRO
2010 Black carbon exposures, blood pressure and interactions with single nucleotide polymorphisms in microRNA processing genes. Environ Health Perspect 118 943 948
52. ShinCM
KimN
JungY
ParkJH
KangGH
2010 The role of Helicobacter pylori infection in aberrant DNA methylation along multistep gastric carcinogenesis. Cancer Sci E-pub ahead of print. 18 February 2010. doi:10.1111/j.1349-7006.2010.01535.x
53. TsaiCN
TsaiCL
TseKP
ChangHY
ChangYS
2002 The Epstein-Barr virus oncogene product, latent membrane protein 1, induces the downregulation of E-cadherin gene expression via activation of DNA methyltransferases. Proc Natl Acad Sci U S A 99 10084 10089
54. BackdahlL
BushellA
BeckS
2009 Inflammatory signalling as mediator of epigenetic modulation in tissue-specific chronic inflammation. Int J Biochem Cell Biol 41 176 84
55. MedzhitovR
HorngT
2009 Transcriptional control of the inflammatory response. Nature Rev Immunol 9 692 703
56. WeaverIC
CervoniN
ChampagneFA
D'AlessioAC
SharmaS
2004 Epigenetic programming by maternal behaviour. Nat Neurosci 7 847 854
57. McGeeSL
FairleeE
GrahamAP
HargreavesM
2009 Exercise-induced histone modifications in human skeletal muscle. J Physiol 587 5951 5981
58. Radom AizikS
ZaldivarFPJr
OliverSR
GalassettiPR
CooperDM
2010 Evidence for microRNA involvement in exercise-associated neutrophil gene expression changes. J Appl Physiol 109 252 261
59. KadotaM
YangHH
HuN
WangC
HuY
2007 Allele-specific chromatin immunoprecipitation studies show genetic influence on chromatin state in human genome. PLoS Genet 3 e81 doi:10.1371/journal.pgen.0030081
60. WongCC
CaspiA
WilliamsB
CraigIW
HoutsR
2010 A longitudinal study of epigenetic variation in twins. Epigenetics 5 516 526
61. BjornssonHT
SigurdssonMI
FallinMD
IrizarryRA
AspelundT
2008 Intra-individual change over time in DNA methylation with familial clustering. JAMA 299 2877 2883
62. FrenchHJ
AttenboroughR
HardyK
ShannonF
WilliamsRBH
2009 Interindividual variation in epigenomic phenomena in humans. Mamm Genome 20 604 611
63. HeijmansBT
KremerD
TobiEW
BoomsaDI
SlagboomPE
2007 Heritable rather than age-related and stochastic factors dominate variation in DNA methylation of the human IGF2/H19 locus. Hum Mol Genet 16 547 554
64. ZhangD
ChengL
BadnerJA
ChenC
ChenQ
2010 Genetic control of individual differences in gene-specific methylation in human brain. Am J Hum Genet 86 411 419
65. DimasAS
DermitzakisET
2009 Genetic variation of regulatory systems. Curr Opin Genet Dev 19 586 590
66. KongA
SteinthorsdottirV
MassonG
ThorleifssonG
SulemP
2009 Parental origin of sequence variants associated with complex diseases. Nature 462 868 874
67. Davey SmithG
LawlorDA
HarbordR
TimpsonN
DayI
2007 Clustered environments and randomized genes: a fundamental distinction between conventional and genetic epidemiology. PLoS Med 4 e352 doi:10.1371/journal.pmed.0040352
68. Davey SmithG
EbrahimS
2003 ‘Mendelian randomization’: can genetic epidemiology contribute to understanding environmental determinants of disease? Int J Epidemiol 32 1 22
69. Davey SmithG
2010 Mendelian randomization for strengthening causal inference in observational studies: applications to gene by environment interaction. Perspect Psychol Sci In press
70. SheehanNA
DidelezV
BurtonPR
TobinMD
2008 Mendelian randomization and causal inference in observational epidemiology. PLoS Med 5 e177 doi:10.1371/journal.pmed.0050177
71. LewisSJ
Davey SmithG
2005 Alcohol, ALDH2 and esophageal cancer: a meta-analysis which illustrates the potentials and limitations of a Mendelian randomization approach. Cancer Epidemiol Biomarkers Prev 14 1967 1971
72. BocciaS
HashibeM
GalliP
De FeoE
AsakageT
2009 Aldehyde dehydrogenase 2 and head and neck cancer: a meta-analysis implementing a Mendelian randomization approach. Cancer Epidemiol Biomarkers Prev 18 248 254
73. ChenL
Davey SmithG
HarbordR
LewisS
2008 Alcohol intake and blood pressure: a systematic review implementing Mendelian randomization approach. PLoS Med 5 e52 doi:10.1371/journal.pmed.0050052
74. Linsel-NitschkeP
GotzA
ErdmannJ
BraenneI
BraundP
2008 Lifelong reduction of LDL-cholesterol related to a common variant in the LDL-receptor gene decreases the risk of coronary artery disease–a Mendelian randomization study. PLoS ONE 3 e2986 doi:10.1371/journal.pone.0002986
75. TeslovichM
MusunumuK
SmithAV
EdmondsonAC
StylianouIM
2010 Biological, clinical and population relevance of 95 loci for blood lipids. Nature 466 707 713
76. SchuldinerAR
PollinTI
2010 Variation in blood lipids. Nature 466 703 704
77. FreathyRM
TimpsonNJ
LawlorDA
PoutaA
Ben-ShlomoY
2008 Common variation in the FTO gene alters diabetes-related metabolic traits to extent expected, given its effect on BMI. Diabetes 57 1419 1426
78. TimpsonN
HarbordR
Davey SmithG
ZachoJ
Tybaerg-HansenA
2009 Does greater adiposity increase blood pressure and hypertension risk? Mendelian randomization using Fto/Mc4r genotype. Hypertension 54 84 90
79. TimpsonNJ
SayersA
Davey SmithG
TobiasJH
2002 How does body fat influence bone mass in childhood? A Mendelian randomisation approach. J Bone Miner Res 24 522 533
80. TimpsonNJ
LawlorDA
HarbordRM
GauntTR
DayINM
2005 C-reactive protein and its role in metabolic syndrome: Mendelian randomisation study. Lancet 366 1954 1959
81. ZachoJ
Tybjoerg-HansenA
JensenJS
GrandeP
SillensenH
2008 Genetically elevated C-reactive protein and ischaemic vascular disease. New Engl J Med 359 1897 1908
82. EmilssonV
ThorleifssonG
ZhangB
LeonardsonAS
ZinkF
2008 Genetics of gene expression and its effect on disease. Nature 452 423 428
83. LiH
LuL
ManlyKF
CheslerEJ
BaoL
2005 Inferring gene transcriptional modulatory relations: a genetical genomics approach. Hum Mol Genet 14 1119 1125
84. GilbertSF
EpelD
2009 Ecological developmental biology: Integrating epigenetics, medicine and evolution MA, USA Sinauer Associates Inc
85. LiuZ
SallA
YangD
2008 MicroRNA: an emerging therapeutic target and intervention tool. Int J Mol Sci 9 978 999
86. AbbottA
2010 Project set to map marks on genome. Nature 463 596 597
Štítky
Interní lékařstvíČlánek vyšel v časopise
PLOS Medicine
2010 Číslo 10
- Příznivý vliv Armolipidu Plus na hladinu cholesterolu a zánětlivé parametry u pacientů s chronickým subklinickým zánětem
- Léčba bolesti u seniorů
- Co lze v terapii hypertenze očekávat od přidání perindoprilu k bisoprololu?
- Nefarmakologická léčba dyslipidémií
- Flexofytol® – přírodní revoluce v boji proti osteoartróze kloubů
Nejčtenější v tomto čísle
- Epigenetic Epidemiology of Common Complex Disease: Prospects for Prediction, Prevention, and Treatment
- Editors, Publishers, Impact Factors, and Reprint Income
- Systematic Evaluation of Serotypes Causing Invasive Pneumococcal Disease among Children Under Five: The Pneumococcal Global Serotype Project
- The Persisting Burden of Intracerebral Haemorrhage: Can Effective Treatments Be Found?