Haplotypes with copy number and single nucleotide polymorphisms in CYP2A6 locus are associated with smoking quantity in a Japanese population.
paper
Cited
Public
- Authors
- Kumasaka, Natsuhiko; Aoki, Masayuki; Okada, Yukinori; Takahashi, Atsushi; Ozaki, Kouichi; Mushiroda, Taisei; Hirota, Tomomitsu; Tamari, Mayumi; Tanaka, Toshihiro; Nakamura, Yusuke; Kamatani, Naoyuki; Kubo, Michiaki
- Year
- 2012
- Journal
- PloS one
- PMID
- 23049750
- DOI
- 10.1371/journal.pone.0044507
- PMCID
- PMC3458030
Smoking is a major public health problem, but the genetic factors associated with smoking behaviors are not fully elucidated. Here, we have conducted an integrated genome-wide association study to identify common copy number polymorphisms (CNPs) and single nucleotide polymorphisms (SNPs) associated with the number of cigarettes smoked per day (CPD) in Japanese smokers (Nβ=β17,158). Our analysis identified a common CNP with a strong effect on CPD (rs8102683; P=3.8 x 10(-42)) in the 19q13 region, encompassing the CYP2A6 locus. After adjustment for the associated CNP, we found an additional associated SNP (rs11878604; P=9.7 x 10(-30)) located 30 kb downstream of the CYP2A6 gene. Imputation of the CYP2A6 locus revealed that haplotypes underlying the CNP and the SNP corresponded to classical, functional alleles of CYP2A6 gene that regulate nicotine metabolism and explained 2% of the phenotypic variance of CPD (ANOVA F-test P=9.5 x 10(-52)). These haplotypes were also associated with smoking-related diseases, including lung cancer, chronic obstructive pulmonary disease and arteriosclerosis obliterans.
Manhattan plot showing the significance of association for all CNPs and SNPs in the genome-wide CPD analysis.The SNPs consist of both Illumina 610K chip and imputed HapMap SNPs. All CNPs and SNPs are plotted on the axis according to their positions on each chromosome against association with CPD on the axis (-value). SNPs and CNPs with -values are highlighted in green. A dark gray line shows the genome-wide significance level after Bonferroni's correction with a total of 2,312,503 SNPs and 4,256 CNPs.
Signal plots before conditioning (a), after conditioning on rs8102683 (b) and after conditioning on rs8102683 and rs11878604 (c).SNPs and CNPs are plotted on the axis according to their positions on chromosome 19 (NCBI Build 37; hg19) against association with CPD on the left axis (-value). SNPs from the 1000 genomes imputation (phase I; 2011-11-23) are indicated with circles, SNPs genotyped on the Illumina 610K chip are indicated with triangles and CNPs genotyped with PlatinumCNV using the raw signal intensity data from the chip are indicated with diamonds. SNPs in the commonly deleted region (shown by the gray shaded area) are imputed as tri-allelic SNPs with deletions (see Materials and Methods for details). All SNP associations are assessed using allele dosages (the number difference between the A and B alleles; see Materials and Methods), and the CNP associations are assessed using the posterior mean copy number dosage [8]. Recombination rates (cM/Mb) across the region are shown by the purple line plotted against the right axis. The most significant variant of the SNP or CNP for each panel is pink, and the surrounding SNPs and CNPs are color-coded to reflect the strength of LD with the top variant according to the Pearson's values.
| # | Section | Preview |
|---|---|---|
| 40 | Materials and Methods β URLs | R statistical software, http://cran.r-project.org; |
| 41 | Materials and Methods β URLs | Human Cytochrome P450 (CYP) Allele Nomenclature Committee, http://www.cypalleles.ki.se/; |
| 42 | Materials and Methods β URLs | PlatinumCNV, http://kumasakanatsuhiko.jp/projects/platinumcnv/; |
| 43 | Materials and Methods β URLs | UGDP selection growser, http://hgdp.uchicago.edu/cgi-bin/gbrowser/HGDP/; |
| 44 | Materials and Methods β URLs | 1000 Genomes Project, http://www.1000genomes.org/. |
β Prev
41β45 of 45
No entities extracted from this document yet.
No uploaded files.
Not in any collection.
| Citation | PMID | DOI | Status |
|---|---|---|---|
| BarnesCA, PlagnolV, FitzgeraldT, RedonR, MarchiniJ, et al (2008) Robust statistical method for case-control association testing with copy number variation. Nat. Genet. 40: 1245β52.10.1038/ng.206PMC278459618776912 | β | β | β |
| BaumLE, PetrieT, SoulesG, WeissN (1970) A maximization technique occurring in the statistical analysis of probabilistic functions of Markov chains. Ann. Math. Statist. 41: 164β71. | β | β | β |
| BodinL, BeaunePH, LoriotMA (2005) Determination of cytochrome P450 2D6 (CYP2D6) gene copy number by real-time quantitative pcr. J. Biomed. Biotechnol. 3: 248β253.10.1155/JBB.2005.248PMC122469816192683 | β | β | β |
| BrowningBL, BrowningSR (2009) A unified approach to genotype imputation and haplotypephase inference for large data sets of trios and unrelated individuals. Am. J. Hum. Genet. 84: 210β23.10.1016/j.ajhg.2009.01.005PMC266800419200528 | β | β | β |
| ConradDF, PintoD, RedonR, FeukL, GokcumenO, et al (2010) Origins and functional impact of copy number variation in the human genome. Nature. 464: 704β12.10.1038/nature08516PMC333074819812545 | β | β | β |
| DempsterER, LernerIM (1950) Heritability of threshold characters. Genetics 35: 212β236.1724734410.1093/genetics/35.2.212PMC1209482 | β | β | β |
| DevlinB, RoederK (1999) Genomic control for association studies. Biometrics 55: 997β1004.1131509210.1111/j.0006-341x.1999.00997.x | β | β | β |
| FujiedaM, YamazakiH, SaitoT, KiyotaniK, GyamfiMA, et al (2004) Evaluation of CYP2A6 genetic polymorphisms as determinants of smoking behavior and tobacco-related lung cancer risk in male japanese smokers. Pharmacogenet. Genomics. 25: 2451β8.10.1093/carcin/bgh25815308589 | β | β | β |
| GirirajanS, CampbellCD, EichlerEE (2011) Human copy number variation and complex genetic disease. Annu. Rev. Genet. 45: 203β26.10.1146/annurev-genet-102209-163544PMC666261121854229 | β | β | β |
| HosonoN, KatoM, KiyotaniK, MushirodaT, TakataS, et al (2009) CYP2D6 genotyping for functional-gene dosage analysis by allele copy number detection. Clinical Chemistry. 55: 1546β54.10.1373/clinchem.2009.12362019541866 | β | β | β |
| Ikeda F, Ninomiya T, Doi Y, Hata J, Fukuhara M, et al.. (2011) Smoking cessation improves mortality in japanese men: the hisayama study. Tob Control. : Published Online First.10.1136/tc.2010.03936221659447 | β | β | β |
| KoopmansJR, SlutskeWS, HeathAC, NealeMC, BoomsmaDI (1999) The genetics of smoking initiation and quantity smoked in dutch adolescent and young adult twins. Behav Genet. 29: 383β93.10.1023/a:102161871973510857244 | β | β | β |
| KornJM, KuruvillaFG, McCarrollSA, WysokerA, NemeshJ, et al (2008) Integrated genotype calling and association analysis of SNPs, common copy number polymorphisms and rare CNVs. Nat. Genet. 40: 1253β60.10.1038/ng.237PMC275653418776909 | β | β | β |
| KumasakaN, FujisawaN, HosonoN, OkadaY, TakahashiA, et al (2011) PlatinumCNV: a Bayesian Gaussian mixture model for genotyping copy number polymorphisms using SNP array signal intensity data. Genet. Epidemiol. 35: 831β844.10.1002/gepi.2063322125222 | β | β | β |
| KumasakaN, Yamaguchi-KabataY, TakahashiA, KuboM, NakamuraY, et al (2010) Establishment of a standardized system to perform population structure analyses with limited sample size or with different sets of snp genotypes. Journal of Human Genetics 55: 525β33.2055533510.1038/jhg.2010.63 | β | β | β |
| LiB, LealSM (2008) Methods for detecting associations with rare variants for common diseases: application to analysis of sequence data. Am J Hum Genet 83: 311β21.1869168310.1016/j.ajhg.2008.06.024PMC2842185 | β | β | β |
| LiMD, ChengR, MaJZ, SwanGE (2003) A meta-analysis of estimated genetic and environmental effects on smoking behavior in male and female adult twins. Addiction. 98: 23β31.10.1046/j.1360-0443.2003.00295.x12492752 | β | β | β |
| LiuDJ, LealSM (2010) A novel adaptive method for the analysis of next-generation sequencing data to detect complex trait associations with rare variants due to gene main effects and interactions. PLoS Genet 6: e1001156.2097624710.1371/journal.pgen.1001156PMC2954824 | β | β | β |
| LiuJZ, TozziF, WaterworthDM, PillaiSG, MugliaP, et al (2010) Meta-analysis and imputation refines the association of 15q25 with smoking quantity. Nat Genet. 42: 436β40.10.1038/ng.572PMC361298320418889 | β | β | β |
| MadsenBE, BrowningSR (2009) A groupwise association test for rare mutations using a weighted sum statistic. PLoS Genet 5: e1000384.1921421010.1371/journal.pgen.1000384PMC2633048 | β | β | β |
| ManolioTA, CollinsFS, CoxNJ, GoldsteinDB, HindorffLA, et al (2009) Finding the missing heritability of complex diseases. Nature. 461: 747β53.10.1038/nature08494PMC283161319812666 | β | β | β |
| McKennaA, HannaM, BanksE, SivachenkoA, CibulskisK, et al (2010) The Genome Analysis Toolkit: A MapReduce framework for analyzing next-generation DNA sequencing data. Genome Res. 20: 1297β1303.10.1101/gr.107524.110PMC292850820644199 | β | β | β |
| McLachlan GJ, Krishman T (1997) The EM Algorithm and Extensions. New York: John Wiley & Sons. | β | β | β |
| MorrisAP, ZegginiE (2010) An evaluation of statistical approaches to rare variant analysis in genetic association studies. Genet Epidemiol 34: 188β93.1981002510.1002/gepi.20450PMC2962811 | β | β | β |
| NakamuraY (2007) The biobank japan project. Clin. Adv. Hematol. Oncol. 5: 696β7.17982410 | β | β | β |
| OkadaY, HirotaT, KamataniY, TakahashiA, OhmiyaH, et al (2011) Identification of nine novel loci associated with white blood cell subtypes in a Japanese population. PLoS Genet. 7: e1002067.10.1371/journal.pgen.1002067PMC312809521738478 | β | β | β |
| PlagnolV, CooperJD, ToddJA, ClaytonDG (2007) A method to address differential bias in genotyping in large-scale association studies. PLoS Genet. 3: e74.10.1371/journal.pgen.0030074PMC186895117511519 | β | β | β |
| PriceAL, PattersonNJ, PlengeRM, WeinblattME, ShadickNA, et al (2006) Principal components analysis corrects for stratification in genome-wide association studies. Nat Genet. 38: 904β9.10.1038/ng184716862161 | β | β | β |
| QuesenberryCP, HalesC (1980) Concentration bands for uniformity plots. J. Statist. Comput. Simul. 11: 41β53. | β | β | β |
| SabetiPC, SchaffnerSF, FryB, LohmuellerJ, VarillyP, et al (2006) Positive natural selection in the human lineage. Science 312: 1614β1620.1677804710.1126/science.1124309 | β | β | β |
| SchoedelKA, HoffmannEB, RaoY, SellersEM, TyndaleRF (2004) Ethnic variation in CYP2A6 and association of genetically slow nicotine metabolism and smoking in adult caucasians. Pharmacogenetics 14: 615β26.1547573510.1097/00008571-200409000-00006 | β | β | β |
| StramDO, PearceCL, BretskyP, FreedmanM, HirschhornJN, et al (2003) Modeling and E-M estimation of haplotype-specific relative risks from genotype data for a case-control study of unrelated individuals. Hum. Hered. 55: 179β90.10.1159/00007320214566096 | β | β | β |
| SwanGE, BenowitzNL, LessovCN, JacovP, TyndaleRF, et al (2005) Nicotine metabolism; the impact of CYP2A6 on estimates of additive genetic influence. Carcinogenesis 15: 115β25.10.1097/01213011-200502000-0000715861035 | β | β | β |
| The International HapMapConsortium (2007) A second generation human haplotype map of over 3.1 million SNPs. Nature. 449: 851β61.10.1038/nature06258PMC268960917943122 | β | β | β |
| ThorgeirssonTE, GudbjartssonDF, SurakkaI, VinkJM, AminN, et al (2010) Sequence variants at CHRNB3-CHRNA6 and CYP2A6 affect smoking behavior. Nat Genet. 42: 448β53.10.1038/ng.573PMC308060020418888 | β | β | β |
| Tobacco and GeneticsConsortium (2010) Genome-wide meta-analyses identify multiple loci associated with smoking behavior. Nat Genet. 42: 441β7.10.1038/ng.571PMC291460020418890 | β | β | β |
| Wellcome Trust Case ControlConsortium (2010) Genome-wide association study of CNVs in 16,000 cases of eight common diseases and 3,000 shared controls. Nature. 464: 713β20.10.1038/nature08979PMC289233920360734 | β | β | β |
| Yamaguchi-KabataY, NakazonoK, AAT, SaitoS, HosonoN, et al (2008) Japanese population structure, based on SNP genotypes from 7003 individuals compared to other ethnic groups: effects on population-based association studies. Am. J. Hum. Genet. 83: 445β56.10.1016/j.ajhg.2008.08.019PMC256192818817904 | β | β | β |
In this knowledge base
External
| Title | Authors | Journal | Year | Link |
|---|---|---|---|---|
| Fine-mapping the CYP2A6 regional association with nicotine metabolism among African American smokers. | Pouget JG et al. | β | 2025 | β |
| Common and distinguishing genetic factors for substance use behavior and disorder: an integrated analysis of genomic and transcriptomic studies from both human and animal studies. | Chang XW et al. | β | 2022 | β |
| Genetic differences in nicotine sensitivity and metabolism in C57BL/6J and NOD/ShiLtJ mouse strains. | Seemiller LR et al. | β | 2022 | β |
| Gene-based association analysis reveals involvement of LAMA5 and cell adhesion pathways in nicotine dependence in African- and European-American samples. | Fan R et al. | β | 2021 | β |
| Association of CYP2A6 gene deletion with cancers in Japanese elderly: an autopsy study. | Abudushataer M et al. | β | 2020 | β |
| Genetics of Smoking Behaviors in American Indians. | Henderson JA et al. | β | 2020 | β |
| Meta-analysis of up to 622,409 individuals identifies 40 novel smoking behaviour associated genetic loci. | Erzurumluoglu AM et al. | β | 2020 | β |
| Translational Molecular Approaches in Substance Abuse Research. | Fulton SL et al. | β | 2020 | β |
| Genome-Wide Variants Shared Between Smoking Quantity and Schizophrenia on 15q25 Are Associated With CHRNA5 Expression in the Brain. | Ohi K et al. | β | 2019 | β |
| Genome-Wide Association Study of Heavy Smoking and Daily/Nondaily Smoking in the Hispanic Community Health Study/Study of Latinos (HCHS/SOL). | Saccone NL et al. | β | 2018 | β |
| Human Genetics of Addiction: New Insights and Future Directions. | Hancock DB et al. | β | 2018 | β |
| The Value of Biosamples in Smoking Cessation Trials: A Review of Genetic, Metabolomic, and Epigenetic Findings. | Saccone NL et al. | β | 2018 | β |
| Tobacco biomarkers and genetic/epigenetic analysis to investigate ethnic/racial differences in lung cancer risk among smokers. | Murphy SE et al. | β | 2018 | β |
| Trends in cigarette consumption and time to first cigarette on awakening from 2002 to 2015 in the USA: new insights into the ongoing tobacco epidemic. | Goodwin RD et al. | β | 2018 | β |
| Aldehyde Dehydrogenase 2 Polymorphism Is a Predictor of Smoking Cessation. | Masaoka H et al. | β | 2017 | β |
| Combination of ALDH2 and ADH1B polymorphisms is associated with smoking initiation: A large-scale cross-sectional study in a Japanese population. | Masaoka H et al. | β | 2017 | β |
| CYP2A6 genetic polymorphisms and biomarkers of tobacco smoke constituents in relation to risk of lung cancer in the Singapore Chinese Health Study. | Yuan JM et al. | β | 2017 | β |
| Genome-wide association study implicates<i>CHRNA2</i>in cannabis use disorder | Demontis D et al. | β | 2017 | β |
| Nicotine Metabolism and Smoking: Ethnic Differences in the Role of P450 2A6. | Murphy SE | β | 2017 | β |
| Significant association of the CHRNB3-CHRNA6 gene cluster with nicotine dependence in the Chinese Han population. | Wen L et al. | β | 2017 | β |
| The genetic epidemiology of substance use disorder: A review. | Prom-Wormley EC et al. | β | 2017 | β |
| Converging findings from linkage and association analyses on susceptibility genes for smoking and other addictions. | Yang J et al. | β | 2016 | β |
| CYP2A6 Longitudinal Effects in Young Smokers. | Cannon DS et al. | β | 2016 | β |
| Genetic determinants of CYP2A6 activity across racial/ethnic groups with different risks of lung cancer and effect on their smoking intensity. | Park SL et al. | β | 2016 | β |
| Genetic determinants of cytochrome P450 2A6 activity and biomarkers of tobacco smoke exposure in relation to risk of lung cancer development in the Shanghai cohort study. | Yuan JM et al. | β | 2016 | β |
| Genome-Wide Association of the Laboratory-Based Nicotine Metabolite Ratio in Three Ancestries. | Baurley JW et al. | β | 2016 | β |
| An essential role of acetylcholine-glutamate synergy at habenular synapses in nicotine dependence. | Frahm S et al. | β | 2015 | β |
| EGLN2 and RNF150 genetic variants are associated with chronic obstructive pulmonary disease risk in the Chinese population. | Ding Y et al. | β | 2015 | β |
| Epigenomic mapping and effect sizes of noncoding variants associated with psychotropic drug response. | Higgins GA et al. | β | 2015 | β |
| Genotyping of wild-type cytochrome P450 2A6 and whole-gene deletion using human blood samples and a multiplex real-time polymerase chain reaction method with dual-labeled probes. | Shimizu M et al. | β | 2015 | β |
| The contribution of common genetic variation to nicotine and cotinine glucuronidation in multiple ethnic/racial populations. | Patel YM et al. | β | 2015 | β |
| Genome-wide association study of smoking behaviours among Bangladeshi adults. | Argos M et al. | β | 2014 | β |
| Identification of CHRNA5 rare variants in African-American heavy smokers. | Doyle GA et al. | β | 2014 | β |
| Nicotine N-glucuronidation relative to N-oxidation and C-oxidation and UGT2B10 genotype in five ethnic/racial groups. | Murphy SE et al. | β | 2014 | β |
| Risk loci for chronic obstructive pulmonary disease: a genome-wide association study and meta-analysis. | Cho MH et al. | β | 2014 | β |
| Genetic susceptibility to lung cancer and co-morbidities. | Yang IA et al. | β | 2013 | β |
| Pharmacogenetics of chronic obstructive pulmonary disease. | Hizawa N | β | 2013 | β |