Assessing Causality in the Association between Child Adiposity and Physical Activity Levels: A Mendelian Randomization Analysis
Background:
Cross-sectional studies have shown that objectively measured physical activity is associated with childhood adiposity, and a strong inverse dose–response association with body mass index (BMI) has been found. However, few studies have explored the extent to which this association reflects reverse causation. We aimed to determine whether childhood adiposity causally influences levels of physical activity using genetic variants reliably associated with adiposity to estimate causal effects.
Methods and Findings:
The Avon Longitudinal Study of Parents and Children collected data on objectively assessed activity levels of 4,296 children at age 11 y with recorded BMI and genotypic data. We used 32 established genetic correlates of BMI combined in a weighted allelic score as an instrumental variable for adiposity to estimate the causal effect of adiposity on activity.
In observational analysis, a 3.3 kg/m2 (one standard deviation) higher BMI was associated with 22.3 (95% CI, 17.0, 27.6) movement counts/min less total physical activity (p = 1.6×10−16), 2.6 (2.1, 3.1) min/d less moderate-to-vigorous-intensity activity (p = 3.7×10−29), and 3.5 (1.5, 5.5) min/d more sedentary time (p = 5.0×10−4). In Mendelian randomization analyses, the same difference in BMI was associated with 32.4 (0.9, 63.9) movement counts/min less total physical activity (p = 0.04) (∼5.3% of the mean counts/minute), 2.8 (0.1, 5.5) min/d less moderate-to-vigorous-intensity activity (p = 0.04), and 13.2 (1.3, 25.2) min/d more sedentary time (p = 0.03). There was no strong evidence for a difference between variable estimates from observational estimates. Similar results were obtained using fat mass index. Low power and poor instrumentation of activity limited causal analysis of the influence of physical activity on BMI.
Conclusions:
Our results suggest that increased adiposity causes a reduction in physical activity in children and support research into the targeting of BMI in efforts to increase childhood activity levels. Importantly, this does not exclude lower physical activity also leading to increased adiposity, i.e., bidirectional causation.
Please see later in the article for the Editors' Summary
Vyšlo v časopise:
Assessing Causality in the Association between Child Adiposity and Physical Activity Levels: A Mendelian Randomization Analysis. PLoS Med 11(3): e32767. doi:10.1371/journal.pmed.1001618
Kategorie:
Research Article
prolekare.web.journal.doi_sk:
https://doi.org/10.1371/journal.pmed.1001618
Souhrn
Background:
Cross-sectional studies have shown that objectively measured physical activity is associated with childhood adiposity, and a strong inverse dose–response association with body mass index (BMI) has been found. However, few studies have explored the extent to which this association reflects reverse causation. We aimed to determine whether childhood adiposity causally influences levels of physical activity using genetic variants reliably associated with adiposity to estimate causal effects.
Methods and Findings:
The Avon Longitudinal Study of Parents and Children collected data on objectively assessed activity levels of 4,296 children at age 11 y with recorded BMI and genotypic data. We used 32 established genetic correlates of BMI combined in a weighted allelic score as an instrumental variable for adiposity to estimate the causal effect of adiposity on activity.
In observational analysis, a 3.3 kg/m2 (one standard deviation) higher BMI was associated with 22.3 (95% CI, 17.0, 27.6) movement counts/min less total physical activity (p = 1.6×10−16), 2.6 (2.1, 3.1) min/d less moderate-to-vigorous-intensity activity (p = 3.7×10−29), and 3.5 (1.5, 5.5) min/d more sedentary time (p = 5.0×10−4). In Mendelian randomization analyses, the same difference in BMI was associated with 32.4 (0.9, 63.9) movement counts/min less total physical activity (p = 0.04) (∼5.3% of the mean counts/minute), 2.8 (0.1, 5.5) min/d less moderate-to-vigorous-intensity activity (p = 0.04), and 13.2 (1.3, 25.2) min/d more sedentary time (p = 0.03). There was no strong evidence for a difference between variable estimates from observational estimates. Similar results were obtained using fat mass index. Low power and poor instrumentation of activity limited causal analysis of the influence of physical activity on BMI.
Conclusions:
Our results suggest that increased adiposity causes a reduction in physical activity in children and support research into the targeting of BMI in efforts to increase childhood activity levels. Importantly, this does not exclude lower physical activity also leading to increased adiposity, i.e., bidirectional causation.
Please see later in the article for the Editors' Summary
Zdroje
1. NessAR, LearySD, MattocksC, BlairSN, ReillyJJ, et al. (2007) Objectively measured physical activity and fat mass in a large cohort of children. PLoS Med 4: e97.
2. EkelundU, SardinhaLB, AnderssenSA, HarroM, FranksPW, et al. (2004) Associations between objectively assessed physical activity and indicators of body fatness in 9- to 10-y-old European children: a population-based study from 4 distinct regions in Europe (the European Youth Heart Study). Am J Clin Nutr 80: 584–590.
3. DenckerM, ThorssonO, KarlssonMK, LindenC, EibergS, et al. (2006) Daily physical activity related to body fat in children aged 8–11 years. J Pediatr 149: 38–42.
4. TrostSG, KerrLM, WardDS, PateRR (2001) Physical activity and determinants of physical activity in obese and non-obese children. Int J Obes Relat Metab Disord 25: 822–829.
5. OrtegaFB, RuizJR, SjostromM (2007) Physical activity, overweight and central adiposity in Swedish children and adolescents: the European Youth Heart Study. Int J Behav Nutr Phys Act 4: 61.
6. Jimenez-PavonD, KellyJ, ReillyJJ (2010) Associations between objectively measured habitual physical activity and adiposity in children and adolescents: systematic review. Int J Pediatr Obes 5: 3–18.
7. MetcalfBS, HoskingJ, JefferyAN, VossLD, HenleyW, et al. (2011) Fatness leads to inactivity, but inactivity does not lead to fatness: a longitudinal study in children (EarlyBird 45). Arch Dis Child 96: 942–947.
8. LukeA, CooperRS (2013) Physical activity does not influence obesity risk: time to clarify the public health message. Int J Epidemiol 42: 1831–1836.
9. ChristiansenE, SwannA, SorensenTI (2008) Feedback models allowing estimation of thresholds for self-promoting body weight gain. J Theor Biol 254: 731–736.
10. CookCM, SchoellerDA (2011) Physical activity and weight control: conflicting findings. Curr Opin Clin Nutr Metab Care 14: 419–424.
11. KamathCC, VickersKS, EhrlichA, McGovernL, JohnsonJ, et al. (2008) Behavioral interventions to prevent childhood obesity: a systematic review and metaanalyses of randomized trials. J Clin Endocrinol Metab 93: 4606–4615.
12. HarrisKC, KuramotoLK, SchulzerM, RetallackJE (2009) Effect of school-based physical activity interventions on body mass index in children: a meta-analysis. CMAJ 180: 719–726.
13. McGovernL, JohnsonJN, PauloR, HettingerA, SinghalV, et al. (2008) Clinical review: treatment of pediatric obesity: a systematic review and meta-analysis of randomized trials. J Clin Endocrinol Metab 93: 4600–4605.
14. SunC, PezicA, TikellisG, PonsonbyAL, WakeM, et al. (2013) Effects of school-based interventions for direct delivery of physical activity on fitness and cardiometabolic markers in children and adolescents: a systematic review of randomized controlled trials. Obes Rev 14: 818–838.
15. RiddochCJ, LearySD, NessAR, BlairSN, DeereK, et al. (2009) Prospective associations between objective measures of physical activity and fat mass in 12–14 year old children: the Avon Longitudinal Study of Parents and Children (ALSPAC). BMJ 339: b4544.
16. MooreLL, GaoD, BradleeML, CupplesLA, Sundarajan-RamamurtiA, et al. (2003) Does early physical activity predict body fat change throughout childhood? Prev Med 37: 10–17.
17. RemmersT, SleddensEF, GubbelsJS, de VriesSI, MommersM, et al. (2014) Relationship between physical activity and the development of body mass index in children. Med Sci Sports Exerc 46: 177–184.
18. ReichertFF, Baptista MenezesAM, WellsJC, Carvalho DumithS, HallalPC (2009) Physical activity as a predictor of adolescent body fatness: a systematic review. Sports Med 39: 279–294.
19. WilksDC, SharpSJ, EkelundU, ThompsonSG, ManderAP, et al. (2011) Objectively measured physical activity and fat mass in children: a bias-adjusted meta-analysis of prospective studies. PLoS ONE 6: e17205.
20. EkelundU, LuanJ, SherarLB, EsligerDW, GriewP, et al. (2012) Moderate to vigorous physical activity and sedentary time and cardiometabolic risk factors in children and adolescents. JAMA 307: 704–712.
21. HallalPC, ReichertFF, EkelundU, DumithSC, MenezesAM, et al. (2012) Bidirectional cross-sectional and prospective associations between physical activity and body composition in adolescence: birth cohort study. J Sports Sci 30: 183–190.
22. HjorthMF, ChaputJP, RitzC, DalskovSM, AndersenR, et al. (2013) Fatness predicts decreased physical activity and increased sedentary time, but not vice versa: support from a longitudinal study in 8- to 11-year-old children. Int J Obes (Lond) E-pub ahead of print.
23. Davey SmithG, EbrahimS (2003) ‘Mendelian randomization’: can genetic epidemiology contribute to understanding environmental determinants of disease? Int J Epidemiol 32: 1–22.
24. Davey SmithG, LawlorDA, HarbordR, TimpsonN, DayI, et al. (2007) Clustered environments and randomized genes: a fundamental distinction between conventional and genetic epidemiology. PLoS Med 4: e352.
25. LawlorDA, HarbordRM, SterneJA, TimpsonN, Davey SmithG (2008) Mendelian randomization: using genes as instruments for making causal inferences in epidemiology. Stat Med 27: 1133–1163.
26. DidelezV, SheehanN (2007) Mendelian randomization as an instrumental variable approach to causal inference. Stat Methods Med Res 16: 309–330.
27. TimpsonNJ, HarbordR, Davey SmithG, ZachoJ, Tybjaerg-HansenA, et al. (2009) Does greater adiposity increase blood pressure and hypertension risk?: Mendelian randomization using the FTO/MC4R genotype. Hypertension 54: 84–90.
28. LawlorDA, HarbordRM, Tybjaerg-HansenA, PalmerTM, ZachoJ, et al. (2011) Using genetic loci to understand the relationship between adiposity and psychological distress: a Mendelian randomization study in the Copenhagen General Population Study of 53,221 adults. J Intern Med 269: 525–537.
29. LawlorDA, TimpsonNJ, HarbordRM, LearyS, NessA, et al. (2008) Exploring the developmental overnutrition hypothesis using parental-offspring associations and FTO as an instrumental variable. PLoS Med 5: e33.
30. NordestgaardBG, PalmerTM, BennM, ZachoJ, Tybjaerg-HansenA, et al. (2012) The effect of elevated body mass index on ischemic heart disease risk: causal estimates from a Mendelian randomisation approach. PLoS Med 9: e1001212.
31. TimpsonNJ, NordestgaardBG, HarbordRM, ZachoJ, FraylingTM, et al. (2011) C-reactive protein levels and body mass index: elucidating direction of causation through reciprocal Mendelian randomization. Int J Obes (Lond) 35: 300–308.
32. WelshP, PoliseckiE, RobertsonM, JahnS, BuckleyBM, et al. (2010) Unraveling the directional link between adiposity and inflammation: a bidirectional Mendelian randomization approach. J Clin Endocrinol Metab 95: 93–99.
33. SpeliotesEK, WillerCJ, BerndtSI, MondaKL, ThorleifssonG, et al. (2010) Association analyses of 249,796 individuals reveal 18 new loci associated with body mass index. Nat Genet 42: 937–948.
34. BoydA, GoldingJ, MacleodJ, LawlorDA, FraserA, et al. (2013) Cohort profile: the ‘children of the 90s’—the index offspring of the Avon Longitudinal Study of Parents and Children. Int J Epidemiol 42: 111–127.
35. FraserA, Macdonald-WallisC, TillingK, BoydA, GoldingJ, et al. (2013) Cohort profile: the Avon Longitudinal Study of Parents and Children: ALSPAC mothers cohort. Int J Epidemiol 42: 97–110.
36. GarnSM, LeonardWR, HawthorneVM (1986) Three limitations of the body mass index. Am J Clin Nutr 44: 996–997.
37. PrenticeAM, JebbSA (2001) Beyond body mass index. Obes Rev 2: 141–147.
38. RiddochCJ, MattocksC, DeereK, SaundersJ, KirkbyJ, et al. (2007) Objective measurement of levels and patterns of physical activity. Arch Dis Child 92: 963–969.
39. MattocksC, LearyS, NessA, DeereK, SaundersJ, et al. (2007) Calibration of an accelerometer during free-living activities in children. Int J Pediatr Obes 2: 218–226.
40. MattocksC, NessA, LearyS, TillingK, BlairSN, et al. (2008) Use of accelerometers in a large field-based study of children: protocols, design issues, and effects on precision. J Phys Act Health 5 (Suppl 1) S98–S111.
41. LiY, WillerC, SannaS, AbecasisG (2009) Genotype imputation. Annu Rev Genomics Hum Genet 10: 387–406.
42. LiY, WillerCJ, DingJ, ScheetP, AbecasisGR (2010) MaCH: using sequence and genotype data to estimate haplotypes and unobserved genotypes. Genet Epidemiol 34: 816–834.
43. PalmerTM, LawlorDA, HarbordRM, SheehanNA, TobiasJH, et al. (2012) Using multiple genetic variants as instrumental variables for modifiable risk factors. Stat Methods Med Res 21: 223–242.
44. ReillyJJ, ArmstrongJ, DorostyAR, EmmettPM, NessA, et al. (2005) Early life risk factors for obesity in childhood: cohort study. BMJ 330: 1357–1359.
45. StaigerD, StockJH (1997) Instrumental variables regression with weak instruments. Econometrica 65: 557–586.
46. Baum C, Schaffer M, Stillman S (2007) IVENDOG: Stata module to calculate Durbin-Wu-Hausman endogeneity test after ivreg. Statistical Software Components S494401. Boston: Boston College Department of Economics.
47. Davey SmithG, EbrahimS (2004) Mendelian randomization: prospects, potentials, and limitations. Int J Epidemiol 33: 30–42.
48. Davey SmithG (2011) Use of genetic markers and gene-diet interactions for interrogating population-level causal influences of diet on health. Genes Nutr 6: 27–43.
49. De MoorMH, LiuYJ, BoomsmaDI, LiJ, HamiltonJJ, et al. (2009) Genome-wide association study of exercise behavior in Dutch and American adults. Med Sci Sports Exerc 41: 1887–1895.
50. KimJ, OhS, MinH, KimY, ParkT (2011) Practical issues in genome-wide association studies for physical activity. Ann N Y Acad Sci 1229: 38–44.
51. EvansDM, VisscherPM, WrayNR (2009) Harnessing the information contained within genome-wide association studies to improve individual prediction of complex disease risk. Hum Mol Genet 18: 3525–3531.
52. PurcellSM, WrayNR, StoneJL, VisscherPM, O'DonovanMC, et al. (2009) Common polygenic variation contributes to risk of schizophrenia and bipolar disorder. Nature 460: 748–752.
53. de los CamposG, GianolaD, AllisonDB (2010) Predicting genetic predisposition in humans: the promise of whole-genome markers. Nat Rev Genet 11: 880–886.
54. YangJ, BenyaminB, McEvoyBP, GordonS, HendersAK, et al. (2010) Common SNPs explain a large proportion of the heritability for human height. Nat Genet 42: 565–569.
55. WrayNR, YangJ, HayesBJ, PriceAL, GoddardME, et al. (2013) Pitfalls of predicting complex traits from SNPs. Nat Rev Genet 14: 507–515.
56. YangJ, LeeSH, GoddardME, VisscherPM (2011) GCTA: a tool for genome-wide complex trait analysis. Am J Hum Genet 88: 76–82.
57. PurcellS, NealeB, Todd-BrownK, ThomasL, FerreiraMAR, et al. (2007) PLINK: a tool set for whole-genome association and population-based linkage analyses. Am J Hum Genet 81: 559–575.
58. AngristJD, KruegerAB (1995) Split-sample instrumental variables estimates of the return to schooling. J Bus Econ Stat 13: 225–235.
59. DerSimonianR, LairdN (1986) Meta-analysis in clinical trials. Control Clin Trials 7: 177–188.
60. ColeTJ, BellizziMC, FlegalKM, DietzWH (2000) Establishing a standard definition for child overweight and obesity worldwide: international survey. BMJ 320: 1240–1243.
61. TimpsonNJ, EmmettPM, FraylingTM, RogersI, HattersleyAT, et al. (2008) The fat mass- and obesity-associated locus and dietary intake in children. Am J Clin Nutr 88: 971–978.
62. den HoedM, EkelundU, BrageS, GrontvedA, ZhaoJH, et al. (2010) Genetic susceptibility to obesity and related traits in childhood and adolescence: influence of loci identified by genome-wide association studies. Diabetes 59: 2980–2988.
63. BradfieldJP, TaalHR, TimpsonNJ, ScheragA, LecoeurC, et al. (2012) A genome-wide association meta-analysis identifies new childhood obesity loci. Nat Genet 44: 526–531.
64. KilpelainenTO, ZillikensMC, StancakovaA, FinucaneFM, RiedJS, et al. (2011) Genetic variation near IRS1 associates with reduced adiposity and an impaired metabolic profile. Nat Genet 43: 753–760.
65. SallisJF, ProchaskaJJ, TaylorWC (2000) A review of correlates of physical activity of children and adolescents. Med Sci Sports Exerc 32: 963–975.
66. SzendroediJ, RodenM (2008) Mitochondrial fitness and insulin sensitivity in humans. Diabetologia 51: 2155–2167.
67. JanssenI, LeBlancAG (2010) Systematic review of the health benefits of physical activity and fitness in school-aged children and youth. Int J Behav Nutr Phys Act 7: 40.
68. StrongWB, MalinaRM, BlimkieCJ, DanielsSR, DishmanRK, et al. (2005) Evidence based physical activity for school-age youth. J Pediatr 146: 732–737.
69. LearySD, NessAR, Davey SmithG, MattocksC, DeereK, et al. (2008) Physical activity and blood pressure in childhood—findings from a population-based study. Hypertension 51: 92–98.
70. EkelundU, BrageS, FrobergK, HarroM, AnderssenSA, et al. (2006) TV viewing and physical activity are independently associated with metabolic risk in children: the European Youth Heart Study. PLoS Med 3: 2449–2457.
71. BrageS, WedderkoppN, EkelundU, FranksPW, WarehamNJ, et al. (2004) Objectively measured physical activity correlates with indices of insulin resistance in Danish children. the European Youth Heart Study (EYHS). Int J Obes 28: 1503–1508.
72. AndersenLB, RiddochC, KriemlerS, HillsA (2011) Physical activity and cardiovascular risk factors in children. Br J Sports Med 45: 871–876.
73. LukeA, DugasLR, Durazo-ArvizuRA, CaoGC, CooperRS (2011) Assessing physical activity and its relationship to cardiovascular risk factors: NHANES 2003–2006. BMC Public Health 11: 387.
74. DeforcheB, HaerensL, de BourdeaudhuijI (2011) How to make overweight children exercise and follow the recommendations. Int J Pediatr Obes 6: 35–41.
75. WesterterpKR, SpeakmanJR (2008) Physical activity energy expenditure has not declined since the 1980s and matches energy expenditures of wild mammals. Int J Obes (Lond) 32: 1256–1263.
76. SwinburnB, SacksG, RavussinE (2009) Increased food energy supply is more than sufficient to explain the US epidemic of obesity. Am J Clin Nutr 90: 1453–1456.
77. StubbeJH, BoomsmaDI, De GeusEJ (2005) Sports participation during adolescence: a shift from environmental to genetic factors. Med Sci Sports Exerc 37: 563–570.
78. FranksPW, RavussinE, HansonRL, HarperIT, AllisonDB, et al. (2005) Habitual physical activity in children: the role of genes and the environment. Am J Clin Nutr 82: 901–908.
79. FisherA, van JaarsveldCH, LlewellynCH, WardleJ (2010) Environmental influences on children's physical activity: quantitative estimates using a twin design. PLoS ONE 5: e10110.
Štítky
Interné lekárstvoČlánok vyšiel v časopise
PLOS Medicine
2014 Číslo 3
- Mobilní aplikace jako nová možnost v prevenci napadení klíštětem
- Hydroresponzivní krytí v epitelizační fázi hojení rány
- Parazitičtí červi v terapii Crohnovy choroby a dalších zánětlivých autoimunitních onemocnění
- Vztah mezi statiny a rizikem vzniku nádorových onemocnění − metaanalýza
- Metabolit živočišné stravy produkovaný střevní mikroflórou zvyšuje riziko závažných kardiovaskulárních příhod
Najčítanejšie v tomto čísle
- and Water, Sanitation, and Hygiene: A Committed Relationship
- Representation and Misrepresentation of Scientific Evidence in Contemporary Tobacco Regulation: A Review of Tobacco Industry Submissions to the UK Government Consultation on Standardised Packaging
- The Role of Viral Introductions in Sustaining Community-Based HIV Epidemics in Rural Uganda: Evidence from Spatial Clustering, Phylogenetics, and Egocentric Transmission Models
- How Can Journals Respond to Threats of Libel Litigation?