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Rural environments reduce the genetic influence on adolescent substance use and rule-breaking behavior

Published online by Cambridge University Press:  01 October 2007

L. N. Legrand ,
M. Keyes ,
M. McGue ,
W. G. Iacono  and
R. F. Krueger
L. N. Legrand*
Affiliation:
Department of Psychology, University of Minnesota, Twin Cities Campus, Minneapolis, MN, USA
M. Keyes
Affiliation:
Department of Psychology, University of Minnesota, Twin Cities Campus, Minneapolis, MN, USA
M. McGue
Affiliation:
Department of Psychology, University of Minnesota, Twin Cities Campus, Minneapolis, MN, USA
W. G. Iacono
Affiliation:
Department of Psychology, University of Minnesota, Twin Cities Campus, Minneapolis, MN, USA
R. F. Krueger
Affiliation:
Department of Psychology, University of Minnesota, Twin Cities Campus, Minneapolis, MN, USA
*
*Address for correspondence: Dr L. N. Legrand, University of Minnesota, Department of Psychology, 75 East River Road, Minneapolis, MN 55455, USA. (Email: legra002@umn.edu)
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Abstract

Background

There is increasing evidence that certain environmental factors can modify genetic effects. This is an important area of investigation as such work will help to guide the development of new intervention programs. In this paper, we address whether rural environments moderate the genetic influence on adolescent substance use and rule-breaking behavior (i.e. externalizing psychopathology).

Method

Over 1200 Minnesotan 17-year-old twins were classified as either urban or rural. Externalizing behavior was operationalized as the use and abuse of alcohol and drugs along with symptoms of conduct, oppositional defiant, and antisocial personality disorders. Biometric factor modeling estimated whether the relative contribution of genetic and shared environmental factors varied from urban to rural settings.

Results

Residency effects reached statistical significance in the male sample only. In urban environments, externalizing behavior was substantially influenced by genetic factors, but in rural environments, shared environmental factors became more influential. This was apparent at both the individual-variable and factor levels.

Conclusions

These findings suggest a gene–environment interaction in the development of male adolescents' problem behaviors, including substance use. The results fit within an expanding literature demonstrating both the contextual nature of the heritability statistic and how certain environments may constrain the expression of genetic tendencies.

Keywords

Gene–environment interactionheritabilityruralurban
Type
Original Articles
Information
Psychological Medicine , Volume 38 , Issue 9 , September 2008 , pp. 1341 - 1350
Copyright
Copyright © 2007 Cambridge University Press

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References

Akaike, H (1987). Factor analysis and AIC. Psychometrika 52, 317332.Google Scholar
Boomsma, DI, de Geus, EJC, van Baal, CGM, Koopmans, JR (1999). A religious upbringing reduces the influence of genetic factors on disinhibition: evidence for interaction between genotype and environment on personality. Twin Research 2, 115125.Google Scholar
Burt, SA, McGue, M, DeMarte, JA, Krueger, RF, Iacono, WG (2006). Timing of menarche and the origins of conduct disorder. Archives of General Psychiatry 63, 890896.CrossRefGoogle ScholarPubMed
Caspi, A, Moffitt, TE, Cannon, M, McClay, J, Murray, R, Harrington, H, Taylor, A, Arseneault, L, Williams, B, Braithwaite, A (2005). Moderation of the effect of adolescent-onset cannabis use on adult psychosis by a functional polymorphism in the catechol-O-methyltransferase gene: longitudinal evidence of a gene×environment interaction. Biological Psychiatry 57, 11171127.Google Scholar
Caspi, A, Sugden, K, Moffitt, TE, Taylor, A, Craig, IW, Harrington, H, McClay, J, Mill, J, Martin, J, Braithwaite, A, Poulton, R (2003). Influence of life stress on depression: moderation by a polymorphism in the 5-HTT gene. Science 301, 386389.CrossRefGoogle ScholarPubMed
Cronk, CE, Sarvela, PD (1997). Alcohol, tobacco, and other drug use among rural/small town and urban youth: a secondary analysis of the monitoring the future data set. American Journal of Public Health 87, 760764.CrossRefGoogle Scholar
Eaves, LJ (2006). Genotype×environment interaction in psychopathology: fact or artifact? Twin Research and Human Genetics 9, 18.Google Scholar
Eley, TC, Sugden, K, Corsico, A, Gregory, AM, Sham, P, McGuffin, P, Plomin, R, Craig, IW (2004). Gene–environment interaction analysis of serotonin system markers with adolescent depression. Molecular Psychiatry 9, 908915.Google Scholar
Grabe, HJ, Lange, M, Wolff, B, Volzke, H, Lucht, M, Freyberger, HJ, John, U, Cascorbi, I (2005). Mental and physical distress is modulated by a polymorphism in the 5-HT transporter gene interacting with social stressors and chronic disease burden. Molecular Psychiatry 10, 222224.Google Scholar
Han, C, McGue, MK, Iacono, WG (1999). Lifetime tobacco, alcohol and other substance use in adolescent Minnesota twins: univariate and multivariate behavioral genetic analyses. Addiction 94, 981993.Google Scholar
Heath, AC, Berg, K, Eaves, LJ, Solaas, MH, Corey, LA, Sundet, J, Magnus, P, Nance, WE (1985). Education policy and the heritability of educational attainment. Nature 314, 734736.Google Scholar
Heath, AC, Eaves, LJ, Martin, NG (1998). Interaction of marital status and genetic risk for symptoms of depression. Twin Research 1, 119122.CrossRefGoogle ScholarPubMed
Heath, AC, Jardine, R, Martin, NG (1989). Interactive effects of genotype and social environment on alcohol consumption in female twins. Journal of Studies on Alcohol 50, 3848.Google Scholar
Hicks, BM, Krueger, RF, Iacono, WG, McGue, M, Patrick, CJ (2004). Family transmission and heritability of externalizing disorders: a twin-family study. Archives of General Psychiatry 61, 922928.CrossRefGoogle ScholarPubMed
Iacono, WG, Carlson, SR, Taylor, J, Elkins, IJ, McGue, M (1999). Behavioral disinhibition and the development of substance use disorders: findings from the Minnesota Twin Family Study. Developmental Psychopathology 11, 869900.Google Scholar
Jacobson, KC, Prescott, CA, Kendler, KS (2002). Sex differences in the genetic and environmental influences on the development of antisocial behavior. Development and Psychopathology 14, 395416.CrossRefGoogle ScholarPubMed
Johnson, W, Krueger, RF (2005). Genetic effects on physical health: lower at higher income levels. Behavior Genetics 35, 579590.Google Scholar
Kahn, RS, Khoury, J, Nichols, WC, Lanphear, BP (2003). Role of dopamine transporter genotype and maternal prenatal smoking in childhood hyperactive-impulsive, inattentive, and oppositional behaviors. Journal of Pediatrics 143, 104110.Google Scholar
Kendler, KS, Aggen, SH, Prescott, CA, Jacobson, KC, Neale, MC (2004). Level of family dysfunction and genetic influences on smoking in women. Psychological Medicine 34, 12631269.Google Scholar
Kendler, KS, Prescott, CA, Myers, J, Neale, MC (2003). The structure of genetic and environmental risk factors for common psychiatric and substance use disorders in men and women. Archives of General Psychiatry 60, 929937.Google Scholar
Kendler, KS, Thornton, LM, Pedersen, NL (2000). Tobacco consumption in Swedish twins reared apart and reared together. Archives of General Psychiatry 57, 886892.Google Scholar
Koopmans, JR, Slutske, WS, van Baal, GCM, Boomsma, DI (1999). The influence of religion on alcohol use initiation: evidence for genotype×environment interaction. Behavior Genetics 29, 445453.CrossRefGoogle Scholar
Krueger, RF (1999). The structure of common mental disorders. Archives of General Psychiatry 56, 921926.Google Scholar
Krueger, RF, Hicks, BM, Patrick, CJ, Carlson, SR, Iacono, WG, McGue, M (2002). Etiologic connections among substance dependence, antisocial behavior, and personality: modeling the externalizing spectrum. Journal of Abnormal Psychology 111, 411424.CrossRefGoogle ScholarPubMed
Krueger, RF, Nichol, PE, Hicks, BM, Markon, KE, Patrick, CJ, Iacono, WG, McGue, M (2004). Using latent trait modeling to conceptualize an alcohol problems continuum. Psychological Assessment 16, 107119.CrossRefGoogle ScholarPubMed
Levine, SB, Coupey, SM (2003). Adolescent substance use, sexual behavior, and metropolitan status: is ‘urban’ a risk factor? Journal of Adolescent Health 23, 350355.CrossRefGoogle Scholar
Littell, R, Milliken, G, Stroup, W, Wolfinger, R (1996). SAS System for Mixed Models. SAS Institute, Inc.: Cary, NC.Google Scholar
McGue, M, Iacono, WG (2005). The association of early adolescent problem behavior with adult psychopathology. American Journal of Psychiatry 162, 11181124.Google Scholar
CASA (2000). No Place to Hide: Substance Abuse in Mid-size Cities and Rural America. National Center on Addiction and Substance Abuse (CASA) at Columbia University: New York.Google Scholar
Neale, MC, Boker, SM, Xie, G, Maes, HH (2002). Mx: Statistical Modeling, 6th edn.Department of Psychiatry, : Richmond, VA.Google Scholar
Neale, MC, Cardon, LR (1992). Methodology for Genetic Studies of Twins and Families. NATO ASI Series. Kluwer Academic Publishers: Dordrecht.Google Scholar
O'Connor, TG, Caspi, A, DeFries, JC, Plomin, R (2003). Genotype–environment interaction in children's adjustment to parental separation. Journal of Child Psychology and Psychiatry 44, 849856.CrossRefGoogle ScholarPubMed
Offord, DR, Boyle, MH, Szatmari, P, Rae-Grant, NI, Links, PS, Cadman, DT, Byles, JA, Crawford, JW, Blum, HM, Byrne, C, Thomas, H, Woodward, CA (1987). Ontario child health study: II. Six month prevalence of disorder and rates of service utilization. Archives of General Psychiatry 44, 832836.Google Scholar
Ozkaragoz, T, Noble, EP (2000). Extraversion interaction between D2 dopamine receptor polymorphisms and parental alcoholism. Alcohol 22, 139146.Google Scholar
Paykel, ES, Abbott, R, Jenkins, R, Brugha, TS, Meltzer, H (2000). Urban–rural mental health differences in Great Britain: findings from the National Morbidity Survey. Psychological Medicine 31, 269280.Google Scholar
Raine, A (2002). Biosocial studies of antisocial and violent behavior in children and adults: a review. Journal of Abnormal Child Psychology 30, 311326.CrossRefGoogle ScholarPubMed
Reich, W, Welner, Z (1988). Diagnostic Interview for Children and Adolescents–Revised: DSM-III-R version (DICA-R). Washington University: St Louis.Google Scholar
Rhee, SH, Waldman, ID (2002). Genetic and environmental influences on antisocial behavior: a meta-analysis of twin and adoption studies. Psychological Bulletin 128, 490529.CrossRefGoogle ScholarPubMed
Robins, LM, Babor, T, Cottler, LB (1987). Composite International Diagnostic Interview: Expanded Substance Abuse Module. Department of Psychiatry, Washington University: St Louis.Google Scholar
Robins, LM, Wing, J, Wittchen, HU, Helzer, JE, Babor, TF, Burke, J, Famer, A, Jablenski, A, Pickens, R, Regier, DA, Sartorious, N, Towle, LH (1988). The Composite International Diagnostic Interview: an epidemiologic instrument suitable for use in conjunction with different diagnostic systems and in different cultures. Archives of General Psychiatry 45, 10691077.Google Scholar
Romano, E, Tremblay, RE, Vitaro, F (2001). Prevalence of psychiatric diagnoses and the role of perceived impairment: findings from an adolescent community sample. Journal of Child Psychology and Psychiatry 42, 451461.CrossRefGoogle ScholarPubMed
Rose, RJ, Dick, DM, Viken, RJ, Kaprio, J (2001). Gene–environment interaction in patterns of adolescent drinking: regional residency moderates longitudinal influences on alcohol use. Alcoholism: Clinical and Experimental Research 25, 637643.Google Scholar
Shaw, C, McKay, HD (1969). Juvenile Delinquency and Urban Areas. University of Chicago Press: Chicago.Google Scholar
Silberg, J, Rutter, M, Neale, M, Eaves, L (2001). Genetic moderation of environmental risk for depression and anxiety in adolescent girls. British Journal of Psychiatry 179, 116121.Google Scholar
Turkheimer, E, Haley, A, Waldron, M, D'Onofrio, B, Gottesman, II (2003). Socioeconomic status moderates heritability of IQ in young children. Psychological Science 14, 623628.CrossRefGoogle Scholar
Tuvblad, C, Grann, M, Lichtenstein, P (2006). Heritability for adolescent antisocial behavior differs with socioeconomic status: gene–environment interaction. Journal of Child Psychology and Psychiatry 47, 734743.Google Scholar
Wahlberg, K-E, Wynne, LC, Oja, H, Keskitalo, P, Pykalainen, L, Lahti, I, Moring, J, Naarala, M, Sorri, A, Seitamaa, M, Laksy, K, Kolassa, J, Tienari, P (1997). Gene-environment interaction in vulnerability to schizophrenia: findings from the Finnish adoptive family study of schizophrenia. American Journal of Psychiatry 154, 355362.Google ScholarPubMed
Young, SE, Stallings, MC, Corley, RP, Krauter, KS, Hewitt, JS (2000). Genetic and environmental influences on behavioral disinhibition. American Journal of Medical Genetics (Neuropsychiatric Genetics) 96, 684695.3.0.CO;2-G>CrossRefGoogle ScholarPubMed
Zahner, GEP, Jacobs, JH, Freeman, DH, Trainor, KF (1993). Rural–urban child psychopathology in a Northeastern U.S. State: 1986–1989. Journal of the American Academy of Child and Adolescent Psychiatry 32, 378387.Google Scholar