Extended Pedigrees HGEN619 class 2007.

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Presentation transcript:

Extended Pedigrees HGEN619 class 2007

Classic Twin Design ACE / ADE Issues heterogeneity multivariate developmental Issues generalizibility >Additional Siblings

Example Data Study: Virginia 30,000: twins, parents, sibs, spouses, children Data: church attendance Variable: categorical, 6 ordered categories > 5 thresholds Analysis: 2 groups, males

ACE Model Results Parameter Estimates a: 0.44 c: 0.59 e: 0.680 Standardized Estimates + Confidence Intervals a2: 0.20 c2: 0.34 e2: 0.46 CI 0.01-0.20 0.18-0.49 0.42-0.48 Fit Statistics Estimated parameters: 23 Observed statistics: 2807, 1 constraint -2 times log-likelihood of data: 9364.528 Degrees of freedom: 2784

CTD Assumptions Random mating No Age Moderation Assortment will increase MZ and DZ correlations When fitting ACE model, with assortment present, C will be overestimated When fitting AE model, with assortment present, A will be overestimated No Age Moderation When fitting ACE model, with G x age interaction present, C will be overestimated

Correlations Mm Ff Mf Fm MZ .64 .63 _ DZ .49 .53 .41 Sibs .47 .39 P-O .46 Spouse .74

Genetic Factors Decreasing correlations with a decreasing genetic relatedness: MZ twins > first-degree relatives (DZ twins, siblings, parent-child pairs) > second-degree relatives (grandparents, half-siblings, avuncular pairs) > more distant relatives such as cousins >> additive genetic factors Sibling and DZ correlations less than half MZ correlations (expectation is DZ=1/4MZ) and zero correlations for other pairs of relatives >> dominance MZ correlations less than 1 >> specific environmental factors

Environmental Factors Similar sibling, DZ, parent-offspring correlations >> shared environmental factors: increase similarity between people living or having grown up in the same home (first-degree relatives and MZs) Sibling > parent-offspring correlations >> non-parental environmental factors: in common for siblings, such as school environment, peers, friends Twin > sibling correlations >> special twin environment: additional similarity due to greater sharing of aspects of the environment Siblings = parent-offspring correlations > half MZ twins >> cultural transmission

Other Factors If cultural transmission based on phenotype of parents for a trait which also has a genetic component >> GE covariance Non-random mating: source of similarity which may have both genetic and environmental implications effects of assortative mating depend on mechanism by which people chose spouses if selection is based on phenotype of partner > correlations between sources of variance in one spouse with those of other spouse induced, genetic and/or environmental covariance between parent-offspring and sibling pairs increased

Path Diagram Twins & Parents PF : Phenotype Father PM : Phenotype Mother P1 : Phenotype Twin 1 P2 : Phenotype Twin 2

Covariance Matrices MZ/DZ Variance [P] MZ Covariance [U] DZ Covariance [V] Spousal Covariance [W] Parent-offspring Covariance [O]

Genetic Transmission Model Fixed at .5 Residual Genetic Variance Equilibrium of variances across generations

Genetic Transmission Expectations W= 0; ! covariance spouse O= .5a2; ! covariance parent-offspring U= a2; ! covariance MZ twins V= .5a2; ! covariance DZ twins P= a2+e2; ! variance twins Q= a2+e2; ! variance parents

Common Environment Model Same for all family members Assortment Function of common environment

Common Environment Expectations W= c2; ! covariance spouse O= .5a2 +c2; ! covariance parent-offspring U= a2+c2; ! covariance MZ twins V= .5a2+c2; ! covariance DZ twins P= a2+c2+e2; ! variance twins Q= a2+c2+e2; ! variance parents

Common Environment Results Parameter Estimates a: 0.26 c: 0.66 e: 0.700 Standardized Estimates + Confidence Intervals a2: 0.07 c2: 0.44 e2: 0.49 CI 0.00-0.18 0.35-0.52 0.44-0.55 Fit Statistics Estimated parameters: 43 Observed statistics: 3351, 1 constraint -2 times log-likelihood of data: 10999.249 Degrees of freedom: 3308

Social Homogamy Model Assortment Cultural Transmission From C to C Non-parental Shared Environment Residual

Social Homogamy Expectations W= dc2; ! covariance spouse O= (f+df)c2+.5a2; ! covariance parent-child x= 2f2+2df2+r; ! common environment variance twins U= a2+xc2; ! covariance MZ twins V= .5a2+xc2; ! covariance DZ twins P= a2+xc2+e2; ! variance twins Q= a2+c2+e2; ! variance parents Constrain x=1

Social Homogamy Results Parameter Estimates a: 0.20 c: 0.69 e: 0.69 d: 1.00 f: 0.43 r: 0.26 p: 1.00 q: 1.00 x: 1.00 Standardized Estimates + Confidence Intervals a2: 0.04 r2: 0.13 t2: 0.38 e2: 0.48 CI 0.04-0.05 0.12-0.14 0.23-0.47 0.44-0.49 r2: non-parental shared environment, t2: cultural transmission t2 + r2 =c2 Fit Statistics Estimated parameters:46, Obs statistics: 3352, 2 constraints -2 times log-likelihood of data: 10994.427, df: 3306

Phenotypic Assortment Model Cultural Transmission From P to C Non-parental Shared Environment Residual Genotype-Environment Covariance

Phenotypic Assortment Expectations W= pdp; ! covariance spouse T= ga+sc; ! covariance G-phenotype O= (pf+wf)c+.5a(1+pd)t; ! covariance parent-child J= asc+csa; ! covariance GE U= ga2+xc2+j; ! covariance MZ twin Y= g+.5(t(d+d)t); ! assortment V= .5ya2+xc2+j; ! covariance DZ twin

Constraints K= .5(g+.5(t(d+d)t')+1); L= .5t(2f+ 2dpf); ! genetic variance constraint L= .5t(2f+ 2dpf); ! A-C constraint M= 2fpf+2fwf+ r; ! common environment variance constraint Z= ga2+xc2+e2+2asc; ! phenotypic variance constraint

Phenotypic Assortment Results Parameter Estimates a: 0.46 c: 0.31 e: 0.67 d: 0.58 f: 0.36 g: 1.32 p: 1.00 s: 0.42 x: 1.41 Standardized Estimates + Confidence Intervals a2: 0.28 c2: 0.14 e2: 0.46 s2: 0.12 CI 0.04-0.60 0.00-0.41 0.41-0.51 -0.02-0.16 g2: 0.21 d2: 0.00 t2: 0.04 r2: 0.10 CI 0.04-0.39 0.00-0.21 0.00-0.20 0.00-0.23 s2: genotype-environment covariance, g2: genetic variance, d2: genetic variance through assortment, d2 + g2 = a2 Fit Statistics Estimated parameters:48, Obs statistics: 3354, 4 constraints -2 times log-likelihood of data: 10987.365, df: 3306

Model Comparisons

Heritability

Shared Environment *GE Covariance: lower CI:-2; point:12; upper CI:16

Limitations Cultural Transmission versus Dominance versus Reduced Genetic Transmission Sex Differences in magnitude or nature of effects Age Regression and Moderation

Dominance

Sex Differences

Summary Common Environment Social Homogamy Phenotypic Assortment Assortment function of C Social Homogamy Social Assortment Cultural Transmission C->C Phenotypic Assortment Cultural Transmission P->C