Estimating the Extent of Parameter Bias in the Classical Twin Design: a Comparison of Parameter Estimates from Extended Twin-family and Classical Twin Designs

Overview

Journal Twin Res Hum Genet

Publisher Cambridge University Press

Specialty Genetics

Date 2005 Jul 2

PMID 15989749

Citations 29

Authors

William L Coventry

Matthew C Keller

Affiliations

Soon will be listed here.

Abstract

The classical twin design (CTD) circumvents parameter indeterminacy by assuming (1) negligible higher-order epistasis; and (2) either nonadditive genetic or common environmental effects are nonexistent, creating two potential sources of bias (Eaves et al., 1978; Grayson, 1989). Because the extended twin-family design (ETFD) uses many more unique covariance observations to estimate parameters, common environmental and nonadditive genetic parameters can be simultaneously estimated. The ETFD thereby corrects for what is likely to be the largest of the two sources of bias in CTD parameter estimates (Keller & Coventry, 2005). In the current paper, we assess the extent of this and other potential sources of bias in the CTD by comparing all published ETFD parameter estimates to CTD parameter estimates derived from the same data. CTD estimates of the common environment were lower than ETFD estimates of the common environment for some phenotypes, but for other phenotypes (e.g., stature in females and certain social attitudes), what appeared as the common environment was resolved to be assortative mating in the ETFD. On average, CTD estimates of nonadditive genetic factors were 43% lower, and additive genetic factors 63% higher, than ETFD estimates. However, broad-sense heritability estimates from the CTD were only 18% higher than ETFD estimates, highlighting that the CTD is useful for estimating broad-sense but not narrow-sense heritability. These results suggest that CTD estimates can be misleading when interpreted literally, but useful, albeit coarse, when interpreted properly.

Citing Articles

Evidence of correlations between human partners based on systematic reviews and meta-analyses of 22 traits and UK Biobank analysis of 133 traits.

Horwitz T, Balbona J, Paulich K, Keller M Nat Hum Behav. 2023; 7(9):1568-1583.

PMID: 37653148 PMC: 10967253. DOI: 10.1038/s41562-023-01672-z.

Why we need families in genomic research on developmental psychopathology.

Cheesman R, Ayorech Z, Eilertsen E, Ystrom E JCPP Adv. 2023; 3(1):e12138.

PMID: 37431320 PMC: 10241449. DOI: 10.1002/jcv2.12138.

Preliminary Evidence for Genetic Nurture in Depression and Neuroticism Through Polygenic Scores.

Tubbs J, Sham P JAMA Psychiatry. 2023; 80(8):832-841.

PMID: 37285136 PMC: 10248817. DOI: 10.1001/jamapsychiatry.2023.1544.

Transcriptome-wide gene-gene interaction associations elucidate pathways and functional enrichment of complex traits.

Evans L, Arehart C, Grotzinger A, Mize T, Brasher M, Stitzel J PLoS Genet. 2023; 19(5):e1010693.

PMID: 37216417 PMC: 10237671. DOI: 10.1371/journal.pgen.1010693.

Measuring heritable contributions to Alzheimer's disease: polygenic risk score analysis with twins.

Karlsson I, Escott-Price V, Gatz M, Hardy J, Pedersen N, Shoai M Brain Commun. 2022; 4(1):fcab308.

PMID: 35169705 PMC: 8833403. DOI: 10.1093/braincomms/fcab308.