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A Model for the Analysis of Mate Selection in the Marriages of Twins Application to Data on Stature*

Published online by Cambridge University Press:  01 August 2014

W. E. Nance*
Affiliation:
Department of Human Genetics, Medical College of Virginia, Richmond
L. A. Corey
Affiliation:
Department of Human Genetics, Medical College of Virginia, Richmond
L. J. Eaves
Affiliation:
Department of Psychology, Oxford University
*
Department of Human Genetics, Medical College of Virginia, Richmond, VA 23298

Abstract

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Analysis of the multiple correlations in body height within a sample of 117 monozygotic twin pairs and their spouses confirmed the existence of a high degree of assortative mating. However, the data also revealed an underlying asymmetry in the mate selection process. With respect to height, male twins were more selective than were members of female pairs, and among male twin pairs, those who were intermediate in height appeared to make the greatest contribution to the observed pattern of nonrandom mating. Because of their magnitude and potential asymmetry, the effects of phenotypic correlations between the spouses of related individuals must be correctly specified in any rigorous quantitative genetic analysis that extends beyond the nuclear family unit.

Type
Research Article
Copyright
Copyright © The International Society for Twin Studies 1980

Footnotes

*

This is paper no. 99 from the Department of Human Genetics of the Medical College of Virginia and was supported in part by USPHS grants HD-10291 and GM-21045.

References

REFERENCES

1.Christian, JC, Kang, KW (1977): Maternal influence on plasma cholesterol variation. Am J Hum Genet 20:462467.Google Scholar
2.Cloninger, Cr, Rice, J, Reich, T (1979): Multifactorial inheritance with cultural transmission and assortative mating. II. A general model of combined polygenic and cultural inheritance. Am J Hum Genet 31:176198.Google Scholar
3.Cloninger, CR, Rice, J, Reich, T (1979): Multifactorial inheritance with cultural transmission and as-sortative mating. III. Family structure and the analysis of separation experiments. Am J Hum Genet 31:366388.Google Scholar
4.Eaves, LJ (in press): The use of twins in the analysis of assortative mating. Heredity.Google Scholar
5.Ewell, LW, Corey, LA, Winter, PM, Boughman, JA, Nance, WE (1978): Blood pressure studies in monozygotic twins and their families. In Nance, WE, Allen, G, Parisi, P (eds): “Progress in Clinical and Biological Research: Twin Research – Clinical Studies.” New York: Alan R. Liss, vol 24C, pp 2938.Google Scholar
6.Fisher, RA (1918): The correlations between relatives on the supposition of Mendelian inheritance. Trans R Soc Edin 52:399433.Google Scholar
7.Li, CC (1978): Progress of the kinship correlation models. In Morton, NE, Chung, CJ (eds): “Genetic Epidemiology.” New York: Academic Press, p 55.Google Scholar
8.Nance, WE, Nakata, M, Paul, TD, Yu, P (1974): The use of twin studies in the analysis of phenotypic traits in man. In Janerich, DT, Skalko, RG, Porter, IH (eds): “Congenital Malformations: New Direction in Research.” New York: Academic Press, pp 2349.Google Scholar
9.Nance, WE, Corey, LA (1976): Genetic models for the analysis of data from the families of identical twins. Genetics 83:811826.Google Scholar
10.Nance, WE (1976): Genetic studies of the offspring of identical twins. Acta Genet Med Gemellol (Rome) 25:96104.Google ScholarPubMed
11.Nance, WE (1977): The use of twins in clinical research. Birth Defects: Orig Art Ser 13(6):1944.Google Scholar
12.Nance, WE, Corey, LA, Boughman, JA (1978): Monozygotic twin kinships: A new design for genetic and epidemiologic research. In Morton, NE, Chung, CS (eds): “Genetic Epidemiology.” New York: Academic Press, pp 87132.Google Scholar
13.Nance, WE (1979): The role of twin studies in human quantitative genetics. Prog in Med Genet (New Ser) 3:73107.Google ScholarPubMed
14.Nance, WE (1979): A note on assortative mating and maternal effects. In Sing, CF, Skolnick, M (eds): “The Genetic Analysis of Common Diseases: Applications to Predictive Factors in Coronary Heart Disease.” New York: Alan R. Liss, pp 453464.Google Scholar
15.Osborn, RN, DeGeorge, FV (1959): “Genetic Basis of Morphologic Variation.” Cambridge: Harvard University Press.CrossRefGoogle Scholar
16.Rao, DC, Morton, NE, Cloninger, CR (1979): Path analysis under generalized assortative mating. Genet Res 33:175188.CrossRefGoogle ScholarPubMed
17.Reed, T, Evans, MM, Norton, JA, Christian, JC (1979): Maternal effects on finger tip dermatoglyphics. Am J Hum Genet 31:315.Google Scholar
18.Rich, RL, Corey, LA, Nance, WE (1978): Evidence for genetic factors influencing uric acid levels in man. In Nance, WE, Allen, G, Parisi, P (eds): “Progress in Clinical and Biological Research: Twin Research – Clinical Studies.” New York: Alan R. Liss, vol 24C, pp 187192.Google Scholar
19.Rose, RJ, Miller, JZ, Driscoll, M, Evans, MM (1979): Twin-family studies of perceptual speed ability. Behavior Genet 9:7186.Google Scholar
20.Rose, RJ, Miller, JZ, Grim, CE, Christian, JC (1979): Aggregation of blood pressure in the families of identical twins. Am J Epidem 109:503511.Google Scholar
21.Rose, RJ, Harris, EL, Christian, JC, Nance, WE (1979): Genetic variance in nonverbal intelligence: Data from the kinships of identical twins. Science 205:11531154.CrossRefGoogle ScholarPubMed
22.Rose, RJ, Boughman, JA, Corey, LA, Nance, WE, Christian, JC, Kang, KW (in press): Maternal effects on verbal intelligence: Data from the kinships of MZ twins. Nature.Google Scholar
23.Smith, DW (1977): “Growth and Its Disorders.” Philadelphia: W. B. Saunders.Google ScholarPubMed