Behavioral Genetics

doi:10.1017/9781108943529.018

15 - Behavioral Genetics

from Part II - Middle-Level Theories

Published online by Cambridge University Press: 30 June 2022

Severi Luoto and

Michael A. Woodley of Menie

Edited by

Todd K. Shackelford

Show author details

Todd K. Shackelford: Affiliation:
Oakland University, Michigan

Book contents

Get access

Summary

In this introductory chapter, we discuss the nexus between evolutionary theory and behavioral genetics, using it to elucidate the biological origins of human behavior and motivational predispositions. We introduce relevant behavioral genetics methods and evolutionary theoretical background to provide readers with the necessary conceptual tools to deepen their engagement with evolutionary behavioral genetics – as well as to help them take on the challenge of building a scientifically and evolutionarily more consilient account of human behavior. To demonstrate the utility of behavioral genetics in evolutionary behavioral science, our analytical examples range from personality, cognition, and sexual orientation to pair-bonding. We conclude by presenting a few recent landmark studies in behavioral genetics research with a particular focus on two aspects of sexual behavior: assortative mating and same-sex sexual behavior. This chapter considers behavioral genetics methods and their connection with evolutionary science more broadly while providing a succinct overview of recent advances in understanding the evolutionary genetic underpinnings of human sexual behavior, mate choice, and basic motivational processes. It is a sine qua non of scientifically principled evolutionary behavioral scientists to acknowledge the distal evolutionary and proximal genetic processes which, interlinked, underlie the psychobehavioral predispositions that form the variegated fabric of human societies and, more broadly, the diversity of life found in nature. These evolutionary processes operate from distal selection pressures acting on genetic material through hundreds of millions of years of natural selection –and from individual and population differences in genotypes to their manifestations in complex behavioral phenotypes and life outcomes in contemporary humans – which, in turn, enact concomitant selection pressures on the genetic material underlying and arising from them.

Keywords

behavioral genetics evolutionary psychology evolution natural selection sexual selection

Type: Chapter
Information: The Cambridge Handbook of Evolutionary Perspectives on Sexual Psychology , pp. 327 - 359

DOI: https://doi.org/10.1017/9781108943529.018 [Opens in a new window]

Publisher: Cambridge University Press

Print publication year: 2022

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Acevedo, B. P., Poulin, M. J., Collins, N. L., & Brown, L. L. (2020). After the honeymoon: Neural and genetic correlates of romantic love in newlywed marriages. Frontiers in Psychology, 11, 634.Google Scholar

Arslan, R. C., & Penke, L. (2015). Evolutionary genetics. In Buss, D. M. (Ed.), The handbook of evolutionary psychology (pp. 1047–1066). Chichester: Wiley.Google Scholar

Bagshaw, A. T. M., Horwood, L. J., Liu, Y., Fergusson, D. M., Sullivan, P. F., & Kennedy, M. A. (2013). No effect of genome-wide copy number variation on measures of intelligence in a New Zealand birth cohort. PLoS One, 8, e55208.Google Scholar

Bailey, J. M., Vasey, P. L., Diamond, L. M., Breedlove, S. M., Vilain, E., & Epprecht, M. (2016). Sexual orientation, controversy, and science. Psychological Science in the Public Interest, 17, 45–101.Google Scholar

Barbaro, N., & Penke, L. (2020). Behavior genetics. In SAGE handbook of evolutionary psychology (Vol. 1, pp. 336–354). London: Sage.Google Scholar

Barbaro, N., Shackelford, T. K., Holub, A. M., Jeffery, A. J., Lopes, G. S., & Zeigler-Hill, V. (2018). Life history correlates of human (Homo sapiens) ejaculate quality. Journal of Comparative Psychology, 133, 294–300.Google Scholar

Barkow, J., Cosmides, L., & Tooby, J. (1992). The adapted mind: Evolutionary psychology and the generation of culture. New York, NY: Oxford University Press.Google Scholar

Bateson, P., & Gluckman, P. (2011). Plasticity, robustness, development and evolution. Cambridge: Cambridge University Press.CrossRef Google Scholar

Baud, A., Mulligan, M. K., Casale, F. P., Ingels, J. F., Bohl, C. J., Callebert, J., … Stegle, O. (2017). Genetic variation in the social environment contributes to health and disease. PLoS Genetics, 13, e1006498.Google Scholar

Bode, A., & Kushnick, G. (2021). Proximate and ultimate perspectives on romantic love. Frontiers in Psychology, 12, 573123.Google Scholar

Camperio Ciani, A., Battaglia, U., Cesare, L., Camperio Ciani, G., & Capiluppi, C. (2018). Possible balancing selection in human female homosexuality. Human Nature, 29, 14–32.Google Scholar

Chabris, C. F., Hebert, B. M., Benjamin, D. J., Beauchamp, J., Cesarini, D., van der Loos, M., … Laibson, D. (2012). Most reported genetic associations with general intelligence are probably false positives. Psychological Science, 23, 1314–1323.Google Scholar

Conroy-Beam, D., Roney, J. R., Lukaszewski, A. W., Buss, D. M., Asao, K., Sorokowska, A., … Zupančič, M. (2019). Assortative mating and the evolution of desirability covariation. Evolution and Human Behavior, 40, 479–491.Google Scholar

Cornwallis, C. K., & Uller, T. (2010). Towards an evolutionary ecology of sexual traits. Trends in Ecology & Evolution, 25, 145–152.Google Scholar

Crespi, B. (2020). Evolutionary and genetic insights for clinical psychology. Clinical Psychology Review, 78, 101857.Google Scholar

D’Onofrio, B. M., Rickert, M. E., Frans, E., Kuja-Halkola, R., Almqvist, C., Sjölander, A., … Lichtenstein, P. (2014). Paternal age at childbearing and offspring psychiatric and academic morbidity. JAMA Psychiatry, 71, 432–438.Google Scholar

Daniele, V. (2021). Socioeconomic inequality and regional disparities in educational achievement: The role of relative poverty. Intelligence, 84, 101515.Google Scholar

Del Giudice, M. (2020). Rethinking the fast–slow continuum of individual differences. Evolution and Human Behavior, 41, 536–549.Google Scholar

Diekhof, E. K., Richter, A., Brodmann, K., & Gruber, O. (2021). Dopamine multilocus genetic profiles predict sex differences in reactivity of the human reward system. Brain Structure and Function, 226, 1099–1114.Google Scholar

Domingue, B. W., & Belsky, D. W. (2017). The social genome: Current findings and implications for the study of human genetics. PLoS Genetics, 13, e1006615.Google Scholar

Domingue, B. W., Belsky, D. W., Fletcher, J. M., Conley, D., Boardman, J. D., & Harris, K. M. (2018). The social genome of friends and schoolmates in the National Longitudinal Study of Adolescent to Adult Health. Proceedings of the National Academy of Sciences, 115, 702–707.Google Scholar

Eaves, L. J., Neale, M. C., & Maes, H. (1996). Multivariate multipoint linkage analysis of quantitative trait loci. Behavior Genetics, 26, 519–525.Google Scholar

Ellis, B. J., Abrams, L. S., Masten, A. S., Sternberg, R. J., Tottenham, N., & Frankenhuis, W. E. (2020). Hidden talents in harsh environments. Development and Psychopathology. doi: 10.1017/S0954579420000887Google Scholar

Ellis, B. J., & Del Giudice, M. (2018). Developmental adaptation to stress: An evolutionary perspective. Annual Review of Psychology, 70, 111–139.Google Scholar

Ellison, P. T. (2017). Endocrinology, energetics, and human life history: A synthetic model. Hormones and Behavior, 91, 97–106.Google Scholar

Falconer, D. S. (1960). Introduction to quantitative genetics. Edinburgh: Oliver & Boyd.Google Scholar

Figueredo, A. J., Sefcek, J. A., Vasquez, G., Brumbach, B. H., King, J. E., & Jacobs, W. J. (2005). Evolutionary personality psychology. In Buss, D. M. (Ed.), Handbook of evolutionary psychology (pp. 851–877). Hoboken, NJ: Wiley.Google Scholar

Figueredo, A. J., Vasquez, G., Brumbach, B. H., & Schneider, S. M. R. (2004). The heritability of life history strategy: The K‐factor, covitality, and personality. Social Biology, 51, 121–143.Google Scholar PubMed

Fisher, R. A. (1930). The genetical theory of natural selection. Oxford: Oxford University Press.Google Scholar

Frankenhuis, W. E., & Panchanathan, K. (2011). Individual differences in developmental plasticity may result from stochastic sampling. Perspectives on Psychological Science, 6, 336–347.Google Scholar

Froggatt, P., & Nevin, N. C. (1971). The “law of ancestral heredity” and the Mendelian-ancestrian controversy in England, 1889–1906. Journal of Medical Genetics, 8, 1–36.Google Scholar

Galton, F. (1869). Hereditary genius. London: Macmillan.Google Scholar

Galton, F. (1875). The history of twins, as a criterion of the relative powers of nature and nurture. Journal of the Anthropological Institute, 5, 391–406.Google Scholar

Gangestad, S. W. (2010). Evolutionary biology looks at behavior genetics. Personality and Individual Differences, 49, 289–295.Google Scholar

Ganna, A., Verweij, K. J. H., Nivard, M. G., Maier, R., Wedow, R., Busch, A. S., … Zietsch, B. P. (2019). Large-scale GWAS reveals insights into the genetic architecture of same-sex sexual behavior. Science, 365, eaat7693.Google Scholar

Gould, S. J. (2002). The structure of evolutionary theory. Cambridge, MA: Belknap Press.Google Scholar

Haldane, J. B. S. (1937). The effect of variation of fitness. The American Naturalist, 71, 337–349.Google Scholar

Heyes, C. (2012). New thinking: The evolution of human cognition. Philosophical Transactions of the Royal Society B: Biological Sciences, 367, 2091–2096.Google Scholar

Hill, W. D., Arslan, R. C., Xia, C., Luciano, M., Amador, C., Navarro, P., … Penke, L. (2018). Genomic analysis of family data reveals additional genetic effects on intelligence and personality. Molecular Psychiatry, 23, 2347–2362.Google Scholar

Hopkins, W. D., Russell, J. L., & Schaeffer, J. (2014). Chimpanzee intelligence is heritable. Current Biology, 24, 1649–1652.CrossRef Google Scholar PubMed

Houle, D. (2000). Is there a g factor for fitness. In Bock, G. R., Goode, J. A., & Webb, K. (Eds.), The nature of intelligence (pp. 149–170). Chichester: Wiley.Google Scholar

Keller, M. C. (2008). The role of mutations in human mating. In Geher, G. & Miller, G. F. (Eds.), Mating intelligence: Sex, relationships, and the mind’s reproductive system (pp. 173–192). Hove: Psychology Press.Google Scholar

Krams, I., Luoto, S., Rubika, A., Krama, T., Elferts, D., Krams, R., … Rantala, M. J. (2019). A head start for life history development? Family income mediates associations between height and immune response in men. American Journal of Physical Anthropology, 168, 421–427.Google Scholar

Kringelbach, M. L., & Berridge, K. C. (2010). Pleasures of the brain. New York, NY: Oxford University Press.Google Scholar

Lee, J. J., Wedow, R., Okbay, A., Kong, E., Maghzian, O., Zacher, M., … Turley, P. (2018). Gene discovery and polygenic prediction from a genome-wide association study of educational attainment in 1.1 million individuals. Nature Genetics, 50, 1112–1121.Google Scholar

LeVay, S. (1994). The sexual brain. Cambridge, MA: MIT Press.Google Scholar

Lewis, D. M. G., Conroy-Beam, D., Asao, K., & Buss, D. M. (2017). Evolutionary psychology: A how-to guide. American Psychologist, 72, 353–373.Google Scholar

Liew, S. H. M., Elsner, H., Spector, T. D., & Hammond, C. J. (2005). The first “classical” twin study? Analysis of refractive error using monozygotic and dizygotic twins published in 1922. Twin Research and Human Genetics, 3, 198–200.Google Scholar

Linksvayer, T. A. (2007). Ant species differences determined by epistasis between brood and worker genomes. PLoS One, 2, e994.Google Scholar

Luoto, S. (2019a). An updated theoretical framework for human sexual selection: From ecology, genetics, and life history to extended phenotypes. Adaptive Human Behavior and Physiology, 5, 48–102.Google Scholar

Luoto, S. (2019b). Response to commentaries: Life history genetics, fluid intelligence, and extended phenotypes. Adaptive Human Behavior and Physiology, 5, 112–115.Google Scholar

Luoto, S. (2020). Did prosociality drive the evolution of homosexuality? Archives of Sexual Behavior, 49, 2239–2244.Google Scholar

Luoto, S., Krams, I., & Rantala, M. J. (2019a). A life history approach to the female sexual orientation spectrum: Evolution, development, causal mechanisms, and health. Archives of Sexual Behavior, 48, 1273–1308.Google Scholar

Luoto, S., Krams, I., & Rantala, M. J. (2019b). Response to commentaries: Life history evolution, causal mechanisms, and female sexual orientation. Archives of Sexual Behavior, 48, 1335–1347.CrossRef Google Scholar PubMed

Luoto, S., & Varella, M. A. C. (2021). Pandemic leadership: Sex differences and their evolutionary-developmental origins. Frontiers in Psychology, 12, 633862.CrossRef Google Scholar PubMed

Mahner, M., & Kary, M. (1997). What exactly are genomes, genotypes and phenotypes? And what about phenomes? Journal of Theoretical Biology, 186, 55–63.Google Scholar

Marciniak, S., & Perry, G. H. (2017). Harnessing ancient genomes to study the history of human adaptation. Nature Reviews Genetics, 18, 659–674.CrossRef Google Scholar

Miller, G. F. (2000). Sexual selection for indicators of intelligence. In Bock, G. R., Goode, J. A., & Webb, K. (Eds.), The nature of intelligence (pp. 260–275). Chichester: Wiley.Google Scholar

Minkov, M., & Bond, M. H. (2015). Genetic polymorphisms predict national differences in life history strategy and time orientation. Personality and Individual Differences, 76, 204–215.Google Scholar

Moorjani, P., Gao, Z., & Przeworski, M. (2016). Human germline mutation and the erratic evolutionary clock. PLoS Biology, 14, e2000744.Google Scholar

Muller, H. J. (1950). Our load of mutations. American Journal of Human Genetics, 2, 111–176.Google Scholar PubMed

Neale, M. C., & Cardon, L. R. (1992). Methodology for genetic studies of twins and families. Berlin: Springer.Google Scholar

Nila, S., Barthes, J., Crochet, P. A., Suryobroto, B., & Raymond, M. (2018). Kin selection and male homosexual preference in Indonesia. Archives of Sexual Behavior, 47, 2455–2465.Google Scholar

Nishi, A., Alexander, M., Fowler, J. H., & Christakis, N. A. (2020). Assortative mating at loci under recent natural selection in humans. BioSystems, 187, 104040.Google Scholar

Panksepp, J. (1998). Affective neuroscience: The foundations of human and animal. New York, NY: Oxford University Press.Google Scholar

Pearce, E., Wlodarski, R., Machin, A., & Dunbar, R. I. M. (2019). Genetic influences on social relationships: Sex differences in the mediating role of personality and social cognition. Adaptive Human Behavior and Physiology, 5, 331–351.Google Scholar

Penke, L., & Jokela, M. (2016). The evolutionary genetics of personality revisited. Current Opinion in Psychology, 7, 104–109.Google Scholar

Plomin, R., & Deary, I. J. (2015). Genetics and intelligence differences: Five special findings. Molecular Psychiatry, 20, 98–108.Google Scholar

Plomin, R., DeFries, J. C., Knopik, V. S., & Neiderhiser, J. M. (2016). Top 10 replicated findings from behavioral genetics. Perspectives on Psychological Science, 11, 3–23.Google Scholar

Polderman, T. J. C., Benyamin, B., De Leeuw, C. A., Sullivan, P. F., Van Bochoven, A., Visscher, P. M., & Posthuma, D. (2015). Meta-analysis of the heritability of human traits based on fifty years of twin studies. Nature Genetics, 47, 702–709.Google Scholar

Proulx, S. R., & Østman, B. (2016). Natural selection, introduction to. Encyclopedia of Evolutionary Biology, 3, 100–103.Google Scholar

Rahman, Q., & Wilson, G. D. (2003). Born gay? The psychobiology of human sexual orientation. Personality and Individual Differences, 34, 1337–1382.Google Scholar

Rantala, M. J., Luoto, S., Borráz-León, J. I., & Krams, I. (2021). Bipolar disorder: An evolutionary psychoneuroimmunological approach. Neuroscience and Biobehavioral Reviews, 122, 28–37.Google Scholar

Rantala, M. J., Luoto, S., Krama, T., & Krams, I. (2019). Eating disorders: An evolutionary psychoneuroimmunological approach. Frontiers in Psychology, 10, 2200.Google Scholar

Rees, J. S., Castellano, S., & Andrés, A. M. (2020). The genomics of human local adaptation. Trends in Genetics, 36, 415–428.Google Scholar

Rietveld, C. A., Medland, S. E., Derringer, J., Yang, J., Esko, T., Martin, N. W., … Koellinger, P. D. (2013). GWAS of 126,559 individuals identifies genetic variants associated with educational attainment. Science, 340, 1467–1471.Google Scholar

Robinson, M. R., Kleinman, A., Graff, M., Vinkhuyzen, A. A. E., Couper, D., Miller, M. B., … Nolte, I. M. (2017). Genetic evidence of assortative mating in humans. Nature Human Behaviour, 1, 0016.Google Scholar

Safran, R. J., Scordato, E. S. C., Symes, L. B., Rodríguez, R. L., & Mendelson, T. C. (2013). Contributions of natural and sexual selection to the evolution of premating reproductive isolation: A research agenda. Trends in Ecology & Evolution, 28, 643–650.Google Scholar

Segal, N. L. (2008). Born together – reared apart: The landmark Minnesota twin study. Cambridge, MA: Harvard University Press.Google Scholar

Segal, N. L. (2013). Personality similarity in unrelated look-alike pairs: Addressing a twin study challenge. Personality and Individual Differences, 54, 23–28.Google Scholar

Segal, N. L., & Macdonald, K. B. (1998). Behavioral genetics and evolutionary psychology: Unified perspective on personality research. Human Biology, 70, 159–184.Google Scholar

Slatkin, M. (2008). Linkage disequilibrium: Understanding the evolutionary past and mapping the medical future. Nature Reviews Genetics, 9, 477–485.Google Scholar

Stoltzfus, A., & Cable, K. (2014). Mendelian-mutationism: The forgotten evolutionary synthesis. Journal of the History of Biology, 47, 501–546.Google Scholar

Struik, D., Sanna, F., & Fattore, L. (2018). The modulating role of sex and anabolic-androgenic steroid hormones in cannabinoid sensitivity. Frontiers in Behavioral Neuroscience, 12, 249.Google Scholar

Stulp, G., & Barrett, L. (2016). Evolutionary perspectives on human height variation. Biological Reviews, 91, 206–234.Google Scholar

Swift-Gallant, A. (2019). Individual differences in the biological basis of androphilia in mice and men. Hormones and Behavior, 111, 23–30.Google Scholar

Swift-Gallant, A., Coome, L. A., Aitken, M., Ashley Monks, D., & VanderLaan, D. P. (2019). Evidence for distinct biodevelopmental influences on male sexual orientation. Proceedings of the National Academy of Sciences, 116, 12787–12792.Google Scholar

Syme, K. L., & Hagen, E. H. (2020). Mental health is biological health: Why tackling “diseases of the mind” is an imperative for biological anthropology in the 21st century. American Journal of Physical Anthropology, 171, 87–117.Google Scholar

Tinbergen, N. (1963). On aims and methods of ethology. Zeitschrift Für Tierpsychologie, 20, 410–433.Google Scholar

Tooby, J., & Cosmides, L. (1990). On the universality of human nature and the uniqueness of the individual: The role of genetics and adaptation. Journal of Personality, 58, 17–67.Google Scholar

Tucker-Drob, E. M., & Bates, T. C. (2016). Large cross-national differences in gene × socioeconomic status interaction on intelligence. Psychological Science, 27, 138–149.Google Scholar

Uchiyama, R., Spicer, R., & Muthukrishna, M. (2021). Cultural evolution of genetic heritability. Behavioral and Brain Sciences. doi: 10.1017/S0140525X21000893Google Scholar

van der Zee, M. D., Helmer, Q., Boomsma, D. I., Dolan, C. V., & de Geus, E. J. C. (2020). An extended twin-pedigree study of different classes of voluntary exercise behavior. Behavior Genetics, 50, 94–104.Google Scholar

van Doorn, G. S., Edelaar, P., & Weissing, F. J. (2009). On the origin of species by natural and sexual selection. Science, 326, 1704–1707.Google Scholar

Varella, M. A. C., Luoto, S., Silva Soares, R. B. da, & Valentova, J. V. (2021). COVID-19 pandemic on fire: Evolved propensities for nocturnal activities as a liability against epidemiological control. Frontiers in Psychology, 12, 646711.Google Scholar

Wiley, R. H. (2021). Natural selection. In Shackelford, T. K & Weekes-Shackelford, V. A. (Eds.), Encyclopedia of evolutionary psychological science. doi: 10.1007/978-3-319-16999-6_2095-1Google Scholar

Wilson, D. S. (1998). Adaptive individual differences within single populations. Philosophical Transactions of the Royal Society B: Biological Sciences, 353, 199–205.Google Scholar

Winther, R. G. (2000). Darwin on variation and heredity. Journal of the History of Biology, 33, 425–455.Google Scholar

Woodley, M. A. (2011). The cognitive differentiation-integration effort hypothesis: A synthesis between the fitness indicator and life history models of human intelligence. Review of General Psychology, 15, 228–245.Google Scholar

Woodley of Menie, M. A., Fernandes, H. B. F., & Hopkins, W. D. (2015). The more g-loaded, the more heritable, evolvable, and phenotypically variable: Homology with humans in chimpanzee cognitive abilities. Intelligence, 50, 159–163.Google Scholar

Woodley of Menie, M. A., Kanazawa, S., Pallesen, J., & Sarraf, M. A. (2020). Paternal age is negatively associated with religious behavior in a post-60s but not a pre-60s US birth cohort: Evidence for the Social Epistasis Amplification Model. Journal of Religion and Health, 59, 2733–2752.Google Scholar

Woodley of Menie, M. A., Luoto, S., Peñaherrera-Aguirre, M., & Sarraf, M. (2021a). Life history is a major source of adaptive individual and species differences: A critical commentary on Zietsch and Sidari (2020). Evolutionary Psychological Science, 7, 213–231.Google Scholar

Woodley of Menie, M. A., Pallesen, J., & Sarraf, M. A. (2018). Evidence for the Scarr–Rowe effect on genetic expressivity in a large US sample. Twin Research and Human Genetics, 21, 495–501.Google Scholar

Woodley of Menie, M. A., Pawlik, P., Webb, M. T., Bruce, K. D., & Devlin, P. F. (2019). Circadian leaf movements facilitate overtopping of neighbors. Progress in Biophysics and Molecular Biology, 146, 104–111.Google Scholar

Woodley of Menie, M. A., Peñaherrera-Aguirre, M., Dunkel, C., & Sarraf, M. A. (2021b). Evidence for the Scarr–Rowe effect on genetic expressivity in the Health and Retirement Study. Twin Research & Human Genetics, 24, 110–115.Google Scholar

Woodley of Menie, M. A., Peñaherrera-Aguirre, M., & Sarraf, M. A. (2021c). Estimating the additive heritability of historiometric eminence in a super-pedigree comprised of four prominent families. Twin Research & Human Genetics, 24, 191–199.Google Scholar

Woodley of Menie, M. A., & Sarraf, M. A. (2021). Controversies in evolutionary psychology. In Shackelford, T. K. & Weekes-Shackelford, V. A. (Eds.), Encyclopedia of evolutionary psychological science. doi: 10.1007/978-3-319-16999-6_2175-1Google Scholar

Xia, C., Canela-Xandri, O., Rawlik, K., & Tenesa, A. (2021). Evidence of horizontal indirect genetic effects in humans. Nature Human Behaviour, 5, 399–406.Google Scholar

Yang, J., Lee, S. H., Goddard, M. E., & Visscher, P. M. (2011). GCTA: A tool for genome-wide complex trait analysis. American Journal of Human Genetics, 88, 76–82.Google Scholar

Young, E. S., Frankenhuis, W. E., & Ellis, B. J. (2020). Theory and measurement of environmental unpredictability. Evolution and Human Behavior, 41, 550–556.Google Scholar

Zietsch, B. P., de Candia, T. R., & Keller, M. C. (2015). Evolutionary behavioral genetics. Current Opinion in Behavioral Sciences, 2, 73–80.Google Scholar

Zietsch, B. P., Sidari, M. J., Murphy, S. C., Sherlock, J. M., & Lee, A. J. (2021). For the good of evolutionary psychology, let’s reunite proximate and ultimate explanations. Evolution and Human Behavior, 42, 76–78.Google Scholar

Book contents

15 - Behavioral Genetics

Summary

Keywords

Access options

References

Save book to Kindle

Save book to Dropbox

Save book to Google Drive