Female Bisexuality

doi:10.1017/9781108943581.006

4 - Female Bisexuality

from Part I - Controversies and Unresolved Issues

Published online by Cambridge University Press: 30 June 2022

Severi Luoto and

Markus J. Rantala

Edited by

Todd K. Shackelford

Show author details

Todd K. Shackelford: Affiliation:
Oakland University, Michigan

Book contents

Get access

Summary

Bisexual behavior is an order of magnitude more common than exclusive homosexuality in women. Many evolutionary hypotheses on sexual orientation have focused on homosexuality, particularly in men, yet there has recently been a growing recognition that male and female homosexuality may have different evolutionary origins, and that the various forms of nonheterosexuality in the female sexual orientation spectrum may arise via discrete evolutionary–developmental mechanisms. Evolutionarily informed sex research therefore has the fascinating task of understanding the whole spectrum of female sexual orientation – from heterosexual, mostly heterosexual, and bisexual women through to exclusively homosexual women, and from feminine femmes to masculine butches – including the proximate mechanisms and ultimate functions that underlie that variation. Here, we address that task by applying Tinbergen’s four questions to analyze female bisexuality, synthesizing existing research on proximate mechanisms, ontogeny, phylogeny, and ultimate functions. Research in psychology and behavioral sciences indicates that bisexual women comprise a group distinct from heterosexual women and, on some metrics, even from lesbian women: bisexual women have more male-typical personality traits, more unrestricted sociosexual attitudes and behaviors, higher sexual responsiveness, earlier reproduction, higher substance use, higher incarceration rates, and worse health outcomes than heterosexual women. There is broad evidence from across mammalian species that indicates that individual differences in prenatal exposure to sex hormones creates individual differences in brain morphology, cognition, behavioral predispositions, and even life outcomes. They are typically studied in a sex differences framework, but there is now enough evidence to suggest that sexual orientation differences along these parameters can also be robust and informative. We review ten ultimate-level hypotheses on the evolution of female bisexuality and conclude that four hypotheses – balanced polymorphism of masculinity, sexually antagonistic selection, hormonally mediated fast life history strategy, and by-product – are currently best supported by evidence. These hypotheses are also consilient with the wealth of neurodevelopmental evidence on the masculinization of the brain and behavior, which is thought to underlie variation in female sexual orientation. By synthesizing ultimate functions with proximate mechanisms – combined with powerful mid-level frameworks such as life history theory – evolutionary scientists are in a stronger position to provide a comprehensive account of the phenotypic variation observed in the female sexual orientation spectrum.

Keywords

female bisexuality sexual orientation evolutionary psychology behavioral endocrinology brain development life history Tinbergen’s four questions individual differences

Type: Chapter
Information: The Cambridge Handbook of Evolutionary Perspectives on Sexual Psychology , pp. 94 - 132

DOI: https://doi.org/10.1017/9781108943581.006 [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

Aboulghar, M. (2009). Luteal support in reproduction: When, what and how? Current Opinion in Obstetrics and Gynecology, 21(3), 279–284.Google Scholar

Adamsson, N. A., Brokken, L. J. S., Paranko, J., & Toppari, J. (2008). In vivo and in vitro effects of flutamide and diethylstilbestrol on fetal testicular steroidogenesis in the rat. Reproductive Toxicology, 25(1), 76–83.Google Scholar

Albrecht, E. D., & Pepe, G. J. (2010). Estrogen regulation of placental angiogenesis and fetal ovarian development during primate pregnancy. International Journal of Developmental Biology, 54(2–3), 397–407.CrossRef Google Scholar PubMed

Allen, L. S., Hines, M., Shryne, J. E., & Gorski, R. A. (1989). Two sexually dimorphic cell groups in the human brain. Journal of Neuroscience, 9(2), 497–506.Google Scholar

Allen, M. S., & Robson, D. A. (2020). Personality and sexual orientation: New data and meta-analysis. Journal of Sex Research, 57(8), 953–965.Google Scholar

Amateau, S. K., & McCarthy, M. M. (2002). A novel mechanism of dendritic spine plasticity involving estradiol induction of prostaglandin-E2. Journal of Neuroscience, 22(19), 8586–8596.Google Scholar

Amateau, S. K., & McCarthy, M. M. (2004). Induction of PGE2 by estradiol mediates developmental masculinization of sex behavior. Nature Neuroscience, 7(6), 643–650.Google Scholar

Apostolou, M. (2018a). Are women sexually fluid? The nature of female same-sex attraction and its evolutionary origins. Evolutionary Psychological Science, 4(2), 191–201.Google Scholar

Apostolou, M. (2018b). The evolutionary origins of same-sex attraction: Assessing weak negative selection and positive selection arguments. Mankind Quarterly, 59(2), 171–196.Google Scholar

Apostolou, M., Shialos, M., Khalil, M., & Paschali, V. (2017). The evolution of female same-sex attraction: The male choice hypothesis. Personality and Individual Differences, 116, 372–378.Google Scholar

Archer, J. (2019). The reality and evolutionary significance of human psychological sex differences. Biological Reviews, 94(4), 1381–1415.Google Scholar

Arnold, A. P. (2017). A general theory of sexual differentiation. Journal of Neuroscience Research, 95(1–2), 291–300.Google Scholar

Arnold, A. P. (2020). Sexual differentiation of brain and other tissues: Five questions for the next 50 years. Hormones and Behavior. https://doi.org/10.1016/j.yhbeh.2020.104691 CrossRef Google Scholar

Bagemihl, B. (1999). Biological exuberance: Animal homosexuality and natural diversity, 1st ed. New York: St. Martin’s Press.Google Scholar

Bailey, J. M. (2019). How to ruin sex research. Archives of Sexual Behavior, 48(4), 1007–1011.Google Scholar

Bailey, J. M., Willerman, L., & Parks, C. (1991). A test of the maternal stress theory of human male homosexuality. Archives of Sexual Behavior, 20(3), 277–293.Google Scholar

Baker, V. L., Jones, C. A., Doody, K., Foulk, R., Yee, B., Adamson, G. D., … & Soules, M. (2014). A randomized, controlled trial comparing the efficacy and safety of aqueous subcutaneous progesterone with vaginal progesterone for luteal phase support of in vitro fertilization. Human Reproduction, 29(10), 2212–2220.Google Scholar

Bakker, J., Brand, T., van Ophemert, J., & Slob, A. K. (1993). Hormonal regulation of adult partner preference behavior in neonatally ATD-treated male rats. Behavioral Neuroscience, 107(3), 480–487.Google Scholar

Bakker, J., Van Ophemert, J., & Slob, A. K. (1993). Organization of partner preference and sexual behavior and its nocturnal rhythmicity in male rats. Behavioral Neuroscience, 107(6), 1049–1058.Google Scholar

Bakker, J., Van Ophemert, J., & Slob, A. K. (1996). Sexual differentiation of odor and partner preference in the rat. Physiology and Behavior, 60(2), 489–494.Google Scholar

Balthazart, J. (2020). Sexual partner preference in animals and humans. Neuroscience & Biobehavioral Reviews, 115, 34–47.Google Scholar

Bao, A.-M., & Swaab, D. F. (2011). Sexual differentiation of the human brain: Relation to gender identity, sexual orientation and neuropsychiatric disorders. Frontiers in Neuroendocrinology, 32(2), 214–226.Google Scholar

Baron-Cohen, S., Tsompanidis, A., Auyeung, B., Nørgaard-Pedersen, B., Hougaard, D. M., Abdallah, M., … & Pohl, A. (2020). Foetal oestrogens and autism. Molecular Psychiatry, 25, 2970–2978.Google Scholar

Barron, A. B., & Hare, B. (2020). Prosociality and a sociosexual hypothesis for the evolution of same-sex attraction in humans. Frontiers in Psychology, 10, 2955.Google Scholar

Bateson, P., & Laland, K. N. (2013). Tinbergen’s four questions: An appreciation and an update. Trends in Ecology and Evolution, 28(12), 712–718.Google Scholar

Bejerot, S., & Eriksson, J. M. (2014). Sexuality and gender role in autism spectrum disorder: A case control study. PLOS ONE, 9(1), e87961.Google Scholar

Bekker, M., Van Heck, G. L., & Vingerhoets, A. J. (1996). Gender-identity, body-experience, sexuality, and the wish for having children in DES-daughters. Women and Health, 24, 65–82.CrossRef Google Scholar PubMed

Bennett, J. A., Zhu, S. J., Pagano-Mirarchi, A., Kellom, T. A., & Jacobson, H. I. (1998). α-Fetoprotein derived from a human hepatoma prevents growth of estrogen-dependent human breast cancer xenografts. Clinical Cancer Research, 4(11), 2877–2884.Google Scholar

Berenbaum, S. A., & Resnick, S. M. (1997). Early androgen effects on aggression in children and adults with congenital adrenal hyperplasia. Psychoneuroendocrinology, 22(7), 505–515.CrossRef Google Scholar PubMed

Betini, G. S., Avgar, T., & Fryxell, J. M. (2017). Why are we not evaluating multiple competing hypotheses in ecology and evolution? Royal Society Open Science, 4(1), 160756.Google Scholar

Blackburn, S. T. (2018). Maternal, fetal, & neonatal physiology: A clinical perspective, 5th ed. St. Louis, MO: Elsevier.Google Scholar

Bogaert, A. F., & Skorska, M. N. (2020). A short review of biological research on the development of sexual orientation. Hormones and Behavior, 119, 104659.Google Scholar

Breedlove, S. M. (2017). Response to commentaries. Archives of Sexual Behavior, 46(6), 1625–1629.Google Scholar

Breedlove, M. & Hampson, E. (2002). Sexual differentiation of the brain and behavior. In Becker, J., Breedlove, M., Crews, D., & McCarthy, M. M. (Eds.), Behavioral endocrinology (pp. 75–114). Cambridge, MA: MIT Press.Google Scholar

Brown, W. M., Finn, C. J., Cooke, B. M., & Breedlove, S. M. (2002). Differences in finger length ratios between self-identified “butch” and “femme” lesbians. Archives of Sexual Behavior, 31, 123–127.Google Scholar

Brunner, F., Fliegner, M., Krupp, K., Rall, K., Brucker, S., & Richter-Appelt, H. (2016). Gender role, gender identity and sexual orientation in CAIS (“XY-women”) compared with subfertile and infertile 46, XX women. Journal of Sex Research, 53(1), 109–124.Google Scholar

Burri, A., Spector, T., & Rahman, Q. (2015). Common genetic factors among sexual orientation, gender nonconformity, and number of sex partners in female twins: Implications for the evolution of homosexuality. Journal of Sexual Medicine, 12, 1004–1011.Google Scholar

Buss, D. M., & Schmitt, D. P. (2019). Mate preferences and their behavioral manifestations. Annual Review of Psychology, 70, 77–110.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(1), 14–32.CrossRef Google Scholar PubMed

Carroll, J. L., Volk, K. D., & Hyde, J. S. (1985). Differences between males and females in motives for engaging in sexual intercourse. Archives of Sexual Behavior, 14(2), 131–139.Google Scholar

Chivers, M. L. (2017). The specificity of women’s sexual response and its relationship with sexual orientations: A review and ten hypotheses. Archives of Sexual Behavior, 46(5), 1161–1179.Google Scholar

Clemens, L. G., & Gladue, B. A. (1978). Feminine sexual behavior in rats enhanced by prenatal inhibition of androgen aromatization. Hormones and Behavior, 11, 190–201.Google Scholar

Compton, D. R., Farris, D. N., & Chang, Y. T. (2015). Patterns of bisexuality in America. Journal of Bisexuality, 15(4), 481–497.Google Scholar

Confer, J. C., Easton, J. A., Fleischman, D. S., Goetz, C. D., Lewis, D. M. G., Perilloux, C., & Buss, D. M. (2010). Evolutionary psychology: Controversies, questions, prospects, and limitations. American Psychologist, 65(2), 110–126.Google Scholar

Cooke, P. S., Nanjappa, M. K., Ko, C., Prins, G. S., & Hess, R. A. (2017). Estrogens in male physiology. Physiological Reviews, 97(3), 995–1043.Google Scholar

Cornil, C. A., & Bakker, J. (2019). Alternative views on the role of sex steroid hormones on the emergence of phenotypic diversity in female sexual orientation. Archives of Sexual Behavior, 48(5), 1309–1313.Google Scholar

Daly, M., & Wilson, M. (1998). The truth about Cinderella: A Darwinian view of parental love. New Haven, CT: Yale University Press.Google Scholar

Dawkins, R. (2016). The selfish gene, 4th ed. Oxford: Oxford University Press.Google Scholar

de Jonge, F. H., Muntjewerff, J.-W., Louwerse, A. L., & de Poll, N. E. (1988). Sexual behavior and sexual orientation of the female rat after hormonal treatment during various stages of development. Hormones and Behavior, 22(1), 100–115.Google Scholar

Del Giudice, M. (in press a). Measuring sex differences and similarities. In VanderLaan, D. P., & Wong, W. I. (Eds.), Gender and sexuality development: Contemporary theory and research. New York: Springer.Google Scholar

Del Giudice, M. (in press b). Ideological bias in the psychology of sex and gender. In Frisby, C. L., O’Donohue, W. T., Redding, R. E., & Lilienfeld, S. O. (Eds.), Political bias in psychology: Nature, scope, and solutions. New York: Springer.Google Scholar

Diamond, L. M. (2003). What does sexual orientation orient? A biobehavioral model distinguishing romantic love and sexual desire. Psychological Review, 110(1), 173–192.Google Scholar

Diamond, L. M. (2008). Sexual fluidity. Cambridge, MA: Harvard University Press.Google Scholar

Dickins, T. E., & Rahman, Q. (2020). Ancestral primacy of same-sex sexual behaviour does not explain its stable prevalence in modern populations. Nature Ecology and Evolution. https://doi.org/10.1038/s41559–020-1187-5 Google Scholar

Dittmann, R. W., Kappes, M. E., & Kappes, M. H. (1992). Sexual behavior in adolescent and adult females with congenital adrenal hyperplasia. Psychoneuroendocrinology, 17(2), 153–170.Google Scholar

Dittmann, R. W., Kappes, M. H., Kappes, M. E., Börger, D., Stegner, H., Willig, R. H., & Wallis, H. (1990). Congenital adrenal hyperplasia I: Gender-related behavior and attitudes in female patients and sisters. Psychoneuroendocrinology, 15, 401–420.Google Scholar

Dixson, A. (2012). Primate sexuality: Comparative studies of the prosimians, monkeys, apes, and humans. New York: Oxford University Press.Google Scholar

Dixson, A. (2015). Primate sexuality. In Whelehan, P. & Bolin, A. (Eds.), The international encyclopedia of human sexuality. Chichester: Wiley-Blackwell.Google Scholar

Döhler, K. D., Coquelin, A., Davis, F., Hines, M., Shryne, J. E., & Gorski, R. A. (1984). Pre- and postnatal influence of testosterone propionate and diethylstilbestrol on differentiation of the sexually dimorphic nucleus of the preoptic area in male and female rats. Brain Research, 302, 291–295.Google Scholar

Doughty, C., Booth, J. E., McDonald, P. G., & Parrott, R. F. (1975). Inhibition, by the anti oestrogen MER 25, of defeminization induced by the synthetic oestrogen RU 2858. Journal of Endocrinology, 67, 459–460.Google Scholar

Ehrhardt, A. A., Meyer-Bahlburg, H. F. L., Rosen, L. R., Feldman, J. F., Veridiano, N. P., Zimmerman, I., & McEwen, B. S. (1985). Sexual orientation after prenatal exposure to exogenous estrogen. Archives of Sexual Behavior, 14, 57–77.Google Scholar

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

Faber, K. A., & Hughes, C. L. (1991). The effect of neonatal exposure to diethylstilbestrol, genistein, and zearalenone on pituitary responsiveness and sexually dimorphic nucleus volume in the castrated adult rat. Biology of Reproduction, 45, 649–653.Google Scholar

Farr, R. H., Diamond, L. M., & Boker, S. M. (2014). Female same-sex sexuality from a dynamical systems perspective: Sexual desire, motivation, and behavior. Archives of Sexual Behavior, 43(8), 1477–1490.Google Scholar

Figueredo, A. J., Fernandes, H. B. F., & Peñaherrera-Aguirre, M. (2019). Do the predictors of atypical sexual orientations in women generalize across different evolutionary tests? Archives of Sexual Behavior, 48(5), 1325–1328.Google Scholar

Fisher, A. D., Ristori, J., Morelli, G., & Maggi, M. (2018). The molecular mechanisms of sexual orientation and gender identity. Molecular and Cellular Endocrinology, 467, 3–13.Google Scholar

Fisher, H. E., Aron, A., & Brown, L. L. (2006). Romantic love: A mammalian brain system for mate choice. Philosophical Transactions of the Royal Society of London. Series B, Biological Sciences, 361(1476), 2173–2186.Google Scholar

Frisén, L., Nordenström, A., Falhammar, H., Filipsson, H., Holmdahl, G., Janson, P. O., … & Nordenskjöld, A. (2009). Gender role behavior, sexuality, and psychosocial adaptation in women with congenital adrenal hyperplasia due to CYP21A2 deficiency. Journal of Clinical Endocrinology and Metabolism, 94(9), 3432–3439.Google Scholar

Fruth, B., & Hohmann, G. (2006). Social grease for females? Same sex genital contacts in wild bonobos. In Sommer, V. & Vasey, P. L. (Eds.), Homosexual behaviour in animals: An evolutionary perspective (pp. 294–316). Cambridge: Cambridge University Press.Google Scholar

Fudge, D. S. (2014). Fifty years of J. R. Platt’s strong inference. Journal of Experimental Biology, 217, 1202–1204.Google Scholar

George, F. W., & Ojeda, S. R. (1982). Changes in aromatase activity in the rat brain during embryonic, neonatal, and infantile development. Endocrinology, 111(2), 522–529.Google Scholar

Gettler, L. T., Ryan, C. P., Eisenberg, D. T. A., Rzhetskaya, M., Hayes, M. G., Feranil, A. B., … & Kuzawa, C. W. (2017). The role of testosterone in coordinating male life history strategies: The moderating effects of the androgen receptor CAG repeat polymorphism. Hormones and Behavior, 87, 164–175.CrossRef Google Scholar PubMed

Giusti, R. M., Iwamoto, K., & Hatch, E. E. (1995). Diethylstilbestrol revisited: A review of the long-term health effects. Annals of Internal Medicine, 122, 778–788.Google Scholar

González, M., Cabrera-Socorro, A., Pérez-García, C. G., Fraser, J. D., López, F. J., Alonso, R., & Meyer, G. (2007). Distribution patterns of estrogen receptor α and β in the human cortex and hippocampus during development and adulthood. Journal of Comparative Neurology, 503(6), 790–802.Google Scholar

Gorski, R. A., Gordon, J. H., Shryne, J. E., & Southam, A. M. (1978). Evidence for a morphological sex difference within the medial preoptic area of the rat brain. Brain Research, 148, 333–346.Google Scholar

Gorski, R. A., Harlan, R. E., Jacobson, C. D., Shryne, J. E., & Southam, A. M. (1980). Evidence for the existence of a sexually dimorphic nucleus in the preoptic area of the rat. Journal of Comparative Neurology, 193, 529–539.Google Scholar

Grov, C., Bimbi, D. S., Nanín, J. E., & Parsons, J. T. (2006). Race, ethnicity, gender, and generational factors associated with the coming-out process among gay, lesbian, and bisexual individuals. Journal of Sex Research, 43(2), 115–121.Google Scholar

Hämäläinen, A., Immonen, E., Tarka, M., & Schuett, W. (2018). Evolution of sex-specific pace-of-life syndromes: Causes and consequences. Behavioral Ecology and Sociobiology. https://doi.org/10.1007/s00265–018-2466-x Google Scholar

Hashimoto, M., Miyamoto, Y., Iwai, C., Matsuda, Y., Hiraoka, E., Kanazawa, K., … & Akita, H. (2009). Delivery may affect arterial elasticity in women. Circulation Journal, 73(4), 750–754.CrossRef Google Scholar PubMed

Hiestand, K. R., & Levitt, H. M. (2005). Butch identity development: The formation of an authentic gender. Feminism and Psychology, 15, 61–85.CrossRef Google Scholar

Hines, M. (2011a). Gender development and the human brain. Annual Review of Neuroscience, 34, 69–88.CrossRef Google Scholar PubMed

Hines, M. (2011b). Prenatal endocrine influences on sexual orientation and on sexually differentiated childhood behavior. Frontiers in Neuroendocrinology, 32, 170–182.Google Scholar

Hines, M., Ahmed, S. F., & Hughes, I. A. (2003). Psychological outcomes and gender-related development in complete androgen insensitivity syndrome. Archives of Sexual Behavior, 32(2), 93–101.Google Scholar

Hines, M., Brook, C., & Conway, G. S. (2004). Androgen and psychosexual development: Core gender identity, sexual orientation, and recalled childhood gender role behavior in women and men with congenital adrenal hyperplasia (CAH). Journal of Sex Research, 41, 75–81.Google Scholar

Hines, M., Constantinescu, M., & Spencer, D. (2015). Early androgen exposure and human gender development. Biology of Sex Differences, 6(1), 3.Google Scholar

Houtsmuller, E. J., Brand, T., de Jonge, F. H., Joosten, R. N. J. M. A., van de Poll, N. E., & Slob, A. K. (1994). SDN-POA volume, sexual behavior, and partner preference of male rats affected by perinatal treatment with ATD. Physiology and Behavior, 56(3), 535–541.Google Scholar

Hughes, S. M., Aung, T., Harrison, M. A., Lafayette, J. N., & Gallup, G. G. (2021). Experimental evidence for sex differences in sexual variety preferences: Support for the Coolidge Effect in humans. Archives of Sexual Behavior, 50, 495–509.Google Scholar

Immonen, E., Hämäläinen, A., Schuett, W., & Tarka, M. (2018). Evolution of sex-specific pace-of-life syndromes: Genetic architecture and physiological mechanisms. Behavioral Ecology and Sociobiology, 72(3), 60.CrossRef Google Scholar PubMed

Ivanova, T., & Beyer, C. (2000). Ontogenetic expression and sex differences of aromatase and estrogen receptor-α/β mRNA in the mouse hippocampus. Cell and Tissue Research, 300(2), 231–237.Google Scholar

Jacobson, C. D., Csernus, V. J., Shryne, J. E., & Gorski, R. A. (1981). The influence of gonadectomy, androgen exposure, or a gonadal graft in the neonatal rat on the volume of the sexually dimorphic nucleus of the preoptic area. Journal of Neuroscience, 1(10), 1142–1147.Google Scholar

Jacobson, C. D., Shryne, J. E., Shapiro, F., & Gorski, R. A. (1980). Ontogeny of the sexually dimorphic nucleus of the preoptic area. Journal of Comparative Neurology, 193(2), 541–548.Google Scholar

Jonason, P. K., & Luoto, S. (2021). The dark side of the rainbow: Homosexuals and bisexuals have higher Dark Triad traits than heterosexuals. Personality and Individual Differences, 181, 111040.CrossRef Google Scholar

Kanazawa, S. (2017). Possible evolutionary origins of human female sexual fluidity. Biological Reviews, 92(3), 1251–1274.Google Scholar

Koebele, S. V., & Bimonte-Nelson, H. A. (2015). Trajectories and phenotypes with estrogen exposures across the lifespan: What does Goldilocks have to do with it? Hormones and Behavior, 74, 86–104.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(3), 421–427.Google Scholar

Kravitz, H. M., Haywood, T. W., Kelly, J., Liles, S., & Cavanaugh, J. L. (1996). Medroxyprogesterone and paraphiles: Do testosterone levels matter? Bulletin of the American Academy of Psychiatry and the Law, 24(1), 73–83.Google Scholar

Krueger, E. A., Fish, J. N., & Upchurch, D. M. (2020). Sexual orientation disparities in substance use: Investigating social stress mechanisms in a national sample. American Journal of Preventive Medicine, 58(1), 59–68.Google Scholar

Kuhle, B. X., & Radtke, S. (2013). Born both ways: The alloparenting hypothesis for sexual fluidity in women. Evolutionary Psychology. https://doi.org/10.1177/147470491301100200 Google Scholar

Lai, M. C., Lombardo, M. V., Suckling, J., Ruigrok, A. N. V., Chakrabarti, B., Ecker, C., … & Baron-Cohen, S. (2013). Biological sex affects the neurobiology of autism. Brain, 136, 2799–2815.Google Scholar

Lam, J. S., Leppert, J. T., Vemulapalli, S. N., Shvarts, O., & Belldegrun, A. S. (2006). Secondary hormonal therapy for advanced prostate cancer. Journal of Urology, 175(1), 27–34.Google Scholar

Lauber, M. E., & Lichtensteiger, W. (1994). Pre- and postnatal ontogeny of aromatase cytochrome P450 messenger ribonucleic acid expression in the male rat brain studied by in situ hybridization. Endocrinology, 135(4), 1661–1668.Google Scholar

Lenz, K. M., Nugent, B. M., & McCarthy, M. M. (2012). Sexual differentiation of the rodent brain: Dogma and beyond. Frontiers in Neuroscience, 6, 26.Google Scholar

Lerch, B. A., & Servedio, M. R. (2020). Same-sex sexual behaviour and selection for indiscriminate mating. Nature Ecology & Evolution. https://doi.org/10.1038/s41559–020-01331-w Google Scholar

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

Levitt, H. M., Gerrish, E. A., & Hiestand, K. R. (2003). The misunderstood gender: A model of modern femme identity. Sex Roles, 48, 99–113.Google Scholar

Levitt, H. M., & Horne, S. G. (2002). Explorations of lesbian-queer genders: Butch, femme, androgynous or “other.” Journal of Lesbian Studies, 6, 25–39.Google Scholar

Lewis, D. M. G., Conroy-Beam, D., Asao, K., & Buss, D. M. (2017). Evolutionary psychology: A how-to guide. American Psychologist, 72(4), 353–373.Google Scholar

Lippa, R. A. (2005). Sexual orientation and personality. Annual Review of Sex Research, 16(1), 119–153.Google Scholar

Lippa, R. A. (2020). Interest, personality, and sexual traits that distinguish heterosexual, bisexual, and homosexual individuals: Are there two dimensions that underlie variations in sexual orientation? Archives of Sexual Behavior, 49, 607–622.Google Scholar

Luoto, S. (2019). An updated theoretical framework for human sexual selection: From ecology, genetics, and life history to extended phenotypes. Adaptive Human Behavior and Physiology, 5(1), 48–102.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(5), 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(5), 1335–1347.Google Scholar

Luoto, S., & Rantala, M. J. (2017). Specificity of women’s sexual response: Proximate mechanisms and ultimate causes. Archives of Sexual Behavior, 46(5), 1195–1198.Google Scholar

Luoto, S., & Rantala, M. J. (2018). On estrogenic masculinization of the human brain and behavior. Hormones and Behavior, 97, 1–2.Google Scholar

MacLusky, N. J., & Naftolin, F. (1981). Sexual differentiation of the central nervous system. Science, 211, 1294–1302.Google Scholar

Mathews, G. A., Fane, B. A., Conway, G. S., Brook, C. G. D., & Hines, M. (2009). Personality and congenital adrenal hyperplasia: Possible effects of prenatal androgen exposure. Hormones and Behavior, 55(2), 285–291.Google Scholar

McCarthy, M. M. (2008). Estradiol and the developing brain. Physiological Reviews, 88, 91–134.Google Scholar

McEwen, B. S., Lieberburg, I., Chaptal, C., & Krey, L. C. (1977). Aromatization: Important for sexual differentiation of the neonatal rat brain. Hormones and Behavior, 9, 249–263.Google Scholar

Meyer, I. H., Flores, A. R., Stemple, L., Romero, A. P., Wilson, B. D. M., & Herman, J. L. (2017). Incarceration rates and traits of sexual minorities in the United States: National inmate survey, 2011–2012. American Journal of Public Health, 107(2), 267–273.Google Scholar

Meyer-Bahlburg, H. F. L., Dolezal, C., Baker, S. W., & New, M. I. (2008). Sexual orientation in women with classical or non-classical congenital adrenal hyperplasia as a function of degree of prenatal androgen excess. Archives of Sexual Behavior, 37, 85–99.Google Scholar

Meyer-Bahlburg, H. F. L., Ehrhardt, A. A., Rosen, L. R., Gruen, R. S., Veridiano, N. P., Vann, F. H., & Neuwalder, H. F. (1995). Prenatal estrogens and the development of homosexual orientation. Developmental Psychology, 31(1), 12–21.Google Scholar

Miller, E. M. (2000). Homosexuality, birth order, and evolution: Toward an equilibrium reproductive economics of homosexuality. Archives of Sexual Behavior, 29, 1–34.Google Scholar

Monk, J. D., Giglio, E., Kamath, A., Lambert, M. R., & McDonough, C. E. (2019). An alternative hypothesis for the evolution of same-sex sexual behaviour in animals. Nature Ecology and Evolution, 3(12), 1622–1631.Google Scholar

Motta-Mena, N. V, & Puts, D. A. (2017). Endocrinology of human female sexuality, mating, and reproductive behavior. Hormones and Behavior, 91, 19–35.Google Scholar

Neulen, J., Zahradnik, H. P., Flecken, U., & Breckwoldt, M. (1989). The effect of cortisol on the synthesis of prostaglandins (PGF2α, PGE2) by human endometrial fibroblasts in vitro with and without addition of estradiol-17β or progesterone. Prostaglandins, 37(5), 587–595.CrossRef Google Scholar PubMed

Palagiano, A., Bulletti, C., Pace, M. C., De Ziegler, D., Cicinelli, E., & Izzo, A. (2004). Effects of vaginal progesterone on pain and uterine contractility in patients with threatened abortion before twelve weeks of pregnancy. Annals of the New York Academy of Sciences, 1034(1), 200–210.Google Scholar

Paredes, R. G., Tzschentke, T., & Nakach, N. (1998). Lesions of the medial preoptic area/anterior hypothalamus (MPOA/AH) modify partner preference in male rats. Brain Research, 813(1), 1–8.Google Scholar

Pasterski, V., Geffner, M. E., Brain, C., Hindmarsh, P., Brook, C., & Hines, M. (2011). Prenatal hormones and childhood sex segregation: Playmate and play style preferences in girls with congenital adrenal hyperplasia. Hormones and Behavior, 59, 549–555.Google Scholar

Pasterski, V., Hindmarsh, P., Geffner, M., Brook, C., Brain, C., & Hines, M. (2007). Increased aggression and activity level in 3- to 11-year-old girls with congenital adrenal hyperplasia (CAH). Hormones and Behavior, 52(3), 368–374.Google Scholar

Pasterski, V., Zucker, K. J., Hindmarsh, P. C., Hughes, I. A., Acerini, C., Spencer, D., … & Hines, M. (2015). Increased cross-gender identification independent of gender role behavior in girls with congenital adrenal hyperplasia: Results from a standardized assessment of 4-to 11-year-old children. Archives of Sexual Behavior, 44, 1363–1375.Google Scholar

Pistella, J., Salvati, M., Ioverno, S., Laghi, F., & Baiocco, R. (2016). Coming-out to family members and internalized sexual stigma in bisexual, lesbian and gay people. Journal of Child and Family Studies, 25(12), 3694–3701.Google Scholar

Playà, E., Vinicius, L., & Vasey, P. L. (2017). Need for alloparental care and attitudes toward homosexuals in 58 countries: Implications for the kin selection hypothesis. Evolutionary Psychological Science, 3(4), 345–352.Google Scholar

Poiani, A. (2010). Animal homosexuality: A biosocial perspective. Cambridge: Cambridge University Press.Google Scholar

Qualls, L. R., Hartmann, K., & Paulson, J. F. (2018). Broad autism phenotypic traits and the relationship to sexual orientation and sexual behavior. Journal of Autism and Developmental Disorders, 48(12), 3974–3983.CrossRef Google Scholar PubMed

Rahman, Q., Xu, Y., Lippa, R. A., & Vasey, P. L. (2020). Prevalence of sexual orientation across 28 nations and its association with gender equality, economic development, and individualism. Archives of Sexual Behavior, 49, 595–606.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

Raznahan, A., & Disteche, C. M. (2021). X-chromosome regulation and sex differences in brain anatomy. Neuroscience & Biobehavioral Reviews, 120, 28–47.Google Scholar

Reinisch, J. M., Mortensen, E. L., & Sanders, S. A. (2017). Prenatal exposure to progesterone affects sexual orientation in humans. Archives of Sexual Behavior, 46(5), 1239–1249.Google Scholar

Reinisch, J. M., Ziemba-Davis, M., & Sanders, S. A. (1991). Hormonal contributions to sexually dimorphic behavioral development in humans. Psychoneuroendocrinology, 16, 213–278.Google Scholar

Reynolds, A. L., & Hanjorgiris, W. F. (2000). Coming out: Lesbian, gay, and bisexual identity development. In Perez, R. M., DeBord, K. A., & Bieschke, K. J. (Eds.), Handbook of counseling and psychotherapy with lesbian, gay, and bisexual clients (pp. 35–55). Washington, DC: American Psychological Association.Google Scholar

Rice, W. R., Friberg, U., & Gavrilets, S. (2016). Sexually antagonistic epigenetic marks that canalize sexually dimorphic development. Molecular Ecology, 25(8), 1812–1822.Google Scholar

Richardson, G. B., Placek, C., Srinivas, V., Jayakrishna, P., Quinlan, R., & Madhivanan, P. (2020). Environmental stress and human life history strategy development in rural and peri-urban South India. Evolution and Human Behavior, 41(3), 244–252.CrossRef Google Scholar

Rieger, G., Holmes, L., Watts-Overall, T. M., Gruia, D. C., Bailey, J. M., & Savin-Williams, R. C. (2020). Gender nonconformity of bisexual men and women. Archives of Sexual Behavior, 49, 2481–2495.Google Scholar

Roselli, C. E., Larkin, K., Resko, J. A., Stellflug, J. N., & Stormshak, F. (2004). The volume of a sexually dimorphic nucleus in the ovine medial preoptic area/anterior hypothalamus varies with sexual partner preference. Endocrinology, 145(2), 478–483.Google Scholar

Roselli, C. E., Meaker, M., Stormshak, F., & Estill, C. T. (2016). Effects of long-term flutamide treatment during development on sexual behaviour and hormone responsiveness in rams. Journal of Neuroendocrinology. https://doi.org/10.1111/jne.12389 Google Scholar

Roselli, C. E., & Resko, J. A. (1993). Aromatase activity in the rat brain: Hormonal regulation and sex differences. Journal of Steroid Biochemistry and Molecular Biology, 44(4–6), 499–508.Google Scholar

Roselli, C. E., Schrunk, J. M., Stadelman, H. L., Resko, J. A., & Stormshak, F. (2006). The effect of aromatase inhibition on the sexual differentiation of the sheep brain. Endocrine, 29(3), 501–511.Google Scholar

Roselli, C. E., & Stormshak, F. (2009). The neurobiology of sexual partner preferences in rams. Hormones and Behavior, 55(5), 611–620.Google Scholar

Rubika, A., Luoto, S., Krama, T., Trakimas, G., Rantala, M. J., Moore, F. R., … & Krams, I. A. (2020). Women’s socioeconomic position in ontogeny is associated with improved immune function and lower stress, but not with height. Scientific Reports. https://doi.org/10.1038/s41598–020-68217-6 Google Scholar

Sabia, J. J., Wooden, M., & Nguyen, T. T. (2017). Sexual identity, same-sex relationships, and labour market dynamics: New evidence from longitudinal data in Australia. Southern Economic Journal, 83(4), 903–931.Google Scholar

Sanders, S. A., & Reinisch, J. M. (1985). Behavioral effects on humans of progesterone-related compounds during development and in the adult. In Ganten, D. & Pfaff, D. (Eds.), Actions of progesterone on the brain (Vol. 5, pp. 175–205). Berlin: Springer.Google Scholar

Santtila, P., Sandnabba, N. K., Harlaar, N., Varjonen, M., Alanko, K., & von der Pahlen, B. (2008). Potential for homosexual response is prevalent and genetic. Biological Psychology, 77(1), 102–105.Google Scholar

Savin-Williams, R. C., Joyner, K., & Rieger, G. (2012). Prevalence and stability of self-reported sexual orientation identity during young adulthood. Archives of Sexual Behavior, 41, 103–110.Google Scholar

Schieve, L. A., Tian, L., Dowling, N., Croen, L., Hoover-Fong, J., Alexander, A., & Shapira, S. K. (2018). Associations between the 2nd to 4th digit ratio and autism spectrum disorder in population-based samples of boys and girls: Findings from the Study to Explore Early Development. Journal of Autism and Developmental Disorders, 48(7), 2379–2395.Google Scholar

Schmitt, D. P. (2007). Sexual strategies across sexual orientations: How personality traits and culture relate to sociosexuality among gays, lesbians, bisexuals, and heterosexuals. Journal of Psychology & Human Sexuality, 18(2–3), 183–214.Google Scholar

Schuler, M. S., & Collins, R. L. (2020). Sexual minority substance use disparities: Bisexual women at elevated risk relative to other sexual minority groups. Drug and Alcohol Dependence, 206, 107755.Google Scholar

Semenyna, S. W., Belu, C. F., Vasey, P. L., & Honey, L. (2018). Not straight and not straightforward: The relationships between sexual orientation, sociosexuality, and dark triad traits in women. Evolutionary Psychological Science, 4(1), 24–37.Google Scholar

Simpson, P. L., Hardiman, D., & Butler, T. (2019). Understanding the over-representation of lesbian or bisexual women in the Australian prisoner population. Current Issues in Criminal Justice, 31(3), 365–377.Google Scholar

Singh, D., Vidaurri, M., Zambarano, R. J., & Dabbs, J. M. (1999). Lesbian erotic role identification: Behavioral, morphological, and hormonal correlates. Journal of Personality and Social Psychology, 76(6), 1035–1049.Google Scholar

Smith, E. P., Boyd, J., Frank, G. R., Takahashi, H., Cohen, R. M., Specker, B., … & Korach, K. S. (1994). Estrogen resistance caused by a mutation in the estrogen-receptor gene in a man. New England Journal of Medicine, 331(16), 1056–1061.Google Scholar

Spencer, D., Pasterski, V., Neufeld, S., Glover, V., O’Connor, T. G., Hindmarsh, P. C., … & Hines, M. (2017). Prenatal androgen exposure and children’s aggressive behavior and activity level. Hormones and Behavior, 96(November), 156–165.Google Scholar

Stief, M. C., Rieger, G., & Savin-Williams, R. C. (2014). Bisexuality is associated with elevated sexual sensation seeking, sexual curiosity, and sexual excitability. Personality and Individual Differences, 66, 193–198.Google Scholar

Stolarski, M., Czarna, A. Z., Malesza, M., & Szymańska, A. (2017). Here and now: Sociosexuality mediates the associations between Dark Triad and time perspectives (in females). Personality and Individual Differences, 111, 119–123.Google Scholar

Sugiyama, N., Barros, R. P. A., Warner, M., & Gustafsson, J. Å. (2010). ERβ: Recent understanding of estrogen signaling. Trends in Endocrinology and Metabolism, 21(9), 545–552.Google Scholar

Swaab, D. F., & Garcia-Falgueras, A. (2009). Sexual differentiation of the human brain in relation to gender identity and sexual orientation. Functional Neurology, 24(1), 17–28.Google Scholar

Swartz, S. K., & Soloff, M. S. (1974). The lack of estrogen binding by human α-fetoprotein. Journal of Clinical Endocrinology and Metabolism, 39(3), 589–591.Google Scholar

Tal, R., Taylor, H. S., Burney, R. O., Mooney, S. B., & Giudice, L. C. (2015). Endocrinology of pregnancy. In Feingold, K. R., Anawalt, B., Boyce, A., Chrousos, G., de Herder, W. W., Dhatariya, K., … & Wilson, D. P. (Eds.), Endotext. Dartmouth, MA: MDText. www.ncbi.nlm.nih.gov/books/NBK278962/Google Scholar

Terentiev, A. A., & Moldogazieva, N. T. (2013). Alpha-fetoprotein: A renaissance. Tumor Biology, 34(4), 2075–2091.Google Scholar

Tinbergen, N. (1963). On aims and methods of ethology. Zeitschrift Für Tierpsychologie, 20(4), 410–433.Google Scholar

Trivers, R. (1972). Parental investment and sexual selection. In Campbell, B. (Ed.), Sexual selection & the descent of man (pp. 136–179). Chicago: Aldine.Google Scholar

Trocki, K. F., Drabble, L. A., & Midanik, L. T. (2009). Tobacco, marijuana, and sensation seeking: Comparisons across gay, lesbian, bisexual, and heterosexual groups. Psychology of Addictive Behaviors, 23, 620–631.Google Scholar

Troisi, R., Palmer, J. R., Hatch, E. E., Strohsnitter, W. C., Huo, D., Hyer, M., … & Titus, L. (2020). Gender identity and sexual orientation identity in women and men prenatally exposed to diethylstilbestrol. Archives of Sexual Behavior, 49(2), 447–454.Google Scholar

Van Griensven, F., Kilmarx, P. H., Jeeyapant, S., Manopaiboon, C., Korattana, S., Jenkins, R. A., … & Mastro, T. D. (2004). The prevalence of bisexual and homosexual orientation and related health risks among adolescents in northern Thailand. Archives of Sexual Behavior, 33(2), 137–147.Google Scholar

Vasey, P. L., & Terry, L. (2009). Sexual fluidity: Understanding women’s love and desire. Archives of Sexual Behavior, 38, 1064.Google Scholar

Wagner, C. K., & Morrell, J. I. (1996). Distribution and steroid hormone regulation of aromatase mRNA expression in the forebrain of adult male and female rats: A cellular-level analysis using in situ hybridization. Journal of Comparative Neurology, 370(1), 71–84.Google Scholar

Wagner, C. K., & Morrell, J. I. (1997). Neuroanatomical distribution of aromatase mRNA in the rat brain: Indications of regional regulation. Journal of Steroid Biochemistry and Molecular Biology, 61(3–6), 307–314.Google Scholar

Wallen, K. (2005). Hormonal influences on sexually differentiated behavior in nonhuman primates. Frontiers in Neuroendocrinology, 26(1), 7–26.Google Scholar

Wells, J. C. K., & Stock, J. T. (2020). Life history transitions at the origins of agriculture: A model for understanding how niche construction impacts human growth, demography and health. Frontiers in Endocrinology, 11, 325.Google Scholar

Wood, C. E. (2014). Estrogen in the fetus. In Zhang, L. & Ducsay, C. (Eds.), Advances in fetal and neonatal physiology (pp. 217–228). New York: Springer.CrossRef Google Scholar

Worthman, C. M., & Trang, K. (2018). Dynamics of body time, social time and life history at adolescence. Nature, 554(7693), 451–457.Google Scholar

Wright, C. L., & McCarthy, M. M. (2009). Prostaglandin E2-induced masculinization of brain and behavior requires protein kinase A, AMPA/kainate, and metabotropic glutamate receptor signaling. Journal of Neuroscience, 29(42), 13274–13282.Google Scholar

Yalom, I. D., Green, R., & Fisk, N. (1973). Prenatal exposure to female hormones: Effect on psychosexual development in boys. Archives of General Psychiatry, 28(4), 554–561.Google Scholar

Young, L. C., Zaun, B. J., & VanderWerf, E. A. (2008). Successful same-sex pairing in Laysan albatross. Biology Letters, 4, 323–325.Google Scholar

Zheng, L., Wen, G., & Zheng, Y. (2018). Butch–femme identity and visuospatial performance among lesbian and bisexual women in China. Archives of Sexual Behavior, 47(4), 1015–1024.Google Scholar

Zietsch, B. P., Morley, K. I., Shekar, S. N., Verweij, K. J. H., Keller, M. C., Macgregor, S., … & Martin, N. G. (2008). Genetic factors predisposing to homosexuality may increase mating success in heterosexuals. Evolution and Human Behavior, 29, 424–433.Google Scholar

Zietsch, B. P., Sidari, M. J., Murphy, S. C., Sherlock, J. M., & Lee, A. J. (2020). For the good of evolutionary psychology, let’s reunite proximate and ultimate explanations. Evolution and Human Behavior. https://doi.org/10.1016/j.evolhumbehav.2020.06.009 Google Scholar

Book contents

4 - Female Bisexuality

Summary

Keywords

Access options

References

Save book to Kindle

Save book to Dropbox

Save book to Google Drive