Epigenetic developmental mechanisms underlying sex differences in cancer
Joshua B. Rubin, … , Jason P. Wong, Lihua Yang
Joshua B. Rubin, … , Jason P. Wong, Lihua Yang
Published July 1, 2024
Citation Information: J Clin Invest. 2024;134(13):e180071. https://doi.org/10.1172/JCI180071.
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Review Series

Epigenetic developmental mechanisms underlying sex differences in cancer

Abstract

Cancer risk is modulated by hereditary and somatic mutations, exposures, age, sex, and gender. The mechanisms by which sex and gender work alone and in combination with other cancer risk factors remain underexplored. In general, cancers that occur in both the male and female sexes occur more commonly in XY compared with XX individuals, regardless of genetic ancestry, geographic location, and age. Moreover, XY individuals are less frequently cured of their cancers, highlighting the need for a greater understanding of sex and gender effects in oncology. This will be necessary for optimal laboratory and clinical cancer investigations. To that end, we review the epigenetics of sexual differentiation and its effect on cancer hallmark pathways throughout life. Specifically, we will touch on how sex differences in metabolism, immunity, pluripotency, and tumor suppressor functions are patterned through the epigenetic effects of imprinting, sex chromosome complement, X inactivation, genes escaping X inactivation, sex hormones, and life history.

Authors

Joshua B. Rubin, Tamara Abou-Antoun, Joseph E. Ippolito, Lorida Llaci, Camryn T. Marquez, Jason P. Wong, Lihua Yang

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Figure 1

Mechanisms of transgenerational epigenetics.

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Mechanisms of transgenerational epigenetics. Transgenerational inheritan...
Transgenerational inheritance of epigenetic modifications are influenced by hormonal endocrine deregulators/disruptors and assisted fertility procedures and environmental exposures (chemicals, pollutants, toxins and pathogens), lifestyle factors (sedentary vs. physical activity, diet, alcohol, drug and nicotine use), maternal and paternal stressors (emotional, physical, psychological, and relationship dynamics) that can be passed on to subsequent generations: from parent (F0) to fetus (F1), to fetal gametes (F2), and so on. Such epigenetic modifications are known to alter the imprinting status of various genes (DLK1-MEG3, PEG1/MEST, UBE3A, CDKN1C, IGF2, H19) that manifest in imprinting disorders including: Prader-Willi Syndrome, and Angelman syndrome, and Beckwith-Wiedemann syndrome, among others. These syndromes are affiliated with cellular growth abnormalities predisposing the affected individual to an array of cancers including Wilms’ tumor, neuroblastoma, hepatoblastoma, and breast, uterine, ovarian and prostate cancers.