Abstract
Using gene expression microarrays and reverse transcription with quantitative polymerase chain reaction (RT-qPCR), we have recently identified several novel genes that are differentially expressed in the neonatal male versus female mouse cortex/hippocampus (Armoskus et al.). Since perinatal testosterone (T) secreted by the developing testes masculinizes cortical and hippocampal structures and the behaviors regulated by these brain regions, we hypothesized that sexually dimorphic expression of specific selected genes in these areas might be regulated by T during early development. To test our hypothesis, we treated timed pregnant female mice daily with vehicle or testosterone propionate (TP) starting on embryonic day 16 until the day of birth. The cortex/hippocampus was collected from vehicle- and TP-treated, male and female neonatal pups. Total RNA was extracted from these brain tissues, followed by RT-qPCR to measure relative mRNA levels of seven sex chromosome genes and three autosomal genes that have previously showed sex differences. The effect of prenatal TP was confirmed as it stimulated Dhcr24 expression in the neonatal mouse cortex/hippocampus and increased the anogenital distance in females. We found a significant effect of sex, but not TP, on expression of three Y-linked (Ddx3y, Eif2s3y, and Kdm5d), four X-linked (Eif2s3x, Kdm6a, Mid1, and Xist), and one autosomal (Klk8) genes in the neonatal mouse cortex/hippocampus. Although most of the selected genes are not directly regulated by prenatal T, their sexually dimorphic expression might play an important role in the control of sexually differentiated cognitive and social behaviors as well as in the etiology of sex-biased neurological disorders and mental illnesses.
Highlights
In many species, including mice and humans, sexual differentiation is essential for the development of distinct brain structure and function between the sexes [1,2,3,4]
Using gene expression microarrays with reverse transcription quantitative polymerase chain reaction, we have recently identified a group of sex-biased genes expressed in the neonatal mouse cortex/ hippocampus [30]
A significant effect of testosterone propionate (TP) treatment was found on brain tissue weight, with greater cortex/ hippocampus weight in TP-treated mice than vehicle-treated controls (p = 0.022)
Summary
In many species, including mice and humans, sexual differentiation is essential for the development of distinct brain structure and function between the sexes [1,2,3,4]. Determination of the mechanisms controlling sexual dimorphism in brain structure and function will enhance our understanding of the underlying causes of the sex bias in neurological disorders and assist development of new treatments for these diseases. Sexual differentiation in mice is determined by the two sex chromosomes: embryos receiving two X chromosomes become females and those with one X and one Y chromosome develop as males. The Sry gene in the sex determining region of the Y chromosome encodes a transcription factor expressed in male undifferentiated gonads to induce testicular development [9]. The rises in circulating T during the late gestation and immediately after birth are essential for masculinization and/or defeminization of certain behaviors and their underlying neural circuits (organizational effect) [10,13]
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