Abstract
Hypothalamic neurons show sex differences in neuritogenesis, female neurons have longer axons and higher levels of the neuritogenic factor neurogenin 3 (Ngn3) than male neurons in vitro. Moreover, the effect of 17-β-estradiol (E2) on axonal growth and Ngn3 expression is only found in male-derived neurons. To investigate whether sex chromosomes regulate these early sex differences in neuritogenesis by regulating the E2 effect on Ngn3, we evaluated the growth and differentiation of hypothalamic neurons derived from the “four core genotypes” mouse model, in which the factors of “gonadal sex” and “sex chromosome complement” are dissociated. We showed that sex differences in neurite outgrowth are determined by sex chromosome complement (XX > XY). Moreover, E2 increased the mRNA expression of Ngn3 and axonal length only in XY neurons. ERα/β expressions are regulated by sex chromosome complement; however, E2-effect on Ngn3 expression in XY neurons was only fully reproduced by PPT, a specific ligand of ERα, and prevented by MPP, a specific antagonist of ERα. Together our data indicate that sex chromosomes regulate early development of hypothalamic neurons by orchestrating not only sex differences in neuritogenesis, but also regulating the effect of E2 on Ngn3 expression through activation of ERα in hypothalamic neurons.
Highlights
Hypothalamic neurons show sex differences in neuritogenesis, female neurons have longer axons and higher levels of the neuritogenic factor neurogenin 3 (Ngn3) than male neurons in vitro
Our previous results indicate that male and female hypothalamic neurons from CD1 mouse cultures present morphologic sex differences in neurite outgrowth starting at 2 days in vitro (DIV) and these sex differences are maintained through 7 DIV12
In order to evaluate the direct role of sex chromosome complement in the described sex differences in neuronal maturation, we analyzed different morphological parameters of cellular shape and Ngn[3] expression in hypothalamic neurons of XY female (XYF) and XX female (XXF) cultures of MF1 mice after 2 DIV (Fig. 2)
Summary
Hypothalamic neurons show sex differences in neuritogenesis, female neurons have longer axons and higher levels of the neuritogenic factor neurogenin 3 (Ngn3) than male neurons in vitro. Using the FCG model, the early developmental effect of sex chromosome complement on sex differences in the brain has been demonstrated in the number of mesencephalic neurons immunoreactive for tyrosine hydroxylase[9], as well as in the expression of the enzyme aromatase in the anterior amygdala[10,11] and the neuritogenic factor neurogenin 3 (Ngn3) in hypothalamic neurons[12]. These sex differences were found in primary neuronal cultures or tissue obtained from FCG mice of embryonic age (E) 14–16 meaning that they cannot be attributed to the prenatal peak in gonadal testosterone occurring at E17–1813,14. We tested the hypothesis that sex chromosomes regulate early sex differences in neuritogenesis by regulating the E2 effect on Ngn[3]
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