Abstract
Several X-linked genes are involved in neuronal differentiation and may contribute to the generation of sex dimorphisms in the brain. Previous results showed that XX hypothalamic neurons grow faster, have longer axons, and exhibit higher expression of the neuritogenic gene neurogenin 3 (Ngn3) than XY before perinatal masculinization. Here we evaluated the participation of candidate X-linked genes in the development of these sex differences, focusing mainly on Kdm6a, a gene encoding for an H3K27 demethylase with functions controlling gene expression genome-wide. We established hypothalamic neuronal cultures from wild-type or transgenic Four Core Genotypes mice, a model that allows evaluating the effect of sex chromosomes independently of gonadal type. X-linked genes Kdm6a, Eif2s3x and Ddx3x showed higher expression in XX compared to XY neurons, regardless of gonadal sex. Moreover, Kdm6a expression pattern with higher mRNA levels in XX than XY did not change with age at E14, P0, and P60 in hypothalamus or under 17β-estradiol treatment in culture. Kdm6a pharmacological blockade by GSK-J4 reduced axonal length only in female neurons and decreased the expression of neuritogenic genes Neurod1, Neurod2 and Cdk5r1 in both sexes equally, while a sex-specific effect was observed in Ngn3. Finally, Kdm6a downregulation using siRNA reduced axonal length and Ngn3 expression only in female neurons, abolishing the sex differences observed in control conditions. Altogether, these results point to Kdm6a as a key mediator of the higher axogenesis and Ngn3 expression observed in XX neurons before the critical period of brain masculinization.
Highlights
The brain is a sexually dimorphic organ, along with many other organs and tissues besides the gonads
Two-way analysis of variance (ANOVA) revealed no effect of gonadal sex, but a significant main effect of sex chromosome complement in Kdm6a, Ddx3x and Eif2s3x, presenting these genes significantly higher expression levels in hypothalamic neurons carrying the XX chromosome complement compared to those carrying the XY, regardless of the gonadal sex of the donor embryos (XX > XY; Kdm6a: F(1, 18) = 6. 58, p = 0.0194; Ddx3x: F(1,19) = 14.14, p = 0.0013; Eif2s3x: F(1,17) = 5.79, p = 0.0278)
Given the results that suggest a participation of Kdm6 enzymes in the sexually dimorphic regulation of axogenesis and neurogenin 3 (Ngn3) expression in hypothalamic neurons, and that treatment with GSK-J4 inhibits the activity of both Kdm6a and Kdm6 subfamily are lysine demethylase 6b (Kdm6b), being impossible by this methodological approach to discern the individual contribution of each demethylase, we proceeded to the specific knockdown of Kdm6a transcripts using Small interfering RNA (siRNA) designed to downregulate the expression of this gene without affecting Kdm6b or Uty
Summary
The brain is a sexually dimorphic organ, along with many other organs and tissues besides the gonads. Two major factors are currently known to contribute to the setting of sexual dimorphisms in the brain during development: (1) a sex-specific trophic environment due to differences in gonadal hormones secretion and (2) a distinct genetic and epigenetic pattern for males and females generated by differences in the expression of X and Y chromosomes-linked genes [3,4,5]. X-linked genes are present in both sexes, the existence of two X in every cell of females and only one in males generates a "dosage difference" in the copy number of virtually all of these genes between the sexes This imbalance is compensated during development by the X chromosome inactivation mechanism (XCI), which involves the transcriptional silencing of one of the two Xs in each cell of an XX embryo, defining an inactive (Xi) and an active (Xa) X chromosome that will be inherited through the successive mitotic divisions to all the cells that shape that individual [8,9,10,11]. XCI does not lead to complete repression of all genes in the Xi, but some "escape" inactivation and are expressed from both Xa and Xi [12,13,14,15]
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