Abstract
Early brain development requires a tight orchestration between neural tube patterning and growth. How pattern formation and brain growth are coordinated is incompletely understood. Previously we showed that aristaless-related homeobox (ARX), a paired-like transcription factor, regulates cortical progenitor pool expansion by repressing an inhibitor of cell cycle progression. Here we show that ARX participates in establishing dorsoventral identity in the mouse forebrain. In Arx mutant mice, ventral genes, including Olig2, are ectopically expressed dorsally. Furthermore, Gli1 is upregulated, suggesting an ectopic activation of SHH signaling. We show that the ectopic Olig2 expression can be repressed by blocking SHH signaling, implicating a role for SHH signaling in Olig2 induction. We further demonstrate that the ectopic Olig2 accounts for the reduced Pax6 and Tbr2 expression, both dorsal specific genes essential for cortical progenitor cell proliferation. These data suggest a link between the control of dorsoventral identity of progenitor cells and the control of their proliferation. In summary, our data demonstrate that ARX functions in a gene regulatory network integrating normal forebrain patterning and growth, providing important insight into how mutations in ARX can disrupt multiple aspects of brain development and thus generate a wide spectrum of neurodevelopmental phenotypes observed in human patients.
Highlights
aristaless-related homeobox (ARX) is a vertebrate homologue of Drosophila aristaless (Al), a paired-like homeodomain transcription factor (TF)
We propose that ARX coordinates telencephalic patterning and forebrain size by regulating DV gene expression, including the suppression of dorsal Olig[2], which modulates the expression of genes including Pax[6] and Tbr[2], influencing forebrain patterning and growth
We compared OLIG2 immunostaining from wild type (WT) (Arx+/y; Emx1cre, referred to as Arx+/y) and Arx cKO (Arxflox/y; Emx1cre, referred to as ArxcKO/y) embryonic brain sections
Summary
ARX is a vertebrate homologue of Drosophila aristaless (Al), a paired-like homeodomain transcription factor (TF). Patients with mutations in ARX present with intellectual disability and epilepsy, with or without structural defects in the brain such as lissencephaly (smooth brain), microcephaly (small brain), and agenesis of the corpus callosum, as well as abnormal genitalia[13,14,15]. Progenitor cells deficient for Arx prematurely exit the cell cycle, resulting in depletion of the proliferating progenitor cell pool and a reduction in upper layer neurons[17] This has been postulated as the mechanism for the reduced brain size (microcephaly) reported in mice as well as in patients[14,15,16,17,18,19,20]. We propose that ARX coordinates telencephalic patterning and forebrain size by regulating DV gene expression, including the suppression of dorsal Olig[2], which modulates the expression of genes including Pax[6] and Tbr[2], influencing forebrain patterning and growth
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