Abstract
Background Emx2 encodes for a transcription factor expressed in the embryonic intermediate mesoderm and central nervous system (CNS). It is implicated in several aspects of cerebral cortex development, including morphogenetic field specification, arealization, precursor proliferation and lamination. Four Emx2-associated antisense transcripts have been found in the urogenital system; one of them, Emx2OS, has been also detected in the adult brain. Until now, however, nothing is known about expression and function of Emx2OS in the developing CNS.Methodology/Principal FindingsBy quantitative RT-PCR and in situ hybridization, we reconstructed the Emx2OS expression profile in the embryonic CNS, paying special attention to the developing cerebral cortex. Emx2OS was observed in a number of CNS structures expressing also Emx2. Within the cortex, Emx2OS was detectable in periventricular precursors, expressing the sense transcript, and peaked in newly born post-mitotic neurons not expressing such transcript. By integrating lentiviral gene delivery, RNAi, TetON technology, morpholino-mediated gene knock-down, drug-induced perturbation of gene expression, and quantitative RT-PCR, we addressed possible roles of Ex2 antisense RNA in Emx2 regulation, in primary CNS precursor cultures. We found that, in both cortical precursors and their neuronal progenies, Emx2 antisense RNA contributes to post-transcriptional down-regulation of its sense partner, possibly by a Dicer-promoted mechanism. The same RNA, when delivered to rhombo-spinal precursors, stimulates ectopic expression of Emx2, whereas Emx2 knock-out dramatically impairs Emx2OS transcription. This suggests that, within the developing CNS, a reciprocal Emx2/Emx2OS regulatory loop may normally sustain transcription at the Emx2 locus.Conclusions/SignificanceThis study shows that antisense transcripts may contribute to developmental regulation of a key transcription factor gene implicated in CNS patterning, possibly by complex and multilevel mechanisms. The activation of Emx2 by a short antisense transcript may be a prototype of a method for overexpressing single specific genes, without introducing additional copies of them into the genome.
Highlights
Emx2 is a transcription factor gene expressed in the developing urogenital and central nervous systems (CNS) [1,3], crucial for proper morphogenesis of these structures [4,6]
Conclusions/Significance: This study shows that antisense transcripts may contribute to developmental regulation of a key transcription factor gene implicated in CNS patterning, possibly by complex and multilevel mechanisms
We investigated the expression pattern of Emx2OSncRNA in the developing CNS, by quantitative reverse transcription polymerase chain reaction and in situ hybridisation (ISH)
Summary
Emx is a transcription factor gene expressed in the developing urogenital and central nervous systems (CNS) [1,3], crucial for proper morphogenesis of these structures [4,6]. It is implicated in dorso-ventral specification of the rostral neural tube, conferring cortico-cerebral identity to precursors in the dorsal telencephalic vesicle and repressing the activation of striatal morphogenetic programs [7]. Emx encodes for a transcription factor expressed in the embryonic intermediate mesoderm and central nervous system (CNS) It is implicated in several aspects of cerebral cortex development, including morphogenetic field specification, arealization, precursor proliferation and lamination. Until now nothing is known about expression and function of Emx2OS in the developing CNS
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