Abstract
Proper development of the mammalian cerebral cortex relies on precise gene expression regulation, which is controlled by genetic, epigenetic, and epitranscriptomic factors. Here we generate RNA demethylase Fto and methyltransferase Mettl3 cortical-specific conditional knockout mice, and detect severe brain defects caused by Mettl3 deletion but not Fto knockout. Transcriptomic profiles using RNA sequencing indicate that knockout of Mettl3 causes a more dramatic alteration on gene transcription than that of Fto. Interestingly, we conduct ribosome profiling sequencing, and find that knockout of Mettl3 leads to a more severe disruption of translational regulation of mRNAs than deletion of Fto and results in altered translation of crucial genes in cortical radial glial cells and intermediate progenitors. Moreover, Mettl3 deletion causes elevated translation of a significant number of mRNAs, in particular major components in m6A methylation. Our findings indicate distinct functions of Mettl3 and Fto in brain development, and uncover a profound role of Mettl3 in regulating translation of major mRNAs that control proper cortical development.
Highlights
The mammalian cerebral cortex plays a central role in controlling a range of behaviors such as perception, movement, cognition, memory, and emotion [1,2,3,4]
We demonstrate that Mettl3 plays a more profound role in cortical development than Fto does using mouse genetic tools
We show that knockout of Mettl3 has a more severe impact on gene transcriptional and translational regulation of mRNAs based on RNA sequencing (RNA-seq) and Ribo-seq analyses
Summary
The mammalian cerebral cortex plays a central role in controlling a range of behaviors such as perception, movement, cognition, memory, and emotion [1,2,3,4]. Neural progenitors reside in the ventricular zone (VZ) and subventricular zone (SVZ) proliferate and give rise to projection neurons, which migrate to the cortical plate (CP) and form six layers structure [7,8,9,10,11,12]. Altered production of neural progenitors and newborn neurons is associated with brain malformations and dysfunctions [13]. Numerous studies have demonstrated crucial roles of genetic and epigenetic factors in regulating proper cortical development [14,15,16,17,18]. Epitranscriptomic regulation in brain development and function has drawn attention, in particular N6-methyladenosine (m6A) modification [19,20,21]
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