Abstract
The RNA-binding protein RBFOX1 is an important regulator of neuron development and neuronal excitability. Rbfox1 is a dosage-sensitive gene and in both mice and humans, decreased expression of Rbfox1 has been linked to neurodevelopmental disorders. Alternative promoters drive expression of Rbfox1 transcript isoforms that encode an identical protein. The tissue- and developmental stage-specific expression of these isoforms, as well as the underlying regulatory mechanisms, are, however, unclear. Here, we set out to capture all of the Rbfox1 transcript isoforms and identify transcriptional mechanisms that regulate brain-specific Rbfox1 expression. Isoform sequencing identified multiple alternative Rbfox1 transcript variants in the mouse cerebral cortex, including transcripts with novel first exons, alternatively spliced exons and 3′-truncations. Quantitative RT-PCR determined the expression of the alternative first exons in the developing cerebral cortex and different subregions of the juvenile brain. Alternative first exons were found to be highly stage- and subregion specific in their expression patterns suggesting that they fulfill specific functions during cortex development and in different brain regions. Using reporter assays we found that the promoter regions of the two first exons E1B and E1C/E1C.1 contain several functional E-boxes. Together, we provide an extensive picture of Rbfox1 isoform expression. We further identified important regulatory mechanisms that drive neuron-specific Rbfox1 expression. Thus, our study forms the basis for further research into the mechanisms that ensure physiological Rbfox1 expression in the brain. It also helps to understand why, in patients with neurodevelopmental disorders deletion of individual RBFOX1 transcript isoforms could affect brain function.
Highlights
The RNA Binding Fox-1 Homolog 1 (Rbfox1) gene is one of the longest genes in the genome with its remarkable size being caused by an extended 5 -noncoding region containing several alternative 5 UTR exons, transcription of which is controlled by alternative promoter usage (Kuroyanagi, 2009; Damianov and Black, 2010; Conboy, 2017)
Heterozygous Copy number variations (CNVs) in the 5’-noncoding part of the RBFOX1 gene that typically only affect some but not all RBFOX1 transcript isoforms are associated with a range of neurodevelopmental disorders (Bhalla et al, 2004; Martin et al, 2007; Zhao, 2013)
We identified all Rbfox1 transcript variants detectable by Isoform sequencing (Iso-Seq) in the mouse cerebral cortex at P0, and characterized the alternative Rbfox1 promoters
Summary
The RNA Binding Fox-1 Homolog 1 (Rbfox1) gene is one of the longest genes in the genome with its remarkable size being caused by an extended 5 -noncoding region containing several alternative 5 UTR exons, transcription of which is controlled by alternative promoter usage (Kuroyanagi, 2009; Damianov and Black, 2010; Conboy, 2017). An important yet unanswered question is why so many alternative Rbfox transcripts exist that encode an identical protein. RBFOX1 shuttles between the nucleus and cytoplasm, an event which is regulated by alternative splicing of the exon A53. Splicing of exon A53 into the Rbfox mRNA causes cytoplasmic localization of RBFOX1 by introducing a frame-shift and an alternative C-terminus lacking the nuclear localization signal (NLS; Underwood et al, 2005; Lee et al, 2009). RBFOX proteins regulate alternative pre-mRNA splicing by binding the consensus sequence (U)GCAUG in introns flanking alternative exons. Cytoplasmic RBFOX1 influences gene expression, by binding the 3 -untranslated regions (3 UTRs) of its target genes (Dredge and Jensen, 2011; Lee et al, 2016; Rajman et al, 2017)
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