Abstract
Alternative splicing is crucial for molecular diversification, which greatly contributes to the complexity and specificity of neural functions in the central nervous system (CNS). Neurofascin (NF) is a polymorphic cell surface protein that has a number of splicing isoforms. As the alternative splicing of the neurofascin gene (Nfasc) is developmentally regulated, NF isoforms have distinct functions in immature and mature brains. However, the molecular mechanisms underlying the alternative splicing of Nfasc in neurons are not yet understood. Here, we demonstrate that, alongside developmental regulation, Nfasc alternative splicing is spatially controlled in the mouse brain. We then identified distinct Nfasc splicing patterns at the cell-type level in the cerebellum, with Nfasc186 being expressed in Purkinje cells and absent from granule cells (GCs). Furthermore, we show that high K+-induced depolarization triggers a shift in splicing from Nfasc140 to Nfasc186 in cerebellar GCs. Finally, we identified a neural RNA-binding protein, Rbfox, as a key player in neural NF isoform selection, specifically controlling splicing at exons 26−29. Together, our results show that Nfasc alternative splicing is spatio-temporally and dynamically regulated in cerebellar neurons. Our findings provide profound insight into the mechanisms underlying the functional diversity of neuronal cell-adhesive proteins in the mammalian CNS.
Highlights
Alternative pre-mRNA splicing is a fundamental mechanism that generates molecular diversity from a single gene, and is thought to be essential for biological complexity and diversity
The PAT domain is included in the neural isoforms NF186 and NF180, with NF186 further including a fifth FNIII domain (FN5)
We noticed that hindbrain areas, such as the cerebellum and brainstem, displayed higher levels of the lower molecular weight protein (i.e., NF140) (Fig. 1b), which has been reported to be expressed in developing brains[11]
Summary
Alternative pre-mRNA splicing is a fundamental mechanism that generates molecular diversity from a single gene, and is thought to be essential for biological complexity and diversity The regulation of this splicing is highly dynamic and complex in the vertebrate central nervous system (CNS)[1, 2]. The other neural isoforms, NF140 and NF180, are embryonic protein variants that regulate neurite outgrowth In accordance with their distinct function, the embryonic isoforms are largely converted to the adult NF186 isoform during neural development and differentiation. This process occurs through the inclusion of four tandem exons (i.e., exons 26, 27, 28, and 29; ex26-29) which encode the fifth FNIII domain and the PAT domain[8]. The detailed molecular mechanisms underlying the alternative splicing of Nfasc are unknown
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