Project description:Neuronal alternative splicing is dynamically regulated in a spatiotemporal fashion. We previously found that STAR family proteins (SAM68, SLM1, SLM2) regulate spatiotemporal alternative splicing in the nervous system. However, the whole aspect of alternative splicing programs governed by STARs remains unclear. We deciphered the alternative splicing programs of SAM68 and SLM1 proteins using transcriptomics. We reveal that SAM68 and SLM1 encode distinct alternative splicing programs; SAM68 preferentially controls alternative last exon (ALE) splicing. Interleukin 1-receptor accessory protein (Il1rap) is a novel target for SAM68. The usage of Il1rap ALEs results in mainly two variants encoding two functionally different isoforms, a membrane-bound (mIL1RAcP) and a soluble (sIL1RAcP) type. The brain exclusively expresses mIL1RAcP. SAM68 knockout results in remarkable conversion into sIL1RAcP in the brain, which significantly disturbs IL1RAcP neuronal function. Thus, we uncover the critical role of proper neuronal isoform selection through ALE choice by the SAM68-specific splicing program.

Project description:We uncover a Sam68-dependent splicing program during cerebellar development. These events direct proper isoform expression of the genes required to guarantee the establishment of the correct spatial/temporal neural circuitry. The dysregulation in Sam68 null mice leads to functional defects in adult neurons

Project description:The paralog RNA binding proteins (RBPs) Sam68 and SLM2 are co-expressed in the cerebral cortex and display very similar splicing activity. However, their relative function(s) in this context is unknown. By performing a time-course analysis, we found that these RBPs exhibit an opposite expression pattern during development. Sam68 expression declines postnatally while SLM2 increases after birth, and this developmental pattern is reinforced by hierarchical control of Sam68 expression by SLM2. Analysis of Sam68:Slm2 double knockout (Sam68:Slm2dko) mice revealed hundreds of exons that are sensitive to concomitant ablation of these proteins. Moreover, parallel analysis of single and double knockout cortices indicated that exons regulated mainly by SLM2 are characterized by a dynamic splicing pattern during development, whereas Sam68-dependent exons are spliced at relatively constant rates. Dynamic splicing of SLM2-sensitive exons is completely suppressed in the Sam68:Slm2dko developing cortex. Sam68:Slm2dko mice die perinatally with defects in neurogenesis and in neuronal differentiation, and the development of a hydrocephalus, consistent with splicing alterations in genes related to these biological processes. Thus, our study reveals that maintenance of the Sam68 and Slm2 paralog genes encoding homologous RBPs enables the orchestration of a dynamic splicing program while ensuring a robust redundant mechanism that supports proper cortical development.

Project description:Cell type-specific alternative splicing during mammalian neuronal differentiation

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Project description:The splicing regulator Rbfox1 (A2BP1) controls neuronal excitation in the mammalian brain

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