Fox-1 family of RNA-binding proteins

The Fox-1 family of RNA-binding proteins are evolutionarily conserved regulators of tissue-specific alternative splicing in metazoans. The Fox-1 family specifically recognizes the (U)GCAUG stretch in regulated exons or in flanking introns, and either promotes or represses target exons. Recent unbiased bioinformatics analyses of alternatively spliced exons and comparison of various vertebrate genomes identified the (U)GCAUG stretch as a highly conserved and widely distributed element enriched in intronic regions surrounding exons with altered inclusion in muscle, heart, and brain, consistent with specific expression of Fox-1 and Fox-2 in these tissues. Global identification of Fox-2 target RNAs in living cells revealed that many of the Fox-2 target genes themselves encode splicing regulators. Further systematic elucidation of target genes of the Fox-1 family and other splicing regulators in various tissues will lead to a comprehensive understanding of splicing regulatory networks

Intronic CA-repeat and CA-rich elements: a new class of regulators of mammalian alternative splicing

We have recently identified an intronic polymorphic CA-repeat region in the human endothelial nitric oxide synthase (eNOS) gene as an important determinant of the splicing efficiency, requiring specific binding of hnRNP L. Here, we analyzed the position requirements of this CA-repeat element, which revealed its potential role in alternative splicing. In addition, we defined the RNA binding specificity of hnRNP L by SELEX: not only regular CA repeats are recognized with high affinity but also certain CA-rich clusters. Therefore, we have systematically searched the human genome databases for CA-repeat and CA-rich elements associated with alternative 5′ splice sites (5′ss), followed by minigene transfection assays. Surprisingly, in several specific human genes that we tested, intronic CA RNA elements could function either as splicing enhancers or silencers, depending on their proximity to the alternative 5′ss. HnRNP L was detected specifically bound to these diverse CA elements. These data demonstrated that intronic CA sequences constitute novel and widespread regulatory elements of alternative splicing

In NF1, CFTR, PER3, CARS and SYT7, alternatively included exons show higher conservation of surrounding intron sequences than constitutive exons

It is still not fully understood to what extent intronic sequences contribute to the regulation of the different forms of alternative splicing. We are interested in the regulation of alternative cassette exon events, such as exon inclusion and exon skipping. We investigated these events by comparative genomic analysis of human and mouse in five experimentally well-characterized genes, neurofibromatosis 1 (NF1), cystic fibrosis transmembrane conductance regulator (CFTR), period 3 (PER3), cysteinyl-tRNA synthetase (CARS) and synaptotagmin 7 (SYT7). In NF1, high intron identity around the 52 constitutive and four alternatively skipped NF1 exons is restricted to the close vicinity of the exons. In contrast, we found on average high conservation of intron sequences over 300 base pairs up- and downstream of the five alternatively included NF1 exons. The investigation of alternatively included exons in CFTR, PER3, CARS and SYT7 supported this finding. In contrast, the mean intron identities around the alternatively skipped exons in CTFR and NF1 do not differ considerably from those around the constitutive exons. In these genes, the difference in intron conservation could point to a difference between the regulation of alternative exon inclusion and alternative exon skipping or constitutive exon splicing. Additional genome-wide investigations are necessary to elucidate to what extent our finding can be generalized

Differential effects of PKA-controlled CaMKK2 variants on neuronal differentiation

Regulation between protein kinases is critical for the establishment of signaling pathways/networks to orchestrate cellular processes. Besides posttranslational phosphorylation, alternative pre-mRNA splicing is another way to control kinase properties, but splicing regulation between two kinases and the effect of resulting variants on cells have not been explored. We examined the effect of the protein kinase A (PKA) pathway on the alternative splicing and variant properties of the Ca++/calmodulin-dependent protein kinase kinase 2 (CaMKK2) gene in B35 neuroblastoma cells. Inclusion of the exon 16 of CaMKK2 was significantly reduced by H89, a PKA selective inhibitor. Consistently, overexpressed PKA strongly promoted the exon inclusion in a CaMKK2 sequence-dependent way in splicing reporter assays. In vitro, purified CaMKK2 variant proteins were kinase-active. In cells, they were differentially phosphorylated by PKA. In RNA interference assays, CaMKK2 was required for forskolin-induced neurite growth. Interestingly, overexpression of the variant without exon 16 (−E16) promoted neurite elongation while the other one (+E16) promoted neurite branching; in contrast, reduction of the latter variant enhanced neurite elongation. Moreover, the variants are differentially expressed and the exon 16-containing transcripts highly enriched in the brain, particularly the cerebellum and hippocampus. Thus, PKA regulates the alternative splicing of CaMKK2 to produce variants that differentially modulate neuronal differentiation. Taken together with the many distinct variants of kinases, alternative splicing regulation likely adds another layer of modulation between protein kinases in cellular signaling networks