Abstract
Deleted in Azoospermia Associated Protein 1 (DAZAP1) is a ubiquitous heterogeneous nuclear ribonucleoprotein (hnRNP) that is expressed abundantly in the testis. DAZAP1 deficiency in mice results in growth retardation and spermatogenic arrest. Previous reports on DAZAP1’s binding to several naturally occurring splicing mutations support a role for DAZAP1 in RNA splicing. To elucidate the biological function(s) of DAZAP1 and to search for its natural RNA substrates, we used microarrays to compare the expression profiles and exon usages of wild-type and Dazap1 mutant testes and identified three genes (Crem, Crisp2 and Pot1a) with aberrant RNA splicing in the mutant testes. We further demonstrated that DAZAP1, but not DAZAP1 mutant proteins, promoted the inclusion of Crem exon 4, Crisp2 exon 9 and Pot1a exon 4 in splicing reporter transcripts in cultured cells. Additional studies on the binding of DAZAP1 to the exons and their flanking intronic sequences and the effects of minigene deletions on exon inclusion identified regulatory regions in Crem intron 3, Crisp2 intron 9 and Pot1a intron 4 where DAZAP1 bound and regulated splicing. Aberrant splicing of the Pot1a gene, which encodes an essential protein that protects telomere integrity, may partially account for the growth retardation phenotype of DAZAP1-deficient mice.
Highlights
Most eukaryotic genes contain introns that are spliced out soon after they are transcribed
We searched for the natural substrates of Deleted in Azoospermia Associated Protein 1 (DAZAP1) using microarray approaches and identified only three genes of which the splicing is regulated by DAZAP1
These genes likely represent only a small fraction of genes regulated by DAZAP1
Summary
Most eukaryotic genes contain introns that are spliced out soon after they are transcribed. RNA splicing is catalysed by the spliceosome, which consists of five small nuclear ribonucleoprotein particles (snRNPs) and a host of RNAbinding proteins that participate in and regulate the event [1]. Based on the location and the effect, these elements are categorized as exonic splicing enhancers (ESEs), exonic splicing silencers (ESSs), intronic splicing enhancers (ISEs) and intronic splicing silencers (ISSs) They are recognized by trans-acting RNA-binding proteins that regulate either or both constitutive and alternative splicing events to determine the inclusion/exclusion of a particular exon. RNA splicing is regulated by a host of RNA-binding proteins, some of which are expressed constitutively in all cells whereas others are expressed in tissue or developmental specific manners Such differential expression of splicing regulatory factors is responsible for the alternative RNA splicing that has greatly increased the complexity of the transcriptome
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