WT1 is essential for normal kidney development, and genetic alterations are associated with Wilms' tumor, Denys Drash (DDS), and Frasier syndromes. Although generally considered a transcription factor this study has revealed that WT1 interacts with an essential splicing factor, U2AF65, and associates with the splicing machinery. WT1 is alternatively spliced and isoforms that include three amino acids, KTS, show stronger interaction with U2AF65 in vitro and better colocalization with splicing factors in vivo. Interestingly a mutation associated with DDS enhanced both −KTS WT1 binding to U2AF65 and splicing-factor colocalization. These data illustrate the functional importance of WT1 isoforms and suggest that WT1 plays a role in pre-mRNA splicing.
Adenosine deaminase that acts on RNA, ADAR, catalyzes the conversion of adenosine into inosine within double-stranded RNA. This type of editing has mainly been found in genes involved in neurotransmission. Site-specific A to I modifications often require intronic sequences to create the double-stranded structure necessary for editing. A system was developed to investigate if editing and splicing of pre-mRNA are coordinated. We have focused on a selectively edited site (R/G) in the glutamate receptor subunit B pre-mRNA. This editing site is situated in close proximity to a 5 splice site. To ensure efficient splicing, the editing site, together with its natural 5 splice site, was fused to a 3 splice site of the major late transcript from adenovirus. In vitro, on a premade transcript, ADAR2 editing and splicing were found to interfere with each other. The stable stem-loop required for ADAR2 editing had a negative effect on in vitro splicing, possibly by sequestering the 5 splice site. Further, RNA helicase A was shown to overcome the splicing inhibition caused by ADAR2. In vivo, allowing cotranscriptional processing, the same construct was found to efficiently edit and splice without interference, suggesting that the two RNA processing events are coordinated.
The C-terminal domain (CTD) of the large subunit of RNA polymerase II (Pol II) influences many steps in the synthesis of an mRNA and helps control the final destiny of the mature transcript. ADAR2 edits RNA by converting adenosine to inosine within double-stranded or structured RNA. Site-selective A-to-I editing often occurs at sites near exon/intron borders, where it depends on intronic sequences for substrate recognition. It is therefore essential that editing precedes splicing. We have investigated whether there is coordination between ADAR2 editing and splicing of the GluR-B pre-mRNA. We show that the CTD is required for efficient editing at the R/G site one base upstream of a 59-splice site. The results suggest that the CTD enhances editing at the R/G site by preventing premature splicing that would remove the intronic recognition sites for ADAR2. Editing at the GluR-B Q/R site, 24 bases upstream of the intron 11 59-splice site, stimulates splicing at this intron. Furthermore, unlike previously studied introns, the CTD actually inhibits excision of intron 11, which includes the complementary recognition sequences for the Q/R editing site. In summary, these results show that the CTD and ADAR2 function together to enforce the order of events that allows editing to precede splicing, and they furthermore suggest a new role for the CTD as a coordinator of two interdependent pre-mRNA processing events.
Evolutionary comparisons frequently pinpoint crucial parts of a protein but, even within coding regions, nucleotides can do more than determine amino acid sequence. One highly conserved feature of the Wilms' tumour suppressor gene, WT1, is the potential, following alternative pre-mRNA splicing, to insert three amino acids (KTS) between the third and fourth zinc fingers. The nucleotides at this position simultaneously define amino acids and the alternative splice site. At the protein level this insertion influences DNA binding affinity and specificity, protein-protein interactions and subnuclear localization. Mutations within the +/-KTS splice junction lead to severe urogenital developmental abnormalities such as Frasier syndrome, indicating that the isoform ratio is critical for wild-type function. Using a series of site-directed mutations in both the genomic and cDNA context, the nucleotide-amino acid relationship was investigated. Mutational analysis within the cDNA suggests that the precise amino acids inserted may not be critical, but rather the disruption of the zinc finger structure alone may be sufficient to generate proteins with different in vitro properties. However, analysis within the genomic context suggests that the precise structure of the splice junction is crucial in retaining the balance between the isoforms, and this may account for the high nucleo-tide conservation of this unusual gene structure from fish to mammals.
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