TY - JOUR
T1 - Multifactorial interplay controls the splicing profile of Alu-derived exons
AU - Ram, Oren
AU - Schwartz, Schraga
AU - Ast, Gil
N1 - Funding Information:
Acknowledgments The research of MC has been support by 200930I053 MICINN-CSIC Grant and by CGL2012-37222 Grant from MINECO. PGdS work has funded by grant CGL2007-66440-C04-01 from MICINN.
PY - 2008/5
Y1 - 2008/5
N2 - Exonization of Alu elements creates primate-specific genomic diversity. Here we combine bioinformatic and experimental methodologies to reconstruct the molecular changes leading to exon selection. Our analyses revealed an intricate network involved in Alu exonization. A typical Alu element contains multiple sites with the potential to serve as 5′ splice sites (5′ss). First, we demonstrated the role of 5′ss strength in controlling exonization events. Second, we found that a cryptic 5′ss enhances the selection of a more upstream site and demonstrate that this is mediated by binding of U1 snRNA to the cryptic splice site, challenging the traditional role attributed to U1 snRNA of binding the 5′ss only. Third, we used a simple algorithm to identify specific sequences that determine splice site selection within specific Alu exons. Finally, by inserting identical exons within different sequences, we demonstrated the importance of flanking genomic sequences in determining whether an Alu exon will undergo exonization. Overall, our results demonstrate the complex interplay between at least four interacting layers that affect Alu exonization. These results shed light on the mechanism through which Alu elements enrich the primate transcriptome and allow a better understanding of the exonization process in general.
AB - Exonization of Alu elements creates primate-specific genomic diversity. Here we combine bioinformatic and experimental methodologies to reconstruct the molecular changes leading to exon selection. Our analyses revealed an intricate network involved in Alu exonization. A typical Alu element contains multiple sites with the potential to serve as 5′ splice sites (5′ss). First, we demonstrated the role of 5′ss strength in controlling exonization events. Second, we found that a cryptic 5′ss enhances the selection of a more upstream site and demonstrate that this is mediated by binding of U1 snRNA to the cryptic splice site, challenging the traditional role attributed to U1 snRNA of binding the 5′ss only. Third, we used a simple algorithm to identify specific sequences that determine splice site selection within specific Alu exons. Finally, by inserting identical exons within different sequences, we demonstrated the importance of flanking genomic sequences in determining whether an Alu exon will undergo exonization. Overall, our results demonstrate the complex interplay between at least four interacting layers that affect Alu exonization. These results shed light on the mechanism through which Alu elements enrich the primate transcriptome and allow a better understanding of the exonization process in general.
UR - http://www.scopus.com/inward/record.url?scp=43249117483&partnerID=8YFLogxK
U2 - 10.1128/MCB.02279-07
DO - 10.1128/MCB.02279-07
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AN - SCOPUS:43249117483
SN - 0270-7306
VL - 28
SP - 3513
EP - 3525
JO - Molecular and Cellular Biology
JF - Molecular and Cellular Biology
IS - 10
ER -