AG-dependent 3′-splice sites are predisposed to aberrant splicing due to a mutation at the first nucleotide of an exon

In pre-mRNA splicing, a conserved AG/G at the 3′-splice site is recognized by U2AF(35). A disease-causing mutation abrogating the G nucleotide at the first position of an exon (E(+1)) causes exon skipping in GH1, FECH and EYA1, but not in LPL or HEXA. Knockdown of U2AF(35) enhanced exon skipping in...

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Autores principales: Fu, Yuan, Masuda, Akio, Ito, Mikako, Shinmi, Jun, Ohno, Kinji
Formato: Texto
Lenguaje:English
Publicado: Oxford University Press 2011
Materias:
RNA
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC3105431/
https://www.ncbi.nlm.nih.gov/pubmed/21288883
http://dx.doi.org/10.1093/nar/gkr026
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author Fu, Yuan
Masuda, Akio
Ito, Mikako
Shinmi, Jun
Ohno, Kinji
author_facet Fu, Yuan
Masuda, Akio
Ito, Mikako
Shinmi, Jun
Ohno, Kinji
author_sort Fu, Yuan
collection PubMed
description In pre-mRNA splicing, a conserved AG/G at the 3′-splice site is recognized by U2AF(35). A disease-causing mutation abrogating the G nucleotide at the first position of an exon (E(+1)) causes exon skipping in GH1, FECH and EYA1, but not in LPL or HEXA. Knockdown of U2AF(35) enhanced exon skipping in GH1 and FECH. RNA-EMSA revealed that wild-type FECH requires U2AF(35) but wild-type LPL does not. A series of artificial mutations in the polypyrimidine tracts of GH1, FECH, EYA1, LPL and HEXA disclosed that a stretch of at least 10–15 pyrimidines is required to ensure normal splicing in the presence of a mutation at E(+1). Analysis of nine other disease-causing mutations at E(+1) detected five splicing mutations. Our studies suggest that a mutation at the AG-dependent 3′-splice site that requires U2AF(35) for spliceosome assembly causes exon skipping, whereas one at the AG-independent 3′-splice site that does not require U2AF(35) gives rise to normal splicing. The AG-dependence of the 3′-splice site that we analyzed in disease-causing mutations at E(+1) potentially helps identify yet unrecognized splicing mutations at E(+1).
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spelling pubmed-31054312011-06-01 AG-dependent 3′-splice sites are predisposed to aberrant splicing due to a mutation at the first nucleotide of an exon Fu, Yuan Masuda, Akio Ito, Mikako Shinmi, Jun Ohno, Kinji Nucleic Acids Res RNA In pre-mRNA splicing, a conserved AG/G at the 3′-splice site is recognized by U2AF(35). A disease-causing mutation abrogating the G nucleotide at the first position of an exon (E(+1)) causes exon skipping in GH1, FECH and EYA1, but not in LPL or HEXA. Knockdown of U2AF(35) enhanced exon skipping in GH1 and FECH. RNA-EMSA revealed that wild-type FECH requires U2AF(35) but wild-type LPL does not. A series of artificial mutations in the polypyrimidine tracts of GH1, FECH, EYA1, LPL and HEXA disclosed that a stretch of at least 10–15 pyrimidines is required to ensure normal splicing in the presence of a mutation at E(+1). Analysis of nine other disease-causing mutations at E(+1) detected five splicing mutations. Our studies suggest that a mutation at the AG-dependent 3′-splice site that requires U2AF(35) for spliceosome assembly causes exon skipping, whereas one at the AG-independent 3′-splice site that does not require U2AF(35) gives rise to normal splicing. The AG-dependence of the 3′-splice site that we analyzed in disease-causing mutations at E(+1) potentially helps identify yet unrecognized splicing mutations at E(+1). Oxford University Press 2011-05 2011-02-02 /pmc/articles/PMC3105431/ /pubmed/21288883 http://dx.doi.org/10.1093/nar/gkr026 Text en © The Author(s) 2011. Published by Oxford University Press. http://creativecommons.org/licenses/by-nc/2.5 This is an Open Access article distributed under the terms of the Creative Commons Attribution Non-Commercial License (http://creativecommons.org/licenses/by-nc/2.5), which permits unrestricted non-commercial use, distribution, and reproduction in any medium, provided the original work is properly cited.
spellingShingle RNA
Fu, Yuan
Masuda, Akio
Ito, Mikako
Shinmi, Jun
Ohno, Kinji
AG-dependent 3′-splice sites are predisposed to aberrant splicing due to a mutation at the first nucleotide of an exon
title AG-dependent 3′-splice sites are predisposed to aberrant splicing due to a mutation at the first nucleotide of an exon
title_full AG-dependent 3′-splice sites are predisposed to aberrant splicing due to a mutation at the first nucleotide of an exon
title_fullStr AG-dependent 3′-splice sites are predisposed to aberrant splicing due to a mutation at the first nucleotide of an exon
title_full_unstemmed AG-dependent 3′-splice sites are predisposed to aberrant splicing due to a mutation at the first nucleotide of an exon
title_short AG-dependent 3′-splice sites are predisposed to aberrant splicing due to a mutation at the first nucleotide of an exon
title_sort ag-dependent 3′-splice sites are predisposed to aberrant splicing due to a mutation at the first nucleotide of an exon
topic RNA
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC3105431/
https://www.ncbi.nlm.nih.gov/pubmed/21288883
http://dx.doi.org/10.1093/nar/gkr026
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AT masudaakio agdependent3splicesitesarepredisposedtoaberrantsplicingduetoamutationatthefirstnucleotideofanexon
AT itomikako agdependent3splicesitesarepredisposedtoaberrantsplicingduetoamutationatthefirstnucleotideofanexon
AT shinmijun agdependent3splicesitesarepredisposedtoaberrantsplicingduetoamutationatthefirstnucleotideofanexon
AT ohnokinji agdependent3splicesitesarepredisposedtoaberrantsplicingduetoamutationatthefirstnucleotideofanexon

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