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W2020345691 abstract "Point mutations in intronic regions near mRNA splice junctions can affect the splicing process. To identify novel splicing variants from exome sequencing data, we developed a bioinformatics splice-site prediction procedure to analyze next-generation sequencing (NGS) data (SpliceFinder). SpliceFinder integrates two functional annotation tools for NGS, ANNOVAR and MutationTaster and two canonical splice site prediction programs for single mutation analysis, SSPNN and NetGene2. By SpliceFinder, we identified somatic mutations affecting RNA splicing in a colon cancer sample, in eight atypical chronic myeloid leukemia (aCML), and eight CML patients. A novel homozygous splicing mutation was found in APC (NM_000038.4:c.1312+5G>A) and six heterozygous in GNAQ (NM_002072.2:c.735+1C>T), ABCC 3 (NM_003786.3:c.1783-1G>A), KLHDC 1 (NM_172193.1:c.568-2A>G), HOOK 1 (NM_015888.4:c.1662-1G>A), SMAD 9 (NM_001127217.2:c.1004-1C>T), and DNAH 9 (NM_001372.3:c.10242+5G>A). Integrating whole-exome and RNA sequencing in aCML and CML, we assessed the phenotypic effect of mutations on mRNA splicing for GNAQ, ABCC 3, HOOK 1. In ABCC 3 and HOOK 1, RNA-Seq showed the presence of aberrant transcripts with activation of a cryptic splice site or intron retention, validated by the reverse transcription-polymerase chain reaction (RT-PCR) in the case of HOOK 1. In GNAQ, RNA-Seq showed 22% of wild-type transcript and 78% of mRNA skipping exon 5, resulting in a 4-6 frameshift fusion confirmed by RT-PCR. The pipeline can be useful to identify intronic variants affecting RNA sequence by complementing conventional exome analysis." @default.
W2020345691 created "2016-06-24" @default.
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W2020345691 date "2013-07-07" @default.
W2020345691 modified "2023-10-14" @default.
W2020345691 title "Identification of novel point mutations in splicing sites integrating whole‐exome and <scp>RNA</scp> ‐seq data in myeloproliferative diseases" @default.
W2020345691 cites W1530850449 @default.
W2020345691 cites W1583240815 @default.
W2020345691 cites W1927136327 @default.
W2020345691 cites W1975922601 @default.
W2020345691 cites W1975993620 @default.
W2020345691 cites W1979263210 @default.
W2020345691 cites W1980740976 @default.
W2020345691 cites W1983954245 @default.
W2020345691 cites W1984068087 @default.
W2020345691 cites W1987390002 @default.
W2020345691 cites W1998430163 @default.
W2020345691 cites W2010650881 @default.
W2020345691 cites W2013639985 @default.
W2020345691 cites W2013743651 @default.
W2020345691 cites W2014181394 @default.
W2020345691 cites W2018855021 @default.
W2020345691 cites W2021341670 @default.
W2020345691 cites W2024373518 @default.
W2020345691 cites W2029154060 @default.
W2020345691 cites W2029623390 @default.
W2020345691 cites W2032026767 @default.
W2020345691 cites W2039094079 @default.
W2020345691 cites W2043292259 @default.
W2020345691 cites W2052297191 @default.
W2020345691 cites W2053520756 @default.
W2020345691 cites W2055770801 @default.
W2020345691 cites W2058043554 @default.
W2020345691 cites W2059145105 @default.
W2020345691 cites W2059300459 @default.
W2020345691 cites W2067302115 @default.
W2020345691 cites W2072445382 @default.
W2020345691 cites W2075893547 @default.
W2020345691 cites W2076357933 @default.
W2020345691 cites W2087588809 @default.
W2020345691 cites W2088580309 @default.
W2020345691 cites W2092741708 @default.
W2020345691 cites W2097065948 @default.
W2020345691 cites W2098824600 @default.
W2020345691 cites W2099377894 @default.
W2020345691 cites W2103441770 @default.
W2020345691 cites W2107398329 @default.
W2020345691 cites W2108234281 @default.
W2020345691 cites W2109372707 @default.
W2020345691 cites W2114007327 @default.
W2020345691 cites W2114289944 @default.
W2020345691 cites W2117112774 @default.
W2020345691 cites W2123179956 @default.
W2020345691 cites W2124985265 @default.
W2020345691 cites W2127471603 @default.
W2020345691 cites W2136482257 @default.
W2020345691 cites W2138122783 @default.
W2020345691 cites W2138601221 @default.
W2020345691 cites W2140929811 @default.
W2020345691 cites W2141458291 @default.
W2020345691 cites W2144759168 @default.
W2020345691 cites W2144885757 @default.
W2020345691 cites W2144892629 @default.
W2020345691 cites W2145070407 @default.
W2020345691 cites W2145187337 @default.
W2020345691 cites W2151794156 @default.
W2020345691 cites W2152509863 @default.
W2020345691 cites W2154431984 @default.
W2020345691 cites W2155058144 @default.
W2020345691 cites W2155943701 @default.
W2020345691 cites W2158463967 @default.
W2020345691 cites W2161106528 @default.
W2020345691 cites W2161645441 @default.
W2020345691 cites W2163235555 @default.
W2020345691 cites W2171080110 @default.
W2020345691 cites W4247292500 @default.
W2020345691 doi "https://doi.org/10.1002/mgg3.23" @default.
W2020345691 hasPubMedCentralId "https://www.ncbi.nlm.nih.gov/pmc/articles/3960063" @default.
W2020345691 hasPubMedId "https://pubmed.ncbi.nlm.nih.gov/24498620" @default.
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