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Structural analysis of the genome of breast cancer cell line ZR-75-30 identifies twelve expressed fusion genes
BACKGROUND: It has recently emerged that common epithelial cancers such as breast cancers have fusion genes like those in leukaemias. In a representative breast cancer cell line, ZR-75-30, we searched for fusion genes, by analysing genome rearrangements. RESULTS: We first analysed rearrangements of...
| Autores principales: | , , , , , , , , , , , , |
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| Formato: | Online Artículo Texto |
| Lenguaje: | English |
| Publicado: |
BioMed Central
2012
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| Acceso en línea: | https://www.ncbi.nlm.nih.gov/pmc/articles/PMC3548764/ https://www.ncbi.nlm.nih.gov/pubmed/23260012 http://dx.doi.org/10.1186/1471-2164-13-719 |
| _version_ | 1782256365414121472 |
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| author | Schulte, Ina Batty, Elizabeth M Pole, Jessica CM Blood, Katherine A Mo, Steven Cooke, Susanna L Ng, Charlotte Howe, Kevin L Chin, Suet-Feung Brenton, James D Caldas, Carlos Howarth, Karen D Edwards, Paul AW |
| author_facet | Schulte, Ina Batty, Elizabeth M Pole, Jessica CM Blood, Katherine A Mo, Steven Cooke, Susanna L Ng, Charlotte Howe, Kevin L Chin, Suet-Feung Brenton, James D Caldas, Carlos Howarth, Karen D Edwards, Paul AW |
| author_sort | Schulte, Ina |
| collection | PubMed |
| description | BACKGROUND: It has recently emerged that common epithelial cancers such as breast cancers have fusion genes like those in leukaemias. In a representative breast cancer cell line, ZR-75-30, we searched for fusion genes, by analysing genome rearrangements. RESULTS: We first analysed rearrangements of the ZR-75-30 genome, to around 10kb resolution, by molecular cytogenetic approaches, combining array painting and array CGH. We then compared this map with genomic junctions determined by paired-end sequencing. Most of the breakpoints found by array painting and array CGH were identified in the paired end sequencing—55% of the unamplified breakpoints and 97% of the amplified breakpoints (as these are represented by more sequence reads). From this analysis we identified 9 expressed fusion genes: APPBP2-PHF20L1, BCAS3-HOXB9, COL14A1-SKAP1, TAOK1-PCGF2, TIAM1-NRIP1, TIMM23-ARHGAP32, TRPS1-LASP1, USP32-CCDC49 and ZMYM4-OPRD1. We also determined the genomic junctions of a further three expressed fusion genes that had been described by others, BCAS3-ERBB2, DDX5-DEPDC6/DEPTOR and PLEC1-ENPP2. Of this total of 12 expressed fusion genes, 9 were in the coamplification. Due to the sensitivity of the technologies used, we estimate these 12 fusion genes to be around two-thirds of the true total. Many of the fusions seem likely to be driver mutations. For example, PHF20L1, BCAS3, TAOK1, PCGF2, and TRPS1 are fused in other breast cancers. HOXB9 and PHF20L1 are members of gene families that are fused in other neoplasms. Several of the other genes are relevant to cancer—in addition to ERBB2, SKAP1 is an adaptor for Src, DEPTOR regulates the mTOR pathway and NRIP1 is an estrogen-receptor coregulator. CONCLUSIONS: This is the first structural analysis of a breast cancer genome that combines classical molecular cytogenetic approaches with sequencing. Paired-end sequencing was able to detect almost all breakpoints, where there was adequate read depth. It supports the view that gene breakage and gene fusion are important classes of mutation in breast cancer, with a typical breast cancer expressing many fusion genes. |
| format | Online Article Text |
| id | pubmed-3548764 |
| institution | National Center for Biotechnology Information |
| language | English |
| publishDate | 2012 |
| publisher | BioMed Central |
| record_format | MEDLINE/PubMed |
| spelling | pubmed-35487642013-02-04 Structural analysis of the genome of breast cancer cell line ZR-75-30 identifies twelve expressed fusion genes Schulte, Ina Batty, Elizabeth M Pole, Jessica CM Blood, Katherine A Mo, Steven Cooke, Susanna L Ng, Charlotte Howe, Kevin L Chin, Suet-Feung Brenton, James D Caldas, Carlos Howarth, Karen D Edwards, Paul AW BMC Genomics Research Article BACKGROUND: It has recently emerged that common epithelial cancers such as breast cancers have fusion genes like those in leukaemias. In a representative breast cancer cell line, ZR-75-30, we searched for fusion genes, by analysing genome rearrangements. RESULTS: We first analysed rearrangements of the ZR-75-30 genome, to around 10kb resolution, by molecular cytogenetic approaches, combining array painting and array CGH. We then compared this map with genomic junctions determined by paired-end sequencing. Most of the breakpoints found by array painting and array CGH were identified in the paired end sequencing—55% of the unamplified breakpoints and 97% of the amplified breakpoints (as these are represented by more sequence reads). From this analysis we identified 9 expressed fusion genes: APPBP2-PHF20L1, BCAS3-HOXB9, COL14A1-SKAP1, TAOK1-PCGF2, TIAM1-NRIP1, TIMM23-ARHGAP32, TRPS1-LASP1, USP32-CCDC49 and ZMYM4-OPRD1. We also determined the genomic junctions of a further three expressed fusion genes that had been described by others, BCAS3-ERBB2, DDX5-DEPDC6/DEPTOR and PLEC1-ENPP2. Of this total of 12 expressed fusion genes, 9 were in the coamplification. Due to the sensitivity of the technologies used, we estimate these 12 fusion genes to be around two-thirds of the true total. Many of the fusions seem likely to be driver mutations. For example, PHF20L1, BCAS3, TAOK1, PCGF2, and TRPS1 are fused in other breast cancers. HOXB9 and PHF20L1 are members of gene families that are fused in other neoplasms. Several of the other genes are relevant to cancer—in addition to ERBB2, SKAP1 is an adaptor for Src, DEPTOR regulates the mTOR pathway and NRIP1 is an estrogen-receptor coregulator. CONCLUSIONS: This is the first structural analysis of a breast cancer genome that combines classical molecular cytogenetic approaches with sequencing. Paired-end sequencing was able to detect almost all breakpoints, where there was adequate read depth. It supports the view that gene breakage and gene fusion are important classes of mutation in breast cancer, with a typical breast cancer expressing many fusion genes. BioMed Central 2012-12-22 /pmc/articles/PMC3548764/ /pubmed/23260012 http://dx.doi.org/10.1186/1471-2164-13-719 Text en Copyright ©2012 Schulte et al.; licensee BioMed Central Ltd. http://creativecommons.org/licenses/by/2.0 This is an Open Access article distributed under the terms of the Creative Commons Attribution License (http://creativecommons.org/licenses/by/2.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited. |
| spellingShingle | Research Article Schulte, Ina Batty, Elizabeth M Pole, Jessica CM Blood, Katherine A Mo, Steven Cooke, Susanna L Ng, Charlotte Howe, Kevin L Chin, Suet-Feung Brenton, James D Caldas, Carlos Howarth, Karen D Edwards, Paul AW Structural analysis of the genome of breast cancer cell line ZR-75-30 identifies twelve expressed fusion genes |
| title | Structural analysis of the genome of breast cancer cell line ZR-75-30 identifies twelve expressed fusion genes |
| title_full | Structural analysis of the genome of breast cancer cell line ZR-75-30 identifies twelve expressed fusion genes |
| title_fullStr | Structural analysis of the genome of breast cancer cell line ZR-75-30 identifies twelve expressed fusion genes |
| title_full_unstemmed | Structural analysis of the genome of breast cancer cell line ZR-75-30 identifies twelve expressed fusion genes |
| title_short | Structural analysis of the genome of breast cancer cell line ZR-75-30 identifies twelve expressed fusion genes |
| title_sort | structural analysis of the genome of breast cancer cell line zr-75-30 identifies twelve expressed fusion genes |
| topic | Research Article |
| url | https://www.ncbi.nlm.nih.gov/pmc/articles/PMC3548764/ https://www.ncbi.nlm.nih.gov/pubmed/23260012 http://dx.doi.org/10.1186/1471-2164-13-719 |
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