The distribution of BRAF gene fusions in solid tumors and response to targeted therapy

Jeffrey S. Ross; Kai Wang; Juliann Chmielecki; Laurie Gay; Adrienne Johnson; Jacob Chudnovsky; Roman Yelensky; Doron Lipson; Siraj M. Ali; Julia A. Elvin; Jo Anne Vergilio; Steven Roels; Vincent A. Miller; Brooke N. Nakamura; Adam Gray; Michael K. Wong; Philip J. Stephens

doi:10.1002/ijc.29825

The distribution of BRAF gene fusions in solid tumors and response to targeted therapy

Jeffrey S. Ross, Kai Wang, Juliann Chmielecki, Laurie Gay, Adrienne Johnson, Jacob Chudnovsky, Roman Yelensky, Doron Lipson, Siraj M. Ali, Julia A. Elvin, Jo Anne Vergilio, Steven Roels, Vincent A. Miller, Brooke N. Nakamura, Adam Gray, Michael K. Wong, Philip J. Stephens

Research output: Contribution to journal › Article › peer-review

232 Scopus citations

Abstract

Although the BRAF V600E base substitution is an approved target for the BRAF inhibitors in melanoma, BRAF gene fusions have not been investigated as anticancer drug targets. In our study, a wide variety of tumors underwent comprehensive genomic profiling for hundreds of known cancer genes using the FoundationOne™ or FoundationOne Heme™ comprehensive genomic profiling assays. BRAF fusions involving the intact in-frame BRAF kinase domain were observed in 55 (0.3%) of 20,573 tumors, across 12 distinct tumor types, including 20 novel BRAF fusions. These comprised 29 unique 5′ fusion partners, of which 31% (9) were known and 69% (20) were novel. BRAF fusions included 3% (14/531) of melanomas; 2% (15/701) of gliomas; 1.0% (3/294) of thyroid cancers; 0.3% (3/1,062) pancreatic carcinomas; 0.2% (8/4,013) nonsmall-cell lung cancers and 0.2% (4/2,154) of colorectal cancers, and were enriched in pilocytic (30%) vs. nonpilocytic gliomas (1%; p < 0.0001), Spitzoid (75%) vs. nonSpitzoid melanomas (1%; p = 0.0001), acinar (67%) vs. nonacinar pancreatic cancers (<1%; p < 0.0001) and papillary (3%) vs. nonpapillary thyroid cancers (0%; p < 0.03). Clinical responses to trametinib and sorafenib are presented. In conclusion, BRAF fusions are rare driver alterations in a wide variety of malignant neoplasms, but enriched in Spitzoid melanoma, pilocytic astrocytomas, pancreatic acinar and papillary thyroid cancers. What's new? New results may help target a rare genetic alteration that promotes cancer. Activation of the BRAF gene is already known to spur tumor growth, and usually that activation results from a single amino acid substitution. BRAF-inhibiting treatments, then, target that mutation. However, in some cases, BRAF gets revved up by a gene fusion. In our study, the authors tested 20,000 tumors and identified 55 BRAF gene fusions in 12 different tumor types. They found the gene fusions occurred more frequently in certain histologic subtypes, information which will help guide treatment strategies for patients with these tumor subtypes.

Original language	English (US)
Pages (from-to)	881-890
Number of pages	10
Journal	International journal of cancer
Volume	138
Issue number	4
DOIs	https://doi.org/10.1002/ijc.29825
State	Published - Feb 15 2016
Externally published	Yes

Keywords

BRAF fusions
NGS
Sptizoid melanoma
cancer
comprehensive genomic profiling
pancreatic acinar carcinoma
pilocytic astrocytoma
solid tumors
targeted therapy

ASJC Scopus subject areas

Oncology
Cancer Research

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10.1002/ijc.29825

Cite this

Ross, J. S., Wang, K., Chmielecki, J., Gay, L., Johnson, A., Chudnovsky, J., Yelensky, R., Lipson, D., Ali, S. M., Elvin, J. A., Vergilio, J. A., Roels, S., Miller, V. A., Nakamura, B. N., Gray, A., Wong, M. K., & Stephens, P. J. (2016). The distribution of BRAF gene fusions in solid tumors and response to targeted therapy. International journal of cancer, 138(4), 881-890. https://doi.org/10.1002/ijc.29825

Ross, JS, Wang, K, Chmielecki, J, Gay, L, Johnson, A, Chudnovsky, J, Yelensky, R, Lipson, D, Ali, SM, Elvin, JA, Vergilio, JA, Roels, S, Miller, VA, Nakamura, BN, Gray, A, Wong, MK & Stephens, PJ 2016, 'The distribution of BRAF gene fusions in solid tumors and response to targeted therapy', International journal of cancer, vol. 138, no. 4, pp. 881-890. https://doi.org/10.1002/ijc.29825

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title = "The distribution of BRAF gene fusions in solid tumors and response to targeted therapy",

abstract = "Although the BRAF V600E base substitution is an approved target for the BRAF inhibitors in melanoma, BRAF gene fusions have not been investigated as anticancer drug targets. In our study, a wide variety of tumors underwent comprehensive genomic profiling for hundreds of known cancer genes using the FoundationOne{\texttrademark} or FoundationOne Heme{\texttrademark} comprehensive genomic profiling assays. BRAF fusions involving the intact in-frame BRAF kinase domain were observed in 55 (0.3%) of 20,573 tumors, across 12 distinct tumor types, including 20 novel BRAF fusions. These comprised 29 unique 5′ fusion partners, of which 31% (9) were known and 69% (20) were novel. BRAF fusions included 3% (14/531) of melanomas; 2% (15/701) of gliomas; 1.0% (3/294) of thyroid cancers; 0.3% (3/1,062) pancreatic carcinomas; 0.2% (8/4,013) nonsmall-cell lung cancers and 0.2% (4/2,154) of colorectal cancers, and were enriched in pilocytic (30%) vs. nonpilocytic gliomas (1%; p < 0.0001), Spitzoid (75%) vs. nonSpitzoid melanomas (1%; p = 0.0001), acinar (67%) vs. nonacinar pancreatic cancers (<1%; p < 0.0001) and papillary (3%) vs. nonpapillary thyroid cancers (0%; p < 0.03). Clinical responses to trametinib and sorafenib are presented. In conclusion, BRAF fusions are rare driver alterations in a wide variety of malignant neoplasms, but enriched in Spitzoid melanoma, pilocytic astrocytomas, pancreatic acinar and papillary thyroid cancers. What's new? New results may help target a rare genetic alteration that promotes cancer. Activation of the BRAF gene is already known to spur tumor growth, and usually that activation results from a single amino acid substitution. BRAF-inhibiting treatments, then, target that mutation. However, in some cases, BRAF gets revved up by a gene fusion. In our study, the authors tested 20,000 tumors and identified 55 BRAF gene fusions in 12 different tumor types. They found the gene fusions occurred more frequently in certain histologic subtypes, information which will help guide treatment strategies for patients with these tumor subtypes.",

keywords = "BRAF fusions, NGS, Sptizoid melanoma, cancer, comprehensive genomic profiling, pancreatic acinar carcinoma, pilocytic astrocytoma, solid tumors, targeted therapy",

author = "Ross, {Jeffrey S.} and Kai Wang and Juliann Chmielecki and Laurie Gay and Adrienne Johnson and Jacob Chudnovsky and Roman Yelensky and Doron Lipson and Ali, {Siraj M.} and Elvin, {Julia A.} and Vergilio, {Jo Anne} and Steven Roels and Miller, {Vincent A.} and Nakamura, {Brooke N.} and Adam Gray and Wong, {Michael K.} and Stephens, {Philip J.}",

note = "Publisher Copyright: {\textcopyright} 2015 The Authors. Published by Wiley Periodicals, Inc. on behalf of UICC.",

year = "2016",

month = feb,

day = "15",

doi = "10.1002/ijc.29825",

language = "English (US)",

volume = "138",

pages = "881--890",

journal = "International journal of cancer",

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AU - Ross, Jeffrey S.

AU - Wang, Kai

AU - Chmielecki, Juliann

AU - Gay, Laurie

AU - Johnson, Adrienne

AU - Chudnovsky, Jacob

AU - Yelensky, Roman

AU - Lipson, Doron

AU - Ali, Siraj M.

AU - Elvin, Julia A.

AU - Vergilio, Jo Anne

AU - Roels, Steven

AU - Miller, Vincent A.

AU - Nakamura, Brooke N.

AU - Gray, Adam

AU - Wong, Michael K.

AU - Stephens, Philip J.

PY - 2016/2/15

Y1 - 2016/2/15

N2 - Although the BRAF V600E base substitution is an approved target for the BRAF inhibitors in melanoma, BRAF gene fusions have not been investigated as anticancer drug targets. In our study, a wide variety of tumors underwent comprehensive genomic profiling for hundreds of known cancer genes using the FoundationOne™ or FoundationOne Heme™ comprehensive genomic profiling assays. BRAF fusions involving the intact in-frame BRAF kinase domain were observed in 55 (0.3%) of 20,573 tumors, across 12 distinct tumor types, including 20 novel BRAF fusions. These comprised 29 unique 5′ fusion partners, of which 31% (9) were known and 69% (20) were novel. BRAF fusions included 3% (14/531) of melanomas; 2% (15/701) of gliomas; 1.0% (3/294) of thyroid cancers; 0.3% (3/1,062) pancreatic carcinomas; 0.2% (8/4,013) nonsmall-cell lung cancers and 0.2% (4/2,154) of colorectal cancers, and were enriched in pilocytic (30%) vs. nonpilocytic gliomas (1%; p < 0.0001), Spitzoid (75%) vs. nonSpitzoid melanomas (1%; p = 0.0001), acinar (67%) vs. nonacinar pancreatic cancers (<1%; p < 0.0001) and papillary (3%) vs. nonpapillary thyroid cancers (0%; p < 0.03). Clinical responses to trametinib and sorafenib are presented. In conclusion, BRAF fusions are rare driver alterations in a wide variety of malignant neoplasms, but enriched in Spitzoid melanoma, pilocytic astrocytomas, pancreatic acinar and papillary thyroid cancers. What's new? New results may help target a rare genetic alteration that promotes cancer. Activation of the BRAF gene is already known to spur tumor growth, and usually that activation results from a single amino acid substitution. BRAF-inhibiting treatments, then, target that mutation. However, in some cases, BRAF gets revved up by a gene fusion. In our study, the authors tested 20,000 tumors and identified 55 BRAF gene fusions in 12 different tumor types. They found the gene fusions occurred more frequently in certain histologic subtypes, information which will help guide treatment strategies for patients with these tumor subtypes.

AB - Although the BRAF V600E base substitution is an approved target for the BRAF inhibitors in melanoma, BRAF gene fusions have not been investigated as anticancer drug targets. In our study, a wide variety of tumors underwent comprehensive genomic profiling for hundreds of known cancer genes using the FoundationOne™ or FoundationOne Heme™ comprehensive genomic profiling assays. BRAF fusions involving the intact in-frame BRAF kinase domain were observed in 55 (0.3%) of 20,573 tumors, across 12 distinct tumor types, including 20 novel BRAF fusions. These comprised 29 unique 5′ fusion partners, of which 31% (9) were known and 69% (20) were novel. BRAF fusions included 3% (14/531) of melanomas; 2% (15/701) of gliomas; 1.0% (3/294) of thyroid cancers; 0.3% (3/1,062) pancreatic carcinomas; 0.2% (8/4,013) nonsmall-cell lung cancers and 0.2% (4/2,154) of colorectal cancers, and were enriched in pilocytic (30%) vs. nonpilocytic gliomas (1%; p < 0.0001), Spitzoid (75%) vs. nonSpitzoid melanomas (1%; p = 0.0001), acinar (67%) vs. nonacinar pancreatic cancers (<1%; p < 0.0001) and papillary (3%) vs. nonpapillary thyroid cancers (0%; p < 0.03). Clinical responses to trametinib and sorafenib are presented. In conclusion, BRAF fusions are rare driver alterations in a wide variety of malignant neoplasms, but enriched in Spitzoid melanoma, pilocytic astrocytomas, pancreatic acinar and papillary thyroid cancers. What's new? New results may help target a rare genetic alteration that promotes cancer. Activation of the BRAF gene is already known to spur tumor growth, and usually that activation results from a single amino acid substitution. BRAF-inhibiting treatments, then, target that mutation. However, in some cases, BRAF gets revved up by a gene fusion. In our study, the authors tested 20,000 tumors and identified 55 BRAF gene fusions in 12 different tumor types. They found the gene fusions occurred more frequently in certain histologic subtypes, information which will help guide treatment strategies for patients with these tumor subtypes.

KW - BRAF fusions

KW - NGS

KW - Sptizoid melanoma

KW - cancer

KW - comprehensive genomic profiling

KW - pancreatic acinar carcinoma

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KW - solid tumors

KW - targeted therapy

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The distribution of BRAF gene fusions in solid tumors and response to targeted therapy

Abstract

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ASJC Scopus subject areas

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