Whole-genome sequencing reveals breast cancers with mismatch repair deficiency

Helen Davies; Sandro Morganella; Colin A. Purdie; Se Jin Jang; Elin Borgen; Hege Russnes; Dominik Glodzik; Xueqing Zou; Alain Viari; Andrea L. Richardson; Anne Lise Børresen-Dale; Alastair Thompson; Jorunn E. Eyfjord; Gu Kong; Michael R. Stratton; Serena Nik-Zainal

doi:10.1158/0008-5472.CAN-17-1083

Whole-genome sequencing reveals breast cancers with mismatch repair deficiency

Helen Davies, Sandro Morganella, Colin A. Purdie, Se Jin Jang, Elin Borgen, Hege Russnes, Dominik Glodzik, Xueqing Zou, Alain Viari, Andrea L. Richardson, Anne Lise Børresen-Dale, Alastair Thompson, Jorunn E. Eyfjord, Gu Kong, Michael R. Stratton, Serena Nik-Zainal

Surgical Oncology

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

72 Scopus citations

Abstract

Mismatch repair (MMR)–deficient cancers have been discovered to be highly responsive to immune therapies such as PD-1 checkpoint blockade, making their definition in patients, where they may be relatively rare, paramount for treatment decisions. In this study, we utilized patterns of mutagenesis known as mutational signatures, which are imprints of the mutagenic processes associated with MMR deficiency, to identify MMR-deficient breast tumors from a whole-genome sequencing dataset comprising a cohort of 640 patients. We identified 11 of 640 tumors as MMR deficient, but only 2 of 11 exhibited germline mutations in MMR genes or Lynch Syndrome. Two additional tumors had a substantially reduced proportion of mutations attributed to MMR deficiency, where the predominant mutational signatures were related to APOBEC enzymatic activity. Overall, 6 of 11 of the MMR-deficient cases in this cohort were confirmed genetically or epigenetically as having abrogation of MMR genes. However, IHC analysis of MMR-related proteins revealed all but one of 10 samples available for testing as MMR deficient. Thus, the mutational signatures more faithfully reported MMR deficiency than sequencing of MMR genes, because they represent a direct pathophysiologic readout of repair pathway abnormalities. As whole-genome sequencing continues to become more affordable, it could be used to expose individually abnormal tumors in tissue types where MMR deficiency has been rarely detected, but also rarely sought.

Original language	English (US)
Pages (from-to)	4755-4762
Number of pages	8
Journal	Cancer Research
Volume	77
Issue number	18
DOIs	https://doi.org/10.1158/0008-5472.CAN-17-1083
State	Published - Sep 15 2017

ASJC Scopus subject areas

Oncology
Cancer Research

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10.1158/0008-5472.CAN-17-1083

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Davies, H., Morganella, S., Purdie, C. A., Jang, S. J., Borgen, E., Russnes, H., Glodzik, D., Zou, X., Viari, A., Richardson, A. L., Børresen-Dale, A. L., Thompson, A., Eyfjord, J. E., Kong, G., Stratton, M. R., & Nik-Zainal, S. (2017). Whole-genome sequencing reveals breast cancers with mismatch repair deficiency. Cancer Research, 77(18), 4755-4762. https://doi.org/10.1158/0008-5472.CAN-17-1083

Davies, H, Morganella, S, Purdie, CA, Jang, SJ, Borgen, E, Russnes, H, Glodzik, D, Zou, X, Viari, A, Richardson, AL, Børresen-Dale, AL, Thompson, A, Eyfjord, JE, Kong, G, Stratton, MR & Nik-Zainal, S 2017, 'Whole-genome sequencing reveals breast cancers with mismatch repair deficiency', Cancer Research, vol. 77, no. 18, pp. 4755-4762. https://doi.org/10.1158/0008-5472.CAN-17-1083

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title = "Whole-genome sequencing reveals breast cancers with mismatch repair deficiency",

abstract = "Mismatch repair (MMR)–deficient cancers have been discovered to be highly responsive to immune therapies such as PD-1 checkpoint blockade, making their definition in patients, where they may be relatively rare, paramount for treatment decisions. In this study, we utilized patterns of mutagenesis known as mutational signatures, which are imprints of the mutagenic processes associated with MMR deficiency, to identify MMR-deficient breast tumors from a whole-genome sequencing dataset comprising a cohort of 640 patients. We identified 11 of 640 tumors as MMR deficient, but only 2 of 11 exhibited germline mutations in MMR genes or Lynch Syndrome. Two additional tumors had a substantially reduced proportion of mutations attributed to MMR deficiency, where the predominant mutational signatures were related to APOBEC enzymatic activity. Overall, 6 of 11 of the MMR-deficient cases in this cohort were confirmed genetically or epigenetically as having abrogation of MMR genes. However, IHC analysis of MMR-related proteins revealed all but one of 10 samples available for testing as MMR deficient. Thus, the mutational signatures more faithfully reported MMR deficiency than sequencing of MMR genes, because they represent a direct pathophysiologic readout of repair pathway abnormalities. As whole-genome sequencing continues to become more affordable, it could be used to expose individually abnormal tumors in tissue types where MMR deficiency has been rarely detected, but also rarely sought.",

author = "Helen Davies and Sandro Morganella and Purdie, {Colin A.} and Jang, {Se Jin} and Elin Borgen and Hege Russnes and Dominik Glodzik and Xueqing Zou and Alain Viari and Richardson, {Andrea L.} and B{\o}rresen-Dale, {Anne Lise} and Alastair Thompson and Eyfjord, {Jorunn E.} and Gu Kong and Stratton, {Michael R.} and Serena Nik-Zainal",

note = "Funding Information: S. Nik-Zainal and X. Zou were supported by the Wellcome Trust via a Wellcome Trust Strategic Award (WT101126/B/13/Z), S. Nik-Zainal is personally funded by a Cancer Research UK Advanced Clinician Scientist Award (C60100/A23916). A. L. Richardson is partially supported by the Dana-Farber/ Harvard Cancer Center SPORE in Breast Cancer (NIH/NCI5 P50 CA168504-02). G. Kong is supported by National Research Foundation of Korea (NRF) grants funded by the Korean government (NRF2015R1A2A1A10052578). Publisher Copyright: {\textcopyright}2017 American Association for Cancer Research.",

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doi = "10.1158/0008-5472.CAN-17-1083",

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AU - Davies, Helen

AU - Morganella, Sandro

AU - Purdie, Colin A.

AU - Jang, Se Jin

AU - Borgen, Elin

AU - Russnes, Hege

AU - Glodzik, Dominik

AU - Zou, Xueqing

AU - Viari, Alain

AU - Richardson, Andrea L.

AU - Børresen-Dale, Anne Lise

AU - Thompson, Alastair

AU - Eyfjord, Jorunn E.

AU - Kong, Gu

AU - Stratton, Michael R.

AU - Nik-Zainal, Serena

N1 - Funding Information: S. Nik-Zainal and X. Zou were supported by the Wellcome Trust via a Wellcome Trust Strategic Award (WT101126/B/13/Z), S. Nik-Zainal is personally funded by a Cancer Research UK Advanced Clinician Scientist Award (C60100/A23916). A. L. Richardson is partially supported by the Dana-Farber/ Harvard Cancer Center SPORE in Breast Cancer (NIH/NCI5 P50 CA168504-02). G. Kong is supported by National Research Foundation of Korea (NRF) grants funded by the Korean government (NRF2015R1A2A1A10052578). Publisher Copyright: ©2017 American Association for Cancer Research.

PY - 2017/9/15

Y1 - 2017/9/15

N2 - Mismatch repair (MMR)–deficient cancers have been discovered to be highly responsive to immune therapies such as PD-1 checkpoint blockade, making their definition in patients, where they may be relatively rare, paramount for treatment decisions. In this study, we utilized patterns of mutagenesis known as mutational signatures, which are imprints of the mutagenic processes associated with MMR deficiency, to identify MMR-deficient breast tumors from a whole-genome sequencing dataset comprising a cohort of 640 patients. We identified 11 of 640 tumors as MMR deficient, but only 2 of 11 exhibited germline mutations in MMR genes or Lynch Syndrome. Two additional tumors had a substantially reduced proportion of mutations attributed to MMR deficiency, where the predominant mutational signatures were related to APOBEC enzymatic activity. Overall, 6 of 11 of the MMR-deficient cases in this cohort were confirmed genetically or epigenetically as having abrogation of MMR genes. However, IHC analysis of MMR-related proteins revealed all but one of 10 samples available for testing as MMR deficient. Thus, the mutational signatures more faithfully reported MMR deficiency than sequencing of MMR genes, because they represent a direct pathophysiologic readout of repair pathway abnormalities. As whole-genome sequencing continues to become more affordable, it could be used to expose individually abnormal tumors in tissue types where MMR deficiency has been rarely detected, but also rarely sought.

AB - Mismatch repair (MMR)–deficient cancers have been discovered to be highly responsive to immune therapies such as PD-1 checkpoint blockade, making their definition in patients, where they may be relatively rare, paramount for treatment decisions. In this study, we utilized patterns of mutagenesis known as mutational signatures, which are imprints of the mutagenic processes associated with MMR deficiency, to identify MMR-deficient breast tumors from a whole-genome sequencing dataset comprising a cohort of 640 patients. We identified 11 of 640 tumors as MMR deficient, but only 2 of 11 exhibited germline mutations in MMR genes or Lynch Syndrome. Two additional tumors had a substantially reduced proportion of mutations attributed to MMR deficiency, where the predominant mutational signatures were related to APOBEC enzymatic activity. Overall, 6 of 11 of the MMR-deficient cases in this cohort were confirmed genetically or epigenetically as having abrogation of MMR genes. However, IHC analysis of MMR-related proteins revealed all but one of 10 samples available for testing as MMR deficient. Thus, the mutational signatures more faithfully reported MMR deficiency than sequencing of MMR genes, because they represent a direct pathophysiologic readout of repair pathway abnormalities. As whole-genome sequencing continues to become more affordable, it could be used to expose individually abnormal tumors in tissue types where MMR deficiency has been rarely detected, but also rarely sought.

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Whole-genome sequencing reveals breast cancers with mismatch repair deficiency

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