Using a novel panel of drug-resistant triple-negative breast cancer cell lines to identify candidate therapeutic targets and biomarkers
Using a novel panel of drug-resistant triple-negative breast cancer cell lines to identify candidate therapeutic targets and biomarkers
Here, we introduce a novel set of triple-negative breast cancer (TNBC) cell lines consisting of MDA-MB-468, HCC38, and HCC1806 and their sublines adapted to cisplatin, doxorubicin, eribulin, paclitaxel, gemcitabine, or 5-fluorouracil. Whole exome sequencing combined with TCGA-derived patient data resulted in the identification of 682 biomarker candidates in a pan-cancer analysis. Thirty-five genes were considered the most promising candidates because they harbored resistance-associated variants in at least two resistant sublines, and their expression correlated with TNBC patient survival. Exome sequencing and response profiles to cytotoxic drugs and DNA damage response inhibitors identified revealed remarkably little overlap between the resistant sublines, suggesting that each resistance formation process follows a unique route. This reflects recent findings on cancer cell evolution in patients, supporting the relevance of drug-adapted cancer cell lines as preclinical models of acquired resistance. Moreover, all of the drug-resistant TNBC sublines remained sensitive or even displayed collateral sensitivity to a range of tested compounds. Cross-resistance levels were lowest for the CHK2 inhibitor CCT241533, the PLK1 inhibitor SBE13, and the RAD51 recombinase inhibitor B02, suggesting that CHK2, PLK1, and RAD51 are potential drug targets for therapy-refractory TNBC. In conclusion, we present novel preclinical models of acquired drug resistance in TNBC and the identification of novel candidate therapeutic targets and biomarkers for this disease.
Acquired drug resistance, Exome sequencing DNA repair, TCGA, Triple negative breast cancer, de novo variants
Grimsley, Helen E.
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Antczak, Magdalena
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Reddin, Ian G.
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Weiler, Nicole
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McLaughlin, Katie-May
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Rothweiler, Florian
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Haas, Johannes
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Nist, Andrea
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Mernberger, Marco
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Stiewe, Thorsten
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Fenton, Tim R.
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Speidel, Daniel
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Harper-Wynne, Catherine
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Cox, Karina
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Heckl, Dirk
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Cinatl, Jindrich
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Wass, Mark N.
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Garrett, Michelle D.
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Michaelis, Martin
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2 May 2025
Grimsley, Helen E.
bb750c7f-b170-43e3-9e96-cba6f531bb57
Antczak, Magdalena
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Reddin, Ian G.
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Weiler, Nicole
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McLaughlin, Katie-May
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Rothweiler, Florian
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Haas, Johannes
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Nist, Andrea
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Mernberger, Marco
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Stiewe, Thorsten
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Fenton, Tim R.
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Speidel, Daniel
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Harper-Wynne, Catherine
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Cox, Karina
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Heckl, Dirk
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Cinatl, Jindrich
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Wass, Mark N.
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Garrett, Michelle D.
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Michaelis, Martin
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Grimsley, Helen E., Antczak, Magdalena, Reddin, Ian G., Weiler, Nicole, McLaughlin, Katie-May, Rothweiler, Florian, Haas, Johannes, Nist, Andrea, Mernberger, Marco, Stiewe, Thorsten, Fenton, Tim R., Speidel, Daniel, Harper-Wynne, Catherine, Cox, Karina, Heckl, Dirk, Cinatl, Jindrich, Wass, Mark N., Garrett, Michelle D. and Michaelis, Martin
(2025)
Using a novel panel of drug-resistant triple-negative breast cancer cell lines to identify candidate therapeutic targets and biomarkers.
Cancer Letters, 624, [217754].
(doi:10.1016/j.canlet.2025.217754).
Abstract
Here, we introduce a novel set of triple-negative breast cancer (TNBC) cell lines consisting of MDA-MB-468, HCC38, and HCC1806 and their sublines adapted to cisplatin, doxorubicin, eribulin, paclitaxel, gemcitabine, or 5-fluorouracil. Whole exome sequencing combined with TCGA-derived patient data resulted in the identification of 682 biomarker candidates in a pan-cancer analysis. Thirty-five genes were considered the most promising candidates because they harbored resistance-associated variants in at least two resistant sublines, and their expression correlated with TNBC patient survival. Exome sequencing and response profiles to cytotoxic drugs and DNA damage response inhibitors identified revealed remarkably little overlap between the resistant sublines, suggesting that each resistance formation process follows a unique route. This reflects recent findings on cancer cell evolution in patients, supporting the relevance of drug-adapted cancer cell lines as preclinical models of acquired resistance. Moreover, all of the drug-resistant TNBC sublines remained sensitive or even displayed collateral sensitivity to a range of tested compounds. Cross-resistance levels were lowest for the CHK2 inhibitor CCT241533, the PLK1 inhibitor SBE13, and the RAD51 recombinase inhibitor B02, suggesting that CHK2, PLK1, and RAD51 are potential drug targets for therapy-refractory TNBC. In conclusion, we present novel preclinical models of acquired drug resistance in TNBC and the identification of novel candidate therapeutic targets and biomarkers for this disease.
Text
1-s2.0-S0304383525003209-main
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Accepted/In Press date: 26 April 2025
e-pub ahead of print date: 27 April 2025
Published date: 2 May 2025
Additional Information:
Copyright © 2025 The Authors. Published by Elsevier B.V. All rights reserved.
Keywords:
Acquired drug resistance, Exome sequencing DNA repair, TCGA, Triple negative breast cancer, de novo variants
Identifiers
Local EPrints ID: 501904
URI: http://eprints.soton.ac.uk/id/eprint/501904
ISSN: 0304-3835
PURE UUID: f60c2cfb-33fd-432a-8309-211f7ce73df7
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Date deposited: 11 Jun 2025 18:31
Last modified: 22 Aug 2025 02:34
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Contributors
Author:
Helen E. Grimsley
Author:
Magdalena Antczak
Author:
Ian G. Reddin
Author:
Nicole Weiler
Author:
Katie-May McLaughlin
Author:
Florian Rothweiler
Author:
Johannes Haas
Author:
Andrea Nist
Author:
Marco Mernberger
Author:
Thorsten Stiewe
Author:
Daniel Speidel
Author:
Catherine Harper-Wynne
Author:
Karina Cox
Author:
Dirk Heckl
Author:
Jindrich Cinatl
Author:
Mark N. Wass
Author:
Michelle D. Garrett
Author:
Martin Michaelis
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