Subclonal Diversification of Primary Breast Cancer Revealed by Multiregion Sequencing

Overview

Journal Nat Med

Specialties General Medicine
Molecular Biology

Date 2015 Jun 23

PMID 26099045

Citations 441

Authors

Lucy R Yates

Moritz Gerstung

Stian Knappskog

Christine Desmedt

Gunes Gundem

Peter Van Loo

Turid Aas

Ludmil B Alexandrov

Denis Larsimont

Helen Davies

Yilong Li

Young Seok Ju

Manasa Ramakrishna

Hans Kristian Haugland

Peer Kaare Lilleng

Serena Nik-Zainal

Stuart McLaren

Adam Butler

Sancha Martin

Dominic Glodzik

Andrew Menzies

Keiran Raine

Jonathan Hinton

David Jones

Laura J Mudie

Bing Jiang

Delphine Vincent

April Greene-Colozzi

Pierre-Yves Adnet

Aquila Fatima

Marion Maetens

Michail Ignatiadis

Michael R Stratton

Christos Sotiriou

Andrea L Richardson

Per Eystein Lonning

David C Wedge

Peter J Campbell

Affiliations

Soon will be listed here.

Abstract

The sequencing of cancer genomes may enable tailoring of therapeutics to the underlying biological abnormalities driving a particular patient's tumor. However, sequencing-based strategies rely heavily on representative sampling of tumors. To understand the subclonal structure of primary breast cancer, we applied whole-genome and targeted sequencing to multiple samples from each of 50 patients' tumors (303 samples in total). The extent of subclonal diversification varied among cases and followed spatial patterns. No strict temporal order was evident, with point mutations and rearrangements affecting the most common breast cancer genes, including PIK3CA, TP53, PTEN, BRCA2 and MYC, occurring early in some tumors and late in others. In 13 out of 50 cancers, potentially targetable mutations were subclonal. Landmarks of disease progression, such as resistance to chemotherapy and the acquisition of invasive or metastatic potential, arose within detectable subclones of antecedent lesions. These findings highlight the importance of including analyses of subclonal structure and tumor evolution in clinical trials of primary breast cancer.

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