Somatic mutations and copy number variations in breast cancers with heterogeneous HER2 amplification.

Mieke R Van Bockstal,Carolien H M Van Deurzen,Esther H Lips,Hein F B M Sleddens,Ronald Van Marion,Winand N M Dinjens,Peggy N Atmodimedjo,Jelle Wesseling,Marie Colombe Agahozo,Lindy L Visser

doi:10.1002/1878-0261.12650

Abstract

Intratumour heterogeneity fuels carcinogenesis and allows circumventing specific targeted therapies. HER2 gene amplification is associated with poor outcome in invasive breast cancer. Heterogeneous HER2 amplification has been described in 5–41% of breast cancers. Here, we investigated the genetic differences between HER2‐positive and HER2‐negative admixed breast cancer components. We performed an in‐depth analysis to explore the potential heterogeneity in the somatic mutational landscape of each individual tumour component. Formalin‐fixed, paraffin‐embedded breast cancer tissue of ten patients with at least one HER2‐negative and at least one HER2‐positive component was microdissected. Targeted next‐generation sequencing was performed using a customized 53‐gene panel. Somatic mutations and copy number variations were analysed. Overall, the tumours showed a heterogeneous distribution of 12 deletions, 9 insertions, 32 missense variants and 7 nonsense variants in 26 different genes, which are (likely) pathogenic. Three splice site alterations were identified. One patient had an EGFR copy number gain restricted to a HER2‐negative in situ component, resulting in EGFR protein overexpression. Two patients had FGFR1 copy number gains in at least one tumour component. Two patients had an 8q24 gain in at least one tumour component, resulting in a copy number increase in MYC and PVT1. One patient had a CCND1 copy number gain restricted to a HER2‐negative tumour component. No common alternative drivers were identified in the HER2‐negative tumour components. This series of 10 breast cancers with heterogeneous HER2 gene amplification illustrates that HER2 positivity is not an unconditional prerequisite for the maintenance of tumour growth. Many other molecular aberrations are likely to act as alternative or collaborative drivers. This study demonstrates that breast carcinogenesis is a dynamically evolving process characterized by a versatile somatic mutational profile, of which some genetic aberrations will be crucial for cancer progression, and others will be mere ‘passenger’ molecular anomalies.

Highlights

Cancer is a genetic disease, resulting from an accumulation of successive somatic gene mutations that drive cancer cell proliferation (Tomasetti et al, 2017)
Ten patients with a breast cancer with spatially heterogeneous HER2 amplification were included in this study
By using targeted next-generation sequencing (NGS) with a 53-gene panel, we identified a plethora of somatic mutations and copy number variation (CNV) within the HER2-negative components in this series of ten HER2 heterogeneous breast cancers

Summary

Introduction

Cancer is a genetic disease, resulting from an accumulation of successive somatic gene mutations that drive cancer cell proliferation (Tomasetti et al, 2017). Invasive breast cancer is heterogeneous and comprises different molecular subtypes (Perou et al, 2000). Around 12–20% of invasive breast cancers have a HER2 gene amplification, which generally results in overexpression of the HER2 protein (Kraus et al, 1987; Ross, 2010; Venter et al, 1987). HER2 amplification is associated with shorter disease-free and overall survival in patients with node-negative and node-positive invasive breast cancer treated with adjuvant chemotherapy and/or local radiation (Slamon et al, 1987, 1989). The anti-HER2 treatment arsenal has substantially expanded, and current therapeutic options include trastuzumab, pertuzumab (Perjeta; Genentech), trastuzumab emtansine or T-DM1 (Kadcyla; Genentech) and lapatinib (Tykerb; GlaxoSmithKline, Brentford, UK)

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