The temporal mutational and immune tumour microenvironment remodelling of HER2-negative primary breast cancers

Leticia De Mattos-Arruda,Aleix Prat,Roberta Fasani,Rodrigo Dienstmann,Patricia Villagrasa,Guillermo Villacampa,Paolo Nuciforo,Juan Blanco-Heredia,Laia Paré,Isabel T Rubio,Samuel Gonçalves-Ribeiro,Pol Cusco,Vanesa Ortega,José Manuel Pérez-García ,Carla A Souza ,Daniel Guimarães Tiezzi ,Javier Cortés ,Stephen‐John Sammut ,Suet-Feung Chin,Carlos Caldas

doi:10.1038/s41523-021-00282-0

Abstract

The biology of breast cancer response to neoadjuvant therapy is underrepresented in the literature and provides a window-of-opportunity to explore the genomic and microenvironment modulation of tumours exposed to therapy. Here, we characterised the mutational, gene expression, pathway enrichment and tumour-infiltrating lymphocytes (TILs) dynamics across different timepoints of 35 HER2-negative primary breast cancer patients receiving neoadjuvant eribulin therapy (SOLTI-1007 NEOERIBULIN-NCT01669252). Whole-exome data (N = 88 samples) generated mutational profiles and candidate neoantigens and were analysed along with RNA-Nanostring 545-gene expression (N = 96 samples) and stromal TILs (N = 105 samples). Tumour mutation burden varied across patients at baseline but not across the sampling timepoints for each patient. Mutational signatures were not always conserved across tumours. There was a trend towards higher odds of response and less hazard to relapse when the percentage of subclonal mutations was low, suggesting that more homogenous tumours might have better responses to neoadjuvant therapy. Few driver mutations (5.1%) generated putative neoantigens. Mutation and neoantigen load were positively correlated (R2 = 0.94, p = <0.001); neoantigen load was weakly correlated with stromal TILs (R2 = 0.16, p = 0.02). An enrichment in pathways linked to immune infiltration and reduced programmed cell death expression were seen after 12 weeks of eribulin in good responders. VEGF was downregulated over time in the good responder group and FABP5, an inductor of epithelial mesenchymal transition (EMT), was upregulated in cases that recurred (p < 0.05). Mutational heterogeneity, subclonal architecture and the improvement of immune microenvironment along with remodelling of hypoxia and EMT may influence the response to neoadjuvant treatment.

Highlights

Breast cancer is the most commonly diagnosed cancer and the leading cause of female cancer death worldwide[1]
In the early stage breast cancer setting, treatment decisions are guided by clinical subtypes, namely hormone receptor (HR) positive (HR+/HER2−), human epidermal growth factor receptor 2 amplified (HER2+) and triple-negative breast cancer (TNBC)
Primary breast cancer tumour specimens were obtained from the open-label, single-arm SOLTI-1007 NEOERIBULIN phase II clinical

Summary

Introduction

Breast cancer is the most commonly diagnosed cancer and the leading cause of female cancer death worldwide[1] It represents a heterogeneous group of tumours with characteristic molecular features, prognosis and responses to available therapy[2,3]. In the early stage breast cancer setting, treatment decisions are guided by clinical subtypes, namely hormone receptor (HR) positive (HR+/HER2−), human epidermal growth factor receptor 2 amplified (HER2+) and triple-negative breast cancer (TNBC). This general classification does not take into account the complex genomic landscape and breast cancer evolution during therapy administration and disease recurrence or progression[4,5]. The neoadjuvant setting in breast cancer provides a window-of-opportunity to explore the genomic and microenvironment modulation of tumours exposed to therapy over time[5,14]

Objectives

Methods

Results