Sophie C J Bosma1, Marlous Hoogstraat2, Femke van der Leij3, Michiel de Maaker4, Jelle Wesseling4, Esther Lips4, Claudette E Loo5, Emiel J Rutgers6, Paula H M Elkhuizen3, Harry Bartelink3, Marc J van de Vijver7. 1. Department of Radiation Oncology, the Netherlands Cancer Institute, Amsterdam, the Netherlands. Electronic address: s.bosma@nki.nl. 2. Department of Bioinformatics, the Netherlands Cancer Institute, Amsterdam, the Netherlands. 3. Department of Radiation Oncology, the Netherlands Cancer Institute, Amsterdam, the Netherlands. 4. Department of Molecular Pathology, the Netherlands Cancer Institute, Amsterdam, the Netherlands. 5. Department of Radiology, the Netherlands Cancer Institute, Amsterdam, the Netherlands. 6. Department of Surgery, the Netherlands Cancer Institute, Amsterdam, the Netherlands. 7. Department of Pathology, Amsterdam UMC, Amsterdam, the Netherlands.
Abstract
PURPOSE: We aimed to study radiation-induced gene expression changes and to identify differences in gene expression between patients with and without response to radiation therapy (RT) for invasive breast cancer with the purpose of exploring whether a predictive signature could be developed. Such a signature could assist in optimizing individualized locoregional treatment. METHODS AND MATERIALS: RNA-seq using next-generation sequencing was performed on fresh frozen samples from pretreatment biopsies and post-RT surgery specimens from patients with low-risk breast cancer treated within the multicenter preoperative accelerated partial breast irradiation trial. Patients were treated with preoperative RT (10 × 4 Gy in 10 days or 5 × 6 Gy in 5 days) and a lumpectomy 6 weeks thereafter. The response of the tumor to RT was evaluated by pathologic assessment. To analyze the gene expression data, unsupervised and supervised clustering was performed. Gene expression profiles were compared between biopsies of responders and nonresponders and between samples before and after RT. RESULTS: Ninety-four samples from 77 patients were analyzed: 68 pretreatment biopsies and 26 post-RT surgery specimens. Six patients had a (near) complete pathologic response, 3 patients had a good response, 32 patients had a partial response, and 22 patients had no or very limited response. Comparing patients with and without response to RT, 25 genes were significantly differentially expressed and were not linked to a pathway. Comparison of samples before and after RT identified significant changes in gene expression. Genes involved in p53 signaling, TNFA1 signaling, apoptosis, epithelial mesenchymal transition, and inflammatory response were upregulated. Genes involved in mitotic spindle, G2M checkpoint, and E2F targets were downregulated. CONCLUSIONS: Radiation-induced gene expression changes mainly involved p53 signaling, cell cycle regulation, DNA repair, and inflammatory response. No clinically significant differences could be identified in gene expression between patients with and without response to RT.
PURPOSE: We aimed to study radiation-induced gene expression changes and to identify differences in gene expression between patients with and without response to radiation therapy (RT) for invasive breast cancer with the purpose of exploring whether a predictive signature could be developed. Such a signature could assist in optimizing individualized locoregional treatment. METHODS AND MATERIALS: RNA-seq using next-generation sequencing was performed on fresh frozen samples from pretreatment biopsies and post-RT surgery specimens from patients with low-risk breast cancer treated within the multicenter preoperative accelerated partial breast irradiation trial. Patients were treated with preoperative RT (10 × 4 Gy in 10 days or 5 × 6 Gy in 5 days) and a lumpectomy 6 weeks thereafter. The response of the tumor to RT was evaluated by pathologic assessment. To analyze the gene expression data, unsupervised and supervised clustering was performed. Gene expression profiles were compared between biopsies of responders and nonresponders and between samples before and after RT. RESULTS: Ninety-four samples from 77 patients were analyzed: 68 pretreatment biopsies and 26 post-RT surgery specimens. Six patients had a (near) complete pathologic response, 3 patients had a good response, 32 patients had a partial response, and 22 patients had no or very limited response. Comparing patients with and without response to RT, 25 genes were significantly differentially expressed and were not linked to a pathway. Comparison of samples before and after RT identified significant changes in gene expression. Genes involved in p53 signaling, TNFA1 signaling, apoptosis, epithelial mesenchymal transition, and inflammatory response were upregulated. Genes involved in mitotic spindle, G2M checkpoint, and E2F targets were downregulated. CONCLUSIONS: Radiation-induced gene expression changes mainly involved p53 signaling, cell cycle regulation, DNA repair, and inflammatory response. No clinically significant differences could be identified in gene expression between patients with and without response to RT.
Authors: James Meehan; Mark Gray; Carlos Martínez-Pérez; Charlene Kay; Jimi C Wills; Ian H Kunkler; J Michael Dixon; Arran K Turnbull Journal: J Pers Med Date: 2021-08-14