Breast Cancer Research (Dec 2019)

Impact of aromatase inhibitor treatment on global gene expression and its association with antiproliferative response in ER+ breast cancer in postmenopausal patients

  • Qiong Gao,
  • Elena López-Knowles,
  • Maggie Chon U. Cheang,
  • James Morden,
  • Ricardo Ribas,
  • Kally Sidhu,
  • David Evans,
  • Vera Martins,
  • Andrew Dodson,
  • Anthony Skene,
  • Chris Holcombe,
  • Elizabeth Mallon,
  • Abigail Evans,
  • Judith M. Bliss,
  • John Robertson,
  • Ian Smith,
  • Lesley-Ann Martin,
  • Mitch Dowsett,
  • on behalf of the POETIC Trial Management Group and Trialists

DOI
https://doi.org/10.1186/s13058-019-1223-z
Journal volume & issue
Vol. 22, no. 1
pp. 1 – 20

Abstract

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Abstract Background Endocrine therapy reduces breast cancer mortality by 40%, but resistance remains a major clinical problem. In this study, we sought to investigate the impact of aromatase inhibitor (AI) therapy on gene expression and identify gene modules representing key biological pathways that relate to early AI therapy resistance. Methods Global gene expression was measured on pairs of core-cut biopsies taken at baseline and at surgery from 254 patients with ER-positive primary breast cancer randomised to receive 2-week presurgical AI (n = 198) or no presurgical treatment (control n = 56) from the POETIC trial. Data from the AI group was adjusted to eliminate artefactual process-related changes identified in the control group. The response was assessed by changes in the proliferation marker, Ki67. Results High baseline ESR1 expression associated with better AI response in HER2+ tumours but not HER2− tumours. In HER2− tumours, baseline expression of 48 genes associated with poor antiproliferative response (p < 0.005) including PERP and YWHAQ, the two most significant, and the transcription co-regulators (SAP130, HDAC4, and NCOA7) which were among the top 16 most significant. Baseline gene signature scores measuring cell proliferation, growth factor signalling (ERBB2-GS, RET/GDNF-GS, and IGF-1-GS), and immune activity (STAT1-GS) were significantly higher in poor AI responders. Two weeks of AI caused downregulation of genes involved in cell proliferation and ER signalling, as expected. Signature scores of E2F activation and TP53 dysfunction after 2-week AI were associated with poor AI response in both HER2− and HER2+ patients. Conclusions There is a high degree of heterogeneity in adaptive mechanisms after as little as 2-week AI therapy; however, all appear to converge on cell cycle regulation. Our data support the evaluation of whether an E2F signatures after short-term exposure to AI may identify those patients most likely to benefit from the early addition of CDK4/6 inhibitors. Trial registration ISRCTN, ISRCTN63882543, registered on 18 December 2007.

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