Literature DB >> 31763993

Deregulating MYC in a model of HER2+ breast cancer mimics human intertumoral heterogeneity.

Tyler Risom1, Xiaoyan Wang1, Juan Liang1, Xiaoli Zhang1, Carl Pelz2, Lydia G Campbell3, Jenny Eng3, Koei Chin3,4, Caroline Farrington5, Goutham Narla5, Ellen M Langer1,4, Xiao-Xin Sun1,4, Yulong Su1, Colin J Daniel1, Mu-Shui Dai1,4, Christiane V Löhr6, Rosalie C Sears1,4.   

Abstract

The c-MYC (MYC) oncoprotein is often overexpressed in human breast cancer; however, its role in driving disease phenotypes is poorly understood. Here, we investigate the role of MYC in HER2+ disease, examining the relationship between HER2 expression and MYC phosphorylation in HER2+ patient tumors and characterizing the functional effects of deregulating MYC expression in the murine NeuNT model of amplified-HER2 breast cancer. Deregulated MYC alone was not tumorigenic, but coexpression with NeuNT resulted in increased MYC Ser62 phosphorylation and accelerated tumorigenesis. The resulting tumors were metastatic and associated with decreased survival compared with NeuNT alone. MYC;NeuNT tumors had increased intertumoral heterogeneity including a subtype of tumors not observed in NeuNT tumors, which showed distinct metaplastic histology and worse survival. The distinct subtypes of MYC;NeuNT tumors match existing subtypes of amplified-HER2, estrogen receptor-negative human tumors by molecular expression, identifying the preclinical utility of this murine model to interrogate subtype-specific differences in amplified-HER2 breast cancer. We show that these subtypes have differential sensitivity to clinical HER2/EGFR-targeted therapeutics, but small-molecule activators of PP2A, the phosphatase that regulates MYC Ser62 phosphorylation, circumvents these subtype-specific differences and ubiquitously suppresses tumor growth, demonstrating the therapeutic utility of this approach in targeting deregulated MYC breast cancers.

Entities:  

Keywords:  Breast cancer; Cell Biology; Mouse models; Oncogenes; Oncology

Mesh:

Substances:

Year:  2020        PMID: 31763993      PMCID: PMC6934197          DOI: 10.1172/JCI126390

Source DB:  PubMed          Journal:  J Clin Invest        ISSN: 0021-9738            Impact factor:   14.808


  80 in total

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