Molecular Oncology (Nov 2019)

Biochemical pathways mediated by KLK6 protease in breast cancer

  • Georgios Pampalakis,
  • Eleni Zingkou,
  • Konstantinos Gus Sidiropoulos,
  • Eleftherios P. Diamandis,
  • Vassilis Zoumpourlis,
  • George M. Yousef,
  • Georgia Sotiropoulou

DOI
https://doi.org/10.1002/1878-0261.12493
Journal volume & issue
Vol. 13, no. 11
pp. 2329 – 2343

Abstract

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Kallikrein‐related peptidase 6 (KLK6) is a serine protease normally expressed in mammary tissue and aberrantly regulated in breast cancer. At physiological levels, KLK6 functions as a suppressor of breast cancer, while its aberrant overexpression (> 50‐fold higher than normal) is characteristic of a subset of breast cancers and has been linked to accelerated growth of primary breast tumors in severe combined immunodeficiency mice (Pampalakis et al. Cancer Res 2009, 69, 3779). Here, we investigated the molecular mechanisms underlying the concentration‐dependent functions of KLK6 by comparing MDA‐MB‐231 stable transfectants expressing increasing levels of KLK6 in in vitro and in vivo tumorigenicity assays (soft agar, xenograft growth, tail vein metastasis). Quantitative proteomics was applied to identify proteins that are altered upon re‐expression of KLK6 in MDA‐MB‐231 at normal or constitutive levels. Overexpression of KLK6 is associated with increased metastatic ability of breast cancer cells into lungs, increased expression of certain S100 proteins (S100A4, S100A11) and keratins (KRT), and downregulation of the apoptosis‐related proteases CASP7 and CASP8, and RABs. On the other hand, KLK6 re‐expression at physiological levels leads to inhibition of lung metastases associated with suppression of S100 proteins (S100A4, S100A10, S100A13, S100A16) and induced CASP7 and CASP8 expression. As this is the first report that KLK6 expression is associated with S100 proteins, caspases, RABs, and KRTs, we validated this finding in clinical datasets. By integrating proteomics and microarray data from breast cancer patients, we generated two composite scores, KLK6 + S100B‐S100A7 and KLK6 + S100B‐S100A14‐S100A16, to predict long‐term survival of breast cancer patients. We present previously unknown pathways implicating KLK6 in breast cancer. The findings promise to aid our understanding of the functional roles of KLK6 in breast cancer and may yield new biomarkers for the cancer types in which KLK6 is known to be aberrantly upregulated.

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