Rasmus A Sloth1, Trine V Axelsen1, Maria Sofia Espejo1, Nicolai J Toft1, Ninna C S Voss1, Mark Burton2,3,4, Mads Thomassen2,3, Pernille Vahl5, Ebbe Boedtkjer6. 1. Department of Biomedicine, Aarhus University, Aarhus, Denmark. 2. Department of Clinical Genetics, University of Southern Denmark, Odense, Denmark. 3. Clinical Genome Center, University and Region of Southern Denmark, Odense, Denmark. 4. Department of Clinical Medicine, University of Southern Denmark, Odense, Denmark. 5. Department of Pathology, Aarhus University Hospital, Aarhus, Denmark. 6. Department of Biomedicine, Aarhus University, Aarhus, Denmark. eb@biomed.au.dk.
Abstract
BACKGROUND: While cellular metabolism and acidic waste handling accelerate during breast carcinogenesis, temporal patterns of acid-base regulation and underlying molecular mechanisms responding to the tumour microenvironment remain unclear. METHODS: We explore data from human cohorts and experimentally investigate transgenic mice to evaluate the putative extracellular HCO3--sensor Receptor Protein Tyrosine Phosphatase (RPTP)γ during breast carcinogenesis. RESULTS: RPTPγ expression declines during human breast carcinogenesis and particularly in high-malignancy grade breast cancer. Low RPTPγ expression associates with poor prognosis in women with Luminal A or Basal-like breast cancer. RPTPγ knockout in mice favours premalignant changes in macroscopically normal breast tissue, accelerates primary breast cancer development, promotes malignant breast cancer histopathologies, and shortens recurrence-free survival. In RPTPγ knockout mice, expression of Na+,HCO3--cotransporter NBCn1-a breast cancer susceptibility protein-is upregulated in normal breast tissue but, contrary to wild-type mice, shows no further increase during breast carcinogenesis. Associated augmentation of Na+,HCO3--cotransport in normal breast tissue from RPTPγ knockout mice elevates steady-state intracellular pH, which has known pro-proliferative effects. CONCLUSIONS: Loss of RPTPγ accelerates cellular net acid extrusion and elevates NBCn1 expression in breast tissue. As these effects precede neoplastic manifestations in histopathology, we propose that RPTPγ-dependent enhancement of Na+,HCO3--cotransport primes breast tissue for cancer development.
BACKGROUND: While cellular metabolism and acidic waste handling accelerate during breast carcinogenesis, temporal patterns of acid-base regulation and underlying molecular mechanisms responding to the tumour microenvironment remain unclear. METHODS: We explore data from human cohorts and experimentally investigate transgenic mice to evaluate the putative extracellular HCO3--sensor Receptor Protein Tyrosine Phosphatase (RPTP)γ during breast carcinogenesis. RESULTS: RPTPγ expression declines during human breast carcinogenesis and particularly in high-malignancy grade breast cancer. Low RPTPγ expression associates with poor prognosis in women with Luminal A or Basal-like breast cancer. RPTPγ knockout in mice favours premalignant changes in macroscopically normal breast tissue, accelerates primary breast cancer development, promotes malignant breast cancer histopathologies, and shortens recurrence-free survival. In RPTPγ knockout mice, expression of Na+,HCO3--cotransporter NBCn1-a breast cancer susceptibility protein-is upregulated in normal breast tissue but, contrary to wild-type mice, shows no further increase during breast carcinogenesis. Associated augmentation of Na+,HCO3--cotransport in normal breast tissue from RPTPγ knockout mice elevates steady-state intracellular pH, which has known pro-proliferative effects. CONCLUSIONS: Loss of RPTPγ accelerates cellular net acid extrusion and elevates NBCn1 expression in breast tissue. As these effects precede neoplastic manifestations in histopathology, we propose that RPTPγ-dependent enhancement of Na+,HCO3--cotransport primes breast tissue for cancer development.
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Authors: Nicolai J Toft; Trine V Axelsen; Helene L Pedersen; Marco Mele; Mark Burton; Eva Balling; Tonje Johansen; Mads Thomassen; Peer M Christiansen; Ebbe Boedtkjer Journal: Elife Date: 2021-07-05 Impact factor: 8.140
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