Abstract
Even under normoxia, cancer cells exhibit increased glucose uptake and glycolysis, an occurrence known as the Warburg effect. This altered metabolism results in increased lactic acid production, leading to extracellular acidosis and contributing to metastasis and chemoresistance. Current pH imaging methods are invasive, costly, or require long acquisition times, and may not be suitable for high-throughput pre-clinical small animal studies. Here, we present a ratiometric pH-sensitive bioluminescence reporter called pHLuc for in vivo monitoring of tumor acidosis. pHLuc consists of a pH-sensitive GFP (superecliptic pHluorin or SEP), a pH-stable OFP (Antares), and Nanoluc luciferase. The resulting reporter produces a pH-responsive green 510nm emission (from SEP) and a pH-insensitive red-orange 580nm emission (from Antares). The ratiometric readout (R580/510) is indicative of changes in extracellular pH (pHe). In vivo proof-of-concept experiments with NSG mice model bearing human synovial sarcoma SW982 xenografts that stably express the pHLuc reporter suggest that the level of acidosis varies across the tumor. Altogether, we demonstrate the diagnostic value of pHLuc as a bioluminescent reporter for pH variations across the tumor microenvironment. The pHLuc reporter plasmids constructed in this work are available from Addgene.
Highlights
A hallmark of neoplastic diseases is the reprogramming of cellular energy metabolism to actively support cell proliferation (Hanahan and Weinberg, 2011)
Given the significant role of pHe in tumor progression, we present a ratiometric luminescent reporter called pHLuc that allows for live imaging of pH change with tumor progression
The pHLuc reporter detected variations in pHe across SW982 tumor xenografts in NOD.CgPrkdcscid Il2rgtm1Wjl/SzJ (NSG) mice, a finding that is consistent with other reporter systems (Anemone et al, 2019)
Summary
A hallmark of neoplastic diseases is the reprogramming of cellular energy metabolism to actively support cell proliferation (Hanahan and Weinberg, 2011). Cancer cells display an increased rate of glycolysis even under normal oxygen conditions. This “Warburg effect” leads to excessive production of lactic acid, and acidification of the tumor microenvironment, with the extracellular pH (pHe) dropping to as low as 6.4 (Chen et al, 2015). Despite the significance of studying the role of pHe in tumor progression, limited methods exist to monitor the pHe of tumors in vivo. A genetically encoded pH-sensitive luminescence reporter would provide a simple and inexpensive means to study the pHe of tumors in vivo. To the best of our knowledge, no such bioluminescence pH reporter exists hitherto
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