Abstract
Anticancer therapies currently used in the clinic often can neither eradicate the tumor nor prevent disease recurrence due to tumor resistance. In this study, we showed that chemoresistance to pemetrexed, a multi-target anti-folate (MTA) chemotherapeutic agent for non-small cell lung cancer (NSCLC), is associated with a stem cell-like phenotype characterized by an enriched stem cell gene signature, augmented aldehyde dehydrogenase activity and greater clonogenic potential. Mechanistically, chemoresistance to MTA requires activation of epithelial-to-mesenchymal transition (EMT) pathway in that an experimentally induced EMT per se promotes chemoresistance in NSCLC and inhibition of EMT signaling by kaempferol renders the otherwise chemoresistant cancer cells susceptible to MTA. Relevant to the clinical setting, human primary NSCLC cells with an elevated EMT signaling feature a significantly enhanced potential to resist MTA, whereas concomitant administration of kaempferol abrogates MTA chemoresistance, regardless of whether it is due to an intrinsic or induced activation of the EMT pathway. Collectively, our findings reveal that a bona fide activation of EMT pathway is required and sufficient for chemoresistance to MTA and that kaempferol potently regresses this chemotherapy refractory phenotype, highlighting the potential of EMT pathway inhibition to enhance chemotherapeutic response of lung cancer.
Highlights
Experimental and clinical evidence has revealed that cancer cells are heterogeneous regarding tumor-propagating capacity and response to therapeutic drugs
We showed that chemoresistance to pemetrexed, a multi-target anti-folate (MTA) chemotherapeutic agent for non-small cell lung cancer (NSCLC), is associated with a stem cell-like phenotype characterized by an enriched stem cell gene signature, augmented aldehyde dehydrogenase activity and greater clonogenic potential
We show that NSCLC resistance to chemotherapeutic multitargeted anti-folate (MTA) is associated with a stem cell-like phenotype, manifested by an increased level of stem cell factors (Sox[2], Oct[4] and Nanog) and a greater clonogenicity
Summary
Experimental and clinical evidence has revealed that cancer cells are heterogeneous regarding tumor-propagating capacity and response to therapeutic drugs. A prevailing hypothesis states that a phenotypically and functionally distinct subpopulation within the tumor, referred to as cancer stem cells (CSCs), dictates tumor propagation and progression and might account for the tumor resistance to therapeutics.[4,5] The CSC concept explains plausibly the inefficiency of chemotherapeutic drugs used today and implies that CSCs must be taken into account for effective anticancer strategies aimed at permanent clinical remission of tumors. Blocking EMT signaling might be a rational strategy to enhance cancer response to chemotherapeutics
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