Abstract
Chemotherapy resistance poses severe limitations on the efficacy of anti-cancer medications. Recently, the notion of using novel combinations of ‘old' drugs for new indications has garnered significant interest. The potential of using phenothiazines as chemosensitizers has been suggested earlier but so far our understanding of their molecular targets remains scant. The current study was designed to better define phenothiazine-sensitive cellular processes in relation to chemosensitivity. We found that phenothiazines shared the ability to delay γH2AX resolution in DNA-damaged human lung cancer cells. Accordingly, cells co-treated with chemotherapy and phenothiazines underwent protracted cell-cycle arrest followed by checkpoint escape that led to abnormal mitoses, secondary arrest and/or a form of apoptosis associated with increased endogenous oxidative stress and intense vacuolation. We provide evidence implicating lysosomal dysfunction as a key component of cell death in phenothiazine co-treated cells, which also exhibited more typical hallmarks of apoptosis including the activation of both caspase-dependent and -independent pathways. Finally, we demonstrated that vacuolation in phenothiazine co-treated cells could be reduced by ROS scavengers or the vacuolar ATPase inhibitor bafilomycin, leading to increased cell viability. Our data highlight the potential benefit of using phenothiazines as chemosensitizers in tumors that acquire molecular alterations rendering them insensitive to caspase-mediated apoptosis.
Highlights
Modulation of gH2AX clearance by inhibition of DNA repair or through other means has the potential to enhance tumor killing by DNA-damaging drugs
We show that persistence of chemotherapy-induced gH2AX in phenothiazine co-treated lung cancer cells resulted in prolonged cell-cycle arrest followed by checkpoint escape, abnormal mitosis and subsequent induction of secondary arrest and/or cell death
The clonogenic capacity of human non-small cell lung carcinoma (NSCLC) U1810 and H23 cells following DNA-damaging treatment was determined by colony formation assay in the absence and presence of 10 mM TFP (Figure 1a)
Summary
Modulation of gH2AX clearance by inhibition of DNA repair or through other means has the potential to enhance tumor killing by DNA-damaging drugs. Increased generation of reactive oxygen species (ROS) is frequently observed in cells exposed to DNA-damaging agents[13] and depending on the particular model system, ROS signaling has been shown to induce apoptosis, autophagy, necrosis or premature senescence.[14] The intricate interplay between various stress-response pathways and their relation to cell death has not been clearly defined. Our previous work implicated phenothiazines as candidate DNA repair inhibitors.[17] In the current study, we found a novel link between impairment of gH2AX clearance and enhancement of chemosensitivity by phenothiazines. Our data highlight the potential benefit of using phenothiazines as chemosensitizers in tumors that acquire molecular alterations rendering them insensitive to caspasemediated apoptosis
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