Synergistic effect of anticancer drug resistance and Wnt3a on primary ciliogenesis in A549 cell-derived anticancer drug-resistant subcell lines

Primary cilia, antenna-like cellular sensor structures, are generated from the mother centriole in the G0/ G1 cell-cycle phase under control by cellular signaling pathways involving Wnt, hedgehog, and platelet-derived growth factor. Although primary ciliary dynamics have been reported to be closely related to ciliopathy and tumorigenesis, the molecular basis for the role of primary cilia in human disease is lacking. To clarify how Wnt3a affects primary ciliogenesis in anticancer drug-resistant cells, we derived specific drug-resistant subcell lines from A549 human lung cancer cells using anticancer drugs doxorubicin, dasatinib, and paclitaxel (A549/Dox, A549/Das, and A549/Pac, respectively). The primary cilia-containing cell population and primary cilia length increased in the A549/Dox and A549/Pac subcell lines under increased MDR1 expression, when compared to those in the parental A549 cells. In the A549/Das subcell line, primary cilia length increased but the cell population was not affected. In addition, Wnt3a increased primary cilia-containing cell population and primary cilia length in A549/Dox, A549/Das, and A549/Pac cells, without change of cell growth. Abnormal shapes of primary cilia were frequently observed by anticancer drug resistance and Wnt3a stimulation. Taken together, our results indicate that anticancer drug resistance and Wnt3a affect primary ciliogenesis synergistically, suggesting a potential new strategy for overcoming anticancer drug resistance.(c) 2022 The Authors. Published by Elsevier Inc. This is an open access article under the CC BY-NC-ND license (http://creativecommons.org/licenses/by-nc-nd/4.0/).

Automated summary

Primary cilia, regulated by cellular signaling pathways including Wnt, are cellular sensor structures that play a role in anticancer drug resistance. This study found that anticancer drug resistance and Wnt3a stimulation synergistically affect primary ciliogenesis, suggesting a potential new strategy for overcoming drug resistance.