[PDF][PDF] Regulators of mitotic arrest and ceramide metabolism are determinants of sensitivity to paclitaxel and other chemotherapeutic drugs
Cancer cell, 2007•cell.com
Cytotoxic drug resistance is a major cause of cancer treatment failure. We report an RNA
interference screen to identify genes influencing sensitivity of different cancer cell types to
chemotherapeutic agents. A set of genes whose targeting leads to resistance to paclitaxel is
identified, many of which are involved in the spindle assembly checkpoint. Silencing these
genes attenuates paclitaxel-induced mitotic arrest and induces polyploidy in the absence of
drug. We also identify a ceramide transport protein, COL4A3BP or CERT, whose …
interference screen to identify genes influencing sensitivity of different cancer cell types to
chemotherapeutic agents. A set of genes whose targeting leads to resistance to paclitaxel is
identified, many of which are involved in the spindle assembly checkpoint. Silencing these
genes attenuates paclitaxel-induced mitotic arrest and induces polyploidy in the absence of
drug. We also identify a ceramide transport protein, COL4A3BP or CERT, whose …
Summary
Cytotoxic drug resistance is a major cause of cancer treatment failure. We report an RNA interference screen to identify genes influencing sensitivity of different cancer cell types to chemotherapeutic agents. A set of genes whose targeting leads to resistance to paclitaxel is identified, many of which are involved in the spindle assembly checkpoint. Silencing these genes attenuates paclitaxel-induced mitotic arrest and induces polyploidy in the absence of drug. We also identify a ceramide transport protein, COL4A3BP or CERT, whose downregulation sensitizes cancer cells to multiple cytotoxic agents, potentiating endoplasmic reticulum stress. COL4A3BP expression is increased in drug-resistant cell lines and in residual tumor following paclitaxel treatment of ovarian cancer, suggesting that it could be a target for chemotherapy-resistant cancers.
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