Jing Ning

Elimination of dormant, autophagic ovarian cancer cells and xenografts through enhanced sensitivity to anaplastic lymphoma kinase inhibition

BackgroundPoor outcomes for patients with ovarian cancer relate to dormant, drug‐resistant cancer cells that survive after primary surgery and chemotherapy. Ovarian cancer (OvCa) cells persist in poorly vascularized scars on the peritoneal surface and depend on autophagy to survive nutrient deprivation. The authors have sought drugs that target autophagic cancer cells selectively to eliminate residual disease.MethodsBy using unbiased small‐interfering RNA (siRNA) screens, the authors observed that knockdown of anaplastic lymphoma kinase (ALK) reduced the survival of autophagic OvCa cells. Small‐molecule ALK inhibitors were evaluated for their selective toxicity against autophagic OvCa cell lines and xenografts. Autophagy was induced by reexpression of GTP‐binding protein Di‐Ras3 (DIRAS3) or serum starvation and was evaluated with Western blot analysis, fluorescence imaging, and transmission electron microscopy. Signaling pathways required for crizotinib‐induced apoptosis of autophagic cells were explored with flow cytometric analysis, Western blot analysis, short‐hairpin RNA knockdown of autophagic proteins, and small‐molecule inhibitors of STAT3 and BCL‐2.ResultsInduction of autophagy by reexpression of DIRAS3 or serum starvation in multiple OvCa cell lines significantly reduced the 50% inhibitory concentration of crizotinib and other ALK inhibitors. In 2 human OvCa xenograft models, the DIRAS3‐expressing tumors treated with crizotinib had significantly decreased tumor burden and long‐term survival in 67% to 79% of mice. Crizotinib treatment of autophagic cancer cells further enhanced autophagy and induced autophagy‐mediated apoptosis by decreasing phosphorylated STAT3 and BCL‐2 signaling.ConclusionsCrizotinib may eliminate dormant, autophagic, drug‐resistant OvCa cells that remain after conventional cytoreductive surgery and combination chemotherapy. A clinical trial of ALK inhibitors as maintenance therapy after second‐look operations should be seriously considered.

Human epididymis protein 4 antigen‐autoantibody complexes complement cancer antigen 125 for detecting early‐stage ovarian cancer

BackgroundEarly detection of ovarian cancer could significantly improve patient outcomes. Cancer antigen 125 (CA 125) is elevated in sera from approximately 60% of patients with early‐stage (I/II) disease. Sensitivity might be improved through the combination of CA 125 with other biomarkers. Among potential biomarkers, antigen‐autoantibody (Ag‐AAb) complexes have received relatively little attention.MethodsLuminex‐based immunoassays were used to measure human epididymis protein 4 (HE4), anti‐HE4 autoantibody, and HE4 Ag‐AAb complexes in sera from patients with early‐ (n = 73) and late‐stage ovarian cancers (n = 49) at the time of diagnosis and from asymptomatic women with (n = 15) or without ovarian cancer (n = 212) enrolled in the Normal Risk Ovarian Cancer Screening Study.ResultsAt 98% specificity for healthy, asymptomatic women, 7% of patients with early‐stage (I/II) ovarian cancer and 4% of patients with late‐stage (III/IV) disease had elevated levels of HE4 autoantibody, whereas elevated levels of HE4 Ag‐AAb complexes were detected in sera from 38% of early‐stage cases and 31% of late‐stage cases. Complementarity was observed in receiver operating characteristic (ROC) curves between HE4 Ag‐AAb complexes and CA 125 levels in early‐stage ovarian cancer (P < .001). CA 125 detected 63% of cases, and a combination of CA 125 and HE4 Ag‐AAb complexes detected 81%. Complementarity was also observed in ROC curves for an independent validation set with 69 early‐stage patients (P = .039). HE4 Ag‐AAb complexes were detected in serial preclinical serum samples from women destined to develop ovarian cancer: they correlated with CA 125 but did not provide a lead time.ConclusionsHE4 Ag‐AAb complexes could complement CA 125 in detecting a higher fraction of early‐stage ovarian cancers.