Expression of the retained C-terminal extracellular portion of the ovarian cancer glycoprotein MUC16 induces transformation and tumor growth. However, the mechanisms of MUC16 oncogenesis related to glycosylation are not clearly defined. We establish that MUC16 oncogenic effects are mediated through MGAT5-dependent N-glycosylation of two specific asparagine sites within its 58 amino acid ectodomain. Oncogenic signaling from the C-terminal portion of MUC16 requires the presence of Galectin-3 and growth factor receptors co-localized on lipid rafts. These effects are blocked upon loss of either Galectin-3 expression or activity MGAT5. Using synthetic MUC16 glycopeptides, we developed novel N-glycosylation site directed–monoclonal antibodies that block Galectin-3–mediated MUC16 interactions with cell surface signaling molecules. These antibodies inhibit invasion of ovarian cancer cells, directly blocking the in vivo growth of MUC16-bearing ovarian cancer xenografts, elucidating new therapeutic modalities.
Ovarian cancer is the most lethal gynecologic malignancy and the fifth leading cause of cancer-related death in women. Over the past decade, medical imaging has played an increasingly valuable role in the diagnosis, staging, and treatment planning of the disease. In this “Focus on Molecular Imaging” review, we seek to provide a brief yet informative survey of the current state of the molecular imaging of ovarian cancer. The article is divided into sections according to modality, covering recent advances in the MR, PET, SPECT, ultrasound, and optical imaging of ovarian cancer. Although primary emphasis is given to clinical studies, preclinical investigations that are particularly innovative and promising are discussed as well. Ultimately, we are hopeful that the combination of technologic innovations, novel imaging probes, and further integration of imaging into clinical protocols will lead to significant improvements in the survival rate for ovarian cancer.
Immuno-positron emission tomography (immuno-PET) is a powerful tool to noninvasively characterize the in vivo biodistribution of engineered antibodies (Abs). Methods: L1 cell adhesion molecule (L1CAM)-targeting HuE71 immunoglobulin G1 (IgG1) and immunoglobulin G4 (IgG4) Abs bearing identical variable heavy and light chain sequences but different fragment crystallizable (Fc) portions were radiolabeled with Zirconium-89 ( 89 Zr) and the in vivo biodistribution was studied in SKOV3 ovarian cancer xenografted nude mice. Results: In addition to showing uptake in L1CAM-expressing SKOV3 tumors like its parental counterpart HuE71 IgG1, the afucosylated variant having enhanced Fc-receptor (FcR) affinity showed high nonspecific uptake in lymph nodes. On the other hand, aglycosylated HuE71 IgG1 with abrogated FcR binding did not show lymphoid uptake. The use of IgG4 subclass showed high nonspecific uptake in the kidneys, which was prevented by mutating serine at position 228 to proline (S228P) in the hinge region of the IgG4 Ab to mitigate in vivo fragment antigen-binding (Fab) arm exchange. Conclusion: Our findings highlight the influence of Fc-modifications and the choice of IgG subclass on the in vivo biodistribution of Abs and the potential outcomes thereof.
Zoledronic acid (ZA), a bisphosphonate originally indicated for use in osteoporosis, has been reported to exert a direct effect on breast cancer cells, although the mechanism of this effect is currently unknown. Data from the ABCSG-12 and ZO-FAST clinical trials suggest that treatment with the combination of ZA and aromatase inhibitors (AI) result in increased disease free survival in breast cancer patients over AI alone. To determine whether the mechanism of this combination involved inhibition of aromatase, AC-1 cells (MCF-7 human breast cancer cells transfected with an aromatase construct) were treated simultaneously with combinations of ZA and AI letrozole for 72 hours. This combination significantly increased inhibition of aromatase activity of AC-1 cells by compared to letrozole alone. Combination treatment of 1nM letrozole and 1μM and 10μM zoledronic acid resulted in an additive drug interaction on inhibiting cell viability, as measured by MTT assay. Treatment with ZA was found to inhibit phosphorylation of aromatase on serine 473. Zoledronic acid was also shown to be more effective in inhibiting cell viability in aromatase transfected AC-1 cells when compared to inhibition of cell viability observed in non-transfected MCF-7. Estradiol was able to partially rescue the effect of 1μM and 10μM ZA on cell viability following treatment for 72 hours, as shown by a shift to the right in the estradiol dose response curve. In conclusion, these results indicate that the combination of ZA and letrozole results in an additive inhibition of cell viability. Furthermore, ZA alone can inhibit aromatase activity through inhibition of serine phosphorylation events important for aromatase enzymatic activity and contributes to inhibition of cell viability.
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