A mathematical model of antibody-dependent cellular cytotoxicity (ADCC).

Immunotherapies exploit the immune system to target and kill cancer cells, while sparing healthy tissue. Antibody therapies, an important class of immunotherapies, involve the binding to specific antigens on the surface of the tumour cells of antibodies that activate natural killer (NK) cells to kill the tumour cells. Preclinical assessment of molecules that may cause antibody-dependent cellular cytotoxicity (ADCC) involves co-culturing cancer cells, NK cells and antibody in vitro for several hours and measuring subsequent levels of tumour cell lysis. Here we develop a mathematical model of such an in vitro ADCC assay, formulated as a system of time-dependent ordinary differential equations and in which NK cells kill cancer cells at a rate which depends on the amount of antibody bound to each cancer cell. Numerical simulations generated using experimentally-based parameter estimates reveal that the system evolves on two timescales: a fast timescale on which antibodies bind to receptors on the surface of the tumour cells, and NK cells form complexes with the cancer cells, and a longer time-scale on which the NK cells kill the cancer cells. We construct approximate model solutions on each timescale, and show that they are in good agreement with numerical simulations of the full system. Our results show how the processes involved in ADCC change as the initial concentration of antibody and NK-cancer cell ratio are varied. We use these results to explain what information about the tumour cell kill rate can be extracted from the cytotoxicity assays.

Combining virotherapy and angiotherapy for the treatment of breast cancer.

A breast cancer-selective oncolytic adenovirus was engineered to express antagonists of vascular endothelial growth factor (VEGF) and Notch signaling to combine direct anticancer activity with disruption of tumor-associated angiogenesis. Replication of the parental virus, AdEHE2F, is stimulated by estrogen receptor (ER), E2F1 and hypoxia, and it mediates selective lysis of breast cancer cells in vitro and in vivo. Here, we encoded soluble Flt-1 (sFlt1) and soluble Dll4 (sDll4) under control of the E3 promoter. sFlt1 (the extra-cellular domain of VEGF receptor 1) binds VEGF-A and inhibits stimulation of VEGFR2, decreasing angiogenic stimulus. Conversely, sDll4 (the extracellular domain of Delta-like 4) antagonizes Notch signaling to prevent endothelial maturation. We hypothesized that these agents might show additive or synergistic activity. In vitro, sFlt1 inhibited endothelial cell proliferation and sprouting, whereas sDll4 increased the number of vascular branchpoints. In ER-positive ZR75.1 tumors in vivo AdEHE2F showed the potent direct virotherapy with no augmentation owing to sFlt1 or sDll4; however, in ER-negative MDA-231 tumors efficacy was enhanced by encoding sFlt1 or sDll4, with survival time extending to double that of controls. There was also a dramatic decrease in the total number of tumour blood vessels, as well as the number of perfused vessels, suggesting that improved efficacy reflects combined anti-tumour and anti-vascular effects.

The C-terminal domain of the regulatory protein NOVH is sufficient to promote interaction with fibulin 1C: a clue for a role of NOVH in cell-adhesion signaling.

The NOVH protein belongs to the emerging CCN [Connective tissue growth factor (CTGF), Cyr61/Cef10, nephroblastoma overexpressed gene] family of growth regulators sharing a strikingly conserved multimodular organization but exhibiting distinctive functional features. Two members of the family (CYR61 and CTGF) are positive regulators of cell proliferation, whereas NOVH and two other members (ELM1 and RCOP-1) exhibit features of negative regulators of growth. The multimodular structure of these proteins suggests that their biological role(s) may depend on interactions with several factors as well as proteins constitutive of the extracellular matrix. To gain insight into the functionality of these domains, we have used a two-hybrid system to identify proteins interacting with NOVH. We report here that the C-terminal domain confers on the full-length NOVH protein the capacity to bind fibulin 1C, a protein of the extracellular matrix that interacts with several other regulators of cell adhesion. Furthermore, we show that a natural N-truncated isoform of NOVH produced by cells expressing the full-length NOVH protein also binds fibulin 1C with a high affinity, and we hypothesize that the production of truncated isoforms of NOVH (and probably of other CCN proteins) may be a critical aspect in the modulation of their biological activity. These results set the stage for a study of NOVH-fibulin 1C interactions and their potential significance in cell-adhesion signaling in normal and pathological conditions.