Comparison of the cytotoxic response against ovarian cancer by immune effector cells isolated and expanded from normal donors and ovarian cancer patients.

BACKGROUND/AIMS: The aim of this study was to compare the cytotoxic response against ovarian cancer (OC) cells elicited by different immune effector cells in combination with the cytokines interleukin (IL)-2 and interferon (IFN) α-2b. METHODS: OC cells were co-cultured with peripheral blood mononuclear cells (PBMC) from normal donors or OC patients and IL-2 or IFN α-2b alone or in combination, in order to determine the cytotoxicity. T cells were isolated from healthy donors to determine T cell cytotoxic activity. PBMC from healthy donors and OC patients were expanded in an IL-2/IL-7/IL-12 cocktail with and without anti-CD3 antibody, and the cytotoxic activity measured. Flow cytometry was performed on primary, selected and expanded cells to determine T, B, and natural killer- (NK) cell percentages. RESULTS: Healthy donor PBMC elicited a significant cytotoxic response (59%) compared with OC patient PBMC (7%). T cells enriched from normal donors elicited a significant cytotoxic response (18%) compared with controls lacking effector cells (1.4%); however, the cytotoxicity observed was significantly less compared with unselected PBMC. Expanded effector cells consisted primarily of T cells (98%) and the fold-expansion was significantly higher in the presence of anti-CD3 (19- versus 132-fold). No significant difference in the expansion (either fold-expansion or cell type) was observed between OC patients and healthy donors. Expanded cells from both healthy donors and OC patients elicited a significant cytotoxic response in the presence of IL-2 (19% and 22%) compared with controls. CONCLUSIONS: PBMC from OC patients do not elicit a significant cytotoxic response; however, ex vivo-expanded cells from OC patients are capable of cytotoxic killing similar to unexpanded T cells isolated from normal donors. These data provide the groundwork for further development of cellular therapy against OC.

Targeting the IL-6 pathway in multiple myeloma and its implications in cancer-associated gene hypermethylation.

Aberrant methylation of tumor suppressor genes (TSG) is an important epigenetic event in cancer, including multiple myeloma (MM). Interleukin-6 (IL-6), which plays a significant role in the pathogenesis of MM, also regulates DNA methylation. However, attempts to bring IL-6 blockade to the clinic have had limited success. We hypothesize that IL-6 regulation of hypermethylation may be an important pathway leading to rational chemotherapeutic/anti-IL-6 combinations. We first studied the correlation of IL-6 expression and dependence in MM cell lines: U266B1, RPMI8226, and KAS6/1. We confirmed that KAS6/1 is IL-6-dependent whereas U266B1 and RPMI8226 cells are IL-6-independent and that blocking IL-6 inhibited the growth of U266B1 (36% inhibition; p<0.05) and KAS6/1 (68% inhibition; p<0.01), but not the RPMI8226 cells. Using RT-PCR, we showed that U266B1 cells express IL-6, but RPMI8226 and KAS6/1 cells do not. This IL-6 expression pattern correlates with the anti-IL-6 inhibition findings. To correlate IL-6 sensitivity with hypermethylation of TSG, we investigated promoter methylation of CDH1 and DcR1. We found that the promoter of DcR1 and CDH1 is methylated in U266B1 cells and un-methylated in RPMI8226 cells. Furthermore, the DcR1 promoter was un-methylated in KAS6/1 cells. These data support our hypothesis that an IL-6-dependent pathway may regulate hypermethylation of TSG in MM. Newer chemotherapeutic agents that affect methylation are being studied in combination with IL-6 blockade.

Functional characterization of a fluorescent highly tumorigenic ovarian cancer line to test cellular therapy in experimental models.

OBJECTIVES: The objective of this study was to functionally characterize a fluorescent highly tumorigenic ovarian cancer line to test cellular therapy in combination with cytokines or chemotherapies in experimental models. METHODS: A fluorescent highly tumorigenic subline (SKOV3-AF2) was derived from the SKOV3 ovarian cancer cell line. Peripheral blood mononuclear cell (PBMC)-mediated cytotoxicity of SKOV3-AF2 in the presence of interleukin 2 (IL-2) and interferon α-2b (IFNα-2b) was assayed by lactate dehydrogenase release. Sensitivity of SKOV3-AF2 cells to polyethylene glycol-IFNα-2b and IL-2 was assayed in a xenograph nude mouse model. Histopathology was performed to determine necrosis and tumor-infiltrating lymphocytes in the solid tumors. Reverse transcriptase-polymerase chain reaction was used for gene expression analyses of E-cadherin and cysteine-rich 61 (CCN1). RESULTS: The SKOV3-AF2 subline exhibits increased cytotoxicity (up to 70%), mediated by PBMCs, IL-2, and IFNα-2b, compared with parental SKOV3-red fluorescent protein (RFP) cells. SKOV3-AF2 cells are more tumorigenic in vivo as indicated by tumor incidence, time to sacrifice, tumor weight, and ascitic fluid production. SKOV3-AF2 tumor growth was inhibited by polyethylene glycol-IFNα-2b but not low-dose IL-2. Histopathology revealed that the tumors consisted of poorly differentiated surface epithelial carcinoma. SKOV3-RFP, and -AF2 cell lines as well as -AF2 tumors expressed E-cadherin. SKOV3-AF2 derived tumors expressed CCN1; however, the SKOV3-RFP and SKOV3-AF2 cell lines did not. CONCLUSIONS: Characterization of SKOV3-AF2 cells revealed that it is more susceptible to PBMC-mediated cytotoxicity than SKOV3-RFP and highly tumorigenic in a xenograph model, and AF-2 tumors express genes that promote aggressive behavior. Collectively, our data suggest that the SKOV3-AF2 subline will be a useful tool to test cellular therapy for the treatment of ovarian cancer utilizing experimental models.

Deficiencies in the CD40 and CD154 receptor-ligand system reduce experimental lung metastasis.

It is established that experimental metastasis requires platelet activity. CD154 expressed on and released from activated platelets induces an inflammatory response in endothelial cells and monocytes, including tissue factor production. CD154 has also been shown to activate platelets in vitro and promote thrombus stability in vivo. These CD154 effects may be mediated, at least in part, by CD40 signaling on platelets and vascular endothelial cells. We have previously demonstrated prolonged bleeding and PFA-100 closure times in mice deficient for Cd154 or its receptor Cd40. In the present study, we hypothesized that Cd40 and Cd154 promote lung tumor formation in experimental metastasis in mice. We created mice doubly deficient in Cd40 and Cd154 (Dbl KO) and found them to be both fertile and viable. Injected tumor cells seeded poorly in mice deficient in Cd40 or Cd154, as well as Dbl KO, compared to wild-type mice. We sought to determine whether blood-borne Cd40 versus endothelial Cd40 contribute differentially to reduced experimental lung metastasis, as observed in Cd40 deficient mice. By bone marrow transplantation, we created mice deficient for Cd40 either in the blood compartment but not in the endothelium, or vice versa. We found that mice deficient in blood compartment Cd40 had fewer lung nodules compared to wild-type mice and mice deficient in endothelial Cd40. Our findings suggest an important contribution of the Cd40-Cd154 pathway to experimental lung metastasis. Furthermore, the data points to a selective role for peripheral blood cell Cd40 in this process.