The effect of Taurolidine on adherent and floating subpopulations of melanoma cells.

The annual incidence of malignant melanoma is estimated at 10-12 per 100000 inhabitants in countries of Central Europe and the US, with more recent estimates showing a dramatic upward trend. Taurolidine (Carter/Wallace, Cranberry, NJ) is a novel, potentially effective, antitumor chemotherapeutic agent. We hypothesized that Taurolidine could inhibit the growth, induce apoptosis, affect the cell cycle and change morphology of melanoma cells. We expected this process to be different in adherent and floating subpopulations that may be reflective of solid tumors and their metastases. Analysis of MNT-1 human and B16F10 murine melanoma cells showed that at 72 h the IC(50) of Taurolidine was 25.4+/-3.3 microM for MNT-1 human melanoma cells and 30.9+/-3.6 microM for B16F10 murine melanoma cells. Taurolidine induced DNA fragmentation of melanoma cells in a dose-dependent manner. Taurolidine (75 and 100 microM) induced 52-97% Annexin-V binding (apoptosis), respectively. Evaluation of cell cycle after 72 h exposure to Taurolidine (0-100 microM) revealed that the percentage of melanoma cells in S phase increased from 27 to 40% in the adherent subpopulation and from 33 to 49% in the floating subpopulation. Phase contrast microscopy revealed a marked swelling of melanoma cells and decreasing cell numbers in adherent subpopulation starting at 24 h with 25 microM Taurolidine. Shrinkage of cells dominated at 75-100 microM Taurolidine. Using Cytospin assay in the floating population, we observed swelling of melanoma cells induced by 25-100 micro Taurolidine and appearance of giant (multinuclear) forms resulting from exposure to 75-100 micro Taurolidine. Some floating cells with normal morphology were observed with low concentrations of Taurolidine (0-25 microM). These data show that effects of Taurolidine may be different in adherent and floating subpopulations of melanoma cells. More importantly, floating subpopulations that may contain some viable melanoma cells, may be reflective of potential metastasis after treatment of solid tumors in vivo.

Immunotherapy of mice with an irradiated melanoma vaccine coupled with interleukin-12.

Interleukin (IL)-12 can activate cytotoxic lymphocytes, stimulate natural killer cell activity, induce the production of INF-gamma and inhibit the development of various experimental tumors. We previously demonstrated that immunotherapy of melanoma bearing mice with an irradiated melanoma vaccine (IMV) coupled with IL-2 or GM-CSF had beneficial effects against primary melanoma growth and against subsequent spontaneous metastasis. We also had found that treatment of melanoma bearing mice with IL-12 (300 ng/day) for 4 weeks inhibited the development of primary melanoma tumors in 40% of mice. The purpose of this study was to investigate the efficacy of combined therapy of experimental melanoma with an IMV prepared from B16F10 melanoma cells coupled with IL-12 treatment. C57BL/6 mice were challenged subcutaneously in the tail with B16F10 melanoma cells and by the 45th day, more than 50% of the mice had developed visible primary melanoma tumors at the injection site. Subsequent immunotherapy of mice with IMV, when coupled with IL-12, provided partial inhibition of primary melanoma tumor growth. Optimal results against primary tumor growth were observed when IMV therapy was coupled with IL-12 at a dose of 50 ng/day. Combination of IMV with IL-12 at a dose of 100 ng/day significantly reduced melanoma metastasis to the lungs compared with control mice, and an improvement in mean survival time was observed in mice treated with a combination of IMV with IL-12 (300 ng/day).

A new mouse model of experimental melanoma for vaccine and lymphokine therapy.

The annual incidence of malignant melanoma is estimated at 10-12 per 100,000 inhabitants in countries of central Europe and the United States, and alarmingly there has been a dramatic upward trend in that estimate. The B16 murine melanoma is a rapidly growing metastatic tumor of spontaneous origin, as are human malignant melanomas. Melanoma cells produce specific antigens which are uniquely different from normal cellular antigens, and the expression of such antigens is the cornerstone for preparation of anti-melanoma vaccines. One major problem in evaluating the effectiveness of vaccination and other biologic therapies is the variability of experimental tumor models. A new metastatic model of experimental melanoma which was developed in our laboratory imitates the major clinical stages of malignant metastatic melanoma: stage I, primary (local) tumor growth and bone marrow invasion; stage II, regional lymph node involvement; and stage III, metastasis to distant organs, such as the lungs. This model has been used successfully for screening vaccines constructed in our laboratory. Immunization with formalinized vaccines (of extracellular antigens, intact melanoma cells, or B700 antigen) or irradiated vaccines (of intact melanoma cells) partially inhibit primary melanoma tumor growth, reduce metastasis to regional lymph nodes and lungs, and significantly increase mean survival time. These anti-tumor effects were improved when polyvalent and monovalent vaccines were combined with IL-2 therapy. We also compared the immunogenic activity of vaccines made from B16 melanoma cells transfected with genes encoding murine IL-2 or GM-CSF, and effects on tumor bearing mice were compared with or without therapy using the corresponding lymphokines. In sum, comparison of antibody production, growth of primary melanoma tumors, number of surviving mice, mean survival time, and percent of mice with lung metastases, showed that the best course of immunotherapy involves vaccination of mice with irradiated B16 melanoma cells transfected to secrete GM-CSF, coupled with GM-CSF therapy.

Immunization of mice with melanoma cells transfected to secrete the superantigen, staphylococcal enterotoxin A.

Immunization of mice with a melanoma vaccine coupled with staphylococcal enterotoxin A (SEA) inhibits the growth of primary melanoma tumors in mice. We have now successfully transfected B16 cells with the sea gene and have immunized C57BL/6 mice subcutaneously once per week for 4 weeks prior to tumor challenge with vaccines of irradiated B16 cells or, 4 weeks following tumor challenge of naive mice with B16 cells, with irradiated B16 cells transfected with the sea gene. Primary tumor growth following both types of treatments was inhibited significantly. To characterize immune responses to these immunogens, we examined the production of antibodies to the B700 melanoma antigen, the stimulation of endogenous IL-2 production, the expression of CD4, CD8, Vbeta and CD25 T cell markers, and the induction of NK activity. At 4 weeks following immunization of mice, there was a significant increase (P<0.05) in levels of interleukin-2 production by splenocytes from mice immunized with SEA-secreting B16 cells or with the parental B16 cells, compared to controls. Levels of antibodies to the B700 melanoma antigen were also significantly higher in mice immunized with the SEA-secreting B16 cells, as was expression of CD4, CD8, CD25 and Vbeta T cell antigens, particularly CD4. Natural killer cell activity (at various E:T ratios) was tenfold higher in splenocytes of mice immunized with SEA-secreting B 16 cells, and fivefold higher in mice immunized with the parental B16 cells, compared to controls. These data confirm the possibility of using irradiated murine melanoma cells transfected to secrete SEA in vaccines targeted at preventing the development and growth of melanoma.

Immunization of mice with irradiated melanoma tumor cells transfected to secrete lymphokines and coupled with IL-2 or GM-CSF therapy.

We compared the immunogenic activity of irradiated vaccines prepared from B16 F10 melanoma cells with one made from B16 F10 melanoma cells transfected with genes encoding murine IL-2 or GM-CSF. Vaccines were studied in the conditions of treatment of C57BL/6 mice with or without the corresponding lymphokines. Control and prevaccinated mice were challenged with parental B16 F10 murine melanoma cells (5 x 10(5)) subcutaneously in the midtail to examine growth of the primary (local) tumor in the middle of the tall and metastases to the lungs. This experimental model is very close to the clinical stages of metastatic melanoma. The effectiveness of preimmunization of mice was determined by the levels of antibody production to a melanoma-associated antigen termed B700. The comparison of antibody production, growth of primary melanoma tumors, number of mice surviving at the end of the observation period, mean survival time and per cent mice with metastases in the lungs showed that the best course of immunotherapy was prevaccination of mice with a vaccine of irradiated B16 F10 melanoma cells transfected to secrete GM-CSF, coupled with GM-CSF therapy.