Increased local vascular endothelial growth factor expression associated with antitumor activity of proteasome inhibitor

Inhibition of the proteasome, a multicatalytic proteinase complex, is an attractive approach to cancer therapy. Here we report that a selective inhibitor of the chymotrypsin-like activity of the proteasome, PSI (N-benzyloxycarbonyl-Ile-Glu(O-t-butyl)-Ala-leucinal) may inhibit growth of solid tumors not only through apoptosis induction, but also indirectly--through inhibition of angiogenesis. Two murine tumors: colon adenocarcinoma (C-26) and Lewis lung carcinoma (3LL) were chosen to study the antitumor effect of PSI. In an in vivo model of local tumor growth, PSI exerted significant antitumor effects against C-26 colon carcinoma, but not against 3LL lung carcinoma. Retardation of tumor growth was observed in mice treated with both 10 nmoles and 100 nmoles doses of PSI and in the latter group prolongation of the survival time of tumor-bearing mice was observed. PSI inhibited angiogenesis in the C-26 growing tumors with no such effect in 3LL tumors. Unexpectedly, that activity was associated with upregulation of vascular endothelial growth factor (VEGF) at the level of mRNA expression and protein production in C-26 tumors treated with PSI. C-26 cells treated with PSI produced increased amounts of VEGF in vitro in a dose- and time-dependent manner. We demonstrated that in C-26 colon adenocarcionoma higher VEGF production may render endothelial cells susceptible to the proapoptotic activity of PSI and is associated with inhibition of tumor growth.

Potentiated antitumor effects of interleukin 12 and interferon alpha against B16F10 melanoma in mice

Systemic administration of cytokines has not found broad application in cancer immunotherapy due to its toxicity and lack of effectiveness in a broad spectrum of tumors. Among the most promising cytokines used often in pre-clinical and clinical trials are interferon alpha and interleukin 12. We have shown in our study that combining IL-12 with IFN-alpha in a dose which alone does not show antitumor activity results in potentiated antitumor effects without inducing toxicity.

Granulocyte-macrophage colony-stimulating factor potentiates antitumor activity of interleukin-12 in melanoma model in mice

To study the antitumor activity of the combination immunotherapy with interleukin-12 (IL-12) and granulocyte-macrophage colony-stimulating factor (GM-CSF), a murine MmB 16 melanoma tumor model was used. Seven days after inoculation of MmB 16 melanoma cells into the footpad of the right hind limb, mice were treated with IL-12 and/or GM-CSF administered intratumorally for 7 consecutive days. IL-12 used both at a high (1 microg) and at a low (0.01 microg) dose per day produced retardation of tumor growth, although neither treatment resulted in any significant prolongation of the survival of tumor-bearing mice. GM-CSF did not by itself exert antitumor activity in this model; however, it potentiated antitumor effects of IL-12. In particular, survival of tumor-bearing mice treated with IL-12 (0.01 microg per day) and GM-CSF was significantly prolonged compared with that in mice treated with either IL-12 or GM-CSF alone.

Direct stimulation of macrophages by IL-12 and IL-18--a bridge too far?

A novel pathway of autocrine macrophage activation based on a positive feedback loop involving interleukin (IL)-12, IL-18 and IFN-gamma has recently been suggested. However, the macrophage isolation technique employed to describe the above phenomenon does not allow obtaining a pure population of macrophages casting some doubt to its existence. In the present study, we show that even minor contamination with lymphoid cells of a pure population of macrophage-like cells (Raw 264.7) results in a marked production of nitric oxide after stimulation with both IL-12 and IL-18. Neither macrophage-like cells nor lymphoid cells were capable of secreting high amounts of nitric oxide after stimulation with IL-12 and/or IL-18. Based on these observations we hypothesize that proposed autocrine feedback loop of macrophage activation is rather paracrine in nature and involves direct stimulation of residual lymphoid cells to secrete IFN-gamma that is then capable of activating macrophages.

Potentiation of the anti-tumour effects of Photofrin-based photodynamic therapy by localized treatment with G-CSF

Photofrin-based photodynamic therapy (PDT) has recently been approved for palliative and curative purposes in cancer patients. It has been demonstrated that neutrophils are indispensable for its anti-tumour effectiveness. We decided to evaluate the extent of the anti-tumour effectiveness of PDT combined with administration of granulocyte colony-stimulating factor (G-CSF) as well as the influence of Photofrin and G-CSF on the myelopoiesis and functional activity of neutrophils in mice. An intensive treatment with G-CSF significantly potentiated anti-tumour effectiveness of Photofrin-based PDT resulting in a reduction of tumour growth and prolongation of the survival time of mice bearing two different tumours: colon-26 and Lewis lung carcinoma. Moreover, 33% of C-26-bearing mice were completely cured of their tumours after combined therapy and developed a specific and long-lasting immunity. The tumours treated with both agents contained more infiltrating neutrophils and apoptotic cells then tumours treated with either G-CSF or PDT only. Importantly, simultaneous administration of Photofrin and G-CSF stimulated bone marrow and spleen myelopoiesis that resulted in an increased number of neutrophils demonstrating functional characteristics of activation. Potentiated anti-tumour effects of Photofrin-based PDT combined with G-CSF observed in two murine tumour models suggest that clinical trials using this tumour therapy protocol would be worth pursuing.

Interleukin 18--interferon gamma inducing factor--a novel player in tumour immunotherapy?

The list of interleukins is growing at a steady rate. Although, it is over 8 years since the initial description of interferon gamma inducing factor (IGIF, now called IL-18), this novel cytokine is still not well characterised. However, the data were sufficient to support the testing of IL-18 in experimental tumour therapy. IL-18 is produced mainly by macrophages. Similarly to IL-1beta, IL-18 does not possess a signal sequence allowing direct secretion through the plasma membrane. Although, the exact mechanism of IL-18 secretion is not confirmed, it seems that, like IL-1beta, IGIF is processed by the cysteine proteases belonging to caspase family, especially by ICE (interleukin 1beta converting enzyme). Among the target cells responding to IL-18 are T lymphocytes and NK cells, which, under the influence of IL-18, produce substantial amounts of IFN-gamma. In this respect IL-18 seems to be even stronger than IL-12. Similarly to IL-12, IL-18 stimulates cytotoxicity of T and NK cells. Moreover, it enhances FasL-mediated cytotoxicity of CD4+ T and NK cells. A potential role of IL-18 in tumour immunotherapy is discussed in this article with special emphasis on the similarities with IL-12 and the potential mechanisms of its antitumour activity in preclinical models in mice.

Interleukin 12 and indomethacin exert a synergistic, angiogenesis-dependent antitumor activity in mice

Nonsteroidal anti-inflammatory drugs have been shown to reduce the incidence and mortality from colorectal cancer. It has recently been demonstrated that these drugs are capable of suppressing the production of pro-angiogenic factors from tumor cells. The mechanisms of antitumor action of interleukin 12 include the enforced secretion of anti-angiogenic factors and stimulation of antitumor immunity. Therefore, we hypothesized that the combination of a model nonsteroidal anti-inflammatory drug--indomethacin and interleukin 12--would result in enhanced angiogenesis-dependent antitumor effects against a colon-26 carcinoma cells transplanted into syngeneic mice. As expected the combined administration of both agents simultaneously resulted in a strengthened antitumor activity that was manifested as a retardation of tumor growth and prolongation of mouse survival. Importantly some mice were completely cured after the combined treatment. As administration of interleukin 12 and indomethacin resulted in enhanced inhibition of angiogenesis it seems possible that prevention of new blood vessel formation is one of the mechanisms responsible for the observed antitumor effects.

Potentiated antitumor effects of interleukin 12 and matrix metalloproteinase inhibitor batimastat against B16F10 melanoma in mice

The application of antiangiogenic agents in cancer therapy has been studied extensively. Combination of agents with antiangiogenic properties could possibly enhance antitumor effects. Interleukin 12 is a cytokine with potent antitumor activity mediated also via antiangiogenic mechanisms. These effects are attributed to IFN-gamma production stimulated by IL-12. Since IFN-gamma has been reported to augment antitumor effects when combined with one of the metalloproteinase inhibitors--batimastat (BB-94), we have examined a combined treatment with IL-12 and BB-94 in a murine melanoma model. The administration of both agents showed potentiated antitumor activity. Furthermore, we have shown in a tumor-induced angiogenesis model that the combined application of IL-12 and batimastat inhibits the formation of new blood vessels to a greater extent than either agent alone. Our observations show that antiangiogenic effects are at least partly responsible for the enhanced antitumor effects of the combined treatment with IL-12 and BB-94.

The potentiated antileukemic effects of doxorubicin and interleukin-12 combination are not dependent on nitric oxide production

In our recent study we described a significant antileukemic efficacy of a combination therapy with interleukin-12 (IL-12) and doxorubicin (DOX) in the L1210 leukemia model. This therapeutic effect was abrogated by elimination of activated macrophages. Activated macrophages produce a variety of factors that can contribute to the elimination of tumor cells in vivo, including proteases, TNF, reactive oxygen intermediates, and nitric oxide (NO). Based on the results of previous reports, the contribution of NO in potentiated antileukemic effects of IL-12 + DOX combination seemed to be highly possible. Both DOX and IL-12 given alone increased the production of NO by peritoneal macrophages, however, macrophages derived from the mice treated with the combination of those agents produced significantly less NO than macrophages from IL-12-alone-treated mice. Production of NO by spleen macrophages after IL-12 + DOX treatment was higher than it was in controls, IL-12-alone or DOX-alone-treated groups. In serum, concentrations of NOx- in IL-12- or IL-12 + DOX-treated mice were significantly higher in comparison with controls, however not significantly different from each other. Addition of L-NAME treatment to the IL-12 + DOX therapy in leukemia-bearing mice did not significantly change the antileukemic efficacy of this therapy. Thus, our results indicate that the augmented antileukemic effects of IL-12 + DOX combination therapy in L1210 model are NO-independent. Therefore, further studies on the possible mechanisms of potentiated antileukemic activity of combination of IL-12 and DOX would be worth pursuing.

Effective chemo-immunotherapy of L1210 leukemia in vivo using interleukin-12 combined with doxorubicin but not with cyclophosphamide, paclitaxel or cisplatin

It has been well established that chemo-immunotherapy using cytotoxic drugs and appropriate cytokines offers a new approach to increasing the therapeutic index in the treatment of neoplastic diseases. This study investigates the efficacy of combinations of interleukin-12 with cyclophosphamide, paclitaxel, cisplatin or doxorubicin in the murine L1210 leukemia model. Mice inoculated i.p. with 1 x 10(3) or 1 x 10(5) leukemia cells were treated with interleukin-12 and/or chemotherapeutics, and were observed daily for survival. Immunosuppression with X-irradiation or macrophage depletion with injections of silica were used to examine the dependence of the therapeutic effects on the efficiency of the immune system. Treatment with interleukin-12 or one of the studied chemotherapeutics given alone resulted in moderate antileukemic effects. Combination of interleukin-12 with cyclophosphamide or paclitaxel produced no augmentation of anti-leukemic effects in comparison with these agents given alone. Combination of interleukin-12 with cisplatin resulted in prolongation of the survival time; however, in the experiment with mice inoculated with 1 x 10(5) leukemia cells, no long-term survivors (>60 days) were observed; on the contrary, combination of interleukin-12 with doxorubicin resulted in 100% long-term survivors. This effect was completely abrogated either by X-irradiation of mice or by macrophage depletion. We also found that doxorubicin augments IL-12-stimulated production of interferon-gamma in vivo. Our observations demonstrating potentiation of the antileukemic effects of the IL-12 and doxorubicin combination suggest that the combined use of these 2 agents could be beneficial in leukemia therapy.

Granulocyte colony-stimulating factor demonstrates antitumor activity in melanoma model in mice

Granulocyte colony-stimulating factor (G-CSF) was found to exert antitumor activity against murine MmB16 melanoma when administered intratumorally. However, subcutaneous administration of this cytokine at a site distant from the growing tumor did not show any antitumor effects. G-CSF did not influence the proliferative activity of MmB16 in vitro. Intraperitoneal administration of G-CSF resulted in decreased secretion of nitric oxide (NO) by peritoneal macrophages and their decreased tumoricidal activity against MmB16.

Potentiated antitumour effects of cisplatin and lovastatin against MmB16 melanoma in mice

Lovastatin, the drug used in the treatment of hypercholesterolaemia, has previously been reported to exert synergistic antitumour activity in a melanoma model in mice when used together with some immune response modifiers. In this study, we examined the antitumour effect of cisplatin augmented by its combined application with lovastatin, both in vitro and in vivo, in a murine melanoma model. The results of this study suggest that lovastatin may enhance the therapeutic effects of cisplatin in the treatment of malignant melanomas.

G-CSF prevents the suppression of bone marrow hematopoiesis induced by IL-12 and augments its antitumor activity in a melanoma model in mice

BACKGROUND

IL-12 has been successfully used in experimental tumor therapy. However, administration of this cytokine induces dose-dependent suppression of hematopoiesis that could potentially limit its use in clinical trials. We decided to examine whether the myelosuppressive activity of IL-12 could be corrected by the administration of G-CSF.

MATERIALS AND METHODS

In the initial experiments the influence of IL-12 and/or G-CSF on bone marrow and spleen GM-CFC was evaluated. To examine whether C-CSF could influence the antitumor activity of IL-12 the combination therapy with these agents was carried out starting on day seven following inoculation of melanoma MmB16 cells into the footpads of B6D2F1 mice. To obtain insight into the mechanism of the observed augmented antitumor activity of the combination therapy with IL-12 and G-CSF, the influence of these cytokines on macrophage activity (cytotoxicity and nitric oxide release) was analyzed.

RESULTS

In accord with our expectations, the application of G-CSF partially prevented the suppression of bone marrow myelopoiesis in IL-12 treated mice. Unexpectedly, G-CSF also showed potentiation of antitumor effects of IL-12 in this melanoma model. The augmented antitumor activity of combined IL-12/G-CSF immunotherapy could result from the enhanced stimulation of macrophage NO production and cytotoxicity.

CONCLUSION

The simultaneous administration of IL-12 and G-CSF partially prevented suppression of bone marrow myelopoiesis in IL-12-treated mice. Moreover, treatment with these cytokines also results in potentiated antitumor effects in a murine melanoma model.

Augmented antitumor effects of combination therapy with interleukin-12, cisplatin, and tumor necrosis factor-alpha in a murine melanoma model

Interleukin-12 (IL-12) has demonstrated antitumor activity in many murine tumor models. However, toxic effects resulting from treatment with IL-12 have been also described. Combining IL-12 with other antineoplastic agents could potentiate its antitumor efficacy and, furthermore, could minimize its toxicity by reducing the doses necessary to achieve the antitumor activity. We examined in a murine melanoma model the efficacy of combination tumor chemo-immunotherapy based on administration of IL-12, cisplatin (CDDP), and tumor necrosis factor-alpha (TNF-alpha). In the current study pairs of: IL-12 + CDDP and IL-12 + TNF-alpha, showed stronger antitumor activity than either agent given alone. Furthermore, combination tumor therapy with IL-12 + CDDP + TNF-alpha was more effective at retarding local tumor growth than either IL-12 + CDDP, IL-12 + TNF-alpha or CDDP + TNF-alpha combination therapies. Our observations indicate that combining of CDDP with IL-12 and IL-12 with TNF-alpha as well as using the triple combination of CDDP, IL-12 and TNF-alpha could be beneficial in tumor therapy.

Potentiation of the anti-tumor effect of actinomycin D by tumor necrosis factor alpha in mice: correlation between in vitro and in vivo results

The anti-tumor effects of actinomycin D (Act D) and recombinant human tumor necrosis factor (TNF)-alpha have been studied on 4 established murine tumor cell lines: MmB16 melanoma, Lewis lung (LL/2) carcinoma, L1 sarcoma and L1210 leukemia. During short-term incubation (24 hr) Act D produced dose-dependent cytostatic/cytotoxic effects against MmB16, LL/2 and L1 tumor cells but did not reduce the viability of these cells even at high concentration (10 micrograms/ml), below a threshold of 30-60%. However, L1210 leukemic cells were highly susceptible to Act D, and no viable cells were detected in cultures incubated with 1 microgram/ml of Act D. TNF-alpha alone, when used under the same culture conditions, had only a negligible effect on all cell lines tested. However, the combination of this cytokine with Act D produced synergistic cytotoxic effects against MmB16, LL/2 and L1 cells but not against L1210 leukemia cells. In an in vivo model of regional therapy in which tumor-bearing mice were treated with Act D and TNF-alpha, a correlation with in vitro results was observed. In mice bearing MmB16 melanoma, LL/2 carcinoma and L1 sarcoma, the most potent anti-tumor effects were observed in mice treated with Act D and TNF-alpha together. This treatment led to a delay of tumor growth and induced complete tumor regression in some cases. On the contrary, TNF-alpha did not enhance the effect of Act D in mice injected with L1210 leukemia cells. Our results show that TNF-alpha can potentiate the anti-tumor effects of Act D against tumors weakly susceptible to Act D and may be a useful adjuvant to chemotherapy in the local treatment of neoplasia.

Potentiation of antitumor effects of tumor necrosis factor alpha and interferon gamma by macrophage-colony-stimulating factor in a MmB16 melanoma model in mice

The efficacy of systemic infusion of recombinant human macrophage-colony-stimulating factor (M-CSF) in combination with local treatment with human recombinant tumor necrosis factor (TNF) alpha and mouse recombinant interferon (IFN) gamma was studied in vivo on a subclone of B16 melanoma (MmB16) in mice. Short-term intravenous administration of M-CSF at a dose of 10(6) units daily had no antitumor effect in vivo. Similarly, local treatment of tumor with TNF alpha (5 micrograms daily) did not produce any therapeutic effect. However, simultaneous administration of the same dose of TNF alpha with IFN gamma (1000 units daily) resulted in a synergistic effects manifested by the retardation of tumor growth. Addition of systemic infusion of M-CSF to the local therapy with TNF alpha and IFN gamma induced further augmentation of antitumor efficacy and delayed progression of MmB16 melanoma. The strengthened antitumor effect of combination therapy including M-CSF, TNF alpha and IFN gamma was most probably due to the increased release of monocytes from the bone marrow, their recruitment into the site of tumor growth and subsequent local stimulation of their antitumor activity.