Immunotherapy for lung metastases of murine renal cell carcinoma: synergy between radiation and cytokine-producing tumor vaccines.

We investigated the combination therapy of local radiation of lung metastasis and vaccination with autologous tumor cells that produced interleukin (IL)-2, interferon-gamma (IFN-gamma), and granulocyte-macrophage colony-stimulating factor (GM-CSF) using the mouse Renca pulmonary metastasis model. Wild-type Renca (W/Renca) were transfected with pEF-BOS vector incorporating cDNAs for IL-2, IFN-gamma, or GM-CSF to express these cytokines. W/Renca, IL-2-producing Renca (Renca/IL-2), and IFN-gamma-producing Renca (Renca/IFN-gamma) produced subcutaneous tumor at the injection site in eight of eight, one of eight, and two of eight mice, respectively. No tumors were found in the GM-CSF-producing Renca (Renca/GM-CSF) group (zero of eight). Renca/IFN-gamma produced subcutaneous (s.c.) tumors in all Balb/c nude mice, but Renca/IL-2 and Renca/GM-CSF did not. To test the elicitation of antitumor activity, Balb/c mice were injected intravenously with 1 x 10(5) W/Renca on day 0, vaccinated, s.c., with 1 x 10(6) cells each of 5,000 rad preirradiated Renca/IL-2, Renca/IFN-gamma, and Renca/GM-CSF or 3 x 10(6) cells of preirradiated W/Renca on days 1, 7, and 14, and radiated with 300 rad to both lungs on day 5. The animals were killed on day 21 and tumor nodules in the lungs were enumerated. Neither local irradiation alone nor the combination of lung radiation and multiple vaccination with irradiated W/Renca significantly reduced the number of lung tumors. In contrast, the combination of lung radiation and the multiple vaccinations with cytokine-producing Renca cells significantly reduced the number of lung tumors. This regimen was more effective than the multiple vaccinations with cytokine-producing Renca cells alone. These studies demonstrate the efficacy of vaccination with autologous tumor cells expressing these cytokines and sensitization of the tumor target with radiation.     

Combination of interleukin 12 and interferon alpha gene therapy induces a synergistic antitumor response against colon and renal cell carcinoma

The antitumor effect and mechanism of action of IL-12 gene therapy combined with IFN-alpha gene therapy were investigated in tumor-bearing mice using renal and colon carcinoma models, Renca and CT26, respectively. Tumors were treated with murine IL-12 plasmid alone or in combination with IFN-alpha plasmid formulated with a polymeric interactive noncondensing (PINC) gene delivery system. Intratumoral injection of IL-12 DNA/polyvinyl pyrrolidone (PVP) alone induced rejection of 58 and 17% of Renca and CT26 tumors, respectively, whereas 25% (Renca) and 0% (CT26) rejection was observed in mice treated with IFN-alpha plasmid/PVP. Combination gene therapy of formulated plasmids, IL-12 with IFN-alpha, synergistically increased the antitumor response against Renca (100% tumor rejection) and CT26 (50%). In vivo depletion of leukocyte subsets indicated that CD8(+) T and NK cells were the primary effectors of the antitumor response induced by the combined cytokine gene therapy. Moreover, mice that rejected the primary tumors after combined treatment with IL-12 and IFN-alpha plasmid formulation developed protective immunity against a subsequent tumor challenge. Analysis of tumor-infiltrating leukocytes from mice treated with the combined IL-12 and IFN-alpha gene therapy showed upregulation of CD40 molecules on antigen-presenting cells (Mac-1(hi) cells). Finally, levels of mRNA for the chemokines IP-10 and TCA-3 were higher in tumors treated with the combination of cytokine plasmids than in tumors treated with either cytokine gene alone. These data provide evidence that IL12 gene therapy combined with IFN-alpha gene therapy synergistically induces regression of established tumors and may represent a novel therapeutic strategy for cancer treatment.     

Antitumor effect on murine renal cell carcinoma by autologous tumor vaccines genetically modified with granulocyte-macrophage colony-stimulating factor and interleukin-6 cells

The authors evaluted the efficacy of vaccination with murine renal cell carcinoma (Renca) secreting the granulocyte-macrophage colony-stimulating factor (GM-CSF) gene and interleukin-6 (IL-6) gene for the treatment of Renca tumor. Murine GM-CSF and murine IL-6 genes were introduced and expressed in Renca cells (Renca-GM-CSF and Renca-IL-6). For a prevaccination study, wild-type Renca cells were injected subcutaneously into Balb/c mice that had been vaccinated three times with inactivated wild-type Renca, Renca-GM-CSF, Renca-IL-6, or a mixture of Renca-GM-CSF and Renca-IL-6 cells 7, 14, and 21 days before this tumor inoculation. For vaccination experiments, Renca tumor-bearing (8 to 10 mm) mice were injected subcutaneously weekly for 3 weeks with inactivated wild-type Renca cells, or either one or a combination of Renca-GM-CSF and Renca-IL-6. A nonvaccinated control was included in all experiments. The animals were monitored for survival and tumor development for 8 weeks. Mice inoculated with wild-type Renca alone died from the tumor within 35 days. Renca-IL-6 grew slower than wild-type Renca (p < 0.05). No tumor was produced by Renca-GM-CSF. Prevaccination with the combination of Renca-GM-CSF and Renca-IL-6 prevented subsequently inoculated wild-type Renca from forming tumors, and prevaccination with either one of them, compared with prevaccination with wild-type Renca, retarded tumor growth and prolonged survival time. Tumor-bearing mice vaccinated with wild-type Renca died within 42 days. Vaccination with Renca-GM-CSF or Renca-IL-6 alone prolonged the survival time, but only Renca-GM-CSF drastically reduced the tumor size. Vaccination with the combination of them achieved complete remission. Neither of the cytokine-secreting cells enhanced the expression of MHC class I or II molecules. Autologous tumor cell vaccine secreting GM-CSF is effective in preventing and treating established tumors. Its efficacy is enhanced by the cosecretion of IL-6.     

Cancer Immunotherapy Using a Membrane-bound Interleukin-12 With B7-1 Transmembrane and Cytoplasmic Domains

Interleukin-12 (IL-12) has potent antitumor activity, but its clinical application is limited by severe systemic toxicity, which might be alleviated by the use of membrane-anchored IL-12. In the present study, a new membrane-bound IL-12 containing murine single-chain IL-12 and B7-1 transmembrane and cytoplasmic domains (scIL-12-B7TM) was constructed and its efficacy in cancer treatment examined and its protective antitumor mechanism investigated. Surface expression of scIL-12-B7TM on colon adenocarcinoma cells significantly inhibited the growth of subcutaneous tumors, suppressed lung metastasis, and resulted in local and systemic suppression of unmodified tumors. Intratumoral injection of an adenoviral vector encoding scIL-12-B7TM not only resulted in complete regression of a majority of local tumors, but also significantly suppressed the growth of distant, untreated tumors. Moreover, mice that had been treated with scIL-12-B7TM developed memory responses against subsequent tumor challenge. Immunohistochemical staining and in vivo depletion of lymphocyte subpopulations demonstrated that both CD8⁺ T cells and CD4⁺ T cells contributed to the antitumor activity of scIL-12-B7TM. Importantly, the potent antitumor activities of scIL-12-B7TM were achieved with only negligible amounts of IL-12 in the circulation. Our data demonstrate that cancer immunotherapy using membrane-bound IL-12 has the advantage of minimizing systemic IL-12 levels without compromising its antitumor efficacy.     

Intratumoral injection of interleukin-12 plasmid DNA,either naked or in complex with cationic lipid,results in similar tumor regression in a murine model

Effective eradication of established tumors and generation of a lasting systemic immune response is an important goal for cancer gene immunotherapy. The method of gene delivery may also be critical for the generation of an effective antitumor response. We compared the level of transgene expression and antitumor activity of two different interleukin (IL)-12 DNA preparations (naked DNA versus DNA lipid complex). Established murine adenocarcinoma (CT26) and renal cell carcinoma (Renca) tumors in BALB/c mice were treated by direct intratumoral injection of a nonviral plasmid DNA vector encoding the murine IL-12 (mIL-12) gene, either alone (naked) or in complexes with cationic lipid. Both treatments resulted in the same percentage (87%) of mice undergoing a complete tumor regression of the CT26 tumor. For the Renca tumor model, complete tumor regression was observed in 67 and 75% of animals treated with naked mIL-12 DNA and mIL-12 DNA plus lipid, respectively. Mice that were rendered tumor free for > 50 days by mIL-12 gene therapy rejected a subsequent challenge of parental tumor cells but not of an unrelated, syngeneic tumor. The marked reduction of tumor growth in tumor-bearing mice treated with mIL-12 cDNA was associated with the augmentation of tumor-specific cytotoxic T cells, enhanced production of IFN-gamma in spleen and lymph node cells, and increased splenomegaly and lymphadenopathy. The CD8+: CD4+ ratio in tumor-infiltrating lymphocytes was significantly increased in the tumor-bearing mice treated with mIL-12 DNA alone and mIL-12 cDNA plus lipid as compared with a control vector-treated group. These results indicate that direct intratumoral gene transfer with naked nonviral IL-12 DNA provides an effective and simple method for the treatment of murine tumors, suggesting an approach for clinical application.     

Intratumoral dendritic cell vaccination elicits potent tumoricidal immunity against malignant glioma in rats

Dendritic cells (DC) are attractive candidates for innovative cancer immunotherapy by virtue of their ability to function as powerful antigen presenting cells and elicit potent antitumor cytotoxic immune responses. With the aim of generating antitumor immunity, the authors sought to enhance in vivo tumor antigen presentation by using an intratumoral DC vaccination strategy in the setting of partially irradiated intracranial brain tumors. Fisher rats, implanted with 9L gliomas in the right corpus striatum, were treated with freshly cultured, unpulsed syngeneic DC inoculated directly into the tumor bed. Intracranially inoculated DCs were found to drain to ipsilateral deep cervical lymph nodes. This was associated with increased local and systemic antitumor cytoxicity, as evidenced by robust infiltration of treated tumors with CD4 and CD8 T cells as well as by increased IFN-gamma protein and message levels in in vitro restimulated splenic lymphocytes. DC therapy resulted in prolonged survival and immunity to subsequent intracranial tumor re-challenge. These results demonstrate the viability of intratumoral DC vaccination as an effective therapeutic strategy for intracranial glioma.     

Intratumoral delivery of IL-12 gene by polyvinyl polymeric vector system to murine renal and colon carcinoma results in potent antitumor immunity.

We have utilized a nonviral, polymeric interactive non-condensing (PINC) gene delivery system to deliver IL-12 to two different types of murine tumors, an immunogenic renal cell carcinoma, Renca, and a non-immunogenic colon cell carcinoma, CT26. The delivery of IL-12/polyvinyl pyrrolidone (PVP) complexes into Renca led to the expression of IL-12 (146 +/- 89 pg/mg) and IFN-gamma (160 +/- 82 pg/mg) from explanted tumors in culture supernatants. Treated tumors showed increased infiltration of NK, CD4+ and CD8+ T cells and up-regulation of MHC class I molecules on leukocytes in both tumors and lymph nodes. Fifty per cent of tumor-bearing mice rejected Renca or CT26 tumors following IL-12/PVP treatments given at optimal doses of 24 and 48 micrograms, respectively. While polymorphonuclear cells (PMNs) were partially involved in the development of the antitumor immune response elicited by IL-12/PVP treatment, CD8+ T cells were found to be the primary effectors. In contrast, CD4+ T cells did not appear to play a significant role in the development of tumor specific immunity. Finally, mice that rejected the tumors following IL-12/PVP treatment were protected against a second challenge with the same tumor. These data provide evidence that a nonviral IL-12 gene delivery system is well tolerated and generates a potent immune response against established tumors.     

Radiation-inducible Immunotherapy for Cancer: Senescent Tumor Cells as a Cancer Vaccine

Radiotherapy offers an effective treatment for advanced cancer but local and distant failures remain a significant challenge. Here, we treated melanoma and pancreatic carcinoma in syngeneic mice with ionizing radiation (IR) combined with the poly(ADP-ribose) polymerase inhibitor (PARPi) veliparib to inhibit DNA repair and promote accelerated senescence. Based on prior work implicating cytotoxic T lymphocytes (CTLs) as key mediators of radiation effects, we discovered that senescent tumor cells induced by radiation and veliparib express immunostimulatory cytokines to activate CTLs that mediate an effective antitumor response. When these senescent tumor cells were injected into tumor-bearing mice, an antitumor CTL response was induced which potentiated the effects of radiation, resulting in elimination of established tumors. Applied to human cancers, radiation-inducible immunotherapy may enhance radiotherapy responses to prevent local recurrence and distant metastasis.     

Intravenous cytokine gene delivery by lipid-DNA complexes controls the growth of established lung metastases

Local expression of cytokine genes by ex vivo transfection or intratumoral gene delivery can control the growth of cutaneous tumors. However, control of tumor metastases by conventional nonviral gene therapy approaches is more difficult. Intravenous injection of lipid-DNA complexes containing noncoding plasmid DNA can significantly inhibit the growth of early metastatic lung tumors. Therefore, we hypothesized that delivery of a cytokine gene by lipid-plasmid DNA complexes could induce even greater antitumor activity in mice with established lung metastases. The effectiveness of treatment with lipid-DNA complexes containing the IL-2 or IL-12 gene was compared with the effectiveness of treatment with complexes containing noncoding (empty vector) DNA. Treatment effects were evaluated in mice with either early (day 3) or late (day 6) established lung tumors. Lung tumor burdens and local intrapulmonary immune responses were assessed. Treatment with either noncoding plasmid DNA or with the IL-2 or IL-12 gene significantly inhibited the growth of early tumors. However, only treatment with the IL-2 or IL-12 gene induced a significant reduction in lung tumor burden in mice with more advanced metastases. Furthermore, the reduction in tumor burden was substantially greater than that achieved by treatment with recombinant cytokines. Treatment with the IL-2 or IL-12 gene was accompanied by increased numbers of NK cells and CD8+ T cells within lung tissues, increased cytotoxic activity, and increased local production of IFN-gamma by lung tissues, compared with treatment with noncoding DNA. Thus, cytokine gene delivery to the lungs by means of intravenously administered lipid-DNA complexes may be an effective method of controlling lung tumor metastases.     

Inhibition of interleukin-8 reduces tumorigenesis of human non-small cell lung cancer in SCID mice.

The salient feature of solid tumor growth is the strict dependence on local angiogenesis. We have previously demonstrated that IL-8 is an angiogenic factor present in freshly isolated specimens of human non-small cell lung cancer (NSCLC). Using a model of human NSCLC tumorigenesis in SCID mice, we now report that IL-8 acts as a promoter of human NSCLC tumor growth through its angiogenic properties. Passive immunization with neutralizing antibodies to IL-8 resulted in more than 40% reduction in tumor size and was associated with a decline in tumor-associated vascular density and angiogenic activity. IL-8 did not act as an autocrine growth factor for NSCLC proliferation. The reduction in primary tumor size in response to neutralizing antibodies to IL-8 was also accompanied by a trend toward a decrease in spontaneous metastasis to the lung. These data support the notion that IL-8 plays a significant role in mediating angiogenic activity during tumorigenesis of human NSCLC, thereby offering a potential target for immunotherapy against solid tumors.     

Augmentation of local antitumor immunity in the liver by tumor vaccine modified to secrete murine interleukin 12.

Minimal residual lesions have been a major problem in surgical management of cancer. We transfected M5076 with murine IL-12 gene by a retroviral vector, established a stable transfectant secreting IL-12 and investigated its antitumor effects on a spontaneous liver metastasis murine model of M5076 reticulum cell sarcoma. Subcutaneous vaccination of the irradiated transfectant into the remote skin following the amputation of the tumor-bearing limb improved survival when compared with the vaccination of irradiated parental cells (control). Cytotoxic activities against parental M5076 were significantly stronger in the hepatic lymphocytes from the mice vaccinated with the IL-12 transfectant than those from the control. IFN-gamma production of hepatic lymphocytes when they were cocultured with the parental cells was significantly augmented in mice vaccinated with the IL-12 transfectant compared with the control. On the other hand, both cytotoxic activity and IFN-gamma production of spleen cells in the M5076-vaccinated and transfectant-vaccinated mice were at similar levels. Immunophenotypic analysis revealed the selective increase of CD3+NK1+ population in the liver from the transfectant-vaccinated mice. These results suggest that tumor vaccines genetically modified to secrete IL-12 continuously at a relatively low level preferentially augment local antitumor activity in the liver rather than systemic immune responses. This strategy warrants further investigation as an adjuvant modality in the management of postoperative residual tumors.     

Interleukin-18 inhibits osteolytic bone metastasis by human lung cancer cells possibly through suppression of osteoclastic bone-resorption in nude mice

Interleukin (IL)-18 exhibits antitumor as well as antiosteoclastogenic activities. These findings suggest that IL-18 is a potential tool for the treatment of cancers with associated osteolytic bone metastasis. We have previously shown that systemic daily administration of recombinant (r) IL-18 inhibits the development of osteolytic bone metastasis by human breast cancer cells. Here we demonstrate that systemic daily administration of rIL-18 (1 microg/mouse/d) for 21 days significantly inhibited the number and the total area of osteolytic bone metastasis by RWGT2 human lung cancer cells in nude mice. No severe adverse effects were observed. Natural killer (NK) cells did not increase in splenocytes from rIL-18-treated mice, and the in vitro NK activity of splenocytes against RWGT2 cells was only weakly enhanced in the presence of IL-18. The administration of rIL-18 made no difference in the growth of subcutaneous tumors, histologic indices (mitotic index, apoptotic index, and Ki-67-labeling index) of subcutaneous tumors or metastatic bone foci, or in the number of osteoclasts along the bone surface adjacent to tumors. Moreover, serum levels of cytokines including interferon-gamma, IL-1alpha, IL-6, tumor necrosis factor-alpha, and granulocyte/macrophage colony-stimulating factor, which regulate bone-resorbing activity of osteoclasts, were evaluated. Among them, IL-6 was remarkably downregulated in rIL-18-treated mice. These findings suggest that IL-18 inhibits osteolytic bone metastasis possibly through suppression of osteoclastic bone-resorption mediated in part by IL-6.     

Antitumor and antimetastatic activity of interleukin 12 against murine tumors

It has recently been demonstrated that in vivo administration of murine interleukin 12 (IL-12) to mice results in augmentation of cytotoxic natural killer (NK)/lymphocyte-activated killer cell activity, enhancement of cytolytic T cell generation, and induction of interferon gamma secretion. In this study, the in vivo activity of murine IL-12 against a number of murine tumors has been evaluated. Experimental pulmonary metastases or subcutaneous growth of the B16F10 melanoma were markedly reduced in mice treated intraperitoneally with IL-12, resulting in an increase in survival time. The therapeutic effectiveness of IL-12 was dose dependent and treatment of subcutaneous tumors could be initiated up to 14 d after injection of tumor cells. Likewise, established experimental hepatic metastases and established subcutaneous M5076 reticulum cell sarcoma and Renca renal cell adenocarcinoma tumors were effectively treated by IL-12 at doses which resulted in no gross toxicity. Local peritumoral injection of IL-12 into established subcutaneous Renca tumors resulted in regression and complete disappearance of these tumors. IL-12 was as effective in NK cell-deficient beige mice or in mice depleted of NK cell activity by treatment with antiasialo GM1, suggesting that NK cells are not the primary cell type mediating the antitumor effects of this cytokine. However, the efficacy of IL-12 was greatly reduced in nude mice suggesting the involvement of T cells. Furthermore, depletion of CD8+ but not CD4+ T cells significantly reduced the efficacy of IL-12. These results demonstrate that IL-12 has potent in vivo antitumor and antimetastatic effects against murine tumors and demonstrate as well the critical role of CD8+ T cells in mediating the antitumor effects against subcutaneous tumors.     

AV.TK-mediated killing of subcutaneous tumors in situ results in effective immunization against established secondary intracranial tumor deposits

Gene transfer vectors expressing herpes simplex thymidine kinase (HSVtk), in addition to direct killing of tumor cells, often have an associated local "bystander effect" mediated by metabolic coupling of tumor cells. A systemic antitumor effect mediated by the immune system, termed the distant bystander effect, has also been reported. We have observed the development of cytotoxic T-lymphocyte (CTL) populations and long-lasting antitumor immunity following treatment of subcutaneous tumors with an adenoviral vector expressing HSVtk (AV.TK) and ganciclovir (GCV) in rat glioma model. This vaccination effect seen with AV.TK/GCV treatment of subcutaneous tumor could even abrogate or retard growth of previously established secondary intracranial tumors.     

Interleukin 12 gene transfer into skin distant from the tumor site elicits antimetastatic effects equivalent to local gene transfer

We have reported that particle-mediated interleukin 12 (IL-12) gene transfer into the skin overlying the local tumor inhibits systemic metastases. To further characterize this effect, we compared the antitumor and antimetastatic effects of IL-12 cDNA delivered at the local tumor site versus at a site distant from the primary tumor, in a spontaneous metastasis model of LLC-F5 tumor. Local IL-12 gene delivery into the skin overlying the intradermal tumor (local IL-12 treatment) on days 7, 9, and 11 after tumor implantation resulted in the most suppression of the growth of the primary LLC-F5 tumor, whereas IL-12 gene transfer into the skin distant from the tumor (distant IL-12 treatment) was less effective. In contrast, both local IL-12 and distant IL-12 treatment, followed by tumor excision, inhibited lung metastases to a similar extent, resulting in significantly extended survival of test mice. The results of in vivo studies using depleting anti-asialo GM1 antibody and anti-CD4/anti-CD8 monoclonal antibodies, or neutralizing anti-interferon gamma (IFN-gamma) monoclonal antibody demonstrated that natural killer (NK) cells, CD8(+) T cells, and IFN-gamma contributed to the antimetastatic effects in both treatment groups. Furthermore, the levels of mRNA expression of vascular endothelial growth factor and matrix methalloproteinase 9 at the tumor microenvironment were suppressed after both local and distant IL-12 treatment. These results suggest that the current particle-mediated IL-12 gene delivery in the spontaneous LLC-F5 metastasis model can confer antimetastatic activities, irrespective of the gene transfection site, via a combination of several mechanisms involving CD8(+) T cells, NK cells, IFN-gamma, and antiangiogenesis.     

LPD lipopolyplex initiates a potent cytokine response and inhibits tumor growth

Our laboratory has recently developed a lipopolyplex consisting of DOTAP:cholesterol liposomes, protamine sulfate, and plasmid DNA (LPD) that provides improved systemic gene delivery compared with lipoplex following tail vein injection in mice. Because endothelial cells are the primary cells transfected in the lung, it was hypothesized that LPD might be an effective vector for gene therapy of pulmonary metastases. This hypothesis was examined by testing the efficacy of cytokine (IL-12) and tumor suppressor (p53) strategies for treatment of an experimental model of pulmonary metastasis in C57Bl/6 mice. Surprisingly, all LPD complexes including those containing an 'empty' plasmid provided a potent (>50% inhibition) and dose-dependent antitumor effect, compared with dextrose-treated controls. In addition, i.v. injections of LPD containing 'empty' plasmid also inhibited tumor growth in a subcutaneous model of C3 fibrosarcomma. The antitumor effect correlated well with a strong and rapid proinflammatory cytokine (TNF-alpha, IL-12 and IFN-gamma) response. Naked plasmid DNA did not elicit a cytokine response and the response required assembly of DNA into a lipoplex or the LPD lipopolyplex. Except for the heart, elevated levels of cytokine were observed in all organs (lung, liver, kidney and spleen) where LPD is known to have gene transfer activity. Methylation of immune-stimulatory CpG motifs in the plasmid component of LPD inhibited the proinflammatory cytokine response as well as the antitumor effect of LPD in both tumor systems. This suggests that i. v. administration of LPD elicits a systemic proinflammatory cytokine response that mediates the antitumor activity of the lipopolyplex. In addition, the antitumor activity was not observed in SCID mice suggesting a possible role for B or T lymphocytes in the antitumor response initiated by LPD. This represents the first demonstration that an intravenously administered cationic liposome-based nonviral vector can promote a systemic, Th1-like innate immune response. The immune adjuvant properties of LPD might prove to be suitable for delivering tumor-specific antigens in the context of DNA vaccination.     

IL-6 trans-signaling licenses mouse and human tumor microvascular gateways for trafficking of cytotoxic T cells

Immune cells are key regulators of neoplastic progression, which is often mediated through their release of cytokines. Inflammatory cytokines such as IL-6 exert tumor-promoting activities by driving growth and survival of neoplastic cells. However, whether these cytokines also have a role in recruiting mediators of adaptive anticancer immunity has not been investigated. Here, we report that homeostatic trafficking of tumor-reactive CD8+ T cells across microvascular checkpoints is limited in tumors despite the presence of inflammatory cytokines. Intravital imaging in tumor-bearing mice revealed that systemic thermal therapy (core temperature elevated to 39.5°C ± 0.5°C for 6 hours) activated an IL-6 trans-signaling program in the tumor blood vessels that modified the vasculature such that it could support enhanced trafficking of CD8+ effector/memory T cells (Tems) into tumors. A concomitant decrease in tumor infiltration by Tregs during systemic thermal therapy resulted in substantial enhancement of Tem/Treg ratios. Mechanistically, IL-6 produced by nonhematopoietic stromal cells acted cooperatively with soluble IL-6 receptor-α and thermally induced gp130 to promote E/P-selectin- and ICAM-1-dependent extravasation of cytotoxic T cells in tumors. Parallel increases in vascular adhesion were induced by IL-6/soluble IL-6 receptor-α fusion protein in mouse tumors and patient tumor explants. Finally, a causal link was established between IL-6-dependent licensing of tumor vessels for Tem trafficking and apoptosis of tumor targets. These findings suggest that the unique IL-6-rich tumor microenvironment can be exploited to create a therapeutic window to boost T cell-mediated antitumor immunity and immunotherapy.     

Dendritic cell therapy with interferon-alpha synergistically suppresses outgrowth of established tumors in a murine colorectal cancer model

Both dendritic cell (DC)-based immunotherapy and interferon (IFN)-alpha therapy have been proved to have potent long-lasting antitumor effects. In anticipation of synergistic antitumor effects, we performed combination therapy with DCs and IFN-alpha gene-transduced murine colorectal cancer MC38 cells (MC38-IFN-alpha). DCs incubated with MC38-IFN-alpha, but not neomycin-resistance gene-transduced MC38 cells (MC38-Neo), effectively enhanced proliferation of allogeneic splenocytes in vitro. In 12 of 17 mice, DCs in combination with MC38-IFN-alpha prevented the development of a parental tumor, while DCs and MC38-Neo did in only three of 17 mice (P=0.008). In a therapeutic model of an established parental tumor, inoculation of DCs and MC38-IFN-alpha suppressed the growth of the established parental tumors significantly compared with the administration of DCs with MC38-Neo or naive splenocytes with MC38-IFN-alpha (P=0.016 and 0.024, respectively). Analyses of immunohistochemistry and tumor-infiltrating mononuclear cells showed that CD8(+), CD11c(+), and NK1.1(+) cells markedly infiltrated the established tumors of mice treated with DCs and MC38-IFN-alpha. From the results of observation of parental tumor outgrowth in immune cell-depleted mice, CD8(+) cells, and asialo-GM-1(+) cells were thought to contribute to the antitumor effects induced by the combination therapy. Furthermore, MC38-specific cytolysis was detected when splenocytes of mice inoculated with DCs and MC38-IFN-alpha cells were stimulated with MC38-IFN-alpha cells in vitro. Since DC-based immunotherapy in combination with IFN-alpha-expressing tumor cells induces potent antitumor cellular immune responses, it should be considered for clinical application.     

Interleukin-7 gene-modified dendritic cells reduce pulmonary tumor burden in spontaneous murine bronchoalveolar cell carcinoma

The antitumor efficiency of dendritic cells transduced with an adenovirus vector expressing interleukin (IL)-7 (DC-AdIL-7) was evaluated in a murine model of spontaneous bronchoalveolar cell carcinoma. These transgenic mice (CC-10 TAg), expressing the SV40 large T antigen under the Clara cell promoter, develop bilateral multifocal pulmonary adenocarcinomas and die at 4 months as a result of progressive pulmonary tumor burden. Injection of DC-AdIL-7 in the axillary lymph node region (ALNR) weekly for 3 weeks led to a marked reduction in tumor burden with extensive lymphocytic infiltration of the tumors and enhanced survival. The antitumor responses were accompanied by the enhanced elaboration of interferon (IFN)-gamma and IL-12 as well as an increase in the antiangiogenic chemokines, IFN-gamma-inducible protein 10 (IP-10/CXCL10) and monokine induced by IFN-gamma (MIG/CXCL9). In contrast, production of the immunosuppressive mediators IL-10, transforming growth factor (TGF)-beta, prostaglandin E(2) (PGE(2)), and the proangiogenic modulator vascular endothelial growth factor (VEGF) decreased in response to DC-AdIL-7 treatment. Significant reduction in tumor burden in a model in which tumors develop in an organ-specific manner provides a strong rationale for further evaluation of DC-AdIL-7 in regulation of tumor immunity and its use in lung cancer genetic immunotherapy.