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A Pathogenic Role of Th2 Cells and Their Cytokine Products on the Pulmonary Metastasis of Murine B16 Melanoma

Division of Infectious Diseases, Department of Internal Medicine, The University of Texas Medical Branch, Galveston, TX 77555

	Abstract

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The role of Th2 cells and the cytokines produced by these cells on experimental pulmonary metastasis of B16 melanoma was investigated in a murine model implanted with high metastatic (B16F10) or low metastatic (B16F1) melanoma cells. An average of 250 colonies of metastasis in the lungs was counted in mice (BF10 mice) at 14 days after the inoculation of 2 x 10⁵ B16F10 cells/mouse, while <20 colonies were detected in mice (BF1 mice) inoculated with the same number of B16F1 cells. CD4⁺CD11b⁺TCR-ß⁺ T cells (BF10-Th2 cells) were produced in the spleens of BF10 mice, while these cells were not detected in BF1 mice. The BF10-Th2 cells produced IL-4 and IL-10 into culture fluids when stimulated in vitro with anti-CD3 mAb. However, IL-2 and IFN- were not produced. The level of a pulmonary metastasis in BF1 mice increased to the level observed in BF10 mice, when BF10-Th2 cells were adoptively transferred to BF1 mice. Also, an increase in the number of pulmonary melanoma was demonstrated in BF1 mice treated with 10 µg/kg murine rIL-4. The level of pulmonary metastasis in BF10 mice or in BF1 mice inoculated with BF10-Th2 cells decreased to the level observed in BF1 mice when mice were treated with an anti-IL-4 mAb at a dose of 250 µg/kg on days 1, 3, and 5 after tumor inoculation. These results suggest that the severity of pulmonary metastasis in mice receiving B16 melanoma cells is strongly influenced by the IL-4 released from tumor-associated Th2 cells.

	Introduction

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The contribution of suppressed cell-mediated immunity, which includes decreased functionality of antitumor effector cells (activated macrophages, NK cells, lymphokine-activated killer cells, and tumor-specific cytotoxic T cells), on accelerating tumor metastasis has been described previously (1, 2, 3, 4, 5, 6, 7, 8, 9, 10). Soluble tumor Ags (4), formation of circulating immune complexes (5), and immunosuppressive cytokines, such as TGF-ß and IL-10 production by tumor cells (6, 7, 8, 9), have been shown to influence the tumor-associated suppression of cell-mediated immunity. Immunosuppressive soluble factors, such as ₂-acid glycoprotein and 1-methyladenosine produced by either the host’s immunocompetent cells or tumor cells, have also been shown to be involved in tumor-related immunosuppression (11). Type 1 T cell responses enhance cellular immune responses associated with increased levels of type 1 cytokines (IL-2 and IFN-) and the generation of CTL (a typical effector cell of type 1 T cell responses). In most instances, antitumor immunity is produced by the activation of type 1 T cell responses (12, 13). Therefore, the suppression of type 1 T cell responses can result in the acceleration of tumor growth. Type 1 T cell responses are often suppressed by T helper type 2 cells (Th2 cells) that can be demonstrated in tumor-bearing mice (14, 15, 16). Type 2 cytokines (IL-4 and IL-10) released from type 2 T cells are inhibitors of type 1 T cell responses (14, 15, 16). Also, the effector cell activity of type 1 T cells and the production of type 1 cytokines (IFN-, IL-2) by type 1 T cells have been shown to be suppressed by type 2 cytokines (14, 15, 16). This suggests the possibility that a contributor to the decreased effectiveness of immunotherapy in patients with malignancies might be associated with the activity of type 2 cytokines released from tumor-associated type 2 T cells. In the present study, the role of IL-4 and/or tumor-associated Th2 cells on tumor metastasis was investigated in mice inoculated with B16 melanoma cells of either high (B16F10 melanoma cells) or low (B16F1 melanoma cells) metastatic characteristics. Poste and Nicolson (17) have described the metastatic characteristics of B16F10 cells and B16F1 cells in the lung capillary beds of mice. In their article, B16F10 cells had 114 ± 24 pulmonary metastases when they were inoculated into C57BL/6 mice at a inoculum size of 5 x 10⁴ cells/mouse. However, only 16 ± 7 pulmonary metastases were produced when C57BL/6 mice were inoculated with the same number of B16F1 cells. Additional points that distinguish differences between high metastatic B16F10 cells and low metastatic B16F1 cells are: generation speed (18); i.v. collagenase production (19); adherence to poly(hydroxyethylmethacrylate)-coated plates (20); membrane-bound protein kinase levels (21); antigenic properties (22).

	Materials and Methods

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Animals

Eight-week-old C57BL/6 mice (The Jackson Laboratory, Bar Harbor, ME) were used in these experiments. All experiments were approved by the Animal Care and Use Committee (ACUC) of the University of Texas Medical Branch at Galveston (ACUC approval number, 89-03-066).

Reagents

Anti-CD11b, anti-CD28, anti-TCR-ß, anti-TCR- mAbs along with anti-IFN-, anti-IL-2, IL-4, and anti-IL-10 mAbs for ELISA were purchased from PharMingen, San Diego, CA. Murine rIFN-, rIL-2, rIL-4, and rIL-10 were obtained from Genzyme, Cambridge, MA. Anti-CD3 mAb was purchased from Boehringer-Mannheim Biochemicals, Indianapolis, IN. Anti-L3T4 and anti-Lyt-2.2 mAbs were obtained from Accurate Chemical and Scientific, Westbury, NY. Anti-mouse Ig (anti-Ig) antiserum was purchased from Cappel Laboratory, Cochranville, PA, and Low-Tox-M rabbit complement was obtained from Cedarlane Laboratories, Hornby, Ontario, Canada.

Preparations of splenic lymphocytes

As described previously (23), splenic mononuclear cells were prepared from the spleens of mice inoculated with B16 melanoma cells or controls. To prepare CD4⁺ T cells, splenic mononuclear cells (1 x 10⁷ cells/ml) were passed through a CD4 T cell subset column (R&D Systems, Minneapolis, MN) (24). The cells obtained were washed with serum-free RPMI 1640 medium and used in the experiments. When CD4⁺ T cell fractions were treated with anti-L3T4 mAb followed by complement, 96% of viable cells were lysed. When these cell fractions were treated with anti-Lyt-2.2 mAb followed by complement, 2% of viable cells were lysed (24). These results suggested that the purity of the CD4⁺ cell preparation was 96% or greater. For phenotypical analysis, CD4⁺ T cells purified from spleens of tumor-bearing mice were treated with various mAbs (4°C, 30 min) followed by complement (1/30 dilution, 37°C, 30 min) (24). The residual cells were then assayed for their ability to produce IL-4 (see Assay of cytokines). mAbs used for the phenotypic analysis included anti-CD11b (1/100 dilution), anti-CD28 (1/50 dilution), anti-TCR-ß (1/100 dilution), and anti-TCR- mAbs (1/100 dilution) (24).

Mice implanted with B16F1 or B16F10 melanoma cells

B16F1 cells (a low metastatic strain of B16 melanoma cells) and B16F10 cells (a high metastatic strain of B16 melanoma cells), provided by Tohoku University School of Medicine, Sendai, Japan, were grown in vitro with RPMI 1640 medium supplemented with 5% FBS, antibiotics, and 1% L-glutamine (complete medium) and stored in liquid nitrogen (25). For their use in animal experiments, these cells were passed two to five times with complete medium after their regrowth from frozen stocks. Cells in a log growth phase were detached from tissue culture flasks using a mixture of 0.25% trypsin and 0.03% EDTA. The cells were then washed and suspended in PBS just before implantation. The mice were injected i.v. with 0.2 ml of the cell suspension. In these experiments, the mice were inoculated with 2 x 10⁵ cells/mouse of cultured B16F1 cells or B16F10 cells, and designated as BF1 mice² or BF10 mice, respectively. As required, variable numbers of splenic CD4⁺ T cells from normal mice (naive T cells), BF1 mice, or BF10 mice were adoptively transferred i.v. to BF1 mice 3 days after tumor inoculation. Fourteen days after tumor inoculation, lung tissues were removed from these mice and fixed in a 10% formaldehyde solution (25). The number of black metastatic colonies in lungs were counted under a dissecting microscope, as described previously (25). Throughout all experiments, metastatic colonies were demonstrated only in the lungs (not other organs) of BF1 mice and BF10 mice 2 wk after tumor inoculation.

Assay of cytokines

To induce IFN-, IL-2, IL-4, and IL-10 in vitro, 2 x 10⁶ CD4⁺ T cells/ml from BF1 mice or BF10 mice were stimulated with anti-CD3 mAb (2.5 µg/ml) for 48 h at 37°C (26). The culture fluids were harvested and assayed for cytokines by specific ELISA according to standard protocol. In these assays, the detection limit for cytokines using ELISA was between 5 and 50 pg/ml.

Statistical analysis

The results of the pulmonary metastasis and the cytokine assays were statistically analyzed using Student’s t test. If the p value was <0.05, the result was considered to be significant.

	Results

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Generation of Th2 cells in BF10 mice

The number of pulmonary lesions of B16 melanoma cells in BF1 mice and BF10 mice at various days after the tumor cell inoculation is shown in Figure 1. Metastatic colonies of B16 melanoma cells were first detected in BF10 mice 6 days after the inoculation of B16F10 cells (2 x 10⁵ cells/mouse) and reached their peak (an average of 250 colonies or more) at 12 days after inoculation. However, very few pulmonary lesions were observed in BF1 mice 2 wk after inoculation with the same number of B16F1 melanoma cells.

View larger version (12K): [in this window] [in a new window]   FIGURE 1. Pulmonary metastasis in mice various days after inoculation of 2 x 105 B16F10 (BF10 mice) or B16F1 melanoma cells (BF1 mice) per mouse. The metastatic colonies were counted on days 3, 6, 9, 12, and 14 after the tumor inoculation in BF10 mice (•) or BF1 mice (). Values are the average number of pulmonary colonies obtained from five mice. Results are the mean ± SE.

View larger version (15K): [in this window] [in a new window]   FIGURE 2. Production of IL-4 by CD4+ T cells from BF1 mice or BF10 mice. For induction of IL-4, CD4+ T cells (2 x 106 cells/ml) prepared from spleens of BF1 mice or BF10 mice on days 3, 7, and 14 after tumor inoculation were stimulated in vitro with anti-CD3 mAb. As a control, CD4+ T cells from normal mice (naive CD4+ T cells) were stimulated with mAb. Culture supernatants, harvested 48 h after stimulation, were assayed for IL-4 by ELISA. Results are the mean ± SD of triplicate determinations.

To examine the role of BF10-Th2 cells on pulmonary metastasis, adoptive transfer of CD4⁺ T cells from BF10 mice (donors) to BF1 mice (recipients) was performed, and the metastatic colonies in lungs of the recipient mice were counted, as described above. BF10-Th2 cells were prepared from spleens of mice at 14 days after inoculation of 2 x 10⁵ cells/mouse of B16F10 melanoma cells. When 5 x 10⁶ cells/mouse of BF10-Th2 cells were adoptively transferred to BF1 mice, the number of metastatic colonies was 229 ± 45, as compared with 23 ± 6 colonies in lungs of BF1 mice inoculated with naive CD4⁺ T cells. The numbers of colonies in recipient mice increased in response to the numbers of BF10-Th2 cells transferred (Fig. 3). However, when variable numbers of CD4⁺ T cells from BF1 mice or naive CD4⁺ T cells were adoptively transferred to recipient mice, the pulmonary spread did not occur (Fig. 3). These results indicate that the BF10-Th2 cells generated in BF10 mice accelerated the development of pulmonary metastasis in BF1 mice.

View larger version (15K): [in this window] [in a new window]   FIGURE 3. Pulmonary metastasis in BF1 mice inoculated with BF10-Th2 cells. Three days after inoculation of 2 x 105 B16F1 melanoma cells/mouse, mice (BF1 mice) received various numbers of splenic CD4+ T cells obtained from BF1 () or BF10 (•) mice at 14 days after their tumor implantation. As a control, BF1 mice were inoculated with the same number of CD4+ T cells from normal mice (naive CD4+ T cells) (). Fourteen days after inoculation with tumor cells, the number of metastatic colonies in lungs of these mice (five mice each) was examined, as described in text. Results are the mean ± SE.

CD4⁺ T cells from BF10 mice at 14 days after the tumor inoculation (BF10-Th2 cells) were treated with various mAbs followed by complement. The remaining cells were assayed for their ability to produce IL-4. When BF10-Th2 cells were treated with anti-CD11b, anti-CD28, or anti-TCR-ß mAbs followed by complement, the IL-4-producing cells were depleted (Table II). However, BF10-Th2 cells treated with anti-TCR- mAb and complement produced 2380 pg/ml of IL-4 into their supernatant. These results indicate that BF10-Th2 cells were CD4⁺CD11b⁺CD28⁺TCR-ß⁺ Th2 cells.

The IL-4-producing activity of BF10-Th2 cells was demonstrated by the above experiment. Therefore, in the next studies, the role of IL-4 secreted from BF10-Th2 cells on pulmonary metastasis of B16 melanoma in BF10 mice was examined. When BF1 mice were injected i.p. with 0.1 to 10 µg/kg IL-4, pulmonary metastasis was increased in relation to increasing IL-4 amounts administered (Fig. 4). When BF1 mice were treated with a 10-mg/kg dose of IL-4, pulmonary metastasis in BF1 mice was increased to that observed in mice inoculated with 5 x 10⁶ BF10-Th2 cells/mouse (see Figs. 1 and 4). In contrast, pulmonary metastasis in BF10 mice or in BF1 mice inoculated with BF10-Th2 cells was reduced to the same level observed in BF1 mice when they were treated with anti-IL-4 mAb (250 µg/kg) (Table III). These results suggest that the IL-4 released from BF10-Th2 cells was important in the degree of pulmonary metastasis in mice inoculated with B16 melanoma cells.

View larger version (13K): [in this window] [in a new window]   FIGURE 4. Amount of pulmonary metastases in BF1 mice treated with IL-4. Mice (BF1 mice), at 3 days after i.v. inoculation with 2 x 105 B16F1 melanoma cells/mouse, were treated i.p. with various doses of IL-4 once a day for 7 days beginning just after tumor inoculation (10 mice each) (•). As a control, BF1 mice were treated with saline (). The numbers of metastatic colonies in lungs of these mice were counted at 14 days after the tumor implantation, as described in text. The results expressed are the mean ± SE.

	Discussion

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In the present study, the role of type 2 T cells or their cytokine products on experimental pulmonary metastasis was investigated in mice inoculated with a high or low metastatic strain of melanoma cells. In the results obtained, the severity of pulmonary metastasis in mice inoculated with B16 melanoma cells was strongly influenced by tumor-associated CD4⁺CD11b⁺CD28⁺TCR-ß⁺ T cells (BF10-Th2 cells) or IL-4 released from BF10-Th2 cells. BF10-Th2 cells were detected in spleens of mice inoculated with highly metastatic B16F10 melanoma cells (BF10 mice), but they were not observed in spleens of mice inoculated with low metastatic B16F1 melanoma cells (BF1 mice). The intensity of metastasis in lungs of BF1 mice inoculated with BF10-Th2 cells occurred at the level observed in BF10 mice. When BF10-Th2 cells were treated in vitro with anti-CD3 mAb, they produced IL-4. When BF1 mice were treated with rIL-4, an increase in pulmonary metastasis of melanoma cells was demonstrated. In contrast, after the administration of anti-IL-4 mAb, the formation of metastatic colonies in BF10 mice or BF1 mice inoculated with BF10-Th2 cells was reduced. These results suggested that BF10-Th2 cells, or IL-4 secreted from these Th2 cells, accelerate the development of pulmonary metastasis in mice inoculated with B16 melanoma cells.

On the other hand, IL-4 (a representative cytokine for type 2 T cell responses) is known as an inhibitor of the growth of human renal cell carcinoma and malignant melanoma cells (39, 40). These cells express the high affinity receptor for IL-4 (39, 40). Clinical trials of IL-4 as a therapeutic regimen for advanced renal cancer and malignant melanoma are under way (41, 42). In several animal studies (43, 44, 45), an antitumor effect of intralesional administration of IL-4 has also been noted. In addition, other recent studies using tumors genetically engineered to secrete IL-4 have demonstrated activity on the regression of tumors (46, 47, 48, 49). A plasmacytoma cell line engineered to produce high levels of IL-4 decreased human U87 glioma xenografts in mixed s.c. and intracerebral tumor assays in nude mice (46). The tumor-specific antimetastatic activity of lymph node cells from mice inoculated with IL-4-transfected B16 melanoma cells was enhanced when compared with those of effector cells from mice inoculated with parental B16 melanoma cells (47, 48, 49). Other activities also exist for IL-4. It up-regulates protein expression and enzymatic activity of aminopeptidases, which may relate to the tumor cell invasion process and metastasis (50), and stimulates systemic antitumor immunity in hosts bearing B16 melanoma cells (47, 48, 49). Furthermore, IL-4 gene therapies against malignancy are receiving increased attention (51, 52, 53). The antitumor activity of IL-4 demonstrated using gene therapy was more distinct as compared with studies where IL-4 was administered directly (51, 52, 53).

When tumor growth is accelerated by IL-4 and type 2 T cell influences, T cells appear to be major effector cells (14, 15, 16). However, T cells may not be involved when tumor growth is inhibited by IL-4 (43, 44, 45), IL-4-transfected cells (46) or IL-4 gene transfer (51, 52, 53). The antitumor activity of IL-4-transfected cells and IL-4 gene therapy has been demonstrated in T cell-deficient nude mice (40, 44, 51). IL-4 has been shown to be an inducer of VCAM in the tumor microvasculature (54). This suggests that eosinophils with a ligand for VCAM may be allowed to bind effectively to tumor cells following exposure to IL-4. Tepper et al. (43) reported that eosinophils infiltrated into tumor sites were shown to be effector cells since the IL-4-transfected cells were rejected. In a subsequent report using athymic nude mice (44), they described prominent eosinophils that infiltrated into tumor sites and IL-4-mediated antitumor effects were linked. However, it is not clear what conditions are required to enhance tumor growth by IL-4 (or type 2 T cell responses) or IL-4-associated tumor rejections to be activated. The amount of IL-4 injected (exogenous) or released (endogenous), the times after the tumor implantation, the type of malignancy of transplanted tumors, the size of solid tumors, and each individual experimental system (tumor lines, animal strains) might contribute to this discrepancy.

	Footnotes

 
¹ Address correspondence and reprint requests to Dr. Fujio Suzuki, Department of Internal Medicine, The University of Texas Medical Branch, 301 University Boulevard, Galveston, TX 77555-0835.

² Abbreviations used in this paper: BF1 mice, mice implanted with B16F1 melanoma cells; BF10 mice, mice implanted with B16F10 melanoma cells; BF10-Th2 cells, CD4⁺ T cells from BF10 mice 14 days after the tumor inoculation.

Received for publication October 30, 1997. Accepted for publication February 19, 1998.

	References

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1. Werkmeister, J., W. McCarthy, P. Hersey. 1981. Suppressor cell activity in melanoma patients. I. Relation to tumor growth and immunoglobulin levels in vitro. Int. J. Cancer 28:1.[Medline]
2. Mukherji, B., S. A. Wilhelm, A. Guha, M. T. Ergin. 1986. Regulation of cellular responses against autologous human melanoma. I. Evidence for cell-mediated suppression of in vitro cytotoxic immune response. J. Immunol. 136:1888.[Abstract]
3. North, R. J., M. Awwad, P. L. Dunn. 1989. The immune response to tumors. Transplant. Proc. 21:575.[Medline]
4. Vaage, J.. 1974. Circulating tumor antigens versus immune serum factors in depressed concomitant immunity. Cancer Res. 34:2979.[Abstract/Free Full Text]
5. Sjögren, H. O., I. Hellström, S. C. Bansal, K. E. Hellström. 1971. Suppressive evidence that the "blocking antibodies" of tumor-bearing individuals may be antigen-antibody complexes. Proc. Natl. Acad. Sci. USA 68:1372.[Abstract/Free Full Text]
6. Romeo, D. S., S. B. Mizel. 1988. Partial purification of an immunosuppressive protein from human tumor cell line and analysis of its relationship to transforming growth factor. Cell. Immunol. 122:483.
7. Fu, Y. X., G. A. Watson, M. Kasahara, D. M. Lopez. 1991. The role of tumor-derived cytokines on the immune system of mice bearing a mammary adenocarcinoma. J. Immunol. 146:783.[Abstract]
8. Oghiso, Y., Y. Yamada, K. Ando, H. Ishihara, Y. Shibata. 1993. Differential induction of prostaglandin E₂-dependent and -independent immune suppressor cells by tumor-derived GM-CSF and M-CSF. J. Leukocyte Biol. 53:86.[Abstract]
9. Gorelik, L., A. Prokhorova, M. B. Mokyr. 1994. Low-dose melphalan-induced shift in the production of a Th2-type cytokine to a Th1-type cytokine in mice bearing MOPC-315 tumor. Cancer Immunol. Immunother. 39:117.[Medline]
10. Putnam, J. B., J. A. Roth. 1985. Identification and characterization of a tumor-derived immunosuppressive glycoprotein from murine melanoma K-1735. Cancer Immunol. Immunother. 19:90.[Medline]
11. Sami, S., S. Takano, T. Majima, H. Aso, T. Nakamura, N. Ishida. 1986. Low molecular weight immunosuppressive factors found in elevated amounts in cancer ascitic fluids of mice. J. Immunopharmacol. 8:39.[Medline]
12. Yamamura, M., R. L. Modlin, J. D. Ohmen, R. L. Moy. 1993. Local expression of antiinflammatory cytokines in cancer. J. Clin. Invest. 91:1005.
13. Lee, K. Y., P. S. Goedegebuure, D. C. Linehan, T. J. Eberlein. 1994. Immunoregulatory effects of CD4⁺ T helper subsets in human melanoma. Surgery 117:317.
14. Nishioka, Y., S. Sone, E. Orino, A. Nii, T. Ogura. 1991. Down-regulation by interleukin-4 of activation of human alveolar macrophages to the tumoricidal state. Cancer Res. 51:5526.[Abstract/Free Full Text]
15. Lindquist, C., A. L. Ostman, C. Okerblom, K. Akerman. 1992. Decreased interleukin-2 ß chain receptor expression by interleukin-4 on LGL: influence on the IL-2 induced cytotoxicity and proliferation. Cancer Lett. 64:43.[Medline]
16. Moore, K. W., A. O’Garra, R. de Waal Malefyt, P. Vieira, T. R. Mosmann. 1993. Interleukin-10. Annu. Rev. Immunol. 11:165.[Medline]
17. Poste, G., G. L. Nicolson. 1980. Arrest and metastasis of blood-borne tumor cells are modified by fusion of plasma membrane vesicles from highly metastatic cells. Proc. Natl. Acad. Sci. USA 77:399.[Abstract/Free Full Text]
18. Hill, R. P., V. Ling. 1984. Dynamic heterogeneity: rapid generation of metastatic variants in mouse B16 melanoma cells. Science 224:998.[Abstract/Free Full Text]
19. Poste, G., I. J. Fidler. 1980. The pathogenesis of cancer metastasis. Nature 283:139.[Medline]
20. Nabi, I. R., A. Raz. 1988. Loss of metastatic responsiveness to cell shape modulation in a newly characterized B16 melanoma adhesive cell variant. Cancer Res. 48:1258.[Abstract/Free Full Text]
21. Dumont, J. A., Jr W. D. Jones, A. J. Bitonri. 1992. Inhibition of experimental metastasis and cell adhesion of B16F1 melanoma cells by inhibitors of protein kinase C. Cancer Res. 52:1195.[Abstract/Free Full Text]
22. Herd, Z. L.. 1987. Suppression of B16 melanoma lung colonization by syngeneic monoclonal antibodies. Cancer Res. 47:2696.[Abstract/Free Full Text]
23. Suzuki, F., R. R. Brutkiewicz, R. B. Pollard. 1986. Importance of Lyt 1⁺ T-cells in the antitumor activity of an immunomodulator, SSM, extracted from human-type tubercle bacilli. J. Natl. Cancer Inst. 77:441.
24. Kobayashi, M., D. N. Herndon, R. B. Pollard, F. Suzuki. 1995. CD4⁺ contrasuppressor T cells improve the resistance of thermally injured mice infected with HSV. J. Leukocyte Biol. 57:159.
25. Yokoyama, T., O. Yoshie, H. Aso, T. Ebina, N. Ishida. 1986. Inhibition of intravascular mouse melanoma dissemination by recombinant human interferon A/D. Jpn. J. Cancer Res. 77:80.[Medline]
26. Matsuo, R., M. Kobayashi, D. N. Herndon, R. B. Pollard, F. Suzuki. 1996. Interleukin-12 protects thermally injured mice from herpes simplex virus type 1 infection. J. Leukocyte Biol. 59:623.[Abstract]
27. Ghosh, P., K. L. Komschlies, M. Cippitelli, D. L. Longo, J. Subleski, J. Ye, A. Sica, H. A. Young, R. H. Wiltrout, A. C. Ochoa. 1995. Gradual loss of T-helper 1 populations in spleens of mice during progressive tumor growth. J. Natl. Cancer Inst. 87:1478.[Abstract/Free Full Text]
28. Maeda, H., A. Shiraishi. 1996. TGF-ß contributes to the shift toward Th2-type responses through direct and IL-10-mediated pathways in tumor-bearing mice. J. Immunol. 156:73.[Abstract]
29. McAdam, A. J., B. A. Pulaski, S. S. Harkins, E. K. Hutter, E. M. Lord, J. G. Frelinger. 1995. Synergistic effects of co-expression of the Th1-cytokines IL-2 and IFN-gamma on generation of murine tumor-reactive cytotoxic cells. Int. J. Cancer 61:628.[Medline]
30. Pellegrini, P., A. M. Berghella, T. D. Beato, S. Cicia, D. Adorno, C. U. Casciani. 1996. Disregulation in TH1 and TH2 subsets of CD4⁺ T cells in peripheral blood of colorectal cancer patients and involvement in cancer establishment and progression. Cancer Immunol. Immunother. 42:1.[Medline]
31. Handel-Fernandez, M. E., X. Cheng, L. M. Herbert, D. M. Lopez. 1997. Down-regulation of IL-12, not a shift from a T helper-1 to a T helper-2 phenotype, is responsible for impaired IFN- production in mammary tumor-bearing mice. J. Immunol. 158:280.[Abstract]
32. Maeda, H., H. Kuwahara, Y. Ichimura, M. Ohtsuki, S. Kurakata, A. Shiraishi. 1995. TGF-ß enhances macrophage ability to produce IL-10 in normal and tumor-bearing mice. J. Immunol. 155:4926.[Abstract]
33. Hsieh, C. S., S. E. Macatonia, S. Tripp. 1993. Development of Th1 CD4⁺ T cells through IL-12 produced by Listeria-induced macrophages. Science 260:547.[Abstract/Free Full Text]
34. Seder, R. A., R. Gazzinelli, A. Sher, W. E. Paul. 1993. Interleukin 12 acts directly on CD4⁺ T cells to enhance priming for interferon- production and diminishes interleukin 4 inhibition of such priming. Proc. Natl. Acad. Sci. USA 90:1018.[Abstract/Free Full Text]
35. Manetti, R., P. Parronchi, M. G. Giudizi, M. P. Piccinni, E. Maggi, G. Trinchieri, S. Romagnani. 1993. Natural killer cell stimulatory factor (interleukin-12) induces T helper type 1 (Th1)-specific immune responses and inhibits the development of IL-4-producing Th cells. J. Exp. Med. 177:1199.[Abstract/Free Full Text]
36. Macatonia, S. E., N. A. Hosken, M. Litton. 1995. Dendric cells produce IL-12 and direct the development of Th1 cells from naive CD4⁺ T cells. J. Immunol. 154:5071.[Abstract]
37. Nastala, C. L., H. D. Edington, T. G. McKinney. 1994. Recombinant interleukin-12 (IL-12) administration induces tumor regression in association with interferon- production. J. Immunol. 153:1697.[Abstract]
38. Takeuchi, T., T. Ueki, Y. Sasaki, T. Kajiwara, B. Li, N. Moriyama, K. Kawabe. 1997. Th2-line response and antitumor effect of anti-interleukin-4 mAb in mice bearing renal cell carcinoma. Cancer Immunol. Immunother. 43:375.[Medline]
39. Obiri, N. I., G. G. Hillman, G. P. Haas, S. Sud, R. K. Puri. 1993. Expression of high affinity interleukin-4 receptors on human renal carcinoma cells and inhibition of tumor cell growth in vitro by interleukin-4. J. Clin. Invest. 91:88.
40. Topp, M. S., M. Koenigsmann, A. Mire-Sluis, D. Oberberg, F. Eitelbach, Z. Von Marschall, M. Notter, B. Reufi, H. Stein, E. Thiel, W. E. Berder. 1993. Interleukin 4 inhibits growth of a human lung tumor cell line in vitro and has therapeutic activity against xenografts of this cell line in vitro. Int. J. Oncol. 3:167.
41. Margolin, K., F. R. Aronson, M. Sznol, M. B. Atkins, R. Gucalp, R. I. Fisher, M. Sunderland, J. H. Doroshow, M. L. Ernest, J. W. Mier, J. P. Dutcher, E. R. Gaynor, G. R. Weiss. 1994. Phase II studies of recombinant human interleukin-4 in advanced renal cancer and malignant melanoma. J. Immunother. 15:147.
42. Schmidt-Wolf, G., I. G. H. Schmidt-Wolf. 1995. Cytokines and clinical gene therapy. Eur. J. Immunol. 25:1137.[Medline]
43. Tepper, R. I., P. K. Pattengale, P. Leder. 1989. Murine interleukin-4 displays potent anti-tumor activity in vivo. Cell 57:503.[Medline]
44. Tepper, R. I., R. L. Coffman, P. Leder. 1992. An eosinophil-dependent mechanism for the antitumor effect of IL-4. Science 257:548.[Abstract/Free Full Text]
45. Gallagher, G., Y. Zaloom. 1992. Peritumoral IL-4 treatment induces systemic inhibition of tumor growth in experimental melanoma. Anticancer Res. 12:1019.[Medline]
46. Yu, S. J., M. X. Wei, E. A. Chiocca, R. L. Martuza, R. L. Tepper. 1993. Treatment of glioma by engineered interleukin-4-secreting cells. Cancer Res. 53:3125.[Abstract/Free Full Text]
47. Krauss, J. C., S. E. Strome, A. E. Chang, S. Shu. 1994. Enhancement of immune reactivity in the lymph nodes draining a murine melanoma engineered to elaborate interleukin-4. J. Immunother. Emphas. Tumor Immunol. 16:77.[Medline]
48. Souberbielle, B. E., B. C. Knight, M. J. Morrow, D. Darling, M. Fraziano, J. B. Marriott, S. Cookson, F. Farzaneh, A. G. Dalgleish. 1996. Comparison of IL-2 and IL-4-transfected B16-F10 cells with a novel oil-microemulsion adjuvant for B16-F10 whole cell tumor vaccine. Gene Ther. 3:853.[Medline]
49. Lipshy, K. A., P. J. Kostuchenko, G. G. Hamad, C. E. Bland, S. K. Barrett, H. D. Bear. 1997. Sensitizing T-lymphocytes for adoptive immunotherapy by vaccination with wild-type or cytokine gene-transduced melanoma. Ann. Surg. Oncol. 4:334.[Medline]
50. Riemann, D., A. Kehlen, J. Langner. 1995. Stimulation of the expression and the enzyme activity of aminopeptidase N/CD13 and dipeptidylpeptidase IV/CD26 on human renal cell carcinoma cells and renal tubular epithelial cells by T cell-derived cytokines, such as IL-4 and IL-13. Clin. Exp. Immunol. 100:277.[Medline]
51. Wei, M. X., T. Tamiya, Jr R. K. Hurford, E. J. Boviatsis, R. I. Tepper, A. Chiocca. 1995. Enhancement of interleukin-4-mediated tumor regression in athymic mice by in situ retroviral gene transfer. Hum. Gene Ther. 6:437.[Medline]
52. Missol, E., A. Sochanik, S. Szala. 1995. Introduction of murine IL-4 gene into B16(F10) melanoma tumors by direct gene transfer with DNA-liposome complexes. Cancer Lett. 7:189.
53. Jr Hurford, R. K., G. Dranoff, R. C. Mulligan, R. I. Tepper. 1995. Gene therapy of metastatic cancer by in vitro retroviral gene targeting. Nat. Genet. 10:430.[Medline]
54. Schleimer, R. P., S. A. Sterbinsky, J. Kaiser, C. A. Bickel, D. A. Klunk, K. Tomioka, W. Newman, F. W. Luscinskas, M. A. Gimbrone, B. M. McIntyre. 1992. IL-4 induces adherence of human eosinophils and basophils but not neutrophils to endothelium association with expression of VCAM-1. J. Immunol. 148:1086.[Abstract]

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