Anti-tumor effects of interferon in mice injected with interferon-sensitive and interferon-resistant Friend leukemia cells. VI. Adjuvant therapy after surgery in the inhibition of liver and spleen metastases

Adult DBA/2 mice were injected s.c. with the highly malignant, interferon-resistant 3C18 line of Friend erythroleukemia cells (FLC). Eight or 9 days after established s.c. tumors had developed, the primary tumor was excised and mice were treated i.p. with either mouse interferon alpha/beta or a control preparation. At the time of surgery, mice already had tumor cells in the liver. All control-treated mice died in the ensuing 2 weeks with extensive tumor metastases in the liver and spleen. Interferon treatment resulted in an inhibition of the development of liver and spleen metastases and a markedly increased survival time. We conclude that interferon alpha/beta is effective as adjuvant therapy after surgery for metastatic disease in mice.     

Microvascular injury in pathogenesis of interferon-induced necrosis of subcutaneous tumors in mice

DBA/2 mice were injected sc with cells from the highly malignant Friend erythroleukemia cell (FLC) 3Cl8 subline, which is resistant to mouse interferon alpha/beta, or with the ESb lymphoma. When interferon alpha/beta was injected intratumorally or peritumorally, tumor growth was markedly suppressed, and established vascularized tumor nodules became progressively necrotic. Tumor necrosis was of the coagulation type that usually results from deprivation of blood flow. Morphologic examination of approximately 1,000 blood vessel profiles and approximately 2,000 endothelial cells in 1-micron Epon sections of sc 3C18 FLC tumors showed that interferon treatment resulted in rapid and pronounced vascular endothelial cell damage that preceded tumor necrosis. No inflammatory cell infiltrate was observed. Our results suggest that interferon alpha/beta exerted an antitumor effect in these tumor models by damaging tumor blood vessels, causing disruption of tumor blood flow, which led to ischemic tumor necrosis.     

Anti-tumor effects of interferon in mice injected with interferon-sensitive and interferon-resistant friend leukemia cells. IV. Definition of optimal treatment regimens

Mouse interferon alpha/beta exerted a similar anti-tumor effect in DBA/2 mice injected i.p. with Friend erythroleukemia cells (FLC) either sensitive or resistant to interferon as determined by both in vitro and in vivo assays. Using this tumor system we attempted to define optimal treatment regimens for interferon administration. Interferon was most effective when injected at the site of tumor inoculation rather than at a distant site. Two factors seemed of especial importance: the amount of interferon injected and the frequency of interferon administration. Thus, for daily administration of interferon, the antitumor effect was directly related to the amount of interferon injected. For a given total dose of interferon, repeated administration of small doses of interferon was more effective than administration of a larger dose at more widely spaced intervals. The anti-tumor efficacy of interferon was independent of the number of FLC inoculated when 10(2) to 10(5) FLC were injected, but interferon treatment was less effective when 10(6) or 10(7) FLC were injected. The relevance of these results to the use of interferon in patients with cancer is discussed.     

Biologic and biochemical differences between in vitro and in vivo passaged Friend erythroleukemia cells. I. Tumorigenicity and capacity to metastasize

Cloned interferon-sensitive (745) and interferon-resistant (3Cl-8) Friend erythroleukemia cells (FLC) passaged in vitro, are not very tumorigenic when first injected intraperitoneally (i.p.) into syngeneic DBA/2 mice although they do form solid tumors when injected subcutaneously (s.c.). By serially passaging FLC (either 745 or 3Cl-8 cells) i.p. in DBA/2 mice, we obtained two different FLC lines capable of growing i.p. and inducing tumor ascites. The s.c. injection of DBA/2 mice with these in vivo passaged FLC resulted in tumor metastases in the liver and spleen, whereas metastases were not observed in mice inoculated s.c. with in vitro passaged FLC. The capacity of in vivo passaged FLC to metastasize was acquired after several i.p. passages. This highly malignant behavior was a stable characteristic of these cells. All the clones derived from in vivo passaged FLC and passaged more than 14 times in vitro induced hemorrhagic ascites when injected i.p., and metastasized to the liver and spleen when injected s.c. The phenotype of sensitivity or resistance to the inhibitory effect of alpha/beta mouse interferon on virus replication and cell multiplication was conserved during serial i.p. passages and maintained in the clones derived from in vivo passaged cells. These FLC showed a decreased capacity to differentiate in vitro upon treatment with dimethylsulfoxide (DMSO) and a reduced production of Friend leukemia virus with respect to the original clones passaged in vitro.     

Synergistic anti-tumor effects of combined IL-1/IFN-alpha/beta therapy in mice injected with metastatic Friend erythroleukemia cells

Peritumoral injection of relatively low doses of either mouse interferon (IFN)-alpha/beta (10,000-20,000 units/injection) or of recombinant human interleukin-1 (IL-1) beta (125-250 ng/injection) in mice transplanted s.c. with Friend erythroleukemia cells (FLC) resulted in some inhibition of primary tumor growth, inhibition of liver and splenic metastases and increased survival time. A synergistic anti-tumor effect was observed in mice injected with both IL-1 and IFN-alpha/beta. Highly purified mouse IFN-beta also exerted a synergistic anti-tumor effect when combined with IL-1-beta in mice injected with FLC. The anti-tumor action of IL-1/IFN was markedly reduced in mice treated with antibodies to CD4 antigens. Antibodies to asialo-GM1 also diminished the anti-tumor effect by the combined cytokine treatment. The combined IL-1/IFN therapy was effective in NK-deficient bg/bg mice, although the extent of the anti-tumor response in these mice was less than that observed in bg/+mice.     

Anti-tumor effects of interleukin-2 and interleukin-1 in mice transplanted with different syngeneic tumors

We have studied the anti-tumor effects of human recombinant IL-2, alone or in association with LAK cells, in mice transplanted subcutaneously (s.c.) with the following syngeneic tumors: highly metastatic Friend leukemia cells (FLC), nonmetastatic FLC, lymphoma RBL-5 cells and HeJ16 fibrosarcoma cells. In these tumor models, peri-tumoral injections of IL-2 were more effective in inhibiting tumor growth than a systemic treatment. Although s.c. IL-2 treatment resulted in marked inhibition of tumor growth in mice injected s.c. with highly metastatic FLC, it was not effective in inhibiting growth of FLC in the liver and spleen. IL-2 therapy was more effective at increasing survival time in mice transplanted with non-metastatic FLC or with RBL-5 cells. In mice transplanted with HeJ16 fibrosarcomas, s.c. IL-2 treatment resulted in highly significant anti-tumor effect and survival of 70% of tumor-injected mice. No general correlation was found between in vitro sensitivity or resistance to the cytolytic activity of LAK cells and the anti-tumor effects observed in vivo. Subcutaneous injection of IL-1 beta in mice transplanted with highly metastatic FLC resulted in a marked increase in survival time and inhibition of metastatic tumor growth in liver and spleen. Combined treatment of IL-1 beta and IL-2 produced a synergistic anti-tumor effect: 60% of mice injected with highly metastatic FLC survived. Combined IL-1/IL-2 treatments exerted no anti-tumor activity either in DBA/2 mice injected with antibody to Thy 1.2 antigen or in nude mice, indicating that T cells play important roles during IL-1/IL-2 therapy. In vitro treatment of FLC with IL-1 beta resulted in a slight inhibition of cell multiplication, whereas even high doses of IL-2 did not affect FLC multiplication. Our results indicate that local combined treatments with IL-1 and IL-2 can induce potent, host-dependent (T cell-mediated) anti-tumor effects against highly malignant tumors.     

Interferon treatment markedly inhibits the development of tumor metastases in the liver and spleen and increases survival time of mice after intravenous inoculation of Friend erythroleukemia cells

To investigate the effect of interferon treatment on the development of tumor metastases, DBA/2 mice were injected i.v. with 2 X 10(6) Friend erythroleukemia cells (FLC) (equivalent to about 5 X 10(5) LD50). FLC multiplied rapidly in the liver and spleen and all untreated or control treated mice died between 7 and 12 days. Daily treatment of mice with potent preparations of mouse interferon alpha/beta was initiated 3 to 72 hr after i.v. inoculation of tumor cells, at times when FLC were already present in the liver and spleen. Interferon treatment resulted in a 100 to 1,000-fold inhibition of the multiplication of FLC in the liver and spleen and a marked increase in mean survival time. Small numbers of tumor cells persisted in the liver and spleen in some interferon-treated mice and could be recovered by bioassay several weeks after tumor inoculation. Most interferon-treated mice died with tumor in the ensuing months. Three of 34 interferon-treated mice were considered cured as they were alive at 386, 325 and 284 days after tumor inoculation. Daily treatment of tumor-inoculated mice with human recombinant interferons alpha D and alpha BDDD, which had antiviral activity on mouse cells in culture, also increased the survival time of mice injected i.v. with FLC. The use of the interferon-resistant 3C18 line of FLC suggests that the marked inhibition of development of established liver and spleen metastases was not due to a direct effect of interferon on the tumor cells, but was host-mediated.     

31P-nuclear magnetic resonance analysis of interferon-induced alterations of phospholipid metabolites in interferon-sensitive and interferon-resistant Friend leukemia cell tumors in mice

Adult DBA/2 mice were given injections s.c. with either interferon-sensitive (745) or -resistant (3Cl-8) Friend erythroleukemia cells (FLC). After tumor nodules had developed, mouse interferon-alpha/beta was injected daily into the tumor. 31P-Nuclear magnetic resonance (NMR) spectroscopy examinations were undertaken on freshly dissected tumors at different days of treatment with either interferon or control preparations. Analysis of 745 FLC tumors in untreated mice at different days of tumor growth (day 8 to 13 after tumor implantation) showed marked increases in the levels of phosphorylcholine (PCho), glycerophosphorylethanolamine (GroPEtn) and glycerophosphorylcholine (GroPCho). In contrast high levels of PCho, GroPEtn and GroPCho were already detectable in the 3Cl-8 FLC tumors on day 8, and no significant changes were observed during subsequent tumor growth. The intracellular pH value remained practically constant in both FLC tumors. Daily intratumoral administration of either partially purified (10(7) IU/mg of protein) or highly purified (10(9) IU/mg of protein) mouse interferon-alpha/beta to both cell tumors resulted in decreases in the levels of PCho, GroPEtn and GroPCho and in increases in the intracellular pH with respect to tumors treated with control preparations or left untreated. Two days of daily treatment of mice with interferon sufficed to induce these metabolic changes which preceded the appearance of necrosis in the tumors. Treatment of FLC tumors with X-rays on day 12 of tumor growth did not result in any comparable metabolic changes 2 days after irradiation. Changes in the levels of phospholipid metabolites were not observed when 745 or 3Cl-8 cells were cultivated in the presence of interferon. As interferon induced these changes in both interferon-sensitive and -resistant tumors we conclude that interferon treatment results in host-mediated effects on the biosynthesis and/or catabolism of tumor cell phospholipids.     

Antitumor effects of interferon in mice injected with interferon-sensitive and interferon-resistant Friend leukemia cells. I

Interferon-sensitive (745) and interferon-resistant (3C1-8) Friend leukemia cells (FLC) are highly tumorigenic for DBA/2 mice. The phenotype of interferon sensitivity or resistance does not change with in vivo passage. Daily administration of mouse interferon markedly enhanced the survival time of mice injected with either 745 or 3C1-8 cells. Use of quantitative methods for determining the number of FLC (colony formation in agarose and immunofluorescence) permitted us to show that potent, partially purified or highly purified mouse interferon (s.a. 0.5 to 1 X 10(9) u/mg protein) induced a 100- to 1,000-fold decrease in the number of tumor cells in the peritoneal cavity in the days following inoculation of 745 or 3C1-8 cells. Interferon decreased the number of FLC even when treatment was initiated at a time when tumor cells were multiplying exponentially in the peritoneal cavity. There was no evidence that interferon acted as an inducer of FLC differentiation in vivo. The finding that interferon was equally effective in mice inoculated with interferon-resistant cells as in mice inoculated with interferon-sensitive cells suggests that in this experimental system interferon does not act directly on the tumor cells, but that the interferon-induced antitumor activity is mediated by the host.     

Tumor necrosis factor alpha induces early morphologic and metabolic alterations in Friend leukemia cell tumors and fibrosarcomas in mice

Morphologic and metabolic studies have been carried out on Friend leukemia cell (FLC) tumors (grown in DBA/2 mice) or fibrosarcomas (grown in C3H/HeN or C3H/HeJ mice) shortly after peritumoral injection of recombinant mouse tumor necrosis factor (TNF) alpha. Marked vascular congestion and focal extravasation of erythrocytes were observed as soon as 1 hr after injection of either FLC tumors or fibrosarcomas with TNF. Focal areas of disaggregation of tumor cells were observed 1 hr after injection of TNF. Intraluminal thrombi (composed of degranulated platelets and fibrin) were detected 3 and 6 hr after TNF treatment, and were associated with areas of depletion of endothelial cell cytoplasm. To correlate these morphologic changes in the tumor with alterations in tumor metabolism, NMR spectroscopy and biochemical studies were undertaken on freshly dissected FLC tumors and fibrosarcomas shortly after injection of TNF. The earliest metabolic alterations observed after 1 hr in TNF-treated FLC tumors of fibrosarcomas were: (i) increase in the average intratumoral pH; (ii) decrease in the levels of ATP. These phenomena were not associated with a reduced glycolytic capacity of TNF-treated tumors as, at these early times after injection, the levels of lactic acid were virtually the same for TNF-treated or control treated tumors. Alterations in the levels of some products of phospholipid degradation (GroPCho, GroPEtn, GroP and Cho) also occurred in these tumors as early as 3 hr after TNF treatment. These metabolic changes were not observed in ascitic FLC tumors after TNF treatment. We suggest that TNF induces alterations in tumor blood vessels which subsequently lead to changes in tumor metabolism and tumor degeneration.     

Interleukin-1 beta induces tumor necrosis and early morphologic and metabolic changes in transplantable mouse tumors. Similarities with the anti-tumor effects of tumor necrosis factor alpha or beta

Peri-tumoral injection of recombinant human interleukin-1 beta in mice transplanted s.c. with Friend erythroleukemia cells (FLC) resulted in marked inhibition of tumor growth and increased survival. However, in vitro treatment of FLC (745 or 3Cl-8) with IL-1 beta barely inhibited cell multiplication. IL-1 beta, injected into established solid tumors, induced marked morphologic changes. Vascular congestion and focal extravasation of erythrocytes were observed as early as 6 hr after injection with IL-1 beta of FLC and L1210 tumors and HeJ16 fibrosarcomas. Focal areas of disaggregation of tumor cells and tumor necrosis were observed 6 and 24 hr after IL-1 injection. These morphologic changes were similar to those observed in FLC tumors or HeJ16 fibrosarcomas treated with TNF-alpha or beta. These cytokines determined morphological changes in tumor blood vessels of FLC tumors within 1 hr of injection. Freshly dissected FLC tumors and their tissue extracts were studied by Nuclear Magnetic Resonance (NMR) spectroscopy, shortly after peri-tumoral injection of IL-1 beta or TNF-beta. After 6 hr, both cytokines induced a 3-fold reduction in the levels of two catabolites, glycerophosphorylcholine and glycerophosphorylethanolamine, an accumulation of sn-glycerol 3-phosphate and a more than 10-fold increase in the choline/phosphorylcholine ratio. These results are similar to those reported for TNF-alpha, and can be interpreted on the basis of an activation of glycerophosphorylcholine phosphodiesterase (EC 3.1.4.2) and partial inhibition of choline kinase (EC 2.7.1.32). IL-1 beta and TNF-beta (like TNF-alpha) also induced alkaline shifts (0.10-0.25 units) in the average intratumoral pH value. We suggest that alterations of tumor blood vessels may be the primary events in solid tumors treated with IL-1 beta or TNF. Such alterations lead to early changes in tumor metabolism and subsequent tumor cell degeneration.     

A novel recombinant tumor necrosis factor-alpha mutant with increased anti-tumor activity and lower toxicity.

We prepared a novel recombinant tumor necrosis factor-alpha (TNF) mutant (mutant 471), in which 7 N-terminal amino-acids were deleted and Pro8Ser9Asp10 was replaced by ArgLysArg, and compared its biological activity with that of wild-type recombinant TNF. Mutant 471 had a 7-fold higher anti-tumor activity against murine L-M cells in vitro, and a higher binding activity to TNF receptors on L-M cells, than wild-type TNF. Furthermore, mutant 471 showed a higher anti-tumor effect on murine Meth A-HM tumors transplanted into BALB/c mice, with complete regression of the tumors being observed in the animals. The possible cachectin activity of mutant 471 was almost the same as that of wild-type TNF. The acute lethal toxicity of mutant 471 in beta-D-galactosamine-sensitized C3H/HeJ mice was 18 times lower than that of wild-type TNF. These results suggest that mutant 471 might be a more promising anti-cancer agent than wild-type TNF.     

Inhibition of mouse alpha/beta-interferon of the multiplication of alpha/beta-interferon-resistant Friend erythroleukemia cells cocultured with mouse hepatocytes

Administration of alpha/beta-interferon (IFN) exerts a marked antitumor effect in DBA/2 mice given injections i.v. of large numbers of IFN-alpha/beta-resistant erythroleukemia cells (FLC). To investigate the possible mechanisms of FLC tumor inhibition in the liver of interferon-treated mice, we developed an in vitro model consisting of a coculture of IFN-alpha/beta-resistant 3Cl8 FLC and syngeneic mouse hepatocytes. Whereas IFN-alpha/beta did not inhibit the multiplication of 3Cl8 FLC cultivated alone, it effectively inhibited the multiplication of 3Cl8 FLC in coculture with hepatocytes. The inhibitory effect was directly proportional to the amount of IFN-alpha/beta added to the cocultures, and more than 90% inhibition of FLC multiplication was noted with 1.6 x 10(5) IU/ml of IFN-alpha/beta on Day 3 of coculture. When FLC were separated from the monolayer of hepatocytes by a pored membrane (0.4 microns), the inhibitory effect on FLC proliferation was unchanged, indicating that a soluble factor(s) released from IFN-treated hepatocytes was most important in the inhibition of FLC multiplication. An inhibitory activity of FLC multiplication was detected only in the conditioned medium of IFN-treated hepatocytes but not in the conditioned medium of control hepatocytes nor in extracts of IFN-treated or control hepatocytes. The inhibitory factor(s) in the conditioned medium of IFN-treated hepatocytes was retained by an ultrafiltration membrane (Mr cut off 10,000), and its activity was completely abrogated by trypsin digestion. Its stability to treatment with 1 M acetic acid as well as lack of correlation between the antiproliferative effect and the amount of L-arginine in the medium distinguished this factor(s) from liver arginase which was also found to be a potent inhibitor of FLC multiplication in vitro. The inhibitory factor(s) was also distinguishable in its biological activity from IFN gamma, interleukin 1 alpha and beta, and transforming growth factor beta 1 and beta 2. These results suggest the possibility that the inhibitory effect of IFN-alpha/beta on the development of 3Cl8 FLC in the livers of IFN-treated mice may be mediated by an IFN-induced inhibitor of FLC multiplication.     

Importance of interferon alpha in the resistance of allogeneic C57B1/6 mice to the multiplication of Friend erythroleukemia cells in the liver

Friend erythroleukemia cells (FLC) (H-2d) injected intravenously multiply extensively in the livers of syngeneic DBA/2 mice and not at all in the livers of allogeneic C57B1/6 mice. Our results indicate that interferon alpha (IFN-alpha) is an important factor in the resistance of allogeneic mice to the multiplication of FLC in the liver. (a) After i.v. inoculation of FLC there was an inverse correlation between the presence of IFN-alpha in the serum and the capacity of FLC to multiply in the liver. Thus, all 44 FLC-injected adult C57B1/6 mice had circulating IFN-alpha and FLC did not multiply in the liver of any of the mice. Interferon was not detected in the serum of 83% of 41 FLC-injected DBA/2 mice (and was found only at a low titer in 17% of the mice) and FLC multiplied in the liver of all mice. (b) FLC did multiply in the livers of newborn C57B1/6 mice and in the livers of irradiated adult C57B1/6 mice, and IFN-alpha was not detected in their sera. In contrast, after i.v. inoculation of FLC, IFN-alpha was detected in the sera of 3-week-old and athymic nu/nu adult C57B1/6 mice while FLC failed to multiply in the liver. (c) FLC also induced IFN-alpha in congenic B10.D2 (H-2d) mice and FLC did not multiply in the liver. We suggest that, depending on the site of tumor implantation, different host mechanisms have various degrees of importance in controlling the growth and/or rejection of allogeneic tumor cells, and that IFN-alpha is particularly important when FLC are injected i.v.     

Interactions of interferons and transforming growth factors during clonal growth of mouse or human cells in soft agar and in mice

The mouse fibroblast-like transformed cell line C-243 adapted to growth in suspension was used as a source of virus-induced interferons (MulFN-alpha, beta), and spontaneously produced active growth factors. These factors were purified from C-243 cells grown as tumors in BALB/c mice, and had properties identical to those of TGF-alpha or TGF-beta isolated by others from different tissues. Exogenous TGF-alpha, beta stimulated colony formation by C-243 cells in soft agar, whereas MulFN-alpha, beta inhibited it. Clonal growth of human lung adenocarcinoma A549 cells in soft agar was inhibited as well by human interferons (types alpha, beta, or gamma) as by TGF-beta. Inhibition was dose-related. Pure EGF, which is an analogue of TGF-alpha, diminished the antiproliferative activity of interferons alpha, beta, and gamma in A549 cells. On the other hand, the anti-mitogenic action of IFN-beta and TGF-beta was clearly synergistic. In mice bearing C-243 cell tumors, TGF-alpha, beta stimulated growth, whereas MulFN-alpha, beta inhibited it. Stimulation of tumor growth was also observed after administration of anti-IFN serum that could neutralize endogenous IFN-alpha, beta. The simultaneous administration of MulFN-alpha, beta and TGF-alpha, beta diminished anti-tumor effects of IFN in mice. Our results suggest that both TGFs and IFNs are autocrine, positive or negative growth factors modulating the rate of proliferation and the neoplastic behavior of the cells. The final effects depend on the target-cell sensitivity and on the relative concentration of the various hormone-like factors. Cancer cells overstimulated by TGF-alpha, beta or by EGF may not respond to IFNs.     

Immunomodulation of natural killer cell activity by flavone acetic acid: occurrence via induction of interferon alpha/beta

The investigational drug flavone acetic acid (FAA) systemically augments natural killer (NK) cell activity in normal and tumor-bearing mice and in human cancer patients. The results from the present investigation demonstrate that in vivo administration of FAA induces in a dose-dependent manner high levels of serum interferon (IFN) within 4 hours in BALB/c, C57BL/6, and BALB/c nude mice. Antibody neutralization studies indicated that FAA induced IFN of the alpha/beta type, while molecular hybridization studies demonstrated that FAA rapidly stimulated the production of IFN alpha mRNA in splenic leukocytes. In vivo administration of anti-IFN alpha/beta antibodies to FAA-treated mice inhibited the FAA-induced augmentation of splenic NK cell activity at 4 hours. These results suggest that FAA mediates its anti-tumor effects indirectly by immunomodulation as well as directly by antiproliferative or cytotoxic activity.     

Anti-tumor immune responses in immune-reconstituted mice injected with a tumor vaccine

Homeostasis-driven proliferation of T cells is an important means of reconstituting T-cell-dependent immunity after lymphodepletion regimens, such as chemotherapy or radiotherapy. Immune-reconstituted mice that receive a tumor vaccine mount more efficient anti-tumor immune responses compared with control mice. In the present study, we evaluated the anti-tumor immune responses in immune-reconstituted mice vaccinated with inactivated leukemia cells and explored the mechanisms underlying these immune responses. Test C57BL/6 mice were lymphodepleted by irradiation and immune-reconstituted with na?ve mouse spleen lymphocytes. Mice were then injected with an inactivated FBL-3 tumor cell vaccine and challenged with FBL-3 tumor cells. Anti-tumor responses were evaluated by determining the rate of tumor formation, latency, tumor size, interferon gamma levels, and macrophage and CTL cytotoxicities. When challenged with tumor cells, immune-reconstituted, vaccinated mice exhibited a significantly lower mortality, smaller average tumor volume, and a significantly longer mean survival time. They had more robust cellular immunity, reflected by higher levels of INF-γ production and higher macrophage- and CTL-mediated cytotoxicities. Our results suggest that immune reconstitution enhanced the anti-tumor immune responses in mice injected with a tumor vaccine via generation of CTLs. These results have important implications for immunotherapy used for leukemia.     

Antitumoral effects of lipopolysaccharides, tumor necrosis factor, interferon and activated macrophages: synergism and tissue distribution

Treatment of C57BL/6 mice bearing Lewis lung carcinoma or of BALB/c mice bearing EMT6 sarcoma with tumor necrosis factor (TNF), lipopolysaccharides (LPS) or interferon caused necrosis of the solid tumors and regression. Toxicity was observed in tumor-bearing animals when TNF or LPS were used at effective antitumoral doses. Similar antitumoral effects could be achieved using less than 1 million macrophages from C57BL/6, lung of from BALB/c peritoneal cavity expanded in vitro, and spontaneously fully activated to cytotoxicity during culture. This effect, observed after transfer twice a week by intravenous or peritumoral route, was not dependent on histocompatibility. Additive effects were observed after combined treatment with activated macrophages and a low dose of LPS or TNF. The biodistribution of labelled LPS and of labelled cytotoxic macrophages was studied in tumor-bearing mice. Although, as expected, LPS was concentrated essentially in the liver, a slow accumulation in the center of the tumor was observed. Macrophages injected intravenously accumulated in the lung and were then redistributed towards liver, kidney and the tumor periphery. Macrophages injected locally remained essentially in the tumor periphery with a slow redistribution in the body. The complementary localization of LPS and of cytotoxic macrophages respectively in the center and periphery of solid tumors might explain their synergism.     

Isolation of human colon carcinoma cells for resistance to a single interferon associated with cross-resistance to multiple recombinant interferons: alpha, beta, and gamma

We established variants resistant to human interferon (IFN) from an IFN-sensitive human colon carcinoma cell line and delineated some of the mechanisms for resistance to IFN-mediated cytotoxicity. The parent KM12C cells were incubated for 2 months in medium containing recombinant human IFN-alpha hybrid BBDD (r-IFN-alpha) or recombinant human IFN-gamma (r-IFN-gamma). Surviving variants were designated KM12 alpha R and KM12 gamma R, respectively. KM12 alpha R cells were cross-resistant to the cytostatic and cytolytic effects of r-IFN-alpha, r-IFN-beta, and r-IFN-gamma, whereas KM12 gamma R cells were resistant only to the effects of r-IFN-gamma. The parent and variant cell lines had similar in vitro growth rates and similar tumorigenicity in male BALB/c nude mice, but the mechanisms for resistance to IFNs differed in the two variant lines. The resistance of the cross-resistant KM12 alpha R cell line was not attributable to the loss of specific receptors, because our analyses demonstrated the presence of receptors for IFN-gamma, whereas the KM12 gamma R line lacked specific receptors for IFN-gamma. Northern blot analyses revealed that messenger RNA (mRNA) from the proto-oncogene c-myc was equally expressed in the IFN-sensitive and IFN-resistant cell lines and that treatment with r-IFN-gamma did not alter its expression. Treatment with r-IFN-gamma induced the expression of manganous superoxide dismutase mRNA in KM12C and KM12 alpha R cells, but not in KM12 gamma R cells, confirming that both KM12C and KM12 alpha R cells, but not KM12 gamma R cells, have functional receptors for IFN-gamma.     

The antitumor effects of interferon

Interferons show antitumor activity in patients with various malignancies. The mechanism(s) of the antitumor effects are not altogether clear. In one experimental animal model discussed herein, mice were injected with Friend erythroleukemia cells and treated with mouse interferon alpha/beta. The results suggest that interferon does not act directly on the tumor cells but acts via host mechanisms that are still ill defined.