Interleukin 2 gene transfer into tumor cells abrogates tumorigenicity and induces protective immunity

Gene Delivery to Human B-Precursor Acute Lymphoblastic Leukemia Cells

Autologous leukemia cells engineered to express immune-stimulating molecules may be used to elicit antileukemia immune responses. Gene delivery to human B-precursor acute lymphoblastic leukemia (ALL) cells was investigated using the enhanced green fluorescent protein (EGFP) as a reporter gene, measured by flow cytometry. Transfection of the Nalm-6 and Reh B-precursor ALL leukemia cell lines with an expression plasmid was investigated using lipofection, electroporation, and a polycationic compound. Only the liposomal compound Cellfectin showed significant gene transfer (3.9% to 12% for Nalm-6 cells and 3.1% to 5% for Reh cells). Transduction with gibbon-ape leukemia virus pseudotyped Moloney murine leukemia virus (MoMuLV)-based retrovirus vectors was investigated in various settings. Cocultivation of ALL cell lines with packaging cell lines showed the highest transduction efficiency for retroviral gene transfer (40.1% to 87.5% for Nalm-6 cells and 0.3% to 9% for Reh cells), followed by transduction with viral supernatant on the recombinant fibronectin fragment CH-296 (13% to 35.5% for Nalm-6 cells and 0.4% to 6% Reh cells), transduction on human bone marrow stroma monolayers (3.2% to 13.3% for Nalm-6 cells and 0% to 0.2% Reh cells), and in suspension with protamine sulfate (0.7% to 3.1% for Nalm-6 cells and 0% for Reh cells). Transduction of both Nalm-6 and Reh cells with human immunodeficiency virus–type 1 (HIV-1)–based lentiviral vectors pseudotyped with the vesicular stomatitis virus-G envelope produced the best gene transfer efficiency, transducing greater than 90% of both cell lines. Gene delivery into primary human B-precursor ALL cells from patients was then investigated using MoMuLV-based retrovirus vectors and HIV-1–based lentivirus vectors. Both vectors transduced the primary B-precursor ALL cells with high efficiencies. These studies may be applied for investigating gene delivery into primary human B-precursor ALL cells to be used for immunotherapy.

Prospects for gene therapy in human prostate cancer

Prostate cancer is the most common neoplasm in men and a significant cause of mortality in affected patients. Despite significant advances, current methods of treatment are effective only in the absence of metastatic disease. Gene therapy offers a renewed hope of using the differential characteristics of normal and malignant tissue in constructing treatment strategies. Several clinical trials in prostate cancer gene therapy are currently under way, using immunomodulatory genes, anti-oncogenes, tumor suppressor genes and suicide genes. A continued understanding of the etiological mechanisms involved in the establishment and progression of prostate cancer, along with advances in gene therapy technology, should make gene therapy for prostate cancer therapeutically valuable in the future.

CTLA-4 blockade synergizes with tumor-derived granulocyte-macrophage colony-stimulating factor for treatment of an experimental mammary carcinoma

Generation of a T cell-mediated antitumor response depends on T cell receptor engagement by major histocompatibility complex/antigen as well as CD28 ligation by B7. CTLA-4 is a second B7 receptor expressed by T cells upon activation that, unlike CD28, appears to deliver an inhibitory signal to T cells. Recently, we and others demonstrated that administration of an anti-CTLA-4 antibody was sufficient to promote regression of several murine tumors. However, certain tumors, such as the SM1 mammary carcinoma, remain refractory to this type of immunotherapy. In the present study, we report that the combination of both CTLA-4 blockade and a vaccine consisting of granulocyte-macrophage colony-stimulating factor-expressing SM1 cells resulted in regression of parental SM1 tumors, despite the ineffectiveness of either treatment alone. This synergistic therapy resulted in long-lasting immunity to SM1 and depended on both CD4(+) and CD8(+) T cells. Interestingly, synergy was not observed between CTLA-4 and a B7-expressing SM1 vaccine. Given that granulocyte-macrophage colony-stimulating factor promotes differentiation and activation of dendritic cells as well as enhances cross-priming of T cells to tumor-derived antigens and that SM1 is major histocompatibility complex class II-negative, our findings suggest that CTLA-4 blockade acts at the level of a host-derived antigen-presenting cell. In addition, these results also support the idea that the most effective and synergistic vaccine strategy targets treatments that enhance T cell priming at the level of host-derived antigen-presenting cells.

Induction of a CD3+/CD56+ lymphocyte population following gene therapy with transgenic IL-2 secreting fibroblasts in a child with peripheral neuroectodermal malignancy

BACKGROUND

Adjuvant interleukin-2 (IL-2) therapy after stem cell transplantation can improve the prognosis of patients with Ewing tumors. This has been attributed to stimulation of the immune system and its antineoplastic activity, thus eliminating minimal residual disease. As the side effects of systemic IL-2 limit the dosage, attempts have been made to locally augment the concentration of IL-2 in the proximity of the tumor. To achieve this, fibroblasts and/or tumor cells can be genetically modified to secrete IL-2 and then be injected to generate tumor immunogen.

PROCEDURE

In a preliminary clinical trial we assessed whether the administration of transgenic IL-2-secreting fibroblasts was feasible without major toxicity and whether it had any effect regarding the activation of the immune system. We treated an 11-year-old boy with a peripheral neuroectodermal tumor of the left neck in fourth relapse, who was refractory to all available therapy. We transfected fibroblasts of the patient with an IL-2 gene expression vector using a cationic liposome reagent. In 51Cr cytotoxicity assays we obtained lysis of this patient's tumor cells by IL-2-stimulated mononuclear cells (MNCs). Under CT-guidance we intratumorally injected IL-2 transgenic autologous fibroblasts.

RESULTS

We observed no local or systemic toxicity. In addition, we found a rise in the CD3+CD56+ lymphocyte population, previously described as cytokine-induced killer cells. No other hematological parameter changed significantly.

CONCLUSIONS

Our data suggest that the intratumoral injection of transgenic IL-2-secreting fibroblasts is feasible without major toxicity and may lead to an increase in CD3+CD56+ cells.

An IgG3-IL-2 fusion protein recognizing a murine B cell lymphoma exhibits effective tumor imaging and antitumor activity

Antibody (Ab)-based tumor therapeutics use the tumor-binding specificity of the Ab to target Fc functions or associated molecules to the site of the tumor. We have used an Ab-interleukin-2 (IL-2) fusion protein to deliver IL-2 to a murine B cell lymphoma (38C13). This anti-Id IgG3-CH3-IL-2, which recognizes the idiotype present on the surface of the lymphoma has a half-life in mice approximately 17-fold longer than the half-life reported for IL-2. Gamma camera studies showed that anti-Id IgG3-CH3-IL-2 localizes at the site of a subcutaneous tumor in mice. The anti-Id IgG3-CH3-IL-2 also shows enhanced antitumor activity compared with the combination of Ab and IL-2 administered together. However, the mechanism of antitumor activity appears to depend on the dose and the treatment schedule used. A single dose of fusion protein prevented tumor in only 50% of the animals, although all the survivors showed some evidence of immunologic memory. Although multiple doses are more effective in preventing tumor growth (87% survivors), they are ineffective in generating protective immunologic memory. Our results suggest that Ab-IL-2 fusion proteins will be useful in the diagnosis and treatment of human B cell lymphomas and other related malignancies.

Multiple effects of transfection with interleukin 2 and/or interferon gamma on the behavior of mouse T lymphoma cells

We have previously reported that transfection of mouse interferon gamma (IFN-gamma) in H-2Kk-positive BW variants (BW-Sp3) abolishes tumorigenicity and reduces metastatic capacity. To further increase the immunogenicity of BW-Sp3 cells, the gene for human interleukin 2 (huIL-2) was transfected in these cancer cells. Single BW-Sp3(huIL-2) and double BW-Sp3(huIL-2+IFN-gamma) transfectants were generated and their behavior was investigated as compared to parental and IFN-gamma-transfected BW-Sp3. Although expression of huIL-2 was equally effective as IFN-gamma in preventing tumor formation and reducing experimental metastasis, it did not confer protection to spontaneous metastases and even reversed the anti-metastatic activity of IFN-gamma. Inoculation of the BW variants in immunocompromised mice revealed that expression of IL-2 activates both T cells and aspecific immune effectors. However, in immunocompromised mice a clear pro-metastatic effect of IL-2 was recorded. Analysis of membrane antigens on the different variants showed a selective effect of huIL-2 on the expression of two surface antigens, i.e. L-selectin and metastatic T cell hybridoma antigen (MTH), which may contribute to metastasis. Hence upon expression of huIL-2 in T lymphoma variants, tumor outcome will depend on the balanced effects of the transfected cytokines on the immune response and the redirected effect on tumor progression.

Coadministration of IL-12 or IL-10 expression cassettes drives immune responses toward a Th1 phenotype

Cytokines are important regulators of the immune response. They influence immune expression, the development of immunologic memory, and regulation of antigen-specific and nonspecific immune activation as well as allergic responses. In a model system in mice, we have studied the effect of plasmids expressing interleukin (IL)-10 or IL-12 on the modulation of antigen-specific responses. Coadministration of IL-12 or IL-10 genes with DNA immunogens directed the antigen-specific immune response toward a T helper (Th1)-type immunity. In addition to the modulation of antigen-specific immune responses, we studied the induction of delayed-type hypersensitivity (DTH) to contact allergens as an in vivo model of the Th1 response. We found that IL-12 and IL-10 gene-containing plasmids, and not the bacterial plasmid alone, upregulate this response. Our cytokine gene delivery technique demonstrates an important level of control of the magnitude and direction of induced immune responses and could be advantageous in a wide variety of immunotherapeutic strategies.

Transduction of human hepatocellular carcinoma cells with human γ-interferon gene via retroviral vector

AIM: To investigate the therapeutic potential of gamma interferon (IFN-γ) genemodified human hepatocellular carcinoma (HCC) cells.

METHODS: The IFN-γ gene was introduced retrovirally into four HCC cell lines. Secreted IFN-γ activity was assessed using bioassay. The expression of MHC molecules was detected by FACS. Tumorigenicity was analysed by tumor formation in nude mice.

RESULTS: Four IFN-γ gene transduced HCC cell lines secreted different amounts of IFN-γ, as in the same case of five clones derived from one HCC cell line. Transduction with IFN-γ caused significant increase in the expression of major histocompatibility complex (MHC) antigens on HCC cells. The expression of HLA class I was increased by 2-3 times in terms of mean fluorescence intensities, while for class II expression, the percentage of positive cells augmented from < 10% to > 50%. When equal amount of tumor cells were injected into nude mice, the tumor igenicity some transduced cells decreased dramantically.

CONCLUSION: IFN-γ gene transduction can convert weakly imunogenic HCC cells to activate antitumor immune response, and further pave the way for the future use of such gene modified tumor cells as a modality for the cancer immunotherapy.

In vivo tumor transfection with superantigen plus cytokine genes induces tumor regression and prolongs survival in dogs with malignant melanoma

In vivo transfection of established tumors with immunostimulatory genes can elicit antitumor immunity. Therefore, we evaluated the safety and efficacy of intratumoral injections of a bacterial superantigen with a cytokine gene in dogs with malignant melanoma, a spontaneous and highly malignant canine tumor. 26 dogs with melanoma were treated with lipid-complexed plasmid DNA encoding staphylococcal enterotoxin B and either GM-CSF or IL-2. Dogs were evaluated for treatment-associated toxicity, tumor responses, immunologic responses, and survival times. The overall response rate (complete or partial remissions) for all 26 dogs was 46% (12 of 26), and was highest in patients with smaller tumors. Toxicity was minimal or absent in all dogs. Injected tumors developed marked infiltrates of CD4+ and CD8+ T cells and macrophages, and tumor regression was associated with development of high levels of antitumor cytotoxic T lymphocyte activity in peripheral blood lymphocytes. Survival times for animals with stage III melanomas treated by intratumoral gene therapy were prolonged significantly compared with animals treated with surgical tumor excision only. Thus, local tumor transfection with superantigen and cytokine genes was capable of inducing both local and systemic antitumor immunity in an outbred animal with a spontaneously developing malignant tumor.

Gene therapy for lung cancer

Gene therapy has received considerable attention and some speculation as to its value. Although few patients have been treated, the preliminary results of the phase I lung cancer gene therapy clinical trials are very promising. Clinically relevant basic research in the molecular pathogenesis and immunology of lung cancer is progressing. As improved vector technologies are developed, new opportunities will be available to initiate lung cancer gene therapy trials that are based on a more detailed understanding of lung cancer biology. In conclusion, although important biologic and technical questions remain unanswered, recent research suggests that gene therapy will have a profound impact on lung cancer treatment.

Gene therapy for hepatic micrometastasis of murine colon carcinoma

BACKGROUNDS/AIMS

Pit cells are located in the hepatic sinusoids and are organ-associated natural killer cells that contribute to immune surveillance in the liver. In the present study, the interleukin-2 gene was introduced into hepatocytes using an adenovirus vector to induce interleukin-2 production in an attempt to enhance the natural killer activity of pit cells, leading to inhibition of metastasis of colon carcinoma.

METHODS

The recombinant adenovirus vector "Adex1CAmIL2" was constructed by inserting an expression unit which was composed of the CAG promotor (cytomegalovirus enhancer plus chicken beta-actin promotor), murine interleukin-2 cDNA, and a rabbit beta-globin polyadenylation signal. After administration of Adex1CAmIL2 to mice (4x10(7) pfu per animal), the expression of murine interleukin-2 in hepatocytes was examined by immunostaining and in situ hybridization, and the natural killer activity of hepatic mononuclear cells was measured. Inhibition of hepatic metastasis of colon carcinoma was examined after infusion of colon 38 tumor cells into the superior mesenteric vein.

RESULTS

After administration of Adex1CAmIL2, interleukin-2 mRNA expression was demonstrated in hepatocytes until day 7, and the serum interleukin-2 level was increased. The natural killer activity of hepatic mononuclear cells was markedly enhanced for 7-10 days. Hepatic metastasis was inhibited by administration of Adex1CAmIL2 until day 7 after tumor cell inoculation.

CONCLUSION

These results suggest that gene therapy using Adex1CAmIL2 could be potentially useful for inhibiting hepatic micrometastasis by enhancing the natural killer activity of pit cells.

Combination gene therapy for salivary gland cancer

An established combination gene therapy strategy involving adenovirus vector delivery of the herpes thymidine kinase (tk) and murine interleukin-2 genes was adapted to treat salivary gland cancer in a murine model. Salivary tumors were generated by transcutaneous injection of 5 x 10(5) murine squamous carcinoma cells into the submandibular gland of syngeneic C3H/HeJ mice. After one week, established submandibular gland tumors were injected with a recombinant adenovirus containing therapeutic and control genes. Animals were subsequently administered ganciclovir twice daily (25 mg/kg) for six days. All animals receiving tk and ganciclovir demonstrated tumor regression, however a significantly greater response was seen in mice that were treated with both tk + mIL-2. Residual tumors from all treatment and control groups were harvested for microscopic evaluation and immunohistochemistry staining. Specific immunostaining revealed a predominance of CD8+ lymphocytes in the tumor beds of the animals treated with IL-2, suggesting a preferential immune response resulting from the local IL-2 expression. Although still in its infancy, the concept or using adenoviral gene therapy strategies to provide less invasive means of treating salivary tumors is promising.

Antileukemic activity of TNF-alpha gene therapy with myeloid progenitor cells against minimal leukemia

Tumor necrosis factor-alpha (TNF-alpha) has exhibited antitumor activity against a variety of tumors in rodents and human tumor xenografts in nude mice, but it has been only marginally effective in cancer patients because of dose-limiting toxicity associated with systemic TNF-alpha therapy. To circumvent toxicity and to test the antileukemic activity against quantitated minimal leukemia, we have cloned human TNF-alpha (HuTNF-alpha) gene in an advanced myeloid progenitor cell line. 32Dcl3 myeloid progenitor cells transfected with HuTNF-alpha cDNA by the retroviral supernatant infection method stably express HuTNF-alpha gene and secrete substantial amounts of HuTNF-alpha. When injected i.v. into irradiated mice, transduced cells could be detected in the marrow but not in spleen or liver 10-12 days later. Injection of 5 x 10(6) transduced cells produced no obvious symptoms of TNF-alpha toxicity (i.e., weight loss, cachexia, or fever) suggesting that TNF-alpha producing cells are well tolerated by the recipient mice. Coinjection of 5 x 10(6) transduced cells and 10(2) or 10(3) 32Dp210 leukemia (BCR/ABL+) cells resulted in inhibition of leukemia development by 10(2) but not 10(3) 32Dp210 cells. An equal dose of nontransduced 32Dcl3 cells was ineffective in inhibiting leukemia progression by 10(2) 32Dp210 cells. Mice that rejected leukemia were BCR/ABL oncogene negative 8 weeks after leukemia cell injection. These data demonstrate the potential for TNF-alpha gene therapy for destroying residual leukemia, without the toxicity of systemic TNF-alpha therapy, following cytoreductive therapy and bone marrow transplant.

Interleukin-2 gene therapy of surgical minimal residual tumour disease

Our study was designed to examine the effects of IL-2 gene therapy in a surgical minimal residual tumour disease (SMRTD). Mice were inoculated s.c. with methylcholanthrene (MC)-induced MC12 sarcoma cells. When the tumours reached 8 to 12 mm in diameter, they were excised, either completely ("microscopic SMRTD") or incompletely ("macroscopic SMRTD"). On day 90 after surgery, the tumour recurrence rate in untreated mice with microscopic SMRTD was approximately 30%, whereas in those with macroscopic SMRTD it was 75%. After surgery, experimental mice were treated with 2 types of irradiated, IL-2 gene-modified, IL-2-producing tumour cell vaccine. One type of vaccine was derived from the MC12 sarcoma cells (MC12-1L2/IV-3); the other type was derived from an unrelated X63-Ag8.653 plasmacytoma (X63-m-IL-2). Both types of vaccine failed to cure the macroscopic SMRTD. Whereas the X63-m-IL-2 vaccine was also ineffective in the microscopic SMRTD, the MC12-IL2/IV-3 vaccine was capable of preventing growth in all but one mouse (1164) with microscopic SMRTD when administered 2 to 5 days after surgery. If the vaccination took place 2 days before surgery or later than 5 days after surgery, the therapeutic activity was lost. Vaccination with irradiated parental MC12 cells did not produce any significant benefit compared to the operated-only mice. The protective effect of the MC12-L2/IV-3 vaccine was specific and comparatively long-lasting. Vaccinated mice, which had rejected the MC12 tumour residuum, were capable of rejecting a second inoculum of the MC12 sarcoma cells injected on days 35 to 110 after surgery but succumbed to the growth of 2 other unrelated murine sarcomas carrying different tumour-rejection antigens.

Retroviral vector targeting to melanoma cells by single-chain antibody incorporation in envelope

Two strategies for targeting recombinant retroviruses to melanoma cells were compared. One was to extend the tropism of an ecotropic envelope to human melanoma cells, the other was to enhance the tropism of an amphotropic envelope for melanoma cells. Chimeric retroviral envelopes, incorporating a single-chain antibody (ScFv) directed against high-molecular-weight melanoma-associated antigen (HMWMAA) at the amino terminus are correctly processed and incorporated into virions. ScFv-ecotropic envelope chimeras allow specific, but low-titer, targeting of HMWMAA-positive cells, when co-expressed with ecotropic envelopes. ScFv-amphotropic envelope chimeras bind specifically to HMWMAA-positive cells and allow preferential infection at high titer.

Combination therapy with interleukin-2 and wild-type p53 expressed by adenoviral vectors potentiates tumor regression in a murine model of breast cancer

Although cytokine gene transfer for cancer treatment can stimulate immune recognition and tumor regression in animal models, there is still a need for improvements to these strategies. In this study, we examined the efficacy of a combination gene therapy using adenovirus (Ad) 5 vectors expressing human interleukin-2 and the wild-type (wt) human p53 gene under control of the human cytomegalovirus immediate early promoter (AdIL-2 and Adp53wt, respectively). Infected murine cell lines and primary mouse tumor cells secreted high levels of IL-2 and over expressed the p53 protein for at least 9 days. After infection of cells with Adp53wt, DNA synthesis was significantly inhibited and apoptosis was induced within 3-5 days. Both vectors were tested in a transgenic mouse mammary adenocarcinoma model for antitumor response. Following a single intratumoral injection of mice bearing PyMT induced tumors, the combination of Adp53wt (1 x 10(9) pfu) plus a relatively low dose of AdIL-2 (1.5 x 10(8) pfu) caused regressions in 65% of the treated tumors without toxicity. Fifty percent of the treated mice remained tumor free and were immune to rechallenge with fresh tumor cells. In contrast, injection of either vector alone at this does resulted in only a delay in tumor growth. Only mice co-injected with Adp53wt and AdIL-2 showed specific antitumor cytolytic T lymphocyte (CTL) activity, indicating that the immune response involved in tumor regression was promoted by the combination therapy. These results suggest that cancer treatment strategies involving combined delivery of immunomodulatory and antiproliferative genes may be highly effective.

A Double Recombinant Adenovirus Expressing the Costimulatory Molecule B7-1 (Murine) and Human IL-2 Induces Complete Tumor Regression in a Murine Breast Adenocarcinoma Model

Tumors that express tumor-specific antigens can maintain growth in an immunocompetent organism. Current hypotheses tend toward T cell anergy as a key component for the inhibition of immunoreactivity against such tumors. Anergy is thought to occur from hyperactive stimulation of the TCR in the absence of costimulation (costimulation leads to proliferation via IL 2 production). Subcutaneous injection of transgenic polyoma middle T transformed breast adenocarcinoma tumor cells (PyMT) in the hind flank of FVB/n mice results in the formation of tumor nodules at this site. We determined the MHC class I and class II, B7-1, and B7-2 expression in the tumor cells by flow cytometry and showed positive staining for only MHC class I. We show that a single E1-deleted adenovirus constructed to express both the costimulatory molecule B7-1 (murine) and human IL-2 genes (Ad5E1 mB7-1/human IL-2) elicits a very potent antitumor response when administered intratumorally. Ad5E1 mB7-1/human IL-2 induced rapid and complete regression (100%) of all tumors compared with Ad5 E1 mB7-1 (38%), Ad CAIL-2 (42%), and Ad5E1 dl70-3 (control vector) (0%). All mice that exhibited complete tumor regression were fully protected in tumor cell challenge experiments. The systemic immunity generated by intratumoral administration of the Ad vectors was associated with a strong anti-PyMT CTL response. These observations indicate that augmenting the immunogenicity of the tumor with coincident expression of B7-1 in combination with IL-2 may prove beneficial in direct tumor immunotherapy.

Immunotherapy for medullary thyroid carcinoma by a replication-defective adenovirus transducing murine interleukin-2

We have evaluated the feasibility of gene transduction using replication-defective adenovirus vector as a novel therapy for medullary thyroid carcinoma (MTC), a thyroid C cell neoplasm. Replication-defective adenoviruses were constructed to express murine interleukin-2 (mIL-2) gene and Escherichia coli beta-galactosidase (beta-gal; lacZ) gene under the control of the human cytomegalovirus (CMV) promoter (AdCMVmIL2, AdCMVbeta-gal) by homologous recombination. The efficiency of transduction was evaluated using AdCMVbeta-gal at different conditions. The gene transduction efficiency was dependent on multiplicity of infection, duration of exposure to the virus, and viral concentration. The expression of functional mIL-2 in transduced tumor cells was verified both in vitro and in vivo. Two cell lines (rat MTC and mMTC) secreted large amounts of functional mIL-2 after transduction, as tested in cytotoxic T lymphocyte (CTL) L-2 cells. When AdCMVmIL2-infected mMTC cells were injected s.c. into their host animals, tumors developed in 2 of 10 animals, in contrast to 9 of 10 animals injected with AdCMVbeta-gal-infected mMTC cells and all 10 animals injected with parental mMTC cells. Moreover protected animals developed a long lasting immunity against mMTC tumor cells and their splenocytes, showing cytotoxicity to parental tumor cells, and active natural killer (NK) cell activity. BALB/c-SCID (severe combined immune deficiency) mice were also used to evaluate the function of NK cells in antitumor activities. No tumor developed in SCID mice injected with AdCMVmIL2-infected cells, whereas all animals injected with either AdCMVbeta-gal-infected or parental mMTC cells developed tumors. Our data indicate that IL-2 production by MTC cells leads to rejection in syngeneic animals and suggest that both cytotoxic T cells and NK cells may play an important role. In addition, transduction of adenoviral vectors into tumor cells produces some nonspecific antitumor effects.

Antigen presentation by B7-nonprofessional APC does not prevent responses to solid tumor cells

The growth of tumors in vivo often is associated with immune suppression. In this report we tested whether the expression of a known antigen by tumor cells would inhibit the development of antitumor responses when the antigen was subsequently expressed in an immunogenic form. For this, we expressed a well-characterized surrogate tumor antigen, the nucleoprotein (NP) of the PR8 virus, in solid tumor cells. Although the NP+ tumor cells were not rejected in vivo and stimulated nondetectable CTL response in vitro, T cells from these mice differentiated into CTL following i.p. inoculation of PR8 virus and their tumors regressed. The results suggested that prior presentation of tumor antigens by tumor cells does not necessary preclude a response if the peptide is subsequently presented appropriately.

Gene Immunotherapy in Murine Acute Myeloid Leukemia: Granulocyte-Macrophage Colony-Stimulating Factor Tumor Cell Vaccines Elicit More Potent Antitumor Immunity Compared With B7 Family and Other Cytokine Vaccines

In an attempt to explore novel treatment modalities in acute myeloid leukemia (AML), we studied the role of costimulatory and cytokine gene immunotherapy in murine AML. We have previously shown that leukemic mice can be cured with CD80 transfected leukemic cells (B7.1-AML vaccine) administered early in the course of the disease and that the failure B7.1-AML vaccines administered late cannot be attributed to immunosuppression induced by tumor growth. CD8+ T cells, which are necessary for tumor rejection, are activated rather than suppressed during the first half of the leukemic course in nonvaccinated mice. In this report, we question whether CD86 (B7.2) or the cytokines granulocyte-macrophage colony-stimulating factor (GM-CSF), interleukin-4 (IL-4), or tumor necrosis factor-α (TNF-α) can improve the vaccination potential of AML cells. The choice of cytokines was based on their combined and alone as well ability to direct the differentiation of CD34+ cells into potent antigen-presenting dendritic cells in vitro. Our studies show that (1) mice vaccinated with a leukemogenic number of AML cells engineered to express B7.2 (B7.2-AML) or to secrete GM-CSF, IL-4, or TNF-α (GM-, IL-4–, TNF-α–AML) do not develop leukemia; (2) GM-AML cells are tumorigenic in sublethally irradiated SJL/J mice but not in Swiss nu/nu mice, indicating that killing of tumor cells is not T-cell–dependent; (3) vaccines with irradiated GM-AML, but not B7.2-, IL-4–, or TNF-α–AML cells, can elicit leukemia-specific protective and therapeutic immunity; and (4) in head-to-head comparison experiments, vaccination with irradiated GM-AML is more potent than B7.1-AML, curing 80% and providing 20% prolonged survival of the leukemic mice at week 2, as opposed to cures only up to 1 week with B7.1-AML vaccines. These preclinical data emphasize that GM-CSF gene immunotherapy deserves clinical evaluation in AML.

Gene Immunotherapy in Murine Acute Myeloid Leukemia: Granulocyte-Macrophage Colony-Stimulating Factor Tumor Cell Vaccines Elicit More Potent Antitumor Immunity Compared With B7 Family and Other Cytokine Vaccines

In an attempt to explore novel treatment modalities in acute myeloid leukemia (AML), we studied the role of costimulatory and cytokine gene immunotherapy in murine AML. We have previously shown that leukemic mice can be cured with CD80 transfected leukemic cells (B7.1-AML vaccine) administered early in the course of the disease and that the failure B7.1-AML vaccines administered late cannot be attributed to immunosuppression induced by tumor growth. CD8+ T cells, which are necessary for tumor rejection, are activated rather than suppressed during the first half of the leukemic course in nonvaccinated mice. In this report, we question whether CD86 (B7.2) or the cytokines granulocyte-macrophage colony-stimulating factor (GM-CSF), interleukin-4 (IL-4), or tumor necrosis factor-α (TNF-α) can improve the vaccination potential of AML cells. The choice of cytokines was based on their combined and alone as well ability to direct the differentiation of CD34+ cells into potent antigen-presenting dendritic cells in vitro. Our studies show that (1) mice vaccinated with a leukemogenic number of AML cells engineered to express B7.2 (B7.2-AML) or to secrete GM-CSF, IL-4, or TNF-α (GM-, IL-4–, TNF-α–AML) do not develop leukemia; (2) GM-AML cells are tumorigenic in sublethally irradiated SJL/J mice but not in Swiss nu/nu mice, indicating that killing of tumor cells is not T-cell–dependent; (3) vaccines with irradiated GM-AML, but not B7.2-, IL-4–, or TNF-α–AML cells, can elicit leukemia-specific protective and therapeutic immunity; and (4) in head-to-head comparison experiments, vaccination with irradiated GM-AML is more potent than B7.1-AML, curing 80% and providing 20% prolonged survival of the leukemic mice at week 2, as opposed to cures only up to 1 week with B7.1-AML vaccines. These preclinical data emphasize that GM-CSF gene immunotherapy deserves clinical evaluation in AML.

Interleukin-2-mediated modulation of plasma cell tumor growth in a model of multiple myeloma

A number of studies have demonstrated that inoculation of certain types of cancer cells engineered for expression of the interleukin-2 (IL-2) gene results in reduced tumorigenicity and/or protection from subsequent challenge with a tumorigenic dose of wild-type cells. In the current studies, we have employed murine plasma cell tumors to examine IL-2-mediated tumor rejection as a possible model for therapeutic approaches to human myeloma or plasma cell leukemia. Two murine plasma cell tumor lines, S107 and X24, were infected with a retroviral vector expressing the human IL-2 gene, and the antitumor potential of IL-2-expressing infectants was characterized in syngeneic BALB/c and BALB/c nu/nu mice. Results demonstrate that tumorigenicity of both lines correlates inversely with the amount of IL-2 produced by the tumor cells. However, there are clear differences between the two lines in terms of reduced tumorigenicity and the ability to protect against co-injected parental tumor cells that appear unrelated to IL-2 levels. More importantly, intravenous immunization of animals with irradiated, IL-2 secreting cells from either line leads to significant protection from challenge with highly metastatic parental cells. These results suggest that such an approach may warrant consideration in the treatment of human plasma cell dyscrasias.

Genetic immunotherapy by intrapleural, intraperitoneal and subcutaneous injection of IL-2 gene-modified Lewis lung carcinoma cells

The induction and augmentation of tumor non-specific immunity and of tumor-specific immunity by intrapleural, intraperitoneal and subcutaneous injection of interleukin-2 (IL-2) gene-modified Lewis lung carcinoma (LLC) cells (LLC-IL2) was tested in C57BL/6 mice. Intrapleural injection of LLC cells induced lung tumors with a malignant effusion, intraperitoneal injection induced peritoneal tumors with ascites and subcutaneous injection induced subcutaneous tumors. Intrapleural injection of irradiated LLC-IL2 cured pre-existing lung LLC tumors and extended the survival of the mice but did not affect survival of mice with pre-existing peritoneal tumors nor did it affect the growth of s.c. tumors. Intraperitoneal injection of irradiated LLC-IL2 cured pre-existing LLC peritoneal tumors and extended the survival of the mice but did not affect survival of mice bearing lung tumors nor did it affect the growth of s.c. tumors. Subcutaneous injection of irradiated LLC-IL2 did not affect the growth of preexisting s.c. tumors and also did not improve survival of mice bearing the lung or peritoneal tumors. Injection with irradiated LLC-IL2 by all routes, i.e., intrapleural, intraperitoneal and s.c., protected against subsequent re-challenge with LLC. Eight days after the initial immunization (early stage of immunization), non-adherent mononuclear cells in the peritoneal cavity of the mice treated with intraperitoneal injection of irradiated LLC-IL2 displayed enhanced cytotoxicity against LLC, B16-F10 and P815 cells, while the cytotoxic activity of spleen cells in the same mice did not change. The efficiency of induction of tumor-specific immunity was the strongest after intraperitoneal immunization and weakest after s.c. immunization. In vitro analysis using the spleen cells of mice immunized with irradiated LLC-IL2 suggested that CD8+ T cells play a key role in tumor-specific immunity.

In vivo therapy of hepatocellular carcinoma with a tumor-specific adenoviral vector expressing interleukin-2

A recombinant adenovirus (AdVAFP1-IL2) containing the murine alpha-fetoprotein (AFP) promoter was constructed to direct hepatocellular carcinoma (HCC)-specific expression of the human interleukin-2 (IL-2) gene. In vitro testing of AdVAFP1-IL2 showed HCC-specific IL-2 gene expression three to four orders of magnitude higher in AFP-producing HCC lines compared to non-AFP producing non-HCC lines. The in vivo efficacy and tumor specificity of AdVAFP1-IL2 was evaluated compared to AdVCMV-IL2 (in which the IL-2 gene is driven by the strong constitutive cytomegalovirus promoter) in the treatment of established human HCC (Hep 3B/Hep G2) xenografts growing in CB-17/SCID mice. Intratumoral injection of AdV resulted in growth retardation and regression in a majority of established hepatomas, but with a much wider therapeutic index and less systemic toxicity using the AFP vector. This study illustrates the superiority of using transcriptionally targeted recombinant AdV vectors in cytokine-based gene therapy.

A family of bicistronic vectors to enhance both local and systemic antitumor effects of HSVtk or cytokine expression in a murine melanoma model

The herpes simplex virus-thymidine kinase/ganciclovir (HSVtk/GCV) system produces both direct and immune-mediated tumor cell killing. Here, we compare the efficacy of HSVtk/GCV with cytokines, alone and in combination, on the tumorigenicity and immunogenicity of B16 cells. With respect to single gene modifications, only HSVtk/GCV, or high-level interleukin-2 (IL-2) secretion, completely prevented tumor growth, whereas granulocyte-macrophage colony-stimulating factor (GM-CSF) generated the best levels of long-term systemic protection. To augment both local killing and immune activation, we constructed bicistronic constructs that express HSVtk and a cytokine within the same cell. Co-expression of HSVtk with IL-2 or GM-CSF enhanced the local antitumor activity of any gene alone. In a tumor-prevention model, HSVtk killing, in an environment preprimed with GM-CSF, generated the best long-term immune protection. However, in a short-term therapy model, continued IL-2 expression was most effective against 3-day established tumors. This probably reflects differences in the activities of IL-2 and GM-CSF in generating short-term, nonspecific immune stimulation compared to long-term immunological memory, respectively. As a prelude to in vivo delivery experiments, we also demonstrated that these bicistronic cassettes can be packaged normally into retroviral (5 x 10(5) virus/ml from pooled populations) and adenoviral vectors (5 x 10(9) virus/ml) and function as predicted within virally infected cells. This family of bicistronic vectors can be used to stimulate synergy between suicide and cytokine genes, overcomes the problems of delivering two genes on separate vectors, and should allow easier preparation of vectors for the delivery of multiple genes to patients' tumor cells.

Gene therapy with B7.1 and GM-CSF vaccines in a murine AML model

PURPOSE

Characterization of B7.1 and GM-CSF vaccines on the induction of anti-tumor immunity in a murine AML model.

MATERIALS AND METHODS

Primary AML cells were retrovirally transduced with the murine costimulatory molecule B7.1, a natural ligand for the T-cell receptors CD28 and CTLA-4, or the cytokine GM-CSF. Mice were vaccinated with irradiated AML cells expressing B7.1 or GM-CSF before or after inoculation of wild type AML cells.

RESULTS

Intravenous injection of irradiated B7.1 or GM-CSF expressing AML cells can provide long lasting systemic immunity against a subsequent challenge of wild type AML cells. Vaccination with irradiated B7.1 or GM-CSF expressing AML cells results in rejection of established leukemia when the vaccination occurs in the early stages of the disease. However, when the vaccines are administered > 2 weeks after leukemic inoculation, only mice which receive the GM-CSF vaccine are cured of leukemia.

CONCLUSIONS

These results suggest that tumor burden and vaccine efficiency are most likely to be the limiting factors in the curative potential of tumor vaccines. Novel approaches such as this experiment could provide improved therapeutic outcomes in patients with AML and other cancers.

Combination therapy with antibody and interleukin-2 gene transfer against multidrug-resistant cancer cells

In the present study, we examined the effect of interleukin-2 (IL-2) gene transfer into multidrug resistance (MDR) cancer cells on the therapeutic efficacy of MRK16. Human MDR ovarian cancer cells, AD10, were transduced with a bicistronic IL-2 retrovirus, Ha-IL2-IRES-Neo. The G418-resistant population, IL2-AD10, secreted IL-2 into the culture supernatant and did not form a tumor mass in nude mice. The IL2-AD10 cells were more susceptible to the cytotoxicity of murine spleen cells than AD10 cells in vitro. For examination of the effect of IL-2 gene transfer on the antitumor activity of MRK16 against P-glycoprotein-positive tumors, IL2-AD10 cells were co-transplanted s.c. with AD10 cells into nude mice in a ratio of 1:3, and the mice were treated with MRK16 on days 2 and 7. MRK16 markedly inhibited the growth of AD10 cells mixed with IL2-AD10 cells under conditions (0.3-1 microgram/body) where it showed only marginal effects on the growth of AD10 tumors. These findings suggest that IL-2 gene transfer potentiates the antitumor activity of MRK16 against MDR tumors.

New advances in microsphere-based single-dose vaccines

Polymer microspheres have shown great potential as a next generation adjuvant to replace or complement existing aluminum salts for vaccine potentiation. Microsphere-based systems can now be made to deliver subunit protein and peptide antigens in their native form in a continuous or pulsatile fashion for periods of weeks to months with reliable and reproducible kinetics, often obviating the need for booster immunizations in animal models. Microspheres have also shown potential as carriers for oral vaccine delivery due to their protective effects on encapsulated antigens and their ability to be taken up by the Peyer's patches in the intestine. The potency of these optimal depot formulations for antigen may be enhanced by the co-delivery of vaccine adjuvants, including cytokines, that are either entrapped in the polymer matrix or, alternatively, incorporated into the backbone of the polymer itself and released concomitantly with antigen as the polymer degrades. In this article we review the use of polymer microspheres for single-step immunization and discuss future applications for the improvement of vaccines and immunotherapies by utilizing encapsulation technology.

CD40 Ligand Induces an Antileukemia Immune Response In Vivo

Leukemia cells may express tumor specific antigens in association with Class I and II major histocompatability complex (MHC) molecules. However, lack of expression of conventional costimulator molecules means that these cells tend to induce specific T-cell anergy rather than activation. CD40 ligand (CD40L) is a costimulator molecule that directly activates T cells and may promote antigen presentation by CD40-expressing cells, which include professional antigen presenting cells and B-acute lymphoblastic leukemia (ALL) cells from many patients. We determined whether transgenic expression of CD40L could enhance an antileukemia immune response using a CD40+ murine lymphoblastic (A20) leukemia and a CD40− myeloblastic (WEHI-3) leukemia in a tumor treatment model. Injection of otherwise nonimmunogenic A20 cells in the presence of CD40L induced an immune response active against preexisting A20 tumor at a distant site. Moreover, concomitant local secretion of transgenic interleukin-2 (IL-2) further amplified the antileukemic response induced and increased protection against preexisting tumor. In ex vivo studies, CD40 activation of A20 cells enhances the antigen presenting potential of A20 cells by upregulating expression of B7.1 (CD80), Class I and II MHC molecules, and increases expression of fas antigens. The importance of CD40 activation to the resulting antitumor response is further emphasized by the failure of transgenic CD40L to protect against the CD40− WEHI myeloblastic leukemia. Depletion studies showed the protective effects against A20 cells to be mediated by a combination of CD4+ and CD8+ T lymphocytes and by natural killer (NK) cells. These results suggest a means by which CD40+ leukemia cells may be rendered immunogenic in vivo.

A Phase I clinical trial of immunotherapy with interferon-gamma gene-modified autologous melanoma cells: monitoring the humoral immune response

BACKGROUND

Tumor cells transduced with cytokine genes provide immunogenic vaccines for cancer immunotherapy.

METHODS

A Phase I clinical trial was conducted for the specific active immunization of melanoma patients with interferon-gamma (IFN-gamma) gene-modified autologous melanoma tumor cells. Short term melanoma cultures were transduced retrovirally with the gene for human IFN-gamma. The genetically modified melanoma cells secreted biologically active IFN-gamma and showed enhanced expression of major histocompatibility complex class I and class II surface antigens. These cells were inactivated by irradiation (50 gray) and were cryopreserved for the vaccine. Twenty melanoma patients were enrolled in this clinical trial. The immunizations were administered in escalating doses once every 2 weeks for 3 months. The first and second injections consisted of 2 million cells, followed by 6 million for the third and fourth injections, and then 18 million for the fifth and sixth injections. The humoral immune responses of the patients were assessed by enzyme-linked immunoadsorbent assay, radioimmunoassay, and radioimmunoprecipitation.

RESULTS

Thirteen of the 20 patients completed the immunization protocol. Eight of these 13 patients showed a humoral immunoglobulin (Ig)G response against autologous and allogeneic melanoma cells. The other five patients either had no detectable antimelanoma antibodies or showed a weak IgG response that did not rise significantly above the preimmune level. All the sera contained low or undetectable levels of antimelanoma IgM antibodies. The IgG response increased progressively in titer during the course of immunization. The positive sera showed preferentially strong binding to melanoma cell lines and some cross-reactivity to nonmelanoma tumors. A 75-80 kD antigen on melanoma cells was immunoprecipitated by postimmune sera of 3 of the responding patients. Preimmune sera from these three patients and sera from other patients immunized with a standard nontransduced melanoma cell vaccine failed to precipitate this antigen. Two patients with significant increases in serum IgG had clinical tumor regression, and two additional patients with low serum IgG response had transient shrinkage of nodular disease during therapy.

CONCLUSIONS

These data suggest that gene therapy with IFN-gamma-transduced melanoma cells is safe and worthy of further investigation in patients with less advanced stage malignant melanoma. The ability to monitor changes in the humoral responses of the immunized patients has been demonstrated.

Current status of melanoma vaccines

BACKGROUND

Malignant melanoma is increasing worldwide faster than any other cancer and the American lifetime risk is estimated to reach 1 in 75 by the year 2000. Active specific immunotherapy with vaccines is evolving as a promising new modality in the treatment of malignant melanoma.

OBJECTIVE

To present a concise and understandable summary of the key molecular and clinical concepts of melanoma vaccines currently under investigation, the history that led to their development, and their anticipated clinical response.

METHODS

The recent advances in the field of melanoma immunobiology and the newest experiment vaccines are reviewed.

RESULTS

There is no effective melanoma vaccine that successfully treats or prevents melanoma. However, their use has been associated with regression or delayed disease progression in some cases. The minority of patients who do have a major clinical response to vaccine therapy experience an improvement in survival. Even in those patients in whom melanoma vaccines cannot improve survival, the paucity of severe side effects has provided a quality of life superior to standard multiagent chemotherapy.

CONCLUSION

Melanoma vaccines are relatively safe immunotherapeutic modalities for the management of malignant melanoma. The clinical effectiveness of melanoma vaccines is unclear and adequately controlled studies need yet to be performed. Current melanoma vaccines manipulate antigen presentation networks and combine the best cellular and antibody antitumor immune response effective in mediating tumor protective immunity; these combination vaccines hold the most promise. The ideal melanoma vaccine will ultimately prevent melanoma.

Cytokine gene therapy of cancer using gene gun technology: superior antitumor activity of interleukin-12

We compared the antitumor effect of several transgene expression plasmids encoding specific cytokines, including interleukin-2 (IL-2), IL-4, IL-6, IL-12, interferon-gamma (IFN-gamma), tumor necrosis factor-alpha (TNF-alpha), and granulocyte-macrophage colony-stimulating factor (GM-CSF), following gene gun-mediated DNA delivery into the epidermis overlying an established intradermal murine tumor. IL-12 gene therapy was much more effective than treatment with any other tested cytokine gene for induction of tumor regression. Strong activation of antitumor immunity in response to IL-12 gene therapy was evidenced by an augmented CD8+ T cell-mediated cytolytic activity in the draining lymph nodes of tumor-bearing mice. Furthermore, following the IL-12 gene therapy protocol, test mice were able to eradicate not only the treated but also the untreated solid tumors at distant sites. This systemic antitumor effect of IL-12 gene therapy was not associated with visible signs of toxicity or significantly elevated systemic levels of IFN-gamma. These results show that gene gun-mediated in vivo delivery of IL-12 cDNA clearly distinguishes itself from the other cytokine gene therapy approaches tested in parallel, suggesting that this delivery system may be employed as an efficient model for comparative studies of in vivo cytokine gene therapy. The results also suggest that the current IL-12 gene therapy strategy may provide a safer alternative to IL-12 protein therapy for clinical treatment of cancers.

Protective and therapeutic immunity against leukemia induced by irradiated B7-1 (CD80)-transduced leukemic cells

B7 molecules provide an important co-stimulatory signal for T cell receptor/CD3-mediated T cell activation via binding to their cognate receptors, CD28 and CTLA-4. We have introduced B7-1 (CD80) into M1 cells, spontaneously occurring mouse myelocytic leukemic cells, and assessed its potential to induce antitumor immunity to leukemia cells. Syngeneic, immunocompetent SL mice receiving two independent B7-1-transduced monoclonal sublines, M1-B7-1/F/clone F20 and M1-B7-1/F/clone F7, were rejected in 57% and 43% of SL mice, respectively. In vivo depletion of T cell subsets showed that both CD4+ and CD8 T cells were indispensable for the B7-1-dependent anti-leukemic immunity. Although a single exposure of irradiated monoclonal M1-B7/1/F cells was not fully effective, multiple exposures induced protective immunity against subsequent challenge with parental M1 cells. Furthermore, multiple vaccinations with irradiated monoclonal M1-B7-1/F/clone F7 cells could cure 67% of mice previously injected with a lethal number of M1 cells. These results emphasize that multiple exposures of irradiated B7-1-transduced myeloid leukemic cells can induce protective and therapeutic immunity against leukemia and that B7-1-mediated gene therapy may have therapeutic efficacy for patients with acute myelocytic leukemia.

Human gastric carcinoma transduced with the IL-2 gene: increased sensitivity to immune effector cells in vitro and in vivo

We transduced a human gastric carcinoma cell line, HR, with the interleukin 2 (IL-2) gene. Stable HR transfectants secreted nanogram quantities of biologically active IL-2 and had significantly increased expression of IL-2 mRNA relative to that in parental cells. Expression of intracellular IL-2 protein was not quantitatively different in the parental and IL-2 gene-transduced cells, although the former did not secrete IL-2. Surface expression of IL-2 receptors was comparable in the parental and transduced cells at the mRNA or protein levels. Nevertheless, in vitro proliferation of IL-2 gene-transduced HR cells was significantly more rapid than that of parental cells. Both parental and IL-2 gene-transduced HR cells were equally sensitive to lysis by IL-2-activated natural killer (A-NK) cells, as measured in 4 hr 51Cr-release assasys or to apoptosis induced by NK or A-NK cells, assessed in 1 hr 3H-TdR-release assays. In 24 hr MTT assays, however, the IL-2 gene-transduced cells were significantly more sensitive to these effector cells than were parental cells. Upon intrasplenic injection of 5 x 10(6) parental or transduced HR cells into nude mice, liver metastases developed. Metastases of parental HR cells killed the animals in 24 days. In contrast, metastases of the IL-2 gene-transduced HR cells became necrotic by day 14 and were found to be surrounded by murine NK cells and macrophages. Survival of nude mice injected with IL-2 gene-transduced HR cells was significantly prolonged (>50 days) relative to that of mice injected with parental HR. Thus, IL-2 gene-transduced HR cells produced sufficient amounts of functional IL-2 in vivo to be able to recruit to the tumor site and support functions of endogenous cytotoxic immune effector cells, which were responsible for regression of hepatic metastases and significant improvement of survival in these mice.

Expansion of CD3+CD56+ lymphocytes correlates with induction of cytotoxicity by interleukin-2 gene transfer in human breast tumor cultures

BACKGROUND

Mice immunized with murine mammary carcinoma cells genetically engineered to secrete interleukin-2 (IL-2) are rendered resistant to subsequent challenge with unmodified tumor cells, and in the case of mice bearing established tumors, the rate of development of pulmonary metastases is reduced. Despite these encouraging animal results, little is known about the induction of antitumor immunity by IL-2 gene transfer in human breast cancer.

METHODS

Adenovirally mediated IL-2 gene transfer was performed in 12 tumor fragment cultures established from seven primary breast cancers. Autologous tumor infiltrating lymphocytes (TILs) or peripheral blood mononuclear cells (PBMCs) were cocultured with transduced tumor fragments, and changes in phenotype and cytotoxicity were measured.

RESULTS

IL-2 was never detectable in the untransduced cultures, but it peaked at 5.0-1,324.8 ng/ml in the transduced cultures. Lymphocyte counts declined in all untransduced cultures, but they increased two- to sevenfold in four transduced cultures. CD4:CD8 ratios decreased from a mean of 2.11 at baseline to 1.27 after stimulation in coculture (p = 0.03). Expansion of lymphocytes expressing the natural killer cell phenotype (CD3-CD56+) occurred in only one culture, but the CD3+CD56+ population increased in four of six cultures. Lymphocytes from four of 10 cocultures generated significant cytotoxicity against allogeneic breast cancer cells. Induction of cytotoxicity correlated with expansion of the CD3+CD56+ phenotype (R2 = 0.805, p = 0.02).

CONCLUSIONS

IL-2 gene expression by human breast cancer causes expansion of CD3+CD56+ cytotoxic-lymphocytes. This phenotype is consistent with that of a non-major histocompatibility complex (MHC)-restricted cytokine induced killer cell population previously described.