An Ad5[E1-, E2b-]-HER2/neu vector induces immune responses and inhibits HER2/neu expressing tumor progression in Ad5 immune mice

Immunotherapy is a promising approach for the treatment of cancers. Modified adenovirus 5 (Ad5) vectors have been used as a platform to deliver genes encoding tumor associated antigens (TAA). A major obstacle to Ad5 vector immunotherapy has been the induction of vector immunity following administration or the presence of pre-existing Ad5 immunity, which results in vector mitigation. It has been reported by us that the Ad5[E1-, E2b-] platform with unique deletions in the E1, E2b and E3 regions can induce potent cell mediated immunity (CMI) against delivered transgene products in the presence of pre-existing Ad5 immunity. Here we report the use of an Ad5[E1-, E2b-] vector platform expressing the TAA HER2/neu as a breast cancer immunotherapeutic agent. Ad5[E1-, E2b-]-HER2/neu induced potent CMI against HER2/neu in Ad5 na?ve and Ad5 immune mice. Humoral responses were also induced and antibodies could lyse HER2/neu expressing tumor cells in the presence of complement in vitro. Ad5[E1-, E2b-]-HER2/neu prevented establishment of HER2/neu-expressing tumors and significantly inhibited progression of established tumors in Ad5 na?ve and Ad5 immune murine models. These data demonstrate that in vivo delivery of Ad5[E1-, E2b-]-HER2/neu can induce anti-TAA immunity and inhibit progression of HER2/neu expressing cancers.     

Systemic antitumor effect of intratumoral injection of dendritic cells in combination with local photodynamic therapy.

PURPOSE: Photodynamic therapy (PDT), which is used clinically for the palliative treatment of cancer, induces local tumor cell death but has no effect on tumors in untreated sites. The purpose of this study was to determine if local PDT followed by intratumoral injection of na?ve dendritic cells (IT-DC) induces systemic antitumor immunity that can inhibit the growth of untreated as well as PDT + IT-DC-treated tumors. EXPERIMENTAL DESIGN: BALB/c or C57Bl/6 mice were injected s.c. with CT26 colorectal carcinoma cells and B16 melanoma cells, respectively, and following 10 to 12 days of tumor growth, the tumors were treated with PDT alone or PDT followed by IT-DC or IT-PBS. In other studies, tumors were established simultaneously in both lower flanks or in one flank and in the lungs, but only one flank was treated. RESULTS: Whereas neither PDT nor IT-DC alone was effective, PDT + IT-DC eradicated both CT26 and B16 tumors in a significant proportion of animals and prolonged the survival of mice of which the tumors were not cured. The spleens of mice treated with PDT + IT-DC contained tumor-specific cytotoxic and IFN-gamma-secreting T cells whereas the spleens of control groups did not. Moreover, adoptive transfer of splenocytes from successfully treated CT26 tumor-free mice protected na?ve animals from a subsequent challenge with CT26, and this was mediated mainly by CD8 T cells. Most importantly, PDT plus IT-DC administered to one tumor site led to tumor regression at distant sites, including multiple lung metastases. CONCLUSIONS: PDT + IT-DC induces potent systemic antitumor immunity in mice and should be evaluated in the treatment of human cancer.     

Oncolytic poliovirus therapy and immunization with poliovirus-infected cell lysate induces potent antitumor immunity against neuroblastoma in vivo

In a previous study, we demonstrated that neuroblastoma subcutaneously implanted in immuno-competent mice is eliminated by intratumoral administration of neuroattenuated poliovirus (PV). Our results also suggested that the in vivo destruction of neuroblastoma cells by virotherapy lead to a robust antitumor immune response. In this work, splenocytes harvested from neuroblastoma-bearing animals treated with neuroattenuated PV exhibited significantly higher lytic activity against tumor target cells than did those from splenocytes derived from control mice. In vitro T-cell depletion experiments indicated that CD8(+) T cells were essential for the cytotoxic antitumor activity of splenocytes. Moreover, adoptive transfer of splenocytes obtained from mice cured of neuroblastoma by PV virotherapy markedly delayed the tumor growth of previously established neuroblastomas in recipient na?ve mice. These results confirmed that treatment with a neuroattenuated oncolytic PV strain induces antitumor immunity against neuroblastoma that is mainly mediated by cytotoxic CD8(+) T cells. Immunocompetent mice, on the other hand, were immunized with PV-infected neuroblastoma cell lysate prior intravenous challenge with neuroblastoma cells. As a control, mice were vaccinated with either non-infected neuroblastoma cell lysate alone or mixed with PV, or with PBS prior tumor cell injection. Results showed that survival is significantly prolonged only in mice immunized with PV-infected tumor lysate. This finding clearly suggested that in vitro poliovirus infection of neuroblastoma cells turns these cells into a potent tumor immunogen. Further studies in oncolytic treatment of neuroblastoma using attenuated PV alone or in combination with immunotherapy with PV oncolysate should improve the probability for successful translation in the clinic.     

Surrogate tumor antigen vaccination induces tumor-specific immunity and the rejection of spontaneous metastases

The nonimmunogenic 4T1 murine mammary carcinoma model and a model surrogate tumor antigen (sTA) were employed to explore the possibility of inducing tumor-specific immunity through active immunization in the absence of defined tumor-associated antigens. Immunization of naive mice with protein-based sTA resulted in protection from s.c. challenge, with 4T1 modified to express the sTA (4T1.sTA), or from a sTA-expressing unrelated tumor cell line (mKSA). Immunization had no effect on parental 4T1 tumor growth or the formation of parental 4T1 spontaneous lung metastases. Mice that were sTA immunized and successfully rejected 4T1.sTA challenge also rejected a subsequent challenge in the contralateral flank with parental 4T1 and strikingly prevented the formation of spontaneous parental 4T1 lung metastases. The rejection of parental 4T1 seemed to be specific for and associated with unknown 4T1 tumor-associated antigens, because rejection of mKSA did not induce cross-protection against a challenge with parental 4T1. To evaluate the effect of this vaccine approach on established disease, mice were simultaneously challenged on day 0 with 4T1.sTA and parental 4T1 in contralateral flanks and then immunized on days 3, 10, 17, and 24 with sTA protein. Tumor growth and metastasis were delayed in four of five animals, and 20% (2 of 5) of the animals were tumor free at the completion of the experiment. Together, these data suggest that prior vaccination with a sTA followed by inoculation with poorly immunogenic tumor cells modified to express the sTA activates determinant spreading and the induction of systemic tumor immunity resulting in indigenous tumor rejection.     

Immunization with type 5 adenovirus recombinant for a tumor antigen in combination with recombinant canarypox virus (alvac) cytokine gene delivery induces destruction of established prostate tumors

Prostate‐specific antigen (PSA) is expressed by prostate epithelial cells and has a highly restricted tissue distribution. Prostatic malignancies in 95% of patients continue to express PSA, making this antigen a good candidate for targeted immunotherapy. The goals of our studies are to generate a recombinant PSA adenovirus type 5 (Ad5‐PSA) that is safe and effectively activates a PSA‐specific T‐cell response capable of eliminating prostate cancer cells, and to characterize the immunologic basis for this rejection. Here we show that immunization of mice with Ad5‐PSA induced PSA‐specific cellular and humoral immunity that was protective against a subcutaneous challenge with RM11 prostate cancer cells expressing PSA (RM11psa), but not mock‐transfected RM11 tumor cells (RM11neo). Mice immunized with recombinant adenovirus type 5 encoding β‐galactosidase (Ad5‐lacZ) did not generate protective immunity. Antitumor activity was predominantly mediated by CD8⁺ T lymphocytes. Although Ad5‐PSA immunization prior to RM11psa challenge was protective, Ad5‐PSA immunization alone was not able to control the growth of existing RM11psa tumors. In contrast, established RM11psa tumors ranging in size from 500 to 1,000 mm³ were efficiently eliminated if Ad5‐PSA priming was followed 7 days later by intratumoral injection of recombinant canarypox viruses (ALVAC) encoding interleukin‐12 (IL‐12), IL‐2, and tumor necrosis factor‐α. In this case, antitumor immunity was still dominated by CD8⁺ T lymphocytes, but natural killer cells became necessary for a maximal response. These data provide information on the effector cell populations in a protective immune response to prostate cancer and demonstrate the utility of an Ad5‐PSA vaccine combined with cytokine gene delivery to eliminate large established tumors that are refractory to other interventional methods. © 2001 Wiley‐Liss, Inc.     

Doxorubicin resistant neuroblastoma cells secrete factors that activate AKT and attenuate cytotoxicity in drug-sensitive cells

Different vaccines based on naked DNA and the modified vaccinia virus Ankara (MVA) were compared for their efficiency to protect mice against tumors bearing the model antigen beta-galactosidase (beta-Gal) and for their potential to induce an antigen specific cellular immune response. Mice were immunized with the LacZ gene applied as naked DNA. In accordance with the observed beta-Gal-specific T-cell frequency, only 20% of mice boosted with LacZ naked DNA developed tumors whereas all mice boosted with MVA expressing LacZ developed a tumor. Mice vaccinated with mock DNA or mock virus developed tumors in 60 or 100%, respectively. MVA vaccination led to strong and long-lasting CD4- and CD8-T-cell responses against viral antigens but not against beta-Gal.     

CCL21 induces extensive intratumoral immune cell infiltration and specific anti-tumor cellular immunity

Chemokines are vital messengers that regulate immune cell activity. The chemokine CCL21 is normally expressed in secondary lymphoid organs and acts as a chemoattractant for several populations of immune cells. Herein, we report that intratumoral CCL21 administration recruited significant numbers of immune cells into murine pancreatic tumors and inhibited tumor growth. Detailed flow cytometric and confocal analysis of CCL21-treated tumor cell isolates revealed increased lymphoid-related dendritic cells (lDC) and myeloid DC (mDC), na?ve and mature T cells, natural killer (NK) cells, and NKT cells infiltrating the tumor mass. Furthermore, CCL21 intratumoral treatments resulted in significant tumor growth inhibition in wild-type (WT) C57BL/6 mice, but no therapeutic benefit was observed in C57BL/6 RAG2-/-Pfp-/- mice, suggesting that the growth inhibition observed was immunologically mediated. CCL21 intratumoral injections generated immune responses that were tumor-specific and that could be transferred to na?ve animals via splenocytes. In addition, intratumoral injection of CCL21 into pancreatic tumors reduced the growth of distant tumors as well as treated tumors. Thus, these data demonstrate in a pancreatic tumor model that intratumoral administration of CCL21 can cause significant immune cell infiltration of the tumor mass, delay growth of treated tumors, and generate a tumor-specific cellular immune response.     

Vaccination-induced autoimmune vitiligo is a consequence of secondary trauma to the skin

A major concern for cancer vaccines targeting self-tumor antigens is the risk of autoimmune sequelae. Although antitumor immunity correlates with autoimmune disease in some preclinical models, the mechanism(s) linking antitumor immunity and subsequent autoimmune pathology remain(s) to be determined. In the current study, we demonstrated that intradermal (i.d.) immunization with a recombinant adenovirus (Ad) expressing the murine melanoma antigen tyrosinase-related protein 2 (AdmTrp-2) results in a moderate level of tumor protection against the B16F10 murine melanoma without any vitiligo. Similar immunization with an Ad encoding human Trp-2 (AdhTrp-2) resulted in 50-fold greater protective immunity and produced vitiligo in all of the mice, suggesting that the development of autoimmunity may reflect the potency of the vaccine. Interestingly, delivery of AdhTrp-2 by i.m. injection generated protective immunity comparable with that seen in mice that received the vaccine by the i.d. route, but none of the recipients in the i.m. group developed vitiligo. The cellular and humoral responses in the i.m. immunized mice were greater than in the i.d. group; therefore, the lack of vitiligo was not caused by reduced efficacy of the vaccine. These results led us to hypothesize that vaccine-induced vitiligo was associated with local inflammatory responses. Mice immunized i.m. with AdhTrp-2 did develop vitiligo when they subsequently were injected i.d. with either a control Ad vector or complete Freund's adjuvant, suggesting that vitiligo is initiated by some form of trauma within the skin. Our data demonstrated that autoimmune pathology is not an unavoidable outcome of effective cancer vaccines directed against self-tumor antigens.     

Immunization with an antigen identified by cytokine tumor vaccine-assisted SEREX (CAS) suppressed growth of the rat 9L glioma in vivo

We have reported previously that s.c. immunization of rats with IL-4 transduced 9L gliosarcoma cells (9L-IL-4) induced a potent antitumor immunity against intracranial, parental 9L tumors. Subcutaneous implantation of 9L-IL-4 influenced the systemic humoral response, which was demonstrated by Th2-type isotype-switching and the induction of cellular immune responses, which played a critical role in the rejection of tumors. Serological analyses of recombinant cDNA expression libraries (SEREX), has recently emerged as a powerful method for serological identification of tumor-associated antigens (TAAs) and/or tumor rejection antigens (TRAs). Because IL-4 is known to activate B cells and to promote humoral responses, and inasmuch as induction of humoral responses by central nervous system tumors has been reported to be minimal, we investigated whether the induction of a potent humoral immune response against 9L TAAs or TRAs in rats immunized s.c. with 9L-IL4 could be demonstrated. Screening of 5 x 10(5) independent clones of 9L-expression cDNA library for the presence of reactive antibodies in the serum from a 91-IL-4 immunized rat led to the identification of three different TAAs. One 9L TAA (clone 29) was demonstrated to be calcyclin, a member of the S-100 family of calcium-binding proteins. The second 9L TAA (clone 37) was demonstrated to be the rat homologue of the J6B7 mouse immunomodulatory molecule. The third TAA (clones 158 and 171) was determined to be the rat homologue of the mouse Id-associated protein 1 (MIDA1), a DNA-binding, protein-associated protein. Northern blotting demonstrated that message for calcyclin was overexpressed in 9L cells. Message encoding MIDA1 was highly expressed in parental 9L cells and thymus and, to a lesser degree, in testis, suggesting that MIDA1 was comparable with the cancer/testis category of TAAs. Sera obtained from animals bearing 9L-IL-4 were found to have a higher a frequency and titer of antibodies to these antigens when compared with sera obtained from rats bearing sham-transduced 9L (9L-neo) cells. To determine whether immunization with these TAAs induced antitumor immunity, animals were immunized by intradermal injection with expression plasmids encoding calcyclin or MIDA1. Subsequent challenge of rats with parental 9L resulted in significant suppression of tumor growth in animals immunized with MIDA1, but not with calcyclin. These results indicate that MIDA1 is an effective 9L TRA and will be useful for the investigation of specific antitumor immunity in this glioma model. Furthermore, these results suggest that this approach, termed "cytokine-assisted SEREX (CAS)," may serve as an effective strategy for identification of TRAs for in animal-glioma models of cytokine gene therapy, and potentially in humans undergoing cytokine gene therapy protocols as well.     

Immune response to somatic cell hybrids between ultraviolet radiation-induced regressor and spontaneous progressor C3H mouse tumor cells

We used somatic cell hybridization to determine whether the regressor phenotype exhibited by UV-induced murine tumors was dominant or recessive and whether this technique could confer immunogenic properties on nonimmunogenic syngeneic tumors. We transfected a highly antigenic UV-induced C3H mouse tumor cell line (UV-2240) with the plasmid pSV2-neo and selected G418-resistant clones. The resulting cell line was fused with a spontaneously transformed nonimmunogenic C3H progressor tumor cell line (SF-2T) that had been selected previously for resistance to 3.0 mM ouabain. These two cell lines were fused by a brief exposure to polyethylene glycol and heterokaryons isolated by growth in medium containing both G418 and ouabain. Hybrid cell lines established from individual colonies and from pools of colonies were tested for tumorigenicity in normal C3H and athymic nude mice. The results indicated that all the hybrid cell lines tested were highly antigenic in that they were completely rejected when transplanted into normal syngeneic mice but grew progressively in nude mice. Furthermore, immunization of C3H mice with the hybrid cell lines induced protective immunity against challenge with the immunizing tumor and generated cross-protective immunity against challenge with the regressor parental cell line but not against challenge with the progressor parental cell line. These results demonstrate that the regressor phenotype of the UV-2240 tumor is dominant in nature and that the immune response induced by somatic cell hybrids is uniquely directed against the dominant tumor-specific transplantation antigens expressed on the regressor tumor. This implies that introduction of tumor-specific transplantation antigens from an immunogenic tumor into a nonimmunogenic tumor, although sufficient to confer immunogenic properties to the hybrid, is insufficient to induce cross-protective transplantation immunity against the nonimmunogenic tumor.     

Immunization against endogenous retroviral tumor-associated antigens.

Endogenous retroviral gene products have been found in some human tumors, and therefore, may serve as antigens for immunotherapy approaches. The murine colorectal carcinoma CT26 and melanoma B16 have recently been found to express the endogenous retroviral gene products gp70 and p15E, respectively, that can serve as antigens recognized by T cells. To date, though, there has been no demonstration of tumor treatment using an endogenous retroviral protein. In this study, we demonstrate that mice immunized with recombinant vaccinia encoding the gp70 H2-L(d)-restricted minimal determinant were protected from CT26 tumor challenge. Splenocytes from mice immunized with vaccinia gp70 specifically secreted IFN-gamma in response to gp70 peptide-pulsed stimulators. Although this strategy could protect against subsequent tumor challenge, it was ineffective against established tumors. Therefore, to investigate the treatment of established CT26 or B16 lung metastases, mice were treated with cultured dendritic cells (DCs) pulsed with gp70 or p15E peptide. Significant inhibition of established lung metastases required immunization with peptide-pulsed DCs pretreated with CD40 ligand that has been demonstrated to increase the T-cell stimulatory activity of DCs. The ability to immunize against endogenous retroviral tumor antigens may have relevance in the induction of antitumor immunity for some human cancers.     

Targeting of antigens to activated dendritic cells in vivo cures metastatic melanoma in mice

Anti (alpha)-DEC-205 antibodies target to the DEC-205 receptor that mediates antigen presentation to T cells by dendritic cells. To exploit these properties for immunization purposes, we conjugated the melanoma antigen tyrosinase-related protein (TRP)-2 to alphaDEC-205 antibodies and immunized mice with these conjugates together with dendritic cell-activating oligonucleotides (CpG). Upon injection of the melanoma cell line B16, alphaDEC-TRP immunized mice were protected against tumor growth. Even more important for clinical applications, we were able to substantially slow the growth of implanted B16 cells by injection of alphaDEC-TRP2 conjugates into tumor bearing hosts. Approximately 70% of the animals were cured from existing tumors by treatment with alphaDEC conjugates carrying two different melanoma antigens (TRP-2 and gp100). This protection was due to induction of melanoma-specific CD4 and CD8 responses. Thus, these data show that targeting of dendritic cells in situ by the means of antibody-antigen conjugates may be a novel way to induce long-lasting antitumor immunity.     

In situ tumor ablation creates an antigen source for the generation of antitumor immunity

Tumor-destructing techniques, like radiofrequency ablation (RFA), allow eradication of large tumors. Potentially, in situ tumor destruction also can provide the immune system with an antigen source for the induction of antitumor immunity. Antigen-presenting cells could take up antigens in the periphery after which they induce specific immune responses. Recent data show that especially antigen-presenting dendritic cells are crucial for the induction of potent immune responses. However, virtually nothing is known regarding the induction of immune responses after in situ tumor destruction in mice or humans. We used the well-defined murine B16-OVA melanoma cell line to develop a novel tumor model to explore: (a). the immunologic consequences of in situ tumor destruction; and (b). the efficacy of a combination approach of tumor destruction and immunostimulation. Applying this model system we demonstrate that following RFA, a weak but detectable immune response develops, directed against OVA, but also against a broader range of B16 antigens. Adoptive transfer experiments further indicate that antitumor reactivity can be transferred to na?ve mice by splenocytes. To augment the response observed, we administered a blocking monoclonal antibody against cytotoxic T-lymphocyte-associated antigen 4 at the time of tumor destruction. Interestingly, this strongly enhanced antitumor immunity, resulting in long-lasting tumor protection. These results illustrate that in situ tumor destruction can provide a useful antigen source for the induction of antitumor immunity, provided that additional immunostimulatory signals are coadministered.     

Increased immunogenicity of tumor vaccines complexed with anti-Gal: studies in knockout mice for alpha1,3galactosyltransferase.

A major prerequisite for the success of tumor vaccines is their effective uptake by antigen-presenting cells (APCs) and transport of these APCs to the draining lymph nodes, where the processed and presented tumor-associated antigens activate tumor-specific naive T cells. We previously suggested that the immunogenicity of autologus tumor vaccines in humans may be augmented by engineering vaccinating tumor cell membranes to express alpha-galactosyl (alpha-gal) epitopes (i.e., Galalpha1,3Galbeta1,4GlcNAc-R). Subsequent in situ binding of natural anti-Gal IgG molecules to these epitopes would result in the formation of immune complexes that target tumor vaccines for uptake by APCs, via the interaction of the Fc portion of anti-Gal with Fcgamma receptors on APCs. This hypothesis was tested in a unique experimental animal model of knockout mice for alpha1,3galactosyltransferase (alpha1,3GT) and the mouse melanoma B16-BL6 (referred to here as BL6). Like humans, these mice lack alpha-gal epitopes and produce anti-GaL BL6 melanoma cels are highly tumorigenic, and like human tumor cells, they lack alpha-gal epitopes. Expression of alpha-gal epitopes on these melanoma cells was achieved by stable transfection with alpha,3GT cDNA. The transfected melanoma cells (termed BL6alphaGT) express approximately 2 x 10(6) alpha-gal epitopes per cell and readily form immune complexes with anti-Gal. Vaccination of the mice with 2 x 10(6) irradiated melanoma cells that express alpha-gal epitopes, followed by challenge with 0.5 x 10(6) live parental melanoma cells, resulted in protection for at least 2 months (i.e, no tumor growth) in one-third of the mice, whereas all mice immunized with irradiated parental melanoma cells developed tumors 21-26 days post-challenge. The proportion of protected mice doubled when the mice were immunized twice with irradiated melanoma cells expressing alpha-gal epitopes and challenged with 0.2 x 10(6) live BL6 cells. Histological studies on the developing tumors in challenged mice that were immunized with melanoma cells expressing alpha-gal epitopes demonstrated extensive infiltration of T lymphocytes and macrophages, whereas no mononuclear cell infiltrates were observed in tumors of mice immunized with parental tumor cells. Overall, these studies imply that immunization of alpha1,3GT knockout mice with BL6 melanoma cells that express alpha-gal epitopes elicits, in a proportion of the population, protective immune response against the same tumor lacking such epitopes. These studies further suggest that similar immunization of cancer patients with autologous tumor vaccines that are engineered to express alpha-gal epitopes may increase the immune response to autologous tumor-associated antigens and, thus, may elicit immune-mediated destruction of metastatic cells expressing these antigens.     

Identification of functional domains of adenovirus tumor-specific transplantation antigen in types 5 and 12 by viable viruses carrying chimeric E1A genes

The adenovirus (Ad) EIA gene induces in immunized animals a strong tumor transplantation (TSTA) immunity against Ad tumors. Such immunity with group-A and group-C viruses is highly group-specific and no cross-protection is detected between se retypes 5 and 12. This fact was used to map the domains of the Ad 5 and Ad12 EIA gene products, respectively, which control the TSTA. We constructed a library of 8 recombinant viruses (H5sub1101 through H5sub1108) which carry chimeric Ad5/Ad12 EIA genes in the background of Ad5. The chimeric genes are functional and these viruses are viable. Some of these constructs induce strong and highly specific tumor syngraft immunity in immunized rats. The viruses carrying the 5′ terminus of the first EIA exon derived from Ad12 (viruses H5sub1101, H5sub1102 and H5sub1103) induce strong protection against Ad12 tumors irrespective of the rest of their EIA sequence. The viruses which carry the second exon of the AdS EIA gene (viruses H5sub1101, H5sub1102 and H5sub1106) protect against group-C tumors, regardless of the origin of the rest of their EIA gene. The 2 viruses that carry the 5′ EIA terminus of the first exon of Ad12 and the second exon of AdS (H5sub1101 and H5sub1102) are thus effective in inducing immunity against Ad12 tumors as well as against Ad2 tumors. The viruses which carry the 5′ terminus of the first exon derived from Ad5 and the second exon of Ad12 (H5sub1107 and H5sub1108) fail to induce immunity against either tumor. Expression of only the truncated 5′ terminus of the Ad12 EIA gene (viruses H5sub1104 and H5sub 1105) is sufficient for induction of Ad12 TSTA. Our results provide direct and unequivocal in vivo evidence that TSTA activities of adenovirus groups A and C are controlled by different domains of their respective EIA genes. The Ad12 TSTA is a function of the 5′ terminus of the first EIA exon, while the Ad5 TSTA is coded for by the 3′ exon of its EIA gene. © 1994 Wiley-Liss, Inc.     

Transplantable Marek's disease lymphomas. III. Induction of MHC-restricted tumor immunity by lymphoblastoid cells in F1 hosts

F1 chickens, which were a cross between birds of the related inbred lines G-B1 and G-B2, were immunized with in vitro cultured virus-non-producer lymphoblastoid cells that were either syngeneic or allogeneic with the challenge tumor cells. The lymphoblastoid cells were derived from Marek's disease herpesvirus (MDV)-induced transplantable tumors. Previous findings showed that such immunization of G-B1 and G-B2 chickens prevented early mortality caused by the tumors. Lymphoblastoid cells syngeneic with the tumors were more effective than allogeneic cells, suggesting that an MHC-restricted immune response was induced, or, alternatively, that immune elimination of allogeneic cells prevented them from initiating strong immunity to MDV-associated tumor antigens. Immune elimination of the immunizing cells should not occur in F1 birds heterozygous for the 2 different parental MHC haplotypes (B6 and B13). Early mortality among F1 chickens immunized with lymphoblastoid cells that were syngeneic with the challenge tumor cells was significantly lower than for non-immunized control chickens or for birds immunized with lymphoblastoid cells that were allogeneic with the challenge tumor cells. Our results suggest that MDV-induced tumor antigens may be recognized by the host as altered-self MHC antigens.     

Combined intratumoral injection of bone marrow-derived dendritic cells and systemic chemotherapy to treat pre-existing murine tumors

Dendritic cells (DCs) are attractive candidates for innovative cancer immunotherapy by virtue of their potential to function as professional antigen-presenting cells for initiating cellular immune responses. In this study, we evaluated a possible synergy of conventional chemotherapy together with intratumoral injection of syngeneic bone marrow-derived DCs for the treatment of preexisting tumors. Using murine CT26 colon adenocarcinoma cells (parental or modified to express beta-galactosidase as a model tumor antigen) to produce s.c. tumors in syngeneic BALB/c mice, the data demonstrate that direct injections of DCs at the tumor site result in partial eradication of established tumors. Strikingly, the addition of systemic chemotherapy (cyclophosphamide) combined with local intratumoral injection of DCs led to complete tumor regression in the treated animals. The tumor-free mice were able to resist a repeat challenge with the same tumor, suggesting that the animals had acquired long term antitumor immunity. Supporting evidence for the paradigm of systemic chemotherapy and intratumoral administration of DCs was obtained using melanoma B16 syngeneic tumor treated with Adriamycin plus DCs. These novel findings raise the possibility of using this potent strategy of combined intratumoral injections of DCs and systemic chemotherapy for cancer treatment.     

Native anti-tumor responses elicited by immunization with a low dose of unmodified live tumor cells

The present study demonstrates that immunization with a low dose of unmodified live myeloma tumor cells (FO) elicited tumor-specific immunity. BALB/c mice were vaccinated with 10(4) live dendritic cells (DC)-FO fusion cells or 10(3) live FO cells. 80% of vaccinated mice survived from the later challenge with 1 x 10(6) FO cells, whereas all control mice developed tumors. Additionally, vaccination with live FO cells gave no protection against the growth of Lewis lung carcinoma cells in C57BL/6 mice. Cellular immunity was found to be primarily responsible for anti-tumor responses. In an adoptive immune model, the development of myeloma was greatly reduced by transfusion of lymphocytes but not sera from mice immunized with FO. T cells from immunized mice also induced lysis of FO cells in the cytotoxic T lymphocyte (CTL) assay. After co-culture with FO, IFN-gamma released from immunized T helper cells increased >10-fold, while IL-4 remained unchanged in comparison with control T cells. These findings provided the first evidence that immunization with a low dose of unmodified live FO cells was safe to mice and capable of eliciting specific protective immunity against tumor growth.     

Idiotype vaccination post-bone marrow transplantation for B-cell lymphoma: initial studies in a murine model.

Studies in the 38C13 model, a lethal murine B-cell lymphoma of C3H origin, have previously demonstrated the efficacy of immunization with tumor idiotype against established tumors, especially in the setting of reduced tumor burden when combined with chemotherapy. We have extended these studies to test the protective effect of immunization with 38C13 idiotype protein (38C-Id), coupled to KLH and administered with an adjuvant, against a subsequent tumor challenge following lethal total body irradiation (950 R) and reconstitution with syngeneic bone marrow (20 x 10(6) cells) from normal donors. Animals prepared in this manner which were immunized with 38C-Id after 3 weeks recuperation and challenged with 1000 38C13 tumor cells 2 weeks later demonstrated significantly longer survival when compared to control animals which had been immunized with irrelevant idiotype protein. Irradiated reconstituted mice immunized after 5 weeks recuperation and challenged with 1000 tumor cells also demonstrated prolonged survival compared to controls, as well as a small number of cures (approximately 40%). Anti-38C-Id antibodies, implicated in the mechanism of idiotype induced anti-tumor immunity in this model, were detectable after immunization at both 3 and 5 weeks, although there was no significant correlation between serum antibody levels and survival of individual mice. These results suggest that immunologic recovery as early as 3 to 5 weeks following marrow grafting is sufficient to allow induction of idiotype-specific, anti-tumor immunity and form a model for our clinical trial of tumor idiotype vaccination for patients with B-cell lymphoma undergoing autologous BMT.     

Therapeutic vaccination against murine lymphoma by intratumoral injection of naive dendritic cells

Dendritic cells are potent antigen-presenting cells that can induce both immune responses and tolerance depending on their state of activation. Immunologic tolerance to established tumors is a major impediment for the development of effective cancer immunotherapy. Dendritic cells may be deficient in number or in function at the tumor site. To address this problem, we evaluated the ability of immature na?ve dendritic cells to induce an antitumor immune response when injected directly into a murine B-cell lymphoma. Mice with advanced transplanted syngeneic tumor were given intratumoral injections of bone marrow-derived dendritic cells. Intratumoral dendritic cell injection alone had no antitumor effect. Systemic chemotherapy alone resulted in only transient tumor regression. However, the intratumoral injection of dendritic cells after chemotherapy led to complete, long-term tumor regression in the majority of treated mice. This dendritic cell-mediated antitumor effect was systemic, resulting in simultaneous elimination of the tumor at second uninjected sites. In addition, it resulted in long-term memory with resistance to tumor rechallenge. Both CD4+ and CD8+ T cells are necessary for the antitumor effect. Furthermore, tumors that occasionally recurred in mice with initial complete tumor regression could be retreated by the same combined chemoimmunotherapy approach. These results show that immunotherapy can succeed in the setting of advanced lymphoma if dendritic cells are restored and loaded with tumor antigens in situ at a single tumor site.