Regression of intestinal adenomas by vaccination with heat shock protein 105-pulsed bone marrow-derived dendritic cells in Apc(Min/+) mice

Heat shock protein (HSP) 105 is overexpressed in various cancers, but is expressed at low levels in many normal tissues, except for the testis. A vaccination with HSP105-pulsed bone marrow-derived dendritic cells (BM-DC) induced antitumor immunity without causing an autoimmune reaction in a mouse model. Because Apc^Min/+ mice develop multiple adenomas throughout the intestinal tract by 4 months of age, the mice provide a clinically relevant model of human intestinal tumor. In the present study, we investigated the efficacy of the HSP105-pulsed BM-DC vaccine on tumor regression in the Apc^Min/+ mouse. Western blot and immunohistochemical analyses revealed that the tumors of the Apc^Min/+ mice endogenously overexpressed HSP105. Immunization of the Apc^Min/+ mice with a HSP105-pulsed BM-DC vaccine at 6, 8, and 10 weeks of age significantly reduced the number of small-intestinal polyps accompanied by infiltration of both CD4⁺ and CD8⁺ T cells in the tumors. Cell depletion experiments proved that both CD4⁺ and CD8⁺ T cells play a critical role in the activation of antitumor immunity induced by these vaccinations. These findings indicate that the HSP105-pulsed BM-DC vaccine can provide potent immunotherapy for tumors that appear spontaneously as a result of the inactivation of a tumor suppressor gene, such as in the Apc^Min/+ mouse model. ( Cancer Sci 2007; 98: 1930–1935)     

Targeting the immunoregulator SRA/CD204 potentiates specific dendritic cell vaccine-induced T-cell response and antitumor immunity

Although dendritic cell (DC) vaccines offer promise as cancer immunotherapy, further improvements are needed to amplify their clinical therapeutic efficacy. The pattern recognition scavenger receptor SRA/CD204 attenuates the ability of DCs to activate CD8(+) T-cell responses. Therefore, we examined the impact of SRA/CD204 on antitumor responses generated by DC vaccines and we also evaluated the feasibility of enhancing DC vaccine potency by SRA/CD204 blockade. DCs from SRA/CD204-deficient mice were more immunogenic in generating antitumor responses to B16 melanoma, compared with DCs from wild-type mice. Similarly, siRNA-mediated knockdown of SRA/CD204 by lentiviral vectors improved the ability of wild-type DCs to stimulate the expansion and activation of CD8(+) T cells specific for idealized or established melanoma antigens in mice. Using SRA/CD204-silenced DCs to generate antigen-targeted vaccines, we documented a marked increase in the level of antitumor immunity achieved against established B16 tumors and metastases. This increase was associated with enhanced activation of antigen specific CTLs, greater tumor infiltration by CD8(+) T cells and NK cells, and increased intratumoral ratios of both CD4(+) and CD8(+) T-effector cells to CD4(+)CD25(+) T-regulatory cells. Our studies establish that downregulating SRA/CD204 strongly enhances DC-mediated antitumor immunity. In addition, they provide a rationale to enhance DC vaccine potency through SRA/CD204-targeting approaches that can improve clinical outcomes in cancer treatment.     

Genetically modified dendritic cells prime autoreactive T cells through a pathway independent of CD40L and interleukin 12: implications for cancer vaccines

Genetic immunization through ex vivo transduction of dendritic cells has been suggested as an effective approach to enhance antitumor immunity by activating both CD4+ and CD8+ T cells. Immunizing mice with dendritic cells transduced with an adenovirus expressing the human melanoma antigen glycoprotein 100 (DCAdhgp100) as a cancer vaccine, we demonstrated complete protective immunity and a potent CTL response against melanomas expressing murine glycoprotein 100 in a CD4+ cell-dependent manner. Surprisingly, however, effective tumor rejection was not the result of cooperation between CD4+ and CD8+ T cells. Protective immunity was completely lost when CD4+ cells were depleted immediately before tumor challenge, whereas it was unaffected by removal of CD8+ cells, establishing a principal role for CD4+ cells in the effector phase of tumor rejection. Neither protective immunity nor CTL generation in this model required interleukin 12, in spite of high levels of IFN-gamma secretion by tumor-reactive T cells. Most notably, the DCAdhgp100 vaccine could elicit protective antitumor CD4+ cells in the absence of CD40 ligand, although it does not bypass the need for CD40-mediated signals to generate melanoma-reactive CTLs. Thus, in contrast to the current thinking that the optimal cancer vaccine should include determinants for both CD4+ and CD8+ cells, the potency of the DCAdhgp100 vaccine appears to be a result of its ability to directly prime autoreactive CD4+ cells through a process that does not require interleukin 12 and CD40 signals.     

Intratumoral administration of immature dendritic cells following the adenovirus vector encoding CD40 ligand elicits significant regression of established myeloma

Our previous study showed that J558 myeloma cells engineered CD40L lost their tumorigenicity in syngeneic mice, and the inoculation of J558/CD40L tumor cells further led to the protective immunity against wild tumors. In the present study, we investigated whether the vaccine can exert more efficient antitumor immunity by combination with adenovirus mediated CD40L gene therapy and immature dendritic cells (iDCs). The results demonstrated that intratumoral administration of iDCs 2 days after AdVCD40L injection, not only significantly suppressed the tumor growth, but also eradiated the established tumors in 40% of the mice. The potent antitumor effect produced by the combination therapy correlated with high expression of MHC, costimulatory and Fas molecules on J558 cells, which was derived from CD40L transgene expression. In addition, transgene CD40L expression could dramatically induce J558 cell apoptosis. Effectively capturing apoptotic bodies by iDCs in vivo could induce DC maturation, prime tumor-specific CTLs and tend to Th1-type immune response. Finally, in vivo depletion experimentation suggested both CD4+ and CD8+ T cells were involved in mediating the antitumor immune responses of combined treatment of AdVCD40L and iDCs, with CD8+ T cells being the major effector. These findings could be beneficial for designing strategies of DCs vaccine and CD40L for anticancer immunotherapy.     

Concurrent induction of antitumor immunity and autoimmune thyroiditis in CD4+ CD25+ regulatory T cell-depleted mice

When CD4+ CD25+ regulatory T cells are depleted or inactivated for the purpose of enhancing antitumor immunity, the risk of autoimmune disease may be significantly elevated because these regulatory T cells control both antitumor immunity and autoimmunity. To evaluate the relative benefit and risk of modulating CD4+ CD25+ regulatory T cells, we established a new test system to measure simultaneously the immune reactivity to a tumor-associated antigen, neu, and an unrelated self-antigen, thyroglobulin. BALB/c mice were inoculated with TUBO cells expressing an activated rat neu and treated with anti-CD25 monoclonal antibody to deplete CD25+ cells. The tumors grew, then regressed, and neu-specific antibodies and IFN-gamma-secreting T cells were induced. The same mice were also exposed to mouse thyroglobulin by chronic i.v. injections. These mice produced thyroglobulin-specific antibody and IFN-gamma-secreting T cells with inflammatory infiltration in the thyroids of some mice. The immune responses to neu or thyroglobulin were greater in mice undergoing TUBO tumor rejection and thyroglobulin injection than in those experiencing either alone. To the best of our knowledge, this is the first experimental system to assess the concurrent induction and possible synergy of immune reactivity to defined tumor and self-antigens following reduction of regulatory T cells. These results illustrate the importance of monitoring immune reactivity to self-antigens during cancer immunotherapy that involves immunomodulating agents, and the pressing need for novel strategies to induce antitumor immunity while minimizing autoimmunity.     

CD4+ T cells are able to promote tumor growth through inhibition of tumor-specific CD8+ T-cell responses in tumor-bearing hosts

Modulation of the immune response by established tumors may contribute to the limited success of therapeutic vaccination for the treatment of cancer compared with vaccination in a preventive setting. We analyzed the contribution of the CD4+ T-cell population to the induction or suppression of tumor-specific CD8+ T cells in a tumor model in which eradication of tumors crucially depends on CD8+ T cell-mediated immunity. Vaccine-mediated induction of protective antitumor immunity in the preventive setting (i.e., before tumor challenge) was CD4+ T cell dependent because depletion of this T-cell subset prevented CD8+ T-cell induction. In contrast, depletion of CD4+ cells in mice bearing established E1A+ tumors empowered the mice to raise strong CD8+ T-cell immunity capable of tumor eradication without the need for tumor-specific vaccination. Spontaneous eradication of tumors, which had initially grown out, was similarly observed in MHC class II-deficient mice, supporting the notion that the tumor-bearing mice harbor a class II MHC-restricted CD4+ T-cell subset capable of suppressing a tumor-specific CD8+ T-cell immune response. The deleterious effects of the presence of CD4+ T cells in tumor-bearing hosts could be overcome by CD40-triggering or injection of CpG. Together these results show that CD4+ T cells with a suppressive activity are rapidly induced following tumor development and that their suppressive effect can be overcome by agents that activate professional antigen-presenting cells. These observations are important for the development of immune interventions aiming at treatment of cancer.     

Specific antitumor immunity induced by cross-linking complex heat shock protein 72 and alpha-fetoprotein

Hepatocellular carcinoma (HCC) is one of the most common malignancies over the world. Alpha-fetoprotein (AFP) is an oncofetal protein during HCC development that could generate weaker and less reproducible antitumor protection, and it may serve as a target for immunotherapy. Therefore, it is imperative to enhance its immunogenicity and develop therapeutic vaccines to eliminate AFP-expressing tumors. In this study, by way of glutaraldehyde cross-linking, we constructed a potential therapeutic protein complex vaccine, heat shock protein 72 (HSP72)/AFP. Our results demonstrated that AFP and HSP72 synergistically exhibited significant increases in AFP-specific CD8(+) T cell responses and impressive antitumor effects against AFP-expressing tumors. Priming mice with the reconstructed vaccine, we elicited robust strong protective immunity. Our study suggests that a tumor vaccine by cross-linking tumor antigen and HSP72 is a promising approach for cancer therapy.     

Blockade of TGF‐β enhances tumor vaccine efficacy mediated by CD8+ T cells

Though TGF‐β inhibition enhances antitumor immunity mediated by CD8⁺ T cells in several tumor models, it is not always sufficient for rejection of tumors. In this study, to maximize the antitumor effect of TGF‐β blockade, we tested the effect of anti‐TGF‐β combined with an irradiated tumor vaccine in a subcutaneous CT26 colon carcinoma tumor model. The irradiated tumor cell vaccine alone in prophylactic setting significantly delayed tumor growth, whereas anti‐TGF‐β antibodies alone did not show any antitumor effect. However, tumor growth was inhibited significantly more in vaccinated mice treated with anti‐TGF‐β antibodies compared to vaccinated mice without anti‐TGF‐β, suggesting that anti‐TGF‐β synergistically enhanced irradiated tumor vaccine efficacy. CD8⁺ T‐cell depletion completely abrogated the vaccine efficacy, and so protection required CD8⁺ T cells. Depletion of CD25⁺ T regulatory cells led to the almost complete rejection of tumors without the vaccine, whereas anti‐TGF‐β did not change the number of CD25⁺ T regulatory cells in unvaccinated and vaccinated mice. Though the abrogation of CD1d‐restricted NKT cells, which have been reported to induce TGF‐β production by MDSC through an IL‐13‐IL‐4R‐STAT6 pathway, partially enhanced antitumor immunity regardless of vaccination, abrogation of the NKT cell‐IL‐13‐IL‐4R‐STAT‐6 immunoregulatory pathway did not enhance vaccine efficacy. Taken together, these data indicated that anti‐TGF‐β enhances efficacy of a prophylactic vaccine in normal individuals despite their not having the elevated TGF‐β levels found in patients with cancer and that the effect is not dependent on TGF‐β solely from CD4⁺CD25⁺ T regulatory cells or the NKT cell‐IL‐13‐IL‐4R‐STAT‐6 immunoregulatory pathway.     

Tumor regression induced by intratumor administration of adenovirus vector expressing CD40 ligand and naive dendritic cells

We have previously shown that in vivo genetic modification of tumors with an adenovirus (Ad) vector engineered to express CD40 ligand (AdmCD40L) induces tumor-specific CTLs and suppresses tumor growth in vivo. In the present study, we investigate the hypothesis that this treatment can be made more efficient with 10(2)-fold less Ad vector by also administering bone marrow-generated dendritic cells (DCs) to the tumor. Using AdmCD40L and the number of DCs that alone had no effect on tumor growth, the data show that the growth of CT26 (colon adenocarcinoma; H-2d) and B16 (melanoma; H-2b) murine s.c. tumors is significantly suppressed by direct administration of DCs into s.c. established tumors that had been pretreated with AdmCD40L 2 days previously. The antitumor effect produced by the combination therapy AdmCD40L + DCs correlated with in vivo priming of tumor-specific CTLs. The antitumor cell-mediated immunity was transferable to naive mice by spleen cells from AdmCD40L + DC-treated animals. The interactions between CD40L and CD40 within treated tumors were critical because tumor suppression was abrogated by coadministration to the tumors of neutralizing monoclonal antibody against CD40L along with the DCs. Finally, in vivo depletion and knockout mice experiments demonstrated that tumor regression produced by this combination therapy depends on CD8+ T cells, but not on CD4+ T cells. These findings should be useful in designing strategies for use of DCs and AdmCD40L in cancer immunotherapy.     

Dendritic cells transduced with tumor-associated antigen gene elicit potent therapeutic antitumor immunity: comparison with immunodominant peptide-pulsed DCs

Several studies have shown that vaccine therapy using dendritic cells (DCs) pulsed with specific tumor antigen peptides can effectively induce antitumor immunity. Peptide-pulsed DC therapy is reported to be effective against melanoma, while it is still not sufficient to show the antitumor therapeutic effect against epithelial solid tumors such as gastrointestinal malignancies. Recently, it has been reported that vaccine therapy using DCs transduced with a surrogate tumor antigen gene can elicit a potent therapeutic antitumor immunity. In this study, we investigated the efficacy of vaccine therapy using DCs transduced with the natural tumor antigen in comparison with peptide-pulsed DCs. DCs derived from murine bone marrow were adenovirally transduced with murine endogenous tumor antigen gp70 gene, which is expressed in CT26 cells, or DCs were pulsed with the immunodominant peptide AH-1 derived from gp70. We compared these two cancer vaccines in terms of induction of antigen-specific cytotoxic T lymphocyte (CTL) responses, CD4+ T cell response against tumor cells, migratory capacity of DCs and therapeutic immunity in vivo. The cytotoxic activity of splenocytes against CT26 and Meth-A pulsed with AH-1 in mice immunized with gp70 gene-transduced DCs was higher than that with AH-1-pulsed DCs. CD4+ T cells induced from mice immunized with gp70 gene-transduced DCs produced higher levels of IFN-gamma by stimulation with CT26 than those from mice immunized with AH-1-pulsed DCs (p < 0.0001), and it was suggested that DCs transduced with tumor-associated antigen (TAA) gene induced tumor-specific CD4+ T cells, and those CD4+ T cells played a critical role in the priming phase of the CD8+ T cell response for the induction of CD8+ CTL. Furthermore, DCs adenovirally transduced with TAA gene showed an enhancement of expression of CC chemokine receptor 7 and improved the migratory capacity to draining lymph nodes. In subcutaneous models, the vaccination using gp70 gene-transduced DCs provided a remarkably higher therapeutic efficacy than that using AH-1-pulsed DCs. These results suggested that vaccine therapy using DCs adenovirally transduced with TAA gene can elicit potent antitumor immunity, and may be useful for clinical application.     

MHC class II-transduced tumor cells originating in the immune-privileged eye prime and boost CD4(+) T lymphocytes that cross-react with primary and metastatic uveal melanoma cells

Uveal melanoma, the most common malignancy of the eye, has a 50% rate of liver metastases among patients with large primary tumors. Several therapies prolong survival of metastatic patients; however, none are curative and no patients survive. Therefore, we are exploring immunotherapy as an alternative or adjunctive treatment. Uveal melanoma may be particularly appropriate for immunotherapy because primary tumors arise in an immune-privileged site and may express antigens to which the host is not tolerized. We are developing MHC class II (MHC II)-matched allogeneic, cell-based uveal melanoma vaccines that activate CD4(+) T lymphocytes, which are key cells for optimizing CD8(+) T-cell immunity, facilitating immune memory, and preventing tolerance. Our previous studies showed that tumor cells genetically modified to express costimulatory and MHC II molecules syngeneic to the recipient are potent inducers of antitumor immunity. Because the MHC II-matched allogeneic vaccines do not express the accessory molecule, Invariant chain, they present MHC II-restricted peptides derived from endogenously encoded tumor antigens. We now report that MHC II-matched allogeneic vaccines, prepared from primary uveal melanomas that arise in the immune-privileged eye, prime and boost IFNgamma-secreting CD4(+) T cells from the peripheral blood of either healthy donors or uveal melanoma patients that cross-react with primary uveal melanomas from other patients and metastatic tumors. In contrast, vaccines prepared from metastatic cells in the liver are less effective at activating CD4(+) T cells, suggesting that tumor cells originating in immune-privileged sites may have enhanced capacity for inducing antitumor immunity and for serving as immunotherapeutic agents.     

CD4+ T cell-mediated HER-2/neu-specific tumor rejection in the absence of B cells

HER-2/neu (HER-2) is a cell surface proto-oncogene that is often overexpressed in carcinomas. Passive administration of anti-HER-2 antibodies in breast cancer patients has achieved promising results, but less is known about the role of antibodies in active immunization. We asked whether B cells/antibodies are needed for tumor immunity induced by plasmid (HER-2 and GM-CSF) immunization. HER-2 specific tumor immunity relied completely on both CD4+ and CD8+ T cells. IFN-gamma, and to a lesser extent IL-4, seemed to be crucial cytokines during tumor rejection. Protection was associated with production of anti-HER-2 IgG antibodies in B cell competent mice. After immunization, however, B cell-deficient mice rejected HER-2-expressing tumors as efficiently as control littermates. We conclude that T cells are the main effector cells in DNA vaccine induced immunity against HER-2 and that anti HER-2 antibodies are not necessary to elicit a protective anti tumor immune response in this model.     

Combination vaccine of dendritic cells (DCs) and T cells effectively suppressed preestablished malignant melanoma in mice

The study aims at establishing a novel vaccine procedure, using bone marrow-derived DCs that have ingested apoptotic B16 melanoma (DCs(+)), alone or in combination with splenic T lymphocytes from a syngenic donor. Co-immunization with DCs(+) and T cells showed the highest antitumor potential against preestablished B16 tumor in mice, in which CTL and NK cytotoxicities were drastically elevated, while either DCs(+) alone, naive DCs (DCs(-)) alone, or a mixture of DCs(-) and T cells induced less significant therapeutic outcomes. Use of extracellular matrix proteins elevated antitumor activity of DC(-)/T cell vaccine. Compared with the CD8(+) cells, the CD4(+)T cells more remarkably improved the efficacy of DC-based immunotherapy. The present system may be a feasible therapeutic modality to eradicate malignancies including melanoma.     

Vascular endothelial growth factor blockade reduces intratumoral regulatory T cells and enhances the efficacy of a GM-CSF-secreting cancer immunotherapy.

PURPOSE: The purpose of the present study was to evaluate granulocyte macrophage colony-stimulating factor (GM-CSF)-secreting tumor cell immunotherapy in combination with vascular endothelial growth factor (VEGF) blockage in preclinical models. EXPERIMENTAL DESIGN: Survival and immune response were monitored in the B16 melanoma and the CT26 colon carcinoma models. VEGF blockade was achieved by using a recombinant adeno-associated virus vector expressing a soluble VEGF receptor consisting of selected domains of the VEGF receptors 1 and 2 (termed sVEGFR1/R2). Dendritic cell and tumor infiltrating lymphocyte activation status and numbers were evaluated by fluorescence-activated cell sorting analysis. Regulatory T cells were quantified by their CD4+CD25hi and CD4+FoxP3+ phenotype. RESULTS: The present study established that GM-CSF-secreting tumor cell immunotherapy with VEGF blockade significantly prolonged the survival of tumor-bearing mice. Enhanced anti-tumor protection correlated with an increased number of activated CD4+ and CD8+ tumor-infiltrating T cells and a pronounced decrease in the number of suppressive regulatory T cells residing in the tumor. Conversely, overexpression of VEGF from tumors resulted in elevated numbers of regulatory T cells in the tumor, suggesting a novel mechanism of VEGF-mediated immune suppression at the tumor site. CONCLUSION: GM-CSF-secreting cancer immunotherapy and VEGF blockade increases the i.t. ratio of effector to regulatory T cells to provide enhanced antitumor responses. This therapeutic combination may prove to be an effective strategy for the treatment of patients with cancer.     

Intratumoral injection of immature dendritic cells enhances antitumor effect of hyperthermia using magnetic nanoparticles

Dendritic cells (DCs) are potent antigen-presenting cells that play a pivotal role in regulating immune responses in cancer and have recently been shown to be activated by heat shock proteins (HSPs). We previously reported that HSP70 expression after hyperthermia induces antitumor immunity. Our hyperthermia system using magnetite cationic liposomes (MCLs) induced necrotic cell death that was correlated with HSP70 release. In the present study, we investigated the therapeutic effects of DC therapy combined with MCL-induced hyperthermia on mouse melanoma. In an in vitro study, when immature DCs were pulsed with mouse B16 melanoma cells heated at 43 degrees C, major histocompatibility complex (MHC) class I/II, costimulatory molecules CD80/CD86 and CCR7 in the DCs were upregulated, thus resulting in DC maturation. C57BL/6 mice bearing a melanoma nodule were subjected to combination therapy using hyperthermia and DC immunotherapy in vivo by means of tumor-specific hyperthermia using MCLs and directly injected immature DCs. Mice were divided into 4 groups: group I (control), group II (hyperthermia), group III (DC therapy) and group IV (hyperthermia + DC therapy). Complete regression of tumors was observed in 60% of mice in group IV, while no tumor regression was seen among mice in the other groups. Increased cytotoxic T lymphocyte (CTL) and natural killer (NK) activity was observed on in vitro cytotoxicity assay using splenocytes in the cured mice treated with combination therapy, and the cured mice rejected a second challenge of B16 melanoma cells. This study has important implications for the application of MCL-induced hyperthermia plus DC therapy in patients with advanced malignancies as a novel cancer therapy.     

Paradoxical enhancement of CD8 T cell-dependent anti-tumor protection despite reduced CD8 T cell responses with addition of a TLR9 agonist to a tumor vaccine

Generation of antigen-specific CD8+ T cell responses is considered optimal for an effective immunotherapy against cancer. In this study, we provide a proof of principle that in vitro observed diminished CD8+ T cell response provided a strong in vivo tumor protection. Immunization with an adenovirus vaccine containing ovalbumin (OVA) gene (Ad5-OVA) strongly induces antigen-specific CD8+ T cell responses measured in vitro using various immunological assays. However, in an attempt to augment the antigenic CD8+ T cell response, coinjection of a TLR9 agonist CpG ODN with the viral vaccine unexpectedly reduced the CD8+ T cell responses measured in vitro but provided a remarkably enhanced tumor protection compared to the CD8+ T cell response generated by Ad5-OVA vaccine alone. Interestingly, despite reduced ex vivo/in vitro CD8+ T cell responses following Ad5-OVA+CpG immunization, immunodepletion studies revealed that the augmented anti-tumor immunity was primarily dependent on CD8+ T cells. The magnitude and effector function of anti-OVA CD8+ T cells remain low following primary and secondary antigenic challenge, presenting a dichotomy between in vitro CD8 T cell responses and in vivo anti-tumor immunity. To examine the impact of CpG ODN, we observed that presence of CpG suppresses the CD8+ T cell proliferation both in vitro and in vivo. These data demonstrate that coadministration of adenovirus vaccine with a TLR9 agonist can generate potentially effective tumor-reactive CD8+ T cells in vivo. In addition, the results indicate that widely used standard immune parameters may not predict the vaccine efficacy containing a TLR9 agonist as adjuvant.     

Deoxyribonucleic acid (DNA) encoding a pan-major histocompatibility complex class II peptide analogue augmented antigen-specific cellular immunity and suppressive effects on tumor growth elicited by DNA vaccine immunotherapy

Vaccine immunotherapy must induce helper and cytotoxic cell-mediated immunity to generate the powerful antitumor immune responses needed to suppress cancer progression. We reported previously that a 16-amino acid peptide analogue derived from pigeon cytochrome c can bind broad ranges of MHC class II types and activate helper T cells in mice. To determine whether DNA encoding the Pan-MHC class II IA peptide (Pan-IA) can increase the efficacy of tumor suppression by DNA vaccine immunotherapy targeting tumor antigens, Pan-IA DNA was administered with ovalbumin (OVA) DNA to C57BL/6 mice bearing the OVA-expressing tumor cell line E.G7. Specific proliferative responses to and cytotoxic activities against OVA-expressing targets were induced in mice vaccinated with both OVA and Pan-IA DNA but not in those vaccinated with OVA DNA alone or control DNA plus Pan-IA DNA. Growth of E.G7 cells was suppressed only by combined vaccination with OVA and Pan-IA DNA, and tumors in five of the nine mice that received this combined vaccination were eradicated completely. In those mice, the frequency of CD8-positive T cells reactive with OVA(257-264) peptides in the context of H-2K(b) was significantly increased in the tumor site. Furthermore, immunofluorescent study of the inoculated tumors revealed increased accumulation of both CD4- and CD8-positive T cells producing IFN-gamma in the tumor only by this vaccine protocol. The data suggest that Pan-IA DNA can augment suppressive effects of DNA vaccines on tumor growth by increasing numbers of antigen-specific CTLs and helper T cells. This is the first study in which established tumors have been eradicated successfully by vaccination with DNA corresponding to CTL epitopes and helper T cell epitopes. Our animal model may contribute to the development of therapeutic DNA vaccines against cancer.     

Cytotoxic T lymphocytes: role in immunosurveillance and in immunotherapy

Experiments in mice and recent human clinical studies have clearly shown the contribution of CD8+ T lymphocyte in the control of tumor development. CD8+ T lymphocytes are a constitutive component of the immune response during the development of cancer. In murine models, the efficiency of various cancer vaccines mainly depends on their ability to induce CD8+ T lymphocytes. Clinical responses in immunotherapy treated cancer patients have been associated with the presence of antitumor specific CD8+ T lymphocytes. In spontaneous regressive melanomas, intratumor antigen specific CD8+ cytotoxic T cells were expanded suggesting their involvement in the tumor shrinkage. Administration of antitumor specific cytotoxic T clones in mice resulted in antitumor responses which directly demonstrated the therapeutic efficiency of these cells. However, in most cases during cancer progression, the presence of antitumor CD8 T lymphocyte is not associated with clinical responses. Intrinsic functional abnormalities of these cells or a defect of CD8+ T cell migration to the tumor may in part explain their failure to inhibit tumor development. On the other hand, tumors also develop immune escape mechanisms (down modulation of tumor antigens, secretion of immunosuppressive factors, expression of anti-apoptotic molecules by the tumors, or pro-apoptotic factors inducing T cell death) to resist to the CD8+ T cell attack. To circumvent these tumor escape mechanisms, efficient cancer vaccines will have to recruit CD8+ T cells associated with other immune effectors.     

HSP70多肽复合物的抗肿瘤作用研究

目的： 研究HSP70多肽复合物对结肠癌荷瘤小鼠的免疫治疗作用,并探讨其抗肿瘤作用机制。方法：Colon26细胞经42 ℃水浴1 h、再分别于37 ℃培养8和12 h,并用反复冻融法筛选出含有高表达HSP70多肽复合物的瘤细胞裂解液。建立Colon26细胞的荷瘤小鼠模型,分别将含有高表达HSP70多肽复合物的瘤细胞裂解液 (实验组),常规培养条件下制备的瘤细胞裂解液 (对照组Ⅰ),以及PBS (对照组Ⅱ)分4次注射于小鼠皮下,观察小鼠体内成瘤性、生长情况及小鼠生存期。用流式细胞技术检测小鼠脾脏CD3+、CD4+和CD8+等T细胞亚型的变化。用ELISA法检测荷瘤小鼠血清中TGF-β1和IFN-γ水平的变化。结果：将高表达HSP70多肽复合物的瘤细胞裂解液注射于荷瘤小鼠后,小鼠的肿瘤生长速度、肿瘤体积和质量明显小于对照组Ⅰ与对照组Ⅱ,生存期也明显延长 (P<0.05);实验组小鼠脾脏单个核细胞表面分子与对照组Ⅰ和对照组Ⅱ相比CD8+ T细胞显著增加 (P<0.05),而CD3+和CD4+/CD8+ T细胞显著降低 (P<0.05);实验组小鼠血浆中TGF-β1与对照组Ⅰ和对照组Ⅱ相比显著降低 (P<0.05),但IFN-γ含量则显著升高 (P<0.05)。结论：含高表达HSP70多肽复合物的瘤细胞裂解液能抑制荷瘤小鼠瘤组织增长,延长荷瘤小鼠生存期,证明该多肽复合物通过调节免疫功能在小鼠体内发挥抗肿瘤作用。