Murine B16 melanoma vaccination-induced tumor immunity: identification of specific immune cells and functions involved.

Vaccination using inactivated B16 melanoma cells that have been treated in vitro for > 2 weeks with interferon-alpha (IFN-alpha) (B16alpha cells) has been shown to elicit a protective host antitumor immunity. In these studies, vaccination with B16alpha cells has been shown to provide protection against primary B16 tumor challenge, established B16 tumors, and metastatic B16 tumors. Specific immune cells and factors that might mediate this tumor immunity have now been evaluated. Macrophage depletion studies suggest that macrophage function is required for expression of tumor immunity either for processing of antigen or for cytokine production but that macrophage function is not involved in direct cytotoxicity against the B16 challenge tumor. CD8(+) T cell depletion studies show that cytotoxic T cell function is required for expression of tumor immunity. Syngeneic knockout mouse experiments offer further insights into the immune cells and factors that mediate the development and expression of tumor immunity. First, interleukin-12 (IL-12) knockout mouse experiments identify IL-12 as an important cytokine in mediating the development of tumor immunity. Second, specific knockout mouse experiments show that tumor immunity requires the function of CD4(+) T cells, CD8(+) T cells, and natural killer (NK) cells. Third, specific knockout mouse experiments show that tumor immunity does not require the function of B cells. The results suggest that vaccination with inactivated B16alpha cells induces an active, cell-mediated immunity to B16 melanoma cells. The tumor vaccination protocol with B16alpha cell vaccinations establishes a potent tumor immunity against B16 melanoma tumors in mice and may serve as a model for induction of tumor immunity against primary or secondary melanoma tumors in humans.     

Vaccination with B7-1+ Tumor and Anti-Adhesion Therapy with RGD Pseudo-Peptide (FC-336) Efficiently Induce Anti-Metastatic Effect

We have previously shown that expression of costimulatory ligand B7-1 on MHC class I⁺ tumor cells (B16-BL6 melanoma) resulted in marked reduction of lung metastasis caused by i.v. injection into immunocompetent syngeneic mice and led to induction of immunity to the challenge by the parental B7-1 negative tumor. Here we investigated the effectiveness of irradiated B7-1 transfected tumor cells as a vaccine on established tumor metastasis and whether or not expression of B7-1 molecule on tumor cells in combination with administration of anti-adhesion peptide FC-336 can augment the antimetastatic efficacy. Immunization with X-irradiated B7-1 transfectants after i.v. injection of B7-1⁻ parental B16-BL6 cells was effective in inhibiting lung metastasis. We also found that vaccination with irradiated B7-1 transfectants after excision of primary tumor on day 21 resulted in significant inhibition of spontaneous lung metastasis by intrafootpad injection of viable parental B16-BL6 melanoma, as compared with the untreated control. However, immunizing twice with mock transfectants did not affect inhibition of spontaneous lung metastasis of wild-type tumors. On the other hand, multiple administration of a pseudo-peptide of RGD sequence (FC-336) after tumor inoculation inhibited spontaneous lung metastasis through the interference of tumor invasion, migration and adhesion. Combined treatment of B7-1 transfected tumor vaccine and anti-adhesive therapy with FC-336 led to the augmentation of the antimetastatic effect in both experimental and spontaneous metastasis models, as compared with either treatment alone. B7-1- and FC-336-mediated inhibition of tumor metastasis may be mediated by different mechanisms at various steps of metastasis, based on the regulation (promotion or inhibition) of tumor interaction with host cells and components. This revised version was published online in August 2006 with corrections to the Cover Date.     

Effective induction of therapeutic antitumor immunity by dendritic cells coexpressing interleukin-18 and tumor antigen

Dendritic cell (DC) based cancer vaccine can induce potent antitumor immunity in murine models; however, objective clinical responses have been observed only in a minority of cancer patients. To improve the antitumor effect of DC vaccine, Th1-biasing cytokine interleukin (IL) 18 and melanoma-associated antigen gp100 were cotransfected into bone marrow-derived DC (IL-18/gp100-DC), which were used as vaccine to induce the protective and therapeutic immunity in a B16 melanoma model. Immunization with IL-18/gp100-DC resulted in tumor resistance in 87.5% of the mice challenged with B16 cells; however, 12.5% and 25% of mice immunized with gp100 gene-modified DC (gp100-DC) or IL-18 gene-modified DC (IL-18-DC) were tumor free, respectively. Most importantly, IL-18/gp100-DC immunization led to the generation of potent therapeutic immunity that significantly inhibited the tumor growth and improved the survival period of mice bearing established melanoma. Immune cell depletion experiments identified that CD4(+) T cells also played an important role in the priming phase of antitumor immunity and CD8(+) T lymphocytes were the primary effectors. gp100-specific CTL response were induced most markedly in the tumor-bearing mice immunized with IL-18/gp100-DC. Administration with such vaccine also significantly increased the production of Th1 cytokine (IL-2 and interferon-gamma) and induced infiltration of inflammatory cells inside and around the tumors. In addition, natural killer cell activity was also augmented. These results indicate that immunization with DC vaccine coexpressing Th1 cytokine IL-18 and tumor antigen gene may be an effective strategy for a successful therapeutic vaccination.     

Immune phenomena involved in the in vivo regression of fibrosarcoma cells expressing cell-associated IL-1alpha

Constitutive expression of cell-associated, but not secreted, interleukin-1alpha (IL-1alpha) by oncogene-transformed fibrosarcoma cells induced regressing tumors in mice, a phenomenon that was abrogated by the IL-1 inhibitor, the IL-1 receptor antagonist (IL-1Ra). On the contrary, non-IL-1alpha-expressing tumor cells induce progressive tumors in mice. In vivo and ex vivo experiments have shown that regression of IL-1alpha-positive fibrosarcoma cells depends on CD8(+) T cells, which can also be activated in CD4(+) T cell-depleted mice, with some contribution of natural killer cells. In spleens of mice bearing the non-IL-1alpha-expressing fibrosarcoma cells, some early and transient manifestations of antitumor-specific immunity, such as activation of specific proliferating T cells, are evident; however, no development of cytolytic T lymphocytes or other antitumor protective cells could be detected. In spleens of mice bearing the non-IL-1alpha-expressing fibrosarcoma cells, the development of early tumor-mediated suppression was observed, and in spleens of mice injected with IL-1alpha-positive fibrosarcoma cells, protective immunity developed in parallel to tumor regression. Treatment of mice bearing violent fibrosarcoma tumors with syngeneic-inactivated, IL-1alpha-positive fibrosarcoma cells, at a critical interval after injection of the malignant cells (Days 5-12), induced tumor regression, possibly by potentiating and amplifying transient antitumor cell immune responses or by ablation of tumor-mediated suppression. Membrane-associated IL-1alpha may thus serve as an adhesion molecule, which allows efficient cell-to-cell interactions between the malignant and immune effector cells that bear IL-1Rs and function as a focused cytokine with adjuvant activities at nontoxic, low levels of expression. Our results also point to the potential of using antitumor immunotherapeutic approaches using cell-associated IL-1alpha.     

Tumor cells cotransfected with interleukin-7 and B7.1 genes induce CD25 and CD28 on tumor-infiltrating T lymphocytes and are strong vaccines

Interleukin-7 (IL-7) and the membrane molecule B7 are both able to provide proliferation and activation signals for T cells. However, tumor cells transfected to express either molecule alone are not reliably rejected in syngeneic hosts or are not sufficiently immunogenic to serve as potent tumor vaccines. Since IL-7 and B7 have shown synergistically to induce activation and proliferation of T cells in vitro, we have expressed B7.1 by means of a retrovirus in the mammary adenocarcinoma TS/A which arose spontaneously in a BALB/c mouse and in the plasmacytoma J558L and their IL-7-transfected sublines to improve vaccine efficacy. Expression of IL-7 or B7.1 alone in tumor cells decreased tumorigenicity, but nevertheless tumors grew in a substantial number of mice. In contrast, IL-7/B7.1 cotransfected cells did not grow as tumor in a single case. This inhibition of tumor growth was completely T cell dependent, because TS/A-IL-7/B7.1 cells retained their full tumorigenic potential in T cell-deficient mice. Analysis of tumor-infiltrating T lymphocytes revealed increased numbers of T cells in B7, IL-7 and IL-7/B7 transfected compared to parental tumors. In IL-7/B7 transfected tumors, T cell numbers were not further increased compared to that in singlegene-transfected tumors. However, T cells in B7 and IL-7 transfected tumors differed phenotypically with respect to activation markers. In B7 transfected tumors, T cells were predominantly CD28⁺ and CD25⁺, while in IL-7-transfected tumors, T cells were mainly CD28^? and CD25⁺. In IL-7/B7 cotransfected tumors, the majority of T cells was CD28⁺ and CD25⁺. Thus, IL-7 and B7 induced an anti-tumor immune response by complementary T cell directed pathways in a cooperative fashion. Importantly, immunization of mice with the transfected cells and subsequent contralateral challenge with parental tumor cells showed that IL-7/B7 co-expressing cells induced the most strongly protective immunity, which is superior to that induced by single-gene transfectants and to the adjuvant Corynebacterium parvum. Vaccine efficacy was abrogated when irradiated cells were used for vaccination. Together, our results show that IL-7 and B7.1 transfected tumor cells induce strong T cell activation and tumor immunity.     

人IL-6基因转染的小鼠黑色素瘤细胞B16-IL-6~ 致瘤性降低的实验研究

应用细胞因子基因转染的瘤苗治疗肿瘤是近年来肿瘤基因治疗的重要进展之一。本研究采用磷酸钙DNA共沉淀法将人IL-6基因转染入B16黑色素瘤细胞中,筛选出一株高分泌IL—6(240U/ml)克隆(B16—IL—6~ ),B16—IL-6~ 细胞体外生长能力减弱,小鼠皮下接种后肿瘤结节形成率降低,生长速度减慢,并对再次接种野生型B16细胞具有抵抗作用。小鼠静脉接种后形成的肺转移结节数显著减少,荷瘤小鼠存活期延长。结果表明IL-6基因转染的肿瘤细胞致瘤性显著下降。并能诱导机体产生抗肿瘤免疫功能。     

糖基化磷脂酰肌醇修饰的小鼠IL-21瘤苗抗肿瘤效应及其机制初探

目的 构建糖基化磷脂酰肌醇(glycosyl phosphafidylinositol,GPI)修饰的小鼠IL-21瘤苗,并对此瘤苗的抗肿瘤效应及其机制作初步探讨.方法 通过重叠PCR方法获得IL-21-GPI融合基因并将其插入空载体pcDNA3.1.将鉴定过的重组载体以脂质体法转染B16F10细胞制成瘤苗,细胞间接免疫荧光法及流式细胞仪检测转染瘤细胞膜表面IL-21的表达,通过对小鼠脾细胞的增殖作用鉴定表达的IL-21的生物学活性.将瘤苗接种小鼠后,通过观察小鼠肿瘤体积和生存率分析瘤苗的抗瘤性,并检测了瘤苗免疫鼠的细胞免疫活性.结果 正确构建了pcDNA3.1/IL-21-GPI重组载体,膜表达的IL-21有良好的生物学活性,制备的瘤苗能发挥抗肿瘤效应,其机制与免疫鼠细胞免疫活性增强有关.结论 成功构建了具有抗肿瘤活性的GPI修饰的IL-21瘤苗,为其进一步抗肿瘤免疫治疗研究奠定了基础.     

Peritransplantation vaccination with chaperone-rich cell lysate induces antileukemia immunity.

We have reported that chaperone-rich cell lysate (CRCL) is an effective anticancer vaccine in immunocompetent mice. In this study, we explored the therapeutic applicability of CRCL in the context of syngeneic hematopoietic cell transplantation (HCT) to treat preexisting leukemia. Our results demonstrate that tumor growth is significantly delayed in mice receiving syngeneic HCT from 12B1 tumor CRCL-immunized donors compared with animals receiving HCT from nonimmunized donors. CRCL immunization after immune HCT further hindered tumor growth when compared with immune HCT without posttransplantation vaccination. The magnitude of the immune response was consistent with the antitumor effects observed in vivo. Rechallenge of surviving mice with 12B1 or A20 cells in opposite groins confirmed that mice had developed long-term tumor-specific immunity against 12B1 tumor cells. In addition, we documented that both T cells and natural killer cells contributed to the antitumor effect of CRCL vaccination, because depletion of either subset hampered tumor growth delay. Thus, our results indicate that CRCL is a promising vaccine capable of generating specific immune responses. This antitumor immunity can be effectively transferred to a host via HCT and further enhanced after HCT with additional tumor CRCL immunizations.     

Murine oviduct epithelial cell cytokine responses to Chlamydia muridarum infection include interleukin-12-p70 secretion

Epithelial cells play an important role in host defense as sentinels for invading microbial pathogens. Chlamydia trachomatis is an intracellular bacterial pathogen that replicates in reproductive tract epithelium. Epithelial cells lining the reproductive tract likely play a key role in triggering inflammation and adaptive immunity during Chlamydia infections. For this report a murine oviduct epithelial cell line was derived in order to determine how epithelial cells influence innate and adaptive immune responses during Chlamydia infections. As expected, oviduct epithelial cells infected by Chlamydia muridarum produced a broad spectrum of chemokines, including CXCL16, and regulators of the acute-phase response, including interleukin-1alpha (IL-1alpha), IL-6, and tumor necrosis factor alpha. In addition, infected epithelial cells expressed cytokines that augment gamma interferon (IFN) production, including IFN-alpha/beta and IL-12-p70. To my knowledge this is the first report of a non-myeloid/lymphoid cell type making IL-12-p70 in response to an infection. Equally interesting, infected epithelial cells significantly upregulated transforming growth factor alpha precursor expression, suggesting a mechanism by which they might play a direct role in the pathological scarring seen as a consequence of Chlamydia infections. Data from these in vitro studies predict that infected oviduct epithelium contributes significantly to host innate and adaptive defenses but may also participate in the immunopathology seen with Chlamydia infections.     

Interferon (IFN)-beta gene transfer into TS/A adenocarcinoma cells and comparison with IFN-alpha: differential effects on tumorigenicity and host response

Our group had previously shown that transfer of the mouse interferon (IFN)-alpha1 gene into the metastasizing TS/A mammary adenocarcinoma resulted in T-cell-mediated tumor rejection and development of antitumor immunity. Moreover, we had shown that the metastatic ability of TS/A tumor cells producing IFN-alpha was strongly impaired, whereas IFN-gamma expression did not influence or augmented metastasis formation by TS/A cells. In this study, we have analyzed the in vitro and in vivo behavior of various TS/A tumor cell clones isolated after the transduction with a recombinant retroviral vector carrying the mouse IFN-beta gene. We have also compared the tumorigenicity of these clones with that of TS/A cells expressing IFN-alpha1. BALB/c mice were inoculated subcutaneously with parental TS/A cells, transduction control TS/A cells, or TS/A cells producing IFN-alpha or IFN-beta. Tumor growth was evaluated by the measurement of tumor masses and analysis of survival. The features of tumor growth and rejection were examined by histological and immunohistochemical analyses. The metastatic ability of parental TS/A cells, transduction control TS/A cells, or TS/A cells producing IFN-alpha, IFN-beta, or IFN-gamma was evaluated after intravenous injection of the tumor cells into BALB/c mice by counting of the lung metastatic nodules and analysis of survival. A strong inhibition of tumorigenicity and development of tumor immunity were observed upon subcutaneous injection of syngeneic mice with TS/A tumor cells producing high amounts of IFN-beta, but not with clones expressing low levels of the cytokine, as observed for cells expressing IFN-alpha. IFN-alpha secretion by TS/A cells at the site of tumor growth induced a stronger inflammatory response as compared with IFN-beta, which appeared to be more active in the inhibition of tumor-induced angiogenesis. Notably, the metastatic ability of IFN-beta-producing TS/A cells after intravenous injection was either not affected or only slightly impaired as compared with parental TS/A tumor cells. In contrast, even cells producing low levels of IFN-alpha proved to be poorly metastatic. These findings represent the first comparison of the effectiveness of IFN-alpha versus IFN-beta produced by genetically modified cells on their tumorigenic behavior and suggest the existence of some notable differences in the capabilities of these two cytokines to induce a host antitumor reactivity in mice.     

小鼠IL-18基因修饰瘤苗的抗白血病作用研究

我们在前期工作中成功制备了IL-18基因修饰的白血病疫苗,为了探讨IL-18基因修饰瘤苗的体内抗白血病作用,实验采用L1210小鼠淋巴细胞白血病模型,在小鼠体内接种IL-18基因修饰瘤苗,观察瘤苗对L1210细胞致瘤性的影响及免疫保护作用,并进一步对其抗白血病作用机制进行了探索。结果显示,IL-18基因修饰瘤苗能够明显延长荷瘤小鼠存活时间,大部分小鼠达到长期生存,且长生存小鼠用野生型L1210细胞二次攻击后大多数仍能长期生存,表明IL-18基因修饰瘤苗有显著的抗白血病作用,并可诱导小鼠产生免疫记忆和免疫保护。机制探讨发现,接种IL-18基因修饰瘤苗后,小鼠脾脏淋巴细胞对L1210肿瘤细胞的CTL及NK细胞杀伤活性明显高于对照组(P<0.05),提示IL-18基因修饰瘤苗能够显著增强抗肿瘤CTL和NK细胞反应。接种瘤苗可使小鼠IFN-γ水平升高,但与对照相比无统计学意义,提示IFN-γ可能在IL-18基因修饰瘤苗诱导的抗肿瘤免疫应答中作用不大。     

Antigen-specific regression of established tumors induced by active immunization with irradiated IL-12- but not B7-1-transfected tumor cells

Transfection of modestly immunogenic tumors to express B7 family co- stimulator molecules results in their rejection by syngeneic mice, suggesting a possible clinical application in cancer patients. Immunization of naive mice with irradiated B7-1-transfected P1.HTR cells is sufficient to induce specific cytolytic T lymphocytes (CTL) and to protect against tumor challenge. However, patients to be treated will have an existing tumor burden; thus, preclinical models should examine therapeutic efficacy in an established tumor setting. Contrary to expectations, immunization of mice with irradiated B7-1-transfected P1.HTR cells had no impact on the growth of pre-established control- transfected tumors. Mice bearing control-transfected P1.HTR tumors successfully rejected living B7-1 transfectants on the contralateral flank, demonstrating the ability of tumor-bearing mice to respond to B7 co-stimulation. Inasmuch as IL-12 is another important factor for CTL maturation, P1.HTR transfectants expressing B7-1 and/or IL-12 were then constructed. Remarkably, regression of pre-established tumors was achieved following immunization with irradiated IL-12 transfectants, even without co-expression of B7-1. Rejection required a shared antigen with the tumor used for immunization, could not be reproduced with rIL- 12 alone, depended on host T lymphocytes and correlated with a high IFN- gamma-producing T cell phenotype. In addition, IL-12-facilitated tumor rejection required co-operation with a CTLA-4 ligand provided by the host, and correlated with up-regulation of B7-1 and B7-2 on host antigen-presenting cells. Thus, active immunization in the established tumor setting is benefitted greatly by the provision of IL-12, which may recruit participation of sufficient B7 co-stimulation from the host that it need not be provided exogenously.      

IL—6基因转染的瘤苗体内诱导的抗肿瘤免疫功能与效果

经丝裂霉素C体外处理后,将IL-6基因转染的、高分泌的IL-6的B16黑色素瘤细胞制成瘤苗。结果发现,体内注射IL-6基因转染的瘤苗后,小鼠脾脏CTL活性、NK活性及IL-2诱导的LAK活性显著升高。经IL-6基因转染瘤苗体内治疗后,荷瘤小鼠的皮下肿瘤生长显著减慢、肺转移结节数显著降低、存活期显著延长,若同时合用低剂量IL-2,则上述治疗效果更好。可见IL-6基因转染的瘤苗能有效地通过诱导机体抗肿瘤免疫功能而发挥抗肿瘤作用,与低剂量IL-2合用后,IL-6基因转染的瘤苗的抗肿瘤效果更佳。     

IL—12和B7—1协同抗肿瘤作用和疫苗效应的研究

研究了IL-12和B7-1基因导入小鼠EL-4胸腺瘤细胞后在小鼠体内诱导的协同抗肿瘤免疫作用。方法将逆转录病毒载体重组的小鼠IL-12,B7-1基因表达质粒分别导入小鼠EL-4胸腺瘤细胞,利用转基因细胞治疗小鼠观察其抗肿瘤免疫效果。结果转基因细胞的肿瘤原性较EL-4/Wt和EL-4/Neo组明显降低(P<0.001)。同时免疫原性明显增强,以     

A Novel Approach for Cancer Immunotherapy: Tumor Cells with Anchored Superantigen SEA Generate Effective Antitumor Immunity

Murine B16 melanoma cell line is poorly immunogenic and highly aggressive. We recently reported that the transmembrane staphylococcal enterotoxin A (TM-SEA) anchors onto B16 cells and stimulates lymphocyte proliferation. The purpose of the study was to investigate whether vaccination with B16 cells bearing membrane-anchored TM-SEA fusion protein could cause tumor-specific immunity. Mice in the therapeutic vaccination group received B16 tumor inoculations, followed by treatment with B16-TM-SEA vaccine or control vaccines. Mice in the prophylactic vaccination group were given B16-TM-SEA vaccine or control vaccines, followed by challenge with wild type B16 or control EL4 cells. Significant tumor growth inhibition, prolongation of survival, and marked augmentation of NK and CTL activities were observed in mice which received B16-TM-SEA vaccine as compared to controls. Overall, our results suggest that the TM-SEA cellular vaccine is a novel and effective strategy for cancer immunotherapy.     

B16与活化B细胞融合瘤细胞主动免疫诱导抗肿瘤作用的初步研究

通过５０％ＰＥＧ诱导细胞融合，ＨＡＴ选择培养得到Ｂ１６黑色素瘤与活化Ｂ淋巴细胞的融合细胞（Ｂ１６．Ｂ）。体外进行混合淋巴细胞，肿瘤细胞培养，发现Ｂ１６．Ｂ能诱发小鼠脾脏淋巴细胞的增生反应，而Ｂ１６无此作用。体内实验表明：Ｂ１６．Ｂ３次免疫后，能获得对Ｂ１６攻击的抵抗，皮下形成肿瘤时间较Ｂ１６免疫组明显推迟，存活期也延长，但不能获得对无关瘤株的抵抗力，对荷瘤小鼠的治疗实验也显示，Ｂ１６．Ｂ腹腔注射能     

Immunotherapy of mice with an irradiated melanoma vaccine coupled with interleukin-12

Interleukin (IL)-12 can activate cytotoxic lymphocytes, stimulate natural killer cell activity, induce the production of INF- and inhibit the development of various experimental tumors. We previously demonstrated that immunotherapy of melanoma bearing mice with an irradiated melanoma vaccine (IMV) coupled with IL-2 or GM-CSF had beneficial effects against primary melanoma growth and against subsequent spontaneous metastasis. We also had found that treatment of melanoma bearing mice with IL-12 (300 ng/day) for 4 weeks inhibited the development of primary melanoma tumors in 40% of mice. The purpose of this study was to investigate the efficacy of combined therapy of experimental melanoma with an IMV prepared from B16F10 melanoma cells coupled with IL-12 treatment. C57BL/6 mice were challenged subcutaneously in the tail with B16F10 melanoma cells and by the 45th day, more than 50% of the mice had developed visible primary melanoma tumors at the injection site. Subsequent immunotherapy of mice with IMV, when coupled with IL-12, provided partial inhibition of primary melanoma tumor growth. Optimal results against primary tumor growth were observed when IMV therapy was coupled with IL-12 at a dose of 50 ng/day. Combination of IMV with IL-12 at a dose of 100 ng/day significantly reduced melanoma metastasis to the lungs compared with control mice, and an improvement in mean survival time was observed in mice treated with a combination of IMV with IL-12 (300 ng/day).     

Innate and adaptive immunity to tumors: IL-12 is required for optimal responses

We have investigated the importance of endogenously produced IL-12 in innate and adaptive immunity to tumor transplants. The immunogenic lymphoma RMA and its TAP-deficient variant RMA-S were tested for rejection responses by normal and IL-12-deficient mice. IL-12 was crucial for the immunity induced by one immunization with irradiated RMA cells, as well as for in vivo priming of a CTL response in mixed lymphocyte tumor cultures against this MHC class I-expressing tumor. The defective in vivo response could be overcome by multiple immunizations. In further studies of in vitro CTL responses, we found that IL-12 production from either the antigen-pulsed dendritic cells or from host cells was necessary to obtain strong CTL responses. In the complete absence of IL-12, no or only very weak responses could be detected. NK cell-mediated innate resistance, as assessed in non-immunized mice inoculated with a threshold dose of RMA-S cells, also required IL-12. However, NK cells with reduced activity were present in IL-12-deficient mice and contributed to innate resistance, as demonstrated with lower cell dose challenges. In conclusion, IL-12 is required for optimal adaptive and innate responses against tumors.     

The plague virulence protein YopM targets the innate immune response by causing a global depletion of NK cells

Yersinia pestis, the etiologic agent of plague, delivers six Yersinia outer proteins (Yops) into host cells upon direct bacterial contact. One of these, YopM, is necessary for virulence in a mouse model of septicemic plague, but its pathogenic function is unknown. We report here the immune processes affected by YopM during infection. To test whether the innate or adaptive immune system is targeted by YopM, C57BL/6 (B6) and B6 SCID mice were infected with either the conditionally virulent Y. pestis KIM5 or a yopM deletion mutant and evaluated for bacterial growth in spleen and liver. Both B6 and SCID mice succumbed to infection with Y. pestis KIM5, whereas both mouse strains survived infection by the YopM(-) mutant. These data showed that YopM counteracts innate defenses present in SCID mice. The YopM(-) strain grew more slowly than the parent Y. pestis during the first 4 days of infection in both mouse strains, indicating an early pathogenic role for YopM. In B6 mice, populations of cells of the immune system were not differentially affected by the two Y. pestis strains, with one major exception: the parent Y. pestis KIM5 but not the YopM(-) mutant caused a significant global decrease in NK cell numbers (blood, spleen, and liver), beginning early in infection. NK cells and macrophages isolated early (day 2) from livers and spleens of mice infected with either Y. pestis strain contained comparable levels of cytokine mRNA: interleukin (IL)-1 beta, IL-12, IL-15, IL-18, and tumor necrosis factor alpha in macrophages and gamma interferon in NK cells. However, by day 4 postinfection, cells from mice infected with the parent Y. pestis expressed lower levels of these messages, while those from mice infected with the mutant retained strong expression. Significantly, mRNA for the IL-15 receptor alpha chain was not expressed in NK cells from Y. pestis KIM5-infected mice as early as day 2 postinfection. These findings suggest that YopM interferes with innate immunity by causing depletion of NK cells, possibly by affecting the expression of IL-15 receptor alpha and IL-15.     

Interleukin-12 and B7.1 co-stimulation cooperate in the induction of effective antitumor immunity and therapy of established tumors

Interleukin-12 (IL-12) promotes specific and long-lasting anti-tumor immunity mediated by T cells in a variety of murine tumor models. IL-12 also synergizes with B7.1 (CD80) co-stimulation to induce proliferation and cytokine production by both human and murine T cells in vitro. We evaluated the combined antitumor efficacy of IL-12 and B7.1 gene delivery in two apparently poorly immunogenic tumor models (TS/A and MCA207). In both of these models, expression of B7.1 and production of IL-12 in the inoculum led to improved anti-tumor immunity, with up to 80% long-term tumor-free animals (vs 0– 20% of mice remaining tumor free when inoculated with either B7.1- or IL-12-transfected tumors alone). Tumor-free mice were capable of rejecting a subsequent rechallenge with the wild-type tumor in 66% of the cases. Cooperativity was dependent upon the level of IL-12 secreted by engineered cells. IL-12 delivery required B7 expression of therapeutic effects to be observed in these models. Vaccines provided at a site distal to a control, non-transfected tumor slowed (TS/A) or abrogated (MCA207) the progression of wild-type tumors. The synergistic anti-tumor effects associated with combined application of B7.1- and IL-12-transfected tumors were partially negated by systemic administration of the CD28-B7.1/B7.2 antagonist CTLA4-Ig or by inoculation with neutralizing antibodies directed against murine interferon-γ or tumor necrosis factor-α, two cytokines elicited in response to IL-12 stimulation. These data support the potential clinical utility of combined gene therapy using IL-12- and B7.1-engineered autologous cells (tumor or fibroblasts) as a vaccine to elicit specific anti-tumor immunity.