Establishment of tumor-specific immunotherapy model utilizing vaccinia virus-reactive helper T cell activity

It was previously demonstrated that preimmunization of mice with live vaccinia virus (VV) and subsequent immunization with VV-infected (modified), syngeneic tumor cells resulted in enhanced induction of tumor-specific immunity through a cellular collaboration between VV-reactive helper T (VV-Th) cells and tumor-specific effector cell precursors. On the basis of this augmenting system, a tumor-specific immunotherapy model was established in which a growing tumor regressed. C3H/HeN mice were pretreated with cyclophosphamide to eliminate nonspecific suppressor T cell activity and subsequently inoculated (primed) s.c. with live VV, leading to augmented induction of VV-Th cell activities. Four weeks later, the mice were inoculated i.d. with syngeneic X5563 myeloma cells. Six days after the tumor cell inoculation, live VV was injected into the tumor mass three times at 2-day intervals. Seven of ten mice which had received VV priming and subsequent VV injection into the tumor mass exhibited complete tumor regression. On the contrary, mice which had received mere intratumoral VV injection in the absence of VV priming failed to exhibit appreciable tumor regression. Mice whose tumor had completely regressed (regressor mice) by the above VV immunotherapy were shown to have acquired systemic anti-tumor immunity, which was confirmed by a challenge with syngeneic tumor cells after the tumor regression. In vitro analysis of these immune mice revealed that potent tumor-specific cytotoxic T lymphocyte responses were preferentially induced, but with no detectable anti-tumor antibody responses. Such a potent tumor-specific immunity was not observed in mice which had received an intratumoral VV injection in the absence of VV priming. Thus the results clearly indicate that the tumor regression was accompanied by concurrent generation of a potent tumor-specific immunity, suggesting that the cellular collaboration between VV-Th cells and tumor-specific effector cell precursors is also functioning in this VV-immunotherapy protocol, likewise the immunoprophylactic model. Therefore, the present model provides an effective maneuver for tumor-specific immunotherapy and this system will be theoretically applicable to human cancer treatment.     

Combination chemo-immunotherapy of murine solid tumor with OK-432, G-CSF,IL-2, and chemotherapeutics

An experimental tumor model was previously established in which BALB/c mice could survive the otherwise fatal intraperitoneal (i.p.) inoculation of BAMC-1 fibrosarcoma cells if the mice were treated with five sequential i.p. injections of OK-432 (a potent BRM) starting 2 days after tumor inoculation. In the present study, although a single i.p. injection of OK-432 alone on day 2 was not enough to cure the tumor-bearing mice, a combination therapy, an injection of OK-432 (5 mg/kg) on day 2 followed by injection of G-CSF (50 μg/kg) on day 3, could eradicate the tumor cells in more than 80% of the mice. In contrast to this ascites tumor model, solid tumors induced by intradermal transplantation of BAMC-1 tumor cells were resistant to the combined treatments with OK-432 and G-CSF, dying within 60 days. However, when these mice received a combined chemoimmunotherapy with cisplatin, OK-432, G-CSF and IL-2, starting on day 4, the tumors had regressed, and were completely eradicated. When the same treatment was started as late as day 8, no significant therapeutic effect was observed. Even at this advanced stage, however, it was found that a similar chemo-immunotherapy protocol using CAP-D (cyclophosphamide, epirubicin and DWA2114R) in lieu of cisplatin was extremely effective, achieving the eradication of tumors in more than 70% of the mice. These results indicated that the combination therapy with OK-432, G-CSF, IL-2, and chemotherapeutics could achieve a potent anti-tumor effect against the solid tumor, even at the advanced stage. Subsequent experiments using athymic nude mice transplanted with the tumor cells revealed that the same combination therapy showed weak tumor-regressing effects without achieving a complete cure. These results suggest that T-cells are key effectors in this type of chemo-immunotherapy of malignant tumors.     

Dendritic cells modified to express fractalkine/CX3CL1 in the treatment of preexisting tumors

Fractalkine (CX3CL1) is a unique membrane-bound CX3C chemokine that serves as a potent chemoattractant for lymphocytes. The hypothesis of this study is that dendritic cells (DC) genetically modified ex vivo to overexpress fractalkine would enhance the T cell-mediated cellular immune response with a consequent induction of anti-tumor immunity to suppress tumor growth. To prove this hypothesis, established tumors of different mouse cancer cells (B16-F10 melanoma, H-2b, and Colon-26 colon adenocarcinoma, H-2d) were treated with intratumoral injection of bone marrow-derived DC that had been modified in vitro with an RGD fiber-mutant adenovirus vector expressing mouse fractalkine (Ad-FKN). In both tumor models tested, treatment of tumor-bearing mice with Ad-FKN-transduced DC gave rise to a significant suppression of tumor growth along with survival advantages in the treated mice. Immunohistochemical analysis of tumors treated with direct injection of Ad-FKN-transduced DC demonstrated that the treatment prompted CD8+ T cells and CD4+ T cells to accumulate in the tumor milieu, leading to activation of immune-relevant processes. Consistent with the finding, the intratumoral administration of Ad-FKN-transduced DC evoked tumor-specific cytotoxic T lymphocytes, which ensued from in vivo priming of Th1 immune responses in the treated host. In addition, the anti-tumor effect provided by intratumoral injection of Ad-FKN-transduced DC was completely abrogated in CD4+ T cell-deficient mice as well as in CD8+ T cell-deficient mice. These results support the concept that genetic modification of DC with a recombinant fractalkine adenovirus vector may be a useful strategy for cancer immunotherapy protocols.     

Radiation-induced apoptosis along with local and systemic cytokine elaboration is associated with DC plus radiotherapy-mediated renal cell tumor regression

Utilizing melanoma and sarcoma tumor models syngeneic to C57BL/6 mice, we previously reported the antitumor effects of intratumoral (i.t.) administration of dendritic cells (DC) combined with localized radiotherapy (RT). However, the mechanisms underlying the augmented therapeutic effects have yet to be fully defined. Using the BALB/c host, we explored in this study the capacity of RT to augment the therapeutic efficacy of DC in the syngeneic renal cell cancer, Renca. I.t. DC administration combined with RT inhibited tumor growth in a synergistic manner. This extends our previous findings using a different host strain and two histologically distinct tumor models. More importantly, we provide evidence in this report that RT induced significant apoptosis and necrosis in Renca tumor cells, which involved down-regulated expression of Bcl-2 and a concurrent up-regulated expression of Bax. We also found significantly elevated expression of TNFalpha in RT plus DC-treated Renca tumors. Furthermore, splenocytes isolated from DC plus RT-treated mice elaborated higher levels of IL-2, IL-4, IFNgamma and IgG, IgM in response to tumor cells compared with splenocytes from monotherapy-treated hosts. These data support the conclusion that radiotherapy enhanced DC vaccination by inducing tumor cell apoptosis in BABL/c host, and the significantly augmented therapeutic efficacy by RT+DC treatment was associated with an increased local production of TNFalpha as well as an amplified systemic antitumor responses conferred by the combined therapy. I.t. DC administration in concert with localized RT may represent a promising novel regimen for human cancer therapy.     

Comparison of the chemotactic responsiveness of two fibrosarcoma subpopulations of differing malignancy.

There are several points of similarity between the processes of cancer metastasis and inflammation. In both, cells circulate in the vasculature, arrest, and cross vessel walls, thereby entering the extravascular tissues. In vitro, leukocytes and some, but not all, tumor cells exhibit chemotaxis. Since the chemotactic response of leukocytes effect their transvascular migration, we propose that chemotactic responsiveness contributes to the ability of circulating tumor cells to localize in extravascular tissues. This study was done to seek a relationship between chemotactic responsiveness of tumor cells and their behavior in vivo. Two subpopulations of cells were isolated from a methylcholanthrene-induced fibrosarcoma. The two cell lines were compared with regard to their biologic behavior in vivo and their chemotactic responsiveness in vitro. In vivo one subpopulation was highly malignant. An injection of 2.0 x 10(5) cells into the footpad of syngeneic mice led to the development of primary tumors in 87% of the animals and lung metastases in 61% of the animals with primary tumors. This line demonstrated chemotaxis to a factor that behaved similarly in gel filtration and showed immunologic reactivity similar to that of a previously described tumor cell chemotactic factor derived from the fifth component of complement. In contrast, an injection of the same number of cells from the second subpopulation of fibrosarcoma cells led to the development of primary tumors in only 12% of syngeneic mice, and lung metastases did not occur. Neither this subpopulation nor normal embryonic fibroblasts demonstrated chemotactic responsiveness. We postulate that the ability of tumor cells to respond to specific chemotactic stimuli may be one of the many unique properties which distinguish malignant from benign tumor cells. This is the first report documenting the chemotactic responsiveness of non-ascites tumors and fibrosarcomas.     

瘤内注射MIP-3α对小鼠肝癌生长抑制作用的研究

目的:探讨瘤内注射巨噬细胞炎症蛋白-3α(macrophage inflammatory protein-3α,MIP-3α)能否趋化外周树突状细胞(Dendritic cells,DCs)至肿瘤组织内,诱导特异性免疫应答。方法:成功建立小鼠皮下肝癌模型后随机分为3组,第10天起分别向MIP-3α治疗组、PBS对照组的小鼠皮下肿瘤内注射MIP-3α溶液及PBS,空白对照组小鼠不予任何处理。20天后取肿瘤组织,免疫组化法检测肿瘤内DCs、CD4+、CD8+细胞浸润情况,流式细胞术检测肿瘤内DCs浸润数量及其表型。另外,每组各10只小鼠持续观察,用于绘制肿瘤生长曲线并观察生存时间。结果:①MIP-3α治疗组的小鼠肿瘤内浸润的CD4+、CD8+细胞及DCs数量均显著高于其他两组。②MIP-3α治疗组小鼠肿瘤内浸润性DCs的CD80、CD86表达率显著高于其他两组(P<0.05)。③MIP-3α治疗组小鼠肿瘤生长速率显著低于对照组(P<0.001),生存时间较对照组明显延长(P<0.05)。结论:①瘤内注射MIP-3α可在小鼠肝癌病灶内趋化、募集外周的树突状细胞,使其摄取并提呈肿瘤抗原,有效诱导针对肝癌细胞的特异性免疫应答。②MIP-3α在小鼠皮下肝癌模型的局部微环境下可能具有促进树突状细胞成熟的作用。     

Significant anti-tumour activity of adoptively transferred T cells elicited by intratumoral dendritic cell vaccine injection through enhancing the ratio of CD8+ T cell/regulatory T cells in tumour

We have shown that immunization with dendritic cells (DCs) pulsed with hepatitis B virus core antigen virus‐like particles (HBc‐VLP) packaging with cytosine–guanine dinucleotide (CpG) (HBc‐VLP/CpG) alone were able to delay melanoma growth but not able to eradicate the established tumour in mice. We tested whether, by modulating the vaccination approaches and injection times, the anti‐tumour activity could be enhanced. We used a B16‐HBc melanoma murine model not only to compare the efficacy of DC vaccine immunized via footpads, intravenously or via intratumoral injections in treating melanoma and priming tumour‐specific immune responses, but also to observe how DC vaccination could improve the efficacy of adoptively transferred T cells to induce an enhanced anti‐tumour immune response. Our results indicate that, although all vaccination approaches were able to protect mice from developing melanoma, only three intratumoral injections of DCs could induce a significant anti‐tumour response. Furthermore, the combination of intratumoral DC vaccination and adoptive T cell transfer led to a more robust anti‐tumour response than the use of each treatment individually by increasing CD8⁺ T cells or the ratio of CD8⁺ T cell/regulatory T cells in the tumour site. Moreover, the combination vaccination induced tumour‐specific immune responses that led to tumour regression and protected surviving mice from tumour rechallenge, which is attributed to an increase in CD127‐expressing and interferon‐γ‐producing CD8⁺ T cells. Taken together, these results indicate that repeated intratumoral DC vaccination not only induces expansion of antigen‐specific T cells against tumour‐associated antigens in tumour sites, but also leads to elimination of pre‐established tumours, supporting this combined approach as a potent strategy for DC‐based cancer immunotherapy.     

Tumor cell apoptosis induces tumor-specific immunity in a CC chemokine receptor 1- and 5-dependent manner in mice

The first step in the generation of tumor immunity is the migration of dendritic cells (DCs) to the apoptotic tumor, which is presumed to be mediated by various chemokines. To clarify the roles of chemokines, we induced apoptosis using suicide gene therapy and investigated the immune responses following tumor apoptosis. We injected mice with a murine hepatoma cell line, BNL 1ME A.7R.1 (BNL), transfected with HSV-thymidine kinase (tk) gene and then treated the animals with ganciclovir (GCV). GCV treatment induced massive tumor cell apoptosis accompanied with intratumoral DC infiltration. Tumor-infiltrating DCs expressed chemokine receptors CCR1 and CCR5, and T cells and macrophages expressed CCL3, a ligand for CCR1 and CCR5. Moreover, tumor apoptosis increased the numbers of DCs migrating into the draining lymph nodes and eventually generated a specific cytotoxic cell population against BNL cells. Although GCV completely eradicated HSV-tk-transfected BNL cells in CCR1-, CCR5-, or CCL3-deficient mice, intratumoral and intranodal DC infiltration and the subsequent cytotoxicity generation were attenuated in these mice. When parental cells were injected again after complete eradication of primary tumors by GCV treatment, the wild-type mice completely rejected the rechallenged cells, but the deficient mice exhibited impairment in rejection. Thus, we provide definitive evidence indicating that CCR1 and CCR5 and their ligand CCL3 play a crucial role in the regulation of intratumoral DC accumulation and the subsequent establishment of tumor immunity following induction of tumor apoptosis by suicide genes.     

Therapeutic immune response induced by intratumoral expression of the fusogenic membrane protein of vesicular stomatitis virus and cytokines encoded by adenoviral vectors

We assessed whether intratumoral expression of the fusogenic membrane protein of vesicular stomatitis virus (VSV-G), encoded by a replication-defective adenovirus vector (Ad.VSV-G), alone or in combination with local coexpression of cytokines induces tumor-specific immune responses in a syngeneic murine colon cancer model. We confirmed in vitro by dye colocalization that transduction of murine cells with Ad.VSV-G induces cell-cell fusion. In a bilateral syngeneic subcutaneous colon cancer model in C57BL/6 and BALB/c mice, we demonstrated that intratumoral injection of Ad.VSV-G leads to a significant growth reduction of the directly vector-treated tumor, but also of the contralateral not directly vector-treated tumor. When compared to monotherapy, the anti-neoplastic efficacy was significantly enhanced when intratumoral Ad.VSV-G administration was combined with adenovirus vectors encoding IL-2, IL-12, IL-18, IL-21, or GM-CSF. The anti-tumor effects of the first three cytokines in combination with VSV-G expression were somewhat greater than those of the latter two. However, the differences did not reach statistical significance. The combination therapy resulted also in a significantly enhanced survival when compared to monotherapy. In addition, we demonstrated that intratumoral expression of VSV-G in combination with the tested cytokines induced a strong tumor-specific cytotoxic T lymphocyte (CTL) response and infiltration of tumors with macrophages. The effects of the combination therapy were clearly greater than those of the monotherapy. Our experimental data indicate that intratumoral expression of VSV-G, particularly in combination with cytokines, is a promising novel tool for the development of in situ tumor vaccination approaches.     

In vitro and in vivo adherence of tumor cell variants correlated with tumor formation.

Murine fibrosarcoma variants that differed greatly in tumorgenicity, in vivo growth rate, and rate of spontaneous metastasis formation were compared for their ability to induce tumors in the lungs of syngeneic mice after intravenous injection of a suspension of single cells. Significantly more tumors were observed in the lungs of mice that received 1 x 10(5) of the cells of high malignant potential than in the lungs of animals that received 1 x 10(5) cells of lower malignant potential (54 tumors per animal vs 3 tumors per animal). When the tumor cells were prelabeled in culture for 24 hours with 125I-IUDR prior to intravenous injection, it was found that both the "high" and "low malignant" cells rapidly accumulated in the lungs (55-59% of the radioactivity was found in the lung tissue by 5 minutes after injection). However, by 4 hours only 4% of the low malignant cells (as indicated by the amount of radioactivity present) were still in the lungs, while a significantly higher percentage (13%) of the high malignant cells were still present in the lungs. The difference between the high and low malignant cells with regard to ability to remain sequestered in the lungs of syngeneic mice and to subsequently form tumors in the lungs of these animals correlated with the ability of the cells to form stable attachments to monolayers of endothelial cells in culture. While both the high and low malignant cells attached at the same rate to monolayers of bovine endothelial cells, once the cells were attached, the low malignant cells were released by trypsin treatment more easily than the high malignant cells. These observations suggest that the difference in malignant potential between the variants may be due, at least in part, to differences in ability to form stable attachments.     

Combination tumor immunotherapy with radiotherapy and Th1 cell therapy against murine lung carcinoma

Mice bearing established Lewis lung carcinoma (LLC) expressing model tumor antigen, ovalbumin (OVA) (LLC-OVA) marginally responded to local radiotherapy, but none of the mice was cured. In contrast, treatment of the tumor-bearing mice with intratumoral injection of tumor-specific T helper type 1 (Th1) cells and tumor antigen (OVA) after radiotherapy dramatically prolonged the survival days and induced complete cure of the mice at high frequency (80%). Radiation therapy combined with Th1 cells or OVA alone showed no significant therapeutic activity against LLC-OVA. Such a strong therapeutic activity was not induced by intratumoral injection of Th1 cells plus OVA. Compared with other treatment, radiation therapy combined with Th1 cells and OVA was superior to induce the generation of OVA/H-2^b tetramer⁺ tumor-specific cytotoxic T lymphocyte (CTL) with a strong cytotoxicity against LLC-OVA in draining lymph node (DLN). Moreover, the combined therapy is demonstrated to inhibit the growth of tumor mass, which grew at contralateral side. These results indicated that radiotherapy combined with Th1 cell/vaccine therapy induced a systemic antitumor immunity. These findings suggested that combination therapy with radiotherapy and Th1 cell/vaccine therapy may become a practical strategy for cancer treatment. Hiroshi Yokouchi and Kenji Chamoto are equally contributed.     

The Antitumor Effect Induced by Local Injections with Interleukin-2 is Diminished by Combing with a Local Injection with Mitomycin C

We investigated the antitumor effect of local injections with interleukin (IL)-2 in combination with an injection with mitomycin C (MMC). In BALB/c mice inoculated intraperitoneally (i.p.) with syngeneic Meth A fibrosarcoma on day 0, the i.p. injections with IL-2 at a dose of 20000U twice daily from day 7 to day 10 significantly prolonged survival of the treated mice and such treatment augmented a concomitant immunity specific for the tumor i.p. inoculated. On the other hand, the i.p. injections with IL-2 at a dose of either 5000U or 50000U resulted in no prolonged survival of the treated mice. In addition, neither intravenous nor subcutaneous injections with IL-2 at a dose of 20000U showed the prolonged survival of the treated mice. We further investigated a modulatory effect of a local injection with MMC on the IL-2-induced antitumor effect. The in vivo antitumor effect of local injections with IL-2 was not detected when combined with a local administration of MMC, whereas a systemic administration of MMC showed no such inhibitory effect on the IL-2-induced antitumor effect. Moreover, a delayed-type hypersensitivity response against Meth A, which was augmented by the local injections with IL-2, was significantly diminished by the local administration of MMC. Collectively, our results indicate that local injections with IL-2 could elicit the antitumor effect in viva only when given at an optimal dose and that this effect could be rather diminished by combing with a local administration of MMC.     

The therapeutic T‐cell response induced by tumor delivery of TNF and melphalan is dependent on early triggering of natural killer and dendritic cells

The fusion protein L19mTNF (mouse TNF and human antibody fragment L19 directed to fibronectin extra domain B) selectively targets the tumor vasculature, and in combination with melphalan induces a long‐lasting T‐cell therapeutic response and immune memory in murine models. Increasing evidence suggests that natural killer (NK) cells act to promote effective T‐cell‐based antitumor responses. We have analyzed the role of NK cells and dendritic cells (DCs) on two different murine tumor models: WEHI‐164 fibrosarcoma and C51 colon carcinoma, in which the combined treatment induces high and low rejection rates, respectively. In vivo NK‐cell depletion strongly reduced the rejection of WEHI‐164 fibrosarcoma and correlated with a decrease in mature DCs, CD4⁺, and CD8⁺ T cells in the tumor‐draining LNs and mature DCs and CD4⁺ T cells in the tumor 40 h after initiation of the therapy. NK‐cell depletion also resulted in the impairment of the stimulatory capability of DCs derived from tumor‐draining LNs of WEHI‐164‐treated mice. Moreover, a significant reduction of M2‐type infiltrating macrophages was detected in both tumors undergoing therapy. These results suggest that the efficacy of L19mTNF/melphalan therapy is strongly related to the early activation of NK cells and DCs, which are necessary for an effective T‐cell response.     

蓖麻毒素温敏型凝胶瘤内注射治疗耐药卵巢癌的实验研究

目的 探讨超声介导下蓖麻毒素缓释剂瘤体内注射对荷紫杉醇耐药人卵巢癌裸鼠皮下移植瘤增殖的抑制作用.方法 采用开环聚合法合成聚乳酸羟基乙酸-聚乙二醇-聚乳酸羟基乙酸(PLGA-PEG-PLGA),并制成蓖麻毒素温敏型凝胶、紫杉醇凝胶.采用浓度梯度递增法建立人卵巢癌耐药细胞株A2780/PTX,建立荷紫杉醇耐药人卵巢癌细胞的...     

The antitumor efficacy of functional paclitaxel nanomicelles in treating resistant breast cancers by oral delivery

Paclitaxel has shown potent efficacy against a wide spectrum of cancers in clinical treatment. However, chemotherapy with paclitaxel has been limited due to serious allergic reactions in patients caused by cremophor EL, and multidrug resistance in many types of tumors, and the restricted permeability across the intestinal barrier. Functional paclitaxel nanomicelles were developed to overcome these obstacles. Evaluations were performed on the breast cancer MCF-7 and resistant MCF-7/Adr cells, MCF-7 and MCF-7/Adr tumor spheroids, Caco-2 cell manolayers, everted gut sacs and the xenografted resistant MCF-7/Adr cancers in nude mice. The functional paclitaxel nanomicelles were approximately of 15?nm in diameter, significantly increased the intracellular uptake of paclitaxel, and selectively accumulated into mitochondria and endoplasmic reticulum after treatment, showing strong inhibitory effect on MCF-7 and MCF-7/Adr cells. They were able to penetrate deeply into the central region of the MCF-7 and MCF-7/Adr spheroids, resulting in a significant reduction in the size of the spheroids. TEM observations showed that the intact functional paclitaxel nanomicelles were transported across the Caco-2 cell manolayer or the everted gut sac. A significant antitumor efficacy in the xenografted resistant MCF-7/Adr cancers in mice was evidenced by oral administration, which was comparable to intravenous administration. The functional paclitaxel nanomicelles would provide a strategy for oral administration of paclitaxel, increasing solubility of paclitaxel, and overcoming the multidrug resistant cancers.     

Antimetastatic effect of suicide gene therapy for mouse mammary cancers requires T-cell-mediated immune responses

These experiments were conducted to investigate whether the antimetastatic effects of HSVtk/GCV therapy involve T-cell-mediated immune responses. In the first experiment, immunocompetent syngeneic mice were inoculated with metastatic mammary cancers, then given a direct intratumoral injection of a plasmid vector containing a suicide gene (pHSVtk) or control vector once a week for 8 weeks. Gene electrotransfer treatment was applied to the tumors, and mice were administered ganciclovir (GCV) using a mini-osmotic pump. At the end of the experiment, tumor volume was significantly lower in the pHSVtk/GCV group. Macrophage accumulations were frequently observed in the peripheries of the necrotic regions in pHSVtk-transfected mice. Levels of CD4 and CD8 proteins in tumors were higher in the pHSVtk/GCV group than in the control group. Interleukin (IL)-12 mRNA levels tended to be higher in tumors in the pHSVtk/GCV group, but there were large variations. Tumor microvessel density was significantly lower in the pHSVtk/GCV group. The numbers of dilated lymphatic vessels containing intraluminal tumor cells tended to be higher in the pHSVtk/GCV group. However, vascular endothelial growth factor (VEGF)-A and VEGF-C mRNA levels in tumors were similar in the control and pHSVtk/GCV groups. In the second experiment, tumor volume and metastatic parameters were compared for immunocompetent syngeneic mice and immunodeficient athymic mice (without an intact T-cell system) given pHSVtk/GCV therapy. Although tumor volumes were significantly smaller in both syngeneic and athymic mice given pHSVtk/GCV therapy, the inhibition ratios (relative to control mice) were much greater in syngeneic mice than in athymic mice. No suppression of metastasis to the lymph nodes and lungs was observed for athymic mice given pHSVtk/GCV therapy. Our data suggest that HSVtk/GCV suicide gene therapy exerts an antimetastatic effect via a T-cell-mediated immune response.     

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.     

The role of DCs in the immunoprotective effects of active immunization of elemene combo-tumor cell vaccine

The role of DCs in the immunoprotective effects of active immunization of elemene combo-tumor cell vaccine     

Significance of platelets in an antimetastatic activity of bacterial lipopolysaccharide

Recently we reported an antimetastatic activity of bacterial lipopolysaccharide (LPS) on a NK-cell-resistant murine fibrosarcoma (NFSa). Here we investigate and report the mechanistic significance of platelets in this activity. The number of circulating platelets was reduced to 63% of the control 3 days after an i.v. injection of 1.0 µg LPS, and then recovered to the level of control at day 10. Aggregation efficiency of platelets was impaired by LPS. The number of metastatic lung colonies after an i.v. injection of tumor cells was maximally reduced to 2.2% of the control at day 3 and increased in proportion to the recovery of platelet number. Neuraminidase (Ndase), which caused a non-immunological thrombocytopenia, also inhibited lung metastasis when injected prior to an i.v. tumor cell challenge. LPS and Ndase showed an identical pattern against five other syngeneic tumors; these agents inhibited lung metastases of the FSa fibrosarcoma and the SCC VII squamous cell carcinoma but failed to inhibit those of the NR-S1 squamous cell carcinoma, the MMCa#4 mammary adenocarcinoma and the NR-PG parotid gland tumor. All the three cells which were not responsive to any agents possessed a high aggregating activity of platelets while the other three tumors responsive to both agents did not show a detectable level of this activity. Platelet transfusion failed to modify the antimetastatic activity of LPS. These results suggest that platelets play an important role in the antimetastatic activity of LPS, though whether the role is principal or assistant remains to be seen.