Effective immunotherapy of cancer by DNA vaccination.

Direct injection of naked plasmid DNA either intramuscularly or intradermally induces strong, long-lived cell-mediated and humoral immune responses to the antigen encoded by the gene vaccine. In the present study, we used gene vaccination with naked plasmid DNA to induce prophylactic immune responses to tumor associated antigens. MAGE-1 (melanoma antigen 1) is an ideal candidate for cancer vaccines because it belongs to a family of genes that are expressed in a number of human tumors of various histological types but not in normal adult tissues except for the testis, and because both humoral and cell-mediated immune responses against MAGE-1 antigen were detected in tumor patients. Intradermal administration of plasmid DNA encoding MAGE-1 (pcMAGE1) induced anti-MAGE-1-specific antibody in BALB/c mice. In contrast, no detectable level of anti-MAGE-1 antibody was induced by intramuscular injection of pcMAGE1. Also, intradermal injection of pcMAGE1 was capable of generating CTLs reactive with MAGE-1-transfected murine tumor cells, M-MSV-MAGE1. Most of the mice (8 out of 10) immunized with pcMAGE1 rejected the challenge of M-MSV-MAGE1 tumor cells, compared with control animals most of which developed tumors. This suggests that intradermal DNA vaccination could provide a novel immunotherapy of cancer.     

Induction of antitumor immunity by vaccination of dendritic cells transfected with MUC1 RNA

Dendritic cells (DC) are potent APCs. In this study, murine bone marrow-derived DC were transfected with RNA encoding the MUC1 Ag that is aberrantly overexpressed in human breast and other carcinomas. The MUC1 RNA-transfected DC exhibited cell surface expression of MUC1 and costimulatory molecules. After injection at the base of the tail, the transfected DC were detectable in inguinal lymph nodes by dual immunochemical staining. Vaccination of wild-type mice with MUC1 RNA-transfected DC induced anti-MUC1 immune responses against MUC1-positive MC38/MUC1, but not MUC1-negative, tumor cells. Mice immunized with the transfected DC were protected against challenge with MC38/MUC1 tumor cells. Furthermore, mice with established MC38/MUC1 tumors were eliminated after receiving the vaccination. CTLs isolated from mice immunized with the transfected DC exhibited specific cytolytic activity against MC38/MUC1 tumor cells. In contrast to these findings, there was little if any anti-MUC1 immunity induced with the transfected DC in MUC1 transgenic (MUC1.Tg) mice. However, coadministration of the transfected DC and IL-12 reversed the unresponsiveness to MUC1 Ag in MUC1.Tg mice and induced MUC1-specific immune responses. These findings demonstrate that vaccination of DC transfected with MUC1 RNA and IL-12 reverses tolerance to MUC1 and induces immunity against MUC1-positive tumors.     

A low-level expression of human MUC1 mucin enhances lethality of murine tumor cells

We report here the development of a mouse mammary adenocarcinoma cell line containing full-length human MUC1 cDNA that can be more lethal than the parental cell line. The metastatic murine mammary adenocarcinoma cell line 410.4 was transfected with cDNA coding for a 42-tandem-repeat version of human MUC1. Two cell lines were selected, one for stable, high expression in vitro of cell-surface MUC1 (GZHi) and one for stable, low expression in vitro of cell-surface MUC1 (GZLo). Following subcutaneous challenge of CB6F1 mice with various doses of tumor cells, GZHi tumors showed loss of MUC1 expression; negligible amounts of serum MUC1 mucin were detected and the mice survived longer than mice challenged with GZLo or wild-type (410.4) tumor cells. Mice challenged with GZLo tumor cells had shorter survival times than mice challenged with either GZHi or 410.4 tumor cells. GZLo-challenged mice that showed rapidly increasing serum MUC1 mucin levels several weeks prior to death had a shorter survival than mice without detectable rising MUC1 serum levels. Surprisingly, SCID-BEIGE mice challenged with GZLo cells also survived for a shorter time than those challenged with either GZHi or 410.4 cells. This suggests that MUC1 mucin may also enhance the aggressiveness of GZLo tumors by non-immune mechanisms. Received: 30 November 1999 / Accepted: 13 March 2000     

日本血吸虫新抗原基因的筛选、克隆、 表达和免疫效果研究

为了寻找日本血吸虫 (Schistosoma japonicum, Sj) 新的疫苗候选基因并进行免疫效果研究,用 Sj 雌虫抗原免疫家兔制备血清,对Sj成虫 cDNA 文库进行免疫筛选,将获得的新基因 ( 命名为Sj-F1, GenBank 登录号为 AY261995) 克隆入原核表达载体 pTWIN1 和真核表达载体 pcDNA3 ,经 PCR 、限制性酶切筛选和鉴定阳性重组子. 将 pTWIN1/Sj-F1 质粒转化大肠杆菌 ER2566,在低温和低 IPTG 浓度下诱导表达可溶性重组融合蛋白 (rSj-F1/intein2),并经 SDS- 聚丙烯酰胺凝胶电泳 (SDS-PAGE) 和蛋白质印迹 (Western blot) 分析鉴定. 将 pcDNA3/Sj-F1 质粒转化大肠杆菌 ER2502 ,大量制备 DNA 疫苗. 用重组融合蛋白和 DNA 疫苗免疫小鼠,末次免疫后 2 周用Sj尾蚴进行攻击感染. 感染后 42 天剖杀冲虫,计算减虫率和减卵率. 感染前采血用 ELISA 法检测抗体. 免疫保护效果测定显示：重组蛋白疫苗以 FCA 作佐剂经皮下免疫和以壳聚糖作佐剂经粘膜免疫分别获得了 28.07%、 24.69% 的减虫率和 48.30% 、 46.38% 的减卵率; DNA 疫苗 (pcDNA3/Sj-F1) 单独免疫获得了 18.47% 的减虫率和 35.06% 的减卵率;用 DNA 疫苗启动免疫后用重组蛋白疫苗经皮下加强免疫,减虫率和减卵率分别提高到了 40.42% 和 56.17%;用 DNA 疫苗启动免疫后用重组蛋白疫苗经黏膜加强免疫,减虫率和减卵率增高更明显,分别提高到了 42.38% 和 62.87%. 结果表明,Sj-F1 重组蛋白疫苗及 DNA 疫苗均可诱导小鼠产生部分抗血吸虫感染的保护力,两者联合免疫保护效果优于单一疫苗.     

Induction of impaired antitumor immunity by fusion of MHC class II-deficient dendritic cells with tumor cells

To dissect the role of Ag presentation through MHC class I and/or II pathways by dendritic cell (DC)-tumor fusion cells, we have created various types of DC-tumor fusion cells by alternating fusion cell partners. Fusions of MC38/MUC1 carcinoma cells with DC from wild-type (WT-DC), MHC class I knockout (IKO-DC), class II knockout (IIKO-DC), or class I and II knockout (I/IIKO-DC) mice created WTDC-fusion cells (FC), IKO-FC, IIKO-FC, and I/IIKO-FC, respectively. MHC class II- and MUC1-positive fusion cells were constructed by fusion of B16/MUC1 melanoma cells with IKO-DC (IKO/B16-FC). Immunization of MUC1 transgenic mice with 5 x 10(5) WTDC-FC, IKO-FC, IIKO-FC, or I/IIKO-FC provided 100, 91.7, 61.5, and 15.4% protection, respectively, against tumor challenge with MC38/MUC1 cells. In contrast, all mice immunized with irradiated MC38/MUC1 tumor cells or WT-DC developed tumors. One group of mice was immunized with 5 x 10(5) IKO/B16-FC and then challenged with B16/Ia(+)/MUC1 on one flank and MC38/MUC1 on the other flank. Immunization of these mice with IKO/B16-FC resulted in 100 and 78.6% protection against B16/Ia(+)/MUC1 and MC38/MUC1 tumor challenge, respectively. The antitumor immunity induced by immunization with IKO/B16-FC was able to inhibit the growth of MHC class II-negative tumor. In addition, in vivo results correlated with the induction of Ag-specific CTL. Collectively, the data indicate that MHC class II Ag presentation targeting activation of CD4 T cells is indispensable for antitumor immunity.     

Recombinant human tumor antigen MUC1 expressed in insect cells: structure and immunogenicity

MUC1, a member of the mucin family of molecules, is a transmembrane glycoprotein abundantly expressed on human ductal epithelial cells and tumors originating from those cells. MUC1 expressed by malignant cells is aberrantly O-glycosylated. Differences in O-glycosylation of the tandem repeat region of MUC1 make tumor and normal forms of this antigen immunologically distinct. The tumor-specific glycoform is, therefore, expected to be a good target for immunotherapy and a good immunogen for generation of antitumor immune responses. We have generated a renewable source of this glycoform by expressing MUC1 cDNA in Sf-9 insect cells using a baculovirus vector. This form of MUC1 (BV-MUC1) is O-glycosylated at a very low level, approximately 0.3% (w/w), and this is not due to the lack of appropriate glycosylotransferases in insect cells. Peptidyl GalNAc-transferases isolated from Sf-9 cells were able to glycosylate in vitro a synthetic MUC1 peptide as efficiently as the transferases isolated from human milk. Neither preparation of peptidyl GalNAc-transferases, however, was able to glycosylate BV-MUC1. This underglycosylated recombinant MUC1 mimics underglycosylated MUC1 on human tumor cells and could serve as an immunogen to stimulate responses that would recognize MUC1 on tumor cells. To test this we immunized mice with Sf-9 cells expressing BV-MUC1. Sera from immunized mice recognized MUC1 on human tumor cells. We also generated MUC1-specific T cells that proliferated in response to synthetic MUC1 peptide.     

The cooperation between two CD4 T cells induces tumor protective immunity in MUC.1 transgenic mice

Immunity and tumor protection in mice transgenic for human MUC.1, a glycoprotein expressed in the majority of cancers of epithelial origin in humans, were induced by vaccination with B lymphocytes genetically programmed to activate MUC.1-specific CD4 T cells. Their activation required a functional cooperation between two Th cells, one specific for a self (MUC.1) and the other for a nonself T cell determinant. The immunological switch provided by Th-Th cooperation was sufficient to induce MUC.1-specific CD4 and CD8 T cell responses in MUC.1-transgenic mice, and protect them permanently from tumor growth. CD4 T cells specific for MUC.1 lacked cytolytic function, but produced IFN-gamma upon restimulation with Ag. We conclude that immunity against tumor self-Ags and tumor protection can be regulated exploiting an inherent property of the immune system.     

DNA immunization confers protection against murine cytomegalovirus infection.

The murine cytomegalovirus (MCMV) immediate-early gene 1 (IE1) encodes an 89-kDa phosphoprotein (pp89) which plays a key role in protecting BALB/c mice against the lethal effects of the MCMV infection. In this report, we have addressed the question of whether "naked DNA" vaccination with a eukaryotic expression vector (pcDNA-89) that contains the MCMV IE1 gene driven by a strong enhancer/promoter can confer protection. BALB/c mice were immunized intradermally with pcDNA-89 or with the plasmid backbone pcDNAI/Amp (pcDNA) and then challenged 2 weeks later with either a lethal or a sublethal intraperitoneal dose of the K181 strain of MCMV. Variable results were obtained for the individual experiments in which mice received a lethal challenge. In four separate trials, an average of 63% of the mice immunized with pcDNA-89 survived, compared with 18% of the mice immunized with pcDNA. However, in two other trials there was no specific protection. The results of experiments in which mice were injected with a sublethal dose of MCMV were more consistent, and significant decreases in viral titer in the spleen and salivary glands of pcDNA-89-immunized mice were observed, relative to controls. At the time of peak viral replication, titers in the spleens of immunized mice were reduced 18- to >63-fold, while those in the salivary gland were reduced approximately 24- to 48-fold. Although DNA immunization elicited only a low level of seroconversion in these mice, by 7 weeks postimmunization the mice had generated a cytotoxic T-lymphocyte response against pp89. These results suggest that DNA vaccination with selected CMV genes may provide a safe and efficient means of immunizing against CMV disease.     

Xenogeneic Human p53 DNA Vaccination by Electroporation Breaks Immune Tolerance to Control Murine Tumors Expressing Mouse p53

The pivotal role of p53 as a tumor suppressor protein is illustrated by the fact that this protein is found mutated in more than 50% of human cancers. In most cases, mutations in p53 greatly increase the otherwise short half-life of this protein in normal tissue and cause it to accumulate in the cytoplasm of tumors. The overexpression of mutated p53 in tumor cells makes p53 a potentially desirable target for the development of cancer immunotherapy. However, p53 protein represents an endogenous tumor-associated antigen (TAA). Immunization against a self-antigen is challenging because an antigen-specific immune response likely generates only low affinity antigen-specific CD8⁺ T-cells. This represents a bottleneck of tumor immunotherapy when targeting endogenous TAAs expressed by tumors. The objective of the current study is to develop a safe cancer immunotherapy using a naked DNA vaccine. The vaccine employs a xenogeneic p53 gene to break immune tolerance resulting in a potent therapeutic antitumor effect against tumors expressing mutated p53. Our study assessed the therapeutic antitumor effect after immunization with DNA encoding human p53 (hp53) or mouse p53 (mp53). Mice immunized with xenogeneic full length hp53 DNA plasmid intramuscularly followed by electroporation were protected against challenge with murine colon cancer MC38 while those immunized with mp53 DNA were not. In a therapeutic model, established MC38 tumors were also well controlled by treatment with hp53 DNA therapy in tumor bearing mice compared to mp53 DNA. Mice vaccinated with hp53 DNA plasmid also exhibited an increase in mp53-specific CD8⁺ T-cell precursors compared to vaccination with mp53 DNA. Antibody depletion experiments also demonstrated that CD8⁺ T-cells play crucial roles in the antitumor effects. This study showed intramuscular vaccination with xenogeneic p53 DNA vaccine followed by electroporation is capable of inducing potent antitumor effects against tumors expressing mutated p53 through CD8⁺ T cells.     

Memory and cellular immunity induced by a DNA vaccine encoding self antigen TPD52 administered with soluble GM-CSF

Tumor protein D52 (TPD52) is involved in cellular transformation, proliferation and metastasis. TPD52 over expression has been demonstrated in several cancers including prostate, breast, and ovarian carcinomas. Murine TPD52 (mD52) has been shown to induce anchorage independent growth in vitro and metastasis in vivo, and mirrors the function and normal tissue expression patterns of the human orthologue of TPD52. We believe TPD52 represents a self, non-mutated tumor associated antigen (TAA) important for maintaining a transformed and metastatic cellular phenotype. The transgenic adeno-carcinoma of the mouse prostate (TRAMP) model was employed to study mD52 as a vaccine antigen. Naïve mice were immunized with either recombinant mD52 protein or plasmid DNA encoding the full-length cDNA of mD52. Following immunization, mice were challenged with a subcutaneous, tumorigenic dose of mD52 positive, autochthonous TRAMP-C1 tumor cells. Sixty percent of mice were tumor free 85 days post challenge with TRAMP-C1 when immunized with mD52 as a DNA-based vaccine admixed with soluble granulocyte-macrophage colony stimulating factor (GM-CSF). Survivors of the initial tumor challenge rejected a second tumor challenge given in the opposite flank approximately 150 days after the first challenge, and remained tumor free for more than an additional 100 days. The T cell cytokine secretion patterns from tumor challenge survivors indicated that a T_H1-type cellular immune response was involved in tumor protection. These data suggest that mD52 vaccination induced a memory, cellular immune response that resulted in protection from murine prostate tumors that naturally over express mD52 protein.     

Dissecting the Immune Response to Moloney Murine Sarcoma/Leukemia Virus-Induced Tumors by Means of a DNA Vaccination Approach

The intramuscular inoculation of Moloney murine sarcoma/leukemia (M-MSV/M-MuLV) retroviral complex gives rise to sarcomas that undergo spontaneous regression due to the induction of a strong immune reaction mediated primarily by cytotoxic T lymphocytes (CTL). We used a DNA-based vaccination approach to dissect the CTL response against the Gag and Env proteins of M-MSV/M-MuLV in C57BL/6 (B6) mice and to evaluate whether plasmid DNA-immunized mice would be protected against a subsequent challenge with syngeneic tumor cells expressing the viral antigens. Intramuscular DNA vaccination induced CTL against both Gag and Env proteins. A detailed analysis of epitopes recognized by CTL generated in mice inoculated with the whole virus and with the Gag-expressing plasmid confirmed the presence of an immunodominant peptide in the leader sequence of Gag protein (Gag_85–93, CCLCLTVFL) that is identical to that described in B6 mice immunized with Friend MuLV-induced leukemia cells. Moreover, CTL generated by immunization with the Env-encoding plasmid recognized a subdominant Env peptide (Env_189–196, SSWDFITV), originally described in the B6.CH-2^bm13 mutant strain. B6 mice immunized with the Gag-expressing plasmid were fully protected against a lethal tumor challenge with M-MuLV-transformed MBL-2 leukemia cells, while vaccination with the Env-expressing plasmid resulted in rejection of the tumor in 44% of the mice and in increased survival of an additional 17% of the animals. Taken together, these results indicate the existence of a hierarchy in the capacity of different structural viral proteins to induce a protective immune response against retrovirus-induced tumors.     

Vaccination with metastasis-related tumor associated antigen TPD52 and CpG/ODN induces protective tumor immunity

Tumor protein D52 (TPD52) is involved in transformation and metastasis and has been shown to be over-expressed in tumor cells compared to normal cells and tissues. Murine TPD52 (mD52) shares 86% protein identity with the human TPD52 orthologue (hD52). To study TPD52 protein as a target for active vaccination recombinant, mD52 was administered as a protein-based vaccine. Naïve mice were immunized with either mD52 protein and CpG/ODN as a molecular adjuvant or CpG/ODN alone. Two weeks following the final immunization, mice were challenged s.c. with syngeneic tumor cells that over-express mD52. Two distinct murine tumor cell lines were used for challenge in this model, mKSA and 3T3.mD52. Half of the mice immunized with mD52 and CpG/ODN rejected or delayed onset of mKSA s.c. tumor cell growth, and 40% of mice challenged with 3T3.mD52 rejected s.c. tumor growth, as well as the formation of spontaneous lethal lung metastases. Mice immunized with mD52 and CpG/ODN generated detectable mD52-specific IgG antibody responses indicating that mD52 protein vaccination induced an adaptive immune response. In addition, mice that rejected tumor challenge generated tumor-specific cytotoxic T lymphocytes’ responses. Importantly, microscopic and gross evaluation of organs from mD52 immunized mice revealed no evidence of autoimmunity as assessed by absence of T cell infiltration and absence of microscopic pathology. Together, these data demonstrate that mD52 vaccination induces an immune response that is capable of rejecting tumors that over-express mD52 without the induction of harmful autoimmunity.     

A DNA vaccine candidate for <Emphasis Type="Italic">B. anthracis</Emphasis> immunization,pcDNA3.1+PA plasmid,induce Th1/Th2 mixed responses and protection in mice

The protective antigen (PA) of Bacillus anthracis (B. anthracis) is a potent immunogen and a candidate subunit vaccine. To address the question whether antibodies raised against PA following injection of pcDNA3.1+PA plasmid, encoding PA, can protect against virulent B. anthracis two different regimens of PA based vaccines (DNA and live spore) were used. The groups of BALB/c mice that received live spores of the Sterne strain, naked pcDNA3.1 and naked pcDNA3.1+PA were compared to control groups. All groups were injected three times with 30-day intervals. Two weeks after the last immunization, all mice were subjected to challenge with a pathogenic strain of B. anthracis (C2). Blood samples were taken before each injection and challenge. Evaluation of the sera by ELISA method showed that DNA immunization using pcDNA3.1+PA plasmid resulted in an antibody profile representative of a mixed Th1 and Th2 response, with a skewing to a Th1 response. The group which received the naked pcDNA3.1+PA had a survival rate of >80%. This challenge assay revealed that antibodies raised following DNA vaccination against PA can confer strong protection, and resistance against virulent species of B. anthracis.     

MUC1 enhances tumor progression and contributes toward immunosuppression in a mouse model of spontaneous pancreatic adenocarcinoma

MUC1, a membrane tethered mucin glycoprotein, is overexpressed and aberrantly glycosylated in >80% of human ductal pancreatic adenocarcinoma. However, the role of MUC1 in pancreatic cancer has been elusive, partly due to the lack of an appropriate model. We report the characterization of a novel mouse model that expresses human MUC1 as a self molecule (PDA.MUC1 mice). Pancreatic tumors arise in an appropriate MUC1-tolerant background within an immune-competent host. Significant enhancement in the development of pancreatic intraepithelial preneoplastic lesions and progression to adenocarcinoma is observed in PDA.MUC1 mice, possibly due to increased proliferation. Tumors from PDA.MUC1 mice express higher levels of cyclooxygenase-2 and IDO compared with PDA mice lacking MUC1, especially during early stages of tumor development. The increased proinflammatory milieu correlates with an increased percentage of regulatory T cells and myeloid suppressor cells in the pancreatic tumor and tumor draining lymph nodes. Data shows that during pancreatic cancer progression, MUC1-mediated mechanisms enhance the onset and progression of the disease, which in turn regulate the immune responses. Thus, the mouse model is ideally suited for testing novel chemopreventive and therapeutic strategies against pancreatic cancer.     

Systemic priming-boosting immunization with a trivalent plasmid DNA and inactivated murine cytomegalovirus (MCMV) vaccine provides long-term protection against viral replication following systemic or mucosal MCMV challenge

We previously demonstrated that vaccination of BALB/c mice with a pool of 13 plasmid DNAs (pDNAs) expressing murine cytomegalovirus (MCMV) genes followed by formalin-inactivated MCMV (FI-MCMV) resulted in complete protection against viral replication in the spleen and salivary glands following sublethal intraperitoneal (i.p.) challenge. Here, we found that following intranasal (i.n.) challenge, titers of virus in the lungs of the immunized mice were reduced approximately 1,000-fold relative to those for mock-immunized controls. We next sought to extend these results and to determine whether similar protection levels could be achieved by priming with a pool of three pDNAs containing three key plasmids (IE1, M84, and gB). We found that the three-pDNA priming elicited IE1- and M84-p65-specific CD8+ T lymphocytes and, following FI-MCMV boost, high levels of virion-specific immunoglobulin G (IgG) and virus-neutralizing antibodies. When mice were i.n. challenged 4 months after the last boost, titers of virus in the lungs of immunized mice were reduced 1,000- to 2,000-fold from those for controls during the peak of viral replication. Additionally, titers of virus were either at or below the detection limits for the salivary glands, liver, and spleen of the majority of the immunized mice. Following sublethal i.p. challenge, virus was undetectable in all of the above target organs of the immunized mice. Virion-specific IgA in the lungs was consistently detected by day 6 post-i.n. challenge for the immunized mice and by day 14 for controls. These results demonstrate the immunity and high levels of protection of the priming-boosting vaccination against both systemic and mucosal challenge.     

A long-term memory obtained by genetic immunization results in full protection from a mammary adenocarcinoma expressing an EBV gene

We have tested the capability of a plasmid DNA (pDNA) expressing the EBV nuclear Ag-4 (EBNA-4) to evoke a T cell response-associated protective immune response against a tumor expressing this gene. We have found that ACA mice immunized with EBNA-4-expressing plasmid were partially protected against syngeneic mammary carcinoma line (S6C) expressing EBNA-4 (S6C-E4). This protection was enhanced by coimmunizing mice with EBNA-4- and GM-CSF-expressing plasmids, and a full protection was achieved by coimmunizing mice with EBNA-4- and IFN-gamma-expressing plasmids. Furthermore, mice that have rejected the EBNA-4-positive tumor were also resistant against a subsequent challenge with the original nontransfected tumor line. We then checked for the ability of pDNA immunization to provide a protective long-term memory response. We indeed found that even after 3 mo from the last immunization, full protection was obtained by this method, as compared with full tumor outgrowth in the control-immunized group. These findings support the concept that a nonviral, pDNA-based vaccination strategy is useful to fully protect from the outgrowth of tumors expressing this EBV gene.     

Transplacental genetic immunization after intravenous delivery of plasmid DNA to pregnant mice.

A number of factors influence the development of tolerance, including the nature, concentration, and mode of Ag presentation to the immune system, as well as the age of the host. The studies were conducted to determine whether immunizing pregnant mice with liposome-encapsulated DNA vaccines had an effect on the immune status of their offspring. Two different plasmids (encoding Ags from HIV-1 and influenza virus) were administered i.v. to pregnant mice. We examined the uptake of plasmid DNA by the fetuses until the 21st postcoital day, but little such transfer occurred in early pregnancy. At 9.5 days postconception with cationic liposomes, injected plasmid was present in the tissues of the fetus, consistent with transplacental transfer. When the offspring of vaccinated dams were immunized with DNA vaccine, they mounted stronger Ag-specific immune responses than controls, and were protected against challenge by homologous influenza virus after vaccination. Moreover, such immune responses were strong in the offspring of mothers injected with DNA plasmid 9.5 days after coitus. These results suggest that DNA-vaccinated mothers confer the Ag-specific immunity to their progeny.     

Coadministration of gamma interferon with DNA vaccine expressing woodchuck hepatitis virus (WHV) core antigen enhances the specific immune response and protects against WHV infection

DNA vaccinations are able to induce strong cellular immune responses in mice and confer protection against infectious agents. However, DNA vaccination of large animals appears to be less effective and requires repeated injections of large amounts of plasmid DNA. Enhancement of the efficiency of DNA vaccines may be achieved by coapplication of cytokine-expressing plasmids. Here we investigated, with woodchucks, whether coadministration of an expression plasmid for woodchuck gamma interferon (IFN-gamma), pWIFN-gamma, can improve DNA vaccination with woodchuck hepatitis virus core antigen (WHcAg). Animals were immunized with pWHcIm (a plasmid expressing WHcAg) alone or with a combination of pWHcIm and pWIFN-gamma using a gene gun. Six weeks postimmunization, all animals were challenged with 10(5) genome equivalents of woodchuck hepatitis virus (WHV). The antibody and lymphoproliferative immune responses to WHV proteins were determined after immunization and after challenge. Vaccination with pWHcIm and pWIFN-gamma led to a pronounced lymphoproliferative response to WHcAg and protected woodchucks against subsequent virus challenge. Two of three animals vaccinated with pWHcIm alone did not show a detectable lymphoproliferative response to WHcAg. A low-level WHV infection occurred in these woodchucks after challenge, as WHV DNA was detectable in the serum by PCR. None of the pWHcIm-vaccinated animals showed an anti-WHcAg antibody response after DNA vaccination or an anamnestic response after virus challenge. Our results indicate that coadministration of the WIFN-gamma gene with pWHcIm enhanced the specific cellular immune response and improved the protective efficacy of WHV-specific DNA vaccines.     

Prophylactic tumor vaccination: comparison of effector mechanisms initiated by protein versus DNA vaccination

Clinical success in tumor vaccination frequently does not reach expectation. Since vaccination protocols are quite variable, we used the murine renal cell carcinoma line RENCA transfected with the lacZ gene (RENCA-beta-gal) to compare the efficacy of two different vaccination strategies or their combination and to elaborate on the underlying mechanisms. BALB/c mice were vaccinated either with naked lacZ DNA or with attenuated SALMONELLA: typhimurium transformed with lacZ DNA or with dendritic cells (DC) loaded with the beta-galactosidase protein or mice were vaccinated with both DNA and protein. Although all regimens led to a prolongation of survival time, oral vaccination with transfected S. typhimurium followed by i.v. transfer of protein-loaded DC provided the optimal schedule. In this setting, >50% of mice remained tumor free after challenge with 10 times the lethal tumor dose of RENCA-beta-gal. As explored in transfer experiments, the superior efficacy of combining DNA and protein vaccination is due to the facts that 1) optimal protection depends on both activated CD4(+) and CD8(+) cells and 2) CD8(+) CTL are most strongly activated by vaccination with transformed SALMONELLA:, whereas vaccination with protein-loaded DC is superior for the activation of Th. The latter induced sustained activation of CTL and recruitment of nonadaptive defense mechanisms. The data demonstrate the strength of DNA vaccination, particularly by the oral route, and provide evidence that a combined treatment with protein-loaded DC can significantly increase the therapeutic efficacy.     

No influence of tumor growth by intramuscular injection of hepatocyte growth factor plasmid DNA: safety evaluation of therapeutic angiogenesis gene therapy in mice

Recently, a novel therapeutic treatment for ischemic diseases using angiogenic growth factors to augment collateral artery development has been proposed. As intramuscular injection of naked human hepatocyte growth factor (HGF) plasmid DNA induced therapeutic angiogenesis in several animal test subjects, we have started a clinical trial to treat peripheral arterial disease. However, one might assume that over-expression of angiogenic growth factors could enhance tumor growth. To resolve this issue, we examined the over-expression of HGF in tumor bearing mice. Tumors on their backs were prepared with an intradermal inoculation of A431, human epidermoid cancer cells expressing c-Met. These mice were intramuscularly injected with human HGF plasmid or control plasmid into the femoral muscle. Human HGF concentration was increased only in the femoral muscle, but not in blood. Although recombinant HGF stimulated the growth of A431 cells in vitro, temporally and locally HGF elevation in hindlimb had no effect on tumor growth in mice.