树突状细胞融合瘤苗在肿瘤免疫中的研究进展

树突状细胞(DC)是诱导初始免疫应答反应的专职抗原提呈细胞,它能捕获抗原并加工处理成小分子多肽,通过MHC Ⅰ类和Ⅱ类分子提呈给T细胞和B细胞.Dc与肿瘤细胞融合所获得的融合瘤细胞,在共刺激信号存在的条件下,能够加工处理细胞内许多已知和未知的肿瘤相关抗原(TAA),并通过MHC Ⅰ类和Ⅱ类分子提呈.目前,DC融合瘤苗在动物和临床研究中取得了许多进展,已成为肿瘤免疫治疗的热点之一.     

Tumor cells transduced with the MHC class II Transactivator and CD80 activate tumor-specific CD4+ T cells whether or not they are silenced for invariant chain

The specificity and potency of the immune system make immunotherapy a potential strategy for the treatment of cancer. To exploit this potential, we have developed cell-based cancer vaccines consisting of tumor cells expressing syngeneic MHC class II and costimulatory molecules. The vaccines mediate tumor regression in mice and activate human CD4+ T cells in vitro. Previous vaccines were generated by transducing MHC II negative tumor cells with a single HLA-DR allele. Because expression of multiple MHC II alleles would facilitate presentation of a broader repertoire of tumor antigens, we have now transduced tumor cells with the MHC class II transactivator (CIITA), a regulatory gene that coordinately increases expression of all MHC II alleles. Previous studies in mice indicated that coexpression of the MHC II accessory molecule invariant chain (Ii) inhibited presentation of endogenously synthesized tumor antigens and reduced vaccine efficacy. To determine if Ii expression affects presentation of MHC class II-restricted endogenously synthesized tumor antigens in human tumor cells, HLA-DR-MCF10 breast cancer cells were transduced with the CIITA, CD80 costimulatory molecule gene, and with or without small interfering RNAs (siRNA) specific for Ii. Ii expression is silenced >95% in CIITA/CD80/siRNA transductants; down-regulation of Ii does not affect HLA-DR expression or stability; and Ii(+) and Ii(-) transductants activate human CD4+ T cells to DRB1*0701-restricted HER-2/neu epitopes. Therefore, tumor cells transduced with the CIITA, CD80, and with or without Ii siRNA present endogenously synthesized tumor antigens and are potential vaccines for activating tumor-specific CD4+ T cells.     

A novel strategy for the discovery of MHC class II-restricted tumor antigens: identification of a melanotransferrin helper T-cell epitope

CD4+ helper T cells play a critical role in orchestrating host immune responses, including antitumor immunity. The limited availability of MHC class II-associated tumor antigens is still viewed as a major obstacle in the use of CD4+ T cells in cancer vaccines. Here, we describe a novel approach for the identification of MHC class II tumor-associated antigens (TAAs). By combining two-dimensional liquid chromatography and nanoelectrospray ionization tandem mass spectrometry, we developed a highly sensitive method for the detection of human leukocyte antigen (HLA)-DR-associated peptides of dendritic cells upon exposure to necrotic tumor cells. This approach led to the identification of a novel MHC class II-restricted TAA epitope derived from melanotransferrin. The epitope stimulated T cells derived from melanoma patients and healthy individuals and displayed promiscuity in HLA-DR restriction. Moreover, the same peptide was also presented by MHC class II-positive melanoma cells. This strategy may contribute to increase the number of tumor epitopes presented by MHC class II molecules and may support the development of more efficacious vaccines against cancer.     

Direct identification of human tumor-associated peptide antigens and a preclinical model to evaluate their use

Although the arsenal of a healthy immune system includes both circulating antibodies and cellular components such as T cells, the latter seem to be particularly important in tumor immunology. Under normal conditions, the immune system does not react to the body's cells, which may be described as expressing "self" antigens on the cell surface. When a cell becomes cancerous, however, novel antigens are expressed on the cell surface. These novel "tumor" antigens are recognized as foreign by the body's immune system, and the cells that express them are destroyed or incapacitated. Whereas antibodies may react directly with protein antigens, T cells instead recognize peptide antigens presented by class I and class II molecules of the major histocompatibility complex (MHC). All cells normally break down proteins that they have made. The class I antigen-processing pathway has evolved to display peptides produced by this breakdown process as a way to provide information to cytotoxic T cells about what the cell is making. The display of new peptides as a result of infection or transformation can stimulate cytotoxic T cells to kill the cell. In addition, antigen-processing cells such as dendritic cells engulf dead or dying cells and degradeproteins into peptide fragments. These peptides are then displayed by the MHC class II molecules and presented to T helper cells, which augment the activity of the cytotoxic T cells. Cytotoxic T lymphocytes have recently been isolated from human tumors (especially melanoma) and are critical to the development of promising immunotherapeutic agents. As we shall discuss, these cells can recognize antigens that are common to tumors from different patients. We shall also explore how advances in instrumentation and the use of transgenic mice have increased our understanding of tumor-associated peptides to the point where we can begin to strive for a peptide-based therapeutic vaccine. The caveats for such therapy will also be addressed.     

Clinical significance of MHC class II-associated invariant chain expression in human gastric carcinoma

MHC class II antigens serve as restricted elements for cell presenting antigens to CD4+ helper T cells. CD4+ T cells and CD8+ cytotoxic T cells, which are tumor-infiltrating lymphocytes (TILs), and play a major role in the survey and attack against tumor cells in primary lesions. Invariant chain (Ii) has several functions in MHC class II-restricted antigen presentation. In addition, Ii is found to be closely involved in the regulation of anti-tumor immunity in several tumor types. However, the significance of Ii expression in tumor cells is not fully illustrated. Immunohistochemical staining of Ii expression was performed in 58 cases of human gastric carcinoma specimens. The prognostic analysis of patients with gastric carcinoma was also performed. A total of 67.2% (39/58) gastric carcinomas were found to be Ii-positive, whereas only 20.7% (12/58) showed positive immunoreactivity with anti-MHC class II determinants. Furthermore, Ii expression showed significant correlation with the differentiation of gastric carcinoma (p<0.05). Ii expression also showed an inverse correlation with the frequency of TILs around carcinoma tissues, as well as with the prognosis of gastric carcinoma (p<0.01). Ii expression is closely correlated with anti-tumor immunity in human gastric carcinoma. Therefore, Ii may serve as an independent clinical marker for poor biological behavior and prognostic analysis in patients with gastric carcinoma.     

Influence of major histocompatibility complex class I, class II and TLA genes on tumor rejection.

T lymphocytes recognize antigen associated with MHC class I and/or class II gene products. Recognition of malignant cells is therefore dependent on presentation of tumor associated antigen(s) by MHC molecules. We have studied immunity to tumors that have down-regulated class I expression. These studies demonstrate a requirement for class I antigens, but suggest that additional factors may also be required for tumor-specific immunity. The MHC also encodes TLA class I antigens, whose function is unknown. Our studies suggest that these molecules function is unknown. Our studies suggest that T lymphocytes, specifically in tumor cells that do not express H-2K or H-2D moieties. Other studies are aimed at improving tumor-specific Th cell generation by producing class II+ tumor cells. The success of these experiments indicates that this approach may be a potentially useful immunotherapy.     

Small cell lung carcinomas express shared and private tumor antigens presented by HLA-A1 or HLA-A2.

Tumor-derived peptides presented by MHC class I molecules are targets for tumor rejection by CD8+ CTLs. MHC-restricted CD8+ CTLs are required also for the identification and characterization of tumor antigens that will be useful for immune therapy. For many human solid tumors, however, tumor antigens remain undefined because of the difficulty of generating MHC-restricted, tumor-specific CTLs required for their analysis. CD8+ CTL responses are modulated by CD4+ helper T cells and by antigen-presenting cells. In this study, highly purified CD8+ T cells were mixed with tumor cells in primary cultures in the absence of any other cells to reduce the complexity of CTL generation. Tumor cells were transfected with HLA-A1 or HLA-A2 and used to stimulate partly matched HLA-A1- or HLA-A2-positive CD8+ T cells. Partial MHC class I matching of tumor and CD8+ T cells and omission of other cells in primary culture was highly effective in generating MHC class I-restricted CTL to poorly immunogenic small cell lung carcinomas (SCLCs). Cytotoxicity was further enhanced by cotransfection of tumor cells with B7.1 (CD80). ICAM-1 (CD54) was not as effective as costimulation. SCLC cells presented tumor-specific peptides with HLA-A1 and HLA-A2 and were lysed by A1- or A2-restricted CD8+ CTLs. A1- and A2-restricted CD8+ CTLs detected shared tumor antigens on unrelated SCLC tumor lines in addition to private antigens. The use of direct antigen presentation by MHC class I-transfected tumors to MHC class I-matched CD8+ T cells is an effective way to generate MHC class I-restricted CTLs toward poorly immunogenic tumors in vitro, permitting the molecular identification of their tumor antigens.     

Efficient presentation of known HLA class II-restricted MAGE-A3 epitopes by dendritic cells electroporated with messenger RNA encoding an invariant chain with genetic exchange of class II-associated invariant chain peptide

For the induction of an optimal immune response against cancer or infections not only CD8(+) CTLs but also CD4(+) T helper cells must be induced, in particular IFN-gamma-secreting type 1 T helper cells. Several strategies have been explored to target tumor-associated antigens to the HLA class II processing compartments. We engineered a genetic construct encoding an invariant chain (Ii) protein where the CLIP region has been replaced by sequences encoding HLA class II-restricted MAGE-A3 epitopes. Monocyte-derived dendritic cells (DCs) were electroporated with in vitro transcribed mRNA encoding a modified Ii protein containing the HLA-DP4-restricted MAGE-A3 epitope. The capacity of these electroporated DCs to stimulate a MAGE-A3-specific T-cell clone was compared at different stages of DC maturation with the T-cell stimulatory capacity of DCs pulsed with the synthetic peptide. After electroporation, the T-cell stimulatory capacity was shown to be high and long lasting, whereas the stimulatory capacity of peptide-pulsed DCs decreased rapidly. Upon coculture with epitope-specific T cells, electroporated immature DCs expressed enhanced levels of costimulatory molecules, HLA class II molecules, and CD83, suggesting the induction of maturation. The electroporated DCs can be frozen and thawed without losing their capability to stimulate the specific T-cell clone in vitro, and they are able to stimulate unprimed CD4(+) T cells specific to the HLA-DP4-restricted MAGE-A3 epitope in vitro. Similar results were obtained with a recombinant Ii containing the MAGE-A3 epitope presented in the context of HLA-DR13.     

HLA expression in basal cell carcinomas.

Decreased expression of MHC class I molecules in tumor cells has been reported to be associated with enhanced malignancy both in human and murine tumors. This paper studies HLA-ABC and HLA-DR expression in 56 basal cell carcinomas. Our results show that these tumors have a heterogeneous expression of MHC class I molecules: 11% exhibit uniform staining of most tumor cells; 25% are only partially positive, and the remaining 64% are MHC class I negative. A positive correlation between the level of HLA-ABC molecule expression and the degree of histological differentiation has been found. The expression pattern of tumor cells with anti-class II monoclonal antibodies shows weak homogeneous staining in 5%, staining in only a few areas of the tumor in 32%, whereas 63% has no significant staining for MHC class II antigens. Most mononuclear cells infiltrating the tumor were T lymphocytes (CD-3 positive). Results also show that 68% of the tumors express class II molecules homogeneously in the infiltrate. The expression of class II antigens in infiltrating lymphocytes correlated with the level of class II expression in the tumor cells probably as a consequence of lymphokine production by activated T cells.     

Superior tumor protection induced by a cellular vaccine carrying a tumor-specific T helper epitope by genetic exchange of the class II-associated invariant chain peptide

Efficient loading of MHC class II molecules with a T helper epitope of choice can be achieved through genetic exchange of the MHC class II-associated invariant chain peptide (CLIP) sequence with a sequence encoding the helper peptide. We have now used this method to engineer a cellular vaccine that continuously expresses a tumor-specific helper epitope in a defined costimulatory context. We provide evidence (a) that this cellular vaccine induces peptide-specific helper T cells in vivo that are functional in protecting mice from challenge with a highly aggressive tumor, (b) that this vaccine can directly prime tumor-specific helper T cells in vivo, and (c) that this cellular vaccine is superior compared with similar cells loaded with synthetic T helper peptide in inducing tumor protection. In conclusion, cellular vaccines for activation of antigen-specific helper T cells can be greatly improved by the introduction of invariant chain constructs containing a T helper epitope by class II-associated invariant chain peptide exchange.     

CD40-stimulated B lymphocytes pulsed with tumor antigens are effective antigen-presenting cells that can generate specific T cells

Although they are considered as antigen-presenting cells, the role of antigen-unspecific B lymphocytes in antigen presentation and T-lymphocyte stimulation remains controversial. In this paper, we tested the capacity of normal human peripheral activated B cells to stimulate T cells using melanoma antigens or melanoma cell lysates. B lymphocytes activated through CD40 ligation and then pulsed with tumor antigens efficiently processed and presented MHC class II-restricted peptides to specific CD4(+) T-cell clones. This suggests that CD40-activated B cells have the functional and molecular competence to present MHC class II epitopes when pulsed with exogenous antigens, thereby making them a relevant source of antigen-presenting cells to generate T cells. To test this hypothesis, CD40-activated B cells were pulsed with a lysate prepared from melanoma cells and used to stimulate peripheral autologous T cells. Interestingly, T cells specific to melanoma antigens were generated. Additional analysis of these T-cell clones revealed that they recognized MHC class II-restricted epitopes from tyrosinase, a known melanoma tumor antigen. The efficient antigen presentation by antigen-unspecific activated B cells was correlated with a down-regulation in the expression of HLA-DO, a B cell-specific protein known to interfere with HLA-DM function. Because HLA-DM is important in MHC class II peptide loading, the observed decrease in HLA-DO may partially explain the enhanced antigen presentation after B-cell activation. Results globally suggest that when they are properly activated, antigen-unspecific B-lymphocytes can present exogenous antigens by MHC class II molecules and stimulate peripheral antigen-specific T cells. Antigen presentation by activated B cells could be exploited for immunotherapy by allowing the in vitro generation of T cells specific against antigens expressed by tumors or viruses.     

Melanosomal targeting sequences from gp100 are essential for MHC class II-restricted endogenous epitope presentation and mobilization to endosomal compartments

CD4+ T lymphocytes play an important role in CD8+ T cell-mediated responses against tumors. Considering that approximately 20% of melanomas express MHC class II, it is plausible that concomitant presentation by MHC class I and class II shapes positive (helper T cells) or negative (regulatory T cells) antitumor responses. Interestingly, gp100, a melanoma antigen, can be presented by both MHC class I and class II when expressed endogenously, suggesting that it can reach endosomal/MHC class II compartments (MIIC). Here, we showed that gp100 putative NH2-terminal signal sequence and the last 70 residues in COOH terminus are essential for MIIC localization and MHC class II presentation. Confocal microscopy analyses confirmed that gp100 was localized in LAMP-1+/HLA-DR+ endosomal/MIIC. Gp100 targeting sequences were characterized by deleting different sections in the COOH terminus (last 70 residues). Transfection in 293T cells, expressing MHC class I and class II molecules, revealed that specific deletions in COOH terminus resulted in decreased MHC class II presentation, without effects on class I presentation, suggesting a role in MIIC trafficking for these deleted sections. Then, we used these gp100 targeting sequences to mobilize green fluorescent protein to endosomal compartments and to allow MHC class II and class I presentation of minimal endogenous epitopes. We conclude that these specific sequences are MIIC-targeting motifs, which could be included in expression cassettes for endogenously expressed tumor or viral antigens for MHC class II and class I presentation and optimize in vivo T-cell responses or as an in vitro tool for characterization of new MHC class II epitopes.     

Tumor-specific CD4+ T cells from a patient with renal cell carcinoma recognize diverse shared antigens

Murine models for immune-mediated tumor regression have defined an essential role for CD4+ T helper (Th) cells, but the contribution of these cells to antitumoral immune responses in humans remains poorly defined. Here, we investigated the Th cell response against the autologous tumor in a patient with metastasized renal cell carcinoma (RCC) exhibiting objective clinical response to immunotherapy. Peripheral blood T cells of the patient were repeatedly stimulated in vitro using either autologous IFNgamma-treated whole tumor cells or Epstein-Barr virus-immortalized B cells (EBV-B) pulsed with tumor cell lysate. CD4+ T-cell clones recognizing autologous tumor cells but not EBV-B cells were efficiently reactivated and expanded with both types of stimulator cells, establishing the latter as potentially useful for isolating CD4+ T cells reactive against MHC class II-negative tumors. Two T-cell clones from both stimulation protocol were further characterized. The restricting MHC class II molecules were defined by using allogeneic EBV-B cells pulsed with tumor lysate, and the expression pattern of the antigens was examined by analyzing lysates from normal kidney cells, allogeneic RCCs as well as tumors of different histologic origin. Furthermore, the subcellular localization of the antigens recognized by the T-cell clones was examined by fractionating the tumor lysate, and the Th phenotype was determined by assessing the cytokines released after T cell activation. These experiments show that a dual Th1/Th2, MHC class II-restricted T-helper-cell response against diverse shared tumor antigens has been elicited in this patient.     

Hyperexpressed hairy leukemic cell Ii might bind to the antigen-presenting site of class II MHC molecules

The p35 protein which is hyperexpressed on hairy leukemic cells was determined to be Ii, the electrophoretically invariant glycoprotein that is associated with class II major histocompatibility complex (Ia) antigens from the time of their synthesis. The principal function of class II MHC antigens is to present to T cell receptors those digested foreign antigenic peptides that probably fold as amphipathic alpha-helices and adsorb to a hydrophobic surface (desetope) on Ia. By a novel strip-of-helix hydrophobicity algorithm we found that the sequence Leu-142 to His-170 in Ii formed a five-cycle, amphipathic, alpha-helix, the highest scoring one among a series of proteins commonly used as experimental antigens. This finding led to the hypothesis that this sequence in Ii bound to the antigen-binding site (desetope) of Ia until release and self-aggregation in the endosome in order that digested foreign peptides could then bind to Ia. Abundant expression of Ii in leukemic cells might be associated with an altered capacity of those cells to present foreign or leukemic antigens to the host's immune system.     

Activation of tumor-specific CD4(+) T lymphocytes by major histocompatibility complex class II tumor cell vaccines: a novel cell-based immunotherapy

Mouse tumor cells transfected with syngeneic MHC class II and costimulatory molecule genes are therapeutic vaccines in mice, provided they do not coexpress the class II-associated invariant chain (Ii). We demonstrated previously that the vaccine cells present tumor peptides via the endogenous antigen presentation pathway to activate CD4(+) and CD8(+) T cells. Because of their efficacy in mice, we are translating this vaccine strategy for clinical use. To obtain MHC class II(+)CD80(+)Ii(-) human tumor cells, we developed retroviruses encoding HLA-DR and CD80. The HLA-DR virus encodes the DRalpha and DRbeta0101 chains using an internal ribosomal entry site to coordinate expression. SUM159PT mammary carcinoma and Mel 202 ocular melanoma cells transduced with the retroviruses DRB1/CD80 express high levels of DRB0101 and CD80 on the cell surface in the absence of Ii. Irradiated SUM159PT/DR1/CD80 vaccines stimulate proliferation of non-HLA-DRB0101 peripheral blood mononuclear cells and present an exogenous DR1-restricted tetanus toxoid (TT) peptide, indicating that the transduced DRB0101 is functional. SUM159PT/DR1/CD80 vaccines were further transduced with a retrovirus encoding the TT fragment C gene, as a model tumor antigen. These cells stimulate IFN-gamma release from TT-primed human DRB0101 peripheral blood mononuclear cells, demonstrating their ability to present "endogenous" tumor antigen. Depletion and antibody blocking experiments confirm that MHC class II-restricted, endogenously synthesized epitopes are presented to CD4(+) T cells. Therefore, the MHC class II vaccines are efficient antigen-presenting cells that activate tumor-specific MHC class II-restricted, CD4(+) T lymphocytes, and they are a novel and potential immunotherapeutic for metastatic cancers.     

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.     

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.     

Major histocompatibility complex class II antigen presentation in Hodgkin's disease

The malignant cells in Hodgkin's disease (HD), commonly referred to as Hodgkin and Reed-Sternberg (HRS) cells, express major histocompatibility complex (MHC) class II molecules and, like "professional" antigen-presenting cells (APCs), different accessory or costimulatory molecules which can provide an additional activation signal to T cells. Despite expressing the key effector molecules of APCs, HRS cells fail to evoke an effective T cell response in vivo. Previous work addressing this paradox has shown that in a large proportion of HRS cells MHC class II molecules present the non-immunogenic MHC class II-associated invariant chain peptide (CLIP). The inability of many HRS cells to present MHC class II-associated antigenic peptides to surrounding helper T lymphocytes could explain how these malignant APCs can thrive in a hostile environment of apparently immunocompetent cells.     

MHC class I and class II presentation of tumor antigen in retrovirally and adenovirally transduced dendritic cells

The unique antigen-presenting capabilities of dendritic cells (DCs) make them an attractive means with which to initiate an antitumor immune response. Using DCs transduced with tumor antigens for immunotherapy has several theoretical advantages over peptide-pulsed DCs including the possibility that transduced DCs are capable of presenting epitopes on both class I and class II MHC molecules. To test this theory, we inserted the human tumor antigen gp100 into mouse DCs transgenic for HLA-DRbeta1*0401 using either adenoviral vector or a VSV-G pseudotyped retroviral vector. DCs transduced with tumor antigen were able to be recognized by both a murine CD8(+) T-cell clone and a murine CD4(+) T-cell line in a cytokine release assay, thereby demonstrating presentation of both MHC class I and class II gp100 epitopes. This study describes the simultaneous presentation of a tumor-associated antigen to both CD4(+) and CD8(+) T cells and lends support to the use of gene-modified DCs as a means to initiate both CD4(+) and CD8(+) antitumor responses.