Dendritic cell-based vaccine: a promising approach for cancer immunotherapy

Enhancement of dendritic cell immunotherapy by recalling antigens for hepatocellular carcinoma in mice

Background: The therapeutic efficacy of dendritic cell (DC)-immunotherapy for large hepatoma in mice is unsatisfactory. Materials & methods: DC-based immunotherapy was used to treat Hepa1-6 tumors measuring 6 ± 1 mm in diameter, enhanced by boosting tumor antigens. Results: CD4⁺ and CD8⁺ T-cells were contracted and transformed into memory phenotypic cells after DC-based vaccination. When T-cells were re-stimulated, T-cells obtained from mice boosted by tumor antigen injection showed highest proliferation capacity. When mice with large tumors were treated, DC-based vaccination boosted by tumor antigen and an additional DC-infusion yielded curative rates of 50% and 23.1%, respectively. Conclusion: DC vaccination induced effector memory cells. Antigen presentation recalled by DC or tumor antigens increased the curative rate in mice with large tumors.

Stem cell factor produced by tumor cells expands myeloid-derived suppressor cells in mice

Immunotherapy is a novel treatment approach for cancers; however, its therapeutic effects are impeded by myeloid-derived suppressor cells (MDSCs). This study aimed to determine how MDSCs are expanded in cancer hosts. MDSCs were positive for Gr-1 and CD11b. Hepa1-6 hepatoma cells, EL4 lymphoma cells, and mice bearing Hepa1-6 hepatoma or lymphoma were examined. Following the inoculation of Hepa1-6 cells into the flanks of mice, a linear correlation was evident between the frequency of MDSCs in the spleen and tumor sizes. MDSC numbers diminished gradually and returned to the normal level within 3 weeks if the tumors were excised. To identify the cytokines produced by tumor cells that allowed expansion of MDSCs, cytokines in Hepa1-6 cell culture medium and murine serum were examined using a cytokine array. Stem cell factor (SCF) was implicated as the relevant cytokine. When recombinant SCF was added to the spleen cell culture medium, MDSC expansion could occur. In the presence of c-kit blockade, this effect of SCF was partially reversed. In conclusion, MDSCs can be expanded in tumor cells in a process that involves SCF released by tumor cells.

Increased Neutralizing Antibody Production and Interferon-γ Secretion in Response to Porcine Reproductive and Respiratory Syndrome Virus Immunization in Genetically Modified Pigs

T cell-mediated immunity plays a prominent role in combating pathogens infection. Both the engagement of the T cell receptor with the peptide-bound major histocompatibility complex and a costimulatory signal are needed for the complete activation of the T cell. To determine whether host immune responses to vaccination could be improved by enhancing CD28-mediated costimulation and verify whether the boosted immune responses could protect the host against viral challenge, we produced a transgenic pig line expressing an extra copy of the CD28 gene controlled by its own promoter at the Rosa26 locus. As expected, in response to porcine reproductive and respiratory syndrome virus (PRRSV) strain vaccination, CD4⁺ T cells was remarkably increased in CD28 transgenic pigs and a similar response in CD8⁺ T cells was elicited after challenge. Importantly, because of increased T cell frequencies, the virus-neutralizing antibody against JXA-1 (a highly pathogenic Chinese PRRSV strain), as well as interferon-γ secretion, were enhanced in transgenic pigs. These findings in our translational study provide a novel concept for farm animal breeding in disease resistance, in which we may use the transgenic technology to force overexpression of confirmed immunity-promoting molecules like CD28 and produce an animal with enhanced immune responses to vaccination and broad-spectrum resistance to infectious diseases.

Novel prostate acid phosphatase-based peptide vaccination strategy induces antigen-specific T-cell responses and limits tumour growth in mice

Treatment options for patients with advanced prostate cancer remain limited and rarely curative. Prostatic acid phosphatase (PAP) is a prostate-specific protein overexpressed in 95% of prostate tumours. An FDA-approved vaccine for the treatment of advanced prostate disease, PROVENGE® (sipuleucel-T), has been shown to prolong survival, however the precise sequence of the PAP protein responsible for the outcome is unknown. As the PAP antigen is one of the very few prostate-specific antigens for which there is a rodent equivalent with high homology, preclinical studies using PAP have the potential to be directly relevant to clinical setting. Here, we show three PAP epitopes naturally processed and presented in the context of HHDII/DR1 (114-128, 299-313, and 230-244). The PAP-114-128 epitope elicits CD4(+) and CD8(+) T-cell-specific responses in C57BL/6 mice. Furthermore, when immunised in a DNA vector format (ImmunoBody®), PAP-114-128 prevents and reduces the growth of transgenic adenocarcinoma of mouse prostate-C1 prostate cancer cell-derived tumours in both prophylactic and therapeutic settings. This anti-tumour effect is associated with infiltration of CD8(+) tumour-infiltrating lymphocytes and the generation of high avidity T cells secreting elevated levels of IFN-γ. PAP-114-128 therefore appears to be a highly relevant peptide on which to base vaccines for the treatment of prostate cancer.

Novel strategies for immunotherapy in multiple myeloma: previous experience and future directions

Multiple myeloma (MM) is a life-threatening haematological malignancy for which standard therapy is inadequate. Autologous stem cell transplantation is a relatively effective treatment, but residual malignant sites may cause relapse. Allogeneic transplantation may result in durable responses due to antitumour immunity mediated by donor lymphocytes. However, morbidity and mortality related to graft-versus-host disease remain a challenge. Recent advances in understanding the interaction between the immune system of the patient and the malignant cells are influencing the design of clinically more efficient study protocols for MM. Cellular immunotherapy using specific antigen-presenting cells (APCs), to overcome aspects of immune incompetence in MM patients, has received great attention, and numerous clinical trials have evaluated the potential for dendritic cell (DC) vaccines as a novel immunotherapeutic approach. This paper will summarize the data investigating aspects of immunity concerning MM, immunotherapy for patients with MM, and strategies, on the way, to target the plasma cell more selectively. We also include the MM antigens and their specific antibodies that are of potential use for MM humoral immunotherapy, because they have demonstrated the most promising preclinical results.

DNA vaccine with α-galactosylceramide at prime phase enhances anti-tumor immunity after boosting with antigen-expressing dendritic cells

DNA vaccines contribute to a promising new approach for the generation of cytotoxic T lymphocytes (CTL). DNA vaccines do have several disadvantages, including poor immunogenicity and oncogene expression. We used the natural killer T-cell (NKT) ligand α-galactosylceramide (α-GalCer) as an adjuvant to prime initial DNA vaccination; and used the potent immune-stimulatory tumor antigen-expressing dendritic cells (DCs) as a booster vaccination. A DNA vaccine expressing human papillomavirus (HPV) type 16 E7 (pcDNA3-CRT/E7) was combined with α-GalCer at the prime phase, and generated a higher number of E7-specific CD8(+) T-cells in vaccinated mice than vaccine used at boost phase. Therefore, priming with a DNA vaccine in the presence of α-GalCer and boosting with E7-pulsed DC-1 led to a significant enhancement of E7-specific CD8(+) effector and memory T-cells as well as significantly improved therapeutic and preventive effects against an E7-expressing tumor model (TC-1) in vaccinated mice. Our findings suggested that the potency of a DNA vaccine combined with α-GalCer could be further enhanced by boosting with an antigen-expressing DC-based vaccine to generate anti-tumor immunity.

Phase I study of autologous dendritic cell tumor vaccine in patients with non-small cell lung cancer

BACKGROUND

A dendritic cell vaccine has been developed as a novel strategy for generating antitumor immunity in the treatment of cancer. The purpose of this study was to assess the maximal tolerated dose, safety, and immunologic response of a new dendritic cell vaccine (DC-Vac) into which tumor lysate was loaded by electroporation and pulse in patients with advanced non-small cell lung cancer (NSCLC).

PATIENTS AND METHODS

Fifteen patients with inoperable stage III or IV NSCLC were assigned to cohorts that received 3, 6, or 12 × 10(6) DC-Vac intradermally 3 times at 2 week intervals. We also evaluated immunologic and tumor responses.

RESULTS

The maximum dose of DC-Vac (12 × 10(6)) was shown to be safe. In 5 of 9 patients, the vaccine resulted in increased interferon (IFN)-γ production by CD8+ cells after exposure to tumor lysate. Additionally, there were mixed responses which do fulfill progressive disease definition but demonstrate some clinical benefit in two patients.

CONCLUSION

The administration of tumor lysate-loaded autologous dendritic cells by electroporation and pulse was non-toxic and induced immunologic responses to tumor antigens. The two mixed tumor responses which were achieved may represent a potential benefit of this new DC-Vac.

Increased plasma-immune cytokines throughout the high-dose melphalan-induced lymphodepletion in patients with multiple myeloma: a window for adoptive immunotherapy

High-dose melphalan (HDM) followed by autologous stem cell transplantation (ASCT) is a standard treatment for patients with multiple myeloma. However, lymphocyte reconstitution is impaired after HDM. Recent work has suggested that the lymphopenia period occurring after various immunosuppressive or chemotherapy treatments may provide an interesting opportunity for adoptive antitumor immunotherapy. The objective of this study was to determine an immunotherapy window after HDM and ASCT, evaluating T cell lymphopenia, and measuring circulating immune cytokine concentrations in patients with multiple myeloma. The counts of T cell subpopulations reached a nadir at day 8 post-ASCT (day 10 post-HDM) and recovered by day 30. IL-6, IL-7, and IL-15 plasma levels increased on a median day 8 post-ASCT, respectively, 35-fold, 8-fold, and 10-fold compared with pre-HDM levels (p < or = 0.05). The increases in IL-7 and IL-15 levels were inversely correlated to the absolute lymphocyte count, unlike monocyte or myeloid counts. Furthermore, we have shown that CD3 T cells present in the ASC graft are activated, die rapidly when they are cultured without cytokine in vitro, and that addition of IL-7 or IL-15 could induce their survival and proliferation. In conclusion, the early lymphodepletion period, occurring 4-11 d post-HDM and ASCT, is associated with an increase of circulating immune cytokines and could be an optimal window to enhance the survival and proliferation of polyclonal T cells present in the ASC autograft and also of specific antimyeloma T cells previously expanded in vitro.

[Therapeutic applications and promises of cellular and tissue engineering. What strategic choice for the Etablissement Français du Sang?]

A new medical field, known as regeneration medicine, is developing and attracting more and more researchers and practitioners. Whereas hematopoietic cell-based therapies have already proven their efficacy in numerous--malignant or not--diseases, non-hematopoietic cell-based therapies have not. They can be useful to dozens, if not hundreds, of patients with various disorders, such as cardiopathy, diabetes, some types of cancer, osteoarticular and neurodegenerative disorders. In these fields, numerous clinical applications are possible for mesenchymal stem cells. Cell and tissue (corneas, bone, skin) therapy products require the definition of pharmaceutical standards with new European requirements in terms of quality and safety. The legitimacy of the Etablissement Français du Sang (EFS) in cell and tissue engineering activities is established, it is recognized by most specialists and by regulatory authorities and has been asserted by the orientations of its "contrat d'objectifs et de moyens". An independent committee has been set up by the EFS President to define an EFS-specific strategy. This committee made up of qualified specialists was required to draw up a rational organization plan for these activities, in order for EFS to be in a position to produce cells and tissues according to pharmaceutical standards. The committee proposals are based on economic data and an inventory of existing cell and tissue engineering activities. Public/private partnerships are required and efforts must focus towards the industrial valorization of EFS expertise in R&D activities and staff know-how. Implementing such a new organization requires national management and the cooperation of institutional actors (university hospitals, cancer treatment centers, universities). For the success of this approach, EFS personnel must be convinced of its legitimacy and new skills must be encouraged. With its numerous assets, EFS can be ambitious and assert itself as a major actor in cell and tissue engineering in Europe.

Vaccination of advanced hepatocellular carcinoma patients with tumor lysate-pulsed dendritic cells: a clinical trial

Hepatocellular carcinoma (HCC) is a common and rapidly progressing malignancy. Current treatment options for advanced HCC are limited. This clinical study of dendritic cell (DC)-based immunotherapy for HCC enrolled 31 patients with advanced HCC. DCs, propagated from peripheral blood monocytes, were pulsed with autologous tumor lysates to treat HCC. The first 14 patients underwent pulsed therapy with five courses of DC vaccination intravenously at weekly intervals. The other 17 patients underwent monthly boost vaccinations after the initial pulsed therapy. Among the 31 patients, 4 (12.9%) exhibited partial response to DC vaccination. Seventeen patients (54.8%) had stable disease. Ten patients (32.3%) had progressive disease. The overall 1-year survival rate of all 31 patients was 40.1 +/- 9.1%. The patients treated with pulsed and boosted therapy had better 1-year survival rates than those treated by pulsed therapy alone (63.3 +/- 12.0% vs. 10.7 +/- 9.4%; P < 0.001). In this trial, DC vaccinations for advanced HCC were safe. Liver function tests showed no difference before and after DC vaccinations. The results of this clinical trial indicate that DC vaccination is a safe treatment for HCC. Pulsed DC vaccination followed by boosters can provide better clinical survival for advanced HCC patients than pulsed DC vaccination only. Further studies are needed to increase the efficacy of this therapeutic approach.

Protein Kinase C Blockade Inhibits Differentiation of Myeloid Blasts into Dendritic Cells by Calcium Ionophore A23187

Direct differentiation of myeloid leukemia blasts into antigen-presenting dendritic cells (DCs) for use as cellular vaccines is unique in that identification of tumor-specific antigens may not be necessary because the antigens should already be endogenously expressed. We hypothesized that signaling through protein kinase C (PKC) is required for differentiation of HL-60 promyeloblasts into DCs upon stimulation with calcium ionophore A23187. To demonstrate the inhibitory effect of PKC blockade, we pretreated HL-60 myeloid blasts with the protein kinase inhibitor bisindolylmaleimide I (Bis-1) for 24 hours and then treated the cells with calcium ionophore A23187 for an additional 24 hours. Controls consisted of HL-60 blasts treated with A23187, Bis-1 alone, or media. We noted that blasts cultured in media, Bis-1, or Bis-1 then A23187 did not develop the morphologic and phenotypic DC characteristics, up-regulate Rel B, or activate allogeneic T-cells. Our findings suggested that PKC blockade inhibits morphologic, phenotypic, and functional differentiation of HL-60 promyeloblasts into antigen-presenting DCs. Our findings supported the role of PKC as an obligatory pathway for calcium ionophore A23187-induced differentiation of HL-60 myeloblasts into antigen-presenting DCs.

Closed system generation of dendritic cells from a single blood volume for clinical application in immunotherapy

Dendritic cells (DC) used for clinical trials should be processed on a large scale conforming to current good manufacturing practice (cGMP) guidelines. The aim of this study was to develop a protocol for clinical grade generation of immature DC in a closed-system. Aphereses were performed with the Cobe Spectra continuous flow cell separator and material was derived from one volume of blood processed. Optimisation of a 3-phase collection autoPBSC technique significantly improved the quality of the initial mononuclear cell (MNC) product. Monocytes were then enriched from MNC by immunomagnetic depletion of CD19+ B cells and CD2+ T cells and partial depletion of NK cells using the Isolex 300I Magnetic cell selector. The quality of the initial mononuclear cell product was found to determine the outcome of monocyte enrichment. Enriched monocytes were cultured in Opticyte gas-permeable containers using CellGro serum-free medium supplemented with GM-CSF and IL-4 to generate immature DC. A seeding concentration of 1 x 10(6) was found optimal in terms of DC phenotype expression, monocyte percentage in culture, and cell viability. The differentiation pattern favours day 7 for harvest of immature DC. DC recovery, viability, as well as phenotype expression after cryopreservation of immature DC was considered in this study. DC were induced to maturation and evaluated in FACS analysis for phenotype expression and proliferation assays. Mature DC were able to generate an allogeneic T-cell response as well as an anti-CMV response as detected by proliferation assays. These data indicate that the described large-scale GMP-compatible system results in the generation of stable DC derived from one volume of blood processed, which are qualitatively and quantitatively sufficient for clinical application in immunotherapeutic protocols.

An Insight into the Dendritic Cells at the Maternal-Fetal Interface

The conditions that permit the genetically distinct fetus to survive and develop within the mother are among the most fascinating immunologic puzzles. The presence of dendritic cells in the maternal decidua pointed to a biologic role of antigen-presenting cells in maternal-fetal interaction. The method of study included recent findings on the lineage, maturity, phenotype and function of dendritic cells at the maternal-fetal interface. The increment of uterine dendritic cells occurs simultaneously with the decisive phase of gestation, when implantation takes place. Decidual dendritic cells of the first trimester pregnancy, with a phenotype characteristic of the mature myeloid lineage, express MHC class II, co-stimulatory and adhesion molecules, control Th1/Th2 balance and activate the proliferative response of autologous NK cells. Dendritic cells are specifically equipped to control immunity, to trigger immune response and also to maintain tolerance, avoiding the rejection of the conceptus by the maternal immune system.

Direct injection of immature dendritic cells into irradiated tumor induces efficient antitumor immunity

Although there are several ways to load tumor antigens to DCs, in vitro preparation of tumor antigens and manipulation of DCs are usually required. Therefore, to develop a simple antitumor immunization method, we examined if direct injection of DCs into tumor apoptosed by ionizing IR could induce efficient antitumor immunity. Ionizing IR with 15 Gy induced apoptosis in tumor maximally after 6 hr. Injection of DCs i.t. into IR tumor induced strong cytotoxicity of splenocytes against tumor cells compared to i.t. injection of DCs or ionizing IR of tumor, both of which induced weak cytotoxicity. In an animal study, i.t. injection of DCs into IR tumor induced therapeutic antitumor immunity against a tumor established at a distant site. Moreover, when TNF-alpha or LPS was added as a danger/maturation signal to DC suspension before i.t. injection, antitumor immunity was significantly potentiated compared to a group treated with i.t. injection of DCs into IR tumor. Our results suggest that injection of DCs into tumor apoptosed by ionizing IR might be a simple and efficient method of immunization against tumor.

Generation of Ag-specific cytotoxic T lymphocytes by DC transfected with in vitro transcribed influenza virus matrix protein (M1) mRNA

BACKGROUND

Application of DC transfected with tumor Ag RNA is promising for DC-based tumor immunotherapy. In this study, Ag-specific cytotoxic T lymphocytes (CTL) were generated by priming lymphocytes with DC transfected with in vitro transcribed (IVT) influenza virus matrix protein M1 (M1) mRNA.

METHODS

Human UC blood-CD34+ cell-derived DC were transfected with IVT mRNA encoding either the enhanced green fluorescence protein (EGFP), or M1 by square-wave electroporation. DC were confirmed to have typical morphology and phenotype. DC transfected with IVT EGFP mRNA were analyzed with the FACScan flow cytometer, to confirm the efficiency of this transfection method. On Days 7, 14, 21 and 28 after the start of DC culture, DC were harvested and electroporated with M1 mRNA. The transfected DC were co-cultured with autologous UC blood CD34- cells. One week after the fourth priming of autologous CD34 negative cells with M1 mRNA electroporated DC, Ag-specific CTL activity was evaluated. To prepare target cells, M1 mRNA was added to autologous DC 48 h prior to CTL assays.

RESULTS

Our CTL assays results indicate that UC blood CD34+ cell-derived DC transfected with M1 mRNA by electroporation stimulated Ag-specific CTL responses that are capable of recognizing and lysing autologous DC loaded with M1 mRNA. M1 mRNA transfected DC-primed CTL showed a significant cytotoxic activity against M1 mRNA loaded autologous DC, while nearly baseline cytotoxic activity was recorded for the M1 mRNA unloaded DC.

DISCUSSION

Our results showed that mRNA-transfected DC are potent stimulators of T-cell immunity in vitro. In addition, mRNA-loaded DC can function as targets in CTL cytotoxicity assays, which offer a practical substitute for tumor cells in assays to test the immunological effects of specific Ags.

Novel therapeutic agents under investigation for malignant melanoma

Malignant melanoma presents a therapeutic challenge. Patients at high risk for recurrence (stage III) are eligible for adjuvant treatment with IFN-alpha or may enrol in a clinical trial. Both options offer no meaningful survival advantage. Patients with metastatic disease (stage IV) have a 5-year survival of < 10% and have no effective treatment options. Despite aggressive investigations into vaccine therapy, no vaccine has yet received FDA approval. Biological therapies with IFN-alpha and IL-2 have demonstrated a real but minimal effect. Chemotherapeutic options are even more dismal. Single-agent chemotherapy yields a 15-20% response rate of short lived duration. Combination chemotherapy alone or with immunological adjuvants yields response rates of 35-45% but with significant toxicity and no significant improvement in survival. Novel treatment agents that target metabolic pathways, angiogenesis inhibitors, antisense therapies, gene therapies and innovative vaccines may offer hope for an otherwise grave disease.

A trial of IRX-2 in patients with squamous cell carcinomas of the head and neck

A Phase II trial in 42 patients with squamous cell cancer of the head and neck (H and NSCC) was performed using a combination immunotherapy with 10-20 days of perilymphatic injections of a natural cytokine mixture (NCM: IRX-2; 200 units IL-2 equivalence) preceded by low dose cyclophosphamide (CY; 300 mg/m(2)) and followed by daily oral indomethacin (25 mg t.i.d.) and zinc (65 mg in a multivitamin preparation). Thirty-nine patients underwent subsequent surgical resection and 22 stage IV patients received additional radiotherapy. Forty-two percent were adjudged to have complete and partial clinical responses (>50% tumor reduction); an additional five patients had minor responses for a total of 58%. Comparison of post-treatment biopsies or surgical specimens showed 90% of patients had reduction in tumor area from 79% to 48% (over half of which was fragmented) and increased area of leukocyte infiltration from 9% to 32% (79% of which was lymphoid). The treatment with IRX-2 was not associated with significant side effects and 24 of patients showed improvement in eating, breathing or phonation or reduced pain and bleeding. Fifteen patients with lymphocytopenia (lymphocyte counts [LC] less than or equal to 1500 mm(3)) showed significant increases in LC, CD3+, CD4+ and CD8+ T lymphocytes of 401, 147, 95 and 100/mm(3), respectively. Analysis of outcome of 32 on protocol patients after 36 months versus 32 concurrent institutional H and NSCC controls showed delayed recurrences and significant increases in mean survival time (MST) and survival (p's<0.02). The data document immunotherapy induced regression of H and NSCC with delayed recurrence and improved mean survival time.

Immunotherapy of cancer by active vaccination: does allogeneic bone marrow transplantation after non-myeloablative conditioning provide a new option?

The critical role of antigen-specific T cells in cancer immunotherapy has been amply demonstrated in many model systems. Though success of clinical trials still remains far behind expectation, the continuous improvement in our understanding of the biology of the immune response will provide the basis of optimized cancer vaccines and allow for new modalities of cancer treatment. This review focuses on the current status of active therapeutic vaccination and future prospects. The latter will mainly be concerned with allogeneic bone marrow cell transplantation after non-myeloablative conditioning, because it is my belief that this approach could provide a major breakthrough in cancer immunotherapy. Concerning active vaccination protocols the following aspects will be addressed: i) the targets of immunotherapeutic approaches; ii) the response elements needed for raising a therapeutically successful immune reaction; iii) ways to achieve an optimal confrontation of the immune system with the tumor and iv) supportive regimen of immunomodulation. Hazards which one is most frequently confronted with in trials to attack tumors with the inherent weapon of immune defense will only be briefly mentioned. Many question remain to be answered in the field of allogeneic bone marrow transplantation after non-myeloablative conditioning to optimize the therapeutic setting for this likely very powerful tool of cancer therapy. Current considerations to improve engraftment and to reduce graft versus host disease while strengthening graft versus tumor reactivity will be briefly reviewed. Finally, I will discuss whether tumor-reactive T cells can be "naturally" maintained during the process of T cell maturation in the allogeneic host. Provided this hypothesis can be substantiated, a T cell vaccine will meet a pool of virgin T cells in the allogeneically reconstituted host, which are tolerant towards the host, but not anergised towards tumor antigens presented by MHC molecules of the host.

Lack of dendritic cell mobilization into the peripheral blood of cancer patients following standard- or high-dose chemotherapy plus granulocyte-colony stimulating factor

BACKGROUND

Dendritic cells (DC), the most specialized antigen-presenting cells, can be detected in the peripheral blood (PB) and divided into two subsets of populations, DC1 and DC2, endowed with different functions. The aim of this study was to evaluate the effect on DC release and on their subsets of three regimens utilized to mobilize CD34+ cells into the PB in cancer patients and in normal CD34+ cell donors.

PATIENTS AND METHODS

The mobilizing sequences were: standard-dose epirubicin+taxol+granulocyte-colony-stimulating factor (G-CSF; 15 patients with advanced breast cancer), high-dose cyclophosphamide (CTX)+G-CSF (10 patients with breast cancer patients and 7 with non-Hodgkin's lymphoma, NHL), and G-CSF alone (5 normal donors of CD34+ cells for allogeneic transplantation). Comparative data were obtained from the steady-state PB of 20 healthy volunteers. For flow cytometric analysis, DC were gated as negative for specific lineage markers (CD3, CD11b, CD14, CD16, CD56, CD19, CD20, CD34) and positive for HLA-DR. The DC1 and DC2 subsets were defined as CD11c and CDw123 positive, respectively.

RESULTS

The percentages of DC at baseline and the time of CD34+ cell peak were: 0.48 and 0.51 for standard-dose chemotherapy (CT); 0.55 and 0.63 for breast cancer after high-dose CTX+G-CSF; 0.53 and 0.71 for NHL after high-dose CTX+G-CSF; and 0.51 and 0.54 for normal donors of CD34+ cells after G-CSF alone (all p=n.s.). Mean DC1/DC2 ratios in each study group at the time of CD34+ cell peak were 0.10, 0.12, and 0.18, respectively. Finally, in the group of healthy volunteers, the percentage of circulating DC was 0.95 and the mean DC1/DC2 ratio was 1.28.

CONCLUSION

To our knowledge, this is the first report that demonstrates that both standard-dose or high-dose CT, when utilized together with G-CSF, do not induce DC mobilization into the PB, whereas a reversed DC1/DC2 ratio is observed. Furthermore, a lack of significant DC mobilization after G-CSF alone was also seen, in contrast to what was previously observed by others. These data should be taken in account when evaluating clinical correlations between DC number and CPC engraftment in both the transplantation setting, when monitoring the effects on the immune system of combinations of new drugs and/or cytokines, and when high numbers of DC are required for both experimental and clinical applications.

Current status of dendritic cell immunotherapy of malignancies

Because dendritic cells (DC) are central to the induction of antigen-specific T cell responses, their use for the active immunotherapy of malignancies has been of considerable interest. Since clinical trials with DC-based vaccines have been initiated, a number of important developmental issues have become apparent. These include the ideal source and type of DC, the form of antigen and method of loading DC, whether to induce maturation, the route and timing of immunization, and the optimal clinical scenario. Clinical responses such as stability of disease and tumor regressions have been reported in some patients, particularly with melanoma, myeloma, and prostate cancer.

The role of PGE(2) in the differentiation of dendritic cells: how do dendritic cells influence T-cell polarization and chemokine receptor expression?

The role of prostaglandin E(2) (PGE(2)) in the function of dendritic cells (DCs), T-cell polarization, and expression of chemokine receptors was evaluated in human cells. Immature DCs were generated from peripheral blood CD14(+) cells using a combination of GM-CSF and interleukin-4 (IL-4) with or without PGE(2). On day 6, maturation of DCs was induced by the addition of tumor necrosis factor alpha with or without PGE(2). DCs harvested on day 6 (immature DCs) or day 9 (mature DCs) were examined using functional assays. In the presence of PGE(2), immature and mature DCs showed, phenotypically, a lower expression of CD1a and, functionally, a higher allostimulatory capacity at a high DC/T-cell ratio than control cells cultured in the absence of PGE(2). DCs cultured in the presence of PGE(2) induced the differentiation of naïve T cells toward a helper T-cell type 1 (Th1) response, which was independent of IL-12 secretion in the basal state despite a slightly lower interferon gamma secretion compared with control cells. However, the function of cytotoxicity-stimulating autologous T cells was not augmented by the addition of PGE(2). Immature DCs expressed the inflammatory chemokine receptors, CCR1 and CXCR4, but not CCR6, regardless of the presence or absence of PGE(2). Mature DCs expressed CCR7 equally, measured using a migration test and the measurement of calcium flux with macrophage inflammatory protein-3beta and reverse transcription-polymerase chain reaction assay in all of the groups. All of these findings suggest that PGE(2) affects the DC-promoted differentiation of naïve T cells to a Th1 response in the basal state, without affecting chemokine receptor expression on DCs.

Rapamycin specifically interferes with GM-CSF signaling in human dendritic cells, leading to apoptosis via increased p27KIP1 expression

The longevity of dendritic cells (DCs) is a critical regulatory factor influencing the outcome of immune responses. Recently, we demonstrated that the immunosuppressive drug rapamycin (Rapa) specifically induces apoptosis in DCs but not in other myeloid cell types. The present study unraveled the mechanism used by Rapa to induce apoptosis in human monocyte-derived DCs. Our data demonstrate that granulocyte-macrophage colony-stimulating factor (GM-CSF) preserves DC survival specifically via the phosphatidylinositol-3 lipid kinase/mammalian target of rapamycin (PI3K/mTOR) signaling pathway, which is abrogated by Rapa at the level of mTOR. Disruption of this GM-CSF signaling pathway induced loss of mitochondrial membrane potential, phosphatidyl-serine exposure, and nuclear changes. Apoptosis of these nonproliferating DCs was preceded by an up-regulation of the cell cycle inhibitor p27(KIP1). Overexpression of p27(KIP1) in DCs using adenoviral gene transduction revealed that apoptosis is directly regulated by p27(KIP1). Furthermore, both overexpression of p27(KIP1) and disruption of the GM-CSF/PI3K/mTOR signaling pathway decreased the expression of the antiapoptotic protein mcl-1. This mTOR/p27(KIP1)/mcl-1 survival seems unique for DCs and may provide novel opportunities to influence immune responses by specific interference with the life span of these cells.

Dendritic cells present an intracellular viral antigen derived from apoptotic cells and induce a T-cell response

We investigated if dendritic cells (DCs) were able to present intracellularly located antigens derived from apoptotic cells to T cells, thereby inducing a CD4+ and a CD8+ response. A transfected cell line with the cytomegalovirus-derived protein pp65 was triggered to go into apoptosis by ultraviolet B (UVB) irradiation, and after the uptake of apoptotic cells by DC, the activation and proliferation of T cells were determined. We found that DC efficiently phagocytosed apoptotic cells and induced a CD4+ and a CD8+ T-cell response specific for the viral protein pp65. This mechanism can be useful for vaccination studies to induce an antiviral immune response.

Uptake of poly(D,L-lactic-co-glycolic acid) microspheres by antigen-presenting cells in vivo

Dendritic cells are the most potent antigen-presenting cells (APC) and the most effective stimulators of primary T cell responses. Based on the strong influence of the APC on the immune response, we investigated cellular uptake of a biodegradable antigen delivery system, poly(D,L-lactic-co-glycolic acid) (PLGA) microspheres, at two sites of injection: intraperitoneal and intradermal. We hypothesized that a fluorescent probe, tetramethylrhodamine labeled dextran, loaded in PLGA microspheres would be taken up by APCs and thereby provide a means for studying cellular uptake of PLGA microspheres in vivo. Phagocytic load and cell phenotype were determined using flow cytometry and confocal laser scanning microscopy. The results revealed cellular uptake of tetramethylrhodamine dextran loaded PLGA microspheres at both injection sites. After intraperitoneal immunization, the predominant cell phagocytosing PLGA microspheres in the peritoneal cavity was the macrophage whereas the intradermal immunization resulted in uptake of PLGA microspheres by dendritic cells. Hence, these results suggest that the profile for cellular uptake varies with the site of injection. More importantly, this study provides direct and conclusive evidence of uptake of PLGA microspheres by the most potent APC, the dendritic cell.

Specific immunotherapy of cancer in elderly patients

The concept of immunotherapy of cancer is more than a century old, but only recently have molecularly defined therapeutic approaches been developed. In this review, we focus on the most promising approach, active therapeutic vaccination. The identification of tumour antigens can now be accelerated by methods allowing the amplification of gene products selectively or preferentially transcribed in the tumour. However, determining the potential immunogenicity of such gene products remains a demanding task, since major histocompatibility complex (MHC) restriction of T cells implies that for any newly defined antigen, immunogenicity will have to be defined for any individual MHC haplotype. Tumour-derived peptides eluted from MHC molecules of tumour tissue are also a promising source of antigen. Tumour antigens are mostly of weak immunogenicity, because the vast majority are tumour-associated differentiation antigens already 'seen' by the patient's immune system. Effective therapeutic vaccination will thus require adjuvant support, possibly by new approaches to immunomodulation such as bispecific antibodies or antibody-cytokine fusion proteins. Tumour-specific antigens, which could be a more potent target for immunotherapy, mostly arise by point mutations and have the disadvantage of being not only tumour-specific, but also individual-specific. Therapeutic vaccination will probably focus on defined antigens offered as protein, peptide or nucleic acid. Irrespective of the form in which the antigen is applied, emphasis will be given to the activation of dendritic cells as professional antigen presenters. Dendritic cells may be loaded in vitro with antigen, or, alternatively, initiation of an immune response may be approached in vivo by vaccination with RNA or DNA, given as such or packed into attenuated bacteria. The importance of activation of T helper cells has only recently been taken into account in cancer vaccination. Activation of cytotoxic T cells is facilitated by the provision of T helper cell-derived cytokines. T helper cell-dependent recruitment of elements of non-adaptive defence, such as leucocytes, natural killer cells and monocytes, is of particular importance when the tumour has lost MHC class I expression. Barriers to successful therapeutic vaccination include: (i) the escape mechanisms developed by tumour cells in response to immune attack; (ii) tolerance or anergy of the evoked immune response; (iii) the theoretical possibility of provoking an autoimmune reaction by vaccination against tumour-associated antigens; and (iv) the advanced age of many patients, implying reduced responsiveness of the senescent immune system.

Inhibiting effects on the induction of cytotoxic T lymphocytes by dendritic cells pulsed with lysates from acute myeloid leukemia blasts

Dendritic cells (DCs) were established from 25 patients in complete remission of acute myeloid leukemia (AML). In patients during hematopoietic regeneration following chemotherapy the yield of DC was comparable to that of healthy donors. In patients, more than 2 months after chemotherapy, significantly less DC were generated. Comparison of the antigen-presenting capacity using tetanus toxoid of six AML patients and six healthy volunteers did not show significant differences. In six AML patients, lymphocytes stimulated with blast cell lysate pulsed DC were analyzed for cytotoxic activity against autologous blast cells. 8.4-35.6% of autologous blast cells were lysed by DC stimulated lymphocytes. In three of the six patients maximum lysis of target cells was achieved by unpulsed DC. Thus, it seems that in some patients blast cell lysates mediate inhibitory effects, which may explain to some extend immune escape mechanisms in AML.

Optimal cytokine stimulation for the enhanced generation of leukemic dendritic cells in short-term culture

Dendritic cells (DCs) are professional antigen presenting cells derived from myeloid or lymphoid precursors. Functional DCs have been generated from the malignant counterpart of these precursor cells. Herein, we describe the generation of DCs from different leukemias and determine the optimal culture conditions with minimal manipulation. Primary leukemic cells were cultured for 1, 3, and 5 days in 11 different cytokine combinations and analyzed for the expression of a mature DC phenotype. Optimal growth and DC characteristics were obtained with GM-CSF, FL, and SCF in 3-5 day cultures, suggesting a practical strategy for the immunotherapy of leukemia.

Generation in vitro of B-cell chronic lymphocytic leukaemia-proliferative and specific HLA class-II-restricted cytotoxic T-cell responses using autologous dendritic cells pulsed with tumour cell lysate

Immunotherapy using dendritic cells has shown encouraging results in both haematological and non-haematological malignancies. In this study, monocyte-derived dendritic cells from patients with B-CLL were cultured for 6 days in the presence of IL-4 and GM-CSF. Autologous B-CLL T-cells were cultured alone or with B-CLL lysate-pulsed and unpulsed autologous dendritic cells. IFN-gamma secretion was assessed using ELISA. Cytotoxicity was assessed, after 21 days in culture and re-stimulation, using flow cytometry with and without blockade by anti-HLA class I, anti-HLA class II, anti-CD4, anti-CD8 and anti-TCRalphabeta monoclonal antibodies. B-CLL T cells stimulated with B-CLL lysate-pulsed autologous dendritic cells showed a significant (P = 0.0004) increase in IFN-gamma secretion and a significant (P = 0.0008) increase in specific cytotoxicity to autologous B-cell targets, but none to autologous T cell or B cell targets from healthy individuals. B-CLL T cells cultured with (non-B-CLL) B-cell lysate-pulsed B-CLL dendritic cells showed no significant response. Pulsing dendritic cells from healthy volunteers with an autologous (non-B-CLL) B-cell lysate did not stimulate proliferation, cytokine production or cytotoxicity by autologous T cells. Pulsing B-CLL dendritic cells with allogeneic B-CLL lysates and culturing with autologous T-cells elicited cytotoxicity against autologous B-CLL targets in some cases, but not in others. Cytotoxicity was significantly reduced by blocking with anti-HLA class II (P = 0.001), anti-TCRalphabeta (P = 0.03) and anti-CD4 (P = 0.046) antibodies. Phenotyping of the responding T-cell population demonstrated the majority to be CD4 positive. Our data demonstrate that HLA class II-restricted proliferative and cytotoxic T-cell responses to B-CLL can be generated using autologous dendritic cells pulsed with tumour cell lysate.

CD20 antibody (C2B8)-induced apoptosis of lymphoma cells promotes phagocytosis by dendritic cells and cross-priming of CD8+ cytotoxic T cells

C2B8 (Rituximab, MabThera) is a chimeric mouse/human monoclonal antibody (mAb) directed against the human B cell-restricted cell surface antigen CD20 which is used as an alternative medication in the treatment of B cell non-Hodgkin lymphomas (NHL). Treatment of CD20+ B cells with C2B8 triggers different cell damaging effects including complement-dependent lysis of tumor cells, antibody-dependent cellular cytotoxicity and induction of apoptosis. Dendritic cells (DC) have recently been shown to ingest cell debris and to present associated antigens even on MHC class I molecules, a mechanism called cross-presentation. In this study, we investigated whether C2B8 treatment of lymphoma promotes the induction of CD8+ T cell responses against lymphoma cell-associated antigens via, cross-presentation. We used Daudi lymphoma cells as a model system in our studies and could demonstrate, that C2B8-treated Daudi cells undergo apoptosis, are phagocytosed by DC and induce in DC typical features of maturation; among them, the induction of CD83 expression as well as the up-regulation of prominent accessory molecules (CD40, CD86) and MHC molecules. Importantly, upon co-culture of such lymphoma cell-pulsed DC with autologous T cells, we could induce efficient cytotoxic T cell (CTL) responses against Daudi cell-associated antigens. These findings suggest that antibody treatment of tumor cells can, in addition to its direct cell damaging effects, under certain conditions, contribute to an induction of potentially protective cytotoxic T cell responses.

Characterization of hybrid CTL epitope delivery systems consisting of the Antennapedia homeodomain peptide vector formulated in liposomes

Peptide carriers, such the homeodomain of Antennapedia molecule (AntpHD), which spontaneously cross cellular membranes, have been exploited to deliver antigenic peptide Cw3 to the major histocompatibility complex (MHC) class-I presentation pathway and to prime cytotoxic T cells (CTL). However, the in vivo use of AntpHD recombinant peptide has been limited because CTLs can only be primed in the presence of sodium dodecyl sulfate (SDS) as adjuvant. In this report, we have exploited liposomes to protect the AntpHD-Cw3 from serum degradation and to facilitate the delivery of the recombinant peptide into the MHC class-I pathway of antigen-presenting cells. We have demonstrated that AntpHD recombinant peptide spontaneously associates with liposomes and this association is stable in vitro. However, exchange studies assessing the transfer of the peptide to model membranes or cells in vitro indicates that approximately 50% of the liposome-associated peptide is readily exchangeable. This is consistent with trypsin-protection assays, which have shown that approximately 40% of the liposome-associated peptide is protected from hydrolysis. Importantly, macrophages and dendritic cells are able to internalize AntpHD recombinant peptide associated with liposomes resulting in efficient delivery of the CTL peptide into the cytosol. These studies have demonstrated that dendritic cells treated with AntpHD-Cw3 in liposomes sensitize CTL clones to lyse syngeneic target cells expressing Cw3 epitope. This strategy, which combines liposomes and a peptide vector, provides a new approach for introducing molecules into the MHC class-I antigen presentation pathway of dendritic cells.

Gene delivery by attenuated Salmonella typhimurium: comparing the efficacy of helper versus cytotoxic T cell priming in tumor vaccination

Using the murine B16F1 melanoma, we compared a CTL- versus helper T cell (TH)-directed vaccination approach. Mice were either orally vaccinated with attenuated Salmonella typhimurium (SL) or subcutaneously with dendritic cells (DCs) loaded with gp100 peptides predicted to bind to H2-Kb/H2-Db molecules. SL were transformed with the murine gp100 cDNA (SL-gp100) or with a fusion construct of gp100 and a fragment of invariant chain cDNA (SL-gp100/Ii). Transcription of these genes in vivo has been readily observed in monocytes and DC. Retardation of B16F1 growth was more efficiently achieved by vaccination with SL-gp100 than with DC. Vaccination with SL-gp100/Ii aiming at preferential presentation by MHC II molecules provided some further improvement due to a stronger expansion of TH and CTL. The importance of help was further sustained by a prolongation of the survival time when mice concomitantly received IL2. Notably, prophylactic, compared to therapeutic, vaccination had no additional impact on survival time/rate. This was due to a striking decrease in frequencies of gp100-specific TH, CTL, and cytokine-expressing cells during tumor growth. Thus, the efficacy of vaccination was limited by tumor-induced immunosuppression. Our data demonstrate the oral route of vaccination via Salmonella as a most convenient transfer regimen and confirm the superiority of protocols aiming at preferential activation of TH.

Highly efficient gene delivery by mRNA electroporation in human hematopoietic cells: superiority to lipofection and passive pulsing of mRNA and to electroporation of plasmid cDNA for tumor antigen loading of dendritic cells

Designing effective strategies to load human dendritic cells (DCs) with tumor antigens is a challenging approach for DC-based tumor vaccines. Here, a cytoplasmic expression system based on mRNA electroporation to efficiently introduce tumor antigens into DCs is described. Preliminary experiments in K562 cells using an enhanced green fluorescent protein (EGFP) reporter gene revealed that mRNA electroporation as compared with plasmid DNA electroporation showed a markedly improved transfection efficiency (89% versus 40% EGFP(+) cells, respectively) and induced a strikingly lower cell toxicity (15% death rate with mRNA versus 51% with plasmid DNA). Next, mRNA electroporation was applied for nonviral transfection of different types of human DCs, including monocyte-derived DCs (Mo-DCs), CD34(+) progenitor-derived DCs (34-DCs) and Langerhans cells (34-LCs). High-level transgene expression by mRNA electroporation was obtained in more than 50% of all DC types. mRNA-electroporated DCs retained their phenotype and maturational potential. Importantly, DCs electroporated with mRNA-encoding Melan-A strongly activated a Melan-A-specific cytotoxic T lymphocyte (CTL) clone in an HLA-restricted manner and were superior to mRNA-lipofected or -pulsed DCs. Optimal stimulation of the CTL occurred when Mo-DCs underwent maturation following mRNA transfection. Strikingly, a nonspecific stimulation of CTL was observed when DCs were transfected with plasmid DNA. The data clearly demonstrate that Mo-DCs electroporated with mRNA efficiently present functional antigenic peptides to cytotoxic T cells. Therefore, electroporation of mRNA-encoding tumor antigens is a powerful technique to charge human dendritic cells with tumor antigens and could serve applications in future DC-based tumor vaccines.

Gene-based cancer vaccines: an ex vivo approach

The application of gene transfer techniques to immunotherapy has animated the field of gene-based cancer vaccine research. Gene transfer strategies were developed to bring about active immunization against tumor-associated antigens (TAA) through gene transfer technology. A wide variety of viral and nonviral gene transfer methods have been investigated for immunotherapeutic purposes. Ex vivo strategies include gene delivery into tumor cells and into cellular components of the immune system, including cytotoxic T cells and dendritic cells (DC). The nature of the transferred genetic material as well as the gene transfer method has varied widely depending on the application. Several of these approaches have already been translated into clinical gene therapy trials. In this review, we will focus on the rationale and types of ex vivo gene-based immunotherapy of cancer. Critical areas for future development of gene-based cancer vaccines are addressed, with particular emphasis on use of DC and on the danger-tolerance hypothesis. Finally, the use of gene-modified DC for tumor vaccination and its prospects are discussed.

Establishment of a follicular lymphoma cell line (FLK-1) dependent on follicular dendritic cell-like cell line HK

A novel cell line, FLK-1, was established from bone marrow cells of a patient with follicular lymphoma by means of co-culture with follicular dendritic cell (FDC)-like cell line HK. Immunophenotypic analysis showed that FLK-1 expressed CD10, CD19, CD20, CD38, IgG and HLA-DR, which is a typical feature of germinal center B cells. Cytogenetic analysis of FLK-1 demonstrated t(14;18)(q32;q21) translocation involving BCL2 and immunoglobulin heavy chain genes. Especially noteworthy is that the growth of FLK-1 was found to be dependent on a FDC line, HK. When HK cells were removed from the culture, FLK-1 cells stopped growing and eventually died. An apoptotic mechanism appeared to be involved as indicated by the presence of chromosome condensation and DNA ladder formation. The culture experiment using micropore membranes showed that soluble factor(s) of HK cells supported the growth, while direct cell-to-cell contact appeared to be necessary for longterm cell proliferation. These findings suggest the importance of the micro-environment for follicular lymphoma cells to grow. The FLK-1 cell line may thus prove to be useful for studying the growth mechanism of follicular lymphoma and provide new insights into the pathogenesis of follicular lymphoma.

Extensive characterization of dendritic cells generated in serum-free conditions: regulation of soluble antigen uptake, apoptotic tumor cell phagocytosis, chemotaxis and T cell activation during maturation in vitro

Dendritic cells (DC) play a key role in the initiation of primary immune response, and pilot clinical studies have demonstrated their ability to induce efficient antitumor immunity. However, the DC used in these clinical trials were generated with various serum sources and were poorly characterized. Obtaining fully characterized DC in controlled and reproducible culture conditions is thus of major interest. We demonstrate that X-VIVO 15 medium supplemented with 2% human albumin can be used to obtain DC. The phenotypic and functional characteristics of these clinical-grade DC were analyzed according to their differentiation stages. CD83 immature DC, obtained in the presence of granulocyte-macrophage colony-stimulating factor (GM-CSF) and interleukin (IL)-4, were able to endocyte soluble antigens and internalize apoptotic tumor cells, and also expressed receptors for inflammatory chemokines. Tumor necrosis factor-alpha (TNF-alpha) induced irreversible DC maturation in association with a decreased ability to uptake antigens and an increased allostimulatory capacity. CD83+ mature DC became responsive to EBI1 ligand chemokine (ELC), a chemokine specifically expressed in secondary lymphoid organs. In addition, mature DC obtained with TNF-alpha produced IL-12 and some IL-10 in response to CD40 stimulation. In conclusion, we present well-defined culture conditions allowing the control of DC maturation for clinical or fundamental studies.

Transfected human dendritic cells to induce antitumor immunity

Dendritic cells are professional antigen-presenting cells able to prime naive T lymphocytes and regulate steadily the delicate balance between tolerance and activation during the immune response. In past years several reports have shown that genetically engineered dendritic cells (DCs) can be a powerful tool for inducing an antigen-specific immune response. The use of such modified antigen-presenting cells is a real working hypothesis in preclinical studies and in clinical vaccination approaches for cancer treatment. The definition of optimal transfection conditions for preserving DC survival and functionality is necessary to design a correct immunotherapeutic protocol. Different lipid-based transfection compounds were studied for their effects on DC survival, phenotype and functional properties. All the transfection procedures were able to select DCs with a higher expression of activation and costimulatory molecules (ie MHCII-DR, CD83, CD86, CD25) than the untreated DCs. However, only two compounds (LipofectAMINE PLUS and FuGENE 6), preserved or even increased the immunopotency of DCs as antigen-presenting cells. These protocols were applied to modify DCs in order to express an epithelial tumor-associated antigen, MUC1, and such cells were able to induce in vitro a specific immune response in healthy donors.

DNA vaccines for cancer therapy

Vaccination with a tumour antigen-expressing plasmid DNA (pDNA) is a novel approach to human cancer immunotherapy. Initial results in preclinical rodent tumour models are promising, revealing that pDNA cancer vaccines can elicit both humoral, as well as cell-mediated immunity and, in some cases, protect against tumour growth. Compared to peptide, viral or dendritic cell vaccines, the delivery of tumour antigens using pDNA has the advantages of ease of manufacture, lack of toxicity and broad applicability to large populations. With advances in modern genomics strategies and the identification of an increasing number of tumour antigen genes, pDNA-based cancer vaccines may be used in the future to treat a wide variety of human cancers.