Immunologic and clinical effects of injecting mature peptide-loaded dendritic cells by intralymphatic and intranodal routes in metastatic melanoma patients.

PURPOSE: A phase I/II trial was conducted to evaluate clinical and immunologic responses after intralymphatic and intranodal injections of mature dendritic cells. EXPERIMENTAL DESIGN: Fourteen patients with a metastatic melanoma received matured dendritic cells, loaded with Melan-A/MART-1 and/or NA17-A peptides and keyhole limpet hemocyanin. The cells were matured overnight with Ribomunyl, a toll-like receptor ligand, and IFN-gamma, which ensured the production of high levels of interleukin-12p70. Dendritic cells were injected at monthly intervals, first into an afferent lymphatic and then twice intranodally. Immunologic responses were monitored by tetramer staining of circulating CD8(+) lymphocytes and delayed-type hypersensitivity tests. RESULTS: Dendritic cell vaccination induced delayed-type hypersensitivity reactivity toward NA17-A-pulsed, keyhole limpet hemocyanin-pulsed, and Melan-A-pulsed dendritic cells in 6 of 10, 4 of 11, and 3 of 9 patients, respectively. Four of the 12 patients analyzed by tetramer staining showed a significantly increased frequency of Melan-A-specific T cells, including one patient vaccinated only with NA17-A-pulsed dendritic cells. Furthermore, 2 of the 12 analyzed patients had a significant increase of NA17-A-specific T cells, including one immunized after an optional additional treatment course. No objective clinical response was observed. Two patients were stabilized at 4 and 10 months and three patients are still alive at 30, 39, and 48 months. CONCLUSIONS: Injections into the lymphatic system of mature peptide-loaded dendritic cells with potential TH1 polarization capacities did not result in marked clinical results, despite immunologic responses in some patients. This highlights the need to improve our understanding of dendritic cell physiology.

Hepatic environment elicits monocyte differentiation into a dendritic cell subset directing Th2 response.

BACKGROUND/AIMS: Dendritic cells (DCs), which play a critical role during immune response, could present alternative differentiation patterns depending on tissue microenvironment. Our aim was to examine the influence of hepatic microenvironment on human monocyte differentiation into DCs. METHODS: Cytology, immunophenotyping, cytokine production and T-cell activation were analyzed in DCs differentiated from human monocytes co-cultured with rat liver epithelial cells (RLEC) or human cells from various tissue origins and compared to control DCs obtained on plastic with GM-CSF/IL-4. RESULTS: RLEC environment promotes DC differentiation in the presence of IL-4 without GM-CSF. These DCs evidence similar expression of MHC-II, co-stimulatory and adhesion molecules than control DCs, but distinct lineage markers defining a CD11c+/CD14+/CD123+ DC subset. This phenotype is common to DCs from RLEC and human liver environment and differs from that obtained with skin or intestine environments. Functionally, they produce IL-10 but not IL-12p70 and favor IL-4/IL-10 secretion by T-cells rather than IFN-gamma. CONCLUSIONS: Our results confirm that tissue niches modulate DC differentiation and demonstrate that hepatic environment influences monocyte differentiation into a DC subset directing Th2 response, a key data for understanding the specialized immune response in liver. They also make RLEC co-culture system useful for studying liver DC functions.

Biodistribution of radiolabelled human dendritic cells injected by various routes.

PURPOSE: The purpose of this study was to investigate the biodistribution of mature dendritic cells (DCs) injected by various routes, during a cell therapy protocol. METHODS: In the context of a vaccine therapy protocol for melanoma, DCs matured with Ribomunyl and interferon-gamma were labelled with( 111)In-oxine and injected into eight patients along various routes: afferent lymphatic vessel (IL) (4 times), lymph node (IN) (5 times) and intradermally (ID) (6 times). RESULTS: Scintigraphic investigations showed that the IL route allowed localisation of 80% of injected radioactivity in eight to ten nodes. In three cases of IN injection, the entire radioactivity stagnated in the injected nodes, while in two cases, migration to adjacent nodes was observed. This migration was detected rapidly after injection, as with IL injections, suggesting that passive transport occurred along the physiological lymphatic pathways. In two of the six ID injections, 1-2% of injected radioactivity reached a proximal lymph node. Migration was detectable in the first hour, but increased considerably after 24 h, suggesting an active migration mechanism. In both of the aforementioned cases, DCs were strongly CCR7-positive, but this feature was not a sufficient condition for effective migration. In comparison with DCs matured with TNF-alpha, IL-1beta, IL-6 and PGE2, our DCs showed a weaker in vitro migratory response to CCL21, despite comparable CCR7 expression, and higher allostimulatory and TH1 polarisation capacities. CONCLUSION: The IL route allowed reproducible administration of specified numbers of DCs. The IN route sometimes yielded fairly similar results, but not reproducibly. Lastly, we showed that DCs matured without PGE2 that have in vitro TH1 polarisation capacities can migrate to lymph nodes after ID injection.

Efficient migration of dendritic cells toward lymph node chemokines and induction of T(H)1 responses require maturation stimulus and apoptotic cell interaction.

Dendritic cells (DCs) have the unique ability to initiate primary immune responses, and they can be conditioned for vaccinal purposes to present antigens after the engulfment of apoptotic cells. To recruit the rare antigen-specific naive T cells, DCs require a maturation step and subsequent transport toward lymph node (LN). To date, prostaglandin E2 (PGE2) is the best-characterized compound inducing this LN-directed migration in vitro, but PGE2 may skew the immune responses in a T(H)2 direction. We demonstrate here that on incubation with apoptotic tumor cells and tumor necrosis factor-alpha (TNF-alpha) or lipopolysaccharide (LPS), human monocyte-derived DCs become fully mature and acquire high migratory capacities toward LN-directing chemokines. The migration of TNF-alpha-treated DCs occurs only after cotreatment with apoptotic cells but not with necrotic cells. DC migration requires CD36 expression and incubation with apoptotic cells in the presence of heat-labile serum components. Moreover, on treatment with apoptotic cells and LPS, the migrating DCs are able to recruit naive T cells to generate T(H)1 immune responses. Our results show that the cotreatment of DCs with apoptotic tumor cells and inflammatory signals is promising for the design of an antitumoral DC-based vaccine.

[Vaccinal cell therapy in melanoma]. / Thérapies cellulaires vaccinales dans le mélanome.

Cell vaccination therapy in melanoma has now an around 15-year experience. Initially, the treatment was based on the use of autologous or allogeneic inactivated tumor cells. Today, new means become available, such as synthetic peptide tumor antigens, preparations of dendritic cells of various sorts and transfer of genes into vaccinating cells. In the protocols that have been published and that utilize dendritic cells or macrophages, about 10% of the patients show objective tumor responses. Improving the treatments requires choices among the numerous options now proposed. Pre-clinical investigations are designed to select the cell products to be tested in phase I, then II, clinical protocols. Later on, only phase-III randomized trials will confirm or not the efficacy of this new therapeutic approach.

Injection by various routes of melanoma antigen-associated macrophages: biodistribution and clinical effects.

Patients' autologous macrophages (AM) were used as antigen-presenting cells (APC) in a vaccination protocol against malignant melanoma. AM were administered by various routes, including intralymphatic, since these cells did not express CCR7, a molecule required for APC migration to lymph nodes. Seven HLA-A2 patients with metastatic melanoma-two classified as M1 and five as M3-were included in the study. AM were produced from leukapheresis-separated mononuclear cells by 7-day culture with granulocyte-macrophage colony-stimulating factor. After separation by elutriation, AM were frozen in aliquots and subsequently thawed at monthly intervals, exposed to MAGE-3(271-279) peptide and injected subcutaneously into lymph nodes or into one peripheral lymph vessel. Intradermal tests were performed before and after treatment to determine peptide reactivity. No acute toxicity was observed following injection. One M1 patient had a 7-mm induration intradermal reaction response and was stabilized for 64 weeks. The M3 patients did not show any immunological or clinical response. In 11 patients, the biodistribution of 111In-labeled AM was investigated. There was no clear evidence that AM injected intradermally or subcutaneously left the site of injection. After injection into a lymph vessel of the foot region, scintigraphs showed five to ten popliteal and inguinocrural lymph nodes. This appeared to be the most efficient way to administer rapidly and safely large amounts of peptide-loaded APC into lymph nodes.