Cell interactions in three-dimensional environment between dendritic cell-tumor hybrid cells and human lymphocytes: looking for antitumor vaccine enhancement strategies.

Células híbridas dendríticas-tumorais vem sendo usadas em vacinas terapêuticas contra o câncer e tem mostrado resultados promissores, porém seu comportamento e funções são insuficientemente conhecidos. O presente trabalho pretende estudar a interação dessas células híbridas com diferentes subpopulações de linfócitos T em um ambiente 3D com colágeno tipo III. Nossos resultados indicaram que as células híbridas do grupo Fusão Tumoral interagiram tanto com linfócitos CD4 quanto com CD8. Linfócitos CD4 interagiram 2 vezes mais no grupo Fusão Linhagem do que nos outros grupos e sua interação foi de apenas com um único linfócito. Linfócitos CD8 do grupo Fusão Tumoral interagiram mais tempo quando comparado aos outros grupos. Não foi observada IL-2 na culturas onde as células híbridas estavam presentes e a proliferação de linfócitos no grupo Fusão Tumoral também não foi observada. Assim, a cocultura 3D foi capaz de demonstrar a importância de um protocolo personalizado para cada tipo de tumor, levando em consideração as características únicas de cada tumor.Dendritic cell-tumor cell hybrids have been used in therapeutic vaccines against cancer and has shown promising results, but their behavior and functions are insufficiently known. In this context, this study aims the interaction of these hybrid cells with different subpopulations of T cells in a 3D environment with collagen type III. Our results indicated that cells in Tumor Fusion group interacted with both CD4 and CD8 T lymphocytes. CD4 lymphocytes interacted 2 times more in the SKBR-3 Fusion group than another groups and their interaction was only with a single lymphocyte. CD8 lymphocytes interaction with the Tumor Fusion group resulted in longer interactions when in comparison with the another groups. No IL-2 was observed in cultures where the hybrid cells were present and the proliferation of lymphocytes in Tumor Fusion group was not observed. Thus, the 3D co-culture was able to demonstrate the importance of a custom protocol for each type of tumor, taking into consideration the unique characteristics of each one

Dendritic cells and T lymphocytes interactions in a novel 3D system

We describe the interactions between monocyte-derived DCs, in different stages of maturation, with allogeneic T lymphocytes in a 3D system. Maturation of DCs increased their interaction time with T lymphocytes from 43 to 138 minutes. The average motility of T lymphocytes interacting or not with DCs was also affected, varying from 0.21μm-0.37μm/minute to 0.36μm- 0.52μm/minute. These data indicate that this 3D BiotekTM scaffold enables interactions between lymphocytes and DCs at different stages of maturation and may be useful for the characterization of these interactions, the cellular subtypes and patterns of response induced

Dendritic cells stimulated by cationic liposomes

Immunotherapy of cancer aims to harness the immune system to detect and destroy cancer cells. To induce an immune response against cancer, activated dendritic cells (DCs) must present tumor antigens to T lymphocytes of patients. However, cancer patients’ DCs are frequently defective, therefore, they are prone to induce rather tolerance than immune responses. In this context, loading tumor antigens into DCs and, at the same time, activating these cells, is a tempting goal within the field. Thus, we investigated the effects of cationic liposomes on the DCs differentiation/maturation, evaluating their surface phenotype and ability to stimulate T lymphocytes proliferation in vitro. The cationic liposomes composed by egg phosphatidylcholine, 1,2-dioleoyl-3-trimethylammonium propane and 1,2-dioleoylphosphatidylethanolamine (50/25/25% molar) were prepared by the thin film method followed by extrusion (65 nm, polydispersity of 0.13) and by the dehydration–rehydrationmethod (95% of the population 107 nm, polydispersity of 0.52). The phenotypic analysis of dendritic cells and the analysis of T lymphocyte proliferation were performed by flow cytometry and showed that both cationic liposomes were incorporated and activated dendritic cells. Extruded liposomes were better incorporated and induced higher CD86 expression for dendritic cells than dehydrated–rehydrated vesicles. Furthermore, dendritic cells which internalized extruded liposomes also provided stronger T lymphocyte stimulation. Thus, cationic liposomes with a smaller size and polydispersity seem to be better incorporated by dendritic cells. Hence, these cationic liposomes could be used as a potential tool in further cancer immunotherapy strategies and contribute to new strategies in immunotherapy161270279FUNDAÇÃO DE AMPARO À PESQUISA DO ESTADO DE SÃO PAULO - FAPESPsem informaçã

Cationic liposomes produced via ethanol injection method for dendritic cell therapy

Cationic liposomes can be designed and developed in order to be an efficient gene delivery system for mammalian cells. Dendritic cell (DC) vaccines can be used to treat cancer, as cationic liposomes can deliver tumor antigens to cells while cells remain active. However, most methods used for liposome production are not able to reproduce in large scale the physicochemical and biological properties of liposomes produced in laboratory scale. In this context, ethanol injection method achieved promising results, although requiring post-treatment for size reduction and/or to remove residual ethanol. Thus, the purpose of this study was to generate cationic liposomes suitable for gene therapies via ethanol injection method in only one step (VEI) and compared to those submitted to a size reduction processes by microfluidization (MFV). For this, the method to produce cationic liposomes composed of egg phosphatidylcholine (EPC), 1,2-dioleoyl-3-trimethylammonium propane (DOTAP) and 1,2-dioleoylphosphatidylethanolamine (DOPE) was optimized using a statistical design approach. As a result, the size of VEI decreased from 290 nm to 110 nm and the polydispersity from 0.54 to 0.17. In the case of MFV, size decreased from 128 nm to 107 nm and polydispersity from 0.40 to 0.18. ST and MFV before and after optimization were also characterized in terms of morphology by transmission electron microscopy (TEM) and structure by differential scanning calorimetry (DSC). Finally, to show their potential in gene/immune therapies applications, DCs were stimulated by such liposomes. Cells internalized liposomes, increasing expression of the costimulatory molecule CD86 and inducing T lymphocyte proliferation274249263FUNDAÇÃO DE AMPARO À PESQUISA DO ESTADO DE SÃO PAULO - FAPESPsem informaçã

Cationic liposomes produced via ethanol injection method for dendritic cell therapy

<p>Cationic liposomes can be designed and developed in order to be an efficient gene delivery system for mammalian cells. Dendritic cell (DC) vaccines can be used to treat cancer, as cationic liposomes can deliver tumor antigens to cells while cells remain active. However, most methods used for liposome production are not able to reproduce in large scale the physicochemical and biological properties of liposomes produced in laboratory scale. In this context, ethanol injection method achieved promising results, although requiring post-treatment for size reduction and/or to remove residual ethanol. Thus, the purpose of this study was to generate cationic liposomes suitable for gene therapies via ethanol injection method in only one step (VEI) and compared to those submitted to a size reduction processes by microfluidization (MFV). For this, the method to produce cationic liposomes composed of egg phosphatidylcholine (EPC), 1,2-dioleoyl-3-trimethylammonium propane (DOTAP) and 1,2-dioleoylphosphatidylethanolamine (DOPE) was optimized using a statistical design approach. As a result, the size of VEI decreased from 290 nm to 110 nm and the polydispersity from 0.54 to 0.17. In the case of MFV, size decreased from 128 nm to 107 nm and polydispersity from 0.40 to 0.18. ST and MFV before and after optimization were also characterized in terms of morphology by transmission electron microscopy (TEM) and structure by differential scanning calorimetry (DSC). Finally, to show their potential in gene/immune therapies applications, DCs were stimulated by such liposomes. Cells internalized liposomes, increasing expression of the costimulatory molecule CD86 and inducing T lymphocyte proliferation.</p