Tumor-specific CD8 T cell responses to MCA102 fibrosarcoma cells expressing the cytotoxic T cell epitope gp33 from lymphocytic choriomeningitis virus were studied. MCA102gp33 tumors grew progressively in C57BL/6 mice, despite induction of peripheral gp33-tetramer+ T cells that were capable of mediating antiviral protection, specific cell rejection, and concomitant tumor immunity. MCA102gp33 tumors were infiltrated with a high number (∼20%) of CD11b+CD11c− macrophage-phenotype cells that were able to cross-present the gp33 epitope to T cells. Tumor-infiltrating CD8 T cells exhibited a highly activated phenotype but lacked effector cell function. Strikingly, a significant portion of tumor-infiltrating lymphocytes expressed TCRs specific for gp33 but bound MHC tetramers only after cell purification and a 24-h resting period in vitro. The phenomenon of “tetramer-negative T cells” was not restricted to tumor-infiltrating lymphocytes from MCA102gp33 tumors, but was also observed when Ag-specific T cells derived from an environment with high Ag load were analyzed ex vivo. Thus, using a novel tumor model, allowing us to trace tumor-specific T cells at the single cell level in vivo, we demonstrate that the tumor microenvironment is able to alter the functional activity of T cells infiltrating the tumor mass.
The role of perforin, IFN-γ, and TNF-α in anti-tumor CD8 T cell immunity was examined in a new tumor model using a CD8 T cell epitope (GP33) derived from lymphocytic choriomeningitis virus as a tumor-associated Ag. In contrast with parental 3LL-A9 (A9) Lewis lung carcinoma cells that progressively grow in C57BL/6 mice, s.c. injection of GP33-transfected A9GP33 tumor cells induced a protective GP33-specific CD8 T cell response that led to complete tumor cell elimination. Tumor regression was dependent on perforin, IFN-γ, or TNF-α, because A9GP33 tumors developed in mice deficient in one of these genes. A9GP33 tumors arising in perforin- and IFN-γ-deficient mice represented GP33 Ag-loss variants, demonstrating that GP33-specific CD8 T cells from these mice were able to exert an Ag selection pressure. In contrast, tumor cells growing in TNF-α knock-out mice still expressed the tumor-associated GP33 peptide despite the presence of activated GP33-specific CD8 T cells. These findings provide evidence for a crucial role of TNF-α in A9 tumor cell elimination by CD8 T cells in vivo.
Diploid fibroblast (dFb) cultures were established from a total of 106 skin and serosa biopsies of human adults. Using an optimized enzymatic dissociation procedure, 10(11) dFb/cm2 skin were obtained from patients younger than 60 years after an average time of 89 +/- 8 days, with a mean population doubling time of 3.87 +/- 1.4 days. Enzymatic dissociation of skin biopsies yielded cultures of significantly higher growth capacity of dFb than those prepared by mechanical dissociation followed by spontaneous outgrowth of cells. The plating efficiency that may be crucial for clonal selection of transfected cells was negligible when dFb were plated without feeder cells at low density, while it was enhanced to 9-24% by the addition of a feeder layer of irradiated human embryonal fibroblasts. DFb secreted various cytokines with spontaneous release of interleukin-6 (IL-6) in high quantities of up to 20 ng/10(6) cells/24 hr. In addition, one-third of the culture secreted substantial amounts of granulocyte-macrophage colony-stimulating factor (GM-CSF), while low amounts of tumor necrosis factor-alpha (TNF-alpha) were detectable in some cases after irradiation of the cells. Comparison of various transfection methods by a transient luciferase expression assay demonstrated that receptor-mediated gene transfer was approximately 10-fold more efficient than cationic lipofection of dFb, while electroporation resulted in substantially less expression of the reporter gene. We conclude that primary dFb can be obtained reproducibly from human adults and represent a suitable target cell population for receptor-mediated gene transfer and cationic lipofection.(ABSTRACT TRUNCATED AT 250 WORDS)
It is well established by in vivo and in vitro studies that dendritic cells (DCs) originate from hematopoietic progenitor cells. However, the presumed intermediate of Birbeck granule (BG)+ Langerhans cells (LCs) has not been detected in cultures derived from bone marrow or peripheral blood progenitor cells (PBPCs), thus contrasting with the data obtained with cord blood. We show here that large numbers of BG+ LCs can be generated from human CD34+ PBPCs in vitro, when granulocyte-macrophage colony-stimulating factor and interleukin-4, potent promotors of LC/DC differentiation, are combined with a cocktail of early acting hematopoietic growth factors. LCs were found to emerge from CD33+CD11b+CD14-progenitor cells that they share with the monocytic lineage. During culture, these cells exhibited a sequence of dramatic morphologic changes, starting with a major increase in granularity followed by an increase in size herein exceeding that of all peripheral blood cells. At the same time, CD1a and major histocompatibility complex class II expression were upregulated and virtually all CD1a++ cells were BG+ by electron microscopy. With prolonged culture, CD1a was downregulated on a major population of cells, paralleled by a loss of BG and an increase of CD4, CD25, and CD80 expression that may correspond to the maturation of epidermal LC in vitro. However, these cells were consistently CD5- and did not exhibit changes in the CD45-isoform expression during culture. The availability of large numbers of these highly purified BG+ LCs and mature DCs allows for specific analysis of these subpopulations and provides a source of potent antigen-presenting cells from individual patients for vaccination protocols against infectious or tumor-associated antigens.
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