In a study aiming at the identification of molecular signatures for alternatively activated DC it was found that AA-DC induced in the presence of LPS and IL-10 also produced high levels of the long pentraxin PTX3. DC produced conspicuous amounts of PTX3 when stimulated with LPS and this production is further increased in the presence of IL-10. However, PTX3 production was not increased in other alternative conditions of activation, such as in the presence of dexamethasone or calcitriol. PTX3 has properties similar to antibodies. Its production is induced by pa...

When identifying molecular signatures for alternatively activated DC (AA-DC) it was found that the hallmark of AA-DC was the production of the angiogenic cytokine VEGF in vitro, and in vivo when the cells were implanted into the chicken embryo CAM assay. VEGF production by DC was selectively observed only when the DC where alternatively activated. Therefore, VEGF production by DC can be considered a signature of this state of activation.

An mAb reacting to the immunodominant LACK156-173 peptide of leishmania bound to I-Ad MHC class II molecules was prepared. To this aim, we injected I-Ad/LACK recombinant dimers to TCR transgenic mice which exhibited an increased frequency of LACK-specific T cells. Four out of 600 supernatants, i.e. 2C44, 2F74, 2E60 and 2X8, readily stained LACK156-173-pulsed fibroblasts, but neither unpulsed fibroblasts nor OVA323-339-pulsed cells. BIAcore measurements yielded equilibrium dissociation constants ranging from 1.1 nM for 2C44 mAb to 120 nM for 2F74 mAb.

Surface markers were used to establishe routine monitoring of tumor-specific T-cell subsets by multicolor flow cytometry. For this purpose multimers were used kindly provided by Pierre Coulie (Brussels) together with surface markers (such as CD8, CD4, CD3, CD45RA, CCR7, CD25, CD27, CD137, CD127) in different 8-color panels on the BD FACSCanto II. Additionally, these CD107a functional markers were used and intracellular cytokine staining for the further analysis of individual T-cell populations and T-cell clones.

Surface markers were used to establishe routine monitoring of tumor-specific T-cell subsets by multicolor flow cytometry. For this purpose multimers were used kindly provided by Pierre Coulie (Brussels) together with CD137 surface markers (and additionally, CD8, CD4, CD3, CD45RA, CCR7, CD25, CD27, CD127) in different 8-color panels on the BD FACSCanto II. Additionally, functional markers such as CD107a were used and intracellular cytokine staining for the further analysis of individual T-cell populations and T-cell clones.

Surface markers were used to establishe routine monitoring of tumor-specific T-cell subsets by multicolor flow cytometry. For this purpose multimers were used kindly provided by Pierre Coulie (Brussels) together with CD27 surface markers (and additionally, CD8, CD4, CD3, CD45RA, CCR7, CD25, CD137, CD127) in different 8-color panels on the BD FACSCanto II. Additionally, functional markers such as CD107a were used and intracellular cytokine staining for the further analysis of individual T-cell populations and T-cell clones.

Surface markers were used to establishe routine monitoring of tumor-specific T-cell subsets by multicolor flow cytometry. For this purpose multimers were used kindly provided by Pierre Coulie (Brussels) together with CD127 surface markers (and additionally, CD8, CD4, CD3, CD45RA, CCR7, CD25, CD27, CD137) in different 8-color panels on the BD FACSCanto II. Additionally, functional markers such as CD107a were used and intracellular cytokine staining for the further analysis of individual T-cell populations and T-cell clones.

The expression and function of these murine FcgammaR in CD11c+CD11b-B220+ plasmacytoid DCs (pDCs) was investigated. pDCs express mostly FcgammaRIIB while the expression of FcgammaRI and FcgammaRIII is only detected by RT-PCR at low but significant level. Moreover, the ITAM-containing intracellular chain associated to FcgammaRI and FcgammaRIII is strongly expressed in pDCs as detected by biochemical assay.

Surface markers were used to establishe routine monitoring of tumor-specific T-cell subsets by multicolor flow cytometry. For this purpose multimers were used kindly provided by Pierre Coulie (Brussels) together with CD4 surface markers (and additionally, CD8, CD3, CD45RA, CCR7, CD25, CD27, CD137, CD127) in different 8-color panels on the BD FACSCanto II. Additionally, functional markers such as CD107a were used and intracellular cytokine staining for the further analysis of individual T-cell populations and T-cell clones.

Surface markers were used to establishe routine monitoring of tumor-specific T-cell subsets by multicolor flow cytometry. For this purpose multimers were used kindly provided by Pierre Coulie (Brussels) together with CD25 surface markers (and additionally, CD8, CD4, CD3, CD45RA, CCR7, CD27, CD137, CD127) in different 8-color panels on the BD FACSCanto II. Additionally, functional markers such as CD107a were used and intracellular cytokine staining for the further analysis of individual T-cell populations and T-cell clones.

Surface markers were used to establishe routine monitoring of tumor-specific T-cell subsets by multicolor flow cytometry. For this purpose multimers were used kindly provided by Pierre Coulie (Brussels) together with CD3 surface markers (and additionally, CD8, CD4, CD45RA, CCR7, CD25, CD27, CD137, CD127) in different 8-color panels on the BD FACSCanto II. Additionally, functional markers such as CD107a were used and intracellular cytokine staining for the further analysis of individual T-cell populations and T-cell clones.

These surface markers were used to establishe routine monitoring of tumor-specific T-cell subsets by multicolor flow cytometry. For this purpose multimers were used kindly provided by Pierre Coulie (Brussels) together with surface markers (such as CD8, CD4, CD3, CD45RA, CCR7, CD25, CD27, CD137, CD127) in different 8-color panels on the BD FACSCanto II. Additionally, functional markers such as CD107a were used and intracellular cytokine staining for the further analysis of individual T-cell populations and T-cell clones.

TNF alpha was used for DC maturation with the final aim to produce a DC vaccine.

IFN alpha was used in a DC maturation process with the final aim to produce a DC vaccine.

This PGE2 was used in a DC maturation process with the final aim to produce a DC vaccine.

The TcR-Tg clones are specific for the 0T-1-OVA antigen. In the individual T cells, we studied the expression of twenty different genes either mediating effector functions, or coding for different receptors involved in T cell differentiation and memory generation.

These TcR-Tg clones are specific for the P14-GP33 antigen. In the individual T cells, we studied the expression of twenty different genes either mediating effector functions, or coding for different receptors involved in T cell differentiation and memory generation.

CD1 molecules are refolded in vitro in order to generate CD1 tetramers.

CD1 molecules that are subsequently to be refolded in vitro in order to generate CD1 tetramers.

The CD1d tetramers were generated from in vitro refolded CD1 molecules. The ability to generate CD1d tetramers has provided us with the opportunity of comparing a broad panel of CD1d binding compounds for their ability to stimulate iNKT cells.