T Cell Activation Pathways : B7, LFA-3, and ICAM-1 Shape Unique T Cell Profiles

Two signals are required for induction of cell proliferation and cytokine production in resting T cells. Occupancy of the T cell receptor by antigen/MHC complexes delivers the first signal to the T cell, while the second signal is provided by interaction with costimulatory ligands on APC. CD2, LFA-1, and CD28 are the major costimulatory and adhesive molecules on T cells and bind to the LFA-3, ICAM-1 and B7 ligands, respectively, on APC. LFA-3 plays a central role for naive and memory T helper cells during the early phase of an immune response. The LFA-3/CD2 pathway initiates strong antigen-independent cell adhesion, substantial expansion of naive T helper cells, and induction of large amounts of IFN-γ in memory cells. The release of IFN-γ may upregulate expression of ICAM-1 and B7 on APC and allows multiple adhesion pathways to amplify the immune response. The LFA- 1/ICAM-l pathway stimulates adhesion and cell proliferation more efficiently in memory T helper cells than in naive cells. Further, the results suggest that naive T helper cells express functionally inactive LFA-1 molecules on the cell surface, which may have a physiological role in keeping these cells in a resting state. B7 costimulation superinduces IL-2 production in both naive and memory T helper cells and generates long-lasting cell proliferation. This permits transition from an autocrine to a paracrine immune response. Coexpression of B7/LFA-3 provides an optimal APC function and enables a vigorous T cell response to minute amounts of antigen. AP-1 and NF-κB transcription factors are involved in the induction of several cytokine gene promoters and play a central role in the regulation of IL-2 gene transcription. LFA-3 costimulation only moderately enhances AP-1 DNA-binding activity and does not influence the NF-κB activity induced by TCR engagement, whereas B7 costimulation induces large amounts of NF-κB and AP-1 activity in T helper cells. The costimulatory ligands represent a family of adhesion molecules with considerable redundancy. Interfamily redundancy of LFA-3, B7, and ICAM ligands offers an opportunity to regulate distinct T cell response profiles in various microenvironments at separate time points of an immune response

Endothelial Cells Expressing an Inflammatory Phenotype Are Lysed by Superantigen-Targeted Cytotoxic T Cells

The objective of this study was to investigate whether the superantigen staphylococcal enterotoxin A (SEA), which binds to HLA class II and T-cell receptor Vβ chains, can direct cytotoxic T cells to lyse cytokine-stimulated endothelial cells (EC). In addition, we wanted to determine whether SEA-primed cytotoxic T cells could be targeted to EC surface molecules as a means of a novel cancer immunotherapy. Human umbilical vein EC (HUVEC), dermal microvascular EC (HMVEC), or the EC line EA.hy926 stimulated with gamma interferon (IFN-γ) or tumor necrosis factor alpha (TNF-α) displayed upregulated HLA class II and adhesion molecule (CD54 and CD106) expression, respectively. SEA-primed T cells induced a strong cytotoxicity against IFN-γ- and TNF-α-activated EA.hy926 which had been preincubated with SEA. Blocking of CD54 completely abrogated the T-cell attack. SEA-D227A, which has a mutated class II binding site, did not promote any cytotoxicity. A strong lysis was observed when a fusion protein consisting of protein A and SEA-D227A was added together with T cells to TNF-α-induced EA.hy926 and HUVEC precoated with monoclonal antibodies (MAb) directed against HLA class I, CD54, or CD106 molecules. Finally, an scFv antibody fragment reactive with an unknown EC antigen was fused with SEA-D227A. Both EA.hy926 and HMVEC were efficiently lysed by scFv-SEA-D227A-triggered cytotoxic T cells. Taken together, superantigen-activated T-cell-dependent EC killing was induced when EC expressed an inflammatory phenotype. Moreover, specific MAb targeting of the superantigen to surface antigens induced EC lysis. Our data suggest that directed T-cell-mediated lysis of unwanted proliferating EC, such as those in the tumor microvasculature, can be clinically useful