A large T cell invagination with CD2 enrichment resets receptor engagement in the immunological synapse.

T cell activation is driven by the TCR and complemented by costimulation. We have studied the dynamics of ligand-engagement of the costimulatory receptor CD2 in T cell/APC couples. Thousands of ligand-engaged CD2 molecules were included in a large T cell invagination at the center of the cellular interface within 1 min of cell couple formation. The structure and regulation of this invagination shared numerous features with phagocytosis and macropinocytosis. Three observations further characterize the invagination and the inclusion of CD2: 1) numerous ligand-engaged receptors were enriched in and internalized through the T cell invagination, none as prominently as CD2; 2) dissolution of the T cell invagination and CD2 engagement were required for effective proximal T cell signaling; and 3) the T cell invagination was uniquely sensitive to the affinity of the TCR for peptide-MHC. Based on this characterization, we speculate that the T cell invagination, aided by CD2 enrichment, internalizes parts of the TCR signaling machinery to reset T cell signaling upon agonist-mediated, stable APC contact.

The CD3 gamma epsilon/delta epsilon signaling module provides normal T cell functions in the absence of the TCR zeta immunoreceptor tyrosine-based activation motifs.

T cell receptor (TCR) signal transduction is mediated by the immunoreceptor tyrosine-based activation motifs (ITAM). The ten ITAM in the TCR complex are distributed in two distinct signaling modules termed TCR zetazeta and CD3 gammaepsilon/deltaepsilon. To delineate the specific role of the zeta ITAM in T cell development and TCR signal transmission, we compared the properties of T cells from different TCR zeta-transgenic lines wherein tyrosine-to-phenylalanine substitutions had been introduced in the zeta subunit. These lines lack selected phosphorylated forms of TCR zeta including just p23, both p21 and p23, or all phospho-zeta derivatives. We report herein that the efficiency of positive selection in HY TCR-transgenic female mice was directly related to the number of zeta ITAM in the TCR. In contrast, TCR-mediated signal transmission and T cell proliferative responses following agonist peptide stimulation were similar and independent of the zeta ITAM. Only the duration of MAPK activation was affected by multiple zeta ITAM substitutions. These results strongly suggest that the ITAM in the CD3 gammaepsilon/deltaepsilon module can provide normal TCR signal transmission, with zeta ITAM providing a secondary function facilitating MAPK activation and positive selection.

T cell receptor (TCR) clustering in the immunological synapse integrates TCR and costimulatory signaling in selected T cells.

During T cell activation, T cell receptors (TCR) cluster at the center of the T cell/antigen-presenting cell interface forming a key component of the immunological synapse. The function of this TCR clustering is still unresolved. A comprehensive search for such a function yielded a very limited and specific result. A micrometer-scale receptor clustering integrated the TCR and CD28 signals required for IL-2 secretion in primary 5C.C7 T cells, a low-affinity/avidity TCR system. 5C.C7 TCR signaling itself was not affected. In addition, central TCR accumulation was not required for any T cell effector function tested in three other TCR transgenic models. Central TCR accumulation thus had a specific role in signaling integration in low-affinity T cells.

Stepwise cytoskeletal polarization as a series of checkpoints in innate but not adaptive cytolytic killing.

Cytolytic killing is a major effector mechanism in the elimination of virally infected and tumor cells. The innate cytolytic effectors, natural killer (NK) cells, and the adaptive effectors, cytotoxic T cells (CTL), despite differential immune recognition, both use the same lytic mechanism, cytolytic granule release. Using live cell video fluorescence microscopy in various primary cell models of NK cell and CTL killing, we show here that on tight target cell contact, a majority of the NK cells established cytoskeletal polarity required for effective lytic function slowly or incompletely. In contrast, CTLs established cytoskeletal polarity rapidly. In addition, NK cell killing was uniquely sensitive to minor interference with cytoskeletal dynamics. We propose that the stepwise NK cell cytoskeletal polarization constitutes a series of checkpoints in NK cell killing. In addition, the use of more deliberate progression to effector function to compensate for inferior immune recognition specificity provides a mechanistic explanation for how the same effector function can be used in the different functional contexts of the innate and adaptive immune response.