Activation of biological functions in T lymphocytes is determined by the molecular dynamics occurring at the T cell͞opposing cell interface. In the present study, a central question of cytotoxic T lymphocyte (CTL) biology was studied at the single-cell level: can two distinct activation thresholds for cytotoxicity and cytokine production be explained by intercellular molecular dynamics between CTLs and targets? In this study, we combine morphological approaches with numerical analysis, which allows us to associate specific patterns of calcium mobilization with different biological responses. We show that CTLs selectively activated to cytotoxicity lack a mature immunological synapse while exhibiting a low threshold polarized secretion of lytic granules and spike-like patterns of calcium mobilization. This finding is contrasted by fully activated CTLs, which exhibit a mature immunological synapse and smooth and sustained calcium mobilization. Our results indicate that intercellular molecular dynamics and signaling characteristics allow the definition of two activation thresholds in individual CTLs: one for polarized granule secretion (lytic synapse formation) and the other for cytokine production (stimulatory synapse formation).
Helper T cells discriminate among different antigen-presenting cells to provide their help in a selective fashion. The molecular mechanisms leading to this exquisite selectivity are still elusive. Here, we demonstrate that immunological synapses are dynamic and adaptable structures allowing T cells to communicate with multiple cells. We show that T cells can form simultaneous immunological synapses with cells presenting different levels of antigenic ligands but eventually polarize toward the strongest stimulus. Remarkably, living T cells form discrete foci of signal transduction of different intensities during the interaction with different antigen-presenting cells and rapidly relocate TCR and Golgi apparatus toward the cell providing the strongest stimulus. Our results illustrate that, although T cell activation requires sustained signaling, T cells are capable of rapid synapse remodeling and swift polarization responses. The combination of sustained signaling with preferential and rapid polarization provides a mechanism for the high sensitivity and selectivity of T cell responses.
The sustained increase of the cytosolic calcium concentration ([Ca2+]i) plays a central role in T-cell receptor (TCR)-mediated T-cell activation. Previous experiments using a [Ca2+]i clamp technique have demonstrated that specificity is encoded by the [Ca2+]i oscillation frequency since cytokine transcription factors are activated in a frequency-dependent manner. An outstanding question is how encoding of specific activation occurs under physiological conditions. In this case, continuous TCR interactions with specific peptides bound to cell surface-associated major histocompatibility complexes are driving the sustained [Ca2+]i increase. Addressing this question, we analyzed [Ca2+]i time series from individual T-cells mathematically. We are able to identify signal fluctuations associated with the TCR-triggering dynamics. We also find that [Ca2+]i time series associated with T-cells activated to IFN-gamma production exhibit oscillations with higher frequencies than the time series corresponding to T-cells not activated to IFN-gamma production. We show that signal autocorrelations are a means to distinguish functional signals according to their associated cytokine production. The signal level, however, allows for the distinction of nonfunctional from functional signals. These findings provide strong evidence for specificity encoding of biological functions in intracellular signals via signal level and signal correlations.
The interaction of T-lymphocytes with antigen-presenting cells displaying a small number of specific peptide/major histocompatibility complexes results in the downregulation of a large number of T-cell receptors (TCR), suggesting serial TCR triggering. However, the details of TCR downregulation are controversial. In particular, the level of comodulation of nonengaged TCR reported by different authors ranges from essentially none to considerable levels. Here, we address this controversy using complementary experimental and mathematical techniques. We find that TCR downregulation is very rapid during the first 2-4 min after T-cell antigen-presenting cells contact formation. After this phase, TCR downregulation proceeds at a relatively slow rate. Statistical and computational analyses show that this pronounced change in downregulation kinetics is compatible with the notion of initial serial triggering of clustered TCR followed by serial triggering of individual TCR. We further propose a compatible mechanism for concurrent triggering of multiple TCR by a single peptide/major histocompatibility complex. We provide a unified picture of productive TCR engagement and downregulation in which TCR triggering characteristics evolve from an initial cooperative phase to a sustained phase of signal accumulation.
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