Upon antigen recognition, T cells form either static (synapses) or migratory (kinapses) contacts with antigen-presenting cells. Addressing whether synapses and kinapses result in distinct T cell receptor (TCR) signals has been hampered by the inability to simultaneously assess T cell phenotype and behavior. Here, we introduced dynamic in situ cytometry (DISC), a combination of intravital multiphoton imaging and flow cytometry-like phenotypic analysis. Taking advantage of CD62L shedding as a marker of early TCR signaling, we examined how T cells sense TCR ligands of varying affinities in vivo. We uncovered three modes of antigen recognition: synapses with the strongest TCR signals, kinapses with robust signaling, and kinapses with weak signaling. As illustrated here, the DISC approach should provide unique opportunities to link immune cell behavior to phenotype and function in vivo.
The immune system is increasingly found to be involved in the development of several chronic illnesses, for which allopathic medicine has provided limited tools for treatment and especially prevention. In that context, it appears worthwhile to target the immune system in order to modulate the risk of certain chronic illnesses. Meanwhile, natural health products (NHPs) are generating renewed interest, particularly in the prevention and treatment of several chronic diseases. Over 20 scientists from fields related to immune function and NHPs were thus convened to establish the state of knowledge on these subjects and to explore future research directions. This review summarizes the result of discussions held during the symposium. It thus seeks to be thought provoking rather than to comprehensively cover such broad areas of research. Notably, a brief overview of the immune system is presented, including potentially useful targets and strategies to keep it in an equilibrated state, in order to prevent certain disorders. The pertinence and limitations of targeting the immune system to prevent chronic diseases is also discussed. The paper then discusses the usefulness and limitations of current experimental tools available to study the immune modulating effects of NHPs. Finally, a concise review of some of the most studied NHPs showing promising immunomodulatory activity is given, and avenues for future research are described.
In vitro studies have revealed that T cell activation occurs during the formation of either dynamic or stable interactions with antigenpresenting cells (APC), and the respective cell junctions have been referred to as immunological kinapses and synapses. However, the relevance and molecular dynamics of kinapses and synapses remain to be established in vivo. Using two-photon imaging, we tracked the distribution of LAT-EGFP molecules during antigen recognition by activated CD4 + T cells in lymph nodes. At steady state, LAT-EGFP molecules were preferentially found at the uropod of rapidly migrating T cells. In contrast to naïve T cells that fully stopped upon systemic antigen delivery, recently activated T cells decelerated and formed kinapses, characterized by continuous extension of membrane protrusions and by the absence of persistent LAT-EGFP clustering. On the other hand, activated CD4 + T cells formed stable immunological synapses with antigen-loaded B cells and displayed sustained accumulation of LAT-EGFP fluorescence at the contact zone. Our results show that the state of T cell activation and the type of APC largely influence T cell-APC contact dynamics in lymph nodes. Furthermore, we provide a dynamic look at immunological kinapses and synapses in lymph nodes and suggest the existence of distinct patterns of LAT redistribution during antigen recognition. Reorganization of the actin cytoskeleton (2, 3), translocation of the microtubule organizing center (4, 5), segregation of surface and signaling molecules into central and peripheral regions of the contact zone (cSMAC and pSMAC, respectively) (6, 7), condensation of membrane microdomains (8), and formation of dynamic microclusters (9-13) contribute to immunological synapse formation and have been proposed to participate in and/or regulate T cell activation. Of note, the topology of the immunological synapse is not unique and may depend on the type of APC, the T cell phenotype, and the strength of stimulation (14-16). In various experimental conditions, both bull's eye shaped and multifocal synapses have been described (6,7,17,18).In sharp contrast, evidence for organized immunological synapse and cSMAC formation in vivo is scarce and has been limited to static images (19)(20)(21)(22)(23). This remains a critical issue because T cell and APC behaviors are profoundly dependent on their surrounding microenvironment. For instance, T cells are highly motile in secondary lymphoid organs (24) but largely sessile in cell suspension. Thus, the topology and dynamics of T cell synapses in vivo remain to be established (25).Two-photon imaging is a technique of choice to tackle immune cell behavior in physiologic settings (26). Several studies have characterized the frequency, stability, and duration of interactions established by T cells and dendritic cells (DCs) or B cells in intact lymph nodes (reviewed in refs. 27 and 28). One of the interesting observations offered by these studies is that antigen (Ag) recognition by T cells can occur during long-lived interactio...
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