Adenosine regulates CD8 T‐cell priming by inhibition of membrane‐proximal T‐cell receptor signalling
Summary Adenosine is a well‐described anti‐inflammatory modulator of immune responses within peripheral tissues. Extracellular adenosine accumulates in inflamed and damaged tissues and inhibits the effector functions of various immune cell populations, including CD8 T cells. However, it remains unclear whether extracellular adenosine also regulates the initial activation of naïve CD8 T cells by professional and semi‐professional antigen‐presenting cells, which determines their differentiation into effector or tolerant CD8 T cells, respectively. We show that adenosine inhibited the initial activation of murine naïve CD8 T cells after αCD3/CD28‐mediated stimulation. Adenosine caused inhibition of activation, cytokine production, metabolic activity, proliferation and ultimately effector differentiation of naïve CD8 T cells. Remarkably, adenosine interfered efficiently with CD8 T‐cell priming by professional antigen‐presenting cells (dendritic cells) and semi‐professional antigen‐presenting cells (liver sinusoidal endothelial cells). Further analysis of the underlying mechanisms demonstrated that adenosine prevented rapid tyrosine phosphorylation of the key kinase ZAP‐70 as well as Akt and ERK1/2 in naïve αCD3/CD28‐stimulated CD8 cells. Consequently, αCD3/CD28‐induced calcium‐influx into CD8 cells was reduced by exposure to adenosine. Our results support the notion that extracellular adenosine controls membrane‐proximal T‐cell receptor signalling and thereby also differentiation of naïve CD8 T cells. These data raise the possibility that extracellular adenosine has a physiological role in the regulation of CD8 T‐cell priming and differentiation in peripheral organs.
Cross-presentation of soluble Ag on MHC class I molecules to naive CD8 T cells by liver sinusoidal endothelial cells (LSECs) leads to induction of T cell tolerance that requires interaction between coinhibitory B7-H1 on LSECs and programmed cell death-1 on CD8 T cells. In this study, we investigate whether cross-presentation of high as well as low Ag concentrations allowed for LSEC-induced tolerance. Ag concentration directly correlated with the cross-presentation capacity of murine LSECs and thus strength of TCR stimulation. Although LSEC cross-presentation at low-Ag concentrations resulted in tolerance, they induced differentiation into effector T cells (CTL) at high-Ag concentrations. CTL differentiation under these conditions was not caused by increased expression of costimulatory CD80/86 on cross-presenting LSECs but was determined by early IL-2 release from naive CD8 T cells. B7-H1 signals from LSECs and TCR avidity reciprocally controlled early T cell release of IL-2 and CTL differentiation. B7-H1 expression directly correlated with cross-presentation at low- but not high-Ag concentrations, indicating an imbalance between TCR and coinhibitory signals regulating T cell release of IL-2. Exogenous IL-2 overrode coinhibitory B7-H1–mediated signals by LSECs and induced full CTL differentiation. Our results imply that LSEC-mediated T cell tolerance can be broken in situations where T cells bearing high-avidity TCR encounter LSECs cross-presenting high numbers of cognate MHC class I peptide molecules, such as during viral infection of the liver. Furthermore, we attribute a novel costimulatory function to IL-2 acting in a T cell autonomous fashion to promote local induction of immunity in the liver even in the absence of CD80/86 costimulation.
Systemic antigen cross-presented by liver sinusoidal endothelial cells induces liver-specific CD8 T-cell retention and tolerization
Peripheral CD8 T-cell tolerance can be generated outside lymphatic tissue in the liver, but the course of events leading to tolerogenic interaction of hepatic cell populations with circulating T-cells remain largely undefined. Here we demonstrate that preferential uptake of systemically circulating antigen by murine liver sinusoidal endothelial cells (LSECs), and not by other antigen-presenting cells in the liver or spleen, leads to cross-presentation on major histocompatibility complex (MHC) I molecules, which causes rapid antigen-specific naïve CD8 T-cell retention in the liver but not in other organs. Using bone-marrow chimeras and a novel transgenic mouse model (Tie2-H-2K b mice) with endothelial cell-specific MHC I expression, we provide evidence that cross-presentation by organ-resident and radiationresistant LSECs in vivo was both essential and sufficient to cause antigen-specific retention of naïve CD8 T-cells under noninflammatory conditions. This was followed by sustained CD8 T-cell proliferation and expansion in vivo, but ultimately led to the development of T-cell tolerance.
Distinct kinetics and dynamics of cross-presentation in liver sinusoidal endothelial cells compared to dendritic cells
Cross-presentation is an important function of immune competent cells, such as dendritic cells (DCs), macrophages, and an organ-resident liver cell population, i.e., liver sinusoidal endothelial cells (LSECs). Here, we characterize in direct comparison to DCs the distinct dynamics and kinetics of cross-presentation employed by LSECs, which promote tolerance induction in CD8 T cells. We found that LSECs were as competent in cross-presenting circulating soluble antigen ex vivo as DCs at a per-cell basis. However, antigen uptake in vivo was 100-fold more pronounced in LSECs, indicating distinct mechanisms of cross-presentation. In contrast to mannose-receptor-mediated antigen uptake and routing into stable endosomes dedicated to cross-presentation in DCs, we observed distinct antigen-uptake and endosomal routing with high antigen turnover in LSECs that resulted in short-lived crosspresentation. Receptor-mediated endocytosis did not always lead to cross-presentation, because immune-complexed antigen taken up by the Fc-receptor was not cross-presented by LSECs, indicating that induction of CD8 T cell tolerance by LSECs is impaired in the presence of preexisting immunity. Conclusion: These results provide a mechanistic explanation how organ-resident LSECs accommodate continuous scavenger function with the capacity to cross-present circulating antigens using distinct kinetics and dynamics of antigenuptake, routing and cross-presentation compared to DCs. (HEPATOLOGY 2009;50:909-919.)
The liver has a pivotal role in glucose, lipid and protein metabolism as well as in removal of toxins and waste products. A unique microanatomy and a network of resident scavenger cell populations specialized in endocytic uptake of antigens and macromolecules cooperatively mediate these salient hepatic functions together with parenchymal hepatocytes. Antigens taken up by hepatic scavenger cell populations, such as Kupffer cells, hepatic dendritic cells, stellate cells and liver sinusoidal endothelial cells (LSECs), can be (cross-)presented on MHC class I and II molecules, which leads to modulation of T cell immune functions. Among these cell populations, LSECs are endowed with the highest scavenger activity and are the most efficient cell population in cross-presenting soluble exogenous antigens to CD8 T cells. Together with their large number and the high cumulative surface area, LSECs represent the hepatic cell population that is best situated to interact with circulating T cells. Under physiological conditions, antigen-specific interaction of LSECs with CD8 T cells induces tolerance that is characterized by nonresponsiveness towards T cell receptor-mediated stimulation. In contrast to functional maturation of dendritic cells by activation through pattern recognition receptors, there is no such maturation in antigen-presenting LSECs, demonstrating that even under inflammatory conditions induction of CD8 T cell tolerance is preserved. However, upon viral infection of LSECs, a unique program of T cell differentiation into effector cytotoxic T cells is initiated that is independent of currently known costimulatory signals. These results highlight specific mechanisms operative in liver-resident antigen-presenting cells governing the local balance between tolerance and immunity.
In vivo evaluation of CD8 T cell effector (cytotoxic T lymphocyte [CTL]) function in peripheral organs such as the liver is currently not possible but would greatly improve our understanding of local immune regulation, because simple determination of antigen-specific CTL numbers does not predict the outcome of immune responses. In particular, measurement of alanine aminotransferase serum levels is not sensitive enough to detect T cell immunity against low numbers of target hepatocytes. We developed a procedure that detects virus-specific effector function of CTLs in the liver after simultaneous adenoviral transfer of reporter and immune target genes into hepatocytes, followed by bioluminescence imaging of reporter genes. Bioluminescence imaging enabled detection of as few as 10,000 infected hepatocytes in vivo, and even more importantly, quantification of antiviral effector function of as few as 50,000 CTLs. Conclusion: Our results provide evidence that low numbers of antigen-specific CTLs are sufficient to control viral gene expression and eliminate viral infection from hepatocytes. The experimental system established here is a highly sensitive method to simultaneously detect viral infection of hepatocytes and to quantify antiviral CTL function in the liver in vivo and will help in characterizing principles of hepatic immune regulation.
Innate immunity is crucial for an effective host defense against pathogenic microorganisms in periodontal tissues. As periodontal ligament (PDL) cells synthesize immunomodulatory cytokines, the aim of this in vitro study was to investigate whether these cells can interact with innate immune cells. Resting and inflammatory primed (IL-1β, TNF-α, HMGB1) human PDL cells were co-cultured with human monocyte-derived dendritic cells or macrophages. Migration, phenotypic maturation and modulation of phagocytosis of Porphyromonas gingivalis by immune cells were investigated upon co-culture with PDL cells and/or their released soluble factors. PDL cells interacted with immune cells under both non-inflammatory and inflammatory conditions. Immune cell migration was significantly enhanced by co-culture with PDL cells, which also affected their phenotypic maturation both through cell-cell contact and through released soluble mediators. The dendritic cell maturation markers CD83 and CD86 were upregulated as much as both ‘alternatively activated’ M2 macrophage maturation markers CD23 and CD163. In contrast, the ‘classically activated’ M1 macrophage maturation marker CD64 was downregulated. Finally, PDL cells significantly enhanced the phagocytosis of Porphyromonas gingivalis by immune cells. Our experiments revealed that PDL cells are not only structural elements of the periodontium, but actively influence immune responses by interaction with innate immune cells.
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