Effects of IL-12 and IL-23 on antigen-presenting cells at the interface between innate and adaptive immunity

Recent evidence from different experimental systems has demonstrated that autocrine activation of antigen-presenting cells (APCs) may be important at the initiation of an immune response, and that a specific set of cytokines may meet the dual needs of activating APCs and priming and/or maintaining the antigen-specific T-cell response. Composite factors with p40, including IL-12 (p40/p35) and IL-23 (p40/p19), may be two such immunoregulatory cytokines, their effects encompassing actions on both myeloid APCs and T cells. However, although both cytokines enhance the Th1 costimulatory functions of APCs, and IL-23 does induce IL-12 from APCs, their effects, which in part overlap, can be differentiated from one another. This review summarizes recent data on the actions of IL-12 and IL-23 on dendritic cells and macrophages at the interface between innate and adaptive immunity.     

Synthetic surfaces as artificial antigen presenting cells in the study of T cell receptor triggering and immunological synapse formation

T cell activation occurs when T cell receptors engage peptide-major histocompatibility complex (pMHC) molecules displayed on the surface of antigen presenting cells (APCs). Clustering of TCRs and other receptors in physical patterns at the T-APC interface forms a structure known as an immunological synapse (IS). Studies of the IS are challenging due to the cell-cell contact context of the governing interactions. Model surfaces as synthetic APCs have thus been developed, where the type, quantity, and physical arrangement of ligands displayed to T cells are precisely controlled. These model systems have provided important insights into the structure and function of the IS.     

Understanding T cell signaling using membrane reconstitution

T cells are central players of our immune system, as their functions range from killing tumorous and virus‐infected cells to orchestrating the entire immune response. In order for T cells to divide and execute their functions, they must be activated by antigen‐presenting cells (APCs) through a cell‐cell junction. Extracellular interactions between receptors on T cells and their ligands on APCs trigger signaling cascades comprised of protein‐protein interactions, enzymatic reactions, and spatial reorganization events, to either stimulate or repress T cell activation. Plasma membrane is the major platform for T cell signaling. Recruitment of cytosolic proteins to membrane‐bound receptors is a common critical step in many signaling pathways. Membranes decrease the dimensionality of protein‐protein interactions to enable weak yet biologically important interactions. Membrane resident proteins can phase separate into micro‐islands that promote signaling by enriching or excluding signal regulators. Moreover, some membrane lipids can either mediate or regulate cell signaling by interacting with signaling proteins. While it is critical to investigate T cell signaling in a cellular environment, the large number of signaling pathways involved and potential crosstalk have made it difficult to obtain precise, quantitative information on T cell signaling. Reconstitution of purified proteins to model membranes provides a complementary avenue for T cell signaling research. Here, I review recent progress in studying T cell signaling using membrane reconstitution approaches.     

Attenuation of Th1 effector cell responses and susceptibility to experimental allergic encephalomyelitis in histamine H2 receptor knockout mice is due to dysregulation of cytokine production by antigen-presenting cells

Histamine, a biogenic amine with both neurotransmitter and vasoactive properties, is well recognized as an immunomodulatory agent in allergic and inflammatory reactions. It also plays a regulatory role in the development of antigen-specific immune responses. CD4+ T-cells from histamine H1 receptor (H1R)-deficient (H1RKO) mice produce significantly less interferon-gamma and more interleukin (IL)-4 in in vitro recall assays compared to wild-type controls. H1RKO mice are also less susceptible to acute early-phase experimental allergic encephalomyelitis indicating that H1R signaling in CD4+ T cells plays a central role in regulating pathogenic T-cell responses. In this study, we show that mice lacking histamine H2 receptor (H2RKO) are similar to H1RKO mice in that they develop encephalitogen-specific T-cell responses as assessed by proliferation and IL-2 production and present with less severe acute early-phase experimental allergic encephalomyelitis. However, unlike T cells from H1RKO mice, which exhibit a strong Th2 bias, T cells from H2RKO mice do not. Rather, they are uniquely characterized by a significant inhibition of Th1 effector cell responses. Given that both histamine and adjuvants such as pertussis toxin modulate antigen-presenting cell (APC) maturation and function, including T-cell-polarizing activity, we analyzed the cytokines/chemokines secreted by APCs from wild-type, H1RKO, and H2RKO mice. Significant differences in cytokine/chemokine production by APCs from unimmunized and immunized mice were delineated. APCs from H2RKO mice produce significantly less IL-12 and IL-6 and markedly greater amounts of MCP-1 compared to wild-type and H1RKO mice. Because MCP-1 is known to inhibit IL-12 production, the failure of H2RKO mice to generate encephalitogenic Th1 effector cell responses is consistent with inhibition of negative regulation of MCP-1 secretion by H2R signaling in APCs.     

TCR triggering on the move: diversity of T-cell interactions with antigen-presenting cells

Summary: Polarized T cells are mobile cells optimized for migration, receptor scanning, and signaling. When in contact with antigen-presenting cells (APCs), polarized T cells can develop a spectrum of biophysical interaction modes ranging from adhesive sticking to dynamic crawling. Both static and dynamic contacts support sustained triggering of the T-cell receptor (TCR), leading to signal induction, T blast formation, and proliferation. In dynamic interactions, T cells crawl across the surface of the APC at speeds of 2–6 µm/min and simultaneously establish an asymmetric tight yet mobile junction plane, representing a dynamic immunological synapse. In dynamic synapses three functional compartments of the polarized T cell are in close contact with the APC surface, i.e. leading edge, cell body and uropod. Through its mobility, the asymmetric junction is topographically suited for receptor scanning and engagement at the leading edge, retrograde receptor movement along the junction, and exit from the uropod. Herein we develop a model on scanning encounters between T cells and APCs that includes the simultaneous engagement of T-cell leading edge and uropod and implicates a serial receptor triggering mode in cell-cell recognition.     

Human NKT cells direct the differentiation of myeloid APCs that regulate T cell responses via expression of programmed cell death ligands

NKT cells are innate lymphocytes that can recognize self or foreign lipids presented by CD1d molecules. NKT cells have been shown to inhibit the development of autoimmunity in murine model systems, however, the pathways by which they foster immune tolerance remain poorly understood. Here we show that autoreactive human NKT cells stimulate monocytes to differentiate into myeloid APCs that have a regulatory phenotype characterized by poor conjugate formation with T cells. The NKT cell instructed myeloid APCs show elevated expression of the inhibitory ligand PD-L2, and blocking PD-L1 and PD-L2 during interactions of the APCs with T cells results in improved cluster formation and significantly increased T cell proliferative responses. The elevated expression of PD-L molecules on NKT-instructed APCs appears to result from exposure to extracellular ATP that is produced during NKT-monocyte interactions, and blocking purinergic signaling during monocyte differentiation results in APCs that form clusters with T cells and stimulate their proliferation. Finally, we show that human monocytes and NKT cells that are injected into immunodeficient mice co-localize together in spleen and liver, and after 3 days in vivo in the presence of NKT cells a fraction of the myeloid cells have upregulated markers associated with differentiation into professional APCs. These results suggest that autoreactive human NKT cells may promote tolerance by inducing the differentiation of regulatory myeloid APCs that limit T cell proliferation through expression of PD-L molecules.     

Regulation of effector T cells by antigen-presenting cells via interaction of the C-type lectin MGL with CD45

Homeostatic control of T cells involves tight regulation of effector T cells to prevent excessive activation that can cause tissue damage and autoimmunity. Little is known, however, about whether antigen-presenting cells (APCs) are also involved in maintaining immune system homeostasis once effector T cells are stimulated. Here we found that immature APCs downregulated effector T cell function by a mechanism involving the C-type lectin MGL expressed by APCs. Glycosylation-dependent interactions of MGL with CD45 on effector T cells negatively regulated T cell receptor-mediated signaling and T cell-dependent cytokine responses, which in turn decreased T cell proliferation and increased T cell death. Thus, regulation of effector T cells by MGL expressed on APCs may provide a target for regulating chronic inflammatory and autoimmune diseases.     

Transfer of extracellular vesicles during immune cell-cell interactions

The transfer of molecules between cells during cognate immune cell interactions has been reported, and recently a novel mechanism of transfer of proteins and genetic material such as small RNA between T cells and antigen-presenting cells (APCs) has been described, involving exchange of extracellular vesicles (EVs) during the formation of the immunological synapse (IS). EVs, a term that encompasses exosomes and microvesicles, has been implicated in cell-cell communication during immune responses associated with tumors, pathogens, allergies, and autoimmune diseases. This review focuses on EV transfer as a mechanism for the exchange of molecules during immune cell-cell interactions.     

A Hypothesis for the Selection of Available Repertoires: T-Cell Network Early in the Intrathymic Differentiation

T-cell recognition requires direct cell-cell interactions mediated by major histocompatibility complex (MHC)-restricted α-β heterodimeric receptors (Ti) in association with a constant protein complex termed T3 (TcR, Ti-T3). Interleukin 2 (IL-2) promotes growth and maturation of T cells upon binding to high affinity receptors (IL2-R). They are expressed after the recognition of antigen on accessory cells through the TcR [44]. Furthermore, current hypotheses propose that T-cell interactions are also mediated by a group of T-cell antigens, particularly T4/L3T4 and T8/Lyt 2 [35], and perhaps Tγ [15]. All their encoding genes are rearranged and/or expressed sequentially during thymocyte differentiation [5, 8, 40, 41, 46, 51, 52]. Thus, developmental analyses of T-cell function are essential to gain insight into the mechanisms for selection of available repertoires, one of the central problems in immunology.     

Autocrine IL-2 is required for secondary population expansion of CD8(+) memory T cells

Two competing theories have been put forward to explain the role of CD4(+) T cells in priming CD8(+) memory T cells: one proposes paracrine secretion of interleukin 2 (IL-2); the other proposes the activation of antigen-presenting cells (APCs) via the costimulatory molecule CD40 and its ligand CD40L. We investigated the requirement for IL-2 by the relevant three cell types in vivo and found that CD8(+) T cells, rather than CD4(+) T cells or dendritic cells (DCs), produced the IL-2 necessary for CD8(+) T cell memory. Il2(-/-) CD4(+) T cells were able to provide help only if their ability to transmit signals via CD40L was intact. Our findings reconcile contradictory elements implicit in each model noted above by showing that CD4(+) T cells activate APCs through a CD40L-dependent mechanism to enable autocrine production of IL-2 in CD8(+) memory T cells.     

Impaired T cell receptor signaling and development of T cell–mediated autoimmune arthritis

Mutations of the genes encoding T-cell receptor (TCR)-proximal signaling molecules, such as ZAP-70, can be causative of immunological diseases ranging from T-cell immunodeficiency to T-cell–mediated autoimmune disease. For example, SKG mice, which carry a hypomorphic point mutation of the Zap-70 gene, spontaneously develop T-cell–mediated autoimmune arthritis immunopathologically similar to human rheumatoid arthritis (RA). The Zap-70 mutation alters the sensitivity of developing T cells to thymic positive/negative selection by self-peptides/MHC complexes, shifting self-reactive TCR repertoire to include a dominant arthritogenic specificity and also affecting thymic development and function of autoimmune suppressive regulatory T (Treg) cells. Polyclonal self-reactive T cells, including potentially arthritogenic T cells, thus produced by the thymus recognize self-peptide/MHC complexes on antigen-presenting cells (APCs) in the periphery and stimulate them to produce cytokines including IL-6 to drive the arthritogenic T cells to differentiate into arthritogenic T-helper 17 (Th17) cells. Insufficient Treg suppression or activation of APCs via microbial and other environmental stimuli evokes arthritis by activating granulocyte-macrophage colony-stimulating factor-secreting effector Th17 cells, mediating chronic bone-destructive joint inflammation by activating myeloid cells, innate lymphoid cells, and synoviocytes in the joint. These findings obtained from the study of SKG mouse arthritis are instrumental in understanding how arthritogenic T cells are produced, become activated, and differentiate into effector T cells mediating arthritis, and may help devising therapeutic measures targeting autoimmune pathogenic Th17 cells or autoimmune-suppressing Treg cells to treat and prevent RA.     

Diverse functional activity of CD83+ monocyte-derived dendritic cells and the implications for cancer vaccines

Antigen-loaded dendritic cells (DCs) provide key regulatory signals to T cells during a developing antitumor response. In addition to providing costimulation, mature DC provides cytokine and chemokine signals that can define the T1 vs T2 nature of the antitumor T-cell response as well as whether T cells engage in direct interactions with tumor cells. In serum-free culture conditions that hasten the differentiation of monocytes into mature DCs, certain agents, such as CD40L, accelerate phenotypic maturation (e.g., CD83 and costimulatory molecule expression) without influencing the acquisition of Dc1/Dc2 characteristics. In contrast, exposure to serum-free medium and interferon-gamma (IFN-gamma) rapidly influences CD83+ DCs to secrete high levels of IL-12, IL-6, and MIP-1beta, and promotes Dcl differentiation. In contrast, CD83+ DCs matured in serum-free medium in the absence of IFN-gamma, or in the presence of calcium signaling agents, prostaglandin-E2, or IFN-alpha, produce no IL-12, scant IL-6, and prodigious IL-8, MDC, and TARC, and promote Dc2 differentiation. T cells sensitized via IL-12-secreting, peptide-pulsed DCs secrete cytokines when subsequently exposed to relevant peptide-pulsed antigen-presenting cells (APCs) or to HLA-compatible tumor cells endogenously expressing the peptide. In contrast, T cells sensitized via IL-12 nonsecreting DC were limited to antigenic reactivation through APC contact rather than tumor cell contact. Therefore, the development of antitumor responses can be dramatically influenced not only by costimulation, but also by the cytokine and chemokine production of DCs, which must be considered in the development of cancer vaccines.     

The insulin-like growth factor-I receptor is regulated by CD28 and protects activated T cells from apoptosis

Co-stimulatory signals through the CD28 receptor enhance the survival of T cells that have their antigen receptor (TCR) engaged. Here we show that stimulation through the CD28 receptor in the absence of TCR engagement with either an anti-CD28 cross-linking antibody or the CD80 ligand transiently increases expression of the insulin-like growth factor-I receptor (IGF-IR) on T cells. Antibodies that block signaling through the IGF-IR decrease the survival of T cells activated through the TCR and CD28 in the presence of IL-2 by more than 50%, and also enhance susceptibility to Fas-induced apoptosis. CD28 stimulation increases IGF-IR expression on Jurkat cells, and exogenously added IGF-I can protect these cells from Fas-induced apoptosis. We conclude that CD28-mediated enhancement of IGF-IR expression provides activated T cells with essential survival signals that are independent of survival mediated by IL-2 and Bcl-xl.     

T-cell activation through immunological synapses and kinapses

Summary: T-cell activation requires 'contact' with antigen-presenting cells (APCs) to bring the T-cell receptor (TCR) and antigenic major histocompatibility complex (MHC)-peptide complex together. Contact is defined by the size of the TCR and MHC–peptide complex, which at approximately 13 nm requires extensive interdigitation of the glycocalyx of the T cell and APC. T cells may be activated through formation of a stable T cell–APC junction, referred to as an immunological synapse. It has also been shown in vitro that T cells can integrate signals from APCs without a stable interaction. In vivo imaging studies supported the importance of both motile and stable T cell–APC interactions in T-cell priming. We have found that stability depends not upon turning off motile machinery but by symmetrization of force-generating structures to balance forces and hold the cell in place. Motility is induced by breaking this symmetry, which may be necessary to maintain the differentiation potential of the T cell. Recently, we also discovered a mode of T-cell signaling leading to tolerance in vivo based purely on motile interactions. Because this entire process takes place in a state of continuous T-cell kinesis, I propose the term 'kinapse' for motile T cell–APC contacts leading to signaling. Synapses and kinapses are inter-convertible by symmetrization/symmetry breaking processes, and both modes appear to be involved in normal T-cell priming. Imbalance of synapse/kinapse states may lead to immunopathology.     

Locally produced complement fragments C5a and C3a provide both costimulatory and survival signals to naive CD4+ T cells

Costimulatory signals are critical to T cell activation, but how their effects are mediated remains incompletely characterized. Here, we demonstrate that locally produced C5a and C3a anaphylatoxins interacting with their G protein-coupled receptors (GPCRs), C5aR and C3aR, on APCs and T cells both upstream and downstream of CD28 and CD40L signaling are integrally involved in T cell proliferation and differentiation. Disabling these interactions reduced MHC class II and costimulatory-molecule expression and dramatically diminished T cell responses. Importantly, impaired T cell activation by Cd80-/-Cd86-/- and Cd40-/- APCs was reconstituted by added C5a or C3a. C5aR and C3aR mediated their effects via PI-3 kinase-gamma-dependent AKT phosphorylation, providing a link between GPCR signaling, CD28 costimulation, and T cell survival. These local paracrine and autocrine interactions thus operate constitutively in naive T cells to maintain viability, and their amplification by cognate APC partners thus is critical to T cell costimulation.     

Cell-cell interactions for CD23 expression and soluble CD23 release from peripheral lymphocytes of atopic donors.

The cell-cell interactions for CD23 expression and soluble (s)CD23 release from peripheral blood lymphocytes (PBL), as well as purified cells (B, T cells, monocytes) of atopic donors, were studied. Cells either stimulated combined and subsequently separated or stimulated after separation were analysed. IL-4, IL-2, phytohaemagglutinin (PHA), interferon-gamma (IFN-gamma) and the combined interaction of IL-4 and IFN-gamma as well as PHA and IFN-gamma were used as stimuli. sCD23 release in the cell supernatant was determined from cells separated before stimulation. CD23 expression induced by IL-4 on cells stimulated and subsequently separated was significantly lower compared with amounts on separated cells which were subsequently stimulated. Major expression of CD23 was obtained on B cells and monocytes. Stimulation with PHA led to an increased expression on T cells compared to the control. When cells were stimulated, combined and separated, the combined stimuli of IL-4 and IFN-gamma showed a reduced CD23 expression for both experimental procedures and an enhanced release of sCD23. The data suggest an important role for cell-cell interactions. These results were supported by experiments in which separated cells were either co-cultured or cultured in Transwells. Co-culture of T cells with B cells and monocytes suggested that T cells are responsible for suppressed CD23 expression. No or only slight enhancement was obtained for sCD23 release. Our data indicate that cell-cell interactions and cytokines regulate CD23 expression, while sCD23 release is apparently solely regulated by soluble mediators (e.g. cytokines).     

The immunological synapse

The immunological synapse plays a central role in organising the immune system. Through their synaptic activity both T and B cells usually, but not always, acquire the information that critically determines the level and nature of the responses that they make. For T cells much of that information comes from epicrine and paracrine cell-cell interactions in the cluster that forms around a dendritic cell. These interactions are being dissected by experiments in which two populations of TCR-transgenic T cells are combined in vivo. Another important aspect of synaptic activity is the way in which different levels of expression of MHC class II molecules influence Th1/Th2 balance. In exploring this form of control we are learning something of general importance about cis-regulation.     

The regulatory, inflammatory, and T cell programming roles of interleukin-2 (IL-2)

Signaling through IL-2 induces the activation of pathways that lead to the proliferation, survival and cytokine production of effector T cells. However, through negative feedback mechanisms, internalization of the IL-2 receptor, induction of activation-induced cell death, and the generation of regulatory T cells, IL-2 also promotes the suppression of inflammatory responses. In regulatory T cells, IL-2 signaling upregulates the expression of FoxP3. Regulatory T cell induction by TGF-beta also requires IL-2. Additionally, pro-inflammatory and pro-survival pathways involving PI3K upon IL-2 stimulation is inhibited by PTEN in regulatory T cells. Importantly, IL-2 signaling is key for the development, expansion and maintenance of regulatory T cells. However, gamma(c) cytokines can replace requirements for IL-2 in regulatory T cells, although not with the same efficacy. The dual roles of IL-2 in inflammation are demonstrated in that mice deficient in both FoxP3 and IL-2 display less severe symptoms compared to FoxP3 deficient mice. Finally, IL-2 not only plays a key role in the induction of effector T cells and regulatory T cells, it also inhibits IL-17 producing T cells. By understanding complex dynamics of IL-2 interactions in the inflammatory response, therapies may be developed or modified for regulating immune related diseases.     

Influence of a mutation in IFN-γ receptor 2 (IFNGR2) in human cells on the generation of Th17 cells in memory T cells

The T cell subsets involved in inflammatory reactions are mainly the IFN-γ secreting Th1 cells and IL17-producing Th17 cells. Although Th17 cells are primed in the thymus, there is evidence that Th17 cells can be generated from effector memory CD4⁺ T cells. Cytokines as IL-6, TGF-β, IL-21 and IL-23 involved in development of Th17 cells are well described. Here we analyzed the impact of a mutation in the IFN-γ receptor 2 (IFN-γR2) on the induction of Th17 cells. By isolation of T cells and monocytes of a patient with this mutation we could demonstrate an inhibitory role of IFN-γ signaling as IFN-γR2-deficient monocytes induce a higher percentage of IL-17⁺ cells from both healthy and IFN-γR2-deficient CD4⁺ T cells. This data confirm the interference of these two T helper subsets and points to a balance of Th1 and Th17 cells obtained by their own cytokine production and their interplay with APCs.