Following the exposition to the cell surface of “cryptic” antigens, the appearance of a wide spectrum of new peptides can therefore induce an “acquired cell recognition of new self-determinants” by the antigen-presenting cells (APC), playing a crucial role not only in the arising but also mainly in the progression of the ITP (62). These cells in normal conditions play the primary function of recognizing, binding to and internalizing protein antigens for endosomal proteolytic degradation. After these peptides complexed with MHC molecules are presented to T cells in conjunction with signaling costimulatory events (i.e., CD28/B7 and CD80/86 interactions between APC and T cell), and in the presence of appropriate cytokines, the T cell become properly activated (44). The local microenvironment and extrinsic stimuli can influence APC phenotype and function; in certain conditions, such as inflammation, APC abnormalities, in number and function, lead to abnormal processing or presentation of self antigens or inappropriate T cell activation. Dendritic cells, even referred as professional APC, are the most specialized among all leukocytes in the presentation of antigen. Peripheral blood DCs are classified in two broad groups according to their lineage, myeloid DCs (mDCs), often referred as conventional DCs, and plasmacytoid DCs (pDCs) (63). The mDC subset plays specific functions in the initiation of adaptive immune response, being critical for the activation of effector T cells and differentiation of naive CD4⁺ T cells into Th1 cells. The pDCs produce high levels of type I interferon (IFN-α/β/ω), reflecting their important function in antiviral immune responses (1, 63–65). The type I IFN is a pleiotropic cytokine not only with antiviral properties but also with capability to regulate pDC survival, mDC differentiation, mDC-mediated cytotoxic T cell responses, cross presentation, upregulation of costimulatory MHC molecules, and activation of natural killer (NK) and B cells (63, 66–69). Plasmacytoid DCs also display pro-inflammatory and immunosuppressive tolerogenic properties (70). Recently, low number of circulating pDCs has been shown in untreated patients with ITP (65). These authors explained this result as an abnormality of their distribution and suggested that pDCs could be mobilized into peripheral inflamed tissues, particularly to the spleen. Together with the pDC number alteration, also the dysfunction of DCs has been demonstrated to contribute to the development of ITP (71). In experiments performed by pulsing DCs from ITP patients and healthy donors, with autologous/allogeneic fresh and aged platelets, Catani et al. (71) showed that the DCs from patients stimulated T-cell proliferation in a greater degree than those one from healthy donors. They concluded that this might be due to an increased expression of the costimulatory antigen CD86 on the surface of DC patients (71). The importance of the ITP dysregulation of the APC-T cell cross talk has been reported by Zhong et al. (72).

Cytotoxic T lymphocytes (CTLs) are cells able to kill neoplastic or infected cells with bacteria or viruses by programing these cells to undergo apoptosis (73). In ITP patients, with no identifiable anti-platelets autoantibodies, CTLs have been shown to increase both platelet and MK lysis, suggesting the role of these cells in mediating thrombocytopenia (31, 32, 74–76). Apoptosis and perforin/granzyme-mediated cytotoxicity constitute the main pathway used by CTLs to destruct autologous platelets (75). A variety of T cell and cytokine abnormalities have been observed in patients with ITP, suggesting that T cell-mediated peripheral platelet destruction and MK destruction/inhibition could be involved in the pathogenetic mechanism of thrombocytopenia (26, 27, 31, 44, 77–79). Interleukin-27 (IL-27), a member of IL-12 family, is a cytokine with multiple immunomodulatory functions, showing both pro-inflammatory and anti-inflammatory effects (80). Liu et al. demonstrated low plasma and mRNA expression levels of IL27 in active ITP patients, suggesting that this cytokine might be involved in the pathogenesis of ITP (81). Recent data suggested that IL-27 could inhibit platelet destruction by negatively regulating CTL cytotoxicity toward autologous platelets in ITP (80); this negative regulation was obtained by decreasing granzyme B expression whereas granzyme A and perforin were not affected (80). Based on these experiments, it has been suggested that IL-27 might have a therapeutic role in ITP patients (80). Thus, in addition to platelet-specific autoantibodies, also CTLs and aberrant cytokine profiles can be involved in platelet destruction, playing important role in the pathogenesis of ITP (73, 80).

T follicular helper cells are the specialized providers of B cell help; they are the key cell type required for the formation of germinal centers (GCs) and the generation of long-lived serological memory. TFHs have emerged to play a key role in regulating the humoral immune response that occurs with autoimmune diseases, infectious diseases, and tumors (82). TFHs are characterized by low expression levels of cytokines, IFN-γ, IL-4, and IL-17, characteristic of Th1, Th2, and Th17 cells respectively and by the expression of effector molecules that are critical for their development and function, including chemokine receptor 5 (CXCR5), inducible costimulator (ICOS), programed death-1 (PD-1), surface receptors of IL-21, IL-6, CD40, and transcription factors Bcl-6 and c-Maf (2, 83). It has been demonstrated that human splenic TFHs are the main producers of interleukin IL-21 (2), a cytokine playing a critical role in T cell and B cell homeostasis. In B cells, IL-21 signaling is involved in germinal center formation, Ig-secreting B cells, and antibody response (83, 84), while in CD4 T cells, it promotes the development of Th17 and TFHs themselves (83–85).

In ITP patients, splenic TFH frequency is higher than healthy donors and correlates with germinal center and plasma cell percentages that are also increased (2). Although the role of the inflammatory environment in the increase in TFH frequency could not be completely excluded, Audia et al. (2) strongly suggested that the expansion of TFHs could be involved in B-cell recruitment and differentiation in the spleen of ITP patients, through IL-21 secretion and by the interaction of CD154 with CD40, contributing to the development of plasma cells producing antiplatelet autoantibodies. Therefore, TFHs and associated molecules, such as IL-21 and CD40, could be new promising therapeutic targets for ITP patients.

Immune homeostasis is maintained via a balance of two types of responses, defined by cytokine secretion profiles. The responses of type 1, characterized primarily by IL2, IFNγ, TNFα, and TNFβ1 production, are involved in response to intracellular pathogens and generally promote pro-inflammatory, cell-mediated, complement fixing phenotypes. On the other hand, type 2 reactions, characterized by IL4, IL5, IL6, IL10, and IL13 cytokine production, function in the fight against extracellular pathogens, and typically elicit an immediate-type hypersensitivity response (43). The polarization of the immune system toward either type 1 or type 2 immunity is dependent on the level of the cytokines. In ITP, type 1/type 2 ratio is unbalanced, shifted toward a type 1 phenotype, favoring autoreactive B cell development (a Th2 phenotype being observed in patients during remission or during intravenous immunoglobulin treatment) (1, 43, 86, 87). This has been attributed to the reduction of peripheral Th2 cells, of Tc2 cells and of CD25^brightFoxp3⁺ Tregs either in number or in function (30, 43, 87–90). Zhong et al. (72) showed that the CD16⁺ monocyte subset from the peripheral blood of chronic ITP promoted the expansion of the Th1 subset via IL12 secretion, while inhibited the proliferation of Th17 cells and the induction of Tregs. The Th1/Th2 balance in ITP is showed in Figure 4.

Tregs are a subpopulation of T cells specialized in immune suppression and contribute to the maintenance of peripheral immune tolerance; their defects are thought to play a role in the pathogenesis of various autoimmune diseases (91). In the last decade, data from numerous studies have demonstrated a dysregulation of Treg cell population in ITP (29, 30, 91–102). Treg deficiency was reported in both adults and children with ITP (91): the lowest Treg frequency was detected in patients with acute phase of the disease and/or with low platelet count, while Tregs increase was observed in remission phase. Interestingly, a failure of the cross communication between DCs and Tregs in patients with ITP has been reported (103). These authors showed that the decreased expression and/or activity of the immunomodulatory enzyme indoelamine 2,3-dioxygenase 1 (IDO1) by DCs, contributed to the reduced conversion from T cells into Tregs, suggesting the importance of the cross talk between DCs and the adaptative immune system in the pathophysiology of immune thrombocytopenia (103). T cell-related pro-inflammatory cytokines may play a pivotal role in immune dysregulation during active ITP. In the past years, increased levels of macrophage colony-stimulating factor (M-CSF) (causing a stimulus for to the platelet antigen presentation by macrophages to T cells), reduced levels of transforming growth factor (TGF)-β production have been described in children with chronic ITP (104). IL10 is a cytokine with anti-inflammatory properties; initially described as a product of Th2 cells able to inhibit cytokine synthesis of Th1 cells (105), IL-10 is now known to be produced by many different types of cells, including Tregs (106). Based on data showing that IL10 producing Tregs contributed to the effective control of several autoimmune diseases (107), a recent study investigated the role of this cytokine in newly diagnosed ITP patients (106). The Authors identified a numerical and functional defect of Tregs associated with an excessive activation T effector cells, suggesting that the assessed insufficient secretion of IL-10 could compromise the inhibitory capability of Tregs against T effectors cells and play a major role in the exuberant CD4⁺ T cell immune response of ITP (106). More attention has been deserved to IL17, a cytokine produced by Th17 cells, a newly defined CD4⁺ Th subset; Th17 cells modulate the pro-inflammatory response by producing, as well as IL17, also IL6, IL21, tumor necrosis factor (TNF), and other mediators (108–110). Thus, while Treg cells play a fundamental role in the maintenance of immune tolerance to prevent autoimmune disease, Th17 cells play the opposite role. Indeed, it has been demonstrated that Th17 cells are more potent than Th1 cells in inducing autoimmune disorders (111–113). Several reports support a role for IL17 in the pathogenesis of ITP. Rocha et al. (110) suggested that increased levels of IL17 and of Th17-related cytokines found in adult patients with chronic ITP might contribute to the disease pathogenesis. The Treg/Th17 imbalance has been found associated with disease activity among adult ITP patients, implying an association between Th17 cell elevation and the development of ITP and suggesting a prognostic role of this cytokine (114). Wang et al. (115) found that IL17 levels were elevated in pediatric patients with chronic ITP and positively correlated with INFγ expression, suggesting that both Th17 and Th1 might be simultaneously involved in the dysregulation of cellular immunity observed in pediatric patients. However, other groups did not report significant differences either in the serum levels or in the expression of IL17 on peripheral blood mononuclear cells between ITP patients and normal controls (116, 117), arguing that IL17 might not play an important role in the pathogenesis of adult patients with chronic ITP. These conflicting results concerning the IL17 role underline the variability in the clinical phenotype and evolution of the disease duration among the ITP population. The IL23/IL17 axis is critical for the development of inflammatory diseases. IL23, which is mainly secreted by APCs, is the pivotal mediator responsible for the differentiation of naive CD4+ T cells into Th17 cells; the importance of the IL23 cytokine and of its receptor in both Th17 maturation and function has been demonstrated (113, 118, 119). Several studies reported that the IL23/Th17 pathway was strongly involved in the pathogenesis of many autoimmune diseases, such as rheumatoid arthritis (120), multiple sclerosis (121), primary biliary cirrhosis (122), and inflammatory bowel disease (123). However, less is known with regard to the levels of expression and synthesis of these two cytokines in patients with ITP. The role of IL23/Th17 pathway in adult ITP patients has been recently investigated (113). These Authors, found higher levels of IL17 and IL23 in patients with ITP than in controls and a decrease of both cytokines after effective treatment, suggesting that IL23 was engaged in the development of ITP through enhancement of the Th17 response.

Interestingly, Bregs are a distinct B cell population with potent immunoregulatory properties; among them, the most well subset characterized is the IL10-producing subset (B10 cells) (1, 124, 125), which plays an important role in autoimmune diseases (1, 87, 126, 127). Recent findings showed that IL10 produced by B10 cells is required in combination with different costimulatory molecules for the differentiation and maintenance of Tregs and for inhibition of Th17 cells (87, 128, 129). Recently, it has been demonstrated that a dysregulation of Breg compartment was an additional defect in the immune network in ITP patients (1, 87). Hua et al. (87) demonstrated that the number of B10 cells positively correlated with both Treg count and Treg/Th17 ratio, suggesting that the ability of these cells to regulate functional T cell subsets might be impaired in ITP patients.