Differential expression and function of human IL-12Rß2 polymorphic variants.

The receptor for interleukin-12, formed by IL-12Rß1 and IL-12Rß2, mediates the type I immune responses of various types of lymphocytes. Polymorphisms in IL12RB2, the gene encoding IL-12Rß2, were reported to be associated with several immune related diseases, such as Crohn's disease. Because the IL23R and IL12RB2 genes are located in close proximity on the genome, the reported associations might also be attributable to linked polymorphisms in IL23R, which were found to be associated with immune related diseases as well. To clarify the role of IL-12Rß2 in immune diseases, we investigated the functional consequences of thirteen amino acid substitutions in IL-12Rß2. We developed a model with retroviral expression of IL-12Rß2 in B cell lines. With the use of this model the expression and function of the variants was compared within the same genetic background. Four of the IL-12Rß2 variants, N271Y, R313G, A604V and L808R showed reduced IL-12 responses compared to the wild type variant. Two of these are relatively common in some populations and may be used in future association studies to reveal a role for IL-12 in infectious and/or immune related diseases.

IL-12 receptor ß1 deficiency alters in vivo T follicular helper cell response in humans.

Antibody responses represent a key immune protection mechanism. T follicular helper (Tfh) cells are the major CD4(+) T-cell subset that provides help to B cells to generate an antibody response. Tfh cells together with B cells form germinal centers (GCs), the site where high-affinity B cells are selected and differentiate into either memory B cells or long-lived plasma cells. We show here that interleukin-12 receptor ß1 (IL-12Rß1)-mediated signaling is important for in vivo Tfh response in humans. Although not prone to B cell-deficient-associated infections, subjects lacking functional IL-12Rß1, a receptor for IL-12 and IL-23, displayed substantially less circulating memory Tfh and memory B cells than control subjects. GC formation in lymph nodes was also impaired in IL-12Rß1-deficient subjects. Consistently, the avidity of tetanus toxoid-specific serum antibodies was substantially lower in these subjects than in age-matched controls. Tfh cells in tonsils from control individuals displayed the active form of signal transducer and activator of transcription 4 (STAT4), demonstrating that IL-12 is also acting on Tfh cells in GCs. Thus, our study shows that the IL-12-STAT4 axis is associated with the development and the functions of Tfh cells in vivo in humans.

IL-12Rß2 is critical for survival of primary Francisella tularensis LVS infection.

Using a panel of vaccines that provided different degrees of protection, we previously identified the IL-12 receptor subunit ß2 as a mediator, whose relative expression correlated with strength of protection against secondary lethal challenge of vaccinated mice with an intracellular bacterium, the LVS of Francisella tularensis. The present study therefore tested the hypothesis that IL-12Rß2 is an important mediator in resistance to LVS by directly examining its role during infections. IL-12Rß2 KO mice were highly susceptible to LVS primary infection, administered i.d. or i.n. The LD50 of LVS infection of KO mice were 2 logs lower than those of WT mice, regardless of route. Five days after infection with LVS, bacterial organ burdens were significantly higher in IL-12Rß2 KO mice. IL-12Rß2 KO mice infected with lethal doses of LVS had more severe liver pathology, including significant increases in the liver enzymes ALT and AST. Despite decreased levels of IFN-γ, LVS-vaccinated IL-12Rß2 KO mice survived large lethal LVS secondary challenge. Consistent with in vivo protection, in vitro intramacrophage LVS growth was well-controlled in cocultures containing WT or IL-12Rß2 KO LVS-immune splenocytes. Thus, survival of secondary LVS challenge was not strictly dependent on IL-12Rß2. However, IL-12Rß2 is important in parenteral and mucosal host resistance to primary LVS infection and in the ability of WT mice to clear LVS infection and serves to restrict liver damage.

Activation mechanisms of natural killer cells during influenza virus infection.

During early viral infection, activation of natural killer (NK) cells elicits the effector functions of target cell lysis and cytokine production. However, the cellular and molecular mechanisms leading to NK cell activation during viral infections are incompletely understood. In this study, using a model of acute viral infection, we investigated the mechanisms controlling cytotoxic activity and cytokine production in response to influenza (flu) virus. Analysis of cytokine receptor deficient mice demonstrated that type I interferons (IFNs), but not IL-12 or IL-18, were critical for the NK cell expression of both IFN-γ and granzyme B in response to flu infection. Further, adoptive transfer experiments revealed that NK cell activation was mediated by type I IFNs acting directly on NK cells. Analysis of signal transduction molecules showed that during flu infection, STAT1 activation in NK cells was completely dependent on direct type I IFN signaling, whereas STAT4 activation was only partially dependent. In addition, granzyme B induction in NK cells was mediated by signaling primarily through STAT1, but not STAT4, while IFN-γ production was mediated by signaling through STAT4, but not STAT1. Therefore, our findings demonstrate the importance of direct action of type I IFNs on NK cells to mount effective NK cell responses in the context of flu infection and delineate NK cell signaling pathways responsible for controlling cytotoxic activity and cytokine production.

Epigenetic changes at Il12rb2 and Tbx21 in relation to plasticity behavior of Th17 cells.

Plasticity within Th cell populations may play a role in enabling site-specific immune responses to infections while limiting tissue destruction. Epigenetic processes are fundamental to such plasticity; however, to date, most investigations have focused on in vitro-generated T cells. In this study, we have examined the molecular mechanisms underpinning murine Th17 plasticity in vivo by assessing H3K4 and H3K27 trimethylation marks at Tbx21, Rorc, Il17a, Ifng, and Il12rb2 loci in purified ex vivo-isolated and in vitro-generated Th17 cells. Although both populations had largely comparable epigenetic signatures, including bivalent marks at Tbx21, freshly isolated ex vivo Th17 cells displayed restricted expression from Il12rb2 due to the presence of repressive chromatin modifications. This receptor, however, could be upregulated on isolated ex vivo Th17 cells after in vitro activation or by in vivo immunization and was augmented by the presence of IFN-γ. Such activated cells could then be deviated toward a Th1-like profile. We show that IL-12 stimulation removes H3K27 trimethylation modifications at Tbx21/T-bet leading to enhanced T-bet expression with in vitro Th17 cells. Our study reveals important potential phenotypic differences between ex vivo- and in vitro-generated Th17 cells and provides mechanistic insight into Th17 cell plasticity.

IL-12p35 promotes antibody-induced joint inflammation by activating NKT cells and suppressing TGF-beta.

The functional role of IL-12 in rheumatoid arthritis is controversial. Moreover, whether IL-12 contributes to regulation of Ab-induced joint inflammation remains unclear. To address these issues, we explored the functional roles of IL-12 in Ab-induced arthritis using the K/BxN serum transfer model. IL-12p35(-/-) and IL-12Rbeta(2)(-/-) mice were resistant to the development of arthritis. Injection of K/BxN serum into IL-12p40-yellow fluorescence protein reporter (yet40) mice induced CD11b(+) cells, CD11c(+) cells, and Gr-1(+) granulocytes to produce IL-12p40 in the joints. The levels of IFN-gamma, IL-4, and IL-6 production were lower in joint tissues of IL-12p35(-/-) and IL-12Rbeta(2)(-/-) mice than in B6 mice, whereas levels of TGF-beta expression were higher. Administering IL-12p35(-/-) mice rIL-12 or IFN-gamma restored joint inflammation and suppressed TGF-beta production in joint tissues. Moreover, administering neutralizing anti-TGF-beta mAb enhanced joint inflammation. Among the immune cells that infiltrated joint tissues during Ab-induced arthritis, NKT cells expressed IL-12beta(2) receptors. Furthermore, the adoptive transfer of splenocytes from B6 or Gr-1(+) granulocyte-depleted mice restored joint inflammation in IL-12Rbeta(2)(-/-) mice as much as in B6 mice, whereas splenocytes from Jalpha18(-/-) mice did not. These findings indicate that signals via IL-12beta(2) receptors on NKT cells play a critical role in the development of Ab-induced arthritis. The IL-12p35/IFN-gamma axis promotes Ab-induced joint inflammation by activating NKT cells and suppressing TGF-beta, which may provide novel information for the development of new therapeutic strategies for the inhibition of rheumatoid arthritis.

Suppression of regulatory T cells by IL-12p40 homodimer via nitric oxide.

Regulatory T cells (Tregs) play a pivotal role in the maintenance of homeostasis between immune response and immune tolerance. The transcription factor Foxp3 and the surface protein CD25 are the two key molecules characterizing Tregs. In autoimmune and various other chronic inflammatory diseases, the expression of Foxp3 is severely down-regulated. However, the molecular mechanism underlying the down-regulation of Foxp3 is not understood yet. Because the IL-12p40 homodimer (p40(2)) is markedly up-regulated in response to various inflammatory stimuli, the present study was undertaken to explore the role of p40(2) in the regulation of Foxp3 in naive mouse splenocytes. IL-12p40(2) dose-dependently inhibited the expression of Foxp3 and CD25, but not CD4. Interestingly, this inhibition was absent in splenocytes of IL-12Rbeta1(-/-), but not IL-12Rbeta2(-/-), mice. Moreover, suppression of Foxp3 in wild-type and IL-12Rbeta2(-/-) splenocytes was accompanied by production of NO. Consistently, l-N(6)-(1-iminoethyl)-lysine hydrochloride, an inhibitor of inducible NO synthase (iNOS), and PTIO, a scavenger of NO, restored the expression of Foxp3 and CD25 in p40(2)-stimulated splenocytes, and p40(2) was unable to down-regulate Foxp3 and CD25 in splenocytes from iNOS(-/-) mice. Furthermore, NO, but not p40(2), was able to inhibit Foxp3 in purified CD4(+)CD25(+) T cells in the absence of iNOS-expressing cells. Hence, our results clearly demonstrate that p40(2) induces NO production via IL-12Rbeta1 and that NO subsequently suppresses Tregs in naive mouse splenocytes. This study, therefore, delineates an unprecedented biological function of p40(2) in the regulation of Foxp3 via IL-12Rbeta1-mediated NO production.

IL-12R beta 2 promotes the development of CD4+CD25+ regulatory T cells.

We have previously shown that mice lacking the IL-12-specific receptor subunit beta2 (IL-12Rbeta2) develop more severe experimental autoimmune encephalomyelitis than wild-type (WT) mice. The mechanism underlying this phenomenon is not known; nor is it known whether deficiency of IL-12Rbeta2 impacts other autoimmune disorders similarly. In the present study we demonstrate that IL-12Rbeta2(-/-) mice develop earlier onset and more severe disease in the streptozotocin-induced model of diabetes, indicating predisposition of IL-12Rbeta2-deficient mice to autoimmune diseases. T cells from IL-12Rbeta2(-/-) mice exhibited significantly higher proliferative responses upon TCR stimulation. The numbers of naturally occurring CD25(+)CD4(+) regulatory T cells (Tregs) in the thymus and spleen of IL-12Rbeta2(-/-) mice were comparable to those of WT mice. However, IL-12Rbeta2(-/-) mice exhibited a significantly reduced capacity to develop Tregs upon stimulation with TGF-beta, as shown by significantly lower numbers of CD25(+)CD4(+) T cells that expressed Foxp3. Functionally, CD25(+)CD4(+) Tregs derived from IL-12Rbeta2(-/-) mice were less efficient than those from WT mice in suppressing effector T cells. The role of IL-12Rbeta2 in the induction of Tregs was confirmed using small interfering RNA. These findings suggest that signaling via IL-12Rbeta2 regulates both the number and functional maturity of Treg cells, which indicates a novel mechanism underlying the regulation of autoimmune diseases by the IL-12 pathway.

IL-23 and IL-12 responses in activated human T cells retrovirally transduced with IL-23 receptor variants.

Interleukin-23 (IL-23) is a regulator of cellular immune responses involved in controlling infections and autoimmune diseases. Effects of IL-23 on T cells are mediated via a receptor complex consisting of an IL-12Rbeta1 and a specific IL-23R chain. The R381Q and P310L variants of the IL-23R were recently reported to be associated with autoimmune diseases, suggesting they have an effect on IL-23R function. To investigate this matter, these variants and a newly identified variant, Y173H, were retrovirally transduced into human T cell blasts and functionally characterized by measuring the IL-23-induced signal transduction pathway (i.e., STAT1, STAT3 and STAT4 phosphorylation), and IFN-gamma and IL-10 production. No differences were detected between the genetic variants and wild-type in the function of the IL-23R-chain. Furthermore, while comparing IFN-gamma and IL-10 production in response to IL-23 and IL-12, we found IL-23 to be a more potent IL-10 inducer, and IL-12 a more potent IFN-gamma inducer. In addition, IL-23 also exerted a minor IL-12-like effect by inducing IL-23R-independent, IL-12Rbeta1-dependent STAT4 phosphorylation and IFN-gamma production. In conclusion, the reported association between R381Q and P310L variants of the IL-23R and autoimmune diseases does not depend on differences in functional activity between wild-type and R381Q and P310L variants of the IL-23R.

The contribution of transcription factor IRF1 to the interferon-gamma-interleukin 12 signaling axis and TH1 versus TH-17 differentiation of CD4+ T cells.

Interleukin-12 (IL-12) and interferon-gamma (IFN-gamma) drive T helper type 1 (T(H)1) differentiation, but the mechanisms underlying the regulation of the complicated gene networks involved in this differentiation are not fully understood. Here we show that the IFN-gamma-induced transcription factor IRF1 was essential in T(H)1 differentiation by acting on Il12rb1, the gene encoding the IL-12 receptor beta1 subunit (IL-12Rbeta1). IRF1 directly interacted with and activated the Il12rb1 promoter in CD4+ T cells. Notably, the IRF1-dependent induction of IL-12Rbeta1 was essential for IFN-gamma-IL-12 signaling but was dispensable for IL-23-IL-17 signaling. Because both IL-12 and IL-23 bind to and transmit signals through IL-12Rbeta1, our data suggest that distinct thresholds of IL-12Rbeta1 expression are required for T(H)1 versus T(H)-17 differentiation.

The interleukin-12 family: new players in transplantation immunity?

Since several years ago, interleukin (IL)-12 is known to be responsible for the differentiation of naive CD4+ T cells into type 1 helper T cells producing interferon-gamma. Recently, two other cytokines of the IL-12 family, IL-23 and IL-27, were shown to play key roles in experimental autoimmune disorders mediated by Th17 cells, a novel pro-inflammatory CD4+ T-cell subset secreting IL-17. As our knowledge of IL-12 family members is rapidly growing and changing, it will be important to specify their involvement in the induction and regulation of allograft rejection in animal models as well as in clinical settings. Herein, we review key features of cytokines belonging to the IL-12 family and discuss their potential relevance to transplantation immunity.