• We are sorry, but NCBI web applications do not support your browser and may not function properly. More information
Logo of jexpmedHomeThe Rockefeller University PressThis articleEditorsContactInstructions for AuthorsThis issue
J Exp Med. Oct 30, 2006; 203(11): 2485–2494.
PMCID: PMC2118119
Article

IL-23 plays a key role in Helicobacter hepaticus–induced T cell–dependent colitis

Abstract

Inflammatory bowel disease (IBD) is a chronic inflammatory disorder of the gastrointestinal tract that is caused in part by a dysregulated immune response to the intestinal flora. The common interleukin (IL)-12/IL-23p40 subunit is thought to be critical for the pathogenesis of IBD. We have analyzed the role of IL-12 versus IL-23 in two models of Helicobacter hepaticus–triggered T cell–dependent colitis, one involving anti–IL-10R monoclonal antibody treatment of infected T cell–sufficient hosts, and the other involving CD4+ T cell transfer into infected Rag−/− recipients. Our data demonstrate that IL-23 and not IL-12 is essential for the development of maximal intestinal disease. Although IL-23 has been implicated in the differentiation of IL-17–producing CD4+ T cells that alone are sufficient to induce autoimmune tissue reactivity, our results instead support a model in which IL-23 drives both interferon γ and IL-17 responses that together synergize to trigger severe intestinal inflammation.

The heterodimeric cytokine IL-12 plays a key role in host defense against intracellular microbes by inducing NK cell IFN-γ production and by favoring the differentiation of IFN-γ–secreting CD4+ Th1 cells (1). IL-12 has also been implicated in chronic inflammatory disorders characterized by excessive Th1 responses. Recently, IL-23 was identified as a new member of the IL-12 cytokine family secreted by activated DCs and macrophages (2). Because of the shared p40 subunit between IL-12 (p40/p35) and IL-23 (p40/p19), early experiments that used anti-p40 mAb to neutralize IL-12 in vivo have had to be reevaluated. With the use of new tools, including p19-deficient mice, several autoimmune and chronic inflammatory diseases previously believed to be caused by IL-12 and Th1 responses have now indeed been shown to depend on IL-23, and not IL-12. Among such diseases are experimental autoimmune encephalomyelitis (EAE) that affects the central nervous system (3, 4) and collagen-induced arthritis (CIA) of the joints (5).

The precise mechanism(s) by which IL-23 contributes to inflammation is currently unknown. The IL-23 receptor, which is composed of IL-12Rβ1 combined with the IL-23R subunit (6), is expressed on activated and memory T cells, NK cells, DCs, and inflammatory macrophages and microglia (2, 3, 6). IL-23 was originally described to induce the proliferation and secretion of IL-17 (IL-17A)/IL-17F by CD4+ T cells with an activated or memory phenotype (2, 7), and such IL-23–driven IL-17+ CD4+ T cells were subsequently shown to be highly potent inducers of immune pathology in EAE (4). Recent studies have established that IL-17+ CD4+ T cells represent a novel subset of Th cells (Th17 cells) that in addition to IL-17/IL-17F also produces IL-6 and TNF-α (4, 8, 9). Binding of IL-17 and/or IL-17F to receptors on myeloid and endothelial cells promotes the expression of IL-1, IL-6, IL-8, TNF, and chemokines that are involved in mobilizing neutrophils and in driving chronic inflammation (3, 10).

Inflammatory bowel disease (IBD), comprising Crohn's disease and ulcerative colitis, is a chronic inflammatory disorder of the gastrointestinal tract that is caused in part by a dysregulated immune response to the intestinal flora. Levels of IL-12 and IL-23 have been shown to be increased in inflamed intestinal tissues (1114), and anti-p40 mAb treatment has proven beneficial in Crohn's disease as well as in experimental models of intestinal inflammation (1519). However, little information is currently available on the relative contribution of IL-12 versus IL-23 in IBD pathogenesis.

We previously established a new model of bacterial-induced colitis involving infection of specific pathogen-free IL-10−/− mice with Helicobacter hepaticus (20, 21). The disease that develops in H. hepaticus–infected (Hh+) IL-10−/− animals is associated with a Th1 response to the bacterium, and treatment from the start of the infection with anti-p40 mAb abrogates the development of intestinal inflammation (20). Furthermore, mice rendered double deficient for both IL-10 and p40 are resistant to H. hepaticus–induced colitis, together demonstrating a crucial role for p40 in disease pathogenesis (21).

In this study, we have investigated the role of IL-12 versus IL-23 in two bacterially driven T cell–dependent colitis models. Using a novel model of colitis involving anti–IL-10R treatment of Hh+ WT mice, as well as our previously established H. hepaticus CD4 T cell adoptive transfer model (22), we demonstrate that IL-23 and not IL-12 is essential to trigger intestinal inflammation. Unexpectedly, although IL-23 has been implicated in the induction of pathogenic IL-17–producing T cells in EAE (4), in our model IL-17 in the absence of IFN-γ does not appear to be sufficient to induce maximal colitis. Instead, our results support a model in which maximal intestinal inflammation depends on the function of both IFN-γ and IL-17.

RESULTS

Anti–IL-10R treatment leads to severe intestinal inflammation in Hh+ WT and IL-12p35−/− mice

Using a T cell transfer model of colitis triggered by adoptive transfer of CD4+ T cells into Hh+ Rag−/− recipients, we previously described the appearance of disease-protective CD4+ IL-10–secreting T regulatory cells after H. hepaticus infection of WT animals (22). Here we demonstrate that the CD4-mediated T regulatory cell mechanism revealed in the Rag−/− transfer model also functions in intact Hh+ WT hosts, as treatment of these animals with anti–IL-10R, but not a control mAb, led to the development of typhlocolitis similar to that seen in Hh+ IL-10−/− mice (Figs. 1, A and B, and 2, A, B, F, and G). Uninfected WT mice given anti–IL-10R did not develop intestinal inflammation (not depicted), demonstrating that the endogenous flora by itself was not sufficient to induce colitis, but that H. hepaticus was required for disease initiation.

Figure 1.
H. hepaticus infection plus anti–IL-10R mAb treatment leads to severe typhlocolitis in WT and p35−/− mice but reduced inflammation in the ascending colon of IFN-γ−/− animals. B6 WT, p40−/− ...
Figure 2.
Intestinal pathology in anti–IL-10R–treated Hh+ T cell–sufficient mice. B6 WT, p40−/−, p35−/−, and IFN-γ−/− mice were infected with H. hepaticus and treated with control ...

In agreement with our earlier findings of a critical role for p40 in colitis induction (20, 21), Hh+ p40−/− mice treated with anti–IL-10R failed to develop typhlocolitis (Figs. 1, A and B, and 2, C and H). Importantly however, anti–IL-10R–treated Hh+ p35−/− mice, which lack the ability to produce IL-12, developed intestinal inflammation comparable to that seen in anti–IL-10R–treated Hh+ WT mice (Figs. 1, A and B, and 2, D and I). Collectively, these findings demonstrate that although the IL-12p40 subunit is essential for colitis development, IL-12 in itself is dispensable for disease pathogenesis.

To investigate the role of IFN-γ, mice deficient in this cytokine were infected with H. hepaticus and treated with anti–IL-10R. Although the degree of cecal inflammation was comparable to that observed in colitic Hh+ WT and p35−/− animals (Figs. 1 A and 2 E), IL-10R blockade led to only a mild inflammatory response in the colon of Hh+ IFN-γ−/− animals (Figs. 1 B and 2 J), suggesting a role for IFN-γ in exacerbating disease at this site. This conclusion was supported by similar findings in an adoptive transfer model (see below), emphasizing a role for IFN-γ in promoting colonic inflammation.

H. hepaticus–specific IFN-γ and IL-17 responses are elevated in colitic mice

To examine H. hepaticus–specific T cell cytokine responses, mesenteric lymph node (MLN) cells were stimulated in vitro with soluble H. hepaticus antigen (SHelAg) and levels of IFN-γ and IL-17 were measured. After bacterial antigen stimulation, MLN cells from Hh+ IL-10−/− mice mounted a strong IFN-γ response and secreted substantial amounts of IL-17, whereas MLN cells from Hh+ WT mice given control mAb failed to produce these cytokines (Fig. 1, C and D). Similarly, no IFN-γ or IL-17 was detected in SHelAg-stimulated MLN cultures from control mAb–treated Hh+ p40−/−, p35−/−, or IFN-γ−/− mice. In contrast, MLN cells from anti–IL-10R–treated Hh+ WT mice secreted elevated amounts of both IFN-γ and IL-17 in response to SHelAg (Fig. 1, C and D). Interestingly, a similar picture was seen for anti–IL-10R–treated Hh+ p35−/− mice, with a significant IFN-γ response and markedly enhanced IL-17 levels after SHelAg stimulation (Fig. 1, C and D). Importantly, although displaying attenuated colonic inflammation, MLN cells from anti–IL-10R–treated Hh+ IFN-γ−/− mice exhibited a strong SHelAg-induced IL-17 response (Fig. 1 D). Intracellular cytokine staining of MLN cells from anti–IL-10R–treated Hh+ WT and Hh+ IL-10−/− mice demonstrated that SHelAg-induced IL-17 and IFN-γ were mainly produced by distinct populations of CD4+ cells, with a smaller fraction of cells staining positive for both cytokines (Fig. 1 E). In preliminary experiments, anti–IL-10R–treated Hh+ IFN-γ−/− mice demonstrated an increased frequency of IL-17+ CD4+ cells after SHelAg stimulation (1.8–4.7-fold increase compared with similarly treated WT mice; data from two independent experiments). Collectively, these results indicate that although Th17 responses may be sufficient to induce severe cecal inflammation, maximal inflammation in the colon also depends on IFN-γ.

To examine cytokine responses at the site of inflammation, mRNA levels for p19, p35, p40, IL-17A, IL-17F, and IFN-γ were measured in colon samples from Hh+ WT mice given control or anti–IL-10R mAb. As shown in Fig. 3, both Hh+ groups showed an approximately twofold increase in p19 levels compared with uninfected controls. In contrast, p35 levels were slightly reduced in both Hh+ groups, whereas p40 levels were unchanged in control mAb–treated Hh+ WT mice but increased >20-fold in anti–IL-10R–treated Hh+ WT mice. Interestingly, mRNA levels for IL-17A, IL-17F, and IFN-γ were approximately 40-fold, ninefold, and 150-fold higher in anti–IL-10R–treated compared with control mAb–treated Hh+ WT mice (Fig. 3).

Figure 3.
Cytokine mRNA levels in the colons of anti–IL-10R–treated Hh+ WT mice. Colonic tissues from uninfected or 4-wk-infected WT mice treated with control mAb or anti–IL-10R were collected and processed for real-time RT-PCR analysis ...

Anti-p40 treatment prevents intestinal pathology in anti–IL-10R–treated Hh+ mice

To examine if the IL-12p40 subunit is also required for disease development in the absence of IL-12, p35−/− mice were infected with H. hepaticus and treated with anti–IL-10R alone or anti–IL-10R plus anti-p40 mAb. As shown in Fig. 4 A, anti-p40 treatment completely abrogated both cecal and colonic inflammation in anti–IL-10R–treated Hh+ WT or p35−/− mice. In addition, anti-p40 treatment blocked SHelAg-induced IFN-γ and IL-17 secretion observed in MLN cultures from the same groups of Hh+ mice (Fig. 4, B and C). Importantly, anti-p40 treatment also prevented the cecal inflammation observed in Hh+ IFN-γ−/− mice given anti–IL-10R (Fig. 4 A), and this correlated with a complete loss of SHelAg-induced IL-17 production (Fig. 4 C). Collectively, these findings confirmed a crucial role for p40 in the development of H. hepaticus–induced intestinal inflammation even in the absence of IL-12, and again indicated a correlation between IL-17, IFN-γ, and pathology.

Figure 4.
Anti-p40 mAb treatment prevents intestinal pathology in anti–IL-10R–treated Hh+ mice. B6 WT, p35−/−, and IFN-γ−/− mice were infected with H. hepaticus and treated with control, anti–IL-10R, ...

IL-12 is not required for the development of T cell–dependent colitis in Hh+ Rag−/− mice

In light of the shared p40 subunit between IL-12 and IL-23, we reasoned that the p40-dependent, but IL-12–independent induction of H. hepaticus–triggered colitis was likely to be mediated by IL-23. As various cytokine-deficient Rag−/− animals were available to us, we next turned to an adoptive transfer model of colitis using Rag−/− mice deficient in IL-12 (p35Rag−/−), IL-23 (p19Rag−/−), or both IL-12 and IL-23 (p40Rag−/−) to further elucidate the role of IL-23 in disease development. In this model, colitis is induced in an IL-10–sufficient setting in Hh+ B6 or B10 Rag−/− recipients by transfer of CD4+ T cells (22). We first confirmed a critical role for p40 in the adoptive transfer model, as Hh+ p40Rag−/− mice failed to develop typhlocolitis after transfer of WT CD4+ CD45RBhi cells (Fig. 5, A and B) or IL-10−/− CD4+ cells (not depicted). In contrast, Hh+ Rag−/− and p35Rag−/− mice developed severe typhlocolitis after reconstitution with the same T cell populations (Fig. 5, A and B, and not depicted). Importantly, anti-p40 treatment inhibited intestinal inflammation in T cell–reconstituted Hh+ Rag−/− and p35Rag−/− animals (Fig. 5, A and B), demonstrating a requirement for p40 but not IL-12 in disease induction also in this model. In contrast, anti–IFN-γ treatment had no effect on cecal pathology (Fig. 5 A) but significantly reduced the inflammation in the colon of the Hh+ Rag−/− and p35Rag−/− recipients (Fig. 5 B). Similarly, although WT and IFN-γ−/− CD4+ CD45RBhi cells induced a similar degree of cecal inflammation in Hh+ Rag−/− mice (Fig. 5 A), recipients of IFN-γ−/− CD4+ cells showed reduced inflammation in the colon (Fig. 5 B). These findings are consistent with the previously observed difference in disease severity in the cecum versus colon of Hh+ IFN-γ−/− mice treated with anti–IL-10R (Figs. 1, A and B, and 2, E and J), and further support an important role for T cell–derived IFN-γ in disease pathogenesis in the colon.

Figure 5.
Hh+ Rag−/− and p35Rag−/−, but not p40Rag−/−, mice develop intestinal inflammation after T cell reconstitution. Hh+ B6/B10 Rag−/−, p40Rag−/−, and p35Rag−/− ...

IL-23 is essential for the development of maximal colitis and intestinal proinflammatory cytokine production

To directly assess the contribution of IL-23 in the development of colitis in the H. hepaticus/Rag−/− transfer model, an additional series of experiments was performed that included p19Rag−/− recipients, which lack the ability to produce IL-23. As shown in Fig. 6 (A and B), CD4+ T cell–reconstituted Hh+ p19Rag−/− mice displayed attenuated intestinal inflammation compared with Rag−/− recipients, demonstrating a crucial role for IL-23 in disease pathogenesis. However, compared with disease-free Hh+ p40Rag−/− recipients, some residual intestinal inflammation was observed in T cell–reconstituted Hh+ p19Rag−/− mice (Fig. 6, A and B). These data suggest that, although not absolutely required for intestinal inflammation, IL-12 contributes to the mild intestinal inflammation observed in the absence of IL-23. Nevertheless, of the two cytokines, IL-23 appears to be more important in the disease process, as the inflammation present in Hh+ p19Rag−/− recipients was significantly reduced compared with that observed in p35Rag−/− hosts (Fig. 6, A and B). Importantly, flow cytometric analysis revealed no significant difference in CD4+ cell numbers in the spleens of Hh+ p19Rag−/− and p35Rag−/− recipients (not depicted), demonstrating that the attenuated pathology in p19Rag−/− mice was not due to lower T cell reconstitution. Moreover, there was no correlation between degree of inflammation and H. hepaticus colonization levels, as all groups harbored similar concentrations of H. hepaticus in their cecal contents (Fig. 6 C).

Figure 6.
IL-23 is essential for the development of maximal colitis and intestinal proinflammatory cytokine production. Hh+ B6 Rag−/−, p40Rag−/−, p35Rag−/−, and p19Rag−/− mice were inoculated ...

We next quantitated cytokines in colon homogenates from the different groups of T cell–reconstituted Hh+ Rag−/− mice. As shown in Fig. 6 (D–G), the absence of both IL-12 and IL-23 led to abolished TNF-α, IFN-γ, MCP-1, and IL-6 levels in colon homogenates of T cell–reconstituted Hh+ p40Rag−/− animals. IL-12–deficient Hh+ p35Rag−/− recipients showed similar or marginally decreased levels of proinflammatory cytokines compared with Hh+ Rag−/− recipients. Finally, the absence of IL-23 in Hh+ p19Rag−/− mice led to a further reduction in proinflammatory cytokine production (Fig. 6, D–G), emphasizing the crucial role for IL-23 in mediating this response.

DISCUSSION

Before the discovery of IL-23 and its recently documented role in autoimmune disorders (25), the common view in the field of Th1-mediated intestinal inflammation has been that IL-12, by initiating and maintaining Th1 responses, is crucial for disease pathogenesis. We here demonstrate that IL-23 and not IL-12 is essential for the induction of maximal bacterial-induced T cell–dependent colitis. This conclusion is based on results from two complementary models of intestinal inflammation triggered by H. hepaticus. Using an established CD4+ T cell adoptive transfer model of colitis (22), we observed that although severe intestinal inflammation was still induced in IL-12–deficient (p35Rag−/−) recipients, selective ablation of IL-23 (p19Rag−/−) resulted in attenuation of disease. In addition, using a novel model of colitis involving anti–IL-10R treatment of Hh+ WT animals that circumvents the lymphopenic environment of Rag−/− mice, we confirm an essential role for p40 and not IL-12 in intestinal inflammation also in immune competent hosts.

IL-23, which is produced by DCs and macrophages in response to Toll-like receptor stimuli (23), may contribute to intestinal pathology in multiple ways. By inducing the production of IL-1β, TNF, IL-12, and IFN-γ by cells of the innate immune system (3, 24), IL-23 can directly participate in triggering a proinflammatory cytokine cascade. A key role for IL-23 in driving innate intestinal pathology was indeed observed in a complementary study by Hue et al. (25), in which depletion of IL-23p19 attenuated the T cell–independent typhlocolitis that develops in Hh+ 129SvEvRag−/− mice. IL-23 is also known to amplify and/or stabilize Th17 cells (26), which through their secretion of IL-17 induce myeloid and endothelial cell expression of proinflammatory cytokines (IL-1, IL-6, IL-8, TNF-α, and GM-CSF) and chemokines (3, 10, 27). In addition to our findings of increased IL-17 responses in colitic mice, several of the effects we observed in our T cell–dependent model of colitis may be interpreted in terms of Th17 function and subsequent recruitment of inflammatory cells to the intestine. Thus, both cecal inflammation and SHelAg-specific IL-17 responses observed in anti–IL-10R–treated Hh+ IFN-γ−/− mice were inhibited by co-administration of anti-p40 mAb. Moreover, IFN-γ−/− CD4+ CD45RBhi cells were equivalent to their WT counterparts in terms of inducing cecal inflammation (Fig. 5 A), and these cells were also pathogenic in an IL-12–deficient setting in p35Rag−/− hosts (not depicted). Collectively, these findings argue for an IL-23–driven IFN-γ–independent component in disease pathogenesis, a conclusion in agreement with the pathogenic role of Th17 cells in EAE and CIA (35, 28).

Th17 cells represent a unique linage distinct from the Th1 and Th2 subsets, as their development is inhibited by IFN-γ and IL-4 and is independent of STAT4, STAT6, STAT1, and T-bet (8, 9). Three recent reports have now established that TGF-β, in the presence of IL-6, is critical for the development of Th17 cells, whereas IL-23 appears dispensable for Th17 commitment and initial IL-17 production (2931). IL-23 is, however, clearly essential for a fully effective Th17 response in vivo, as exemplified in EAE and CIA as well as in various infections with extracellular bacteria (e.g., Klebsiella pneumoniae and Citrobacter rodentium; references 35, 28, 30, and 32). Our findings of up-regulated IL-17A (and to a lesser extent IL-17F) mRNA levels in the absence of significant induction of IL-23p19 or p40 in colonic tissues of Hh+ control mAb–treated WT mice that show no colitis (Fig. 3) support these conclusions. The mechanism behind the IL-23 dependency for effective Th17 responses is still unknown. As IL-23R expression is up-regulated by TGF-β, thus downstream of signals that initiate Th17 differentiation (8, 30), one possibility is that IL-23 stabilizes and/or maintains Th17 cells, analogous to the role of IL-12 in stabilizing Th1 cells after their expression of IL-12Rβ2 (26). So far, the role of IL-10 in Th17 development has not been carefully examined. To the best of our knowledge, the results presented here are the first to demonstrate an inhibitory role for IL-10 in the development of IL-17–producing CD4+ T cells in vivo, as anti–IL-10R treatment of Hh+ WT mice led to markedly increased H. hepaticus antigen-specific IL-17 responses. The mechanism by which IL-10 exerts its down-regulatory effect on IL-17 production is currently unknown but was shown to be independent of IL-12 and IFN-γ, as anti–IL-10R–treated Hh+ p35−/− and IFN-γ−/− mice also displayed increased IL-17 responses. One possibility is that IL-10 inhibits IL-23 secretion by cells of the innate immune system, thereby limiting the amount of IL-23 available to maintain Th17 cells. Alternatively, IL-10 might have a down-regulatory effect on IL-23R expression on CD4+ cells, as has been described for bone marrow–derived macrophages (6), thereby rendering these cells less responsive to IL-23. In the study by Veldhoen et al. (29), IL-17–secreting T cells were generated in vitro in cocultures of naive CD4+ cells with naturally occurring CD25+ CD4+ T regulatory cells in the presence of Toll-like receptor stimuli. In contrast to our findings, blocking IL-10 in this model did not result in an increased frequency of IL-17–producing T cells (29). However, as the percentage of IFN-γ–secreting CD4+ cells increased in the same cultures (29), a possible inhibitory effect of IFN-γ on the development of IL-17–producing cells cannot be excluded.

Although, as shown in this study, IL-23 and not IL-12 is essential for the development of maximal pathology in T cell–dependent bacterial-induced intestinal inflammation, there are some differences between our model and the EAE and CIA models in regard to the contribution of IL-12 and IFN-γ to disease pathogenesis. Thus, in the sole absence of IL-12 (p35−/− mice), disease severity was enhanced in EAE and CIA (3, 5), whereas for colitis induced by anti–IL-10R treatment of Hh+ p35−/− mice or by T cell transfer into Hh+ p35Rag−/− recipients, this was not the case. One explanation for this difference could be that IL-17–secreting CD4+ T cells are the major pathogenic population in the former two models, with IL-12–driven IFN-γ suppressing the generation of IL-17+ Th cells (8, 9, 30), whereas in the colitis setting, both IL-17 and IFN-γ contribute to disease pathogenesis. Indeed, loss of IFN-γ or the IFN-γ receptor was associated with an increased disease severity in both EAE and CIA (3337), whereas as shown here, IFN-γ deficiency led to largely unaffected cecal pathology but reduced colonic inflammation. These findings indicate that IFN-γ enhances rather than suppresses inflammation in the intestinal tract, a conclusion supported by previous studies demonstrating that anti–IFN-γ treatment prevents the development of colitis (20, 38, 39). Yen et al. (40) have recently reported that IL-23 is required for the development of spontaneous enterocolitis in IL-10−/− animals, a finding attributed to IL-17 and IL-6 based on mAb neutralization studies in an adoptive transfer model. Importantly, neutralization of IL-17 or IL-6 alone did not significantly reduce pathology, and although combined treatment attenuated the colitis, it did not completely inhibit the inflammation (40). Based on our findings, we hypothesize that additional pathogenic effector mechanisms synergize with IL-17/IL-6 to induce severe intestinal inflammation. In particular, our results highlight that although not absolutely required for cecal disease, IFN-γ plays a synergistic role in the induction of colonic inflammation. The reason for the difference in cytokine requirements to induce maximal pathology in the cecum versus the colon is currently unclear, but it may reflect distinct levels of bacterial colonization (41) leading to different induction of cytokines and/or chemokines.

Interestingly, this study revealed a role for H. hepaticus–induced IL-12–independent, but p40-dependent IFN-γ in intestinal pathology. Whether the molecular mechanism behind this finding involves p40 acting alone, as a homodimer, or in association with other chains remains unknown. However, it is possible that these observations reflect the involvement of IL-23 in triggering H. hepaticus–induced CD4+ IFN-γ production in IL-12–deficient mice. This conclusion is supported by recent findings from the Mycobacterium tuberculosis model in which antigen-specific IFN-γ+ CD4+ cells were shown to develop in infected p35−/− mice via a p19-dependent mechanism, contributing to the prolonged survival of these hosts compared with infected p40−/− animals (42, 43). The co-appearance of antigen-reactive IFN-γ+ CD4+ and IL-17+ CD4+ cells in p35−/− mice in both the M. tuberculosis (43) and H. hepaticus models suggests that the IL-23–induced IFN-γ detected in these animals may not be sufficient to block the generation of IL-17–secreting CD4+ cells. Based on the data presented here, we instead propose a modified model in which IFN-γ may have either inhibitory or synergistic effects on Th17 development and/or effector function. Thus, in settings with large amounts of the cytokine, IL-12–induced IFN-γ exerts negative effects on Th17 development, as described by Harrington et al. (8), Park et al. (9), and Mangan et al. (30), and as exemplified by Hh+ IL-10−/− mice that mount markedly enhanced IFN-γ but reduced IL-17 levels compared with anti–IL-10R–treated Hh+ p35−/− mice (Fig. 1, C and D). However, in settings with no IL-12, lower levels of IL-23–dependent IFN-γ (or IFN-γ induced by another p40-dependent mechanism) act together with IL-17 to enhance intestinal inflammation (Fig. 1, B–D, compare p35−/− with IFN-γ−/− mice). It is important to point out that although IL-12 is dispensable for colitis induction, this cytokine may still contribute to intestinal pathology, as shown in the T cell transfer experiments in which p19Rag−/− recipients displayed a significantly higher level of intestinal inflammation compared with p40Rag−/− recipients (Fig. 6, A and B). Besides the role of IL-12 in Th1 development, the IL-12p40 subunit by itself (possibly as a homodimer) may also contribute to disease pathogenesis through its effects on myeloid cells (4446) and its recently described role in DC migration and subsequent T cell priming (47).

Collectively, the data presented in this study demonstrate that IL-23 and not IL-12 is essential for the pathogenesis of T cell–dependent bacterial-induced intestinal inflammation. Although IL-23 may constitute a potential therapeutic target for IBD, our findings further support a model in which multiple factors downstream of IL-23 (e.g., IL-17, IL-6, and IFN-γ) may contribute to intestinal inflammation and together synergize to induce maximal pathology. Further identification and characterization of these downstream components and mechanisms should help dissect the immunological pathways involved in IBD, and should aid in the development of new therapeutic treatments for patients with these chronic inflammatory diseases of the intestinal tract.

MATERIALS AND METHODS

Experimental animals and infections.

Female or male specific pathogen-free C57BL/6 (B6) WT, B6 p40−/−, B6 IFN-γ−/−, C57BL/10 (B10) IL-10−/−, B10 Rag-2−/− (Taconic Farms), and B6 p35−/− mice (The Jackson Laboratory) were used at 6–10 wk of age. p40Rag−/− and p35Rag−/− animals were generated by crossing the above mentioned single cytokine-deficient mice, and the progeny were intercrossed to generate double-deficient offspring. For Fig. 6, Rag−/−, p40Rag−/−, p35Rag−/−, and p19Rag−/− animals on the B6 background were used (25). The animals used tested negative for antibodies to specific murine viruses and were free of Helicobacter species as assessed by PCR. Animals were housed in sterile microisolator cages at the National Institute of Allergy and Infectious Disease (NIAID) animal facility under a study proposal approved by the NIAID Animal Care and Use Committee or in accredited animal facilities at the University of Oxford according to the UK Scientific Procedures Act 1986.

Mice were inoculated intragastrically with 0.5 ml of an H. hepaticus suspension (NCI-Frederick isolate 1A [reference 48] isolated from the same mouse colony as isolate Hh-1; American Type Culture Collection 51449 [reference 49]) prepared to a McFarland turbidity standard of 1.0 in PBS representing 2.45 × 109 CFU/ml. For the experiments shown in Fig. 6, three doses of 5 × 107–2 × 108 CFU were given to mice on days 0, 2, and 4. Age- and sex-matched uninfected animals were included as controls.

In vivo mAb treatment.

To analyze the effect of in vivo neutralization of IL-10R, IL-12/IL-23 p40, or IFN-γ, mice were treated i.p. with 1 mg per injection of mAb 1B1.3a (anti–IL-10R), C17.8 (anti-p40), XMG-6 (anti–IFN-γ), or a control mAb, GL113 (anti–β-galactosidase), in 0.5 ml PBS on days 0, 7, 14, and 21 of H. hepaticus infection or cell transfer (for T cell–sufficient mice and Rag−/− recipients, respectively). 1 wk after the last mAb injection, mice were killed, MLNs were collected for in vitro culture, and intestinal tissues were collected in Bouin's fixative for histology and in RNA-later (Ambion) for real-time PCR analysis.

Cell preparations and purifications.

Single cell suspensions were prepared from MLNs, and cells were resuspended in complete tissue culture medium (22). For purification of CD4+ CD45RBhi cells, MLN cells from naive WT or IFN-γ−/− mice were stained with anti–CD4-PE (clone RM4-5) or anti–CD4-CyChrome (RM4-5) and anti–CD45RB-FITC (16A; all from BD Biosciences) and sorted on a FACSVantage or a FACStarPlus (Becton Dickinson), gating on ~50% of the brightest CD4+ cells. For the experiment shown in Fig. 6, splenic CD4+ CD45RBhi cells from WT mice were used. The sorted CD4+ CD45RBhi cells were ≥99% pure.

Cell cultures and cytokine assays.

MLN cells (5 × 106/ml) pooled from three to five mice/group were cultured in medium alone or with 5 μg/ml of SHelAg in 96-well flat-bottomed plates (0.2 ml/well) at 37°C and 5% CO2, and supernatants were collected after 72 h. SHelAg was prepared as described previously (20), boiled for 5 min (22), and stored at −40°C until use. IFN-γ and IL-17 were measured by ELISA using mAb from BD Biosciences and R&D Systems, respectively.

Intracellular cytokine staining.

Analyses of intracellular cytokine expression were performed on cells from the same SHelAg-stimulated MLN cultures used for cytokine secretion assays as described previously (22, 50). In brief, cells were incubated for an additional 18 h in fresh medium added to replace the culture supernatant collected at 72 h. Thereafter, cells were stimulated with 10 ng/ml PMA and 1 μg/ml ionomycin (both from Sigma-Aldrich) for 4.5 h with the addition of 10 μg/ml brefeldin A (Sigma-Aldrich) during the last 2 h. Intracellular staining was then performed as described previously (22, 50) using anti–IL-17–PE (TC11-18H10.1) and anti–IFN-γ–FITC (XMG1.2; both from BD Biosciences). Cell fluorescence was measured using a FACSCalibur (Becton Dickinson), and data were analyzed using CELLQuest software (Becton Dickinson).

Cell transfers to Rag−/− mice.

Unless otherwise indicated, CD4+ CD45RBhi cells (3 × 105/mouse) were transferred i.v. to naive or 2–4-d-infected Rag−/− mice. Mice were killed 4 wk after cell transfer, and intestinal tissues were collected for histologic analysis and measurements of cytokines.

Pathology.

Intestinal tissues were processed and inflammation in the cecum (typhlitis) and ascending colon was scored in a blinded fashion by the same pathologist (A.W. Cheever) on a scale from 0 to 20 as described previously (22). In brief, a longitudinal section of the entire cecum was made together with a cross section of the ascending colon ~1 cm from the cecum, and a total score for the whole section was assigned based on a 0–4+ scoring system for different features with emphasis on the number of infiltrating cells for the lamina propria, the submucosa, and the serosa. In addition, crypt abscesses and ulcers were each given a score from 0 to 4. A total score was calculated by adding the individual scores.

Real-time RT-PCR for detection of cytokine mRNA.

Because, in general, the degree of inflammation in the colon proportionally reflects that observed in the cecum, the colon was chosen for real-time RT-PCR analyses (and cytokine protein determinations; see below) to avoid the lymphocyte patches present irregularly throughout the cecum while preserving the intact cecum for histological examination. Total RNA was isolated from polytron-homogenized colonic tissue (~3 mm of ascending colon distal of the piece used for histology) using the RNeasy mini kit, including a DNase treatment step as recommended by the manufacturer (QIAGEN). 6–9 μg RNA was reverse transcribed using Superscript III reverse transcriptase and oligo-dT primers (both from Invitrogen). cDNA was amplified using TaqMan reagents and a Chromo4 detection system (MJ Research). Cytokine expression levels for each individual sample (run in triplicates) were normalized to HPRT using ΔCt calculations. Mean relative cytokine expression levels between control and experimental groups (n = 2–4 mice/group) were determined using the 2-ΔΔCt formula. Specific primer pairs and FAM/TAMARA- or VIC/TAMARA-labeled probes were as follows: HPRT: primers 5′-GACCGGTCCCGTCATGC-3′, 5′-TCATAACCTGGTTCATCATCGC-3′, probe 5′-ACCCGCAGTCCCAGCGTCGTC-3′; IL-23p19: primers 5′-AGCGGGACATATGAATCTACTAAGAGA-3′, 5′-GTCCTAGTAGGGAGGTGTGAAGTTG-3′, probe 5′-CCAGTTCT- GCTTGCAAAGGATCCGC-3′; IL-12p35: primers 5′-TACTAGAGA- GACTTCTTCCACAACAAGAG-3′, 5′-TCTGGTACATCTTCAAGT- CCTCATAGA-3′, probe 5′-AGACGTCTTTGATGATGACCCTGTG- CCT-3′; IL-12p40: primers 5′-GACCATCACTGTCAAAGAGTTTCTAGAT-3′, 5′-AGGAAAGTCTTGTTTTTGAAATTTTTTAA-3′, probe 5′-CCACTCACATCTGCTGCTCCACAAGAAG-3′; IL-17A: primers 5′-GCTCCAGAAGGCCCTCAG-3′, 5′-CTTTCCCTCCGCATTGA- CA-3′, probe 5′-ACCTCAACCGTTCCACGTCACCCTG-3′; IL-17F: primers 5′-AGGGCATTTCTGTCCCACGTGAAT-3′, 5′-GCATTGA- TGCAGCCTGAGTGTCT-3′, probe 5′-CATGGGATTACAACATCACTCGAGACCC-3′; and IFN-γ: primers 5′-GGATGCATTCATGAGTATTGC-3′, 5′-GCTTCCTGAGGCTGGATTC-3′; probe 5′-TTT- GAGGTCAACAACCCACAGGTCCA-3′.

Cytokine protein determinations in colon homogenates.

To measure cytokines at the protein level in the intestine, colonic tissues were snap frozen and then homogenized in PBS containing a cocktail of protease inhibitors (Protease Inhibitor Cocktail Tablets; Roche) using a tissue polytron. After centrifugation at 10,000 g to pellet debris, levels of TNF-α, IFN-γ, MCP-1, and IL-6 were measured in supernatants using the cytometric bead assay (BD Biosciences). Cytokine amounts were normalized to the total amount of protein in each sample, as measured by Bradford assay (Bio-Rad Laboratories).

Quantitation of H. hepaticus using real-time PCR.

DNA was purified from cecal contents of Hh+ mice using the DNA Stool kit (QIAGEN). H. hepaticus DNA was quantified as described previously (41, 51) using a real-time quantitative PCR method based on the cdtB gene, performed with a Chromo4 detection system. Standard curves were constructed using H. hepaticus DNA that was purified from bacterial cultures using the DNeasy kit (QIAGEN).

Statistical analysis.

Colitis scores were compared using the nonparametric Mann-Whitney U test. Cytokine data and H. hepaticus colonization levels were analyzed by Student's unpaired two-tailed t test. Differences were considered statistically significant with P < 0.05.

Acknowledgments

We are grateful to C. Henry, C. Eigsti, and N. Rust for cell sorting; P. Caspar for technical assistance with ELISA assays; S. Hieny for purification of mAb; and P. Ahern for help with H. hepaticus real-time PCR. We also thank P. Kaye and G. Trinchieri for support and critical reading of the manuscript.

This work was supported by grants from the Wellcome Trust to K.J. Maloy (Career Development Fellowship) and F. Powrie (Senior Fellowship).

The authors have no conflicting financial interests.

Notes

Abbreviations used: CIA, collagen-induced arthritis; EAE, experimental autoimmune encephalomyelitis; Hh+, H. hepaticus–infected; IBD, inflammatory bowel disease; MLN, mesenteric lymph node; SHelAg, soluble H. hepaticus antigen.

K.J. Maloy and A. Sher contributed equally to this work.

References

1. Trinchieri, G. 2003. Interleukin-12 and the regulation of innate resistance and adaptive immunity. Nat. Rev. Immunol. 3:133–146. [PubMed]
2. Oppmann, B., R. Lesley, B. Blom, J.C. Timans, Y. Xu, B. Hunte, F. Vega, N. Yu, J. Wang, K. Singh, et al. 2000. Novel p19 protein engages IL-12p40 to form a cytokine, IL-23, with biological activities similar as well as distinct from IL-12. Immunity. 13:715–725. [PubMed]
3. Cua, D.J., J. Sherlock, Y. Chen, C.A. Murphy, B. Joyce, B. Seymour, L. Lucian, W. To, S. Kwan, T. Churakova, et al. 2003. Interleukin-23 rather than interleukin-12 is the critical cytokine for autoimmune inflammation of the brain. Nature. 421:744–748. [PubMed]
4. Langrish, C.L., Y. Chen, W.M. Blumenschein, J. Mattson, B. Basham, J.D. Sedgwick, T. McClanahan, R.A. Kastelein, and D.J. Cua. 2005. IL-23 drives a pathogenic T cell population that induces autoimmune inflammation. J. Exp. Med. 201:233–240. [PMC free article] [PubMed]
5. Murphy, C.A., C.L. Langrish, Y. Chen, W. Blumenschein, T. McClanahan, R.A. Kastelein, J.D. Sedgwick, and D.J. Cua. 2003. Divergent pro- and antiinflammatory roles for IL-23 and IL-12 in joint autoimmune inflammation. J. Exp. Med. 198:1951–1957. [PMC free article] [PubMed]
6. Parham, C., M. Chirica, J. Timans, E. Vaisberg, M. Travis, J. Cheung, S. Pflanz, R. Zhang, K.P. Singh, F. Vega, et al. 2002. A receptor for the heterodimeric cytokine IL-23 is composed of IL-12Rβ1 and a novel cytokine receptor subunit, IL-23R. J. Immunol. 168:5699–5708. [PubMed]
7. Aggarwal, S., N. Ghilardi, M.H. Xie, F.J. de Sauvage, and A.L. Gurney. 2003. Interleukin-23 promotes a distinct CD4 T cell activation state characterized by the production of interleukin-17. J. Biol. Chem. 278:1910–1914. [PubMed]
8. Harrington, L.E., R.D. Hatton, P.R. Mangan, H. Turner, T.L. Murphy, K.M. Murphy, and C.T. Weaver. 2005. Interleukin 17-producing CD4+ effector T cells develop via a lineage distinct from the T helper type 1 and 2 lineages. Nat. Immunol. 6:1123–1132. [PubMed]
9. Park, H., Z. Li, X.O. Yang, S.H. Chang, R. Nurieva, Y.H. Wang, Y. Wang, L. Hood, Z. Zhu, Q. Tian, and C. Dong. 2005. A distinct lineage of CD4 T cells regulates tissue inflammation by producing interleukin 17. Nat. Immunol. 6:1133–1141. [PMC free article] [PubMed]
10. Kolls, J.K., and A. Linden. 2004. Interleukin-17 family members and inflammation. Immunity. 21:467–476. [PubMed]
11. Parronchi, P., P. Romagnani, F. Annunziato, S. Sampognaro, A. Becchio, L. Giannarini, E. Maggi, C. Pupilli, F. Tonelli, and S. Romagnani. 1997. Type 1 T-helper cell predominance and interleukin-12 expression in the gut of patients with Crohn's disease. Am. J. Pathol. 150:823–832. [PMC free article] [PubMed]
12. Monteleone, G., L. Biancone, R. Marasco, G. Morrone, O. Marasco, F. Luzza, and F. Pallone. 1997. Interleukin 12 is expressed and actively released by Crohn's disease intestinal lamina propria mononuclear cells. Gastroenterology. 112:1169–1178. [PubMed]
13. Becker, C., S. Wirtz, M. Blessing, J. Pirhonen, D. Strand, O. Bechthold, J. Frick, P.R. Galle, I. Autenrieth, and M.F. Neurath. 2003. Constitutive p40 promoter activation and IL-23 production in the terminal ileum mediated by dendritic cells. J. Clin. Invest. 112:693–706. [PMC free article] [PubMed]
14. Schmidt, C., T. Giese, B. Ludwig, I. Mueller-Molaian, T. Marth, S. Zeuzem, S.C. Meuer, and A. Stallmach. 2005. Expression of interleukin-12-related cytokine transcripts in inflammatory bowel disease: elevated interleukin-23p19 and interleukin-27p28 in Crohn's disease but not in ulcerative colitis. Inflamm. Bowel Dis. 11:16–23. [PubMed]
15. Mannon, P.J., I.J. Fuss, L. Mayer, C.O. Elson, W.J. Sandborn, D. Present, B. Dolin, N. Goodman, C. Groden, R.L. Hornung, et al. 2004. Anti-interleukin-12 antibody for active Crohn's disease. N. Engl. J. Med. 351:2069–2079. [PubMed]
16. Fuss, I.J., C. Becker, Z. Yang, C. Groden, R.L. Hornung, F. Heller, M.F. Neurath, W. Strober, and P.J. Mannon. 2006. Both IL-12p70 and IL-23 are synthesized during active Crohn's disease and are down-regulated by treatment with anti-IL-12 p40 monoclonal antibody. Inflamm. Bowel Dis. 12:9–15. [PubMed]
17. Neurath, M.F., I. Fuss, B.L. Kelsall, E. Stuber, and W. Strober. 1995. Antibodies to interleukin 12 abrogate established experimental colitis in mice. J. Exp. Med. 182:1281–1290. [PMC free article] [PubMed]
18. Duchmann, R., E. Schmitt, P. Knolle, K.H. Meyer zum Buschenfelde, and M. Neurath. 1996. Tolerance towards resident intestinal flora in mice is abrogated in experimental colitis and restored by treatment with interleukin-10 or antibodies to interleukin-12. Eur. J. Immunol. 26:934–938. [PubMed]
19. Davidson, N.J., S.A. Hudak, R.E. Lesley, S. Menon, M.W. Leach, and D.M. Rennick. 1998. IL-12, but not IFN-γ, plays a major role in sustaining the chronic phase of colitis in IL-10-deficient mice. J. Immunol. 161:3143–3149. [PubMed]
20. Kullberg, M.C., J.M. Ward, P.L. Gorelick, P. Caspar, S. Hieny, A. Cheever, D. Jankovic, and A. Sher. 1998. Helicobacter hepaticus triggers colitis in specific-pathogen-free interleukin-10 (IL-10)-deficient mice through an IL-12- and gamma interferon-dependent mechanism. Infect. Immun. 66:5157–5166. [PMC free article] [PubMed]
21. Kullberg, M.C., A.G. Rothfuchs, D. Jankovic, P. Caspar, T.A. Wynn, P.L. Gorelick, A.W. Cheever, and A. Sher. 2001. Helicobacter hepaticus-induced colitis in interleukin-10-deficient mice: cytokine requirements for the induction and maintenance of intestinal inflammation. Infect. Immun. 69:4232–4241. [PMC free article] [PubMed]
22. Kullberg, M.C., D. Jankovic, P.L. Gorelick, P. Caspar, J.J. Letterio, A.W. Cheever, and A. Sher. 2002. Bacteria-triggered CD4+ T regulatory cells suppress Helicobacter hepaticus–induced colitis. J. Exp. Med. 196:505–515. [PMC free article] [PubMed]
23. Langrish, C.L., B.S. McKenzie, N.J. Wilson, R. de Waal Malefyt, R.A. Kastelein, and D.J. Cua. 2004. IL-12 and IL-23: master regulators of innate and adaptive immunity. Immunol. Rev. 202:96–105. [PubMed]
24. Belladonna, M.L., J.C. Renauld, R. Bianchi, C. Vacca, F. Fallarino, C. Orabona, M.C. Fioretti, U. Grohmann, and P. Puccetti. 2002. IL-23 and IL-12 have overlapping, but distinct, effects on murine dendritic cells. J. Immunol. 168:5448–5454. [PubMed]
25. Hue, S., P. Ahern, S. Buonocore, M.C. Kullberg, D.J. Cua, B.S. McKenzie, F. Powrie, and K.J. Maloy. 2006. IL-23 drives innate and T cell–mediated intestinal inflammation. J. Exp. Med. 203:2473–2483. [PMC free article] [PubMed]
26. Weaver, C.T., L.E. Harrington, P.R. Mangan, M. Gavrieli, and K.M. Murphy. 2006. Th17: an effector CD4 T cell lineage with regulatory T cell ties. Immunity. 24:677–688. [PubMed]
27. McKenzie, B.S., R.A. Kastelein, and D.J. Cua. 2006. Understanding the IL-23–IL-17 immune pathway. Trends Immunol. 27:17–23. [PubMed]
28. Chen, Y., C.L. Langrish, B. McKenzie, B. Joyce-Shaikh, J.S. Stumhofer, T. McClanahan, W. Blumenschein, T. Churakovsa, J. Low, L. Presta, et al. 2006. Anti-IL-23 therapy inhibits multiple inflammatory pathways and ameliorates autoimmune encephalomyelitis. J. Clin. Invest. 116:1317–1326. [PMC free article] [PubMed]
29. Veldhoen, M., R.J. Hocking, C.J. Atkins, R.M. Locksley, and B. Stockinger. 2006. TGFβ in the context of an inflammatory cytokine milieu supports de novo differentiation of IL-17-producing T cells. Immunity. 24:179–189. [PubMed]
30. Mangan, P.R., L.E. Harrington, D.B. O'Quinn, W.S. Helms, D.C. Bullard, C.O. Elson, R.D. Hatton, S.M. Wahl, T.R. Schoeb, and C.T. Weaver. 2006. Transforming growth factor-β induces development of the TH17 lineage. Nature. 441:231–234. [PubMed]
31. Bettelli, E., Y. Carrier, W. Gao, T. Korn, T.B. Strom, M. Oukka, H.L. Weiner, and V.K. Kuchroo. 2006. Reciprocal developmental pathways for the generation of pathogenic effector TH17 and regulatory T cells. Nature. 441:235–238. [PubMed]
32. Happel, K.I., P.J. Dubin, M. Zheng, N. Ghilardi, C. Lockhart, L.J. Quinton, A.R. Odden, J.E. Shellito, G.J. Bagby, S. Nelson, and J.K. Kolls. 2005. Divergent roles of IL-23 and IL-12 in host defense against Klebsiella pneumoniae. J. Exp. Med. 202:761–769. [PMC free article] [PubMed]
33. Willenborg, D.O., S. Fordham, C.C. Bernard, W.B. Cowden, and I.A. Ramshaw. 1996. IFN-γ plays a critical down-regulatory role in the induction and effector phase of myelin oligodendrocyte glycoprotein-induced autoimmune encephalomyelitis. J. Immunol. 157:3223–3227. [PubMed]
34. Ferber, I.A., S. Brocke, C. Taylor-Edwards, W. Ridgway, C. Dinisco, L. Steinman, D. Dalton, and C.G. Fathman. 1996. Mice with a disrupted IFN-γ gene are susceptible to the induction of experimental autoimmune encephalomyelitis (EAE). J. Immunol. 156:5–7. [PubMed]
35. Krakowski, M., and T. Owens. 1996. Interferon-γ confers resistance to experimental allergic encephalomyelitis. Eur. J. Immunol. 26:1641–1646. [PubMed]
36. Vermeire, K., H. Heremans, M. Vandeputte, S. Huang, A. Billiau, and P. Matthys. 1997. Accelerated collagen-induced arthritis in IFN-γ receptor-deficient mice. J. Immunol. 158:5507–5513. [PubMed]
37. Guedez, Y.B., K.B. Whittington, J.L. Clayton, L.A. Joosten, F.A. van de Loo, W.B. van den Berg, and E.F. Rosloniec. 2001. Genetic ablation of interferon-γ up-regulates interleukin-1β expression and enables the elicitation of collagen-induced arthritis in a nonsusceptible mouse strain. Arthritis Rheum. 44:2413–2424. [PubMed]
38. Powrie, F., M.W. Leach, S. Mauze, S. Menon, L.B. Caddle, and R.L. Coffman. 1994. Inhibition of Th1 responses prevents inflammatory bowel disease in scid mice reconstituted with CD45RBhi CD4+ T cells. Immunity. 1:553–562. [PubMed]
39. Berg, D.J., N. Davidson, R. Kühn, W. Müller, S. Menon, G. Holland, L. Thompson-Snipes, M.W. Leach, and D. Rennick. 1996. Enterocolitis and colon cancer in interleukin-10-deficient mice are associated with aberrant cytokine production and CD4+ TH1-like responses. J. Clin. Invest. 98:1010–1020. [PMC free article] [PubMed]
40. Yen, D., J. Cheung, H. Scheerens, F. Poulet, T. McClanahan, B. McKenzie, M.A. Kleinschek, A. Owyang, J. Mattson, W. Blumenschein, et al. 2006. IL-23 is essential for T cell-mediated colitis and promotes inflammation via IL-17 and IL-6. J. Clin. Invest. 116:1310–1316. [PMC free article] [PubMed]
41. Maloy, K.J., L. Salaun, R. Cahill, G. Dougan, N.J. Saunders, and F. Powrie. 2003. CD4+CD25+ TR cells suppress innate immune pathology through cytokine-dependent mechanisms. J. Exp. Med. 197:111–119. [PMC free article] [PubMed]
42. Cooper, A.M., A. Kipnis, J. Turner, J. Magram, J. Ferrante, and I.M. Orme. 2002. Mice lacking bioactive IL-12 can generate protective, antigen-specific cellular responses to mycobacterial infection only if the IL-12 p40 subunit is present. J. Immunol. 168:1322–1327. [PubMed]
43. Khader, S.A., J.E. Pearl, K. Sakamoto, L. Gilmartin, G.K. Bell, D.M. Jelley-Gibbs, N. Ghilardi, F. deSauvage, and A.M. Cooper. 2005. IL-23 compensates for the absence of IL-12p70 and is essential for the IL-17 response during tuberculosis but is dispensable for protection and antigen-specific IFN-γ responses if IL-12p70 is available. J. Immunol. 175:788–795. [PubMed]
44. Russell, T.D., Q. Yan, G. Fan, A.P. Khalifah, D.K. Bishop, S.L. Brody, and M.J. Walter. 2003. IL-12 p40 homodimer-dependent macrophage chemotaxis and respiratory viral inflammation are mediated through IL-12 receptor β1. J. Immunol. 171:6866–6874. [PubMed]
45. Pahan, K., F.G. Sheikh, X. Liu, S. Hilger, M. McKinney, and T.M. Petro. 2001. Induction of nitric-oxide synthase and activation of NF-κB by interleukin-12 p40 in microglial cells. J. Biol. Chem. 276:7899–7905. [PMC free article] [PubMed]
46. Jana, M., S. Dasgupta, R.N. Saha, X. Liu, and K. Pahan. 2003. Induction of tumor necrosis factor-alpha (TNF-α) by interleukin-12 p40 monomer and homodimer in microglia and macrophages. J. Neurochem. 86:519–528. [PMC free article] [PubMed]
47. Khader, S.A., S. Partida-Sanchez, G. Bell, D.M. Jelley-Gibbs, S. Swain, J.E. Pearl, N. Ghilardi, F.J. Desauvage, F.E. Lund, and A.M. Cooper. 2006. Interleukin 12p40 is required for dendritic cell migration and T cell priming after Mycobacterium tuberculosis infection. J. Exp. Med. 203:1805–1815. [PMC free article] [PubMed]
48. Ward, J.M., J.G. Fox, M.R. Anver, D.C. Haines, C.V. George, M.J. Collins Jr., P.L. Gorelick, K. Nagashima, M.A. Gonda, R.V. Gilden, et al. 1994. Chronic active hepatitis and associated liver tumors in mice caused by a persistent bacterial infection with a novel Helicobacter species. J. Natl. Cancer Inst. 86:1222–1227. [PubMed]
49. Fox, J.G., F.E. Dewhirst, J.G. Tully, B.J. Paster, L. Yan, N.S. Taylor, M.J. Collins Jr., P.L. Gorelick, and J.M. Ward. 1994. Helicobacter hepaticus sp. nov., a microaerophilic bacterium isolated from livers and intestinal mucosal scrapings from mice. J. Clin. Microbiol. 32:1238–1245. [PMC free article] [PubMed]
50. Jankovic, D., M.C. Kullberg, N. Noben-Trauth, P. Caspar, W.E. Paul, and A. Sher. 2000. Single cell analysis reveals that IL-4 receptor/Stat6 signaling is not required for the in vivo or in vitro development of CD4+ lymphocytes with a Th2 cytokine profile. J. Immunol. 164:3047–3055. [PubMed]
51. Ge, Z., D.A. White, M.T. Whary, and J.G. Fox. 2001. Fluorogenic PCR-based quantitative detection of a murine pathogen, Helicobacter hepaticus. J. Clin. Microbiol. 39:2598–2602. [PMC free article] [PubMed]

Articles from The Journal of Experimental Medicine are provided here courtesy of The Rockefeller University Press
PubReader format: click here to try

Formats:

Related citations in PubMed

See reviews...See all...

Cited by other articles in PMC

See all...

Links