Interleukin-27 as a Novel Therapy for Inflammatory Bowel Disease: A Critical Review of the Literature

Abstract

Inflammatory bowel disease (IBD) is an inflammatory disorder of the intestine that affects an estimated 329 per 100,000 people in the United States and is increasing in incidence within a number of cultures worldwide. Likely due to its incompletely understood pathophysiology and etiology, the standard treatments for IBD are only efficacious in subsets of patients and often do not induce lasting remission. As a result, novel therapies are needed. The success of anti–tumor necrosis factor-α treatment in a subset of patients with IBD demonstrated that therapy targeting a single cytokine could be efficacious in IBD, and clinical trials investigating the blockade of a variety of cytokines have commenced. Interleukin (IL) 27 is a relatively recently discovered type I cytokine with established roles in infectious disease, autoimmunity, and cancer in a variety of organs. IL-27 was identified as a candidate gene for IBD, and a number of studies in mouse models of IBD have demonstrated that IL-27 therapy is protective. However, in contrast to these investigations, genetic deletion of the IL-27 receptor has been shown to be protective in some mouse models of IBD. The purpose of this review is to highlight the recent literature investigating the role of IL-27 in IBD and to discuss the possible explanations for the sometimes conflicting results of these studies. Evidence supporting IL-27 therapy as a treatment for IBD will also be discussed.

Inflammatory bowel disease (IBD) refers to a collection of idiopathic inflammatory disorders of the intestine, the most common of which are Crohn's disease and ulcerative colitis. IBD is thought to result from an abnormal inflammatory response to commensal organisms and other antigens normally confined to the intestinal lumen owing to compromise of the mucosal epithelial barrier and subsequent inappropriate exposure of the resident intestinal immune cells to luminal antigens. A single cause for IBD has not been identified. Development of the disease is likely multifactorial, because a variety of etiologic factors, including hygiene status, previous gastrointestinal infection, genetics, diet, and various other lifestyle factors, have been implicated in its pathogenesis.¹ Geographically, the highest incidence of IBD has been reported in northern Europe and North America, where an estimated 329 per 100,000 people in the United States have IBD.^1,2

Treatment for IBD typically involves some form of immunosuppression, necessitating a balance between achieving remission and managing the potential adverse effects. Additionally, likely due to the complex pathophysiology and the multifactorial etiology of IBD, rates for remission induction and maintenance with many of the current standard treatments for IBD remain modest and are often variable.^3,4 As a result, investigation into novel therapeutic targets is sorely needed. The success of anti–tumor necrosis factor (TNF)-α treatment in a subset of patients with IBD demonstrated that therapy targeting a single cytokine could be efficacious in IBD, and antibodies against a variety of cytokines, including interleukin (IL)-13, IL-18, and IL-21, have entered clinical trials.³

IL-27 is a relatively recently discovered type I cytokine with established roles in infectious disease, autoimmunity, and cancer in a variety of organs, including the central nervous system, lung, skin, and gastrointestinal tract.^5,6 However, it has not been definitively determined whether IL-27 ameliorates or promotes intestinal inflammation, because seemingly contradictory roles for IL-27 have been reported in murine models of IBD.⁶ Several excellent reviews have recently discussed the biology of IL-27.^6,–9 The purpose of this review is to highlight recent literature investigating the role of IL-27 in IBD, and to discuss possible explanations for the conflicting results of these studies. Evidence supporting IL-27 therapy as a potential treatment for IBD will also be discussed.

IL-27 and its Receptor

IL-27 is a heterodimeric type I cytokine in the IL-12 cytokine family. It is composed of 2 subunits: Epstein-Barr virus–induced gene 3 and p28, so named because of its predicted molar mass by sodium dodecyl sulfate–polyacrylamide gel electrophoresis.^5,8 IL-27 is predominantly produced by myeloid cells, such as macrophages and dendritic cells, but can also be expressed by the epithelial cells, plasma cells, and endothelial cells.⁶ A variety of signals can induce IL-27 expression, including CD40 ligation, type I and II interferon signaling, and Toll-like receptor (TLR) signaling.⁶ IL-27 expression induced by TLR signaling has been shown to require interferon-α in human macrophages and interferon regulatory factor 3 in murine dendritic cells.^10,11

IL-27 signals through a heterodimeric receptor consisting of IL-27Rα, previously termed TCCR or WSX-1, and gp130.^6,12 The coexpression of both receptor subunits has been detected in T and B lymphocytes, mast cells, natural killer (NK) cells, NK T cells, monocytes, neutrophils, dendritic cells, intestinal epithelial cells, and endothelial cells.^12,–15 Interestingly, expression of the receptor differs among T cell subsets. IL-27Rα is highly expressed by regulatory, effector, and memory T cells, and increases with T cell activation. In contrast, naive T cells express low levels of IL-27Rα. NK and NK T cells express high levels of IL-27Rα, but activation of these cells results in decreased expression of this receptor subunit.¹⁵ Ligation of the IL-27 receptor induces signaling through the Jak/signal transducer and activator of transcription (STAT) pathway, resulting in the phosphorylation of STAT1, 3, 5, or 6.^7,16 In addition to the Jak/STAT pathway, the activated IL-27 receptor has been reported to induce p38mitogen-activated protein kinase (MAPK), ERK, and Akt signaling. IL-27 signaling also induces suppressor of cytokine signaling 3 (SOCS3), a suppressor of IL-27 signaling that directly binds to and inhibits the gp130 receptor subunit and the associated Janus kinases and later facilitates their degradation.⁷

IL-27 Activities in the Immune System

IL-27: The T Cell Police

IL-27 boasts a diverse repertoire of functions in both the adaptive and innate branches of the immune system; however, the most well-known and thoroughly investigated functions of IL-27 relate to its ability to regulate the adaptive immune system by modulating T cell function. When first discovered, IL-27 was reported to induce the expansion of naive murine and human CD4⁺ T cells and to act synergistically with IL-12 to enhance interferon-γ production by both naive T cells and NK cells.⁵ IL-27 blocks Th2 cytokine expression and the differentiation of Th2 cells by simultaneously increasing the expression of the transcription factor T-bet while suppressing GATA-3 expression.¹⁷ Additionally, IL-27 can prevent the expression of both IL-17A and IL-17F by suppressing retinoic acid receptor-related orphan receptor γt (RORγt), a transcription factor necessary for Th17 cell differentiation.¹⁸ IL-27 also inhibits the production of Th17-polarizing cytokines by human dendritic cells. To demonstrate the functional consequences of this inhibition, Murugaiyan et al¹⁹ showed that human memory CD4⁺ T cells cocultured with dendritic cells stimulated with both TLR agonists and IL-27 produced significantly less IL-17 than those exposed to dendritic cells activated by TLR ligands alone.

Additional noteworthy effects of IL-27 on T cells include its ability to prevent Fas-mediated activation-induced cell death²⁰ and to induce IL-10 production.⁶ The ability of IL-27 to stimulate the expression of IL-10 by T cells is perhaps one of its most extensively characterized immunoregulatory functions, having been demonstrated in models of parasitic, viral, and autoimmune diseases.⁶ IL-27 induces IL-10 and T cell immunoglobulin and mucin domain-3 in both CD4⁺ and CD8⁺ T cells by the expression of the transcription factor nuclear factor, interleukin-3 regulated²¹ and also induces the production of IL-10 by Th1 and Th2 cells in a STAT1- and STAT3-dependent manner.²² Even under Th17-polarizing conditions, generally thought to drive primarily proinflammatory cytokine production, the addition of IL-27 elicits significant increases in IL-10 production by human CD4⁺ T cells.¹⁹ Multiple studies have also demonstrated a critical role for IL-27 in the development of IL-10-secreting T regulatory type 1 cells in both humans and mice.^19,23,–27 Interferon-γ and IL-27 have both been shown to promote T-bet⁺ CXCR3⁺ regulatory T cells specialized in modulating Th1 responses; however, the development of this regulatory response in the gut-associated lymphoid tissue required IL-27.¹⁶ Although IL-27 could play a role in the regulation of T regulatory cells by suppressing IL-2, the significance of this potential negative regulatory function has not been characterized in wild-type animals.²⁸

IL-27's Role in Innate Immunity

In addition to its impressive repertoire of regulatory functions in T cell biology, IL-27 has been demonstrated to have a number of both modulatory and complementary roles in innate immunity. After identifying the receptor responsible for IL-27 signaling, Pflanz et al¹² showed that IL-27 induced proinflammatory gene expression in both human mast cells and monocytes, but that this increase in expression occurred in notably fewer genes and at a later time point in monocytes. In contrast, in murine Trichuris muris infection and a murine model of mast cell–dependent passive cutaneous anaphylaxis, mice with genetic deletion of IL-27Rα had enhanced mast cell responses, suggesting that IL-27 may also negatively regulate mast cell activities under certain circumstances.²⁹ IL-27 also acts on dendritic cells. IL-27 can induce the expression of the regulatory molecule CD39 on dendritic cells,³⁰ and when applied to monocyte-derived dendritic cells during their differentiation, IL-27 improved antigen processing and subsequent T cell stimulation.³¹

A critical role for IL-27 in the suppression of neutrophil and monocyte function has been identified that demonstrated strikingly different outcomes in models of infectious disease based on the timing of IL-27 signaling.^32,33 Mice with genetic deletion of IL-27Rα had more severe pulmonary histopathology and greater mortality after influenza infection than wild-type mice, suggesting that IL-27 signaling is protective in influenza infection. In support of this finding, IL-27 treatment of mice in the late stage of influenza infection decreased both clinical signs of disease and lung histopathology scores without reducing the clearance of the virus.³² This improvement in pathology corresponded to significantly lower pulmonary infiltrates of both neutrophils and monocytes, which were proposed by the authors to be due to IL-27–mediated suppression of the chemokines CXCL1, CCL5, and CCL4. However, in sharp contrast to this beneficial function of IL-27, the reduction of neutrophil and monocyte infiltrates owing to the administration of IL-27 early in influenza infection prevented viral clearance and worsened the clinical signs of disease. Accordingly, the highest endogenous levels of the IL-27 p28 subunit in wild-type mice were measured in the late phase of influenza infection as the viral load was declining,³² suggesting that endogenous release of IL-27 can be precisely timed for limiting collateral damage from the inflammatory response while not hindering pathogen clearance.

However, data from a model of septic murine peritonitis provide more evidence for the sometimes deleterious effects of the direct suppression of innate responses by IL-27.³³ Mice lacking the Epstein-Barr virus–induced gene 3 subunit of IL-27 had reduced mortality associated with greater bacterial clearance during septic peritonitis induced by cecal ligation and puncture. The authors further demonstrated that these mice lacking functional IL-27 had more robust intraperitoneal granulocytic infiltrates after cecal puncture, and that IL-27 directly inhibited the bacterial lipopolysaccharide–induced production of reactive oxygen intermediates by both granulocytes and macrophages/monocytes from wild-type mice.³³ Wild-type mice were shown to upregulate the expression of IL-27 within 6 hours of cecal puncture,³³ further suggesting that, when applied early in infection, the immunosuppressive effects of IL-27 may result in reduced pathogen clearance and more severe disease. Complementary to these findings in mice, IL-27 has also been shown to suppress human neutrophil adhesion and bacterial lipopolysaccharide–induced reactive oxygen species production in vitro.¹⁴

Collectively, these data inform critical stipulations for the use of IL-27 or anti–IL-27 as a therapy. As suggested by Wirtz et al,³³ the inhibition of IL-27 signaling may prove effective in conditions such as sepsis in which infection control is key. Alternatively, the administration of IL-27 could be a novel tool for limiting immunopathology in autoimmune diseases and later in the course of infections when dampening inflammation becomes a greater priority than controlling pathogens. However, for both of these potential applications, the timing of therapy and the presence of primary or secondary infections would be crucial factors in determining the treatment regimens.

IL-27 as a Therapy for IBD: Evidence from Human Patients and Mouse Models

IL-27 Polymorphisms and Mutations in IBD and Cancer

Multiple studies have implicated IL-27 as a candidate gene for IBD.^34,–36 A genome-wide association study in early-onset IBD identified IL-27 within a susceptibility locus in a North American–European cohort. In support of this conclusion, the authors also demonstrated that healthy individuals with 2 copies of the risk allele expressed significantly less IL-27 relative to individuals with 2 copies of the nonrisk allele and that colonic expression of IL-27 was significantly lower in patients with early-onset Crohn's disease than in healthy controls.^34,IL-27 polymorphisms have also been associated with risk for IBD in both Chinese and Korean populations.^35,36

The IL-27 receptor, either wild type or mutated, can contribute to hematopoietic cell transformation.^37,38 Although IBD predisposes to colorectal cancer and IL-27 polymorphisms affect the risk for IBD, thus far the potential role of IL-27 polymorphisms in colorectal cancer is unclear, because studies evaluating their association with the risk for colorectal cancer produced conflicting results.^39,–42

IL-27 Ameliorates Colitis Induced by T Cell Transfer or Chemical Induction in Mice

Multiple studies have demonstrated the ability of IL-27 to ameliorate colitis in mice, either through lessening of induced colonic inflammation by IL-27 administration or demonstration of more severe colitis in mice deficient in IL-27 due to either antibody-mediated neutralization or genetic knockout.^43,–47 Mucosal administration of IL-27 synthesized in situ by a food-grade bacterium improved the survival and significantly decreased the disease activity, colon and small intestine histopathology scores, and proinflammatory gene expression within the intestine in a mouse model of enterocolitis induced by T cell transfer.⁴⁴ The treatment effects in this study depended on both T cells and IL-10; however, mucosal delivery of IL-27 was found to be more efficacious than direct mucosal delivery of IL-10 by the bacteria. A possible explanation is that IL-27 induces higher levels of endogenous IL-10 in the intestine and mesenteric lymph nodes than could be achieved by the bacteria producing IL-10 in situ. Interestingly, mucosal delivery of IL-27 was also more effective than systemic administration of recombinant murine IL-27 in this study, which had no detectable therapeutic effect.⁴⁴ Consistent with previous literature,¹⁸ IL-27 treatment significantly decreased the expression of RORγt in the colons of enterocolitic mice in this study, and likely as a result, decreased the expression of both IL-17A and IL-17F as well. This study went further to show that IL-27 treatment also reduced disease activity in dextran sulfate sodium (DSS)–induced colitis, a widely used chemically induced model of colitis.⁴⁴

Subcutaneous treatment with IL-27 in an acute chemically induced model of colitis using 2,4,6-trinitrobenzenesulfonic acid (TNBS) was also reported to be protective,⁴⁶ with improved colonic macroscopic and histopathology scores and reductions in several of the same proinflammatory cytokines previously reported,⁴⁴ including IL-6, TNF-α, IL-17A, and IL-1β.⁴⁶ The ability of subcutaneous IL-27 treatment to protect the mice in this study from TNBS-induced colitis contrasts with the previously discussed findings of Hanson et al,⁴⁴ in which systemically administered IL-27 by intraperitoneal injection showed no therapeutic effect. However, in addition to a different route of injection, the most beneficial effects of subcutaneous IL-27 treatment were at a higher dose than that administered intraperitoneally in the other study, and these 2 studies evaluated IL-27 treatment in 2 mechanistically very different models of colitis (acute chemically induced versus chronic T cell transfer), potentially explaining this discrepancy. The ability of IL-27 to reduce intestinal inflammation by multiple routes of administration could be an advantage clinically, making it a more versatile therapy.^44,46

Ablation of IL-27Rα is Proinflammatory in Murine Models of Colitis

Additional studies have indirectly demonstrated the anti-inflammatory effects of IL-27 in intestinal inflammation by documenting the impact of its absence. Antibody neutralization of IL-27 in mice infected with Citrobacter rodentium precipitated more severe colitis and increased the production of IL-6.⁴³ In another study, a more proinflammatory phenotype was observed in regulatory T cells lacking IL-27Rα, which produced more IL-17 and less IL-10 than regulatory T cells from wild-type mice.⁴⁵ The consequences of this altered phenotype because of IL-27Rα deletion were reported by another laboratory using the T cell transfer model of enterocolitis. In this model, naive CD4⁺ T cells are transferred into an immunodeficient recipient mouse, resulting in enterocolitis. However, the cotransfer of regulatory T cells can prevent the development of enterocolitis in this model. Interestingly, Do et al⁴⁸ demonstrated that Foxp3⁺ regulatory T cells lacking IL-27Rα cotransferred with naive CD4⁺ T cells were, unlike their wild-type counterparts, unable to prevent the development of colitis. This group further showed that IL-27 stimulation of both human and murine regulatory T cells enhanced their ability to suppress inflammation and induced the expression of Lag3, a surface receptor critical for the suppressive function of regulatory T cells.⁴⁸

Complementary to these findings, the induction of regulatory T cells by IL-10–secreting B cells depends on IL-27 signaling in T cells. Genetic deletion of IL-27Rα on CD4⁺ T cells or neutralization of IL-27 blocked the induction of regulatory T cells by IL-10–secreting B cells. This loss of IL-27 signaling also limited the ability of these B cells to suppress proinflammatory cytokine production by both T cells lacking IL-27Rα and wild-type T cells in the presence of antibody-neutralized IL-27. Remarkably, while wild-type B cells cotransferred with wild-type CD4⁺ T cells reduced intestinal pathology, due to T cell transfer; this effect was absent when the transferred T cells lacked IL-27Rα, demonstrating that IL-27 signaling is critical for the suppression of T cell–driven intestinal inflammation by IL-10–secreting B cells.²⁵

In the DSS chemically induced model of colitis, mice lacking the IL-27 receptor had significantly increased ratios of Th17 to Th1 cells in the mesenteric lymph nodes and colon both before and after DSS treatment compared with wild-type controls.⁴⁷ These mice developed more severe colitis more quickly when administered DSS compared with wild-type controls and were significantly less likely to survive DSS exposure.⁴⁷

IL-27 Suppresses the Innate Inflammatory Response

Recent experiments have shown that mucosally administered IL-27 improves the histopathology scores in both the DSS (Andrews, DVM, March 2015, unpublished data) and TNBS models of acute chemically induced colitis.⁴⁹ In the TNBS model, this IL-27 treatment significantly reduced neutrophil infiltrates in inflamed segments of the colon.⁴⁹ These data complement the findings of Li et al,¹⁴ in which IL-27 treatment of human neutrophils suppressed their adhesion capability in vitro. Furthermore, IL-27 treatment of neutrophils in this study reduced gene and protein expression of the integrin Mac-1, which the authors proposed as a possible mechanism for the suppression of neutrophil adhesion by IL-27.¹⁴ Additionally, a separate study found that IL-27 treatment of neutrophils stimulated with a TLR ligand in vitro significantly reduced the production of the proinflammatory cytokines IL-6 and IL-12/IL-23p40.⁴⁷

Further supporting a suppressive role for IL-27 on the innate immune system, the deletion of IL-27Rα in RAG^−/− mice lacking T and B cells made them more sensitive to DSS-induced colitis.⁴⁷ These findings suggest that although IL-27 treatment may depend on the modification of T cell function under certain conditions, its effects on the innate immune system alone may be sufficient for protection against some types of intestinal inflammation, widening its potential therapeutic indications. Collectively, these data lend further support for an immunosuppressive role of IL-27 in both innate and adaptive immunity in the intestine.

Additional Protective Functions of IL-27 in the Intestine

In addition to the studies described above, which directly investigated the role of IL-27 in mouse models of intestinal inflammation, a number of studies have uncovered immunomodulatory and protective roles for IL-27 in the intestine while examining other aspects of intestinal biology. IL-27 promotes oral tolerance⁵⁰ and mediates the ability of Bifidobacterium infantis to suppress IL-17 expression.⁵¹ Additionally, IL-27 was elevated in Fat-1 mice in chronic DSS-induced colitis in association with improved histopathology scores and decreased expression of Th17 cell cytokines.⁵² IL-27 can also promote intestinal epithelial barrier integrity. Intestinal epithelial cells have been shown to upregulate the IL-27 receptor in inflammation and bacterial infection, and IL-27 signaling increased intestinal epithelial cell proliferation and antibacterial peptide production.¹³ IL-27 clearly demonstrates a variety of protective functions in the intestine, and therefore may prove to be an effective therapy for IBD.

The Other Side: Proinflammatory Effects of IL-27 in Mouse Models of Intestinal Disease

Ablation of IL-27Rα Signaling Can Attenuate Intestinal Inflammation Owing To T Cell Transfer, DSS Administration, and IL-10 Deficiency

In contrast to the evidence presented above, a collection of studies have reported deleterious effects of IL-27 in intestinal inflammation based on inhibiting IL-27 receptor signaling.^53,–56 Genetic deletion of IL-27Rα on either transferred T cells or in recipient mice effectively prevented the intestinal inflammation typical of the T cell transfer model of enterocolitis.^53,54 Increased numbers of transferred T cells lacking IL-27Rα became Foxp3⁺, suggesting that IL-27 may negatively regulate the development of Foxp3⁺ regulatory T cells.⁵³ The second study also noted that inhibition of IL-27Rα in recipient mice prevented Th17 cell development by decreasing the production of IL-1β and IL-6 by antigen-presenting cells.⁵⁴ Similarly, IL-27Rα knockout mice reportedly develop less-severe DSS-induced colitis than wild-type mice, characterized by the reduced expression of IL-6, TNF-α, and IFN-γ in intestinal lamina propria mononuclear cells.⁵⁵ IL-10–deficient mice, which spontaneously develop intestinal inflammation, also reportedly have both delayed pathology and a survival advantage when IL-27Rα is concurrently genetically deleted.⁵⁶ Interestingly, a number of these findings attributed to IL-27Rα deletion, including reduced inflammation in both the T cell transfer and DSS models of colitis and reductions in IL-1β, IL-6, and TNF- α, have also been reported as beneficial effects of IL-27 treatment, leaving more questions than answers for the interpretation of these aspects of IL-27 function. A summary of the reported roles for IL-27 in the models of murine colitis detailed above is presented in Table 1.

IL-27 and IBD: Clarity Amid the Confusion

Conflict Resolution

Although a few studies suggest that the inhibition of IL-27 receptor signaling can ameliorate intestinal inflammation, most of the literature supports IL-27 as a suppressor of intestinal inflammation caused by a variety of insults (Fig. 1). It is important to note that all of the studies favoring a proinflammatory role for IL-27 in the intestine examined specific consequences of the genetic deletion of the IL-27 receptor. In contrast, to our knowledge no report to date has demonstrated the deleterious effects of exogenous IL-27 treatment on intestinal inflammation. Additionally, based on the complex biology of IL-27 discussed above, it is not hard to imagine how complete inhibition of IL-27 signaling could eliminate the subtle checks and balances inherent to IL-27 function in wild-type animals, because IL-27 signaling elicits distinct responses based on cell type and timing. For example, genetic deletion of IL-27Rα predicted that IL-27 would be protective in influenza infection. However, the administration of IL-27 late in the course of influenza infection was beneficial, whereas IL-27 therapy early in the infection resulted in more severe disease,³² an outcome impossible to predict by the complete genetic inhibition of IL-27 signaling. Based on the ability of IL-27 to inhibit both Th2 and Th17 cell differentiation and promote T regulatory type 1 cell development,^{17,–19,23,–27} it is also reasonable to speculate that genetic ablation of IL-27 signaling could alter the differentiation and subsequent phenotype of multiple cell types, thereby creating an inflammatory microenvironment that is not representative of that of wild-type animals.

Additionally, the timing of IL-27 signaling and the evaluation of its result are critical. In human mast cells, IL-27 rapidly elicits the transcription of inflammatory cytokine genes, but elicits a slow response in human monocytes.¹² As a result, conclusions taken at a single or limited time points may not fully illustrate the results of IL-27 therapy or elimination and may contribute to discrepancies between studies. Finally, different concentrations of IL-27 have been shown to elicit distinct patterns of cytokine expression.²⁵ Different methods of IL-27 administration may produce different concentrations within the intestine, and may be an explanation for the differing results between some studies. Furthermore, the different patterns of cytokine expression induced by different concentrations of IL-27 suggest that the genetic deletion of IL-27 signaling in an entire animal or subsets of its cells may create a misleading “all or nothing” microenvironment unrepresentative of the physiologic reality.

When interpreting the literature describing the biology of IL-27, it is critical to acknowledge that each subunit of the heterodimeric IL-27 cytokine has unique biologic activities of its own.^57,58 As a result, gene and/or protein expression of either of these subunits, even if coexpressed, is not necessarily indicative of the presence of the complete IL-27 dimer, and may in fact represent production of these subunits independently or some combination of complete IL-27 and free subunits.

Interestingly, the existence of a soluble form of IL-27Rα has been described that is able to antagonize IL-27 and is thought to originate by the cleavage of the membrane-bound receptor.⁵⁹ Dietrich et al⁵⁹ reported that varying levels of soluble IL-27Rα were produced by human CD4⁺ and CD8⁺ T cells, B cells, monocyte-derived dendritic cells, and monocytes. Although only a speculation, it is interesting to question whether genetic deletion of IL-27Rα in only specific cells, such as the transferred T cells or recipient cells in the studies detailed above, could also eliminate or reduce this negative regulator of IL-27, resulting in dysregulated IL-27 signaling in remaining cells with functional IL-27Rα. The discovery of this endogenous, soluble antagonist for IL-27 is intriguing, and further research into its function and regulation could impact the concepts of IL-27 biology and potential therapeutic manipulation.

Lessons Learned from Targeting IL-17 to Treat IBD

IL-23 promotes the development of Th17 cells,^60,61 and a genome-wide association study demonstrated a significant association between variants in the IL-23R gene and both Crohn's disease and ulcerative colitis.⁶² However, although multiple studies have associated Th17 cells with the pathogenesis of IBD, the literature remains conflicted over whether their signature cytokines, IL-17A and IL-17F, drive intestinal inflammation or are protective (or both).^63,64 In contrast to the efficacy of anti-TNFα antibody treatment in a subset of patients with IBD,³ antibody neutralization of IL-17A was surprisingly inefficacious, and in some cases, deleterious in patients with moderate to severe Crohn's disease.⁶⁵ Similarly, a clinical trial investigating antibody blockade of IL-17 receptor A in moderate to severe Crohn's disease was terminated because of the lack of efficacy and worsening of disease in some patients.⁶⁶ However, 2 other therapies known to inhibit Th17 responses have shown promise as treatments for Crohn's disease and ulcerative colitis.^67,68 Vidofludimus, an inhibitor of the enzyme dihydroorotate dehydrogenase known to also inhibit the production of both IL-17A and IL-17F, induced steroid-free remission in at least 50% of both patients with Crohn's disease and ulcerative colitis in a clinical trial. Furthermore, of the remaining patients in the trial, partial remission was achieved in an additional 28.6% and 41.7% of patients with Crohn's disease or ulcerative colitis, respectively.⁶⁷ Two trials have investigated the use of tofacitinib in IBD, demonstrating that it may be an effective therapy for ulcerative colitis, but not Crohn's disease.^68,69 Tofacitinib inhibits Janus kinases 1, 2, and 3, and in doing so also blocks the differentiation of Th17 cells. Patients with moderately to severely active ulcerative colitis showed dose-dependent clinical responses and clinical remission with tofacitinib therapy. Among patients receiving the highest dose, 78% showed a clinical response and 41% achieved clinical remission after 8 weeks of treatment.⁶⁸ A shorter 4-week study found no significant reductions in Crohn's disease activity index in patients with moderate to severe Crohn's disease given tofacitinib⁶⁹; however, whether this lack of efficacy is due to differences between the 2 diseases or the shorter time of treatment (or both) is yet to be determined. Additionally, patients receiving placebo treatment in this study had a higher rate of response and remission than anticipated, leaving the authors to question whether this could have contributed to the nonsignificant difference in treatment results.⁶⁹

Interestingly, a recent study reported that antibody neutralization of both IL-17A and IL-17F, but neither cytokine alone, reduced the colon histopathology scores in the murine T cell transfer model of enterocolitis.⁷⁰ This could explain why vidofludimus and tofacitinib were more successful in clinical trials for IBD than antibody blockade of IL-17A alone, but offers little insight as to why anti–IL-17 receptor A treatment, which should inhibit signaling of both IL-17A and IL-17F,⁷¹ was inefficacious. This is particularly relevant to the discussion herein, because IL-27 is able to block the expression of both IL-17A and IL-17F through inhibition of the transcription factor RORγt.¹⁸ This potential therapeutic effect has been demonstrated experimentally in murine enterocolitis, in which decreased expression of RORγt, IL-17A, and IL-17F was reported in the colons of mice after mucosal administration of IL-27.⁴⁴ IL-27 also inhibits the development of Th17 cells by inducing the expression of programmed death ligand 1 on naive T cells, which when cultured with naive CD4⁺ T cells, prevents their differentiation into Th17 cells.⁷² However, it is unclear what effect, if any, IL-27 may have on the secretion of IL-17 by immune cells other than T cells in the inflamed intestine, such as neutrophils and mast cells, which have been shown to be important sources of IL-17 in arthritis and psoriasis.^73,74 In contrast to antibody neutralization of a cytokine or its receptor, it is interesting to question whether the administration of another cytokine, potentially more subject to endogenous regulation, could create a more physiologically relevant anti-inflammatory microenvironment that might be able to maintain balance in the pro- and anti-inflammatory effects of the immune mediators that it regulates. For example, the elimination of cytokine signaling by antibody neutralization or genetic deletion could block both its beneficial and harmful effects, whereas modulating a cytokine with one of its physiologic regulators could potentially preserve its beneficial functions.

Potential Roles for IL-27 as a Therapy for Both Crohn's Disease and Ulcerative Colitis

Although grouped together as IBD, Crohn's disease and ulcerative colitis are distinct conditions that vary both clinically and immunopathologically.⁷⁵ The lesions of Crohn's disease may be located anywhere throughout the gastrointestinal tract and are characterized by transmural infiltrates of macrophages and lymphocytes, which in many patients multifocally organize to form granulomas. In contrast, ulcerative colitis is limited to the colon and features histopathologic changes of the mucosa only, including infiltrates of granulocytes and lymphocytes. Mucosal ulceration may be present in both conditions. Based on the characterizations of cytokine expression and signaling, Crohn's disease is considered to be driven by Th1 responses, whereas ulcerative colitis is a Th2-mediated disease.⁷⁵

Despite differences in their immunopathology, there are abundant mechanisms by which IL-27 administration could be an effective therapy for both Crohn's disease and ulcerative colitis. Perhaps the most obvious mechanism by which IL-27 could reduce inflammation in IBD is through its stimulation of the immunoregulatory cytokine IL-10, which can be induced by IL-27 signaling in CD8⁺ and regulatory, Th1, Th2, and Th17 cells.^{6,19,21,–27} IL-10 boasts an incredible number of anti-inflammatory functions, including blocking Th1 and Th2 responses; inhibition of inflammatory cytokine and chemokine production by monocytes and neutrophils; limiting the recruitment of dendritic cells, T cells, neutrophils, and monocytes; inducing anergy in activated T cells; stimulating the production of IL-1 receptor antagonist and soluble TNF receptor; and reducing monocyte activation of T cells.^76,77 Complementing these functions of IL-10, IL-27 itself also limits tissue infiltration by neutrophils and monocytes, suppresses chemokine production, and inhibits the generation of reactive oxygen intermediates by both macrophages/monocytes and granulocytes.^32,33 As demonstrated in a mouse model of experimental autoimmune encephalomyelitis, IL-27's ability to induce CD39 on dendritic cells could contribute to the suppression of pathogenic T cell responses in IBD.³⁰ As ulcerative colitis has been shown to be driven by Th2 immunopathology, IL-27's capacity to block Th2 cell differentiation and cytokine expression makes it well suited to treat this condition.^17,75 Additionally, although the treatment of Th1-driven Crohn's disease with a cytokine known to promote Th1 responses sounds counterintuitive,^6,75 IL-27 is also critical for the development of T-bet⁺ CXCR3⁺ regulatory T cells in the gut-associated lymphoid tissue that are specialized for regulating Th1 cells.¹⁶ IL-10 induced by IL-27 treatment could further contribute to the regulation of exuberant Th1 immunity in Crohn's disease.^{6,19,21,–27}

How IL-27's ability to curb Th17 responses may influence its efficacy as a treatment for IBD is uncertain. However, in contrast to the failed trials investigating direct targeting of IL-17 signaling alone as a treatment for Crohn's disease, inhibition of Th17 responses is only one of the many anti-inflammatory functions that IL-27 exerts on adaptive and innate immunity. In this way, IL-27 treatment would be more analogous to vidofludimus and tofacitinib therapies, which were effective in treating ulcerative colitis and/or Crohn's disease,^67,68 and, like IL-27, exert diverse anti-inflammatory functions in addition to the blockade of IL-17A and IL-17F.

IL-27 and IL-27R Expression in IBD

Both subunits of the IL-27 receptor, IL-27Rα and gp130, are expressed at low levels in normal intestinal epithelial cells, but are upregulated in inflammation in both epithelial cells and infiltrating leukocytes.¹³ Increased expression of IL-27 in inflamed segments of the intestinal mucosa has been demonstrated in both Crohn's disease and ulcerative colitis.^13,78 Patients with active Crohn's disease have also been shown to have both significantly increased serum IL-27 and soluble IL-27Rα relative to healthy controls; however, despite an overall positive correlation between these 2 values, the ratio of cytokine to soluble receptor varied widely among patients.⁵⁹Table 2 highlights the evidence for IL-27 as a factor in human IBD.

The question remains whether elevations in IL-27 in the inflamed intestinal mucosa and serum of patients with IBD are contributing to inflammation in these patients or represent an anti-inflammatory response. However, based on the evidence presented herein, it seems most likely that these elevations in IL-27 represent an (inadequate) anti-inflammatory response in diseased segments of the intestine. Although IL-27 signaling in the intestine presumably acts on inflammatory cells, inflamed intestinal epithelial cells upregulate the IL-27 receptor and are therefore also capable of responding to IL-27.

Concluding Remarks

Although complex, the majority of the literature investigating the role of IL-27 in mouse models of IBD complements the knowledge gained from human patients and supports an antiinflammatory role for IL-27 in IBD. However, the studies suggesting a more proinflammatory role for IL-27 should not be ignored, but should rather inform future investigations into the complex physiology of this cytokine. Although it is unlikely that a single “silver bullet” treatment for all cases of IBD will ever be found, IL-27 is a promising potential therapy that warrants further investigation.

References

Author notes