CD4<Superscript>+</Superscript>CD25<Superscript>+</Superscript> Regulatory T Cells Have Divergent Effects on Intestinal Inflammation in IL-10 Gene-Deficient Mice

The regulatory effect of murine CD4⁺CD25⁺ T-cells in vivo appears to be dependent on the secretion of IL-10. The lack of IL-10 in the IL-10 gene-deficient mouse has a profoundly negative effect on the mouse’s regulation of the response to intestinal bacteria, resulting in severe enterocolitis. We investigated the effect of neonatal injection with wild-type CD4⁺CD25⁺ T-cells on the intestinal immune response in IL-10 gene-deficient mice. At the time of analysis, 8–15 weeks later, all mice demonstrated an increased, antigen-stimulated systemic response. However, the intestinal response was divergent with about half of the mice developing an intestinal inflammation with a high injury score, the other half demonstrating a remarkable reduction in injury score with a marked decrease in intestinal IFNγ release. Our data demonstrate that CD4⁺CD25⁺ T-cells can be activated in IL-10 gene-deficient mice and that this stimulation under stringent conditions has the potential to reduce intestinal inflammation.     

An imbalance in mucosal cytokine profile causes transient intestinal inflammation following an animal's first exposure to faecal bacteria and antigens

Intestinal microflora play a critical role in the initiation and perpetuation of chronic inflammatory bowel diseases. In genetically susceptible hosts, bacterial colonization results in rapid‐onset chronic intestinal inflammation. Nevertheless, the intestinal and systemic immune response to faecal bacteria and antigen exposure into a sterile intestinal lumen of a post‐weaned animal with a mature immune system are not understood clearly. This study examined the effects of faecal bacteria and antigen exposure on the intestinal mucosal and systemic immune system in healthy axenic mice. Axenic wild‐type mice were inoculated orally with a crude faecal slurry solution derived from conventionally raised mice and were analysed prior to and then at days 3, 7, 14 and 28 post‐treatment. Ingestion of faecal slurry resulted in a transient, early onset of proinflammatory interferon (IFN)‐γ, tumour necrosis factor (TNF)‐α and interleukin (IL)‐17 response that was maximal at day 3. In contrast, the transient release of the anti‐inflammatory cytokines IL‐10 and IL‐4 occurred later and was maximal at day 7. Both responses subsided by day 14. This early cytokine imbalance was associated with a brief rise in colonic and caecal histopathological injury score at day 7. The bacterial antigen‐specific systemic response was found to follow the intestinal immune response with a maximal release of both pro‐ and anti‐inflammatory cytokines at day 7. Thus, first exposure of healthy axenic wild‐type mice to normal faecal flora and antigens results in an early proinflammatory cytokine response and transient colonic inflammation that then resolves in conjunction with a subsequent anti‐inflammatory cytokine profile.     

Association with Selected Bacteria Does Not Cause Enterocolitis in IL-10 Gene-Deficient Mice Despite a Systemic Immune Response

Resident bacteria have been implicated to play a major role in the development of inflammatory bowel disease. While luminally sterile IL-10 gene-deficient mice remain disease-free, their conventionally raised littermates develop enterocolitis associated with increased numbers of luminal and mucosal adherent bacteria. To investigate the role of defined bacteria on the initiation and development of this enterocolitis, we associated luminally sterile IL-10 gene-deficient mice with pure strains of resident bacteria. Axenic, luminally sterile mice were either monoassociated with viridans group Streptococcus or Clostridium sordellii or co-associated with Bacteroides vulgatus and Clostridium sordellii. Seven to 22 weeks later the mice were analyzed for intestinal histologic injury, epithelial permeability, and an inflammatory immune response to bacterial antigens. Despite optimal colonization none of the tested bacteria caused intestinal inflammation, release of inflammatory cytokines from the epithelia, or disruption of the epithelial barrier integrity. However, in the case of association with Bacteroides vulgatus and Clostridium sordellii, a systemic immune response to bacterial-derived antigens was measured, with a magnitude similar to that seen in conventional sick Il-10 gene-deficient mice. This response was not detected in mice associated with viridans group Streptococcus. We conclude that colonization of the intestinal lumen with individual bacterial species may not be sufficient to alter epithelial barrier integrity, increase intestinal cytokine release, or cause intestinal inflammation in susceptible IL-10 gene-deficient mice, despite the ability of these same bacteria to stimulate a systemic response.     

Bacterial antigens alone can influence intestinal barrier integrity, but live bacteria are required for initiation of intestinal inflammation and injury

Intestinal flora plays a critical role in the initiation and perpetuation of inflammatory bowel disease. This study examined whether live fecal bacteria were necessary for the initiation of this inflammatory response or whether sterile fecal material would provoke a similar response. Three preparations of fecal material were prepared: (1) a slurry of live fecal bacteria, (2) a sterile lysate of bacterial antigens, and (3) a sterile filtrate of fecal water. Each preparation was introduced via gastric gavage into the intestines of axenic interleukin-10 gene-deficient mice genetically predisposed to develop inflammatory bowel disease. Intestinal barrier integrity and degrees of mucosal and systemic inflammations were determined for each preparation group. Intestinal barrier integrity, as determined by mannitol transmural flux, was altered by both live fecal bacterial and sterile lysates of bacterial antigens, although it was not altered by sterile filtrates of fecal water. However, only live fecal bacteria initiated mucosal inflammation and injury and a systemic immune response. Fecal bacterial antigens in the presence of live bacteria and sterile fecal bacterial antigens have different effects on the initiation and perpetuation of intestinal inflammation.     

A defect in epithelial barrier integrity is not required for a systemic response to bacterial antigens or intestinal injury in T cell receptor-alpha gene-deficient mice

BACKGROUND AND AIMS: Genetically induced disruption of the intestinal epithelial barrier leads to development of intestinal inflammation. In the interleukin-10 gene-deficient inflammatory bowel disease (IBD) mouse model, for instance, a primary defect in intestinal epithelial integrity occurs before the development of enterocolitis. In humans, a causal role for epithelial barrier disruption is still controversial. Although studies with first-degree relatives of IBD patients suggests an underlying role of impaired barrier function, a primary epithelial barrier defect in IBD patients has not been confirmed. The purpose of this article is to examine whether a primary epithelial barrier disruption is a prerequisite for the development of intestinal inflammation or whether intestinal inflammation can develop in the absence of epithelial disruption. We examined the intestinal epithelial integrity of the T cell receptor (TCR)-alpha gene-deficient mouse model of IBD. MATERIALS AND METHODS: In vivo colonic permeability, determined by mannitol transmural flux, was assessed in 6-week-, 12-week-, and 25-week-old TCR-alpha gene-deficient and wild-type control mice using a single-pass perfusion technique. Mice were scored for intestinal histological injury and intestinal cytokine levels measured in organ cultures. Systemic responses to bacterial antigens were determined through 48-h spleen cell cultures stimulated with sonicate derived from endogenous bacterial strains. RESULTS: In contrast with previous findings in the interleukin-10 gene-deficient IBD model, TCR-alpha gene-deficient mice did not demonstrate evidence of primary intestinal epithelial barrier disruption at any age, despite developing a moderate to severe colitis within 12 weeks. A rise in intestinal interferon (IFN)-gamma levels preceded the onset of mucosal inflammation and then correlated closely with the degree of intestinal inflammation and injury. Spleen cells from TCR-alpha gene-deficient mice released IFN-gamma in response to stimulation with endogenous luminal bacterial antigens, a finding that suggests that the systemic response to bacterial antigens occurred independently of epithelial barrier disruption. CONCLUSIONS: Intestinal inflammation and a systemic response to bacterial antigens can develop in the absence of a measurable disruption of intestinal permeability.     

Intestinal intraepithelial lymphocytes preferentially repopulate the intestinal epithelium

We have used C.B-17 severe combined immune deficiency (SCID)mice to study the repopulation of intestinal intraepithelialcells in these mice. We have found that intestinal intraepitheliallymphocytes (IELs) injected into SCID mice preferentially repopulatethe intestinal epithelium. About 5 weeks after injection wecan detect significant numbers of IEL in repopulated SCID mice.Repopulation occurs in {small tilde}70% of the injected miceand the amount of recovered cells per mouse is variable. Therecovered cells are of donor-type origin and exhibit a typicalIEL phenotype. The donor-type T lymphocytes that can sometimesbe found in other organs of IEL-repopulated SCID mice are generallyof low number. They are not stained with antibodies againstIEL-specific markers and their phenotypes appear to be moretypical for T cells normally found in these sites. In contrast,the intestinal epithelium of SCID mice cannot be efficientlyrepopulated with lymphocytes using cells of other organs includingthymocytes, Peyer's patch lymphocytes, and bone marrow cells.From our data we conclude that intestinal IELs are confinedto the intestinal epithelium and possibly contain a precursor-typecell that preferentially regenerates cells of its own population.     

beta7 Integrin expression is not required for the localization of T cells to the intestine and colitis pathogenesis

beta7 Integrins have been shown to have an important role in the localization of T cells to the intestine. Utilizing two different experimental mouse models of inflammatory bowel disease (IBD), this study was undertaken to determine if beta7 integrin expression is critical for T cell localization to the intestine and colitis pathogenesis. Transfer of CD4+ CD45RBhigh cells into immunodeficient mice results in colitis. To examine the role of beta7 integrins, donor cells were obtained from beta7 integrin gene-deficient animals and disease induction was examined following transfer into severe combined immunodeficiency (SCID) mice. Additionally, beta7 integrin gene-deficient animals were crossed to IL-2-deficient mice and the onset of spontaneous colitis that normally occurs in IL-2-deficient animals was examined. No differences in the onset or severity of spontaneous colitis was noted in animals that were deficient in both beta7 integrin and IL-2. In contrast, the onset of colitis in recipients of T cells from beta7 integrin-deficient donors was delayed significantly. In mice receiving beta7 integrin negative cells, the initial lack of colitis appeared to correlate with fewer numbers of CD3+beta7 integrin -/- donor lymphocytes present in the host colon. The eventual development of disease, however, was associated with increased numbers of donor beta7 integrin -/- lymphocytes. These results show that beta7 integrin expression is not absolutely required for T cell localization to the intestine and colitis pathogenesis.     

Oral Administration of Curcumin Emulsified in Carboxymethyl Cellulose Has a Potent Anti-inflammatory Effect in the IL-10 Gene-Deficient Mouse Model of IBD

Curcumin is a tumeric-derived, water-insoluble polyphenol with potential beneficial health effects for humans. It has been shown to have preventive as well as therapeutic effects in chemically induced murine models of colitis. To investigate whether curcumin exerts a similar effect on the spontaneous colitis in interleukin (IL)-10 gene-deficient mice, we gavaged these mice daily for 2 weeks with 200 mg/kg per day curcumin emulsified in carboxymethyl cellulose, a food additive generally used as a viscosity modifier. Mice fed the curcumin/carboxymethyl cellulose mixture and those receiving carboxymethyl cellulose alone demonstrated similar reductions in histological injury score and colon weight/length ratio compared to water-fed controls. However, significant reductions in pro-inflammatory cytokine release in intestinal explant cultures were only seen in mice treated with the curcumin mixture. Our data demonstrate that in IL-10 gene-deficient mice, both oral curcumin and carboxymethyl cellulose, appear to have modifying effects on colitis. However, curcumin has additional anti-inflammatory effects mediated through a reduced production of potent pro-inflammatory mucosal cytokines.     

VSL#3 probiotic upregulates intestinal mucosal alkaline sphingomyelinase and reduces inflammation.

BACKGROUND: Alkaline sphingomyelinase, an enzyme found exclusively in bile and the intestinal brush border, hydrolyzes sphingomyelin into ceramide, sphingosine and sphingosine-1-phosphate, thereby inducing epithelial apoptosis. Reduced levels of alkaline sphingomyelinase have been found in premalignant and malignant intestinal epithelia and in ulcerative colitis tissue. Probiotic bacteria can be a source of sphingomyelinase. OBJECTIVE: To determine the effect of VSL#3 probiotic therapy on mucosal levels of alkaline sphingomyelinase, both in a mouse model of colitis and in patients with ulcerative colitis. METHODS: Interleukin-10 gene-deficient (IL10KO) and wild type control mice were treated with VSL#3 (10(9) colony-forming units per day) for three weeks, after which alkaline sphingomyelinase activity was measured in ileal and colonic tissue. As well, 15 patients with ulcerative colitis were treated with VSL#3 (900 billion bacteria two times per day for five weeks). Alkaline sphingomyelinase activity was measured through biopsies and comparison of ulcerative colitis disease activity index scores obtained before and after treatment. RESULTS: Lowered alkaline sphingomyelinase levels were seen in the colon (P=0.02) and ileum (P=0.04) of IL10KO mice, as compared with controls. Treatment of these mice with VSL#3 resulted in upregulation of mucosal alkaline sphingomyelinase activity in both the colon (P=0.04) and the ileum (P=0.01). VSL#3 treatment of human patients who had ulcerative colitis decreased mean (+/- SEM) ulcerative colitis disease activity index scores from 5.3+/-1.8946 to 0.70+/-0.34 (P=0.02) and increased mucosal alkaline sphingomyelinase activity. CONCLUSION: Mucosal alkaline sphingomyelinase activity is reduced in the intestine of IL10KO mice with colitis and in humans with ulcerative colitis. VSL#3 probiotic therapy upregulates mucosal alkaline sphingomyelinase activity.