Amelioration of Immune-Mediated Experimental Colitis: Tolerance Induction in the Presence of Preexisting Immunity and Surrogate Antigen Bystander Effect

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Vol. 297, Issue 3, 926-932, June 2001

Amelioration of Immune-Mediated Experimental Colitis: Tolerance Induction in the Presence of Preexisting Immunity and Surrogate Antigen Bystander Effect

Israel Gotsman, Amir Shlomai, Ruslana Alper, Elazar Rabbani, Dean Engelhardt and Yaron Ilan

Liver Unit Department of Medicine, Hadassah University Hospital, Jerusalem, Israel (I.G., A.S., R.A., Y.I.); and ENZO Biochem Inc., New York, New York (E.R., D.E.)

	Abstract

Top Abstract Introduction Materials and Methods Results Discussion References

Oral tolerance is a recognized procedure for induction of antigen-specific peripheral immune hyporesponsiveness. Recently,it has been shown that oral tolerance can be used to prevent experimentalcolitis. The aim of this study was to test whether induction oforal tolerance toward proteins extracted from inflammatory andnoninflammatory colons can alleviate preexisting experimentalcolitis. Colitis was induced in BALB/c mice by intracolonic instillationof 2,4,6-trinitrobenzenesulfonic acid (TNBS). Mice received fiveoral doses of colonic proteins extracted from TNBS-induced colitisor normal colons, before, or 7 days after colitis was induced.Standard clinical, macroscopic, and microscopic scores were usedfor colitis assessment. Serum interferon $gamma$ (IFN $gamma$ ) and interleukin(IL)4 levels were measured by enzyme-linked immunosorbent assay.Feeding of colitis- or normal colon-extracted proteins before,or following colitis induction, ameliorated colonic inflammationas shown by decreased diarrhea, increased body weight, reductionof colonic ulcerations, intestinal and peritoneal adhesions, wallthickness, and edema. Histological parameters for colitis weremarkedly improved in tolerized animals, and there was a significantreduction in inflammatory response and mucosal ulcerations. Tolerizedmice developed an increase in IL4 and a decrease in IFN $gamma$ serumlevels. The results show that induction of oral tolerance to colitis-or normal colon-extracted proteins down-regulated preexistinganticolon immune response, thereby ameliorating experimental colitis.Tolerance induction was mediated via a shift from a proinflammatoryT helper (Th)1 to an anti-inflammatory Th2 immuneresponse.

	Introduction

Top Abstract Introduction Materials and Methods Results Discussion References

Inflammatory bowel diseases (IBDs) are common immune-mediated disorders of the gastrointestinal tract. An imbalance betweenTh1 proinflammatory and Th2 anti-inflammatory subtypes of immuneresponses plays a role in the pathogenesis of these disorders(Podolsky, 1991; Mizoguchi et al., 1996; Adorini and Francesco,1997). In both experimental colitis, and in patients with IBD,the disease is a Th1-mediated immune disorder, resulting in alife-long inflammatory response against the colon. Secretion ofproinflammatory cytokines such as IFN $gamma$ has been described andcontributes to an increased mucosal permeability in these settings(Strober et al., 1997). Anti-inflammatory cytokines such as IL10down-regulate the proinflammatory effects of Th1-mediated cytokines,thereby alleviating the disease (Neurath et al., 1996; Madsenet al., 1997; Van Deventer et al., 1997).

Oral tolerance is a recognized procedure for induction of antigen-specific peripheral immune hyporesponsiveness (Weiner, 1997).Enteral exposure to high antigen doses induces tolerance by clonalinactivation of antigen-specific T cells. Feeding low antigendoses leads to induction of regulatory cells secreting immunosuppressivecytokines that suppress the generation of antigen-specific effectorcells (Miller et al., 1992). Oral tolerance was previously showneffective in preventing immune-mediated disorders in animal models,such as experimental allergic encephalomyelitis, collagen-inducedarthritis, diabetes, and chronic graft versus host disease (Zanget al., 1990; Trentham et al., 1993; Von Herrath et al., 1996;Ilan et al., 2000a). Oral tolerance toward adenoviral antigenseffectively prevents the antiviral immune response (Ilan et al.,1997c) and seems superior to other modes of immune tolerance induction(Ilan et al., 1996, 1997a,b; Takahashi et al., 1996). Recently,it has been shown by us and others that oral tolerance can beused to prevent experimental colitis in a model system using micetreated with 2,4,6-trinitrobenzenesulfonic acid (TNBS) (Trop etal., 1999; Ilan et al., 2000b). This material induces an autoimmuneresponse resembling Crohn's disease in humans (Neurath et al.,1996). Initiation of oral tolerance via feeding of colitis-extractedproteins, before colitis induction, ameliorates the disease. However,clinical application of oral tolerization for patients with IBDwould require tolerance induction in the presence of preexistingimmunity and established colitis. It would also necessitate theuse of surrogate antigens rather than colitis-extracted proteins.Oral administration of antigens has been shown to alleviate antigen-specificimmune response and secondary immune response in the presenceof preexisting immunity (Ilan et al., 1998). Both in animals andhumans it has had a beneficial effect in alleviating preexistingautoimmune disorders such as scleroderma, rheumatoid arthritis,and diabetes (Weiner et al., 1993; Strobel and Mowat, 1998; Trentham,1998; Gotsman et al., 2000).

In the present study we sought to evaluate whether induction of oral tolerance toward colitis- or normal colon-extracted proteins(CEPs and NCEPs, respectively) could be used to alleviate preexistinghost anticolon immune response and ameliorate experimental colitis.The results show that induction of oral tolerance in the presenceof established disease, and the use of surrogate antigens, hada beneficial effect in alleviating experimentalcolitis.

	Materials and Methods

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Animals

BALB/c male mice, 2 to 4 months old, were obtained from Harlan Laboratories (Indianapolis, IN) and maintained in the AnimalCore of the Hadassah-Hebrew University Medical School, Jerusalem,Israel. Mice were maintained on standard laboratory chow and keptin 12-h light/dark cycles. All animal experiments were carriedout according to the guidelines of the Hebrew-University-HadassahInstitutional Committee for Care and Use of Laboratory Animalsand with the committee'sapproval.

Induction of Colitis

TNBS-colitis was induced by rectal instillation of TNBS (Sigma Diagnostics, St. Louis, MO), 1 mg/mouse, dissolved in 100 µlof 50% ethanol as described (Trop et al., 1999).

Preparation and Administration of the Oral Antigens

The colon was removed from normal or from TNBS-induced colitis colons of mice, 3 days following colitis induction; cut intosmall strips; and mechanically homogenized. Following filtrationthrough a 40-µm nylon cell strainer, the intact cells were spundown and removed. Proteins were quantified using a protein assaykit (Bio-Rad, Richmond, CA). NCEPs and CEPs were orally administeredinto mice from all experimental groups, using a feeding atraumaticneedle, 50 µg/mouse, every other day for 10 days (a total of fivedoses) as described below. This dose was found to be in the low-doseoral tolerancerange.

Experimental Groups

Six groups of mice, consisting of 10 animals each, were studied (Table 1). All mice were challenged with rectal TNBS on day1 of the study. Mice in groups A, B, and E were fed every otherday for 10 days starting on the day of colitis induction. Forevaluation of the effect of tolerance induction on establishedexperimental colitis, mice in groups C, D, and F were fed withidentical doses starting on day 7 following induction of colitis.Mice in groups A and C were fed with CEP. For evaluation of theeffects of surrogate antigens on tolerance induction, mice ingroups B and D were fed with NCEP. Mice in control groups E andF were fed with identical doses of bovine serum albumin (BSA).Mice in all groups were sacrificed 21 days following colitis induction.

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TABLE 1
Experimental and control groups

Evaluation of the Effect of Preexisting Immunity and Surrogate Antigens on Oral Tolerance Induction in the Experimental Colitis Model. The role of presensitization toward target antigens and surrogate antigens on tolerance induction was evaluated by monitoringthe following parameters forcolitis.

Clinical assessment of colitis. Diarrhea was followed daily throughout the study. Body weights were measured before colitis induction, and at the end of studyin all experimentalgroups.

Macroscopic score of colitis. Colitis assessment was performed 21 days following colitis induction, using four standard macroscopic parameters, namely,degree of colonic ulcerations, intestinal and peritoneal adhesions,wall thickness, and degree of mucosal edema (Ilan et al., 2000b).Each parameter was graded on a scale from 0 (completely normal)to 4 (most severe). Coded specimens were scored by two experiencedexaminers.

Grading of histological lesions. For histological evaluation of inflammation, distal colonic tissue (last 10 cm) was removed and fixed in 10% formaldehyde.Five paraffin sections from each mouse were then stained withH&E by using standard techniques. The degree of inflammation onmicroscopic cross sections of the colon was graded semiquantitativelyfrom 0 to 4 (Ilan et al., 2000b): grade 0, normal with no signsof inflammation; grade 1, very low level of leukocyte infiltration;grade 2, low level of leukocyte infiltration; grade 3, high levelof infiltration with high vascular density and bowel wall thickening;and grade 4, transmural infiltrates with loss of goblet cells,high vascular density, wall thickening, and disruption of normalbowel architecture. Coded specimens were scored by two experiencedexaminers.

Evaluation of the Mechanism of Immune Tolerance Induction. Serum IL4 and IFN $gamma$ levels. Serum IL4 and IFN $gamma$ levels were measured by a "sandwich" enzyme-linked immunosorbent assay, usingGenzyme Diagnostics kits (Genzyme Diagnostics, Boston, MA) accordingto manufacturer's instructions. Serum levels were measured inall mice from all experimental and control groups 20 days followingcolitisinduction.

Statistical Analysis

Statistical differences were calculated by the Student's t test. Mice were compared with their respective control group: Micein experimental groups A and B were compared with control groupE, and mice in experimental groups C and D were compared withcontrol groupF.

	Results

Top Abstract Introduction Materials and Methods Results Discussion References

Evaluation of Effect of Preexisting Immunity and Surrogate Antigens on Oral Tolerance Induction in Experimental Colitis Model

Clinical Assessment of Colitis. A marked decrease in diarrhea was observed in tolerized mice from group A fed with mouse CEP. A similar beneficial effectwas observed in mice treated with mouse-derived NCEP in groupB, which were fed starting on day 1. A partial beneficial effectwas observed in mice in which tolerance was induced in the presenceof established colitis (groups C and D). In contrast, mice incontrol groups E and F fed with BSA suffered severediarrhea.

A follow-up observation of mouse body weight disclosed a statistically significant increase in body weight among tolerizedmice in group A compared with control mice in group E (11.7 versus4.2%, respectively, p < 0.005, Fig. 1). A similar beneficial effectwas observed in mice from group B treated with mouse-derived NCEP,and their weight increased by 8.9% (p < 0.005). A favorable effectwas also observed in mice fed with CEP and NCEP starting 7 daysfollowing induction of colitis (9.3 and 7.2% increase in bodyweights for groups C and D, respectively, p < 0.005 compared withcontrol mice in group F). In contrast, no significant increasein body weight was noted in mice treated with BSA. Their bodyweights increased by 4.2 and 4.1%, respectively, for mice in groupsE and F (Fig. 1).

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Fig. 1. Effect of tolerance induction toward colitis and normal colon-extracted proteins on body weights in mice with experimental colitis. Follow-up of mouse body weight disclosed a statistically significant increase in body weight in tolerized mice in group A compared with control mice in group E (p < 0.005). A similar beneficial effect was observed in mice from group B treated with mouse-derived NCEP (p < 0.005). A favorable effect was also observed in mice fed with CEP and NCEP starting 7 days following induction of colitis (p < 0.005 compared with control mice). In contrast, no significant increase in body weight was noted in mice treated with BSA.

Macroscopic Grading of Colitis. Induction of oral tolerance by feeding of mouse-extracted colitis-derived proteins (group A), or with mouse normal colon extractedproteins (group B) markedly alleviated the macroscopic gradingof colitis. The scores for tested macroscopic parameters of colitiswere degree of colonic ulceration, intestinal and peritoneal adhesions,wall thickness, and degree of mucosal edema. Total macroscopicscores measured 0.4 and 0.7 in group A and B mice, respectively,compared with 3.3 and 3.1 in nontreated controls in groups E andF, respectively (p < 0.005, Fig. 2). A favorable effect was alsoobserved in mice fed with CEP starting 7 days following colitisinduction (group C). Their total macroscopic score measured 1.2.A partial beneficial effect was noted in mice fed with NCEP starting7 days following colitis induction, and their scores were 1.9(p < 0.005 compared with control mice in group F, Fig. 2).

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Fig. 2. Effect of tolerization on macroscopic grading of colitis. Parameters tested were graded on a scale from 0 (completely normal) to 4 (most severe), including degree of colonic ulceration, intestinal and peritoneal adhesions, wall thickness, and degree of mucosal edema. All tested parameters were significantly down-regulated in tolerized mice fed with mouse-extracted colitis-derived proteins (group A), or with mouse normal colon-extracted proteins (group B), compared with nontreated controls in groups E and F (p < 0.005). A favorable effect was also observed in mice fed with CEP starting 7 days following colitis induction (group C, p < 0.005 compared with control mice). A partial beneficial effect was noted in mice fed with NCEP starting 7 days following colitis induction.

Grading of Histological Lesions. Histological evaluation of bowel tissue showed a marked reduction in inflammatory response and mucosal ulcerations in tolerizedmice in groups A, B, C, and D, compared with nontolerized controlmice in groups E and F. In mice in groups A and B, almost normalsections or only minimal lymphocytic infiltration was detected(Fig. 3, A and B). In contrast, severe inflammatory reaction (grade3-4) was observed in bowel specimens taken from nontolerized controlmice (Fig. 3, E and F). A partial effect was observed in micefed with CEP or NCEP starting 7 days following colitis inductionin groups C and D (Fig. 3, C and D). The results of standard pathologicaltests in tolerized mice from groups A, B, C, and D produced scoresof 0.4, 1.2, 1.4, and 1.95, respectively. Control nontreated micein groups E and F exhibited severe microscopic colitis, with pathologicalscores of 3.1 and 3.25, respectively (p < 0.005 compared withcontrol mice, Fig. 4).

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Fig. 3. Effect of tolerization on histological evaluation of bowel mucosa in experimental colitis: a marked reduction in inflammatory response and mucosal ulcerations was noted in tolerized mice in groups A, B, C, and D, compared with nontolerized control mice in groups E and F. In mice in groups A and B, almost normal sections, or only minimal lymphocytic infiltration, was detected (A and B). In contrast, severe inflammatory reaction (grade 3-4) was observed in bowel specimens taken from nontolerized control mice (Fig. 3, E and F). A partial effect was observed in mice fed with CEP or NCEP starting 7 days following colitis induction in groups C and D (C and D).

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Fig. 4. Effect of tolerization on the microscopic grading of experimental colitis. The results of standard pathological tests in tolerized mice from groups A, B, C, and D produced significantly lower scores compared with control nontreated mice in groups E and F (p < 0.005).

Mechanism of Immune Tolerance Induction by Administration of Surrogate Antigens in the Experimental Colitis Model

Serum IL4 and IFN $gamma$ Levels. Tolerized mice manifested a shift from a Th1 to Th2 immune response cytokine secretion. The feeding of mouse-derived CEP inducedan increase in IL4 levels and a decrease in IFN $gamma$ serum levels20 days following colitis induction, to 22.4 ± 5 and 1.2 ± 0.7pg/ml, respectively (group A, p < 0.005 compared with controlgroup E, Fig. 5). Similarly, the feeding of mouse-derived NCEPinduced a Th1 to Th2 immune shift with IL4 and IFN $gamma$ serum levelsof 18.4 ± 1.9 and 2.4 ± 0.9, respectively (group B, p < 0.005).Primed mice that were tolerized in the presence of preexistingdisease fed with CEP or NCEP exhibited a similar cytokine paradigm,and their IL4 levels increased to 16.4 ± 2.9 and 10.3 ± 1.1, whereastheir IFN $gamma$ serum levels measured 6.3 ± 0.9 and 7.3 ± 1.1 (groupsC and D, respectively). In contrast, mice from nontolerized controlgroups E and F, exhibited high IFN $gamma$ and low IL4 serum levels (18.4± 2.7 and 1.9 ± 0.3 and 22.1 ± 1 and 2.1 ± 0.5, respectively,p < 0.005 compared with control mice in group F, Fig. 5).

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Fig. 5. Effect of oral tolerization on serum IL4 ( $black-square$ ) and IFN $gamma$ (

) serum levels. Tolerized mice manifested a shift from a Th1 to Th2 immune response cytokine secretion. The feeding of mouse-derived CEP induced an increase in IL4 levels and a decrease in IFN $gamma$ serum levels 20 days following colitis induction (group A). Similarly, the feeding of mouse-derived NCEP induced a Th1 to Th2 immune shift with IL4 and IFN $gamma$ serum levels (group B, p < 0.005). Primed mice that were tolerized in the presence of preexisting disease fed with CEP or NCEP exhibited a similar cytokine paradigm, with increased IL4 and decreased IFN $gamma$ serum levels (groups C and D, respectively, p < 0.005 compared with control mice in group F). In contrast, mice from nontolerized control groups E and F exhibited high IFN $gamma$ and low IL4 serum levels.

	Discussion

Top Abstract Introduction Materials and Methods Results Discussion References

Oral administration of low doses of colitis-extracted proteins to mice with experimental colitis was shown to have inducedimmune tolerance in the presence of established colitis. Toleranceinduction down-regulated the inflammatory response and alleviatedthe disease. Moreover, the feeding of normal colon-extracted proteinshad a significant beneficialeffect.

Oral tolerance is an effective means of inducing antigen-specific immunological hyporesponsiveness (Weiner, 1997; Trop etal., 1999). Oral tolerance has been shown effective in preventingvarious immune-mediated disorders. Both in experimental animalsand in humans, tolerance induction is associated with a shiftfrom a Th1 proinflammatory to a Th2 anti-inflammatory state, withsecretion of immunosuppressive cytokines (Ilan et al., 2000b).The preventive role of oral tolerance via administration of low-dosecolitis-extracted proteins on development of experimental colitiswas recently shown by others and by us (Ilan et al., 2000b). Ina model system that uses mice injected with TNBS, a Th1-mediatedimmune disorder is induced, leading to an experimental colitissimilar to the human disease. By feeding a mixture of colonicproteins exposed to TNBS or with colitis-extracted proteins, thehost colonic inflammatory response was inhibited, thereby preventingthe development of clinical, macroscopic, and microscopic manifestationsof colitis (Neurath et al., 1996; Ilan et al., 2000b). Toleranceinduction in this model replaced a Th1-proinflammatory with aTh2-anti-inflammatory type of immune response (Ilan et al., 2000b).Adoptive transfer of tolerance by transplantation of splenocytesfrom tolerized donors to sublethally irradiated recipients furthersupports the presence of suppressor cells in this setting. However,clinical application of this mode of therapy would require toleranceinduction in the presence of preexisting colitis and the use ofsurrogate antigens extracted from a nondiseasedbowel.

The results of the present study show for the first time that it is possible to induce tolerance toward colitis-extractedproteins in animals with established colitis. Although toleranceinduction in immunologically primed animals with preexisting diseasewas less pronounced than when preventive oral tolerization wasused, it alleviated the disease and was clinically significantcompared with nontolerized control groups. Immunologically primedmice with established colitis fed with colitis-extracted proteinsexhibited a significant increase in body weight and an improvementin all macroscopic and microscopic parameters of colitis (experimentalgroupC).

In several animal models, such as experimental encephalitis, uveitis, and arthritis, oral tolerance was shown to suppressan established immune response (Miller et al., 1992; Lieshmanet al., 1998). Feeding ovalbumin 7 days following immunizationproduces suppression of delayed type hypersensitivity, via suppressionof T cells (Lieshman et al., 1998). Oral tolerance down-regulatesthe secondary immune response in the presence of preexisting antiadenovirusimmunity in animals (Ilan et al., 1998). Enteral administrationof adenoviral structural proteins into preimmunized rats down-regulatedboth a humoral and cellular antiviral immune response. Oral administrationof low-dose hepatitis B virus envelope proteins effectively inhibitsantihepatitis B antibody production in mice with secondary antiviralimmunity (Gotsman et al., 2000). Several clinical trials usingoral tolerance in humans with autoimmune diseases in whom theimmune response is well established, including multiple sclerosis,rheumatoid arthritis, scleroderma, and diabetes, have been published,which show promising results (Weiner et al., 1993; Trentham, 1998).In contrast, several studies have shown that oral tolerance inductionin the setting of a previously primed animal is less effectivein down-regulating immune-mediated inflammatory response. In allergiccontact hypersensitivity models in guinea pigs, oral administrationof nickel to naive animals induces immune hyporesponsiveness andprevents subsequent induction of contact dermatitis. In contrast,oral tolerance to sensitized animals did not prevent subsequentcontact dermatitis (Van Hoogstraten et al., 1994). Antigenic variability,the administered dose, and different mechanisms in various disordersmay be responsible for this variance. The results of the presentstudy show that in the experimental colitis model, tolerance inductionin primed animals, although somewhat less pronounced, was clinicallysignificant (experimental groups A and C versus E andF).

Clinical application of oral tolerance in patients with IBD would require the use of surrogate antigens. A similar approachhas been used in trials in patients with multiple sclerosis, diabetes,and rheumatoid arthritis (Weiner et al., 1993; Weiner, 1997; Trentham,1998). A bystander effect is known to play a role in oral toleranceinduction (Miller et al., 1991; Karpus et al., 1995; Lundin etal., 1996; Von Herrath, 1997). It involves regulatory cells secretingnonantigen-specific cytokines that suppress inflammation in themicroenvironment where the fed antigen is localized. Mucosal Th2/Th3cells, secreting transforming growth factor $beta$ 1 generated by intermittentfeeding of a low-dose antigen may play a role in bystander tolerance(Von Herrath, 1997). Several studies showed only partial or noeffect of bystander oral tolerance (Miller et al., 1993; Balanset al., 1996; Carvalho et al., 1997). In the present study wehave shown that surrogate antigens derived from mouse normal colonicwall induced a beneficial effect, although less pronounced thanthe one achieved by the feeding of mouse-derived colitis-extractedproteins. This effect was more prominent when proteins were administeredpreventively than when they were given to preexisting colitis(experimental groups B and D). These results suggest that surrogateantigens, related to the disease-target epitopes, may have a similarimmunomodulating effect. They imply that closely related proteinsare being presented and processed by gut-associated lymphoid tissuein a similar way. Therefore, both administration of an antigenicallysimilar epitope, or of an epitope distinct from the disease-targetantigen, but found in the target organ, can down-regulate peripheralimmune activation. When suppressor T cells activated by antigen-presentingcell presentation of these proteins encounter similar epitopesin the colon, they secrete anti-inflammatory cytokines (Milleret al., 1991; Karpus et al., 1995). These cytokines are not antigen-specific.We believe that tolerance is induced because both disease-targetantigen and tolerizing epitopes are located in proximity to eachother. Geographical proximity and/or antigenic similarity to thedisease-target antigen may be held responsible for theseeffects.

The pathogenesis of IBD involves exposure of specific epitopes on diseased bowel mucosa through a toxic, infectious, or immune-mediatedeffect (Hibi et al., 1983; Das et al., 1990; Podolsky, 1991; Dasguptaet al., 1994; Neurath et al., 1995). These cryptic antigens incitean active autoimmune inflammatory response (Takahashi and Das,1985; Z'graggen et al., 1997). Both in humans with IBD and inanimals with TNBS-induced experimental colitis, the disease isa Th1-type immune-mediated disorder (Mizoguchi et al., 1996; Neurathet al., 1996). Stimulated cells in the inflamed mucosa produceincreased amounts of IFN $gamma$ and IL2 and reduced amounts of IL4,thereby attracting inflammatory cells and disrupting mucosal integrity.In contrast, anti-inflammatory cytokines such as IL10 down-regulatethe proinflammatory effects of Th1 cytokines and may alleviatethe disease (Madsen et al., 1997). The results of the presentstudy showed that induction of oral tolerance in mice with experimentalcolitis led to a reverse of the cytokine secretion paradigm withincreased secretion of IL4 and decreased secretion of IFN $gamma$ . Incontrast in nontolerized animals, a proinflammatory secretionpattern was observed. Successful treatment of IBD, similar tothat of other immune-mediated disorders requires overcoming theimmune response toward disease-associated target antigens. Thisinvolves generalized immunosuppression, which can bring many undesirableside effects. In contrast, induction of specific tolerance towardcolitis or normal colon-extracted antigens could potentially allowfor long-term alleviation of the disease, while leaving the generalimmunological defense of the recipientintact.

In conclusion, in the present study we have demonstrated that oral administration of colitis-extracted proteins or of surrogateantigens induced immune tolerance and down-regulated the anticoloninflammatory immune response, thus alleviating established colitis.This method opens up the possibility of understanding immune targetantigens involved in the pathogenesis of IBD and has a potentialuse in clinicalpractice.

	Footnotes

Accepted for publication January 31, 2001.

Received for publication September 19, 2000.

This work was supported in part by the following grants: Hadasit-Yissum; a grant from ENZO Biochem Inc., New York, NY; IsraelAcademy of Sciences Grant; and The Roaman-Epstein Liver ResearchFoundation (to Y.I.).

Send reprint requests to: Yaron Ilan, M.D., Liver Unit, Division of Medicine, Hadassah University Hospital, P.O. 12000, Jerusalem, Israel IL-91120. E-mail: Ilan{at}hadassah.org.il

	Abbreviations

IBD, inflammatory bowel disease; Th, T helper; IFN $gamma$ , interferon $gamma$ ; IL, interleukin; TNBS, 2,4,6-trinitrobenzenesulfonic acid; CEP, colitis-extracted protein; NCEP, normal colon extracted protein; BSA, bovine serum albumin.

	References

Top Abstract Introduction Materials and Methods Results Discussion References

Adorini L and Francesco S (1997) Pathogenesis and immunotherapy of autoimmune diseases. Immunol Today 18: 209-211[Medline].
Balans E, Carbone FR, Allison J, Miller JA and Heath WR (1996) Induction of autoimmune diabetes by oral administration of autoantigen. Science (Wash DC) 274: 1707-1709[Abstract/Free Full Text].
Carvalho BA, Verdolin SA and Vaz NM (1997) Indirect effects of oral tolerance cannot be ascribed to bystander suppression. Scand J Immunol 45: 276-281[Medline].
Das KM, Vecchi M and Sakemaki S (1990) A shared and unique epitope(s) on human colon, skin and biliary epithelium detected by a monoclonal antibody. Gastroenterology 98: 464-469[Medline].
Dasgupta A, Mandel A and Das KM (1994) Circulating immunoglobulin G1 in patients with ulcerative colitis against the colonic epithelial protein detected by a novel monoclonal antibody. Gut 35: 1712-1717[Abstract/Free Full Text].
Gotsman I, Beinart R, Safadi R, Engelhardt D, Rabbani E, Shouval D, Gorecki M, Roy Chowdhury N, Roy Chowdhury J and Ilan Y (2000) Oral tolerance towards hepatitis B antigens in a murine model. Antiviral Res 48: 17-26[Medline].
Hibi S, Also N, Ishikawa M, Watanabe M, Yoshida T, Kobayashi K, Asakura H, Tsuru S and Tsuchiya M (1983) Circulating antibodies to the surface antigens on colon epithelial cells in ulcerative colitis. Clin Exp Immunol 54: 163-168[Medline].
Ilan Y, Attavar P, Takahashi M, Davidson A, Horwitz M, Guida J, Roy Chowdhury N and Roy Chowdhury J (1996) Induction of central tolerance by intrathymic inoculation of adenoviral antigens into the host thymus permits long term gene therapy in Gunn rats. J Clin Invest 98: 2640-2647[Medline].
Ilan Y, Droguett G, Roy Chowdhury N, Yongan L, Sengupta K, Thummala NR, Davidson A, Roy Chowdhury J and Horwitz MS (1997a) Insertion of the adenoviral E3 region into a recombinant viral vector prevents antiviral humoral and cellular immune responses and permits long term gene expression. Proc Natl Acad Sci USA 94: 2587-2592[Abstract/Free Full Text].
Ilan Y, Gotsman I, Pines M, Beinart R, Alper R, Zeira M, Rabani E, Engelhardt D, Roy Chowdhury N, Roy Chowdhury J and Nagler A (2000a) Treatment of chronic graft versus host disease by induction of oral tolerance towards recipient antigens. Blood 95: 3613-3619[Abstract/Free Full Text].
Ilan Y, Jona VK, Sengupta K, Davidson A, Horwitz MS, Roy Chowdhury N and Roy Chowdhury J (1997b) Transient immunosuppression with FK506 permits long term expression of therapeutic genes introduced into the liver using recombinant adenoviruses. Hepatology 26: 949-956[Medline].
Ilan Y, Prakash R, Davidson A, Jona VK, Droguett G, Horwitz MS, Roy Chowdhury N and Roy Chowdhury J (1997c) Oral tolerization to adenoviral antigens permits long term gene expression using recombinant adenoviral vectors. J Clin Invest 99: 1098-1106[Medline].
Ilan Y, Sauter B, Roy Chowdhury N, Reddy BVN, Thummala NR, Droguett G, Davidson A, Ott M, Horwitz MS and Roy Chowdhury J (1998) Oral tolerization to adenoviral proteins permits repeated adenovirus-mediated gene therapy in rats with pre-existing immunity to adenovirus. Hepatology 27: 1368-1376[Medline].
Ilan Y, Weksler-Zangen S, Ben-Horin S, Sestiere M, Diment J, Sauter B, Roy Chowdhury N, Roy Chowdhury J and Goldin E (2000b) Treatment of experimental colitis through induction of oral tolerance towards colitis extracted proteins. Am J Gastroenterol 95: 966-973[Medline].
Karpus WJ, Kennedy KJ, Smith WS and Miller SD (1995) Inhibition of relapsing experimental autoimmune encephalomyelitis in SLJ mice by feeding the immunodominant PLP139-151 peptide. J Neurosci Res 45: 410-423.
Lieshman A, Garside P and Mowat A (1998) Immunological consequences of intervention in established immune responses by feeding protein antigens. Cell Immunol 183: 137-148[Medline].
Lundin BS, Dahlgren UIH, Hanson LA and Telemo E (1996) Oral tolerization leads to active suppression and bystander tolerance in adult rats while energy dominates in young rats. Scand J Immunol 43: 46-63.
Madsen KL, Lewis Simon A, Tavernini MM, Hibbard J and Fedorak RN (1997) Interleukin 10 prevents cytokine-induced disruption of T84 barrier integrity and limits chloride secretion. Gastroenterology 113: 151-159[Medline].
Miller A, Lider O and Weiner HL (1991) Antigen bystander suppression after oral administration of antigens. J Exp Med 174: 791-798[Abstract/Free Full Text].
Miller A, Lider O, Roberts AB, Sporn M and Weiner HL (1992) Suppressor T cells generated by oral tolerance to myelin basic protein suppress both in vitro and in vivo immune responses by the release of TGF $beta$ following antigen specific triggering. Proc Natl Acad Sci USA 89: 421-425[Abstract/Free Full Text].
Miller A, Santos LM, Das MP and Weiner HL (1993) Epitopes of myelin basic protein that trigger TGF-beta release after oral tolerization are distinct from encephalitogenic epitopes and mediate epitope-driven bystander suppression. J Immunol 151: 7307-7315[Abstract].
Mizoguchi A, Mizoguchi E, Chiba C, Spiekermann GM, Tonegawa S, Anderson CN and Bhan AK (1996) Cytokine imbalance and autoantibody production in T cell receptor- $alpha$ mutant mice with inflammatory bowel disease. J Exp Med 183: 847-856[Abstract/Free Full Text].
Neurath MF, Fuss I, Kelsall BL, Strober E and Strober W (1995) Antibodies to IL-12 abrogate established experimental colitis in mice. J Exp Med 182: 1281-1290[Abstract/Free Full Text].
Neurath MF, Kelasall BL, Presky DH, Waegell W and Strober W (1996) Experimental granulomatous colitis in mice is abrogated by Induction of TGF $beta$ -mediated oral tolerance. J Exp Med 183: 2605-2616[Abstract/Free Full Text].
Podolsky DK (1991) Inflammatory bowel disease. New Engl J Med 325: 928-935[Medline].
Strobel S and Mowat AM (1998) Immune response to dietary antigens: oral tolerance. Immunol Today 4: 173-181.
Strober W, Kelsall B, Fuss L, Marth T, Ludviksson B, Ehrhardt R and Neurath M (1997) Reciprocal IFN- $gamma$ and TGF $beta$ responses regulate the occurrence of mucosal inflammation. Immunol Today 18: 61-64[Medline].
Takahashi F and Das KM (1985) Isolation and characterization of a colonic autoantigen specifically recognized by colon tissue-bound immunoglobulin G from idiopathic ulcerative colitis. J Clin Invest 76: 311-318.
Takahashi M, Ilan Y, Sengupta K, Roy Chowdhury N and Roy Chowdhury J (1996) Induction of tolerance to recombinant adenoviruses by injection into newborn rats: long term amelioration of hyperbilirubinemia in Gunn rats. J Biol Chem 271: 26536-26542[Abstract/Free Full Text].
Trentham DE., Dynesius-Rentham RA and Orav EJ (1993) Effects of oral administration of type II collagen on rheumatoid arthritis. Science (Wash DC) 261: 1727-1729[Abstract/Free Full Text].
Trentham DE (1998) Oral tolerization as a treatment of rheumatoid arthritis. Rheum Dis Clin N Am 24: 525-534[Medline].
Trop S, Samsonov D, Gotsman I, Alper R, Diment J and Ilan Y (1999) Liver associated lymphocytes expressing NK1.1 are essential for oral tolerance induction in a murine model. Hepatology 29: 746-755[Medline].
Van Deventer Sander J, Charles O and Fedorak RN (1997) Multiple doses of intravenous interleukin 10 in steroid refractory Crohn's disease. Gastroenterology 113: 383-389[Medline].
Van Hoogstraten IMW, Blomberg BME, Boden D, Kraal G and Scheper R (1994) Non sensitizing epicutaneous skin tests prevent subsequent induction of immune tolerance. J Invest Dermatol 102: 80-83[Medline].
Von Herrath MG (1997) Bystander suppression induced by oral tolerance. Res Immunol 148: 541-548[Medline].
Von Herrath MG, Dyrberg T and Oldstone MBA (1996) Oral insulin treatment suppresses virus-induced antigen-specific destruction of $beta$ cells and prevents autoimmune diabetes in transgenic mice. J Clin Invest 98: 1324-1331[Medline].
Weiner HL, Mackin GA, Matsui M, Orav EJ, Khoury SJ, Dawson DM and Hafler DA (1993) Double blind pilot trial of oral tolerization with myelin antigen in multiple sclerosis. Science (Wash DC) 261: 1321-1324[Abstract/Free Full Text].
Weiner HL (1997) Oral tolerance: immune mechanisms and treatment of autoimmune diseases. Immunol Today 18: 335-343[Medline].
Zang ZJ, Lee CSY, Lider O and Weiner HL (1990) Suppression of adjuvant arthritis in Lewis rats by oral administration of type II collagen. J Immunol 145: 2489[Abstract].
Z'graggen K, Walz A, Mazzucchelli L, Strieter RM and Mueller C (1997) The C-X-O chemokine ENA-78 is preferentially expressed in intestinal epithelium in inflammatory bowel disease. Gastroenterology 113: 808-816[Medline].

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