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The Critical Role of LIGHT in Promoting Intestinal Inflammation and Crohn’s Disease¹

Jing Wang^2,*, Robert A. Anders^*, Yang Wang^*, Jerrold R. Turner^*, Clara Abraham^*, Klaus Pfeffer^3, and Yang-Xin Fu^3,*

^* Department of Pathology, University of Chicago, Chicago, IL 60637; and Institute of Medical Microbiology, Immunology, and Hygiene, Technical University of Munich, Munich, Germany

	Abstract

Top Abstract Introduction Materials and Methods Results Discussion Disclosures References

 
Crohn’s disease (CD) is a type of inflammatory bowel disease associated with increased Th1 cytokines and unique pathological features. However, its pathogenesis has not been fully understood. Previous studies showed that homologous to lymphotoxin, exhibits inducible expression, competes with herpesvirus glycoprotein D for HVEM on T cells (LIGHT) transgenic (Tg) mice develop autoimmunity including intestinal inflammation with a variable time course. In this study, we establish an experimental model for CD by adoptive transfer of Tg mesenteric lymph node cells into RAG^–/– mice. The recipients of Tg lymphocytes rapidly develop a disease strikingly similar to the key pathologic features and cytokine characterization observed in CD. We demonstrate that, as a costimulatory molecule, LIGHT preferentially drives Th1 responses. LIGHT-mediated intestinal disease is dependent on both of its identified signaling receptors, lymphotoxin receptor and herpes virus entry mediator, because LIGHT Tg mesenteric lymph node cells do not cause intestinal inflammation when transferred into the lymphotoxin receptor-deficient mice, and herpes virus entry mediator on donor T cells is required for the full development of disease. Furthermore, we demonstrated that up-regulation of LIGHT is associated with active CD. These data establish a new mouse model resembling CD and suggest that up-regulation of LIGHT may be an important mediator of CD pathogenesis.

	Introduction

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Inflammatory bowel disease (IBD)⁴ is characterized by a chronic relapsing inflammation of the gastrointestinal tract and is divided into two primary forms, Crohn’s disease (CD) and ulcerative colitis (UC) (1, 2). The current working hypothesis suggests that an abnormal mucosal T cell response to normal constituents of the mucosal microflora underlies the etiology of IBD (1). Specifically in CD patients, the T cell response exhibits a dominant Th1 phenotype (2) with production of large amounts of IFN-, TNF, and IL-12, which is a Th1-polarizing factor (3). Th1 cytokines have been specifically shown to be elevated in CD patients, whereas the elevation of Th2 cytokines appears to be more related to UC (2, 4, 5). Blockade of TNF with anti-TNF Abs has already proven to be a highly effective treatment in CD, and such treatment achieves positive effects in 60% of patients (6). Previous studies have shown potential mechanisms for anti-TNF action, such as induction of lymphocyte apoptosis (7, 8, 9, 10, 11, 12, 13).

CD is a complex disease with a multifactorial etiology (2, 4). Uncovering the mechanisms underlying CD has been difficult. There are three mouse models that resemble CD in disease location, histological features, and clinical course (i.e., IL-10 deficient, TNF, AU-rich regulatory element (ARE), and SAMP1/Yit mice) (14, 15, 16, 17, 18). Previous studies suggested that a Th1 phenotype is strongly associated with active CD, and the majority of animal models of CD are characterized by overproduction of Th1 cytokines (2). Studies have clearly indicated a convincing role for TNF, IL-12, and IL-18 in the pathogenesis of IBD with results from mice confirmed in human studies (11, 19, 20). However, the cytokines that act on T cells to perpetuate the dominant Th1 response in CD are undefined. Furthermore, the mechanisms by which T cells are activated, expanded, and recruited in the intestine are unclear.

Recent studies in IBD pathogenesis point to an interesting cytokine called homologous to lymphotoxin, exhibits inducible expression, competes with herpesvirus glycoprotein D for HVEM on T cells (LIGHT), a TNF superfamily member (TNF superfamily 14). LIGHT is primarily expressed on activated T cells (21, 22). LIGHT is closely related to TNF and together with lymphotoxin (LT) defines the TNF/LT core family (21, 23). LIGHT is a proinflammatory cytokine and potent T cell costimulatory molecule (24, 25, 26). Previous findings establish a crucial role for LIGHT in T cell activation and expansion by directly stimulating other T cells (26). The role of LIGHT’s involvement in IBD is hinted by several observations. First, LIGHT (27) maps to the region overlapping a susceptibility locus for IBD on human chromosome 19p13.3 (28, 29). Second, transgenic (Tg) mice with enhanced LIGHT expression on T cells develop colitis, suggesting possible contribution in the development of IBD (26, 30). Third, blocking the LT/LIGHT axis by LTR-Ig in two animal models can ameliorate the severity of colitis (31). Despite the implications of these findings, the unique and direct role of LIGHT in CD pathogenesis has not been directly examined.

LIGHT has two signaling receptors (21); LTR is expressed on stromal cells and nonlymphoid hemopoietic cells (32, 33, 34), and herpes virus entry mediator (HVEM) is expressed on T and B lymphocytes as well as other hemopoietic cells (25, 35, 36). LIGHT and LT₁₂ cooperate in lymphoid organogenesis and the development of lymphoid structures by signaling through the LTR (37, 38). It has been shown that signaling LTR via LIGHT transgene was sufficient to induce up-regulation of chemokines and adhesion molecule expression (38, 39). Presumably, the HVEM receptor is responsible for LIGHT-mediated T cell activation, although that has not been formally proven. Moreover, the distinct role of each receptor, HVEM and LTR, in LIGHT-mediated colonic pathogenesis is unclear.

We have developed a Tg model overexpressing LIGHT on T cells that develop autoimmunity including intestinal inflammation, but the time course for the development of colitis was variable in LIGHT Tg mice (39). To establish a consistent and reliable animal model in a timely fashion for the understanding of IBD pathogenesis and developing treatment, we transfer Tg mesenteric lymph node (MLN) cells into RAG^–/– mice and monitor the intestinal inflammation. The transfer of Tg MLN cells or naive thymic T cells into RAG^–/– recipient results in severe intestinal inflammation in 5–6 wk with features reminiscent of CD such as fissuring ulcers and ileitis, which were not present in the original LIGHT Tg mice. Blockade with TNFR-Ig effectively ameliorates the severity of disease. The mechanism by which LIGHT induces CD is to drive a Th1 response and promote activation/expansion of Th1 cells in the intestines via both HVEM and LTR. Our results support the notion that an initial Th1 response underlies the pathological features of CD. Furthermore, we demonstrate that a dramatic increase of LIGHT expression is associated with active CD in humans. This mouse model not only replicates CD in the intestinal pathology but also helps us to explore the immunologic mechanism of CD, identify downstream target genes, and serve as a platform for therapeutic intervention.

	Materials and Methods

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Mice

LIGHT Tg mice were generated as previously described; proximal lck promoter and CD2 enhancer were used to generate the T cell-specific LIGHT Tg mice (40). C57BL/6 (B6) LIGHT Tg mice were crossed to LTR^–/– mice in B6 background. LIGHT Tg mice were crossed to HVEM^–/– mice (crossed to B6 background for six generations) to obtain LIGHT Tg/HVEM^–/– mice. RAG-1^–/– mice (B6 background) were purchased from The Jackson Laboratory. Animal and human experimentation protocols were consistent with National Institutes of Health guidelines and were approved by the Institutional Animal Care and Use Committee at the University of Chicago.

Patient population

Clinical samples were obtained from the multi-institutional tissue bank Ardais BIGR Library (Lexington, MA). The samples were selected by searching the Ardais library for cases of UC, CD, and ischemic bowel disease. The diagnosis was determined using all available clinical and pathologic information at the time of collection. Freshly frozen tissue was harvested into optimal cutting temperature embedding solution at the participating institutions according to the Ardais standardized protocol. Each selected sample contained an accompanying series of histological photomicrographs that were secondarily reviewed to confirm the diagnosis. Clinical information beyond the pathologic diagnosis was not available for the samples selected from the Ardais library: active CD (n = 5), inactive CD (n = 5), active UC (n = 5), inactive UC (n = 5), and controls with ischemic colitis (n = 2) and neoplastic disease (n = 5). All active vs inactive samples were paired from the same patient. The demographic characteristics of the patient population and therapy were not available due to the restriction of Institutional Review Board protocol.

The generation of HVEM KO mice

A genomic bacterial artificial chromosome clone containing the HVEM locus was obtained from Genome Systems by screening a bacterial artificial chromosome library with HVEM-specific primers, derived from the HVEM mRNA sequence (muHVEM2: 5'-atg gcc tga gca agt gtc tgc-3'; and Int3Rev: 5'-aca cac cct gag aac ctg ccc ac-3'). A 8.8-kb genomic subclone (with HindIII restriction sites) with the coding sequence of HVEM was subcloned and completely sequenced. The targeting vector was constructed using homologous fragments of the HVEM locus. Exons 2, 3, and the 5' region of exon 4 was replaced by a intron gene trap cassette encompassing an engrailed two-splice acceptor sequence, a -galactosidase cassette, and a neomycin gene resistance cassette. For negative selection, a viral thymidine kinase cassette was inserted into the targeting vector. Gene targeting in E14.1 ES cells was performed as described previously (41). Screening for homologous recombinant ES cell lines was performed by PCR using the primers HVEM-SP-5' (5'-tcc ctg agg ctg aga ggt tcc-3') and pJak2 (5'-ctg aag agg agt tta cgt cca g-3'). Two of 723 G418-resistant ES cell clones gave positive signals for homologous recombination and could be verified by Southern blot analysis (EcoRI digest) using the 5' flanking probe. Single integration of the targeting vector was verified by Southern blot using a neomycin probe (NheI digest); here only one hybridization band was detectable (data not shown). Both ES cell clones containing the correctly targeted HVEM allele were injected into C57BL/6 blastocysts. The germline transmission of the inactivated HVEM locus of both cell lines was confirmed by PCR and Southern blot analysis. Heterozygous mice were backcrossed five times into the C57BL/6 strain. At the N₅ generation, homozygous offspring was obtained by intercrossing HVEM^+/– mice. In all experiments, littermates were used as controls. Genotyping for the HVEM alleles was performed by PCR using the primers HVEM-SP-5'/pJak2 for the inactivated allele and the primers HVEM-SP-5'/HVEM-SP-3'-WT (5'-aga ggc agc agg gtc agc tgg-3') for the wild-type (wt) allele. The mice were housed and crossed to C57BL/6 in a specific pathogen-free animal facility. For verification of the inactivation of the HVEM gene, a Northern blot analysis of spleen RNA was performed using the cDNA encompassing the extracellular domain of the murine HVEM.

Lamina propria lymphocyte (LPL) purification

LPL purification was performed as previously described (42). Briefly, large bowel including cecum and colon was collected from the wt or Tg recipients of the adoptive transfer. Stool was removed, and samples were washed with RPMI 140 (Mediatech). Then intestine was subject to EDTA digestion (1 mM EDTA in 1x PBS) and serial collagenase digestions (1.5 mg/ml collagenase in RPMI 140) (Sigma-Aldrich). The supernatant of collagenase digestion was collected, resuspended in 40% Percoll, and loaded onto 75% Percoll gradient (Sigma-Aldrich). The interface was collected after 20-min centrifugation at room temperature with the brake off. The cells were washed and used for FACS or intracellular cytokine staining. The cell number for LPL is from the entire large intestine including cecum, descending colon, and rectum from either wt or Tg recipients.

Flow cytometry analysis and intracellular cytokine staining

Single-cell suspensions of splenocytes, lymph node (LN) cells, or LPL were collected and stained with the following Abs: PE-anti-CD8, FITC-anti-CD8, FITC-anti-CD4, CyChrome-anti-CD4, FITC-anti-CD69, CyChrome-anti-CD44, rat anti-mouse MAdCAM-1 (MECA 367; a gift from Dr. D. Chaplin, University of Alabama at Birmingham, Birmingham, AL), PE-anti-LPAM-1 (anti-₄₇; clone DATK32), PE-anti-B220, and FITC-anti-CD3 Abs (BD Pharmingen) in PBS plus 0.01% NaN₃ for 30 min at 4°C. For biotin-labeled Ab, streptavidin-PE (Immunotech) was used as secondary Ab. For MAdCAM-1 staining, bio-goat-anti-rat IgG (BD Pharmingen) and streptavidin-PE were used. After incubation with Abs, the cells were washed and analyzed on a FACScan (BD Biosciences). Intracellular cytokine staining was performed as previously described (26). Allophycocyanin-anti-IFN- and FITC-anti-IL-4 were used for intracellular cytokine staining (BD Pharmingen). LPL purified from wt or Tg recipients was stimulated with 50 ng/ml PMA plus 500 ng/ml ionomycin for 4 h at 37°C in the presence of 10 µg/ml brefeldin A (Sigma-Aldrich).

Histopathology staining

H&E staining of intestine samples was performed as described previously (26). The mean degree of inflammation in the colon is calculated from observation of 20 different fields of H&E-stained longitudinal sections of colon from each animal. The degree of inflammation was graded as follows (31): 0, normal; 1, minor infiltration in the submucosa, presence of goblet cells, and limited elongation of the crypts; 2, large infiltration of leukocytes in the mucosa and submucosa, rare goblet cells, and elongation of the crypts; and 3, massive infiltration of leukocytes in the muscularis layer, submucosa, and mucosa, and no goblet cells.

Real-time PCR and cytokine beads assay

RNA was purified with TRIzol (Invitrogen Life Technologies) and RNA easy kit (Qiagen) following the instructions provided by the manufacturers. cDNA was synthesized and subject to real-time PCR as described previously (42). Each cDNA sample was amplified for the interested gene and GAPDH with the TaqMan Universal PCR master mixture according to the manufacturer’s instructions (Applied Biosystems). The concentration of the interested gene was determined using the comparative CT (threshold cycle number at a cross point between amplification plot and threshold) method and normalized to the internal GAPDH control. The following primers were used: human LIGHT forward primer, 5'-AGCAGCTGATACAAGAGCGAA-3'; human LIGHT reverse primer, 5'-CCGGTCAAGCTGGAGTTGG-3'; human LIGHT probe, 5'-FAM-AGGTCAACCCAGCAGCGCATCTCACA-TAMRA-3'; human GAPDH forward primer, 5'-GAAGGTGAAGGTCGGAGTCA-3'; human GAPDH reverse primer, 5'-GAAGATGGTGATGGGATTTC-3'; human GAPDH probe, 5'-TET-CAAGCTTCCCGTTCTCAGCC-TAMRA-3'; murine IFN- forward primer, 5'-TCAAGTGGCATAGATGTGGAAGAA-3'; murine IFN- reverse primer, 5'-TGGCTCTGCAGGATTTTCATG-3'; murine IFN- probe, 5'-FAM-TCACCATCCTTTTGCCAGTTCCTCCAG-3'; murine IL-12p40 forward primer, 5'-GGAAGCACGGCAGCAGAATA-3'; murine IL-12p40 reverse primer, 5'-AACTTGAGGGAGAAGTAGGAATGG-3'; murine IL-12p40 probe, 5'-FAM-CATCATCAAACCAGACCCGCCCAA-TAMRA-3'; murine IL-4 forward primer, 5'-ACAGGAGAAGGGACGCCAT-3'; murine IL-4 reverse primer, 5'-GAAGCCCTACAGACGAGCTCA-3'; murine IL-4 probe, 5'-FAM-TCCTCACAGCAACGAAGAACACCACA-TAMRA-3'; murine MAdCAM-1 forward primer, 5'-GACACCAGCTTGGGCAGTGT-3'; murine MAdCAM-1 reverse primer, 5'-CAGCATGCCCCGTACAGAG-3'; murine MAdCAM-1 probe, 5'-FAMCAGACCCTCCCAGGCAGCAGTATCC-TAMRA-3'; murine GAPDH forward primer, 5'- TTCACCACCATGGAGAAGGC-3'; murine GAPDH reverse primer, 5'-GGCATGGACTGTGGTCATGA-3'; murine GAPDH probe, 5'-TET-TGCATCCTGCACCACCAACTGCTTAG-TAMRA-3'. Cytokine beads assay (BD Pharmingen) was used to test the cytokine level of the culture supernatant or intestine homogenate following the instructions by the manufacturers (BD Pharmingen).

Cell culture and proliferation assay

wt (B6) LN cells (2 x 10⁵/well) were stimulated with immobilized anti-CD3 mAb (0.2 µg/ml) in the absence or presence of rLIGHT produced by Escherichia coli (24) (10 µg/ml) for 72 h in 96-well plate. Anti-CD28 mAb (10 µg/ml) was used as positive control (StemCell Technologies). Culture supernatant was collected after 72 h and frozen at –20°C, then subject to cytokine beads assay as described by the instructions of the manufacturer (BD Pharmingen). wt or HVEM^–/– splenocytes (2 x 10⁵/well) were stimulated with immobilized anti-CD3 mAb (0.3 µg/ml) in the absence or presence of flag-LIGHT from CHO (12.5 ng/ml) for 72 h in 96-well plate, pulsed with 1 µCi of [³H]thymidine for 16 h, and then harvested for liquid scintillation counting.

Adoptive transfer of LN cells

MLN cells were collected from wt littermates or LIGHT Tg mice (2–3 mo old), and 6 x 10⁶ LN cells were i.v. transferred into RAG-1^–/– mice (B6, at the age of 6–7 wk). TNFR-Ig (a generous gift from Dr. J. Browning, Biogen, Boston, MA) was injected i.p. to Tg recipients (150 µg/mouse) every 5 days. LT^–/– or LTR^–/– mice (6–9 wk) were sublethally irradiated (700 rad) and received MLN cells from wt vs Tg mice. Disease progress was monitored including body weight and survival rate. Samples were collected 4 or 5 wk after MLN transfer and subjected to H&E staining.

	Results

Top Abstract Introduction Materials and Methods Results Discussion Disclosures References

 
LIGHT-induced pathology mimics CD

We have generated a Tg line that expresses LIGHT on T cell lineage, and Tg mice spontaneously develop intestinal inflammation several months after birth (39). The clinical presentation of the disease is highly variable, making the comparison between mice and between experiments difficult. To better understand the mechanism of LIGHT-mediated intestinal inflammation and synchronize disease progression, we developed an adoptive transfer model in which wt or Tg MLN-derived lymphocytes (at the age of 2–3 mo) were transferred into RAG-1^–/– mice. Transgenic MLN T cells at this age did not increase in number or up-regulate activation markers including CD69 (Fig. 1A), CD25, and CD44 (data not shown) as compared with wt controls. Adoptive transfer of Tg MLN cells, a major draining LN for both small and large bowel, into RAG-1^–/– mice (Tg recipients) led to rapid and synchronized development of severe intestinal inflammation 4–5 wk after the transfer (Fig. 1B). The inflammation was consistently accompanied by severe diarrhea and sustained weight loss, and often culminated in death (Fig. 1B). In contrast, adoptive transfer of wt MLN cells into RAG-1^–/– mice (wt recipients) did not cause disease (Fig. 1B). To see whether this effect was primarily dependent upon T cells, naive T cells from wt or Tg thymus (>99% are T cells) were adoptively transferred into RAG-1^–/– mice. The mice receiving Tg thymocytes developed diarrhea and wasting disease with similar intensity and time course as that seen in the adoptive transfer of Tg MLN cells (data not shown). These data suggest that up-regulation of LIGHT on T cells can sufficiently cause intestinal inflammation.

View larger version (56K): [in this window] [in a new window]   FIGURE 1. Establishment of an experimental murine model for CD. A, The percentage of CD4+CD69+ T cells is comparable between wt and Tg mice at the age of 2–3 mo. Representative data are shown (n = 5 per group). B, Body weight and survival curve of the RAG-1–/– recipients. MLN cells from wt or Tg mice (2–3 mo) were transferred into RAG-1–/– mice (6 x 106 cells/mouse, 7–9 wk old). Tg recipients (n = 12) developed weight loss, whereas the body weight of wt recipients (n = 9) increased during the course of the experiment. Significant percentages of Tg recipients develop lethal colitis, whereas wt recipients all survive (wt, n = 18, vs Tg, n = 20). Colonic pathology in the mouse model mimics CD patients (C–J). C, H&E-stained section of murine colon from wt recipients display normal colonic structure. D–F, H&E section of Tg recipients showed the typical ulcerations referred to as "knife-like ulcers" (D), transmural inflammation (E), and lymphocyte aggregated within the muscularis propria (F). G, Normal colonic structure was observed in H&E-stained section of colon from controls. H, H&E section of active CD patients showed the typical ulcerations referred to as "knife-like ulcers"(H), transmural inflammation (I), and lymphocyte aggregates within the muscularis propria (J). K and L, The TNF blockade ameliorates the disease severity. RAG-1–/– mice receiving Tg MLN cells were treated with TNFR-Ig (M and N). H&E section of ileum from wt or Tg recipients. Normal histology was observed in the ileum of wt recipients (M), whereas Tg recipients showed severe ileitis (N). O, Ulcer abscess was observed in Tg recipients. Magnification: x100.

LIGHT on T cells promotes Th1 phenotypes in the gut

It has been shown that the responding T cells in CD patients exhibit a Th1 phenotype and produce large amounts of IFN- and TNF- (2). The role of LIGHT in T cell differentiation has not been defined in vivo, although in vitro data suggested that LIGHT costimulation promotes IFN- production (24). We first examined the cytokine profiles in the reconstituted RAG-1^–/– recipients. Total RNA purified from colon tissues were subjected to real-time RT-PCR for different cytokines. Our data showed that there was a dramatic increase in the amount of IFN- and IL-12 produced in Tg recipients. In contrast, the mRNA expression of IL-4 was reduced in the colon of Tg recipients (Fig. 2A). Cytokine bead analysis confirmed the mRNA analysis with a remarkable amount of TNF- and IFN- produced in the colon of Tg recipients. The production of IL-5 and IL-4 was either reduced or not significantly different between wt and Tg recipients (Fig. 2B). These data suggest that our mouse model displays a dominant Th1 cytokine production in the colon, consistent with the cytokine profile reported in CD patients.

View larger version (34K): [in this window] [in a new window]   FIGURE 2. Dominant Th1 phenotypes in the LIGHT-induced CD model. A, Th1 cytokines such as IFN- and TNF were significantly increased in the colon of Tg recipients (n = 5) as compared with wt recipients (n = 5) shown by real-time PCR. In contrast, the IL-4 level was reduced in the colon of Tg recipients. B, cytokine beads assay confirmed the increase of Th1 cytokines including IFN- and TNF at the protein level in Tg recipients (n = 4). However, the level of IL-5 and IL-4 was reduced in Tg recipients. C, Forward side scatter profile showed the huge expansion of LPL in the large bowel of Tg recipients (n = 5) as compared with wt recipients (n = 5). The majority of the expanded lymphocytes were CD4+ and CD8+ T cells (FACS CD4 vs CD8). The absolute number of T cells was increased in Tg LPL (wt recipients, , vs Tg recipients, ; n = 5 per group). D, Intracellular cytokine staining profile. CD4+ IFN--producing cells were dramatically increased in the large bowel of Tg recipients and the percentage of CD8+ IFN--producing cells was also significantly increased. In contrast, IL-4-producing cells were not increased in either CD4+ or CD8+ T cells in the Tg recipients. Representative data were shown from three independent experiments.

LIGHT directly stimulates Th1 cytokines from T cells

To study whether the cytokine production was mediated by LIGHT costimulation acting directly on T cells, rLIGHT was used to stimulate T cells in combination with anti-CD3 mAb. LIGHT costimulation promoted Th1 cytokine production including IFN- and TNF- but not Th2 cytokines such as IL-4 and IL-5 (Fig. 3A). Anti-CD28 was used as a positive control, which stimulated both Th1 and Th2 cytokine production (Fig. 3A). In addition, LIGHT and anti-CD28 can both increase IL-2 production as compared with anti-CD3 stimulation alone (Fig. 3A). These data show that LIGHT can directly stimulate T cells to produce Th1 cytokines.

View larger version (35K): [in this window] [in a new window]   FIGURE 3. LIGHT promotes Th1 cytokine production from T cells and costimulates activation of T cells. A, LN cells from wt B6 mice were cultured with anti-CD3 (0, 0.2 µg/ml) in the presence (10 µg/ml) or absence of LIGHT. Recombinant LIGHT promotes the production of IFN- and TNF but not IL-4 and IL-5. Anti-CD28 (10 µg/ml) was used as a positive control, which promotes both Th1 and Th2 production. Representative data were shown from three independent experiments. B, LIGHT stimulation up-regulates the activation marker of T cells. The percentage of CD69+ T cells was shown by FACS. Representative data were shown.

Previous studies suggested that LIGHT functions as a costimulatory molecule for T cells (24, 25, 26). Consistent with this notion, rLIGHT can significantly enhance the expression of CD69 on CD4⁺ and CD8⁺ T cells upon anti-CD3 mAb stimulation (Fig. 3B). The receptor mediating LIGHT costimulation has not been experimentally demonstrated, although HVEM on T cells has been considered a strong candidate. HVEM biology has not been well studied due to the lack of reagents and animal models. HVEM-deficient mice were, therefore, generated by standard gene-targeting approach, and there were no significant defects in cellular components of primary and secondary lymphoid tissues (data not shown). We examined whether LIGHT-mediated costimulation is dependent on HVEM signaling. Splenocytes isolated from wt or HVEM^–/– mice were stimulated with anti-CD3 and rLIGHT or anti-CD3 mAb in vitro. Our results showed that LIGHT-induced costimulation was absent in HVEM^–/– T cells as determined by proliferation assays (Fig. 4A). In contrast, the proliferation of wt T cells was much higher in the presence of rLIGHT as compared with treatment with only anti-CD3 mAb (Fig. 4A). Taken together, these results for the first time formally demonstrated that HVEM signaling is essential for LIGHT-mediated costimulation.

View larger version (70K): [in this window] [in a new window]   FIGURE 4. Both signaling receptors HVEM and LTR were essential for the LIGHT-mediated intestinal inflammation. A, HVEM is essential for LIGHT-mediated costimulation. HVEM–/– T cells cannot be costimulated by rLIGHT in the presence of anti-CD3 mAb shown by [3H]thymidine incorporation assay. Representative data were shown from three independent experiments. B, H&E staining of the intestine samples from RAG-1–/– mice receiving wt/HVEM–/–, Tg/HVEM–/–, or Tg MLN cells (n = 5 per group). C, Cytokine beads assay showed the increase of TNF level in Tg/HVEM–/– and Tg recipients (n = 4) as compared with wt/HVEM–/– (n = 5) and wt recipients (n = 8). D, H&E section of colon from wt, Tg, LTR–/–, and Tg/LTR–/– mice (n = 5 per group). Tg/LTR–/– mice showed no intestinal inflammation as compared with Tg mice. Magnification: x200. E, LTR–/– mice receiving wt or Tg MLN cells did not develop severe intestinal inflammation shown by H&E staining (n = 4 for wt donor, vs n = 7 for Tg donor). Magnification: x100.

LTR is required for LIGHT-mediated intestinal inflammation

LIGHT can signal LTR expressed primarily on stromal cells (32, 33, 34). We crossed LIGHT Tg mice with LTR^–/– mice (Tg/LTR^–/–). Tg/LTR^–/– mice did not develop intestinal inflammation (Fig. 4D), but these mice also had severe defects in LN development precluding us from transferring MLN cells into RAG-1^–/– mice. Because LTR is expressed primarily by stromal cells (radioresistant), we used the adoptive transfer approach again by transferring Tg MLN cells into LTR^–/– mice that were sublethally irradiated. LTR^–/– mice receiving Tg MLN cells did not develop wasting disease and lethality (Table I, group 7), and intestinal inflammation was not observed in these recipients (Fig. 4E). Because LTR^–/– mice lack LN, it is possible the absence of intestinal inflammation was caused by this developmental defect instead of LTR deficiency itself. To distinguish between these two possibilities, we transferred the Tg MLN cells into LT^–/– mice, which also have defective LN development similar to that seen in LTR^–/– mice (43). The transfer led to severe intestinal inflammation in LT^–/– mice (Table I, group 5). In contrast, the transfer of wt MLN cells into LT^–/– mice did not cause disease (Table I, group 4). Taken together, our results have definitively demonstrated the essential role of LTR, in LIGHT-mediated intestinal inflammation.

Up-regulation of LIGHT expression in IBD patients

To test whether increased LIGHT expression is associated with CD, we investigated the mRNA expression level of LIGHT in the colonic mucosa of CD patients. We found that LIGHT mRNA was up-regulated significantly in active CD as compared with inactive CD and control patients (Fig. 5), suggesting LIGHT might play a role in the active stage of CD pathogenesis. We show a comparison between samples with active CD (n = 5), inactive CD (n = 5), active UC (n = 5), inactive UC (n = 5), and controls with ischemic colitis (n = 2) and neoplastic disease (n = 5). Interestingly, LIGHT expression was also up-regulated in UC patients as compared with controls. Furthermore, PBMC isolated from CD patients expressed higher levels of LIGHT, which associated with increased T cell proliferation upon anti-CD3 stimulation (data not shown). Taken together, these data implicate that up-regulation of LIGHT on activated T cells might play a role in IBD pathogenesis.

View larger version (24K): [in this window] [in a new window]   FIGURE 5. LIGHT up-regulation is associated with IBD. Real-time PCR showed the significant up-regulation of LIGHT in active CD patients (n = 5) as compared with inactive CD (n = 5) and controls (n = 7). Controls are patients with ischemic colitis (n = 2) or neoplastic disease (n = 5).

	Discussion

Top Abstract Introduction Materials and Methods Results Discussion Disclosures References

Although closely related to TNF and LT, LIGHT is a unique proinflammatory cytokine that acts as a potent costimulatory molecule for T cells. Previous studies showed that LIGHT costimulation promotes the induction of IFN- and GM-CSF from purified T cells (22, 24). Dysregulated LIGHT expression leads to abnormal activation and expansion of T cells in vivo (26, 30). The receptor essential for LIGHT-mediated costimulation has not been formally demonstrated, although it has been assumed the HVEM receptor is responsible for this activity. Our data clearly showed that LIGHT costimulation requires HVEM signaling both in vivo and in vitro. The finding that HVEM expression is required for LIGHT’s function suggests an autocrine effect of LIGHT, i.e., both LIGHT and HVEM are expressed by T cells, which bind to each other and mediate the costimulation effect. This hypothesis is also supported by our previous studies (26) although it is unclear whether LIGHT and HVEM need to be expressed on the same T cell or nearby T cells. The LIGHT-HVEM interaction may serve as a molecular mechanism for the expansion and activation of T cells in CD pathogenesis because LIGHT costimulation seems to preferentially promote Th1 cytokine production. A recent study also suggests that LIGHT can synergize with CD40L to stimulate the maturation of dendritic cells and that LIGHT costimulation allows dendritic cells to prime in vitro-enhanced specific CTL responses (44). Thus, LIGHT provides a unique linkage between innate and adaptive immunity.

A number of studies underline the critical importance of both TNF and TNF family members in IBD pathogenesis. The production of TNF is dramatically up-regulated in IBD patients, and TNF blockade achieves 60% effectiveness in CD patients (2). An experimental model of mucosal inflammation has been produced by creating mice that overexpress TNF due to a deletion in the ARE (TNF ARE mice) (16). The intestinal inflammation in this model resembles the pathology observed in CD patients; in particular, granuloma formation is identified. CD40L is another TNF family member implicated in the pathogenesis of IBD. Overexpression of CD40L under the control of the lck promoter leads to severe intestinal inflammation (45). CD40 and CD40L up-regulation was observed in IBD patients (46), and anti-CD40L administration ameliorated the severity of chronic murine colitis (47). Experimental colitis induced by the transfer of CD4⁺CD45RB^high cells into SCID mice or reconstitution of Tg26 mice with wt bone marrow is attenuated by LTR-Ig treatment (31), and the effect of LTR-Ig treatment in these two models of colitis was as potent as that of anti-TNF treatment. Although inhibition of TNF/TNFR interactions is effective in ameliorating IBD and has been widely applied to IBD patients, inhibition of interactions between LT/LIGHT with LTR is currently being investigated as a potential IBD treatment (48).

The adoptive transfer model we used in the current study is performed by transferring MLN cells into RAG-1^–/– mice. The Tg MLN cells include pathogenic T cells and other cell types that might have regulatory effects on the disease development. We presented the results using 6 million cells; Tg MLN cells caused severe intestinal inflammation in the recipients, whereas the same number of wt MLN cells did not cause intestinal inflammation. Our FACS data showed that the percentage of T cells is comparable between wt and Tg donor cells, and we used young donor at the age of 2–3 mo that did not develop disease yet and showed no sign of activation marker up-regulation (CD4⁺CD69⁺ cells: 3.05% in wt vs 3.47% in Tg). Our preliminary data suggest that as low as 0.5 x 10⁶ purified Tg T cells can also cause lethal IBD in RAG-1^–/– mice (data not shown). In the CD45RB^high transfer model, the activated T cells (i.e., CD45RB^highCD4⁺, 0.4–0.5 x 10⁶) caused disease in severely immunocompromised mice such as SCID (49, 50, 51) or RAG^–/– mice (52). If the regulatory T cells (CD45RB^lowCD4⁺) were present in the transferred T cell population, the recipients would not develop disease. In this transfer model, the recipients develop moderate wasting and extensive inflammation of the large intestine, and in its severest form, these recipients display transmural involvement of the intestine wall. In fact, LTR-Ig treatment ameliorates the severity of the disease in the CD45RB^highCD4⁺-reconstituted SCID mice (31). Therefore, endogenous LIGHT might be involved in causing the diseases in this transfer model.

LIGHT Tg mice spontaneously develop intestinal inflammation several months after birth (39). The severity of the inflammation in the parental Tg line is not as dramatic as that seen in the adoptive transfer recipients. Moreover, there was no typical CD-like pathology observed in parental Tg line. The differences observed between the parental Tg line and adoptive transfer model were likely due to the following reasons. First, the time course of the disease pathogenesis is different. The development of intestinal inflammation in the parental Tg line is over several months and is less severe, suggesting multiple compensatory pathways may be activated. The adoptive transfer model is an acute model (4–5 wk) that probably represents the effector phase of the disease with a dominant Th1 response present. Second, the parental Tg line has the transgene turned on in early life (before birth), whereas the adoptive transfer model provides a scenario in which an adult is acutely exposed to the pathogenic cells. Third, the parental Tg line did not show dominant Th1 responses in the gut. Th1 and Th2 cytokines were both increased dramatically (data not shown). We speculate that LIGHT may initiate a Th1 response in the MLN and/or gut of Tg mice; however, the intestinal stromal cells may develop a compensatory mechanism to counteract the dominant Th1 response by up-regulating Th2 cytokines. Therefore, the aged parental Tg line (5–8 mo) did not show a typical CD-like pathology. In addition, the adoptive transfer model offers other advantages: the disease development is more predictable, synchronized, and dramatically shortened. All of these factors further facilitate the investigation of the mechanism underlying CD and aid the development of therapeutic intervention.

Thus, the potency of LIGHT to mediate CD pathogenesis is attributed to its effects on altering both the microenvironment via LTR and effector T cells via HVEM. Signaling through both receptors by LIGHT eventually results in the transformation of gut mucosa from a normal tertiary immune structure into a pathological lymphoid site. Dysregulated LIGHT expression may well serve as a molecular mechanism to drive the pathogenesis of CD. Therefore, the unique characteristics of LIGHT and its downstream signaling pathways suggest its candidacy as a potential target for CD. In addition, our experimental model of LIGHT- and TNF--mediated ileal and colonic inflammation provides a platform for the understanding of the pathogenesis and therapeutic intervention of CD in the future.

	Acknowledgments

 
We thank Jeff Browning for his advice and TNFR-Ig.

	Disclosures

Top Abstract Introduction Materials and Methods Results Discussion Disclosures References

 
The authors have no financial conflict of interest.

	Footnotes

 
The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore be hereby marked advertisement in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

¹ The studies were supported in part by National Institutes of Health (NIH) Grants R01-HD37104, R01-DK58897, and P01-CA09296-01 (to Y.-X.F.) and NIH Grant R01-DK61931 (to J.R.T.). J.W. is a recipient of NIH Training Grant 5T32 HL07237.

² Current address: Children’s Hospital and Department of Genetics, Harvard Medical School, 300 Longwood Avenue, Karp Building 09006B, Boston, MA 02115.

³ Address correspondence and reprint requests to Dr. Yang-Xin Fu, Department of Pathology, University of Chicago, Chicago, IL 60637. E-mail address: yfu{at}uchicago.edu; or Dr. Klaus Pfeffer, Institute of Medical Microbiology, Immunology, and Hygiene, Technical University of Munich, Munich, Germany. E-mail address: klaus.pfeffer{at}uni-duesseldorf.de

⁴ Abbreviations used in this paper: IBD, inflammatory bowel disease; CD, Crohn’s disease; UC, ulcerative colitis; LIGHT, homologous to lymphotoxin, exhibits inducible expression, competes with herpesvirus glycoprotein D for HVEM on T cells; LT, lymphotoxin; Tg, transgenic; HVEM, herpes virus entry mediator; wt, wild type; LN, lymph node; MLN, mesenteric LN; LPL, lamina propria lymphocyte; ARE, AU-rich regulatory element.

Received for publication July 19, 2004. Accepted for publication March 31, 2005.

	References

Top Abstract Introduction Materials and Methods Results Discussion Disclosures References

 

1. Blumberg, R. S., L. J. Saubermann, W. Strober. 1999. Animal models of mucosal inflammation and their relation to human inflammatory bowel disease. Curr. Opin. Immunol. 11: 648-656.[Medline]
2. Bouma, G., W. Strober. 2003. The immunological and genetic basis of inflammatory bowel disease. Nat. Rev. Immunol. 3: 521-533.[Medline]
3. Monteleone, G., L. Biancone, R. Marasco, G. Morrone, O. Marasco, F. Luzza, F. Pallone. 1997. Interleukin 12 is expressed and actively released by Crohn’s disease intestinal lamina propria mononuclear cells. Gastroenterology 112: 1169-1178.[Medline]
4. Strober, W., I. J. Fuss, R. S. Blumberg. 2002. The immunology of mucosal models of inflammation. Annu. Rev. Immunol. 20: 495-549.[Medline]
5. Heller, F., I. J. Fuss, E. E. Nieuwenhuis, R. S. Blumberg, W. Strober. 2002. Oxazolone colitis, a Th2 colitis model resembling ulcerative colitis, is mediated by IL-13-producing NK-T cells. Immunity 17: 629-638.[Medline]
6. Targan, S. R.. 2000. Biology of inflammation in Crohn’s disease: mechanisms of action of anti-TNF- therapy. Can. J. Gastroenterol. 14:(Suppl. C): 13C-16C.
7. Scallon, B. J., M. A. Moore, H. Trinh, D. M. Knight, J. Ghrayeb. 1995. Chimeric anti-TNF- monoclonal antibody cA2 binds recombinant transmembrane TNF- and activates immune effector functions. Cytokine 7: 251-259.[Medline]
8. Lugering, A., M. Schmidt, N. Lugering, H. G. Pauels, W. Domschke, T. Kucharzik. 2001. Infliximab induces apoptosis in monocytes from patients with chronic active Crohn’s disease by using a caspase-dependent pathway. Gastroenterology 121: 1145-1157.[Medline]
9. ten Hove, T., C. van Montfrans, M. P. Peppelenbosch, S. J. van Deventer. 2002. Infliximab treatment induces apoptosis of lamina propria T lymphocytes in Crohn’s disease. Gut 50: 206-211.[Abstract/Free Full Text]
10. Van den Brande, J. M., H. Braat, G. R. van den Brink, H. H. Versteeg, C. A. Bauer, I. Hoedemaeker, C. van Montfrans, D. W. Hommes, M. P. Peppelenbosch, S. J. van Deventer. 2003. Infliximab but not etanercept induces apoptosis in lamina propria T-lymphocytes from patients with Crohn’s disease. Gastroenterology 124: 1774-1785.[Medline]
11. Papadakis, K. A., S. R. Targan. 2000. Tumor necrosis factor: biology and therapeutic inhibitors. Gastroenterology 119: 1148-1157.[Medline]
12. van Deventer, S. J.. 2002. Anti-tumour necrosis factor therapy in Crohn’s disease: where are we now?. Gut 51: 362-363.[Free Full Text]
13. Stokkers, P. C., D. W. Hommes. 2004. New cytokine therapeutics for inflammatory bowel disease. Cytokine 28: 167-173.[Medline]
14. Kuhn, R., J. Lohler, D. Rennick, K. Rajewsky, W. Muller. 1993. Interleukin-10-deficient mice develop chronic enterocolitis. Cell 75: 263-274.[Medline]
15. Rennick, D. M., M. M. Fort. 2000. Lessons from genetically engineered animal models. XII. IL-10-deficient (IL-10^–/–) mice and intestinal inflammation. Am. J. Physiol. 278: G829-G833.
16. Kontoyiannis, D., M. Pasparakis, T. T. Pizarro, F. Cominelli, G. Kollias. 1999. Impaired on/off regulation of TNF biosynthesis in mice lacking TNF AU-rich elements: implications for joint and gut-associated immunopathologies. Immunity 10: 387-398.[Medline]
17. Kosiewicz, M. M., C. C. Nast, A. Krishnan, J. Rivera-Nieves, C. A. Moskaluk, S. Matsumoto, K. Kozaiwa, F. Cominelli. 2001. Th1-type responses mediate spontaneous ileitis in a novel murine model of Crohn’s disease. J. Clin. Invest. 107: 695-702.[Medline]
18. Strober, W., K. Nakamura, A. Kitani. 2001. The SAMP1/Yit mouse: another step closer to modeling human inflammatory bowel disease. J. Clin. Invest. 107: 667-670.[Medline]
19. Lochner, M., I. Forster. 2002. Anti-interleukin-18 therapy in murine models of inflammatory bowel disease. Pathobiology 70: 164-169.[Medline]
20. Schmidt, C., T. Marth, B. M. Wittig, A. Hombach, H. Abken, A. Stallmach. 2002. Interleukin-12 antagonists as new therapeutic agents in inflammatory bowel disease. Pathobiology 70: 177-183.[Medline]
21. Mauri, D. N., R. Ebner, R. I. Montgomery, K. D. Kochel, T. C. Cheung, G. L. Yu, S. Ruben, M. Murphy, R. J. Eisenberg, G. H. Cohen, et al 1998. LIGHT, a new member of the TNF superfamily, and lymphotoxin are ligands for herpesvirus entry mediator. Immunity 8: 21-30.[Medline]
22. Tamada, K., K. Shimozaki, A. I. Chapoval, Y. Zhai, J. Su, S. F. Chen, S. L. Hsieh, S. Nagata, J. Ni, L. Chen. 2000. LIGHT, a TNF-like molecule, costimulates T cell proliferation and is required for dendritic cell-mediated allogeneic T cell response. J. Immunol. 164: 4105-4110.[Abstract/Free Full Text]
23. Wang, J., Y. X. Fu. 2004. The role of LIGHT in T cell-mediated immunity. Immunol. Res. 30: 201-214.[Medline]
24. Tamada, K., K. Shimozaki, A. I. Chapoval, G. Zhu, G. Sica, D. Flies, T. Boone, H. Hsu, Y. X. Fu, S. Nagata, et al 2000. Modulation of T-cell-mediated immunity in tumor and graft-versus-host disease models through the LIGHT costimulatory pathway. Nat. Med. 6: 283-289.[Medline]
25. Harrop, J. A., P. C. McDonnell, M. Brigham-Burke, S. D. Lyn, J. Minton, K. B. Tan, K. Dede, J. Spampanato, C. Silverman, P. Hensley, et al 1998. Herpesvirus entry mediator ligand (HVEM-L), a novel ligand for HVEM/TR2, stimulates proliferation of T cells and inhibits HT29 cell growth. J. Biol. Chem. 273: 27548-27556.[Abstract/Free Full Text]
26. Wang, J., J. C. Lo, A. Foster, P. Yu, H. M. Chen, Y. Wang, K. Tamada, L. Chen, Y. X. Fu. 2001. The regulation of T cell homeostasis and autoimmunity by T cell-derived LIGHT. J. Clin. Invest. 108: 1771-1780.[Medline]
27. Granger, S. W., K. D. Butrovich, P. Houshmand, W. R. Edwards, C. F. Ware. 2001. Genomic characterization of LIGHT reveals linkage to an immune response locus on chromosome 19p13.3 and distinct isoforms generated by alternate splicing or proteolysis. J. Immunol. 167: 5122-5128.[Abstract/Free Full Text]
28. Rioux, J. D., M. S. Silverberg, M. J. Daly, A. H. Steinhart, R. S. McLeod, A. M. Griffiths, T. Green, T. S. Brettin, V. Stone, S. B. Bull, et al 2000. Genomewide search in Canadian families with inflammatory bowel disease reveals two novel susceptibility loci. Am. J. Hum. Genet. 66: 1863-1870.[Medline]
29. Bonen, D. K., J. H. Cho. 2003. The genetics of inflammatory bowel disease. Gastroenterology 124: 521-536.[Medline]
30. Shaikh, R. B., S. Santee, S. W. Granger, K. Butrovich, T. Cheung, M. Kronenberg, H. Cheroutre, C. F. Ware. 2001. Constitutive expression of LIGHT on T cells leads to lymphocyte activation, inflammation, and tissue destruction. J. Immunol. 167: 6330-6337.[Abstract/Free Full Text]
31. Mackay, F., J. L. Browning, P. Lawton, S. A. Shah, M. Comiskey, A. K. Bhan, E. Mizoguchi, C. Terhorst, S. J. Simpson. 1998. Both the lymphotoxin and tumor necrosis factor pathways are involved in experimental murine models of colitis. Gastroenterology 115: 1464-1475.[Medline]
32. Browning, J. L., I. D. Sizing, P. Lawton, P. R. Bourdon, P. D. Rennert, G. R. Majeau, C. M. Ambrose, C. Hession, K. Miatkowski, D. A. Griffiths, et al 1997. Characterization of lymphotoxin-- complexes on the surface of mouse lymphocytes. J. Immunol. 159: 3288-3298.[Abstract]
33. Browning, J. L., L. E. French. 2002. Visualization of lymphotoxin- and lymphotoxin- receptor expression in mouse embryos. J. Immunol. 168: 5079-5087.[Abstract/Free Full Text]
34. Force, W. R., B. N. Walter, C. Hession, R. Tizard, C. A. Kozak, J. L. Browning, C. F. Ware. 1995. Mouse lymphotoxin- receptor: molecular genetics, ligand binding, and expression. J. Immunol. 155: 5280-5288.[Abstract]
35. Harrop, J. A., M. Reddy, K. Dede, M. Brigham-Burke, S. Lyn, K. B. Tan, C. Silverman, C. Eichman, R. DiPrinzio, J. Spampanato, et al 1998. Antibodies to TR2 (herpesvirus entry mediator), a new member of the TNF receptor superfamily, block T cell proliferation, expression of activation markers, and production of cytokines. J. Immunol. 161: 1786-1794.[Abstract/Free Full Text]
36. Kwon, B. S., K. B. Tan, J. Ni, K. O. Oh, Z. H. Lee, K. K. Kim, Y. J. Kim, S. Wang, R. Gentz, G. L. Yu, et al 1997. A newly identified member of the tumor necrosis factor receptor superfamily with a wide tissue distribution and involvement in lymphocyte activation. J. Biol. Chem. 272: 14272-14276.[Abstract/Free Full Text]
37. Scheu, S., J. Alferink, T. Potzel, W. Barchet, U. Kalinke, K. Pfeffer. 2002. Targeted disruption of LIGHT causes defects in costimulatory T cell activation and reveals cooperation with lymphotoxin in mesenteric lymph node genesis. J. Exp. Med. 195: 1613-1624.[Abstract/Free Full Text]
38. Wang, J., A. Foster, R. Chin, P. Yu, Y. Sun, Y. Wang, K. Pfeffer, Y. X. Fu. 2002. The complementation of lymphotoxin deficiency with LIGHT, a newly discovered TNF family member, for the restoration of secondary lymphoid structure and function. Eur. J. Immunol. 32: 1969-1979.[Medline]
39. Wang, J., R. A. Anders, Q. Wu, D. Peng, J. H. Cho, Y. Sun, R. Karaliukas, H. S. Kang, J. R. Turner, Y. X. Fu. 2004. Dysregulated LIGHT expression on T cells mediates intestinal inflammation and contributes to IgA nephropathy. J. Clin. Invest. 113: 826-835.[Medline]
40. Wang, J., T. Chun, J. C. Lo, Q. Wu, Y. Wang, A. Foster, K. Roca, M. Chen, K. Tamada, L. Chen, et al 2001. The critical role of LIGHT, a TNF family member, in T cell development. J. Immunol. 167: 5099-5105.[Abstract/Free Full Text]
41. Neubauer, H., A. Cumano, M. Muller, H. Wu, U. Huffstadt, K. Pfeffer. 1998. Jak2 deficiency defines an essential developmental checkpoint in definitive hematopoiesis. Cell 93: 397-409.[Medline]
42. Kang, H. S., R. K. Chin, Y. Wang, P. Yu, J. Wang, K. A. Newell, Y. X. Fu. 2002. Signaling via LTR on the lamina propria stromal cells of the gut is required for IgA production. Nat. Immunol. 3: 576-582.[Medline]
43. Fu, Y. X., D. D. Chaplin. 1999. Development and maturation of secondary lymphoid tissues. Annu. Rev. Immunol. 17: 399-433.[Medline]
44. Morel, Y., A. Truneh, R. W. Sweet, D. Olive, R. T. Costello. 2001. The TNF superfamily members LIGHT and CD154 (CD40 ligand) costimulate induction of dendritic cell maturation and elicit specific CTL activity. J. Immunol. 167: 2479-2486.[Abstract/Free Full Text]
45. Clegg, C. H., J. T. Rulffes, H. S. Haugen, I. H. Hoggatt, A. Aruffo, S. K. Durham, A. G. Farr, D. Hollenbaugh. 1997. Thymus dysfunction and chronic inflammatory disease in gp39 transgenic mice. Int. Immunol. 9: 1111-1122.[Abstract/Free Full Text]
46. Liu, Z., S. Colpaert, G. R. D’Haens, A. Kasran, M. de Boer, P. Rutgeerts, K. Geboes, J. L. Ceuppens. 1999. Hyperexpression of CD40 ligand (CD154) in inflammatory bowel disease and its contribution to pathogenic cytokine production. J. Immunol. 163: 4049-4057.[Abstract/Free Full Text]
47. De Jong, Y. P., M. Comiskey, S. L. Kalled, E. Mizoguchi, R. A. Flavell, A. K. Bhan, C. Terhorst. 2000. Chronic murine colitis is dependent on the CD154/CD40 pathway and can be attenuated by anti-CD154 administration. Gastroenterology 119: 715-723.[Medline]
48. Gommerman, J. L., J. L. Browning. 2003. Lymphotoxin/light, lymphoid microenvironments and autoimmune disease. Nat. Rev. Immunol. 3: 642-655.[Medline]
49. Powrie, F., M. W. Leach, S. Mauze, L. B. Caddle, R. L. Coffman. 1993. Phenotypically distinct subsets of CD4⁺ T cells induce or protect from chronic intestinal inflammation in C.B-17 scid mice. Int. Immunol. 5: 1461-1471.[Abstract/Free Full Text]
50. Morrissey, P. J., K. Charrier, S. Braddy, D. Liggitt, J. D. Watson. 1993. CD4⁺ T cells that express high levels of CD45RB induce wasting disease when transferred into congenic severe combined immunodeficient mice: disease development is prevented by cotransfer of purified CD4⁺ T cells. J. Exp. Med. 178: 237-244.[Abstract/Free Full Text]
51. Powrie, F., R. Correa-Oliveira, S. Mauze, R. L. Coffman. 1994. Regulatory interactions between CD45RB^high and CD45RB^low CD4⁺ T cells are important for the balance between protective and pathogenic cell-mediated immunity. J. Exp. Med. 179: 589-600.[Abstract/Free Full Text]
52. Corazza, N., S. Eichenberger, H. P. Eugster, C. Mueller. 1999. Nonlymphocyte-derived tumor necrosis factor is required for induction of colitis in recombination activating gene (RAG)2^–/– mice upon transfer of CD4⁺CD45RB^hi T cells. J. Exp. Med. 190: 1479-1492.[Abstract/Free Full Text]

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