By
From the * Keio Cancer Center, the Department of Internal Medicine, § the Department of
Microbiology, and
the Department of Pathology, School of Medicine, Keio University, Tokyo 160, Japan; ¶ the Department of Immunology, School of Medicine, Tokai University, Isehara 259-11, Japan;
and the ** Shionogi Institute for Medical Science, Osaka 553, Japan
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Abstract |
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We have demonstrated that intestinal epithelial cells produce interleukin 7 (IL-7), and IL-7
serves as a potent regulatory factor for proliferation of intestinal mucosal lymphocytes expressing functional IL-7 receptor. To clarify the mechanism by which locally produced IL-7 regulates the mucosal lymphocytes, we investigated IL-7 transgenic mice. Here we report that
transgenic mice expressing murine IL-7 cDNA driver by the SR promoter developed chronic colitis in concert with the expression of SR
/IL-7 transgene in the colonic mucosa. IL-7 transgenic but not littermate mice developed chronic colitis at 4-12 wk of age, with histopathological similarity to ulcerative colitis in humans. Southern blot hybridization and competitive
PCR demonstrated that the expression of IL-7 messenger RNA was increased in the colonic
mucosal lymphocytes but not in the colonic epithelial cells. IL-7 protein accumulation was decreased in the goblet cell-depleted colonic epithelium in the transgenic mice. Immunohistochemical and cytokine production analysis showed that lymphoid infiltrates in the lamina
propria were dominated by T helper cell type 1 CD4+ T cells. Flow cytometric analysis demonstrated that CD4+ intraepithelial T cells were increased, but T cell receptor
/
T cells and
CD8
/
cells were not increased in the area of chronic inflammation. Increased IL-7 receptor
expression in mucosal lymphocytes was demonstrated in the transgenic mice. These findings
suggest that chronic inflammation in the colonic mucosa may be mediated by dysregulation of
colonic epithelial cell-derived IL-7, and this murine model of chronic colitis may contribute to
the understanding of the pathogenesis of human inflammatory bowel disease.
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Introduction |
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Interleukin 7 (IL-7) is a stromal cell-derived pleiotropic cytokine with cell growth-promoting activity of lymphoid precursors. IL-7 was originally described as a growth factor for precursor B cells (1). Subsequent in vitro studies have demonstrated that IL-7 is also a potent costimulus for immature and mature cells of the T cell lineage (4). Recently IL-7 messenger RNA (mRNA)1 was shown to be expressed in bone marrow stromal cells, thymus stromal cells, spleen, liver, kidney, and skin (9, 10). However, a potential role of IL-7 in peripheral lymphoid tissues remains unclear.
We have demonstrated the IL-7 mRNA expression and
IL-7 protein production in human colonic epithelial cells
(11). Immunohistochemical and in situ hybridization analysis have demonstrated that epithelial goblet cells are the
major source of IL-7 production in the colonic mucosa.
Interactions between mucosal lymphocytes and intestinal epithelial cells are thought to be crucial for maintaining
mucosal immunity. Intestinal mucosal lymphocytes, including both intraepithelial lymphocytes (IELs) and lamina
propria lymphocytes (LPLs), may serve a critical role in the
mucosal immune system by providing immune surveillance
of epithelial cells (12). However, little is known about
the precise mechanisms by which functional differentiation and proliferation of these cells occurs in the intestinal mucosa. We have shown that IL-7 receptor is expressed in the
mucosal lymphocytes and intestinal epithelial cells, and intestinal epithelial cell-derived IL-7 may serve as a potent
regulatory factor for the proliferation of these cells (11, 15).
The importance of IL-7 as a mediator of local inflammatory responses remains unclear. To clarify the mechanism
by which locally produced IL-7 may affect mucosal lymphocyte fraction and the role of IL-7 in colonic inflammation, we investigated transgenic mice carrying murine IL-7
cDNA and SR promoter (16). Here we report that IL-7
transgenic mice develop chronic colitis, in concert with the
expression of SR
/IL-7 transgene in the colonic mucosa.
These findings favor the idea that chronic inflammation in
the colonic mucosa is mediated by a colonic epithelial cell- derived IL-7.
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Materials and Methods |
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IL-7 Transgenic Mice.
Generation of IL-7 transgenic mice has been previously described (16). PCR-amplified murine IL-7 cDNA was ligated with SRHistological and Immunohistological Analysis.
The en block- fixed gastrointestinal tract was dissected into stomach, jejunum and ileum (small intestine), colon, and rectum. Tissue specimens were fixed in 10% formalin and embedded in paraffin. Sections were stained with hematoxylin-eosin. For immunohistochemistry, sections were fixed with 2% periodate lysine paraformaldehyde and frozen in OCT compound. Staining of sections was performed by the avidin-biotin complex method. 6 µm sections were incubated with the primary antibodies. These included anti-CD4 (L3T4), anti-CD8PCR and Southern Blotting for Murine IL-7 and IL-7 Receptor mRNA.
Cytoplasmic RNA was prepared from the indicated tissues using the RNAzol (Biotecx Lab, Houston, TX). First-strand cDNA was synthesized from 2 µg of total RNA with 1 µg oligo (dT) primer and 400 U/µl MMLV reverse transcriptase (Perkin Elmer Cetus, Norwalk, CT) by using SuperScript Preamplification System (GIBCO BRL, Gaithersburg, MD) in 20 µl of the reaction mixture. The sequences for PCR primer to detect SRQuantitative PCR for Murine IL-7 mRNA Using MIMIC cDNA Construct.
Quantitative analysis was conducted by competitive PCR by using stepwise dilutions of competitor primer pairs as a template (PCR MIMICS; Clonotech). Two rounds of PCR amplification were performed. In the first PCR reaction, two composite primers were used. The first PCR primers were: 5Preparation of Mucosal Lymphocytes and Intestinal Epithelial Cells from the Intestinal Mucosa.
We used a modification of previously established method for the isolation of mouse colonic IELs and epithelial cells (18). Intestine free of the lumen content was turned inside-out with the aid of polyethylene tubing. The inverted intestine was fastened to the tubing with a string and then cut into three to four segments. Up to 10 segments of intestines were transferred to a plastic box containing 250 ml of RPMI 1640 medium (2% FCS, 25 mM Hepes, 100 U/ml of penicillin, 100 mg/ml of streptomycin), and the box was shaken at 37°C for 45 min (150 rpm). Cell suspensions were collected in 250-ml tubes and further processed for the purification of IELs according to standard technique. In brief, the cell suspension was first passed through a glass wool column to deplete cell debris and sticky cells, and then subjected to Percoll discontinuous gradient centrifugation. After centrifugation, cells at the top of the 30% percoll solution were found to be enriched with colonic epithelial cells devoid of CD3+ cells. More than 90% of IELs were recovered at the interface of 44 and 70% percoll solutions. This new method yields IELs with minimum contamination by lymphocytes from Peyer's patches or lamina propria, and villus structure (lamina propria) without epithelium remained intact after each isolation. For isolation of LPLs from colon, mesenteric tissues and Peyer's patches were removed from intestines that were then cut open longitudinally, washed with PBS, and cut into smaller pieces. The dissected mucosa was incubated with Ca2+ Mg2+-free Hank's BSS containing 1 mM dithiothreitol (Sigma Chemical Co., St. Louis, MO) to remove mucus. The mucosa was then incubated four times in medium containing 0.75 mM EDTA (Sigma Chemical Co.). The supernatants from these incubations containing IEL population and LPLs were collected and incubated in medium with 0.02% collagenase (Worthington Biomedical Co., Freehold, NJ) and 0.01% DNase (Worthington Biomedical Co.). The fraction was pelleted twice through a 40% isotonic Percoll solution and the cells were centrifuged over Ficoll-Hypaque density gradient. The purity of resulting IELs and LPLs was analyzed by flow cytometry. Cell preparations were adequately pure, sinceEstimation of IL-7 Protein Production in Culture Supernatants of Colonic Epithelial Cells and Infiltrating Mucosal Lymphocytes.
IL-7 protein production by epithelial cells and infiltrating mucosal lymphocytes expressing IL-7 mRNA was measured by the proliferation assay of an IL-7-dependent cell line DW34 (17). Freshly isolated colonic epithelial cells, IELs and LPLs (5 × 106) were cultured in RPMI 1640 medium supplemented with fetal calf serum for 48 h. DW34 (104) cells were incubated with culture supernatants of those cells and cultured for 48 h. The cells were pulsed with 18.5 kBq of [3H]thymidine and harvested for radioactivity. The culture supernatants of colonic epithelial cells, IELs, and LPLs were treated with 10 µg/ml of mouse anti-human/mouse IL-7 mAb (Genzyme Corp.) or isotype-matched mouse Ig for 1 h before the application to DW34 cells, and concentrated using Centricon. Serial dilution (0-100 pg/ml) of rIL-7 (Genzyme Corp.) was used to calibrate IL-7 concentration.Estimation of Cytokine Production in Culture Supernatants of Infiltrating Mucosal Lymphocytes.
Estimation of cytokine production in culture supernatants of infiltrating mucosal lymphocytes was assessed as previously described (19). To measure cytokine production, 24-well plates were coated with 10 µg/ml murine anti-CD3 antibody (clone 145-2C11; PharMingen) overnight at 4°C. Lamina propria CD4+ T cells (105) were then cultured in 1 ml of complete medium in precoated or uncoated wells, and 1 µg/ml soluble anti-CD28 antibody (clone 37.51; PharMingen) was added to the anti-CD3 antibody-coated wells. Culture supernatants were removed after 48 h and assayed for cytokine concentration. Cytokine concentrations were determined by specific ELISA kit for mouse IFN-Flow Cytometry.
mAbs used included anti-CD3, anti-CD4, anti-CD8 ![]() |
Results |
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IL-7 transgenic mice developed acute colitis with infiltrating neutrophils and lymphocytes at 1-3 wk of age (Fig. 1,
A and B). At 1-3 wk of age when mice developed acute
colitis, the SR/IL-7 transgene and IL-7 mRNA expression in the colonic mucosa was revealed in the IL-7 transgenic mice (Fig. 1 C). IL-7 protein was also significantly
expressed in the inflamed colonic mucosa of IL-7 transgenic mice (Fig. 1 D). Infiltrating T cells in the acute colitis
lesion were CD4+ (Fig. 1 E) and T cell receptor
/
T
cells in the IL-7 transgenic mice (Fig. 1 F).
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In the IL-7 transgenic founder number 34 and their
progenies, diarrhea, weight loss, rectal prolapse, and remittent intestinal bleeding was observed frequently at 6-10 wk
of age (Fig. 2). The fact that plural and independent SR/
IL-7 transgenic lines developed rectal prolapse indicates
that this phenomenon was caused by the transgene itself
and not by the positional effect of the transgene insertion
on chromosome. Wide time lags of 4-12 wk of age were observed for the onset of colitis in the mice. The final cumulative frequencies of colitis in the line 34 mice were
~60% at 16 wk of age. Although several other lines of
mice have developed rectal prolapse, the line 34 mice developed it at earlier periods and at high frequency. Therefore, the line 34 mice were used in the subsequent study.
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At 4-12 wk of age, histopathological examination of the colonic tissues revealed the development of chronic colitis in the IL-7 transgenic mice. Erosions and neutrophil infiltration were observed in the anal ring, but no ulceration was demonstrated (Fig. 3 A). The inflammatory cell infiltration and goblet cell depletion was most prominent in the rectum (Fig. 3 B), but observed throughout entire colon (Fig. 3, C and D). Crypt abscess (Fig. 3 E), paneth cell metaplasia (Fig. 3 F), and infiltration of eosinophils were observed in the lesions (Fig. 3 G). These features resembled the histopathological characteristics of ulcerative colitis in humans (20, 21). In contrast, control wild-type mice did not develop chronic intestinal inflammation at all.
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In the IL-7 transgenic mice, 278-bp PCR amplified products of mRNA from
the SR/IL-7 transgene were expressed in the colonic mucosa. Interestingly, the SR
/IL-7 transgene expression in
the colonic mucosa was parallel with development of chronic
colitis in the IL-7 transgenic mice. SR
/IL-7 transgene
was expressed in the colonic mucosa of transgenic mice with
chronic colitis at both 4 and 8 wk, but not expressed in the
colonic mucosa of mice without colitis at 4 and 8 wk (Fig.
4 A). In the colitis lesion of transgenic mice, SR
/IL-7
transgene was expressed in the colonic epithelial cells, IELs,
and LPLs (Fig. 4 B). The transgene was constitutively expressed in the thymus, spleen, kidney, brain, lung, and skin,
but not in the liver and muscle as previously reported (17).
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RT-PCR analysis demonstrated IL-7 mRNA expression in normal murine colonic tissues (Fig. 5). The specificity of amplified bands was validated by their predicted size (496 bp). To ensure the presence of the correct predicted fragments, we digested the amplified IL-7 PCR product by restriction enzyme EcoRI. As shown in Fig. 5 A, 496-bp PCR products from murine colonic mucosa was digested into two predicted fragments with 263 and 233 bp. Southern blot analysis confirmed expression of IL-7 mRNA in normal murine colonic mucosa (Fig. 5 B). IL-7 mRNA expression was detected in the colon as well as the small intestine and stomach tissues. Equivalent hybridization was observed in Southern blot analysis using cDNA prepared from five separate sets of tissue samples.
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To assess the change of IL-7 mRNA expression in the transgenic mice, we performed competitive PCR analysis for various tissues. As shown in Fig. 6, competitive PCR demonstrated that about a 100-fold increase in IL-7 mRNA transcripts was detected in the inflamed colonic mucosa of the IL-7 transgenic mice. In contrast, no difference of the IL-7 mRNA expression was observed in the thymus tissues between wild-type mice and IL-7 transgenic mice. We also detected increased IL-7 mRNA in the small intestine with ileitis, but the expression was quite weak compared to that in the colon with inflammation (data not shown). However, no difference of the IL-7 mRNA expression was observed in the colonic and small intestinal mucosa where no inflammation was observed. These data demonstrate that increased IL-7 mRNA expression occurs in the inflammation site of the intestinal tissues in IL-7 transgenic mice.
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To assess the distribution of increased IL-7 mRNA in the inflamed colonic tissues, we examined the differential expression of IL-7 mRNA between the colonic epithelial cells and colonic mucosal lymphocytes. Colonic IELs and LPLs isolated from the inflamed colonic tissues of IL-7 transgenic mice expressed a significant amount of IL-7 mRNA (Fig. 7 A). However, IELs and LPLs from the colonic tissues of littermate mice showed no expression of IL-7 mRNA. Moreover, competitive PCR analysis demonstrated that IL-7 mRNA expression in the colonic epithelial cells was not changed in transgenic mice (Fig. 7 B). These indicated that increased IL-7 expression in the inflamed colonic mucosa of IL-7 transgenic mice was derived from overexpression of IL-7 mRNA in infiltrated mucosal lymphocytes, but not in the colonic epithelial cells. It is important to assess the correlation between the development of colitis and IL-7 mRNA expression in the colonic tissues. Increased IL-7 mRNA was observed in the colonic mucosa at 2 wk of age. However, the onset of colitis was at as early as 4 wk of age.
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To clarify whether increased IL-7 mRNA expression in the colonic mucosa of transgenic mice led to the local overproduction of IL-7 protein, immunohistochemical analysis using an anti-IL-7 antibody was done in the colonic mucosa. As shown in Fig. 8 A, IL-7 protein expression was demonstrated in the colonic epithelial cells and epithelial goblet cells in the colonic mucosa of normal mice. IL-7 protein expression was not changed in the colonic mucosa of IL-7 transgenic mice at 4-6 wk of age (data not shown). However, IL-7 protein expression seemed to be decreased in the goblet-depleted colonic epithelial cells in the chronic inflamed colonic mucosa at 8-10 wk of age (Fig. 8 B).
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Our previous study indicated that IL-7 protein expression by immunohistochemical technique was demonstrated only in the tissue where secreted IL-7 protein was stored and accumulated (11). Therefore, IL-7 protein production by isolated epithelial cells and infiltrating mucosal lymphocytes expressing IL-7 mRNA was assessed in the proliferation assay of an IL-7-dependent cell line DW34. Isolated epithelial cells, IELs, and LPLs from the inflamed colonic mucosa of IL-7 transgenic mice produced an increased amount of IL-7 (data not shown). These results indicated that IL-7 production was not decreased in the inflamed colonic mucosa of IL-7 transgenic mice in parallel with the increase of IL-7 mRNA, but accumulation of IL-7 protein in the colonic mucosa was decreased in the goblet cell- depleted epithelial cells.
The Infiltrating Cells in the Inflamed Colonic Mucosa Consist of CD4-positive T Cells in IL-7 Transgenic Mice.The phenotype of the infiltrating cells was analyzed by immunohistochemistry and flow cytometry. As shown in Fig. 9, lymphoid infiltrates in the lamina propria at the colitis lesion
were dominated by T cells bearing CD4. Both TCR-/
T cells and -
/
T cells infiltrated in the lamina propria of
colonic mucosa (data not shown). However,
/
intraepithelial T cells were not increased at the chronic colitic lesion (Fig. 10), though
/
T cells were the main components of mononuclear cells infiltrating at the dermatitis lesion of IL-7 transgenic mice as previously reported (17). Flow cytometric analysis of isolated cells from intraepithelium demonstrated that CD4+ T cells, but not CD8+ T
cells were significantly increased at the colitis lesions. Infiltrating CD8+ intraepithelial T cells mainly expressed the
/
heterodimer, indicating that these cells were thymus
dependent (Fig. 10).
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To assess the phenotype of infiltrating lamina propria
CD4+ T cells in the chronic inflamed colonic mucosa of
IL-7 transgenic mice, we examined CD45RB expression,
cytokine mRNA expression, and protein production by
these CD4+ T cells. Flow cytometric analysis of isolated
cells from the intestinal mucosa demonstrated that either
CD45RBhigh CD4+ or CD45RBlow CD4+ lamina propria
T cells were not significantly increased in the IL-7 transgenic mice (data not shown). We also performed PCR
analysis of the homogenates of the chronic inflamed colonic mucosa to assess cytokine mRNA expression, but did
not find the changes in IFN- mRNA expression and IL-4
mRNA expression in the IL-7 transgenic mice (data not
shown). We then examined cytokine protein production by isolated cells from the chronic inflamed colonic mucosa.
Isolated cells were cultured and culture supernatants were
analyzed for concentration of Th1 (IL-2, IFN-
) and Th2
(IL-4) cytokines by specific ELISA. Unstimulated lamina
propria CD4+ T cells from IL-7 transgenic mice and normal littermate mice produced marginal amounts of both
IL-2 and IFN-
. Interestingly, isolated lamina propria CD4+
T cells from the inflamed colonic mucosa of IL-7 transgenic mice produced significantly higher levels of both IL-2
and IFN-
than lamina propria CD4+ T cells from littermate mice after stimulation with anti-CD3 and anti-CD28
mAbs (Fig. 11, A and B). In contrast to Th1 type cytokine
production, secretion of IL-4 by unstimulated lamina propria CD4+ T cells from IL-7 transgenic mice was identical
to lamina propria CD4+ T cells from littermate mice, and
in anti-CD3 and anti-CD28 mAb-stimulated lamina propria CD4+ T cells from IL-7 transgenic mice, the average
secretion of IL-4 was reduced compared with littermate
mice (Fig. 11 C).
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To assess the effect of decreased IL-7 protein expression in the proliferation of infiltrating mucosal lymphocytes, IL-7 receptor mRNA expression was analyzed in the colonic mucosa. Southern blot analysis demonstrated that IL-7 receptor mRNA was not readily detectable in the colonic mucosa from wild-type mice. However, IL-7 receptor expression was strongly detected in the inflamed colonic mucosa of transgenic mice (Fig. 12). Receptor expression was not strong in the colonic mucosa of transgenic mice without obvious inflammation. Immunohistochemical analysis demonstrated that IL-7 receptor was mainly expressed in the colonic mucosal lymphocytes. There was no difference in the expression of IL-7 receptor in the thymus between IL-7 transgenic mice and wild-type mice (data not shown).
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Discussion |
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IL-7 is a growth factor for both murine and human, T cell lineage cells. In the mouse, abundant IL-7 mRNA expression has been demonstrated in bone marrow stroma, thymus, spleen, liver, kidney, and keratinocytes (1, 9, 10). Recent studies have shown that IL-7 is expressed in human thymus, spleen, and keratinocytes (7), although a potential role of IL-7 in peripheral lymphoid tissues remains unclear. We have demonstrated that human intestinal epithelial cells produce IL-7 that serves as a regulatory factor for proliferation of intestinal mucosal lymphocytes expressing functional IL-7 receptor (11, 15). In this study, we demonstrated the presence of epithelial cell-derived IL-7 in the normal murine intestine.
To clarify the mechanism by which intestinal epithelial
cell-derived IL-7 regulates the mucosal lymphocytes, we investigated transgenic mice carrying murine IL-7 cDNA and
SR promoter. The SR
expression system is shown to be
one or two orders of magnitude more active than SV40
early promoter in a wide variety of cell types including lymphoid cells and epithelial cells, and promotes a high level of
expression of various lymphokine cDNAs (17). We established transgenic mice carrying murine IL-7 cDNAs by three promoters, SR
, SV40 early, and metallothionein I (16).
SR
/IL-7 transgenic mice developed severe dermatitis in 7 of 30 founder mice at 4-9 wk of age. However, SV40 early
and metallothionein I/IL-7 transgenic mice never developed dermatitis in 9-mo observation periods. Interestingly,
some SR
/IL-7 transgenic lines, but not SV40 early/IL-7,
or metallothionein I/IL-7 transgenic mice developed anal
bleeding and rectal prolapse. Therefore, we used the SR
/ IL-7 transgenic mice in this study. The fact that plural
SR
/IL-7 transgenic lines developed rectal prolapse means
that this phenomenon was caused by the transgene itself
and not by the positional effect of the transgene insertion
on chromosome.
In this study, we provide the evidence that SR/IL-7
transgenic mice developed chronic colitis with perianal bleeding and rectal prolapse. Histological analysis showed erosions, redness, wall thickening with goblet cell-depleted
epithelium, and mononuclear cell infiltration. In the gastrointestinal tract, inflammation was limited to the colon
and ileum, and the most severe inflammation occurred in
the rectum. The inflammatory cells then consisted of lymphocytes, plasma cells, and macrophages in the IL-7 transgenic mice. These mimicked histopathological characteristics of ulcerative colitis in humans (20, 21).
In the IL-7 transgenic mice, the SR/IL-7 transgene was
constitutively expressed in the thymus, spleen, kidney, brain,
lung, and skin, but not in the liver and muscle as previously
reported (16). Interestingly, development of colitis in the
IL-7 transgenic mice was parallel with the SR
/IL-7 transgene expression in the colonic mucosa. Transgenic mice
with SR
/IL-7 transgene expression in the colonic mucosa
developed colitis, but mice without transgene in the colonic mucosa did not. This result indicated that SR
/IL-7 transgene expression in the colonic mucosa was directly related to chronic inflammation in the colon of transgenic
mice. It would be interesting to clarify whether the increased expression of the transgene in the colonic mucosa
induces chronic colitis or whether chronic inflammation in
the colonic mucosa induces the activation of the transgene.
However, conclusive evidence has not been easily obtained. The final cumulative frequencies of colitis in the
line 34 IL-7 transgenic mice were not 100%, but 60%. It
was quite difficult or impossible to assess which appears earlier in the same mice, the development of colitis or SR
/
IL-7 transgene mRNA expression in the colonic mucosa.
However, we found that SR
/IL-7 transgene mRNA expression was not changed in the thymus, spleen, and skin
without dermatitis between mice with colitis and mice
without colitis (Watanabe, M., unpublished observation). Moreover, we found that 15-20% of transgenic mice with
the SR
/IL-7 transgene mRNA expression in the colonic
mucosa did not develop chronic colitis. The preliminary
histopathological observation of colonic mucosa of these
mice demonstrated that they have little infiltration of mononuclear cells in the lamina propria. On the basis of these
findings, we suggest that the expression of detectable SR
/
IL-7 transgene mRNA in the colonic mucosa is a sign of
developing colitis. However, we cannot deny that after initiation of colitis by the transgene expression, inflammation
in the colonic mucosa also induces the activation of the
transgene and eventually transgene mRNA expression is
increased.
Southern blot hybridization and competitive PCR demonstrated that expression of IL-7 mRNA was increased in the inflamed colonic mucosa of the IL-7 transgenic mice. The distribution of IL-7 mRNA in the colonic tissues was quite interesting. Analysis of differential expression of IL-7 mRNA showed that colonic mucosal lymphocytes expressed a significant amount of IL-7 mRNA, but IL-7 mRNA expression in the colonic epithelial cells was unchanged in the inflamed mucosa. Therefore, increased IL-7 mRNA expression in the inflamed colonic mucosa of IL-7 transgenic mice was derived from the colonic mucosal lymphocytes. Interestingly, immunohistochemical analysis demonstrated that IL-7 protein expression in the colonic mucosa and epithelial cells seemed to be decreased at colitis lesion in the IL-7 transgenic mice. Recent studies demonstrated that intestinal epithelial cells express IL-7 receptor and IL-7 regulates the growth and function of epithelial cells by autocrine or paracrine mechanism (22, 23). Overexpression of IL-7 in mucosal lymphocytes may lead to the downregulation of IL-7 protein production in the colonic epithelial cells. However, our previous study indicated that IL-7 protein expression by immunohistochemical technique was demonstrated only in the tissue where secreted IL-7 protein was stored and accumulated (11). Therefore, we assessed IL-7 protein production by isolated cells. Isolated epithelial cells, IELs, and LPLs form the inflamed colonic mucosa of IL-7 transgenic mice produced an increased amount of IL-7. These results indicated that IL-7 production and secretion were increased in the inflamed colonic mucosa of IL-7 transgenic mice in parallel with the increase of IL-7 mRNA, but accumulation of IL-7 protein in the colonic mucosa was decreased in the colitis mucosa. We have shown that intestinal epithelial goblet cells are the major source of mucosal IL-7 in the human intestinal mucosa (11). In this study, goblet cells in the murine colon also produce IL-7. In the inflamed colonic mucosa of IL-7 transgenic mice, histopathological examination revealed the depletion of goblet cells. This result is consistent with the findings that IL-7 protein accumulation was decreased in the inflamed colonic mucosa of the transgenic mice.
How does mucosal lymphocyte-produced IL-7 in the colonic mucosa of IL-7 transgenic mice affect the proliferation of mucosal lymphocytes? We have demonstrated IL-7 mRNA expression and protein production by human colonic epithelial cell line HT29-18-N2 cells after they differentiated into the goblet cell phenotype (Watanabe, M., unpublished observation). However, these cell lines produced marginal amounts of IL-7 in the culture supernatants though these high levels of expressed IL-7 mRNA. The puzzle regarding the low IL-7 protein production is not specific to the HT29 sublines. As other investigators discussed (9), almost all of the cells and cell lines that have been found to produce IL-7 release IL-7 protein only at low levels. The case is the most extreme in the human cells, since it was difficult to detect IL-7 protein production even in the SK-HEP cell line that was used to clone the cDNA for the human IL-7 (24). These observations suggested that IL-7 protein may be rapidly degraded. Locally produced IL-7 from IELs and LPLs in the colonic mucosa may be also degraded or internalized when it does not accumulate in the colonic mucin of the goblet cells. Therefore, we suggest that accumulation of IL-7 protein in the mucus of the goblet cells in the colonic mucosa is crucial for regulating the proliferation of mucosal lymphocytes.
The importance of IL-7 as a mediator of local inflammatory responses remains unclear. However, a possible role for IL-7 in mucosal inflammation has been recently suggested by the finding of decreased IL-7 mRNA expression and IL-7 protein accumulation in the colonic epithelium in inflamed mucosa of patients with ulcerative colitis (Watanabe, M., unpublished observation). We have also demonstrated that IL-7 mRNA expression and IL-7 protein accumulation was significantly increased in the colonic mucosa of patients with acute Salmonella infectious colitis, where goblet cell depletion was not observed. In the IL-7 transgenic mice, decreased IL-7 protein accumulation in the colonic epithelial cells was demonstrated after the onset of colitis. These results favor the idea that the decrease of IL-7 protein accumulation due to the deletion of goblet cells involves the chronic inflammation of the intestinal mucosa.
Lymphoid infiltrates in the lamina propria at the colitis
lesion of IL-7 transgenic mice were dominated by CD4+ T
cells. Analysis of cytokine production by anti-CD3 and
anti-CD28 mAb-stimulated lamina propria CD4+ T cells
from chronic inflamed colonic mucosa of IL-7 transgenic mice showed elevated levels of IL-2 and IFN- production. In contrast, IL-4 secreted by those lamina propria T
cells were decreased in IL-7 transgenic mice. These results
indicate that Th1 type CD4+ T cells were dominated in
the infiltrating lamina propria T cells in the chronic inflamed colonic mucosa of IL-7 transgenic mice. This Th1
pattern of cytokine production from lamina propria CD4+
T cells was also observed in the inflamed colonic mucosa of
mice with the hapten reagent 2, 4, 6-trinitrobenzene sulfonic acid-induced colitis (19). Flow cytometric analysis of
isolated cells from intraepithelium demonstrated that CD4+
T cells, but not CD8+ T cells were increased at the colitis
lesions. Interestingly, infiltrating CD8+ T cells mainly expressed the
/
heterodimer, indicating that these cells
were thymus dependent. TCR-
/
intraepithelial T cells were not increased, although Uehira et al. reported that
transgenic mice constitutively expressing IL-7 developed
severe dermatitis and double negative
/
T cells were the
main components of the infiltrating mononuclear cells at
the dermatitis lesion (16). Recent evidence of an extrathymic pool of TCR-
/
mucosal lymphocytes in the gut
suggests that intestinal epithelial cells may share some differentiation-inducing capacities with thymic epithelial cells,
leading to in situ TCR rearrangement of extrathymically derived T cells (25). We have recently demonstrated the
presence of a novel lymphoid tissue, cryptopatches (CP), in
the murine intestinal mucosa where clusters of IL-7 receptor+
c-kit+ Thy-1+ lympho-hematopoietic progenitor developed
in IL-7-dependent fashion (26). These results indicated
that IL-7 may mediate an extrathymic pathway of mucosal
T cell proliferation. Therefore, overexpression of IL-7 protein in the colitis mucosa of acute stage and decrease of IL-7
protein accumulation in goblet cell-depleted colonic mucosa of the chronic colitis may disturb IL-7-dependent proliferation of lymphocytes and progenitors in the mucosal tissues.
We have demonstrated that mucosal T cells in the normal murine as well as human colonic mucosa constitutively express the receptor for IL-7. In the present study, IL-7 receptor mRNA expression was strongly detected in the inflamed colonic mucosa of IL-7 transgenic mice, but not readily detectable in the colonic mucosa from normal littermate mice. Receptor expression was not strong in the colonic mucosa of transgenic mice without obvious inflammation. These findings indicated that the infiltrating mucosal lymphocytes in the colonic lesion of IL-7 transgenic mice highly expressed the IL-7 receptor. Interestingly, IL-7 receptor expression was quite marked in the mucosal lymphocytes of severely inflamed colonic mucosa from patients with ulcerative colitis (Watanabe, M., unpublished observation). These results raise the possibility that decreased mucosal IL-7 protein accumulation observed in the colonic mucosa with chronic inflammation of IL-7 transgenic mice may result in the increase of infiltrating mucosal lymphocytes expressing the IL-7 receptor. Previous studies have shown that IL-7 stimulates the proliferation of human mature T cells after exogenous stimulation in short time culture, suggesting that IL-7 receptor is not expressed by resting PBLs, but expressed after activation. Therefore, our results indicate that mucosal lymphocytes are activated in the transgenic mice. These activated T cells may produce regulatory factors such as cytokines that augment the inflammation process.
It has been reported that IL-7 acts synergistically with anti-CD3 Ab to stimulate proliferation of human T cells in the thymus and peripheral blood. However, our previous studies demonstrated that IL-7 inhibited anti-CD3-induced proliferation of mucosal T cells in the normal colonic mucosa. Moreover, we showed that IL-7 alone inhibited the growth of mucosal lymphocytes isolated from the inflamed colonic mucosa (Watanabe, M., unpublished observation). These suggested that IL-7 may inhibit the proliferation of activated and IL-7 receptor-expressing mucosal T cells in the intestinal mucosa.
We are now doing the precise time course studies concerning development of colitis, IL-7 protein expression in
the colonic mucosa, and phenotype of infiltration lymphocytes in the IL-7 transgenic mice. IL-7 transgenic mice developed acute colitis with infiltrating neutrophils and lymphocytes at 1-3 wk of age. At that time, IL-7 protein was
significantly expressed in the inflamed colonic mucosa of
IL-7 transgenic mice, but then decreased with depletion of
goblet cells. Accumulation of IL-7 protein in the colonic
mucosa was significantly decreased at 8-12 wk of age. We
also demonstrated that at 1-3 wk of age, infiltrating T
cells in the acute colitis lesion were /
T cells. This result
is consistent with the findings that
/
T cells were accumulated at the acute dermatitis lesion of IL-7 transgenic
mice (16), and is contrasted with the our findings that
/
T cells were infiltrated in the chronic colitis lesion of the
IL-7 transgenic mice. Therefore, we supposed that at 1-3
wk, IL-7 transgenic mice developed
/
T cell-mediated
acute colitis due to the overexpression of IL-7 protein, but
with the inflammation IL-7 protein-producing goblet cells
decreased and accumulation of IL-7 protein in the colonic mucosa decreased in the goblet cell-depleted epithelial cells. Since we demonstrated that mucosal IL-7 regulates the proliferation of mucosal lymphocytes by apoptotic mechanism
(Watanabe, M., unpublished observation), decreased accumulation of IL-7 protein may lead to the chronic inflammation of colon in the IL-7 transgenic mice. These results
are consistent with our recent findings that IL-7 protein
expression was increased in the inflamed colonic mucosa of
acute Salmonella enterocolitis and initial attack of ulcerative colitis, but significantly decreased at the chronic colitis lesion in the relapsing-remission type and chronic continuous type of ulcerative colitis (Watanabe, M., unpublished
observation).
In this paper, we demonstrate that the dysregulation of mucosal IL-7-mediated immune regulation results in the acute and chronic colitis in IL-7 transgenic mice. This colitis mimicked several histopathological characteristics of ulcerative colitis in humans. A major limitation in understanding the pathogenesis responsible for the mucosal injury observed in human inflammatory bowel disease has been due to the lack of animal models that possess the histopathological features of human disease. A series of valuable new models that spontaneously arise in gene knockout mice gives a major impact in our understanding of the mechanisms that lead to chronic intestinal inflammation (27). Although the mechanism by which these mice developed chronic colitis is unclear, series of the study using these mice and our IL-7 transgenic mice may lead to the understanding of the pathogenesis of human inflammatory bowel disease.
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Footnotes |
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Address correspondence to Dr. Mamoru Watanabe, Keio Cancer Center, 35 Shinanomachi, Shinjuku-ku, Tokyo 160, Japan. Phone: 011-81-3-3357-2778; Fax: 011-81-3-3357-2778; E-mail: mamoru{at}mc.med.keio.ac.jp
Received for publication 3 January 1997 and in revised form 18 November 1997.
The authors would like to express special thanks to Professors Daniel Podolsky, Lloyd Mayer, and Sadakazu Aiso for critical comments; Drs. Noriaki Watanabe, Yasuo Hosoda, Nagamu Inoue, and Hiromasa Takaishi for technical assistance; and Miss Reiko Fujisaki for manuscript preparation.This study was supported in part by Grants-in-Aid from the Japanese Ministry of Education, Culture and Science, the Japanese Ministry of Health and Welfare, and Keio University Medical Science Fund.
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