Selective localization of lymphoblasts prepared from guinea pig intestinal lamina propria

The tissue localization patterns of radiolabeled dividing cells obtained from gut lamina propria (LP), mesenteric (MLN) and peripheral (PLN) lymph nodes, and Peyer's patches (PP) were studied in guinea pigs using an adoptive lymphocyte transfer method. Within 24 hr ¹²⁵I-deoxyuridine-labeled cells from donor LP and MLN, but not PLN, selectively localized in recipient gut and MLN. In contrast, donor PLN lymphoblasts returned to their sites of origin while labeled PP donor cells exhibited no specific tissue localization. These findings suggest that the gut LP, like the MLN, contains a population of cells which, unlike those in the PP and PLN, has the capacity to selectively localize in mucosal tissues. From this and other published work, we conclude that within the LP there is a population of cells at different stages of differentiation with a propensity to populate mucosae.     

Differentiation pathway of Peyer's patch precursors of IgA plasma cells in the secretory immune system

Others have shown that Peyer's patch (PP) precursor cells can seed the small intestine with IgA plasma cells, whose appearance after cell transfer requires an interval of a week. The location of the precursor cells during this period is the subject of the present investigation in which the fate of radiolabeled murine PP cells was studied after intravenous transfer into primary and secondary recipients. In short-term single-transfer experiments, few radiolabeled PP blasts were found in the small intestine and only a small proportion of these contained IgA. Radiolabeled PP blasts were approximately equally distributed between mesenteric lymph nodes (MN) and peripheral lymph nodes (PN). However, a higher proportion of those which went to MN than of those which went to PN was subsequently capable of settling in the small intestine of secondary recipients and a higher proportion of those arriving in the intestine was found to contain IgA. Thus, MN were distinctly superior to PN as an intermediate site for the maturation of PP-derived IgA plasma cell precursors capable of seeding the small intestine, even when these had been injected intravenously. Treatment of PP cells with antiserum to IgA prior to their injection into primary recipients interfered with the homing of IgA precursor cells to the small intestine of secondary recipients, indicating that the precursors are already producing IgA while still in the PP. IgA-containing, radiolabeled PP cells were found in the subcapsular sinus of MN within 30 min of intravenous injection, suggesting that these cells are capable of extravasating from blood and reaching the lymph within the intestine long before they are ready to remain in the intestine as plasma cells. These results imply that the superiority of MN over PN as an intermediate site for the proliferation and differentiation of PP IgA precursor cells into IgA plasma cells capable of seeding the small intestine is due to the location of the MN in the pathway of circulation of mucosal B cells.     

Determinants of the localization, magnitude, and duration of a specific mucosal IgA plasma cell response in enterically immunized rats

The origin and fate of specific IgA plasma cells in intestinal lamina propria were studied in rats immunized enterically with cholera toxin (CT). Our major goal was to define how an anti-CT response is focused and sustained at the site of antigen challenge. To distinguish antigen-dependent from antigen-independent mechanisms, CT exposure was restricted to defined portions of intestine and, in some studies, the distribution of antitoxin-containing plasma cells (ACC) was examined in nonimmune adoptive recipients of post-challenge thoracic duct lymphocytes. After enteric priming and challenge, ACC appeared throughout the gut, but were most numerous at the challenged site. About 25% of ACC appearing at the site of jejunal challenge were due to antigen-driven proliferation of memory cells within the lamina propria; the remainder arose elsewhere, apparently in mucosal follicles or mesenteric lymph nodes, and migrated systemically as antitoxin-containing plasmablasts before homing to the lamina propria. The homing of these migrating ACC precursors was not affected by mucosal exposure to CT, nor did they undergo appreciable antigen-driven division after arrival in gut lamina propria. However, homing was specific for the organ from which they arose, i.e., precursors arising from duodenal challenge homed selectively to jejunum, whereas those from colonic challenge homed to the colon. The organ specificity of homing was determined during the challenge response and was independent of the origin of memory cells participating in the response. The survival of migrating ACC precursors did not differ in segments of gut exposed or nonexposed to CT. However, CT exposure at the time of their migration evoked another secondary-type response, due to stimulation of comigrating memory cells, thus sustaining the secondary response at a high level. These results and those in a previous report identify important mechanisms that affect the localization, magnitude, and duration of a specific IgA response, at least in the intestine. These include: 1) organ-specific homing of migrating IgA plasmablasts, 2) antigen-driven generation of IgA plasma cells from memory cells within the lamina propria, 3) enhanced memory at the site of mucosal priming compared to that a distant mucosae, and 4) regeneration of memory cells during the secondary response.     

Organ and isotype distribution of plasma cells producing specific antibody after oral immunization: evidence for a generalized secretory immune system.

Mice were induced to produce IgA antibodies against ferritin after oral immunization. Such antibodies were detected by immunofluorescence in plasma cells in the intestinal mucosa as well as in secretory sites located elsewhere, such as the lactating mammary gland, salivary gland, and respiratory tract. The observation suggested that cells immunized locally via the gut could home to distant secretory sites. To confirm this hypothesis, lymphocyte transfer studies were done with mesenteric node (MN) versus peripheral node (PN) cells from orally immunized donors into nonimmunized recipients. IgA anti-ferritin cells from MN homed to exocrine targets, whereas IgM and IgG anti-ferritin cells homed to PN. The findings overall support the concept of a generalized and interrelated secretory immune system.     

Selective chemotaxis of subsets of B lymphocytes from gut-associated lymphoid tissue and its implications for the recruitment of mucosal plasma cells

As they differentiate, precursor cells from the gut-associated lymphoid tissue are known to travel via the lymphatic system to the blood and then preferentially to home to various mucosal and exocrine sites such as the lamina propria of the gut and the lactating mammary gland, where they give rise to IgA-secreting plasma cells. The present study, directed at the mechanism by which the circulating precursors of mucosal IgA plasma cells selectively lodge in characteristic locations, explored the hypothesis that such homing is due to a locally produced chemotactic factor and that milk might be a source of such a factor. Subsets of lymphocytes bearing particular surface markers and purified by panning from lymph nodes of mice were examined in a micropore chemotaxis assay to search for the presence of chemotactic activity in mouse milk. The globulin fraction of whey was shown to contain a nondialyzable factor that is chemotactic for IgA (and also IgG)-positive lymphocytes when these are obtained from mesenteric lymph nodes as a source of mucosal-associated lymphoid tissue. Lymphocytes from peripheral lymph nodes, nonmucosal associated, were unaffected as were surface IgM-positive lymphocytes and T lymphocytes obtained from mesenteric nodes. Chemotactic activity for IgA lymphocytes was undetectable in mouse serum. The data are consistent with the idea that precursors of mucosal IgA plasma cells home to mucosal and exocrine sites in response to a specific chemotactic factor elaborated by local differentiated epithelial cells.     

Increased frequency of surface IgA-positive plasma cells in the intestinal lamina propria and decreased IgA excretion in hyper IgA (HIGA) mice, a murine model of IgA nephropathy with hyperserum IgA

Because abnormalities of mucosal immunity have been suggested in human IgA nephropathy, we examined the involvement of mucosal immunity in IgA deposition to the kidney in hyper IgA (HIGA) mice, which was established as a mouse model for human IgA nephropathy with hyperserum IgA. The number of surface IgA+B220- lymphocytes in the intestinal lamina propria (LP) of HIGA mice increased 2.7-fold at 30 wk of age as compared with those at 10 wk of age, whereas normal mice did not show such increase. The surface IgA+B220- LP lymphocytes spontaneously secreted IgA in culture. Morphological studies showed that the surface IgA+B220- lymphocytes of murine intestinal LP are identical with plasma cells (PCs). About 20% of IgA+B220- PC in LP expressed both Mac-1 and CD19, suggesting that they may derive from peritoneal B-1 cells. Cell cycle study on intestinal IgA-PCs using bromodeoxyuridine revealed no difference between HIGA mice and normal mice, suggesting that the high frequency of IgA-producing PCs in HIGA mice is not due to enhanced proliferation or prolonged survival of IgA-producing PCs in LP. In addition, IgA secretion into the gut lumen of HIGA mice decreased drastically (to one forth) with aging. These data suggest that the increased number of intestinal IgA-producing PCs and the down-regulation of IgA excretion into the intestinal lumen might synergistically contribute to the hyperserum IgA in HIGA mice and resultant IgA deposition to the kidney.     

B-lymphocyte responses in the large intestine and mesenteric lymph nodes of mice infected with Eimeria falciformis (Apicomplexa)

B-cell responses of 3 immunoglobulin isotypes (IgA, IgG, and IgM) were investigated in the large intestine and mesenteric lymph nodes (MLN) of naive or immune mice after inoculation of oocysts of Eimeria falciformis. Primary and anamnestic IgA and IgG lymphocyte responses to E. falciformis occurred in the large intestine of nonimmune and immune mice, respectively. IgA-containing lymphocytes (IgAc) were the largest population of responding B cells in the large intestine. In infected mice, IgAc accumulated in the apical portion of the lamina propria, whereas IgG-containing lymphocytes (IgGc) were more numerous at the base of the lamina propria. No significant increase in the number of IgM-containing lymphocytes (IgMc) was observed in the lamina propria of the large intestine. Primary but no anamnestic B-cell responses occurred in the MLN, and immune mice actually had reduced numbers of IgAc and IgGc in the MLN when compared with naive mice. IgGc were the largest population of responding B cells in the MLN. Thus, IgAc appear to accumulate preferentially at the site of parasite development, whereas IgGc are primarily localized deeper in the lamina propria of the large intestine and in the draining lymph nodes of mice infected with E. falciformis.     

Role of mesenteric lymph nodes and aging in secretory IgA production in mice

Although it is known that Peyer's patches are the major inductive site for S-IgA production and B1 cells contribute to half of the IgA plasma cells detected in the gut lamina propria, the type of contribution of mesenteric lymph nodes to the process is still unclear. Cytokines such as TGF-beta, IL-10, IL-4, IL-5, and IL-6, are required to promote IgA class switching and IgA synthesis. Aging-related alterations in T and B cells and in cytokine production are already known. Some reports have also proposed that S-IgA production might be altered in aged animals. Herein, we investigated the role of MLN and aging in S-IgA production. Two- to 18-month-old BALB/c mice were used to evaluate aging-related alterations and MLN were removed to study its role in S-IgA production. We found that MLN are important, although not essential for S-IgA production. In addition, we showed that production of IgA-related cytokines are well preserved in MLN but not in PP of aged mice and that S-IgA levels are not affected by aging. Our results suggest that MLN may play a complementary role in S-IgA production mostly in aged animals.     

IgA allotype suppression in mice: A cellular implication for the IgA preponderance in the gut

Paternal IgA allotype suppressions were induced in (A/HeJ x SJL/J)F₁, (BALB/cJ x CB-20) F₁, and (BALB/cJ x SJL/J)F₁ mice by perinatal exposure of the neonates to antibody against paternal IgA allotype (Ig-2b). All the Ig-2b allotype suppressions were temporary and were prominently seen at the age of 4–10 weeks. These transient Ig-2b allotype suppressions were manifested by a suppression of Ig-2b allotype in the serum and a suppression of Ig-2b allotype-producing cells in the gut lamina propria. During the suppression, no replacement of the Ig-2b allotype by IgM and IgG plasma cells was seen in the gut lamina propria. The transient IgA allotype suppression was primarily due to a depletion of IgA allotype precursors in Peyer's patches; suppressor T cells were not actively involved. These results suggest that IgA preponderance in the gut is due to the migration of the patch IgA precursors and their accumulation and maturation in the gut lamina propria.     

A monoclonal antibody specific for rat intestinal lymphocytes

A monoclonal antibody, RGL-1, was produced by fusion of NSI myeloma cells with spleen cells of a mouse immunized with isolated rat intraepithelial lymphocytes (IEL). SDS-PAGE analysis revealed that RGL-1 precipitated two major noncovalently bound chains of about m.w. 100,000 and 125,000, and a minor component of m.w. 200,000. Examination of both tissue sections and isolated cells indicated that RGL-1 stained the majority of the lamina propria lymphocytes and IEL but only very few cells (less than 2%) in the lymphoid organs and small numbers of lymphocytes in other mucosae. In the small intestine, RGL-1 stained lymphocytes with the helper (W3/25) as well as the cytotoxic/suppressor (OX8) phenotype. The antibody reacted with 95% of the granular IEL but with less than 0.1% of the blood large granular lymphocytes. Although mature IgA plasma cells in the lamina propria were RGL-1-, some large IgA-containing cells were weakly positive. In the gut-associated lymphoid tissues (GALT), studies combining immunofluorescence and autoradiography indicated that 56 and 73% of rapidly dividing cells of mesenteric lymph nodes and of thoracic duct lymph (TDL) stained with RGL-1, respectively. In addition, 90 to 100% of the IgA-containing blasts of MLN and 75% of those of TDL were labeled by RGL-1. In contrast, rapidly dividing cells of spleen and of peripheral lymph nodes did not stain with RGL-1. Because RGL-1 can be demonstrated on both intestinal lymphocytes and their immediate precursors in the GALT, its expression may be related to the homing of lymphocytes into the gut mucosa.     

Strong differential regulation of serum and mucosal IgA responses as revealed in CD28-deficient mice using cholera toxin adjuvant

In this study, we show that costimulation required for mucosal IgA responses is strikingly different from that needed for systemic responses, including serum IgA. Following oral immunization with cholera toxin (CT) adjuvant we found that whereas CTLA4-H1 transgenic mice largely failed to respond, CD28-/- mice developed near normal gut mucosal IgA responses but poor serum Ab responses. The local IgA response was functional in that strong antitoxic protection developed in CT-immunized CD28-/- mice. This was in spite of the fact that no germinal centers (GC) were observed in the Peyer's patches, spleen, or other peripheral lymph nodes. Moreover, significant somatic hypermutation was found in isolated IgA plasma cells from gut lamina propria of CD28-/- mice. Thus, differentiation to functional gut mucosal IgA responses against T cell-dependent Ags does not require signaling through CD28 and can be independent of GC formations and isotype-switching in Peyer's patches. By contrast, serum IgA responses, similar to IgG-responses, are dependent on GC and CD28. However, both local and systemic responses are impaired in CTLA4-Hgamma1 transgenic mice, indicating that mucosal IgA responses are dependent on the B7-family ligands, but require signaling via CTLA4 or more likely a third related receptor. Therefore, T-B cell interactions leading to mucosal as opposed to serum IgA responses are uniquely regulated and appear to represent separate events. Although CT is known to strongly up-regulate B7-molecules, we have demonstrated that it acts as a potent mucosal adjuvant in the absence of CD28, suggesting that alternative costimulatory pathways are involved.     

Development and distribution of B lineage cells in the domestic cat: analysis with monoclonal antibodies to cat mu-, gamma-, kappa-, and lambda-chains and heterologous anti-alpha antibodies

To trace the development and distribution of B lineage cells in the domestic cat (Felis catus), we have produced monoclonal antibodies against mu-, gamma-, kappa-, and lambda-chains of feline immunoglobulins (Ig). Goat antibodies against human mu-, alpha-, and lambda-chains, which are reactive with shared determinants on their feline counterparts, were used in conjunction with the panel of mouse monoclonal antibodies. Cytoplasmic mu+ pre-B cells and surface IgM+ B lymphocytes were observed in 42 day fetal liver in which pre-B cells were more abundant than IgM+ B cells. Pre-B cells also were found in bone marrow in young cats, and continued to be generated in the marrow throughout life. In the spleen, adult levels of B cells were attained by 12 wk of age, at which time the frequencies of surface IgM+, IgG+, and lambda+ cells were 49, 3, and 40%, respectively. The distributions of Ig isotypes also were determined among plasma cells as a function of age and tissue localization. IgM plasma cells were predominant in the bone marrow of 1-wk-old cats, whereas IgG plasma cells were the prevalent isotype in adult bone marrow. In the mesenteric lymph nodes of adult animals, the frequency distributions of IgM, IgG, and IgA plasma cells were similar to the frequency distributions of IgM, IgG, and IgA isotypes among bone marrow plasma cells. IgA+ plasma cells predominated in the intestinal lamina propria, in which IgG+ and IgM+ plasma cells were relatively infrequent. In the tissues of both young and adult animals, the ratio of lambda:kappa expression was approximately 3:1. We conclude that the pattern of B cell development in the cat resembles that found in other mammals, except that the kappa to lambda ratio is reversed.     

Enteric migration of radiolabeled lymphocytes.

The migratory patterns of circulating radioisotopically labeled lymphocytes were studied by means of serial transfer into syngeneic recipients. A sub-population of ⁵¹Cr-labeled lymphocytes, defined by their property of additionally labeling with IUDR, was found to possess migrational specificity for the lamina propria of stomach, jejeunum, ileum, and large bowel. This gut-seeking population was found within peripheral nodes, mesenteric nodes, Peyer's patches, thymus, and spleen and consisted of both B and T cells. Labeled lymphocytes homed to intestine during all phases of the cell cycle, suggesting that specificity for the gut is not linked to specific events in the lymphocyte cell cycle.     

IgA plasma cells express the negative regulatory co-stimulatory molecule programmed cell death 1 ligand and have a potential tolerogenic role in the intestine

To maintain immune homeostasis in the intestine, the intestinal immune system has evolved several tolerogenic mechanisms toward intestinal microflora and food antigens. Although programmed cell death-1 (PD-1) protein has been implicated in immunological tolerance in the intestine and gut-associated lymphoid tissues (GALTs), distribution of its ligands PD-L1 and PD-L2 in the small intestine lamina propria (LP) are unknown. We investigated PD-L1 expression in intestinal LP and found that IgA plasma cells (PCs) were major PD-L1 expressing cells. PD-L1 expression levels on IgA PCs were higher than that on IgG PCs in peripheral lymphoid tissues. IgA PCs expressed antigen-presenting molecule MHC class II and co-stimulatory molecules CD80, CD86, and PD-L2. IgA PCs isolated from intestinal LP exhibited antigen presentation activity, and in the presence of TGF-β induced FoxP3⁺ regulatory T cells, but not IFN-γ⁺ Th1 cells, from naïve T cells. Thus, IgA PCs in the intestine may be involved in an immune regulatory role in the intestinal immune system.     

BAFF induces a hyper-IgA syndrome in the intestinal lamina propria concomitant with IgA deposition in the kidney independent of LIGHT

BAFF is a peripheral B cell survival factor and can mediate antibody (Ab) class switching. Over-expression of BAFF in mice results in B cell hyperplasia, elevated serum immunoglobulin (Ig), spontaneous germinal centre (GC) reactions and mild glomerulonephritis (GN). Here we show that, in addition to driving excessive levels of serum IgA, BAFF over-expression results in increased IgA levels within the intestinal lamina propria (LP) and deposition of IgA immune complexes in the renal glomerular mesangium. LIGHT has been previously shown to mediate a similar phenotype via signaling through the lymphotoxin-beta receptor (LTbetaR). We evaluated if LIGHT and BAFF cooperate in the etiology of a hyper-IgA syndrome in BAFF-overexpressing transgenic (BAFF-Tg) mice. We find that LIGHT-deficient BAFF-Tg mice exhibit similar levels of IgA in the serum, gut and kidney and develop nephritis to the same degree as LIGHT-sufficient BAFF-Tg mice. Therefore, in the context of BAFF over-expression, LIGHT is dispensable for the generation of a hyper-IgA syndrome accompanied by nephritis.     

Lack of J chain inhibits the transport of gut IgA and abrogates the development of intestinal antitoxic protection.

Recent publications have provided confusing information on the importance of the J chain for secretion of dimeric IgA at mucosal surfaces. Using J chain-deficient (J chain-/-) mice, we addressed whether a lack of J chain had any functional consequence for the ability to resist challenge with cholera toxin (CT) in intestinal loops. J chain-/- mice had normal levels of IgA plasma cells in the gut mucosa, and the Peyer's patches exhibited normal IgA B cell differentiation and germinal center reactions. The total IgA levels in gut lavage were reduced by roughly 90% as compared with that in wild-type controls, while concomitantly serum IgA levels were significantly increased. Total serum IgM levels were depressed, whereas IgG concentrations were normal. Following oral immunizations with CT, J chain-/- mice developed 10-fold increased serum antitoxin IgA titers, but gut lavage anti-CT IgA levels were substantially reduced. However, anti-CT IgA spot-forming cell frequencies in the gut lamina propria were normal. Anti-CT IgM concentrations were low in serum and gut lavage, whereas anti-CT IgG titers were unaltered. Challenge of small intestinal ligated loops with CT caused dramatic fluid accumulation in immunized J chain-/- mice, and only 20% protection was detected compared with unimmunized controls. In contrast, wild-type mice demonstrated 80% protection against CT challenge. Mice heterozygous for the J chain deletion exhibited intermediate gut lavage anti-CT IgA and intestinal protection levels, arguing for a J chain gene-dosage effect on the transport of secretory IgA. This study unequivocally demonstrates a direct relationship between mucosal transport of secretory SIgA and intestinal immune protection.     

Alternate mucosal immune system: organized Peyer's patches are not required for IgA responses in the gastrointestinal tract

The progeny of mice treated with lymphotoxin (LT)-beta receptor (LTbetaR) and Ig (LTbetaR-Ig) lack Peyer's patches but not mesenteric lymph nodes (MLN). In this study, we used this approach to determine the importance of Peyer's patches for induction of mucosal IgA Ab responses in the murine gastrointestinal tract. Immunohistochemical analysis revealed that LTbetaR-Ig-treated, Peyer's patch null (PP null) mice possessed significant numbers of IgA-positive (IgA+) plasma cells in the intestinal lamina propria. Further, oral immunization of PP null mice with OVA plus cholera toxin as mucosal adjuvant resulted in Ag-specific mucosal IgA and serum IgG Ab responses. OVA-specific CD4+ T cells of the Th2 type were induced in MLN and spleen of PP null mice. In contrast, when TNF and LT-alpha double knockout (TNF/LT-alpha-/-) mice, which lack both Peyer's patches and MLN, were orally immunized with OVA plus cholera toxin, neither mucosal IgA nor serum IgG anti-OVA Abs were induced. On the other hand, LTbetaR-Ig- and TNF receptor 55-Ig-treated normal adult mice elicited OVA- and cholera toxin B subunit-specific mucosal IgA responses, indicating that both LT-alphabeta and TNF/LT-alpha pathways do not contribute for class switching for IgA Ab responses. These results show that the MLN plays a more important role than had been appreciated until now for the induction of both mucosal and systemic Ab responses after oral immunization. Further, organized Peyer's patches are not a strict requirement for induction of mucosal IgA Ab responses in the gastrointestinal tract.     

Proliferative kinetics of large and small intraepithelial lymphocytes in the small intestine of the mouse.

The proliferative kinetics of the intraepithelial lymphocytes (IL) of the mouse intestine have been evaluated. By inducing mitotic arrest it was found that large IL - constituting about 50% of the IL - showed a mitotic rate of 2.3. Autoradiographic results obtained after two different schedules of 3H-thymidine injections showed that 30% of the large IL were in DNA synthesis, and that the large IL were renewed at a rate comparable to that of blast cells from Peyer's patches, mesenteric lymph nodes and thoracic duct lymph. The small IL were renewed very rapidly compared to small lymphocytes of peripheral lymphoid tissues, although small lymphocytes with lifespans of several weeks were also present in the epithelial sheet. By the use of intestinal perfusion, in vivo, it was estimated that the loss of lymphocytes from intestinal villi into the lumen of the gut was negligible, and it is concluded that the most probable kinetic model for the majority of IL is: B and T lymphoblasts invade the epithelium and undergo mitosis. B lymphoblasts give rise predominantly to plasma cells, and T lymphoblasts give rise to small lymphocytes - probably long-lived - which reenter the circulation.     

Ulmus davidiana var. japonica Nakai Upregulates Eosinophils and Suppresses Th1 and Th17 Cells in the Small Intestine

The bark of Ulmus davidiana var. japonica Nakai (Ulmaceae) has been used in traditional Korean medicine for chronic inflammation in the gastrointestinal tract. Here we investigated the frequency and cytokine profile of the major immune cells in the small intestinal lamina propria (SI LP), spleen, and mesenteric lymph nodes (MLNs) of mice treated orally with Ulmus davidiana var. japonica Nakai bark water extract (UDE) to address the immunomodulatory role of this herb in intestinal homeostasis. B6 mice were given 5g/kg UDE once daily for 14 days. They were then sacrificed, and cells were isolated from the spleen, MLNs, and SI LP. The proportion of B versus T lymphocytes, CD4⁺ versus CD8⁺ T lymphocytes, Th1 and Th17 cells, and Foxp3⁺ regulatory T cells in the spleen, MLNs, and SI LP were analyzed. The frequency of antigen-presenting cells (APCs), including dendritic cells, macrophages, and eosinophils in the SI LP and the expression of costimulatory molecules on APCs were also evaluated. The numbers and frequencies of Th1 and Th17 cells in the SI LP were significantly reduced in the UDE-treated mice compared with PBS controls. In addition, the proportion of IL-4-producing eosinophils in the SI LP was significantly elevated in the UDE-treated mice compared with controls. Taken together, these data indicate that UDE up-regulates the number and frequency of SI LP eosinophils, which can down-regulate the Th1 and Th17 responses via IL-4 secretion and contribute to intestinal homeostasis.