Oral administration of bovine whey proteins to mice elicits opposing immunoregulatory responses and is adjuvant dependent

Most studies investigating the induction of oral tolerance (OT) use purified proteins such as ovalbumin (OVA), bovine serum albumin (BSA) and beta-lactoglobulin (beta-LG). Little information is available regarding the induction of OT to a protein mixture, e.g. cow's milk. In this study we compared the regulatory mechanisms induced after the oral administration of a whey protein concentrate (WP) derived from cow's milk following immunization with two different adjuvants, complete Freund's adjuvant (CFA) and alum. OVA was used as a control antigen. Animals were given a single feed of these proteins at an equivalent dose of 1 mg/g body weight before they were immunized seven days later with the antigen in Freund's adjuvant or alum. Delayed type hypersensitivity (DTH) responses were suppressed by both a feed of WP and OVA after immunization with CFA. However, only OVA feeding suppressed antigen specific IgG responses. In an attempt to investigate whether WP would tolerize the more susceptible IgE responses, alum immunization replaced CFA as the adjuvant used for systemic immunizations. WP, after a single feed, significantly primed for DTH and IgE responses indicating oral sensitization to WP. In contrast, OVA suppressed DTH, IgE and IgG responses. Antigen specific proliferation of mononuclear cells was suppressed in mice fed OVA, but primed in those fed with WP. In addition cells taken from sensitized mice fed WP up-regulated levels of specific interleukin (IL) -4, -10 and -12 in vitro whereas these cytokines were suppressed in cultures from tolerant WP fed mice. Global suppression was obtained in cultures from tolerant OVA fed mice. TGF-beta was not detected in draining PLN cell cultures of either tolerant or sensitized mice. These data suggest that a whey protein mixture induces divergent responses following immunization with either CFA or alum despite being fed at an identical dose. We suggest that that the choice of the adjuvant may determine the immunoregulatory outcome and this is also reflected by the systemic cytokine profile.     

Priming of systemic and local delayed-type hypersensitivity responses by feeding low doses of ovalbumin to mice.

We have examined the effects on both systemic and intestinal immunity of feeding different doses of ovalbumin (OVA) to mice. A single feed of doses of more than 1 mg OVA produced significant suppression of subsequent delayed-type hypersensitivity (DTH) and IgG antibody responses. Feeding 100 micrograms-1 mg OVA had no net effect on systemic immunity, but mice fed 10-50 micrograms OVA had consistently enhanced systemic DTH responses when immunized subsequently with OVA in adjuvant. Oral challenge of these mice with OVA produced alterations in mucosal architecture and in intra-epithelial lymphocyte counts, consistent with the presence of an intestinal DTH response. Similar changes were not found in mice fed tolerogenic doses of OVA. Although feeding low doses of OVA primed both systemic and intestinal DTH responses, this had no effect on serum IgG responses and very little systemic DTH could be revealed in OVA-fed mice without systemic challenge with OVA in adjuvant. We conclude that feeding certain low doses of protein antigens can induce priming of local and systemic DTH responses rather than the immune tolerance which is normally found. The development of clinical food hypersensitivities may be highly dependent on the dose of dietary antigen at the time of first encounter.     

Suppression of an established DTH response to ovalbumin in mice by feeding antigen after immunization

Experiments were designed to examine whether systemic delayed-type hypersensitivity responses (DTH) to ovalbumin (OVA) can be suppressed when antigen is fed after immunization, and to investigate the immunological mechanisms involved. A single 25 mg feed of OVA given 7 or 14 days after immunization with OVA in complete Freund's adjuvant (CFA) suppressed the DTH response of BDF1 mice, but had no significant effect on the serum IgG antibody response. DTH suppression was greatest when antigen was fed soon after immunization, and became less pronounced as the time interval between feeding and immunization increased. The phenomenon was also demonstrated in mice of the BALB/c strain. Cell transfer experiments suggested that the post-immunization suppression was not due to a population of suppressor cells that have been described previously in association with classical oral tolerance for DTH. We conclude that there are separate and distinct mechanisms for the prevention of induction of DTH by antigen feeding in naive mice and the suppression of expression of DTH in sensitized animals.     

Induction of mucosal and systemic immune responses by immunization with ovalbumin entrapped in poly(lactide-co-glycolide) microparticles.

We have examined the range of mucosal and systemic immune responses induced by oral or parenteral immunization with ovalbumin (OVA) entrapped in poly(D,L-lactide-co-glycolide) (PLG) microparticles. A single subcutaneous immunization with OVA-PLG primed significant OVA-specific IgG and delayed-type hypersensitivity (DTH) responses. The DTH responses were of similar magnitude to those obtained using immunostimulating complexes (ISCOMS) as a potent control adjuvant, although ISCOMS stimulated higher serum IgG responses. Both vectors also primed OVA-specific in vitro proliferative responses in draining lymph node cells following a single immunization and strong OVA-specific CTL responses were found after intraperitoneal (i.p.) immunization. ISCOMS were more efficient in inducing cytotoxic T lymphocytes (CTL), requiring much less antigen and only ISCOMS could stimulate primary OVA-specific CTL responses in the draining lymph nodes. Multiple oral immunizations with OVA in PLG microparticles or in ISCOMS resulted in OVA-specific CTL responses and again ISCOMS seemed more potent as fewer feeds were necessary. Lastly, multiple feeds of OVA in PLG microparticles generated significant OVA-specific intestinal IgA responses. This is the first demonstration that PLG microparticles can stimulate CTL responses in vivo and our results highlight their ability to prime a variety of systemic and mucosal immune responses which may be useful in future oral vaccine development.     

Chemical Denaturation of Ovalbumin Abrogates the Induction of Oral Tolerance of Specific IgG Antibody and DTH Responses in Mice

We have examined the effects of ingestion of chemically denatured ovalbumin (OVA) in mice. Both 8 M urea-denatured OVA (UD-OVA) and carboxymethylated UD-OVA (CM-OVA) were purified by gel filtration. Specific IgG antibody and systemic delayed-type hypersensitivity (DTH) responses to OVA were not suppressed by CM-OVA fed prior to or after immunization with OVA in complete Freund's adjuvant (CFA). When CM-OVA was used instead of OVA for immunization, serum IgG and DTH responses to CM-OVA were orally tolerized by OVA, but not by UD-OVA or CM-OVA. Studies of antigen uptake in mice using sandwich ELISA tests showed that OVA, but not CM-OVA, was absorbed after antigen ingestion. In vitro studies further demonstrated that CM-OVA was digested much more rapidly than OVA. Moreover, studies using bovine serum albumin (BSA) demonstrated that both IgG and DTH responses to BSA were orally tolerant to BSA, but not to denatured BSA. Finally, studies using human gamma-globulin (HGG), a well-known tolerogen, also found that the IgG antibody response to HGG was not orally tolerized by denatured HGG. These results suggest that complete denaturation of globular proteins may affect their processing and absorption in the gut and thus abrogates oral tolerance induction.     

Divergent effects of bacterial lipopolysaccharide on immunity to orally administered protein and particulate antigens in mice.

We have investigated whether bacterial lipopolysaccharide (LPS) influences immune responses to dietary protein antigens in experimental animals. Simultaneous intravenous administration of LPS to normal mice fed ovalbumin (OVA) prevented the induction of tolerance for serum IgG antibody responses but did not alter the tolerance of systemic delayed-type hypersensitivity (DTH). In addition, exogenous LPS did not enhance the ability of spleen accessory cells to present OVA to primed T cells. LPS-unresponsive C3H/HeJ mice developed full tolerance of both humoral and cell-mediated immunity after feeding a range of doses of OVA that was equal in degree and persistence to that seen in normal, congenic C3H/HeOla mice and also had normal antigen-presenting cell (APC) activity for OVA. In contrast, C3H/HeJ mice were primed by feeding SRBC instead of developing the systemic tolerance found in normal C3H mice. Our results indicate the complexity of mechanisms that may regulate systemic immunity to orally administered antigens of different forms. Nevertheless, LPS does not modulate DTH responses to fed OVA and does not enhance APC activity, and we conclude that bacterial LPS may be unable to influence hypersensitivity to dietary proteins in man.     

The role of antigen recognition and suppressor cells in mice with oral tolerance to ovalbumin.

The induction of tolerance by feeding proteins may prevent potentially harmful delayed-type hypersensitivity (DTH) reactions to food antigens. Suppressor T cells (Ts) are present in mice with tolerance of systemic DTH after feeding ovalbumin (OVA) but, as other immunoregulatory mechanisms have also been described, the exact role of Ts in maintaining tolerance is not known. In this study, we have used the ability of native and denaturated OVA to cross-react at the level of helper/effector T cells, but not Ts, to re-examine the role of Ts in oral tolerance to OVA. Mice immunized with native OVA (nOVA) or denatured OVA (dOVA) in adjuvant had fully cross-reacting DTH to either nOVA or dOVA, but intravenous administration of antigen induced Ts which were specific for the appropriate form. Mice fed nOVA or dOVA had identical tolerance of systemic DTH to both forms of OVA, and feeding nOVA induced splenic Ts which suppressed the DTH response to both nOVA and dOVA. Splenic Ts could not be detected in mice fed dOVA. The results support the hypothesis that tolerance of systemic DTH in mice fed native proteins is due to Ts. Although, for the moment, there is no complementary evidence for a role for Ts in oral tolerance to denatured proteins, this study is consistent with the idea that Ts are the mechanism which normally prevent enteropathy due to DTH against dietary proteins. In addition, our study underlines the differences between orally and parenterally induced Ts and reinforces the view that fed proteins induce Ts after processing by the gut or its lymphoid accessory cells.     

Maternal determinants of neonatal immune response to ovalbumin: effect of breast feeding on development of anti-ovalbumin antibody in the neonate

Inbred Brown-Norway female rats were immunized intraperitoneally with ovalbumin (OVA) or sham-immunized 14 days before and 10 days after mating. In subsequent studies with OVA, babies fed by immunized mothers, regardless of whether they were born from immunized or sham-immunized mothers, showed suppression of IgG, IgM and IgE anti-OVA responses. In additional studies, these babies developed OX-8-positive but W3/25-negative phenotypic suppressor T-cells specific for anti-OVA antibody production. However, these regulatory cells did not react with OVA itself when tested for in vitro proliferative response to OVA. Subsequent immunization of the neonates with OVA appeared to abrogate suppression of IgG and IgM antibody responses. However, maternally induced suppression of IgE persisted and was not influenced by subsequent immunization.     

Oral tolerance in protein-deprived mice. I. Profound antibody tolerance but impaired DTH tolerance after antigen feeding.

We have examined the effects of protein deprivation on the induction of oral tolerance for systemic antibody and DTH responses to the protein antigen ovalbumin (OVA). Mice were fed 4% or 24% protein diets from weaning and given a single feed of OVA 2 weeks later (short-term deprivation) or after 10 weeks (long-term deprivation). Tolerance for serum antibody responses was more profound in protein-deprived animals than in 24% protein-fed control groups. Conversely, tolerance for DTH responses was impaired in protein-deprived mice. This was demonstrated both for short-term deprivation, where nutritional rehabilitation after OVA feeding was necessary to demonstrate this effect on DTH, and for long-term deprivation. Furthermore, the effect of short-term deprivation on tolerance for DTH responses was similar to that observed after cyclophosphamide pretreatment of OVA-fed mice. Protein deprivation has disparate effects on the humoral and cell-mediated limbs of oral tolerance, and our results support the hypothesis that this regime selectively depletes a population of suppressor T cells responsible for the fine control of DTH tolerance.     

Studies on the immunogenicity of an endogenously processed protein antigen in mice

We have examined the general immunogenicity of a non-replicating antigen which was introduced artificially into the endogenous pathway of antigen processing. EG7.OVA cells transfected with the OVA gene are efficient presenters of endogenously processed OVA and induced high levels of class I major histocompatibility complex (MHC)-restricted cytotoxic T lymphocytes (CTL) in vivo. In addition, mice immunised with EG7.OVA cells developed immune responses more characteristic of class II MHC-restricted T cells, including IgG antibody production, systemic delayed type hypersensitivity (DTH) and a proliferative response to OVA in vitro. However, most of these responses were small, and EG7.OVA cells did not prime mice for secondary antibody or DTH responses. Thus endogenously synthesised, non-replicating antigens are poor stimulators of T cells which exploit the exogenous processing pathway. If vaccine vectors containing purified epitopes are to stimulate all T cells effectively, they will need to utilise strategies which enable direct entry to both antigen processing pathways.     

口服S抗原对抗原诱导性葡萄膜视网膜炎影响的实验研究

目的:观察口服牛视网膜S抗原对Wistar大鼠抗原诱导性葡萄膜视网膜炎(ATU)的影响。方法:用纯化牛视网膜S抗原和福氏完全佐剂的混合乳剂致敏大鼠,14d后接种S抗原于致敏鼠眼玻璃体腔复制AIU模型。观察致敏前后口服S抗原或牛血清白蛋白(BSA)对AIU眼部表现,组织学改变、血清抗体效价、迟发型超敏反应(DTH)、淋巴细胞增殖反应的影响。结果:致敏前后口服BSA对AIU的炎性反应和免疫反应无影响。与口服BSA组比较,预口服S抗原组在AIU第1、3、5d的临床分级参数显著降低,炎症持续时间显著缩短,组织炎性细胞浸润显著减轻,血清特异性抗体滴度降低,DTH显著降低,受S抗原刺激的脾淋巴细胞增殖反应显著降低,加入IL-2共孵育后S抗原刺激的淋巴细胞增殖反应增高。致敏后口服S抗原组在AIU第5d的临床分级参数、炎症持续时间和DTH显著降低,血清特异性抗体滴度降低。结论:口服S抗原可以抑制AIU的炎性反应、细胞免疫反应和体液免疫反应。     

Bystander suppression of the immune response to human serum albumin in rats fed ovalbumin.

Bystander suppression of delayed-type hypersensitivity (DTH) and the antibody response to human serum albumin (HSA) were studied in young normal rats and in young rats made partially tolerant to ovalbumin (OVA) by feeding an OVA-containing diet for 4 weeks from weaning. At 2 months of age, the animals were intracutaneously immunized with a mixture of OVA and HSA in Freund's complete adjuvant (FCA) at one site of the back, or separately at two different sites on the back. All rats made orally tolerant to OVA showed a significantly reduced IgE and IgG anti-OVA antibody production and DTH response to OVA, compared to the controls. OVA-fed rats subsequently immunized with a mixture of OVA + HSA had significantly lower IgE and DTH responses to HSA than the controls. When rats were immunized with OVA and HSA at two different sites, however, there was no difference in the response to HSA between the OVA-fed rats and the control rats, which rules out the possibility of shared epitopes between the antigens. Ear-challenge with the mixture of OVA + HSA gave a significantly lower DTH reaction in the tolerant rats immunized with a mixture of the antigens, compared to the control rats. However, suppression of the DTH reaction was not seen when tolerant and control rats were immunized with HSA alone and challenged with the mixture of OVA + HSA in one ear. These results present evidence that young rats orally tolerant to one antigen show a suppressed T-cell and antibody response to an unrelated antigen, provided that the two antigens are given in a mixture during the inductive phase. There was no evidence for bystander suppression of the T-cell response at the effector site.     

Immunological responses to fed protein antigens in mice. I. Reversal of oral tolerance to ovalbumin by cyclophosphamide

Feeding ovalbumin over a wide range of doses is known to reduce subsequent systemic immune responses to parenteral immunization. In the present study, we have fed mice 2 mg and 25 mg ovalbumin (OVA) 2 weeks before systemic immunization and followed the resulting humoral antibody and cell-mediated immune (CMI) responses. The results indicate that while 25 mg OVA will reduce subsequent IgM, IgG and CMI responses to OVA, feeding 2 mg OVA will only suppress CMI responses and to a lesser extent the IgM response. Furthermore, the tolerant state induced by feeding 25 mg OVA was only partially prevented by 100 mg/kg cyclophosphamide (CY) while the suppressed CMI after feeding 2 mg OVA was completely blocked by CY pretreatment. These findings suggest that the humoral and cell-mediated limbs of the immune response may be controlled by different regulatory systems after feeding antigen, and that activation of these systems is dependent on the dose of oral antigen use. In addition, the results are in agreement with our previous finding that CY pretreatment will allow the development of CMI in the gut and gut-associated lymphoid tissue (GALT) after oral OVA and suggest that this phenomenon is related to breakdown of oral tolerance induction.     

Factors influencing the enhancement of delayed-type hypersensitivity to ovalbumin by cyclosporin A in the guinea pig: possible role of suppressor cells

Enhancement of delayed-type hypersensitivity (DTH) reactions to ovalbumin (OVA) was demonstrated in guinea pigs given a single, high dose of cyclosporin A (CsA) intraperitoneally, 2 days before immunization. Courses of oral CsA, commencing at the time of immunization and lasting until day 4 or 13 also resulted in augmented DTH responses at days 14 and 28, respectively. However, the enhancing protocol (CsA; day 0-4) did not significantly affect circulating anti-OVA antibody titres. The capacity to express increased DTH could be adoptively transferred to naive recipients by systemic injection pooled spleen and peritoneal exudate cells. Moreover, the expression of augmented responses was inhibited by transfer of cells from normally immunized donors. Although augmentation of DTH was accompanied by increased lymphocyte proliferative responses to OVA in vitro, there was no similar effect on T cell responses to polyclonal mitogens. The data support the view that augmentation of DTH by CsA is attributable to suppressor cell dysfunction, but that this is unlikely to be a non-specific suppressor cell impairment.     

Depletion of complement has distinct effects on the primary and secondary antibody responses to a conjugate of pneumococcal serotype 14 capsular polysaccharide and a T-cell-dependent protein carrier

Complement activation plays a critical role in the immune response to T-cell-dependent and T-cell-independent antigens. However, the effect of conjugation of T-cell-dependent protein carriers to T-cell-independent type 2 antigens on the requirement for complement in the humoral immune response to such antigens remains unknown. We studied the role of complement activation on the antibody response of BALB/c mice immunized with the T-cell-independent type 2 antigen serotype 14 pneumococcal capsular polysaccharide (PPS14), either in unmodified form or conjugated to ovalbumin (OVA). In mice immunized with either PPS14 or PPS14-OVA, depletion of endogenous complement at the time of primary immunization by treatment with cobra venom factor (CVF) diminished serum anti-PPS14 concentrations after primary immunization but enhanced antibody responses after secondary immunization. The secondary immunoglobulin G (IgG) anti-PPS14 antibody response after immunization with PPS14-OVA was especially enhanced by complement depletion, was observed at doses as low as 0.2 mug of antigen, and was maximal when CVF was administered within 2 days of immunization. The avidity and opsonophagocytic functions of IgG anti-PPS14 antibodies were comparable in mice immunized with PPS14-OVA with or without complement depletion. Serum anti-PPS14 antibody concentrations were near normal, and the enhancing effects of CVF treatment on the secondary anti-PPS14 antibody response were also apparent in splenectomized mice immunized with PPS14-OVA. These results demonstrate that complement activation can have distinct effects on the primary and secondary antibody responses to a T-cell-independent type 2 antigen, either unmodified or conjugated to a T-cell-dependent protein carrier. These differences should be taken into consideration when using complement to modulate the immune response to vaccines.     

Adjuvant activity of monophosphoryl lipid A for nasal and oral immunization with soluble or liposome-associated antigen

The effectiveness of monophosphoryl lipid A (MPL) as a mucosal adjuvant was investigated following oral or intranasal (i.n.) administration of an aqueous adjuvant formulation of MPL (MPL-AF) added to soluble antigen or liposomal antigen or incorporated into liposomal antigen membranes. Groups of BALB/c female mice were immunized with 50 to 100 microg of free or liposomal Streptococcus mutans crude glucosyltransferase (C-GTF) with or without MPL-AF added to the vaccine or incorporated into the liposomal membrane. Plasma, saliva, vaginal wash, and fecal extract samples were collected biweekly following immunization and assessed for antigen-specific antibody activity by enzyme-linked immunosorbent assay (ELISA). Mice immunized by the i.n. route had higher levels of salivary, plasma, and vaginal immunoglobulin A (IgA) anti-C-GTF responses and higher levels of plasma IgG anti-C-GTF than the orally immunized groups. A second administration of the vaccine 14 weeks after the initial immunization resulted in an anamnestic response to C-GTF resulting in 10- and 100-fold increases in saliva and plasma IgA and plasma IgG, respectively (in the i.n. immunized groups). Mice receiving a second i.n. immunization with liposomal antigen and MPL-AF had higher salivary IgA anti-C-GTF responses than mice immunized with antigen plus MPL-AF or liposomal antigen (P < 0.05). Plasma IgG anti-C-GTF activity was highest in mice immunized by the i.n. route with antigen formulations containing MPL-AF (P < 0.05). These results demonstrate the effectiveness of MPL-AF as an adjuvant for potentiating mucosal and systemic immune responses to liposomal C-GTF following i.n. immunization.     

Oral Tolerization Leads to Active Suppression and Bystander Tolerance in Adult Rats while Anergy Dominates in Young Rats

Oral tolerance was induced in 4-week-old (young) and 12-week-old (adult) rats by feeding ovalbumin (OvA)-containing pellets during 4 weeks. Seven weeks after removal of the OvA-pellets the rats were immunized with a mixture of OvA and human serumalbumin (HSA) in Freund's complete adjuvant (FCA), and the following immune response was monitored. Both the young and adult groups of OvA-fed rats had significantly suppressed OvA-specific delayed-type hypersensitivity (DTH) responses and T-cellproliferation, reflecting a long-lasting T-cell tolerance to OvA both in vivo and in vitro. Furthermore, spleen cells from rats tolerized as adults were able to suppress the proliferation of primed T-cells from normal immunized rats, demonstrating thepresence of antigen-specific suppressive cells. Accordingly, the adult rats showed bystander suppression of the response to HSA with respect to DTH-reaction, specific proliferation, and reduced enlargement of the draining lymph nodes after immunization.There was no evidence of active suppression in vitro or bystander tolerance in the orally tolerized young group, indicating that anergy rather than active suppression was prevalent in these rats. Furthermore, in the young group there was no suppression of the antibody response since the IgG and IgE anti-OvA antibody levels were indistinguishable from those of the controls. Contrary to the young rats, the adult fed group showed transiently elevated levels of IgG anti-OvA antibodies at 1 weekpost-immunization, followed by a subsequent significantly suppressed IgG antibody response. In conclusion, the results demonstrate that the induction of anergy or active suppression after antigen feeding can be determined by the age at which the antigenis introduced to the mucosal immune system.     

Sequential development of helper and suppressor functions, antibody titers and functional avidities to a streptococcal antigen in rhesus monkeys

Sequential development of antibody titer, functional avidity, helper and suppressor activities were investigated in rhesus monkeys. These were immunized with a single dose of 0.1 microgram to 10 mg of a streptococcal protein antigen (SA) in aluminium hydroxide. The IgG antibody titers followed the classical pattern first established in mice, of high-dose and low-dose tolerance with intermediate doses of immunity. This was correlated with a similar pattern of functional avidity of IgG antibodies, as measured by a dissociation assay. Helper and suppressor functions were assayed in parallel by inducing the corresponding factors from monkey lymphocytes in Marbrook flasks and testing the factors which cross the species barrier in cooperative cultures with CBA mouse spleen B cells. A progressive modulation of helper and suppressor activities was elicited by the increasing doses of SA, during the initial 28 days after immunization. Thus, dominant suppressor with minimal helper activity, IgG antibody titer and functional avidity were elicited by 0.1 microgram SA. However, 1 or 10 micrograms SA induced dominant helper with minimal or transient suppressor activity and high IgG antibody titers and functional avidity. Somewhat intermediate responses were elicited by 100 micrograms SA, but 1 mg and especially 10 mg SA induced dominant suppressor and minimal helper activity, with low IgG antibody titers and functional avidities. When the immune response was established, about 28 days after immunization, the intermediate dose of SA elicited IgG antibodies with high titer and functional avidity, high T cell helper but low suppressor activities. In contrast, both high- and low-dose SA induced partial tolerance, with low IgG antibody titer, functional avidity and T cell helper activity. These studies suggest cyclical development of helper and suppressor functions during the 4 weeks after immunization. The emergence of a dominant helper or suppressor function is antigen dose dependent.     

Long-term anergy in orally tolerized mice is linked to decreased B7.2 expression on B cells

Durable antigen (Ag)-specific T- and B-cell anergy induced by oral tolerance is an attractive strategy for immunotherapy of allergic diseases. Here, we address the lasting effect of oral tolerance induction in na?ve or primed mice to ovalbumin (OVA) on antibody production. Single feeding with OVA prior to immunization or double feeding, before and after Ag priming, in A/Sn mice, induced a long-lasting suppression of IgE, IgG1 and IgG2a responses up to 8 months after immunization. In contrast, primed-fed mice had transient IgE inhibition. Naive and double-treated mice showed marked Ag-specific unresponsiveness and scarce cytokines production. Inhibition of IL-2 and IFN-gamma secretion in na?ve-fed mice were restored in the presence of anti-CD28 mAb plus Ag stimulation. The durable inhibition of Ab production in OVA-fed mice was related to the persistent decrease of B7.2 expression on B cells. Ag feeding in naive and primed status may be a prophylactic measure to avoid later Ag sensitization.     

Selective suppression of antigen-specific Th2 cells by continuous micro-dose oral tolerance

The effect on antigen (Ag)-specific Th2 response as well as IgE production of continuous oral administration of micro-doses of Ag was investigated. Transgenic (Tg) mice carrying the α β-T cell receptor (TCR) genes specific for ovalbumin (OVA) peptide fragment 323 – 339 were continuously fed with micro-doses of OVA (100 μg/day) for 14 days. Mice were first immunized by OVA in alum and pertussis toxin 7 days before the oral feeding and given a second immunization 1 day after the oral treatment. This feeding regimen tolerized Th2 but not Th1 responses as shown by decrease of Ag-driven cell proliferation and cytokine secretion of IL- 4 but not of IL-2 or IFN-γ as well as by the absence of Ag-specific antibody production of IgE and IgG1, but not of IgG2a or total IgG. Numbers of clonotype-specific TCR-high CD4-positive T cells in peripheral lymphoid tissues markedly decreased in the orally treated group but not in the control group. However, total numbers of CD4-positive T cells in thymus, spleen and lymph nodes were not affected by the oral treatment, indicating that tolerance induction in Th2 cells was mainly due to the down-regulation of TCR and not clonal deletion. The population of antigen-presenting cells expressing B7-2 (CD86) Ag on the surface was decreased in the spleen of the mice which underwent the feeding regimen. The present results suggest that Ag-specific low responsiveness in Th2 cells, which resulted in suppres sion of the Ag-specific IgE production, can be achieved by continuous feeding with microdoses of Ag.