Cyclooxygenase-2 in mucosal DC mediates induction of regulatory T cells in the intestine through suppression of IL-4

Oral intake of protein leads to tolerance through the induction of regulatory T cells (Tr cells) in mesenteric lymph nodes (MLNs). Here we show that the inhibition of cyclooxygenase-2 (COX-2) in vivo suppressed oral tolerance and was associated with enhanced differentiation of interleukin (IL)-4-producing T cells and reduced Foxp3⁺ Tr-cell differentiation in MLN. As a result, the functional suppressive capacity of these differentiated mucosal T cells was lost. IL-4 was causally related to loss of tolerance as treatment of mice with anti-IL-4 antibodies during COX-2 inhibition restored tolerance. Dendritic cells (DCs) in the MLN differentially expressed COX-2 and reductionist experiments revealed that selective inhibition of the enzyme in these cells inhibited Foxp3⁺ Tr-cell differentiation in vitro. Importantly, the inhibition of COX-2 in MLN-DC caused increased GATA-3 expression and enhanced IL-4 release by T cells, which was directly related to impaired Tr-cell differentiation. These data provide crucial insights into the mechanisms driving de novo Tr-cell induction and tolerance in the intestine.     

Human bone marrow stromal cells hamper specific interactions of CD4 and CD8 T lymphocytes with antigen-presenting cells

Bone marrow stromal cells (BMSCs) may inhibit T-cell functions in vitro and thus have been proposed as immunoregulators to control in vivo graft-versus-host disease (GVHD) in haploidentical hemopoietic stem cell transplants. To better investigate this phenomenon, we used a defined experimental system in which responding T cells are antigen-specific and devoid of alloreactivity against BMSC from a different subject. Thus, we established antigen-specific human CD4 and CD8 T-cell lines as the readout system. Antigen-dependent proliferation was reduced with both T-cell subsets cultured on confluent BMSCs, and also on confluent human skin fibroblasts (HSF) inhibited T-cell proliferation with similar efficiency. Morphological observations of the cocultures showed impairment of physical interactions between T-cell and antigen-presenting cells in the presence of BMSC, with lack of formation of antigen-dependent clusters of T cells and antigen-presenting cells (APCs). In contrast, no effects were seen with BMSC-conditioned medium. Since suppression was seen only with confluent mesenchymal cells, this phenomenon may not be relevant in vivo, where BMSCs are at low frequency. In addition, if the reported suppressive effect of BMSCs on GVHD in vivo is confirmed, a different in vitro system should be envisaged to better understand and exploit the underlying mechanism.     

Suppressive dendritic cells as a tool for controlling allograft rejection in organ transplantation: promises and difficulties

The most important antigen-presenting cells are dendritic cells (DCs), which play a central role in the initiation of immunity and tolerance. Their immunoregulatory properties offer the potential of donor-specific control of graft rejection after organ transplantation. It has not been clarified which DC subpopulations mediate tolerance, and the use of natural DCs for therapeutic applications is therefore problematic. Suppressive DCs can be generated in vitro by treating the cells with biologic, pharmacologic, or genetic agents. Here we discuss approaches for generating inhibitory DCs and present DC-based animal models for control of allograft rejection. A prerequisite of suppressive DCs for therapeutic application in clinical transplantation is a reproducible method for their generation as well as the induction of irreversible suppressive function. Based on lessons learned from the use of DCs as tools in clinical vaccine trials in cancer, we discuss the unknown aspects and risks of DC therapy in transplantation.     

Bone marrow-derived mesenchymal stem cells decrease acute graft-versus-host disease after allogeneic hematopoietic stem cells transplantation

Graft-versus-host disease is a major complication of allogeneic hematopoietic stem cells transplantation, leading to serious morbidity and mortality. Mesenchymal stem cells(MSC)from bone marrow cause immunoregulation in vitro and in vivo. They also have the potential to protect from lethal GVHD after both autologous and allogeneic Hematopoietic Stem Cells Transplantation (HSCT). In this study, we investigated the mechanisms responsible for GVHD in the allo-HSCT co-transplantation with MSC condition. The model of acute GVHD in Rats was established using allogeneic HSC with donor-derived T cells transplantation, with or without additional donor-derived MSC co-transplantation. The degrees of GVHD were compared, the differentiation of CD4⁺, CD8⁺, Th1/Th2 and CD4⁺CD25⁺ T cells in vivo were assessed by flow cytometry and RT-PCR analyses. We found that MSC inhibited lethal GVHD after allo-HSCT. The value of CD8⁺ and CD4⁺ T cells and the ratio of Th1/Th2 T cell subsets decreased, at the same time the proportion of CD4⁺CD25⁺ T cells increased both in spleen lymphocytes and thymocytes in vivo after allo-HSCT with MSC co-transplantation compared with conventional allo-HSCT. Our results strongly suggested that BM-derived MSC has the function of preventing lethal GVHD after allo-HSCT by means of homeostasis of T subsets in vivo.     

AIRE is not essential for the induction of human tolerogenic dendritic cells

Loss-of-function mutations of the Autoimmune Regulator (AIRE) gene results in organ-specific autoimmunity and disease Autoimmune Polyendocrinopathy type 1 (APS1)/Autoimmune Polyendocrinopathy Candidiasis Ectodermal Dystrophy (APECED). The AIRE protein is crucial in the induction of central tolerance, promoting ectopic expression of tissue-specific antigens in medullary thymic epithelial cells and enabling removal of self-reactive T-cells. AIRE expression has recently been detected in myeloid dendritic cells (DC), suggesting AIRE may have a significant role in peripheral tolerance. DC stimulation of T-cells is critical in determining the initiation or lack of an immune response, depending on the pattern of costimulation and cytokine production by DCs, defining immunogenic/inflammatory (inflDC) and tolerogenic (tolDC) DC. In AIRE-deficient patients and healthy controls, we validated the role of AIRE in the generation and function of monocyte-derived inflDC and tolDCs by determining mRNA and protein expression of AIRE and comparing activation markers (HLA-DR/DP/DQ,CD83,CD86,CD274(PDL-1),TLR-2), cytokine production (IL-12p70,IL-10,IL-6,TNF-α,IFN-γ) and T-cell stimulatory capacity (mixed lymphocyte reaction) of AIRE+ and AIRE- DCs. We show for the first time that: (1) tolDCs from healthy individuals express AIRE; (2) AIRE expression is not significantly higher in tolDC compared to inflDC; (3) tolDC can be generated from APECED patient monocytes and (4) tolDCs lacking AIRE retain the same phenotype and reduced T-cell stimulatory function. Our findings suggest that AIRE does not have a role in the induction and function of monocyte-derived tolerogenic DC in humans, but these findings do not exclude a role for AIRE in peripheral tolerance mediated by other cell types.     

Elimination of activated but not resting primary human CD4+ and CD8+ T cells by Fas ligand (FasL/CD95L)-expressing Killer-dendritic cells

Dendritic cells (DC) genetically engineered to express high levels of Fas ligand (FasL/CD95L) have been demonstrated to delete T cells in an antigen specific manner in several different animal models in vivo. However, the immunomodulatory capacity of primary human FasL-expressing Killer-DC has not been determined. Therefore, human Killer-DC were generated from mature monocyte-derived DC using the inducible CRE/LoxP adenoviral vector system, and the immunoregulatory capacity of these cells was analyzed in cocultures with primary human T cells in vitro. Combined transductions of DC by AdloxPFasL and AxCANCre resulted in FasL expression in >70% of DC without affecting the mature phenotype. Proliferation of activated primary human T cells was inhibited up to 80% in cocultures with FasL-expressing DC but not EGFP-transduced DC, which was due to induction of apoptosis in activated but not resting CD4⁺ and CD8⁺ T cells. Apoptosis induced by Killer-DC could be blocked by an anti-FasL-antibody in a dose dependent fashion. The present results demonstrate that FasL-expressing Killer-DC eliminate activated but not resting primary human CD4⁺ and CD8⁺ T cells by induction of Fas-mediated apoptosis supporting the concept to apply Killer-DC as a novel strategy for the treatment of T cell-dependent autoimmune disease and allograft rejection in humans.     

Dendritic cell-based vaccination strategies: induction of protective immunity against leishmaniasis

The clinical symptoms caused by infections with Leishmania parasites range from self-healing cutaneous to uncontrolled visceral disease and depend not only on the parasite species but also on the type of the host's immune response. Infection of genetically susceptible mice with Leishmania major results in the development of disease-promoting T helper cells of type2 (Th2). On the other hand, healing of lesions is dependent on the induction of Th1 cells producing interferon-g (IFN-g). The presence of interleukin 12 (IL-12) is known to be crucial for the differentiation of Th1 cells. Whereas IL-12 release and the T cell stimulatory functions of macrophages are down-regulated by L.major infection, dendritic cells (DC) exposed to L.major readily produce IL-12 and are highly potent antigen-presenting cells. Moreover, DC pulsed ex vivo with L.major antigen induce protection in otherwise susceptible mice against subsequent challenges with the parasites. The protection is long-lasting and correlates with a shift of the cytokine expression pattern towards a Th1 response. Thus, DC serve as immunomodulators in vivo and can be used as an effective adjuvant for vaccination against experimental leishmaniasis. Studies on the ability of DC to induce protective immunity to leishmaniasis may have important implications for the development of novel strategies for prophylactic and therapeutic immunizations against microbial pathogens.     

Roles of lymphoid cells in the differentiation of Langerhans dendritic cells in mice

Langerhans dendritic cells are antigen presenting cells (APC) that reside within the epidermis and are capable of stimulating naive T cells. Reciprocally, lymphocytes may play a role in Langerhans cells (LC) differentiation. Our results show that the differentiation of skin LC is unaffected in the absence of lymphocytes and/or signaling through the common cytokine receptor gamma chain (gammac) required for IL-2, IL-4, IL-7, IL-9, IL-15 and IL-21 signaling. Migration of LC and other dendritic cells (DC) from the skin to the draining lymph nodes (LNs) after FITC skin sensitization, is unaffected in the absence of lymphocytes or CD40. FITC+ LC/DC sorted from the LNs of lymphoid deficient or control mice stimulated naive T cells with similar efficiency. However, while the absence of lymphocytes did not appear to affect the phenotype or number of emigrating LN DC/LC, their persistence in the LN appears to depend on alphabeta T cells. Thus, DC are strikingly reduced in numbers in the peripheral LNs of T-cell deficient mice. Finally, CD8alpha expression on skin emigrants was low and dependent on the presence of CD8+ lymphocytes, while spleen CD8+ DC were present in the absence of lymphocytes. We conclude that the presence of T cells is not required for the differentiation and migration of resident skin DC but is critical for the maintenance of DC and LC migrating into the LNs.     

Lactobacillus acidophilus strain L-92 induces apoptosis of antigen-stimulated T cells by modulating dendritic cell function

Beneficial effects of lactobacilli have been reported for patients with allergic diseases and intestinal disorders such as inflammatory bowel disease. However, it is not fully understood how such bacteria influence the immunologic response. For this purpose, we investigated the effect of Lactobacillus acidophilus strain L-92 (L-92) on antigen-stimulated T cell responses in vitro and in vivo. In vitro, L-92 decreased the proliferation of CD4⁺ T cells stimulated with antigen, and also induced apoptosis of antigen-stimulated T cells. On the other hand, interferon (IFN)-γ secretion from naïve T cells was increased while interleukin (IL)-4 secretion was decreased by L-92. Co-culture with L-92 induced apoptosis of differentiated Th1 and Th2 cells. The degree of apoptosis induction was higher in Th2 cells. Moreover, L-92 up-regulated the expression of B7-H1 and down-regulated that of B7-H2 on dendritic cells (DCs), and DCs exposed to L-92 also induced apoptosis of antigen-stimulated T cells. Finally, orally administered L-92 induced apoptosis of OVA-specific TCR Tg T cells. These results indicate that L-92 attenuates the CD4⁺ T cell response by inducing DC-mediated apoptosis and that it might exert beneficial effects in patients with diseases resulting from a hyper-response of CD4⁺ T cells.     

UVB-irradiated dendritic cells are impaired in their APC function and tolerize primed Th1 cells but not naive CD4+ T cells

We have shown that low-dose UVB radiation converts Langerhans cells (LC) from immunogenic to tolerogenic APC. Therefore, we questioned whether low-dose UVB irradiation of bone marrow-derived dendritic cells (DC) alters their APC function, thereby inducing tolerance in T cells. To address this issue, cocultures of DC; and naive, allogeneic T cells; na?ve, OVA-specific TCR-transgenic T cells from DO11.10 mice; or primed, antigen-specific T cells using the Th1 clone AE7 were analyzed. First, we found low-dose UVB-irradiated DC (UVB-DC) to dose-dependently (50-200 J/m2) inhibit T-cell proliferation of naive and primed T cells. In addition, supernatants harvested from cocultures of UVB-DC and naive T cells showed markedly reduced levels of IL-2 and IFN-gamma and to a lesser degree of IL-4 and IL-10, suggesting a preferential down-regulation of Th1 responses by UVB-DC. FACS analysis of UVB-DC revealed no changes in surface expression of MHC, costimulatory, and adhesion molecules. To test tolerance induction, allo- or antigen-specific T cells isolated from cocultures with unirradiated DC and UVB-DC were restimulated with unirradiated DC or IL-2. It is interesting that UVB-DC induced antigen-specific tolerance in the Th1 clone AE7. In contrast, UVB-DC induced a partial inhibition of allogeneic T-cell proliferation but no tolerance with similar unresponsiveness to restimulation with IL-2 and unirradiated DC irrespective of their haplotype. Similar observations were made when naive, TCR-transgenic T cells from DO11.10 mice were used. In conclusion, UVB-DC are impaired in their APC function and tolerize the primed antigen-specific Th1 clone AE7 but not naive allo- or OVA-specific T cells.     

The role of antigen presenting cells at distinct anatomic sites: they accelerate and they slow down allergies

It has been repeatedly demonstrated that allergic reactions are driven by the continuous flow of antigen uptake and presentation processes, which are perpetuated mainly by dendritic cells (DC). The ability of allergens to cause allergic inflammation is contingent upon the presence of an immunological milieu and microenvironment that either privileges Th2 responses or prohibits these reactions by the induction of contraregulatory anti-inflammatory activities of the immune system. In the light of recent developments it appears that DC have to manage two opposing tasks: on the one hand they can favor pro-inflammatory reactions and actively induce a T-cell response, yet on the other hand they serve an important function as 'silencers' in the immune system by sending out anti-inflammatory, tolerance inducing signals. This unique capacity of DC has opened several exciting possibilities for a role of DC in both - accelerating and slowing down allergic reactions. It is therefore a challenge to understand in which way DC subtypes located at distinct anatomic sites with frequent allergen exposure, such as the skin, the nasal mucosa, the respiratory tree or the mucosa of the intestinal tract can have an impact on mechanisms involved in tolerance induction or effective immunity.     

Induction of anergic and regulatory T cells by plasmacytoid dendritic cells and other dendritic cell subsets

The induction of antigen-specific tolerance is critical for maintaining immune homeostasis and preventing autoimmunity. Because the central tolerance that eliminates potentially harmful autoreactive T cells is incomplete, peripheral mechanisms for suppressing self-reactive T cells play an important role. Dendritic cells (DCs) are professional antigen-presenting cells, which have an extraordinary capacity to stimulate naïve T cells and initiate primary immune responses. Recent accumulating evidence indicates that several subsets of human DCs also play a critical role in the induction of peripheral tolerance by anergizing effector CD4⁺ and CD8⁺ T cells or by inducing the differentiation of naïve T cells into T-regulatory cells, which produce interleukin (IL)-10. Human DC subsets with the property of suppressing an antigen-specific T-cell response include plasmacytoid DCs, which are either in an immature state or in a mature state induced by CD40 ligand stimulation, and monocyte-derived DCs, which are either in an immature state or have had their state modulated by treatment with IL-10 or CD8⁺CD28⁻ T cells. These “tolerogenic” DCs may be relevant to therapeutic applications for autoimmune and allergic diseases as well as organ transplant rejection.     

Infection with prevalent clinical strains of Mycobacterium tuberculosis leads to differential maturation of monocyte derived dendritic cells

The link between innate and adaptive host immune response to Mycobacterium tuberculosis (M.tb) is driven by dendritic cells (DC). In this study, we examined the ability of prevalent clinical strains from south India (S7, S10) and laboratory strain H37Rv (Rv) to induce maturation of monocyte derived dendritic cells (MoDC). The phenotypic and functional changes of DC upon infection with different strains of M.tb were evaluated. It was observed that S7 and Rv strains partially hampered the maturation of MoDC as reflected by the low expression of maturation markers and co-stimulatory markers when compared to LPS stimulated MoDC. In contrast, strain S10 infected DC showed a marked increase in the expression of these markers. The functional property was investigated by the ability of infected MoDC to induce T-cell proliferation and to stimulate secretion of IFN-γ by CD4⁺T-cells. It was found that Rv and S7 infected MoDC were less efficient in inducing T-cell proliferation. The secretion of IL-12 by Rv and S7 infected MoDC was also found to be significantly lesser than LPS stimulated MoDC. On the other hand, S10 infected MoDC showed enhanced T-cell stimulation and cytokine secretion. Together these results indicate that there is a substantial variability in the capacity of M.tb clinical strains to induce maturation of DC which may be dependent upon their virulence.     

MCS-18, a novel natural product isolated from Helleborus purpurascens, inhibits dendritic cell activation and prevents autoimmunity as shown in vivo using the EAE model

Here we report for the first time that MCS-18, a novel natural product isolated from Helleborus purpurascens, is able to inhibit the expression of typical molecules of mature dendritic cells (DC) such as CD80, CD86, and especially of CD83 subsequently leading to a clear and dose-dependent inhibition of the DC-mediated T-cell stimulation. Furthermore, MCS-18 impeded the formation of the typical DC/T-cell clusters, which are essential to induce potent immune responses. Interestingly, MCS-18 also inhibited CCR7 expression on DC which subsequently lead to a dose-dependent block of the CCL19-mediated DC migration. MCS-18 not only inhibited the DC-mediated T-cell stimulation but also the anti-CD3/anti-CD28-mediated T-cell stimulation. Strikingly, MCS-18 also strongly reduced the paralysis associated with the experimental autoimmune encephalomyelitis (EAE), which is a murine model for human multiple sclerosis, in a prophylactic as well as in a “real” therapeutic setting. Even when the EAE was induced for a second time, the MCS-18-treated animals were still protected, suggesting that MCS-18 induces a long-lasting suppressive effect. In addition, and very important for the potential practical application in humans, MCS-18 was also active when administered orally. MCS-18 treatment almost completely reduced leukocyte infiltration in the brain and in the spinal cord. In conclusion, using in vitro as well in vivo assays we were able to show that MCS-18 exerts a strong immunosuppressive activity with remarkable potential for the therapy of diseases characterized by a pathologically over-activated immune system.     

Inflammatory signals in dendritic cell activation and the induction of adaptive immunity

Summary:  Pathogen invasion induces a rapid inflammatory response initiated through the recognition of pathogen-derived molecules by pattern recognition receptors (PRRs) expressed on both immune and non-immune cells. The initial wave of pro-inflammatory cytokines and chemokines limits pathogen spread and recruits and activates immune cells to eradicate the invaders. Dendritic cells (DCs) are responsible for initiating a subsequent phase of immunity, dominated by the action of pathogen-specific T and B cells. As for the early pro-inflammatory response, DC activation is triggered by PRR signals. These signals convert resting DCs into potent antigen-presenting cells capable of promoting the expansion and effector differentiation of naive pathogen-specific T cells. However, it has been argued that signals from PRRs are not a prerequisite for DC activation and that pro-inflammatory cytokines have the same effect. Although this may appear like an efficient way to expand the number of DCs that initiate adaptive immunity, evidence is accumulating that DCs activated indirectly by inflammatory cytokines are unable to induce functional T-cell responses. Here, we review the differences between PRR-triggered and cytokine-induced DC activation and speculate on a potential role for DCs activated by inflammatory signals in tolerance induction rather than immunity.     

Ssu72 is a T-cell receptor-responsive modifier that is indispensable for regulatory T cells

The homeostatic balance between effector T cells and regulatory T cells (Tregs) is crucial for adaptive immunity; however, epigenetic programs that inhibit phosphorylation to regulate Treg development, peripheral expression, and suppressive activity are elusive. Here, we found that the Ssu72 phosphatase is activated by various T-cell receptor signaling pathways, including the T-cell receptor and IL-2R pathways, and localizes at the cell membrane. Deletion of Ssu72 in T cells disrupts CD4⁺ T-cell differentiation into Tregs in the periphery via the production of high levels of the effector cytokines IL-2 and IFNγ, which induce CD4⁺ T-cell activation and differentiation into effector cell lineages. We also found a close correlation between downregulation of Ssu72 and severe defects in mucosal tolerance in patients. Interestingly, Ssu72 forms a complex with PLCγ1, which is an essential effector molecule for T-cell receptor signaling as well as Treg development and function. Ssu72 deficiency impairs PLCγ1 downstream signaling and results in failure of Foxp3 induction. Thus, our studies show that the Ssu72-mediated cytokine response coordinates the differentiation and function of Treg cells in the periphery.     

Functional maturation of lamina propria dendritic cells by activation of NKT cells mediates the abrogation of oral tolerance

We previously showed that although systemic administration of α‐galactosylceramide (αGalCer) or agonistic anti‐CD40 induced functional maturation of dendritic cells (DC) in mesenteric lymph nodes, only the former treatment succeeded in breaking the induction of oral tolerance. In this study, we looked for the essential factor responsible for the disruption of oral tolerance. We found that lamina propria (LP)‐DC was responsible for the oral OVA presentation and that Peyer's patch was not essential for the induction of oral tolerance. Therefore, we investigated the role of LP‐DC. Treatment with αGalCer but not with anti‐CD40 induced the full maturation of LP‐DC at an early time point. This functional activation of LP‐DC was mediated by strong activation of NKT cells that reside abundantly in the small intestinal lamina propria (SI‐LP) and interferon‐γ partially contributed to the LP‐DC activation. LP‐DC isolated from αGalCer‐treated OVA‐fed mice induced the differentiation of naïve CD4⁺ T cells into Th1 and Th2 and was associated with the reduced Foxp3⁺ population. In contrast, LP‐DC isolated from anti‐CD40‐treated OVA‐fed mice failed to generate Th cell differentiation but induced more Foxp3⁺ CD4⁺ T cells. Our results demonstrate that triggered by NKT cells in SI‐LP, functional maturation of Ag‐capturing DC from SI‐LP is necessary for the abrogation of oral tolerance induction.     

The role of dendritic cells in food allergy

In recent years, our understanding of the initiation of T(H)2-type immunity has increased significantly, yet the mechanism behind the induction of T(H)2 responses and allergic sensitization to food antigens largely remains an enigma. Dendritic cells (DCs) were first described almost 4 decades ago and have since been recognized as the most important antigen-presenting cells and crucial in the induction of T-cell differentiation. Here we discuss our current knowledge of the role of DCs in food allergy. In both murine models and allergic patients, characteristics of DCs have been identified that might play a role in sensitization to food and enhance susceptibility to food allergy. In addition, it has now been shown that several allergens, including some from foods, can directly activate DCs to induce T(H)2 skewing. Other cell types with innate immune functions, such as epithelial cells and basophils, might also be involved in sensing of food allergens in human subjects, and interaction of DCs with these cells might facilitate sensitization. DCs appear to play an important role in allergen-specific immunotherapy and could be an attractive target for tolerance induction in patients with food allergy. Further characterization of differences in DC responses between human food-allergic and nonallergic subjects is necessary to gain a better insight into the role of DCs in sensitization and tolerance to food allergens.     

Role of CD4+ regulatory T cells in hyperbaric oxygen-mediated immune nonresponsiveness

We have previously shown that hyperbaric oxygen culture (HOC [95% O₂, 5% CO₂, 25 psi]) is an effective pretransplant tissue-modification technique that results in long-term allograft survival and the induction of systemic immune tolerance in a murine model. Here we address the immune modulatory effects of HOC-treatment of human immune responses using the in vitro mixed lymphocyte reaction (MLR). Pretreatment of allogeneic stimulator cells with HOC results in abrogation of cytotoxic T lymphocyte (CTL) activity, proliferative responses, and IFNγ production in a 7-day MLR. These responses can be restored either by the addition of IFNγ or IL-2 on day 0, or by blocking the activity of IL-4 and IL-10. The addition of IL-2 on day 4 does not restore allospecific CTL activity. The failure of HOC-treated cells to induce allospecific CTL is not due to the induction of anergy, demonstrated by the failure to restore responses after restimulation with allogeneic cells in the presence of IL-2. Removal of CD4⁺ cells prior to restimulation, results in restoration of CTL activity in MLR cultures restimulated with HOC-treated allogeneic cells. These results suggest that HOC-induced immune nonresponsiveness is mediated by the development of CD4⁺ regulatory cells in a Th2-type environment.     

In Vitro Tolerance Induction to a Thymus-Dependent Antigen with BALB/c and C57BL/6 Lymph Node Cells: Effect of Tolerogen Concentration and Duration of Exposure

Further studies on tolerance induction in vitro to bovine gamma globulin (BGG) in nonadherent BALB/c lymph node cells showed that it was dependent upon both the dose of tolerogen and the time of exposure. Nearly complete tolerance was achieved at a dose of 1.0 mg/ ml and an incubation time of 12-18 hours. When C₅₇BL/6 strain was used for comparison with the BALB/c strain because of its relative ease to become tolerant after in vivo injection of tolerogen, the rate of tolerance induction of its nonadherent lymph node cells was not different from that of BALB/c cells. Thus, in the absence of other host factors, the acquisition of tolerance by lymphocytes is gradual and may reflect the time required for a cell to reach a susceptible phase of the cell cycle and/or the activation of suppressor cells.