The transmembrane glycoprotein CD83 has been described as a specific maturation marker for dendritic cells and several lines of evidence suggest that CD83 regulates thymic T cell maturation as well as peripheral T cell activation. Here we show for the first time that CD83 is involved also in the regulation of B cell function. CD83 is up-regulated on activated B cells in vivo, specifically in the draining lymph nodes of Leishmania majorinfected mice. The ubiquitous transgenic (Tg) expression of CD83 interferes with Leishmania-specific T cell-dependent and with T cell-independent antibody production. This defect is restricted to the B cell population since the antigen-specific T cell response of CD83Tg mice to L. major infection is unchanged. The defective immunoglobulin (Ig) response is due to Tg expression of CD83 on the B cells because wild-type B cells display normal antigen-specific responses in CD83Tg hosts and CD83Tg B cells do not respond to immunization in a mixed wild-type/CD83Tg bone marrow chimera. Finally, the treatment of non-Tg C57BL/6 mice with anti-CD83 mAb induces a dramatic increase in the antigen-specific IgG response to immunization, thus demonstrating a regulatory role for naturally induced CD83 on wild-type B cells.
SummaryTrypanosoma cruzi causes a suppression of the immune system leading to persistence in host cells. The trans-sialidase expressed by T. cruzi is a major virulence factor and transfers sialic acid from host glycoconjugates to mucin-like molecules on the parasite. Here we demonstrate that these sialylated structures play a role in the immunosuppression. We used two T. cruzi strains, whose TS activity correlated with their pathogenicity. The Tulahuen strain, characterized by a high TS activity efficiently infected mice, whereas the Tehuantepec strain showing a reduced TS activity could not establish a patent parasitemia. In vitro analysis revealed that these two strains invaded phagocytic and non-phagocytic host cells at a comparable rate, but they exhibited different potentials to modulate dendritic cell function. In contrast to Tehuantepec, the Tulahuen strain suppressed the production of the proinflammatory cytokine IL-12 and subsequent T-cell activation. This inhibitory effect was absent upon desialylation of the parasite. Therefore, we analysed whether sialylated structures of T. cruzi interact with the inhibitory sialic acid-binding protein Siglec-E on DC. Indeed, Siglec-E interacted with the pathogenic Tulahuen strain, but showed a diminished binding to the Tehuantepec strain. Ligation of Siglec-E on DC using antibodies confirmed this inhibitory effect on DC function.
Myelin basic protein (MBP)-specific T cell lines and clones have been established from rats of the major histocompatibility complex (MHC)-compatible Lewis and BS strains. All lines and clones are MHC class II restricted and share the CD4+ phenotype. The cells proliferate specifically in response to either a peptide representing amino acids #68-88 of guinea pig MBP, to residues #47-67 or to an unidentified myelin antigen which is distinct from MBP. All lines and clones specific for MBP express the same T cell receptor (TcR) variable (V) beta chain element, which is homologous to the mouse V beta 8.2 gene segment. Three lines/clones with the same antigen fine specificity have identical V beta D beta J beta junctions on the protein level, a region which represents part of the potential antigen-binding portion of the TcR; two of the lines express members of the V alpha 2 family. These results suggest biased usage of TcR V beta elements in rat T cells specific for MBP. Our findings broaden the basis for a rational therapeutic strategy to specifically intervene in the rodent model system of experimental allergic encephalomyelitis.
In acute Plasmodium falciparum (P. falciparum) malaria, the pro- and anti-inflammatory immune pathways must be delicately balanced so that the parasitemia is controlled without inducing immunopathology. An important mechanism to fine-tune T cell responses in the periphery is the induction of coinhibitory receptors such as CTLA4 and PD1. However, their role in acute infections such as P. falciparum malaria remains poorly understood. To test whether coinhibitory receptors modulate CD4+ T cell functions in malaria, blood samples were obtained from patients with acute P. falciparum malaria treated in Germany. Flow cytometric analysis showed a more frequent expression of CTLA4 and PD1 on CD4+ T cells of malaria patients than of healthy control subjects. In vitro stimulation with P. falciparum-infected red blood cells revealed a distinct population of PD1+CTLA4+CD4+ T cells that simultaneously produced IFNγ and IL10. This antigen-specific cytokine production was enhanced by blocking PD1/PDL1 and CTLA4. PD1+CTLA4+CD4+ T cells were further isolated based on surface expression of PD1 and their inhibitory function investigated in-vitro. Isolated PD1+CTLA4+CD4+ T cells suppressed the proliferation of the total CD4+ population in response to anti-CD3/28 and plasmodial antigens in a cell-extrinsic manner. The response to other specific antigens was not suppressed. Thus, acute P. falciparum malaria induces P. falciparum-specific PD1+CTLA4+CD4+ Teffector cells that coproduce IFNγ and IL10, and inhibit other CD4+ T cells. Transient induction of regulatory Teffector cells may be an important mechanism that controls T cell responses and might prevent severe inflammation in patients with malaria and potentially other acute infections.
Cerebral malaria (CM) associated with Plasmodium berghei ANKA (PbA) infection is an accepted model of human CM. CM during PbA infection critically depends on sequestration of T cells into the brain. Several studies aimed to address the role of regulatory T cells (Treg) in modulating this pathogenic T cell response. However, these studies are principally hampered due to the fact that until recently no reagents were available to deplete Foxp3+ Treg specifically. To study the function of Treg in the genesis of CM, we used depletion of Treg mice that are transgenic for a bacterial artificial chromosome expressing a diphtheria toxin receptor-enhanced GFP fusion protein under the control of the foxp3 gene locus. These mice allow for a selective depletion of Foxp3+ Treg by diphtheria toxin injection, and also their specific detection and purification during an ongoing infection. Using depletion of Treg mice, we found only a small increase in the absolute numbers of Foxp3+ Treg during PbA infection and, consequently, the ratio of Treg to T effector cells (Teff) decreased due to the rapid expansion of Teff. Although the latter sequester in the brains of infected mice, almost no Treg were found in the brains of infected mice. Furthermore, we demonstrate that depletion of Treg has no influence on sequestration of Teff and on the clinical outcome, and only minor influence on T cell activation. Using ex vivo analysis of purified Treg from either naive mice or PbA-infected mice, we found that both exhibit similar inhibitory capacity on Teff.
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