Differential susceptibility of human T(h)1 versus T(h) 2 cells to induction of anergy and apoptosis by ECDI/antigen-coupled antigen-presenting cells.

Antigen-coupled antigen-presenting cells (APC) serve as potent tolerogens for inhibiting immune responses in vivo and in vitro, apparently by providing an antigen-specific signal through the TCR in the absence of co-stimulation. Although this approach has been well studied in rodents, little is known about its effects on human T cells. We evaluated the specificity and mechanisms of tolerization of human T cells in vitro using monocyte-enriched adherent cells that were pulsed with antigen and treated with the cross-linker, 1-ethyl-3-(3-dimethylaminopropyl)-carbodiimide (ECDI). Autologous antigen-coupled APC selectively tolerized T cells of the T(h)1 but not T(h)2 lineage through a mechanism that involved both antigen-specific and antigen-non-specific elements. The tolerization process was dependent on the ECDI and antigen concentration, and the coupling time, and was reflected by initial up-regulation of CD25. However, upon re-stimulation with fresh APC and antigen, tolerized T(h)1 cells failed to proliferate or to produce T(h)1 cytokine message or secreted protein, had decreased expression of CD25, CD28 and B7 and increased expression of MHC class II molecules, and demonstrated an enhanced commitment to apoptosis. T(h)1 cell tolerization could be prevented by adding anti-CD28 antibody, IL-2 or untreated APC at the same time as the ECDI/antigen-coupled APC, or reversed by adding anti-CD28 antibody or IL-2 upon re-stimulation with fresh APC plus antigen. Thus, the tolerizing effect of ECDI/antigen-coupled APC on human T(h)1 cells appears to involve a reversible anergy mechanism leading to apoptosis, whereby the targeted T cells receive full or partial activation through the TCR, without coordinate co-stimulation. These data suggest dichotomous signaling requirements for inactivating cells of the T(h)1 and T(h)2 lineages that may have important implications for treatment of T(h)1-mediated autoimmune or inflammatory diseases.

A rhesus macaque rhadinovirus related to Kaposi's sarcoma-associated herpesvirus/human herpesvirus 8 encodes a functional homologue of interleukin-6.

The rhesus rhadinovirus strain 17577 (RRV strain 17577) genome is essentially colinear with human herpesvirus 8 (HHV8)/Kaposi's sarcoma-associated herpesvirus (KSHV) and encodes several analogous open reading frames (ORFs), including the homologue of cellular interleukin-6 (IL-6). To determine if the RRV IL-6-like ORF (RvIL-6) is biologically functional, it was expressed either transiently in COS-1 cells or purified from bacteria as a glutathione S-transferase (GST)-RvIL-6 fusion and analyzed by IL-6 bioassays. Utilizing the IL-6-dependent B9 cell line, we found that both forms of RvIL-6 supported cell proliferation in a dose-dependent manner. Moreover, antibodies specific to the IL-6 receptor (IL-6R) or the gp130 subunit were capable of blocking the stimulatory effects of RvIL-6. Reciprocal titrations of GST-RvIL-6 against human recombinant IL-6 produced a more-than-additive stimulatory effect, suggesting that RvIL-6 does not inhibit but may instead potentiate normal cellular IL-6 signaling to B cells. These results demonstrate that RRV encodes an accessory protein with IL-6-like activity.

The OX-40 receptor provides a potent co-stimulatory signal capable of inducing encephalitogenicity in myelin-specific CD4+ T cells.

The OX-40 receptor, a member of the nerve growth factor/tumor necrosis factor receptor gene family, is expressed preferentially on autoreactive CD4+ T cells isolated from the site of inflammation in rats with clinical signs of experimental autoimmune encephalomyelitis (EAE). To examine whether the OX-40 receptor has biologic relevance to T cell function, we evaluated the ability of a rat OX-40 receptor-specific antibody to co-stimulate a myelin basic protein (MBP)-reactive CD4+ T cell line. The anti-OX-40 antibody provided a potent co-stimulatory signal to CD4+ T cells when added in conjunction with a submitogenic dose of anti-CD3, but the anti-OX-40 antibody alone did not produce a mitogenic response. The magnitude and dose-response of anti-OX-40 co-stimulation was virtually identical to the signal delivered to T cells when cultured with anti-CD28 in conjunction with anti-CD3. MBP-specific T cells stimulated with both anti-CD3 and anti-OX-40 antibodies expressed increased mRNA and protein for IL-2 when compared to anti-CD3 alone. MBP-specific T cells stimulated with both anti-CD3 and anti-OX-40 antibodies were also able to induce EAE when transferred into naive Lewis rats. In contrast, cells stimulated with anti-CD3 alone were not encephalitogenic. These data suggest that the function of the OX-40 receptor on activated T cells is to provide an alternative pathway for T cell co-stimulation that may be similar in potency to the CD28-mediated signal.

MHC-restriction, cytokine profile, and immunoregulatory effects of human T cells specific for TCR V beta CDR2 peptides: comparison with myelin basic protein-specific T cells.

HLA-DR2+ patients with multiple sclerosis (MS) that respond to vaccination with TCR V beta 5.2-38-58 peptides have increased frequencies of TCR peptide-specific T cells, reduced frequencies of myelin basic protein (MBP)-specific T cells, and a better clinical course than non-responders. To evaluate possible network regulation of MBP responses by TCR peptide-specific T cells, we compared properties of both cell types. Both MBP- and TCR peptide-specific T cell clones were CD4+ and predominantly HLA-DR restricted. HLA-DR2, which is in linkage disequilibrium in MS patients, preferentially restricted TCR peptide-specific clones as well as MBP-specific responses in HLA-DR2 and DR2,3+ donors. Within the DR2 haplotype, however, both DR beta 1*1501 and DR beta 5*0101 alleles could restrict T cell responses to V beta CDR2 peptides, whereas responses to MBP were restricted only by DR beta 5*0101. TCR peptide-specific clones expressed message for Th2 cytokines, including IL-4, IL-5, IL-6, IL-10, and TGF-beta, whereas MBP-specific T cell clones expressed the Th1 cytokines IFN-gamma and IL-2. Consistent with the Th2-like cytokine profile, TCR peptide-specific T cell clones expressed higher levels of CD30 than MBP-specific T cells. Culture supernatants from TCR peptide-specific T cell clones, but not from MBP- or Herpes simplex virus-specific T cells, inhibited both proliferation responses and cytokine message production of MBP-specific T cells. These results demonstrate distinct properties of MBP and TCR peptide-specific T cells, and indicate that both target and bystander Th1 cells can be inhibited by Th2 cytokines secreted by activated TCR peptide-specific T cells. These data support the rationale for TCR peptide vaccination to regulate pathogenic responses mediated by oligoclonal T cells in human autoimmune diseases.

The development of peripheral TNP-tolerance and suppressor function in Xenopus laevis, the South African clawed toad.

In adult Xenopus laevis, inducer- and effector-suppressor functions are located in the spleen. These peripheral suppressor functions must be established at this location near the end of metamorphosis, since both functions are in the thymus in premetamorphic and in developmentally-blocked metamorphosing larvae. This study examined whether TNP-conjugated self-antigens resulting from exposure to trinitrobenzene sulfonic acid (TNBS), will stimulate TNP-tolerance in premetamorphic, metamorphic, and in developmentally-blocked metamorphosing larvae. Premetamorphic and developmentally-blocked larvae produce little TNP-tolerance or peripheral suppressor function. However, when TNBS exposure includes the late stages of the metamorphic period, both TNP-tolerance and splenic anti-hapten suppressor function are demonstrable. Removal of suppressor function with cyclophosphamide prevents expression of tolerance, thus, they are functionally related. Suppressor function and tolerance both differentiate during the late metamorphic stages when new adult antigens are being expressed and incorporated into a library of self.