Erwin Rüde

Characterization of the adjuvant effect of IL-12 and efficacy of IL-12 inhibitors in type II collagen-induced arthritis.

A destructive joint disease can be induced in susceptible DBA/1 mice by immunization with type II collagen emulsified with oil and either killed Mycobacterium tuberculosis or IL-12 as adjuvant. Cellular and humoral anti-collagen immune mechanisms appear to be involved in the pathogenesis of arthritis. We have characterized the adjuvant effect or IL-12 in more detail and addressed the question whether mycobacteria might act via the induction of endogenous IL-12. Injections of IL-12 into collagen-immunized DBA/1 mice promoted the development of IFN-gamma-producing CD4+ T cells and strongly upregulated the production of complement-fixing IgG2a and IgG2b antibodies resulting in severe arthritis. Neutralization of IFN-gamma in vivo largely inhibited the increase in antibody synthesis and prevented joint disease in IL-12-treated mice. However, collagen-specific IFN-gamma synthesis by T cells was further enhanced in these animals. Furthermore, IL-12 treatment promoted the development of IFN-gamma-producing T cells but failed to enhance antibody synthesis and to induce arthritis in C57BL/6 or BALB/c mice immunized with collagen in oil. These results indicate that the induction (by IL-12) of a strong collagen-specific T-cell response alone is not sufficient to trigger arthritis. Attempts to show a role for endogenous IL-12 in DBA/1 mice immunized with collagen with mycobacteria as adjuvant gave no reliable results. Whereas anti-IL-12 treatment delayed the onset and ameliorated the disease in some experiments, it failed to do so in other experiments, or, control reagents also had some effect. A slight inhibition of collagen-specific IgG2a synthesis was observed in most experiments in the sera of anti-IL-12-treated mice. Taken together, the results show that exogenous IL-12 can promote arthritis via its direct effect on T cells and its effect on antibody production, which is at least in part IFN-gamma-dependent. On the other hand, whether or not endogenous IL-12 is involved in the adjuvant effect of mycobacteria needs further clarification.

Role of C3b receptors in the enhancement of interleukin-2-dependent T-cell proliferation

The mechanism by which the complement system influences immune responses to T-cell-dependent antigens has not yet been clarified. That is why we studied the effect of the third complement component (C3) on different T-cell-dependent processes using well-defined mouse T-cell lines. While C3 did not influence the interleukin-2 (IL-2) production of the ST2/K-9 helper T-cells, the IL-2-dependent proliferation of the ST1 line was shown to be dose-dependently enhanced by C3. It is proved that neither the haemolytic activity of C3 nor the C3a fragment had any role in the process. The effect of C3 on the IL-2-dependent T-cell growth is even more enhanced (up to five-fold) when using polymerised C3. When the ST1 cell line is cultured in the presence of the cross-linked ligand, T-cells formed 80% less rosettes with red blood cells coated with antibody and mouse or human C3b. It is strongly suggested that C3--particularly when aggregated--exerts its enhancing effect on the growth of IL-2-dependent cell lines by binding to C3b receptors present on such T-cells.

Characterization of a T cell-derived lymphokine that acts synergistically with IL 3 on the growth of murine mast cells and is identical with IL4

Abstract A mast cell-like cell line (SN-1) was established with the aid of growth factor(s) present in the supernatant of a Con A-stimulated L3T4 + T cell line. In analogy to other mast cell lines, IL 3 was identified as a growth factor for SN-1 cells. In addition, a second lymphokine produced by the T cells synergistically enhanced the IL 3-induced growth. This factor, originally termed mast cell growth enhancing factor (MaGEF), could be separated from IL 2, IL 3, a CSF-like activity and was purified to homogeneity. The N-terminal amino acid sequence (8 residues) and the functional properties of this lymphokine proved to be identical with those reported for BSF-1 (IL 4). Unless applied at high concentrations, purified MaGEF did not stimulate growth of the SN-1 mast cells in the absence of IL 3. MaGEF was also found to act on two IL 2-dependent T cell lines by inducing significant thymidine incorporation which was suboptimal compared to that induced by IL 2 and which cannot be inhibited by anti-IL 2-antibodies. A panel of cell lines developed from mouse bone marrow with IL 3 or with a combination of IL 3 and MaGEF all reacted to MaGEF in the presence of IL 3 with considerably increased proliferation. It is therefore suggested that one of the physiological functions of MaGEF is to promote the recruitment of T-dependent mast cells.

Co-development of naive CD4+ cells towards T helper Type 1 or T helper type 2 cells induced by a combination of IL.-12 and IL-4

Cytokines were found to play a key role in Th cell differentiation. Among them IL-12 was shown to be a potent differentiation factor for Th1 cells, whereas IL-4 is the only known cytokine that promotes the development of Th2 cells. Upon addition of comparable amounts of IL-4 and IL-12 to a primary culture of naive CD4+ T cells activated by immobilized anti-CD3 mAb, it was found that the Th1-inducing capacity of IL-12 is dominated by the Th2-promoting effect of IL-4. However, high amounts of IL-12 (10,000 U/ml) in combination with low amounts of IL-4 (100 U/ml) led to the development of a Th cell population that, upon rechallenge, showed a substantial secondary IFN-gamma (Th1 cytokine) production concomitantly with the production of high amounts of IL-4 (Th2 cytokine). This can be due to the coexistence of Th1 and Th2 cells or to the development of Th0 cells producing a mixed pattern of cytokines. Immunofluorescence double staining of intracellular IL-4 and IFN-gamma in combination with flow cytometry (FACS) revealed that most of the emerging Th cells produced either IL-4 or IFN-gamma. Only a few double producers could be detected. This finding indicates that individual naive CD4+ T cells can differentiate under the same conditions towards Th1 or Th2 cells and implicates that the development of Th1 and Th2 cells is not necessarily mutually exclusive.

Processing Requirements for the Recognition of Insulin Fragments by Murine T cells

In this study we investigated aspects of antigen processing using insulin and insulin A chain-derived fragments as model antigens in Ab alpha Ak beta-restricted T-cell stimulation. Similarly to other proteins, the immunodominant region of insulin recognized by these T cells is limited in size. It is located on the insulin A chain and encompasses a portion of the molecule that is represented faithfully by peptide A1-14(SSO3-)3. Efficient presentation of intact insulin and its entire A chain is dependent on uptake and processing by APC. Whereas peptides stemming from various globular proteins are known to be presented to T cells by APC without requiring processing, this is not the case with A-chain fragment A1-14 (SSO3-)3. This observation suggested that, in addition to proteolytic degradation, other mechanisms might play a role in the processing of these antigens. Three cys-residues are located in close proximity to those amino acid residues of the insulin A chain that are inferred to participate in the specific interaction with MHC class II molecules and the TcR. In A-chain derivatives that are stimulatory for the T cells or in intact insulin these cys residues are engaged in disulfide bonds or are S-sulfonated. Both linkages can be reversibly modified by reaction with thiols. Functional data indicate that from intact insulin and from structurally distinct A-chain derivatives a closely similar or identical peptide is formed and bound to class II molecules for recognition by the T cells. The question arises as to whether, in this processed peptide, the cys residues are present in reduced form, engaged in disulfide bonds, or are modified in some other way. Taken together, these findings suggest that modification of cys residues or isomerization of disulfide bonds may play a role in insulin processing. It can be expected that other proteins carrying cys residues in their immunodominant peptides may show similar processing requirements. The inhibition of N-glycosylation of proteins by tunicamycin in APC blocked the processing and presentation of insulin and OvA whereas, under the same conditions, the presentation of a processing-independent peptide was not affected. Furthermore, an autoreactive T-cell clone was capable of recognizing tunicamycin-treated APC. Since the expression of class II molecules was found to be unaltered as demonstrated by cytofluorometric analysis the deficient N-glycosylation appears to have little influence on class II antigen-mediated T-cell recognition but interferes with uptake of antigen and/or its processing by APC.

PRESENTATION OF INSULIN AND INSULIN A CHAIN PEPTIDES TO MOUSE T CELLS : INVOLVEMENT OF CYSTEINE RESIDUES

The requirements for insulin presentation and recognition by A alpha b A beta b- and A alpha b A beta k-restricted mouse T cells were studied using a variety of derivatives of the insulin A chain. It was found that A chain peptides with irreversibly blocked Cys residues are non-stimulatory for the T cells. This suggests that at least one of the Cys residues is essential for recognition. On the other hand, all A chain peptides containing Cys residues modified in a way reversible by reaction with thiols are stimulatory yet differ in antigenic potency. All these A chain derivatives including a 14 amino acid fragment require uptake by antigen presenting cells (APC) for efficient presentation. Differences in stimulatory potency between the A chain peptides derived from the same insulin appear to be mainly due to the efficiency of uptake and/or processing by APC. Based on these findings we propose that processing in the case of insulin and its A chain derivatives involves the reductive deblocking of Cys residues or the rearrangement of disulfide bonds apart from a possible proteolytic cleavage. The same may apply to other proteins if Cys residues in the presented peptides are important for the interaction with Ia or the T cell receptor.

The specificity of the interaction between the agretope of an antigen and an Ia-molecule can depend on the T cell clonotype

A series of T cell clones was developed from (B10 x B10.BR)F1 mice immunized with the isolated A chain of pig insulin. The T cell clones show considerable diversity as defined by their distinct reactivities to pig, beef, sheep and horse insulins in combination with the same syngeneic Ab alpha Ak beta molecules. These species variants of insulin differ from each other only in amino acid residues in position A8, A9 or A10 within the so-called A chain loop and responsiveness of mice to these variants is under Ir gene control. A detailed analysis of the stimulatory capacity of various insulin/Ia combinations including inhibition experiments with anti-Ia- and -L3T4 antibodies led to the following interpretation: the amino acid residues A8-A10 are involved in the interaction of the insulin A chain with the Ia molecules. This region can, therefore, be regarded as part of the agretope. Structural variations within this region can modify the stimulatory potency of the insulin variants. However, whether a particular amino acid substitution results in an enhancement or a reduction of the response depends on the fine specificity of the T cell clone involved. Thus, an interaction of Ia molecules with antigen cannot solely account for the functional specificity of an agretope, rather this also depends on the structure of the particular T cell receptor that participates in recognition.

Characterization of a T-cell-derived mast cell costimulatory activity (MCA) that acts synergistically with interleukin 3 and interleukin 4 on the growth of murine mast cells

The proliferation of mucosal mast cells (MMC) depends on the presence of interleukin 3 (IL 3) and can be further enhanced by interleukin 4 (IL 4). The supernatant of a TH2 cell clone (ST2/K.9) stimulated by concanavalin A was found to contain a factor, provisionally termed mast cell costimulatory activity (MCA), that substantially enhances the proliferation of MMC promoted by a combination of IL 3 and IL 4. In comparison to other lymphokines MCA is rather resistant to tryptic digestion but is very sensitive to pH values lower than 6.0 and to organic solvents. Chromatographic fractionation of MCA revealed that activity is associated with protein(s) or glycoprotein(s) of 35 to 40 kDa. Partially purified MCA that was functionally free of other T-cell-derived lymphokines did not stimulate mast cell proliferation in the absence of a combination of IL 3 and IL 4. In addition, MCA did not affect the proliferation of mast cells when employed together with either IL 3 or IL 4 alone. Control experiments demonstrated that MCA is identical to neither the T-cell-derived lymphokines IL 2 to IL 6, IL 9, interferon gamma, tumor necrosis factor alpha or beta, or granulocyte-macrophage colony-stimulating factor (CSF), nor to IL 7, granulocyte CSF, macrophage CSF, erythropoietin, leukemia inhibitory factor, or epidermal growth factor (EGF). Finally, experiments using a panel of PPD-reactive TH1- and TH2-like cell lines revealed that MCA is preferentially produced by TH2 cells. These data, especially the relative resistance of MCA to trypsin and the high sensitivity to low pH values and organic solvents, indicate that MCA is distinct from known T-cell-derived lymphokines.(ABSTRACT TRUNCATED AT 250 WORDS)

Xid-defective male (cba/n x c57bl/6)f1 accessory cells present bovine insulin to long-term cultured f1-restricted t-cells.

The reactivity of H-2b-restricted murine T cells towards bovine insulin was reported to depend on the expression of Ia.W39, a private specificity of I-Ab, on antigen-presenting cells. Cells of male (CBA/N x B6)F1 mice carrying the mutation xid on the X chromosome lack Ia.W39 on the cell surface. These cells are unable to present bovine insulin to primed T cells derived from female (CBA/N x B6)F1 mice. We show here that spleen cells of male (CBA/N x B6)F1 hybrids served perfectly as accessory cells for the insulin-dependent induction of a proliferative response of long-term cultured T cells with (B10 x B10.BR)F1 genotype, restricted to recognizing insulin in the context of F1-unique I-A determinants. The epitope on the insulin molecule essential for stimulation was determined to depend on the glutamic acid residue in position 4 of the A chain of insulin. This contrasts with the H-2b-restricted response of B6 mice to bovine insulin, which appears to be directed at the A chain loop determinant (amino acids A8 and A10). These data suggest that distinct I-Ab-encoded structures, the expression of which is regulated independently, may serve as components of restriction elements for H-2b and (H-2b x H-2k)F1 restricted T cells, which are specific for different epitopes of bovine insulin.

Cellular immune responses of macaques exposed to low doses of SIV

In 1993, Mario Clerici and Gene Shearer1 proposed that the balance of the T helper (Th)-cell response, and particularly a Thl-to-Th2 shift, is critical for the etiopathogenesis of human immunodeficiency virus (HIV) infection. Further complexities of the model were considered in a subsequent article2 in 1994. Although, since then, numerous experiments have tested this hypothesis, there remains relatively little information on whether virusspecific Th-cells can protect individuals against primary infection with immunodeficiency viruses. The Th-cell response of uninfected humans3 and monkeys4 upon prior exposure to HIV implies that virusspecific cellular immunity might induce protection against HIV infection. However, these observations need to be examined in an animal model such as the macaque model for simian immunodeficiency virus (SIV) infection. It has been reported previously that administration of low doses of either inactivated SIV antigen5 or infectious SIV (Refs 6,7) results in Th-cell proliferation in macaques, without evoking an SIV-specific antibody response. Importantly, some of the macaques primed with such ‘sub-infectious doses’ were protected against an intrarectal SIVchallenge 6,7. In conclusion, protecFrank Mattner