The functional role of class II-associated invariant chain peptide (CLIP) in its ability to variably modulate immune responses.

During the process of class II MHC assembly and cell surface expression, the class II-associated invariant chain peptide (CLIP) is removed from the peptide-binding groove of MHC, a task mediated by H-2M. This allows binding and presentation of peptide epitopes. We have previously shown that exogenously added CLIP interferes with this process and down-regulates the cell surface expression of class II molecules. In this study, we explored the effect of exogenously added CLIP on antigen-specific immune responses. In vivo studies with CLIP and various peptide and protein antigens with different affinities for I-A(d) molecules demonstrated that CLIP variably affects the T cell-mediated immune responses. Immunization with CLIP along with the antigen induced a shift from a T(h)1- to T(h)2-like response as determined by the cytokine profile and antibody isotype. These results suggest that the presence of exogenous CLIP can significantly influence the presentation of antigen by class II MHC molecules to CD4 T cells and thereby modulate immune responses. Exogenously added CLIP rapidly localized into the subcellular compartment of antigen-presenting cells where MHC class II molecules are present. We suggest that exogenous CLIP reduces the loading of peptides on the class II molecules, thus down-regulating MHC-peptide complexes on the cell surface. Alternatively, CLIP may bind to cell surface class II molecules and this complex is rapidly internalized resulting in reduced cell surface MHC class II expression. The reduced level of MHC-peptide complexes favors the activation of T(h)2 cells over T(h)1 cells. These results have implications in the regulation of immune responses, particularly the prevention of certain autoimmune diseases where T(h)1-type responses are pathogenic and T(h)2-type responses are protective.

Epitope dominance: evidence for reciprocal determinant spreading to glutamic acid decarboxylase in non-obese diabetic mice.

Autoimmune T-cell responses to peptide determinants of several autoantigens have recently been characterized. These data suggest that, in some autoimmune models, such as experimental autoimmune encephalomyelitis, T-cell responses may diversify from a nested set of peptides to include many other peptide regions. A similar immune phenomenon pertaining to autoimmune diabetes (IDDM) is observed in NOD mice. We have explored a similar pattern of T-cell responses related to age and disease status in NOD mice termed epitope dominance, which describes immune responses toward a pronounced subset of determinants of the autoantigen glutamic acid decarboxylase (GAD). Our studies have identified a total of five GAD epitopes between the 65 and 67 kDa isoforms. The magnitude of T-cell responses to these various determinants was dependent on the stage of disease as well as on whether mice were protected from disease. The T-cell responses of these epitopes in NOD mice correlated with the predicted binding of these peptides to the NOD class II molecule I-Ag7. We therefore propose a model which implicates antigen presenting cells as critical entities in the propagation of dominant responses to the presentation of autoantigens to T cells, particularly in the Th 1 environment of the NOD mouse. This hypothesis presents a new framework for the discussion and interpretation of the kinetics of T-cell responses to different peptide epitopes in autoimmune diseases such as IDDM.

Characterization of novel T-cell epitopes on 65 kDa and 67 kDa glutamic acid decarboxylase relevant in autoimmune responses in NOD mice.

It has recently been shown that the T-cell mediated immune responses to glutamic acid decarboxylase (GAD) play an important role in insulin-dependent diabetes mellitus (IDDM) in NOD mice. However, specific epitopes responsible for eliciting these responses remain unresolved. In this study, the T-cell epitopes involved in GAD-specific immune responses in NOD mice were characterized. By priming NOD mice with GAD65, three new GAD65 epitopes (GAD65 78-97, GAD65 202-221, GAD65 217-236) distinct from those previously reported were found. Furthermore, our investigations into the fine determinant specificity of GAD67 revealed two additional GAD67-specific peptide epitopes (GAD67 28-47, GAD67 42-61). Two of the GAD65 epitopes (GAD65 202-221 and GAD65 217-236) are shared between GAD65 and GAD67. Spontaneous immune responses to these peptides were found in pre-diabetic and diabetic mice and differential patterns of responses to these peptides were observed depending on the age of the mice, disease status, or if the mice were protected from diabetes by adjuvant immunotherapy. Characterization of these new epitopes will help in the elucidation of autoimmune responses to GAD in IDDM.

Modulation of antigen presentation and class II expression by a class II-associated invariant chain peptide.

During the process of MHC class II assembly, the class II-associated invariant chain peptide (CLIP) remains bound within the peptide binding groove until its subsequent removal, which is mediated by H-2 M. We have defined the functional role of CLIP, through saturation of the endosomal compartment with exogenous CLIP-(85-101), resulting in reduced class II MHC on the surface of APCs and an impeded T cell response. Conversely, incubation of the same cells with immunogenic peptides or proteins resulted in an up-regulation of surface class II MHC. T cells from CLIP- plus Ag-immunized mice showed a marked decrease in Ag-specific response over that in mice primed with Ag alone. A B cell hybridoma, TA3 (H-2d,k) incubated with CLIP in vitro showed dramatically reduced MHC class II I-A surface expression. APCs derived from CLIP-immunized mice exhibited down-regulation of surface class II MHC, but not of CD45 (B220). Electrophoretic studies showed that the addition of exogenous CLIP resulted in a relative decrease in SDS-stable MHC class II heterodimers in TA3 cells. Studies with FITC-CLIP and FITC-OVA-(323-339) peptides demonstrated that exogenously added CLIP peptide does not bind to surface class II molecules via the endogenous route, whereas OVA peptide does. This suggests that exogenously added CLIP acts intracellularly, perhaps in the compartment where H-2 M intersects with class II molecules. These findings demonstrate the functional role of CLIP to regulate MHC class II-mediated Ag presentation in CD4+ T cell responses.