Showing papers by "B Benacerraf published in 1992"

Heterogeneity in antigen processing by different types of antigen-presenting cells. Effect of cell culture on antigen processing ability.

Abstract: The ability of normal B cells, peritoneal macrophages, and splenic APC to process and present OVA to a panel of T-T hybridomas with different specificities was investigated In all cases, B cells were less efficient than unfractionated splenocytes in presenting OVA or its peptides However, when the presentation of native Ag was compared to the presentation of peptides, it was obvious that there were marked differences in the ability of these two APC populations to generate different epitopes from OVA Leupeptin inhibits the processing of selected epitopes from native OVA differently when it was presented by spleen cells or B cells, suggesting that these two APC populations differ in their protease content The effect of in vitro culture on the ability of splenic and peritoneal APC to process OVA was also investigated Native OVA presentation by macrophages and spleen cells was affected by in vitro culture, more for some epitopes than for other epitopes In contrast, presentation of exogenous peptides by paraformaldehyde-fixed APC was either not affected by previous culturing for 3 days, or very much improved Altogether, these data demonstrate that different epitopes on the same protein may be independently and differentially processed by B cells and spleen cells Furthermore, the precise peptides that are produced may vary with the physiologic state of the APC

Diversity in MHC class II ovalbumin T cell epitopes generated by distinct proteases.

Abstract: It is generally accepted that a limited number of T cell epitopes are generated by APC from an immunogenic protein. To ascertain the number of determinants on OVA recognized in the context of the H-2s haplotype, we generated 19 T-T hybridomas against OVA and H-2s and we synthesized 46 overlapping peptides spanning the entire protein. Eighteen T-T hybrids were stimulated by eight different peptides. The peptide recognized by one T cell hybrid was not identified. The effect of four protease inhibitors on the processing and presentation of OVA by the LS.102.9 B cell hybridoma seemed to implicate several groups of proteases in the processing of this Ag. Alkylation of cysteine residues with iodoacetic acid showed in a few cases a dramatic decrease in the capacity of OVA to stimulate T-T hybrids recognizing cysteine-free peptides. In contrast, two T-T hybrids recognizing cysteine containing peptides were not affected by the alkylation, suggesting that alkylation inhibited the processing of OVA without affecting peptide interaction with class II MHC molecules. These data demonstrate that the repertoire of peptides generated by APC from OVA is not limited to one or few immunodominant peptides, and results from the activity of several endopeptidases and/or exopeptidases. In addition, the structure of the Ag (native or denatured) was shown to affect the efficiency with which different epitopes are generated.

Serum proteases alter the antigenicity of peptides presented by class I major histocompatibility complex molecules

Abstract: Any effect of serum on the antigenicity of peptides is potentially relevant to their use as immunogens in vivo. Here we demonstrate that serum contains distinct proteases that can increase or decrease the antigenicity of peptides. By using a functional assay, we show that a serum component other than beta 2-microglobulin enhances the presentation of ovalbumin peptides produced by cyanogen bromide cleavage. Three features of this serum activity implicate proteolysis: it is temperature dependent, it results in increased antigenicity in a low molecular weight peptide fraction, and it is inhibited by the protease inhibitor leupeptin. Conversely, presentation of the synthetic peptide OVA-(257-264) is inhibited by serum. This inhibition is unaffected by leupeptin but is blocked by bestatin, a protease inhibitor with distinct substrate specificities. Implications for peptide-based vaccine design and immunotherapy are discussed.

The class II MHC-restricted presentation of endogenously synthesized ovalbumin displays clonal variation, requires endosomal/lysosomal processing, and is up-regulated by heat shock.

Abstract: LB27.4 cells (a B lymphoblastoid APC) were transfected with a plasmid containing an OVA cDNA. Functional analysis of six independent clones yielded three patterns of MHC-restricted presentation of the endogenously synthesized OVA. A clone displayed either: 1) strong class I and class II-restricted presentation, 2) strong class I but little or no class II-restricted presentation or, 3) only a modest class I-restricted presentation. There was no clonal variation in class II-restricted presentation of exogenous Ag or in the amount of surface class I or II molecules. Heat shock increased the presentation of endogenous but not exogenous Ag with class II. These results indicate that an endogenously synthesized Ag both constitutively and during heat shock can gain access to the class II, MHC-restricted, presentation pathway. The amount of OVA synthesized by a cell correlated with whether OVA-class II complexes were detected. However, the amount of OVA secreted into the extracellular fluid was not sufficient to sensitize APC, which suggests that endogenously synthesized OVA enters the class II pathway of Ag presentation by an intracellular route rather than by an extracellular/reuptake route. Also, the functional and quantitative analysis of the clones suggests that endogenously synthesized OVA was presented more efficiently with class I as compared to class II-MHC molecules. Leupeptin and chloroquine inhibited the class II-restricted presentation of endogenously synthesized OVA. Together these results indicate that endogenously synthesized OVA can gain access to an endosomal/lysosomal compartment via an intracellular route and be processed and presented in association with class II-MHC molecules.

Chemical cross-linking of class I molecules on cells creates receptive peptide binding sites.

Abstract: Class I heterodimers on the surface of cells are generally unreceptive to binding peptides in the absence of exogenous beta 2-microglobulin. Paraformaldehyde covalently cross-links beta 2-microglobulin to class I heavy chains in situ and stabilizes empty class I heterodimers. Functionally, this cross-linking creates receptive class I peptide binding sites by acting on beta 2-microglobulin-associated molecules. The presentation of preexisting peptide-class I complexes is also enhanced. These findings support a model whereby a structural alteration, the dissociation of beta 2-microglobulin, limits the existence of receptive class I molecules on normal cells and may control the half-life of active class I molecules.