Peptide binding to surface class II molecules is the major pathway of formation of immunogenic class II-peptide complexes for viable antigen presenting cells.

Although studies on fixed APCs have demonstrated that peptide can bind to cell surface class II molecules, the mechanisms by which peptide-class II complexes are formed in viable cells is largely unexplored. To explore the possibility that peptide loading of class II molecules was occurring after endocytosis of peptides as well as by surface binding, we utilized an immunogenic hemagglutinin peptide (HAP 128-145) from the influenza strain A/Japan/57, and studied the appearance of surface complexes of HAP 128-145 bound to HLA-DRw11 molecules on human B-lymphoblastoid cells (BLCLs). Detection of the bound peptide was made possible by a rabbit anti-serum (alpha HAP) raised against HAP 128-145, which recognizes both the free peptide as well as peptide bound to DRw11 on living APCs. Pretreatment of the BLCLs with a variety of inhibitors of protein synthesis and intracellular trafficking failed to decrease the levels of HAP 128-145/DRw11 surface complexes. However, significant inhibition in the appearance of these complexes was caused by a decrease in the temperature at which the cells were incubated with peptide. Temperature-specific inhibition was also observed for fixed DRw11-positive APCs and purified DRw11 molecules indicating that the effect of temperature was directly on the class II molecules. We conclude that surface binding of peptide by class II molecules on human B cells is a major pathway of formation of immunogenic class II-peptide complexes for at least some soluble antigenic peptides, and that endocytosis of soluble peptides with subsequent binding of peptide by intracellular class II molecules plays little if any role in the formation of such complexes. Moreover, class II molecules have evolved to stably bind peptide optimally at physiologic temperatures, independent of cell metabolism.

Mixed haplotypes and autoimmunity.

Why do (NZB x NZW)F1 mice develop an autoimmune lupus-like syndrome? The second exons of the class II genes of NZB and NZW are identical to their counterparts of H-2d and H-2u haplotypes. Several lines of evidence suggest that this allows the production of a mixed haplotype molecule, I-E alpha dE beta z, and that this molecule plays a key role in the development of autoimmunity.

Recognition of the influenza hemagglutinin by class II MHC-restricted T lymphocytes and antibodies. I. Site definition and implications for antigen presentation and T lymphocyte recognition.

We have identified the site encompassing residues 126-145 on the A/Japan/57 influenza hemagglutinin molecule that is recognized in association with HLA-DRw11 by a clonal population of human, influenza specific, CD4+ cytolytic T lymphocytes. The critical core sequence of the T cell determinant spans hemagglutinin residues 129-140 and overlaps a putative antibody binding site. Hemagglutinins of influenza field strains that are not recognized by the T cell clones contain sequence alterations within the 129-140 target site of the CD4+ T cells. Functional analyses, with synthetic peptides, of the contribution of each of the residues within the sequence toward the capacity of the antigenic fragment to associate with both the restriction element and the TCR revealed a continuous linear array of residues necessary for MHC binding and/or Ag receptor engagement. At least one residue, the lysine at position 134, was shown to be critical for both DRw11 association and TCR recognition. The significance of these findings for recognition of glycoproteins by human CD4+ T cells is discussed.

Antibody recognition of an immunogenic influenza hemagglutinin-human leukocyte antigen class II complex.

The A/Japan/57 influenza hemagglutin (HA) peptide HA 128-145, when bound by human histocompatibility leukocyte antigen-DRw11 cells, is recognized by the human CD4+ T cell clone V1. A rabbit antiserum has been raised against HA 128-145 which recognizes not only the free peptide, but also the HA 128-145/DRw11 complex on a solid matrix, in solution, or on the surface of viable cells. The detection of these complexes on viable cells was shown to be class II specific, DRw11 restricted, and commensurate with the level of DRw11 expression. The identity of DRw11 as the cell surface molecule binding HA 128-145 was confirmed by immunoprecipitation, sodium dodecyl sulfate-polyacrylamide gel electrophoresis, and tryptic peptide mapping. Using this antiserum HA 128-145/DRw11 complexes could be detected on the cell surface as soon as 30 min after the peptide was added, and increased up to 24 h. Dissociation kinetics showed these complexes were long-lived, with a half-life of approximately 14 h. This anti-HA peptide antiserum represents the first direct means of studying antigenic peptide-human leukocyte antigen class II complexes on the surface of living cells without the addition of a non-amino acid moiety to the peptide. The properties of this antiserum thus provide the potential to study naturally processed antigenic peptides as well as the mechanism of processing itself in a physiologically relevant system.

A unique sequence of the NZW I-E beta chain and its possible contribution to autoimmunity in the (NZB x NZW)F1 mouse.

The (NZB x NZW)F1 mouse strain develops a syndrome of accelerated autoimmunity including severe renal disease and early death. Evidence suggests that class II molecules play a central role in this process. Previous studies have suggested that the NZW strain contributes at least one gene to the development of accelerated autoimmunity that is linked to the H-2 complex, and antibodies to murine class II molecules have been used to ameliorate disease in (NZB x NZW)F1 mice. We therefore wished to sequence the class II molecules from NZW mice to identify any unique sequences that may contribute to disease development. We constructed oligonucleotide primers corresponding to the 5' and 3' regions of the second exon of class II genes from a variety of haplotypes, and used these primers in a polymerase chain reaction to sequence the second exon of the NZW I-A alpha, I-A beta, and I-E beta genes. We report that the second exons of NZW I-A alpha, I-A beta, and I-E alpha are identical to their counterparts of the previously sequenced u haplotype, and that the second exon of NZW I-E beta is identical to its counterpart from u except for a single base change that results in a substitution of arginine for threonine at amino acid 72. This base and amino acid are identical to those found at the same positions in the s haplotype.