Jan Wouter Drijfhout

Cross-presentation by intercellular peptide transfer through gap junctions

Major histocompatibility complex (MHC) class I molecules present peptides that are derived from endogenous proteins. These antigens can also be transferred to professional antigen-presenting cells in a process called cross-presentation, which precedes initiation of a proper T-cell response; but exactly how they do this is unclear. We tested whether peptides can be transferred directly from the cytoplasm of one cell into the cytoplasm of its neighbour through gap junctions. Here we show that peptides with a relative molecular mass of up to ∼1,800 diffuse intercellularly through gap junctions unless a three-dimensional structure is imposed. This intercellular peptide transfer causes cytotoxic T-cell recognition of adjacent, innocent bystander cells as well as activated monocytes. Gap-junction-mediated peptide transfer is restricted to a few coupling cells owing to the high cytosolic peptidase activity. We present a mechanism of antigen acquisition for cross-presentation that couples the antigen presentation system of two adjacent cells and is lost in most tumours: gap-junction-mediated intercellular peptide coupling for presentation by bystander MHC class I molecules and transfer to professional antigen presenting cells for cross-priming.

A computer program for predicting possible cytotoxic T lymphocyte epitopes based on HLA class I peptide-binding motifs

Vaccination with peptides recognized by antigen-specific CTLs can prevent lethal virus infections and tumor growth. In order to avoid the synthesis and testing of the numerous overlapping peptide of long AA sequences of proteins of interest, we developed a computer program which utilizes the rules, motifs which govern how peptides bind to HLA class I molecules, to derive a predicted binding score for each overlapping peptide. Correlations between the predicted and actual binding results to HLA-A*0201 for 100 peptides selected from six early and two late protein sequences of human papillomavirus type 1a revealed an acceptable level (61%) of concordance. The program is very flexible with regard to the input of protein sequences and motif definitions and is able to handle various motif and peptide lengths.

Mannose receptor mediated uptake of antigens strongly enhances HLA-class II restricted antigen presentation by cultured dendritic cells.

Dendritic cells (DCs) use macropinocytosis and mannose receptor mediated endocytosis for the uptake of exogenous antigens. Here we show that the endocytosis of the mannose receptor and mannosylated antigen is distinct from that of a non-mannosylated antigen. Shortly after internalization, however, both mannosylated and non-mannosylated antigen are found in an MIIC like compartment. The mannose receptor itself does not reach this compartment, and probably releases its ligand in an earlier endosomal structure. Finally, we found that mannosylation of peptides strongly enhanced their potency to stimulate HLA class II-restricted peptide-specific T cell clones. Our results indicate that mannosylation of antigen leads to selective targeting and subsequent superior presentation by DCs which may be useful for vaccine design.

Detailed motifs for peptide binding to HLA-A∗0201 derived from large random sets of peptides using a cellular binding assay

Extensive sets of in total about 2000 synthetic peptides were investigated for their binding affinities to HLA-A*0201. Comparisons of the amino acid compositions of binding to nonbinding sets of peptides provided new information concerning the rules for 9-, 10-, and 11-mer peptide binding at the amino acid level. Preferred primary anchors were shown to depend on peptide length, longer peptides being more demanding in this respect. A clear preference exists for certain amino acids at several nonanchor positions. In addition, the presence of particular amino acids at those positions almost completely precludes peptide binding. We found no evidence for preferred anchor pairs. From these results new and detailed HLA-A*0201 peptide-binding motifs for 9-, 10-, and 11-mer peptide binding were deduced. The motifs are in accordance with earlier reports but include new findings, including C as a C-terminal anchor, the importance of D at positions 4 for binding, and the deleterious effect of R at position 5 (in 9-mers). The motifs are presented in such a way that they can be used to predict peptide binding to HLA-A*0201 by computer analysis (see accompanying paper [56]).

Autoantibodies to p53 in ovarian cancer patients and healthy women: a comparison between whole p53 protein and 18-mer peptides for screening purposes

Autoantibodies against complete p53 protein and 18-mer peptides of p53 in ovarian cancer patients and healthy women were examined. Sera from 9% (4/46) of ovarian cancer patients but none (0/51) of healthy women recognized complete p53 protein. The antibodies were mainly of the IgG1 isotype. Two patients had also IgG2 antibodies. Sera from 28% (13/46) of cancer patients and 21% (11/52) of healthy women contained either IgM, or IgM plus IgG2 antibodies against 18-mer p53 peptides. Screening against complete p53 protein instead of peptides seems necessary for identifying patients with tumor-related antibodies. IgG2 antibodies against p53 suggest p53-specific CD4+ T helper 1 cell activity in some of the ovarian cancer patients.

CLIP binds to HLA class II using methionine-based, allele-dependent motifs as well as allele-independent supermotifs

The invariant chain (Ii) region that interacts with class II and inhibits premature peptide binding has been mapped to amino acids 82-107, known as CLIP. It is unclear whether CLIP binds directly to the class II peptide binding groove and thus competitively blocks binding of other peptides, or whether it binds to conserved class II sites and indirectly inhibits peptide binding by inducing conformational changes in class II. Here we show evidence that strongly suggests that CLIP binds within the peptide binding groove, as CLIP binds to various HLA-DR alleles using allele-dependent as well as allele-independent, methionine-based binding motifs. First, a core sequence of 12 amino acids was identified within CLIP which is required for optimal binding to DR1, DR2, DR3(17) and DR7. This sequence is composed of CLIP p88-99 (SKMRMATPLLMQ). By substitution analysis, all three methionine residues appeared to control CLIP binding to HLA-DR. However, whereas M90 controlled binding to all four alleles, M92 and M98 were of different importance for the various alleles: M92 is involved in CLIP binding to DR1 and DR3(17) but not to DR2 or DR7, and M98 controls CLIP binding to DR2, DR3(17) and DR7 but not DR1. Also, CLIP competes with known immunogenic peptides for class II binding in a manner indistinguishable from regular, class II binding competitor peptides. Finally, the dissociation rates of CLIP-class II complexed are similar to those of antigenic peptide-class II complexes. Thus, CLIP most likely binds to the class II peptide binding groove, since most allelic class II differences are clustered here. CLIP uses unconventional methionine anchor residues representing an allele-independent supermotif (M90) as well as allele-dependent motifs (M92 and M98).

Liposome‐mediated peptide loading of MHC‐DR molecules in vivo

Amino acid residues 3–15 of mycobacterial HSP60 define a dominant T‐cell epitope for HLA‐DR3+ve humans and Mamu‐DR3+ve rhesus monkeys. Our results show that Mamu‐DR3 molecules on PBMC can be efficiently loaded in vivo with the above‐mentioned peptides when they are intravenously injected encapsulated in liposomes, but not in the free form. Mamu‐DR3 loading is abolished by encapsulation of a nonstimulatory peptide. These results have implications for the delivery of therapeutic peptides in vivo.