Kiley R. Prilliman

Large-scale production of class I bound peptides: assigning a signature to HLA-B*1501.

Abstract A peptide-based vaccine must be bound and presented by major histocompatibility complex class I molecules to elicit a CD8+ T-cell response. Because class I HLA molecules are highly polymorphic, it has yet to be established how well a vaccine peptide that stimulates one individual’s CD8+ cytotoxic T lymphocytes will be presented by a second individual’s different class I molecules. Therefore, to facilitate precise comparisons of class I peptide binding overlaps, we uniquely combined hollow-fiber bioreactors and mass spectrometry to assign precise peptide binding signatures to individual class I HLA molecules. In applying this strategy to HLA-B*1501, we isolated milligram quantities of B*1501-bound peptides and mapped them using mass spectrometry. Repeated analyses consistently assign the same peptide binding signature to B*1501; the degree of peptide binding overlap between any two class I molecules can thus be determined through comparison of their peptide signatures.

HLA-B polymorphism affects interactions with multiple endoplasmic reticulum proteins.

To explore the nature of amino acid substitutions that influence association with TAP, we compared a site‐directed mutant of HLA‐B*0702 (Y116D) to unmutated HLA‐B7 in regard to TAP interaction. We found that the mutant had stronger association with TAP, and, in addition, with tapasin and calreticulin. These data confirm the importance of position 116 for TAP association, and indicate that (1) an aspartic acid at the 116 position can facilitate the interaction, and (2) association with tapasin and calreticulin is affected along with TAP. Furthermore, we tested three natural subtypes of HLA‐B15, and found that a B15 subtype with a tyrosine at position 116 (B*1510) was strongly associated not only with TAP, but also with tapasin and calreticulin. In contrast, two B15 subtypes with a serine at position 116 (B*1518 and B*1501) exhibited very little or no association with any of these proteins. Thus, very closely related HLA‐B subtypes can differ in regard to interaction with the entire assembly complex. Interestingly, when their surface expression was tested by flow cytometry, the HLA‐B15 subtypes with little to no detectable intracellular assembly complex association had a slightly, yet consistently, higher level of the open heavy chain form than did the B15 subtype with intracellular assembly complex association. These data suggest that the relatively low strength or short length of interaction between endoplasmic reticulum proteins and natural HLA class I molecules can decrease their surface stability.

COMPLEXITY AMONG CONSTITUENTS OF THE HLA-B*1501 PEPTIDE MOTIF

Abstract Analysis of peptides derived from HLA class I molecules indicates that thousands of unique peptides are bound by a single molecular type, and sequence examination of the pooled constituents yields a motif which collectively defines the peptides bound by a given class I molecule. Motifs resulting from pooled sequencing are then used to infer whether particular viral and tumor protein fragments might serve as class I-presented peptide therapeutics. Still undetermined from a pooled motif is the breadth or range of peptides in the population which are brought together to form the pooled motif, and it is therefore not yet known how representative of the population a pooled motif is. By employing hollow fiber bioreactors for large-scale production of HLA class I molecules, sufficient peptides are produced to investigate individual subsets of peptides comprising a motif. Edman sequencing and mass spectrometric analysis of peptides eluted from HLA-B*1501 reveal that many peptide sequences fail to align with either the N- or C-terminal anchors predicted for the B*1501 peptide motif through whole pool sequencing. These analyses further reveal auxiliary anchors not previously detected and peptides significantly larger and smaller than the predicted nonamer, ranging from 6 to 12 amino acids in length. These results demonstrate that constituents of the B*1501 peptide pool vary markedly in comparison with one another and therefore in comparison with previously established B*1501 motifs, and such complexity indicates that many of the peptide ligands presented to CTL cannot be predicted using class I consensus motifs as search criteria.

C-terminal epitope tagging facilitates comparative ligand mapping from MHC class I positive cells

Purification of specific class I molecules prior to peptide ligand characterization is complicated by the presence of multiple class I proteins in most cell lines. Immortalized B, T, and tumor cell lines typically express endogenous HLA-A, -B, and -C; and most individuals from which the cell lines are derived are heterozygous at these loci. Antibodies specific for a particular HLA molecule may be used for purification, but allele-specific antibodies can be biased by ligands occupying the peptide-binding groove. Through the use of C-terminal tagging, we have developed a method of soluble HLA production such that downstream purification does not skew the peptide analysis of the examined molecule. Comparison of peptides eluted from HLA class I molecules with and without C-terminal tags demonstrates that addition of a tag does not abrogate the peptide binding specificity of the original molecule. Both pooled Edman sequencing and mass spectrometric sequencing identified no substantial differences in peptides bound by untailed, 6-HIS-tailed, and FLAG-tailed class I molecules, demonstrating that the peptide specificity of a given molecule is not distorted by either tag. This production methodology bypasses problems with isolation of specific molecules and permits ligand mapping and epitope discovery in a variety of pathogen-infected and tumor cell lines.