Covalent linkage to beta2-microglobulin enhances the MHC stability and antigenicity of suboptimal CTL epitopes.

Many CTL epitopes of clinical importance, particularly those derived from tumor Ags, display relatively poor MHC binding affinity and stability. Because in vivo immunogenicity, and thus the efficacy of peptide-based vaccines, is thought to be determined by MHC/peptide complex stability, there is a need to develop a simple strategy for enhancing the binding of suboptimal epitopes. Toward this goal, the ability to enhance suboptimal peptides through covalent linkage to beta2-microglobulin (beta2m) was explored. Two suboptimal variants of a high-affinity Db-restricted influenza nucleoprotein peptide were covalently linked, via a polypeptide spacer, to the amino terminus of human beta2m and the recombinant fusion proteins expressed in Escherichia coli. When compared with their uncoupled counterparts, the beta2m-linked epitopes display enhanced MHC stabilization and antigenicity. Thus, tethering epitopes to beta2m provides a simple method for augmenting the biological activity of suboptimal peptides and could be useful in the design of peptide-based vaccines or immunotherapeutics.

Creating CTL targets with epitope-linked beta 2-microglobulin constructs.

Eliciting a strong CTL response is dependent upon displaying suitably high levels of specific class I MHC/peptide complexes at the cell surface. In an effort to enhance the presentation of defined CTL target structures, two unique peptide-linked beta 2-microglobulin (beta 2m) molecules were constructed. The first, designated NP(366-374)-L8-h beta 2m, links the carboxyl terminus of the H-2Db-restricted influenza nucleoprotein (NP) epitope NP(366-374) to the amino terminus of h beta 2m through an eight-amino acid glycine/serine linker. The second molecule, designated NP(147-155)-L12-h beta 2m, similarly couples the H-2Kd-restricted influenza NP epitope NP(147-155) to h beta 2m via a 12-residue polypeptide linker. Transfection of the NP(366-374)-L8-h beta 2m vector into H-2b-expressing cell lines sensitized these cells for lysis by NP(366-374)-specific CTLs. Free NP peptide could not be detected when class I bound peptides were acid-extracted from the surface of NP(366-374)-L8-h beta2m transfectants, indicating that CTL killing was mediated by recognition of the peptide linked to h beta 2m and not by a degradation by-product. CTL target structure formation was also achieved by an exogenous presentation pathway. H-2d-expressing target cells were sensitized for lysis when pulsed with NP(147-155)-L12-h beta 2m protein derived from an Escherichia coli cell lysate. The effect of recombinant NP(147-155)-L12-h beta 2m was inhibited by competitor wild-type h beta 2m, indicating that the active peptide-h beta 2m fusion protein remained intact. The observation that beta 2m with covalently attached peptide can effectively create CTL target structures in vitro offers new possibilities for the in vivo induction of epitope-specific CTL responses by either DNA immunization or injection of the purified epitope-linked beta 2m.

Presentation of an influenza nucleoprotein epitope incorporated into the H-2Db signal sequence requires the transporter-associated with antigen presentation.

In an effort to optimize the formation of peptide-specific CTL target structures in the context of plasmid DNA immunization, a strategy was developed to couple the biosynthesis of a class I heavy chain with its optimal binding epitope. Specifically, a cDNA expression vector was constructed with the influenza nucleoprotein epitope NP366-74 incorporated into the signal sequence of its restriction element H-2Db. Transporter associated with Ag presentation-expressing murine cell lines P815 (H-2d) and BW5147 (H-2k) transfected with this modified heavy chain expressed normal levels of plasmid-encoded Db at the cell surface, and were lysed by NP366-74-specific CTL. These results indicate that the modified signal sequence was successfully delivered to the endoplasmic reticulum, and the epitope within it processed for T cell recognition. In contrast, T2 cells, which lack the TAP transporter, when transfected with the same vector were not lysed by NP366-74 CTL, and exhibited an Ag-processing-defective phenotype. Thus, these data, which indicate TAP-dependent presentation of an optimal CTL epitope located in a signal sequence, challenge the effectiveness of Ag processing in the endoplasmic reticulum.