Major histocompatability molecules (MHC) are involved in presentation of peptide antigens for recognition by the immune system. The density and stability of presented peptides is a critical parameter in determining the magnitude of the immune response. Increasing the half-life and density of an MHC class I-peptide complex should promote a stronger cytotoxic T lymphocyte (CTL) response to clinically important peptides, including those that exhibit low or suboptimal MHC class I binding affinity. We hypothesized that the covalent linkage of a known tumor antigen peptide to beta-2-microglobulin (beta2m) would increase peptide immunogenicity and, therefore, in vivo effectiveness as an antitumor vaccine in BALB/c mice. The iL3 peptide fusion protein (iL3-L12-hbeta2m) was developed based on the mutant iL3 peptide, derived from the L3 ribosomal protein, and expressed in the mutagenized murine fibroblastic tumor cell line, BCA34. The iL3-L12-beta2m and a negative control fusion protein utilizing the H-2K(d)-restricted NP(147-155) influenza peptide (NP-L12-hbeta2m) were both produced in E. coli for exogenous antigen presentation by dendritic cells. In vitro, the iL3-L12-hbeta2m protein was found to stabilize H-2K(d) over time on the surface of H-2K(d)-expressing target cells and sensitized them to peptide-specific CTL-mediated lysis. Furthermore, mice immunized with dendritic cells pulsed with the iL3-L12-hbeta2m protein rejected a challenge with BCA34 cells significantly more so than mice immunized with dendritic cells pulsed with free peptide and hbeta2m. We conclude that vaccines incorporating peptides covalently linked to beta2m may have future potential in the specific targeting of human malignancy.