Cytomegalovirus vaccination of leukemia and lymphoma patients after allogeneic stem cell transplantation--validation of a peptide vaccine.

Peptide vaccination constitutes a novel immunotherapeutical approach for the treatment of patients with solid tumors, lymphoma and leukemia. Moreover it might be of use in hematooncological patients for the prevention and therapy of infections like cytomegalovirus (CMV) reactivation due to immunosuppression. To meet good manufacturing practice (GMP) criteria, we introduce here a bio-assay to validate peptide vaccines for peptide content and bio-activity. As a paradigm for peptide vaccine preparation the immunogenic CMV peptide 495-503 NLVPMVATV lyophilisate was resolubilized in dimethyl sulfoxide, phosphate buffered saline and admixed with Montanide. Addition of different amounts of peptide (10-80 microg) to a mixed lymphocyte peptide culture (MLPC) resulted in the generation of interferon (IFN) gamma and granzyme B releasing CD8(+) CMV tetramer(+) T cells in a dose dependent manner. The combination of FACS and ELISPOT results allowed the definition of the peptide amount in a vaccine preparation. Storage at +/-4 degrees C over 24 h did not result in a significant change of the immunogenicity of the vaccine. In contrast, cryopreservation of the vaccine at -20 degrees C resulted in a loss of immunogenicity. Quantitation of tumor/viral antigen peptides admixed with adjuvants, such as incomplete Freund's adjuvant (IFA), is feasible through bio-assays as the modified ELISPOT/FACS assay described here, meeting GMP criteria for multi-center trials.

Multimer staining of cytomegalovirus phosphoprotein 65-specific T cells for diagnosis and therapeutic purposes: a comparative study.

BACKGROUND: Cytomegalovirus (CMV) disease represents a serious complication after allogeneic peripheral blood stem cell (PBSC) transplantation. If possible, stem cell donors for transplantation are selected on the basis of their CMV serostatus. However, the cytomegalovirus-specific immune status can be further characterized by measuring CMV phosphoprotein 65-specific CD8(+) T cell frequencies using tetramers, pentamers, and streptamers. We therefore investigated the specificity and sensitivity of all 3 methods and compared the results to patient serostatus. METHODS: Twenty-three samples from CMV-seropositive healthy volunteers and 15 samples from CMV-seropositive patients before and after allogeneic PBSC transplantation were stained with tetramers, pentamers, or streptamers and analyzed by flow cytometry. RESULTS: Similar frequencies of CD8(+) and multimer(+) T cells could be measured by all 3 multimer technologies. The lowest background signals (< or =0.02%) were obtained using tetramer technology. Frequencies of 0.19%-2.48% of CMV phosphoprotein 65 495-503-specific CD8(+) T cells were detected in healthy volunteers. Antigen-specific T cells were detected in only 11 (48%) of 23 seropositive healthy volunteers. CMV antigenemia before day 100 after allogeneic PBSC transplantation occurred in 2 of 3 patients without any specific T cells. CONCLUSION: These findings demonstrate the power of multimer staining and a certain limitation of serologic testing to define appropriate donors for transplantation. Therefore, whenever possible, CMV-seropositive donors of transplants to seropositive recipients should be screened for their CD8(+) T cell frequency. All 3 multimer technologies can be used, yielding similar results. The streptamer technology additionally offers the advantage of selecting CMV phosphoprotein 65-specific CD8(+) T cells at the good manufacturing practice level for adoptive T cell transfer.