Immunogenicity and safety of defective vaccinia virus lister: comparison with modified vaccinia virus Ankara.

Potent and safe vaccinia virus vectors inducing cell-mediated immunity are needed for clinical use. Replicating vaccinia viruses generally induce strong cell-mediated immunity; however, they may have severe adverse effects. As a vector for clinical use, we assessed the defective vaccinia virus system, in which deletion of an essential gene blocks viral replication, resulting in an infectious virus that does not multiply in the host. The vaccinia virus Lister/Elstree strain, used during worldwide smallpox eradication, was chosen as the parental virus. The immunogenicity and safety of the defective vaccinia virus Lister were evaluated without and with the inserted human p53 gene as a model and compared to parallel constructs based on modified vaccinia virus Ankara (MVA), the present "gold standard" of recombinant vaccinia viruses in clinical development. The defective viruses induced an efficient Th1-type immune response. Antibody and cytotoxic-T-cell responses were comparable to those induced by MVA. Safety of the defective Lister constructs could be demonstrated in vitro in cell culture as well as in vivo in immunodeficient SCID mice. Similar to MVA, the defective viruses were tolerated at doses four orders of magnitude higher than those of the wild-type Lister strain. While current nonreplicating vectors are produced mainly in primary chicken cells, defective vaccinia virus is produced in a permanent safety-tested cell line. Vaccines based on this system have the additional advantage of enhanced product safety. Therefore, a vector system was made which promises to be a valuable tool not only for immunotherapy for diseases such as cancer, human immunodeficiency virus infection, or malaria but also as a basis for a safer smallpox vaccine.

Rational design, recombinant preparation, and in vitro and in vivo characterization of human prothrombin-derived hirudin antagonists.

A mutant derivative of human prothrombin in which active site aspartate at position 419 is replaced by an asparagine (D419N-prothrombin) has been designed, expressed in recombinant Chinese hamster ovary cells, and purified to homogeneity. D419N-prothrombin was converted to the related molecules D419N-meizothrombin and D419N-thrombin by limited proteolysis by Echis carinatus and Oxyuranus scutellatus venom protease, respectively, and affinity-purified using an immobilized modified C-terminal hirudin-derived peptide. Neither D419N-thrombin nor D419N-meizothrombin exhibited thrombin activity. Titration resulted in no detection of the active site, but binding to the most specific thrombin inhibitor, hirudin, was conserved in both proteins. In vitro examinations showed that D419N-thrombin and D419N-meizothrombin bind to immobilized hirudin, neutralize hirudin in human blood plasma as well as in the purified system, and reactivate the thrombin-hirudin complex. Animal model studies confirmed that D419N-thrombin and D419N-meizothrombin act as hirudin antagonist in blood circulation without detectable effects on the coagulation system. Thus, both D419N-thrombin and D419N-meizothrombin combine for the first time hirudin-neutralizing properties with the advantages of recombinant production of human coagulation factors.