Isolation of a human melanoma adapted Newcastle disease virus mutant with highly selective replication patterns.

The apathogenic Newcastle disease virus (NDV) strain Ulster has been used successfully as an adjuvant component for active specific immunotherapy of malignant mouse lymphoma, and in nude mice it was shown to be able to lead to retardation of the s.c. growth of xenotransplanted human melanoma cells. In order to improve in vivo effectiveness of virotherapy of human tumors without significantly increasing the risk of unspecific viral replication in host cells, we adapted the virus for growth in a human melanoma line (MeWo M). For this purpose NDV Ulster was mutagenized and a variant was selected which could replicate and reinfect the tumor line. The mutant (NDV 1E 10) performed late lysis on the melanoma line. Replication was found to be at least 100 times more efficient in MeWo M than in 6 of 8 other human tumor cell lines of different tissue origin. In 10 of 11 murine cell lines, NDV 1E 10 did not replicate via multicycles. Chick embryonic fibroblasts were permissive for nonlytic replication. Neither the virulent wild-type NDV Italian nor the avirulent strain NDV Ulster shared these specific replication properties with the new variant. We also established MeWo melanoma sublines with different metastatic capacities and tested them as targets for NDV 1E 10 infection. The MeWo subpopulations exhibited comparatively small differences in permissivity for multicyclic replication, but the more metastatic MeWo Met, like allogeneic melanoma lines, was more resistant to lysis. NDV Italian, in contrast, showed no differences in replication and lysis on any of the tested melanoma lines. Trypsin-activation experiments suggested an incomplete cleavage of mutant envelope glycoprotein F by the permissive cell line and, thus, mechanisms of specific infection and replication not requiring fully activated envelope glycoproteins.