Growth and molecular evolution of vesicular stomatitis serotype New Jersey in cells derived from its natural insect-host: evidence for natural adaptation.

In this study we evaluated the growth and molecular evolution of a natural isolate of VSV-NJ (89GAS) from sand flies in cells derived from sand flies (LL5), mosquitoes (C6/36) or hamsters (BHK21). Two VSV-NJ natural isolates of mammalian origin were used for comparison. For each virus we measured: (i) ability to grow in one-step growth curve or after serial passage on each cell type; (ii) ability to induce persistent infection, and (iii) genetic stability of the glycoprotein gene (G) after serial passage in each cell type. Sand fly virus 89GAS grew to higher titers in insect cells compared with viruses of mammalian origin and showed increasing titers with each passage only in C6/36 cells. All viruses established productive persistent infections in both mosquito and sand fly cells but only LL5 cells yielded sustained high virus titers for periods of up to 81 days. Analyses of the consensus sequences of the G gene from each virus after 0, 10 or up to 25 passages in each cell line showed nucleotide substitution rates between 1.39 x l0(-4) and 6.95 x l0(-5). The majority of these changes were non-synonymous, suggesting positive selection. We did not detect increased nucleotide substitution rates on the G gene of 89GAS after passage in cell lines of mosquito or mammalian origin, nor in viruses of mammalian origin after passage in insect cells. This indicates that although VSV G is positively selected in vitro by the insect cell environment, this does not fully explain VSV natural adaptation. This is the first evidence of naturally occurring adaptation of VSV to cells derived from its natural host.