A fragment of the simian virus 40 early genome can induce tumors in nude mice.

Cell lines transformed by simian virus 40 mutant F8dl (deleted from 0.168 to 0.424 map units, corresponding to the carboxy-terminal 62% of the wild-type simian virus 40 large tumor antigen) are tumorigenic in nude mice. Four of five C3H10T1/2 cell lines transformed by F8dl were tumorigenic in nude mice, whereas two of two wild-type transformants were tumorigenic.

Simian virus 40 sequences between 0.168 and 0.424 map units are not required for abortive transformation.

We have isolated a simian virus 40 deletion mutant, F8dl, that lacks the sequences from 0.168 to 0.424 map units. The deleted sequences represent over 60% of the coding region for large T antigen. Despite this deletion, F8dl abortively transformed rat cells as efficiently as wild-type simian virus 40. From this result, we conclude that the region of the simian virus 40 genome between 0.168 and 0.424 map units is not essential for abortive transformation. Since abortive transformation requires the expression of the simian virus 40 maintenance functions, we also infer that the sequences deleted from F8dl are not required to maintain transformation.

Stabilization of the 53,000-dalton nonviral tumor antigen is not required for transformation by simian virus 40.

We have isolated a simian virus 40 deletion mutant, F8dl, that lacks the sequences from 0.168 to 0.424 map units. The deleted sequences represent about one-half of the coding region for large T antigen. We present evidence here that F8dl is able to transform mouse cells in a focus assay and that cell lines derived from these foci exhibit fully transformed phenotypes, have integrated mutant genomes, and express mutant-encoded proteins. This result implies that the region of the simian virus 40 genome between 0.168 and 0.424 map units is not essential for the maintenance of transformation. In addition, we have found that cells fully transformed by F8dl produce a 53,000-dalton nonviral tumor antigen (p53) that is as unstable as the p53 of untransformed cells. From this result we infer that transformation by simian virus 40 does not require the stabilization of p53.

Efficient infection of monkey cells with SV40 DNA. II. Use of low-molecular-weight DEAE-dextran for large-scale experiments.

With standard protocols for DNA infection, only a small percentage (about 4%) of monkey ells exposed to purified DNA of simian virus 40 (SV40) displays cytopathic effect or expresses viral T antigen. We have recently reported (Sompayrac and Danna, 1981) that by extending the time of exposure of BSC-1 cells to DNA in the presence of low concentrations of diethylaminoethyl (DEAE)-dextran, we can infect up to 50% of the cells. Because our protocol was devised for DEAE-dextran of mol. wt. 2 X 10(6), which is no longer commercially available, we have tested a low-molecular-weight polymer (mol. wt. 0.5 X 10(6) that can be purchased. Use of this reagent in our protocol resulted in marginally higher levels of infection than we found with the high-molecular-weight polymer. However, slightly more DNA (about 1.5 times as much) was needed to achieve saturation. With both reagents, the percentage of cells infected was proportional to time of exposure. Therefore, low-molecular-weight DEAE-dextran should be useful for large-scale DNA infections.

Isolation and characterization of simian virus 40 early region deletion mutants.

We constructed a tsB4/dl884 double-mutant helper virus and used it to isolate two simian virus 40 early region deletion mutants that lack about half of the DNA sequences normally used to encode the large tumor antigen (T). Both mutants make a normal-sized small t antigen, but neither mutant can replicate its DNA in the absence of a T+ helper.

Efficient infection of monkey cells with DNA of simian virus 40.

With standard protocols for DNA infection, only a small fraction (about 4%) of monkey cells exposed to purified DNA of simian virus 40 (SV40) exhibits signs of infection. We have devised a protocol by which we can extend the time of exposure of BSC-1 cells to DNA in the presence of low concentrations of DEAE-dextran. The efficiency of infection is proportional to the time of exposure. With an 8-hr exposure, we are reproducibly able to infect 25% of the cells, and we have been able to achieve levels of infection as high as 50% with a 16-hr exposure. The percentage of cells infected was measured either by scoring for nuclei positive for SV40 tumor antigen or by an infectious centers assay. We also report the use of ethidium bromide as a nonspecific nuclear counterstain in the immunofluorescence assay for SV40 tumor antigen.