Expression of the non-structural proteins of parvovirus MVMp from recombinant retroviruses: predominant role of the parvoviral NS-1 product in host cell disturbance.

Stable Psi-2 cell transformants were selected for their resistance to neomycin after transfection with a retroviral pZipNeo-SVX vector carrying sequences encoding for the non-structural proteins of parvovirus minute virus of mice (prototype strain, MVMp). Cells producing both NS-1 and NS-2 proteins (PsiNS) or only the NS-2 polypeptide (PsiNS2) were obtained. PsiNS cells exhibited morphological abnormalities and had a reduced clone-forming ability, whereas PsiNS2 cells were indistinguishable from the parental line. These cellular systems produced recombinant retroviral particles which transduced the NS gene(s) into mouse A9 cells. As in the case of Psi-2 cells, A9 transformants expressing both NS-1 and NS-2 proteins were impaired in their cloning efficiency. These results provided a direct confirmation of the predominant role of protein NS-1 in the cytopathic effect of parvoviruses.

Susceptibility of human cells to killing by the parvoviruses H-1 and minute virus of mice correlates with viral transcription.

Human fibroblasts and epithelial cells differing in their susceptibility to killing by the autonomous parvoviruses H-1 and minute virus of mice were compared for their capacity to express viral mRNAs and proteins. The transition from a parvovirus-resistant to a parvovirus-sensitive phenotype correlated with a proportional increase in the production of the three major viral transcripts and of structural and nonstructural proteins. In contrast, cell sensitization to parvovirus could not be correlated with detectable changes in virus uptake, intracellular localization of gene products, stability of viral mRNAs, or phosphorylation of viral nonstructural polypeptides. Moreover, the H-1 virus-sensitive keratinocyte line studied did not sustain a greater level of viral DNA amplification than its resistant derivative. Therefore, the differential susceptibility of the human cells tested to parvovirus infection appears to be mainly controlled at the level of transcription of the viral genome. Parvoviral gene expression could not be elevated by increasing the input multiplicity of infection in either of the cell systems analyzed. Together, these data suggest that a cellular factor(s) regulating parvoviral transcription may be modulated by oncogenic transformation or by differentiation, as both features have been shown to affect cell susceptibility to parvoviruses.

Sensitization of transformed rat cells to parvovirus MVMp is restricted to specific oncogenes.

The rat cell line FR3T3 was transformed with the retroviral oncogenes v-myc or v-src, with the DNA tumor viruses SV40 or bovine papilloma virus strain 1 (BPV-1) or with the 69% transforming region of BPV-1. The transformants were compared with the uncloned parental line for their susceptibility to the lytic effect and to the replication of MVMp, an autonomous parvovirus. Expression of v-myc and v-src proteins and of SV40 large T antigen correlated with a greater cell susceptibility to MVMp-induced killing. Thus, the expression of both cytoplasmic and nuclear oncogene products may sensitize rat fibroblasts to MVMp. In contrast, cell lines transformed by BPV-1, including highly tumorigenic and tumor-derived clones, were on the average as resistant as the parental cell line to MVMp infection. A similar resistance to MVMp-induced killing was displayed by BPV-1-transformed NIH3T3 cells. However, supertransformation of one of the BPV-1-transformants by the human EJ-Harvey ras-1 oncogene, known to sensitize FR3T3 and NIH3T3 cells, correlated with an increase in susceptibility to MVMp. Therefore, the failure of BPV-1 transformation to sensitize murine cells to parvoviral attack may be ascribed to the tumor virus rather than to the cells undergoing transformation. Hence, cell sensitization to MVMp appears to be oncogene-specific and cannot be taken as an absolute correlative with neoplastic transformation.

Limitations to the expression of parvoviral nonstructural proteins may determine the extent of sensitization of EJ-ras-transformed rat cells to minute virus of mice.

The FR3T3 and NRK rat cell lines and their human EJ Ha-ras-1 oncogene-transformed derivatives, termed FREJ and NREJ, were compared for their susceptibility to the parvovirus MVMp. For a similar production of p21ras protein, FREJ clones are markedly sensitized to killing by MVMp, whereas the NREJ cells are not. Such a contrasting effect of ras transformation on the sensitivity of cells of different origins to MVMp can be traced back to their respective abilities to support the parvoviral life cycle. The FR3T3 line produces a substantial amount of viral DNA whose expression in the form of the nonstructural protein NS-1 is stimulated in its transformed derivatives. Conversely, NRK cells offer an early block to parvoviral DNA replication and expression that appears to persist in the ras-transformed clones. Thus, at least two intracellular restrictions can protect normal rat cells against MVMp infection, and transformation by ras relieves one of them at the level of parvoviral gene expression. A fair correlation was also found between the degree of sensitivity of the various lines to MVMp-induced killing and their capacity to synthesize the nonstructural viral proteins, suggesting a possible role of parvoviral nonstructural proteins in cytotoxicity.

Inhibition by parvovirus H-1 of the formation of tumors in nude mice and colonies in vitro by transformed human mammary epithelial cells.

The formation of tumors in adult nude mice from transformed human mammary epithelial cells was drastically inhibited (greater than 80%) both after coinjection of tumoral cells and virus or after a single s.c. injection of parvovirus H-1 at the site of cell implantation prior to tumor formation. Moreover, when injected i.v. in animals bearing preformed tumors, H-1 virus was able to slow down and even in some cases to revert neoplastic growth. Thus, H-1 virus achieved the suppression of implanted tumors of human origin under conditions where the immune antitumor mechanisms of the recipient animals were dramatically impaired. Viral infection was not accompanied by detectable deleterious side effects. Imprints of H-1 virus DNA were found in one residual tumor. Normal human mammary epithelial cells were also compared with homologous transformed cells, either derived from tumors (three lines) or containing simian virus 40 (one line), for their susceptibility to the lytic replication of H-1 virus in vitro. Transformed cell lines were more sensitive to virus-induced killing than secondary cultures of normal cells. Moreover, the former had much greater abilities than the latter to amplify viral DNA and to express the viral nonstructural protein NS-1. Altogether, these results are compatible with the idea that the oncosuppressive activity exerted by H-1 virus may be mediated, at least in part, by virus replication in developing tumors.

Transformation of human fibroblasts by ionizing radiation, a chemical carcinogen, or simian virus 40 correlates with an increase in susceptibility to the autonomous parvoviruses H-1 virus and minute virus of mice.

Morphologically altered and established human fibroblasts, obtained either by 60Co gamma irradiation, treatment with the carcinogen 4-nitroquinoline 1-oxide, or simian virus 40 (SV40) infection, were compared with their normal finite-life parental strains for susceptibility to the autonomous parvoviruses H-1 virus and the prototype strain of minute virus of mice (MVMp). All transformed cells suffered greater virus-induced killing than their untransformed progenitors. The cytotoxic effect of H-1 virus was more severe than that of MVMp. Moreover, the level of viral DNA replication was much (10- to 85-fold) enhanced in the transformants compared with their untransformed parent cells. Thus, in this system, cell transformation appears to correlate with an increase in both DNA amplification and cytotoxicity of the parvoviruses. However, the accumulation of parvovirus DNA in the transformants was not always accompanied by the production of infectious virus. Like in vitro-transformed fibroblasts, a fibrosarcoma-derived cell line was sensitive to the killing effect of both H-1 virus and MVMp and amplified viral DNA to high extents. The results indicate that oncogenic transformation can be included among cellular states which modulate permissiveness to parvoviruses under defined growth conditions.