The cytotoxicity of the parvovirus minute virus of mice nonstructural protein NS1 is related to changes in the synthesis and phosphorylation of cell proteins.

Autonomous parvoviruses exert lytic and cytostatic effects believed to contribute to their antineoplastic activity. Studies with inducible clones have demonstrated a direct involvement of parvovirus nonstructural proteins (NS) in oncolysis. Human and rat fibroblasts have been stably transfected with MVM(p) (minute virus of mice prototype strain) NS genes cloned under the control of a hormone-inducible promoter. Dexamethasone-induced synthesis of the NS proteins in sensitive transformed cells results in cell killing within a few days. From these sensitive cell lines have been isolated some NS-resistant clones that also prove resistant to MVM(p) infection, suggesting that cell factors modulate NS cytotoxicity. We have previously reported that factors involved in cell cycle regulation may contribute to this modulation, since NS toxicity requires cell proliferation and correlates with a cell cycle perturbation leading to an arrest in phase S/G2. In addition to its role in cytotoxicity, NS1 can regulate transcription driven by parvovirus and nonparvovirus promoters. Since phosphorylation is a critical event in controlling the activity of many proteins, notably transcription factors and cell cycle-regulated proteins, we have examined the effect of NS1 on the synthesis and phosphorylation of cell proteins. Our results indicate that NS1 interferes, within 7 h of induction, with phosphorylation of a protein of about 14 kDa (p14). Cell synchronization has enabled us to show that phosphorylation of this protein occurs in early S phase and is prevented when NS1 is induced. This early effect of NS1 on p14 phosphorylation may be directly linked to cytotoxicity and is probably related to the previously reported inhibition of cell DNA synthesis. Late in the induction period (24 h), NS1 also alters the synthesis of a 50-kDa protein and a 35-kDa protein (p50 and p35, respectively). Microsequencing of p35 reveals sequence homology with beta-tubulin. These effects of NS1, observed only in NS1-sensitive cell lines, may be related to the protein's cytotoxicity.

The nonstructural proteins of the autonomous parvovirus minute virus of mice interfere with the cell cycle, inducing accumulation in G2.

The nonstructural (NS) proteins of the autonomous parvovirus minute virus of mice (prototype strain) are involved in viral DNA replication and in the regulation of parvoviral and heterologous promoters. By constructing cell lines having integrated the NS coding sequence under the control of an inducible promoter, we were able to demonstrate that NS proteins are toxic, once expressed in the transformed cells. Cell killing appears after several days of NS expression, suggesting that NS toxicity involved cellular factors. In this paper, we show that NS proteins are cytotoxic and interfere with the cell cycle in proliferating cells only NS expression is innocuous in resting cells, whereas in growing cells, it induces the accumulation of G2 cells. This cytostatic effect is enhanced upon neoplastic transformation, which sensitized the cells to NS killing. Moreover, as clones resistant to NS toxicity undergo no alteration of their cycle, this cytostatic effect of NS proteins could be an early step on the way to cell killing. These observations strongly suggest that NS toxicity involves cellular factors associated with the regulation of the cell cycle.