Vesicular Egress of Non-Enveloped Lytic Parvoviruses Depends on Gelsolin Functioning

The autonomous parvovirus Minute Virus of Mice (MVM) induces specific changes in the cytoskeleton filaments of infected permissive cells, causing in particular the degradation of actin fibers and the generation of “actin patches.” This is attributed to a virus-induced imbalance between the polymerization factor N-WASP (Wiscott-Aldrich syndrome protein) and gelsolin, a multifunctional protein cleaving actin filaments. Here, the focus is on the involvement of gelsolin in parvovirus propagation and virus-induced actin processing. Gelsolin activity was knocked-down, and consequences thereof were determined for virus replication and egress and for actin network integrity. Though not required for virus replication or progeny particle assembly, gelsolin was found to control MVM (and related H1-PV) transport from the nucleus to the cell periphery and release into the culture medium. Gelsolin-dependent actin degradation and progeny virus release were both controlled by (NS1)/CKIIα, a recently identified complex between a cellular protein kinase and a MVM non-structural protein. Furthermore, the export of newly synthesized virions through the cytoplasm appeared to be mediated by (virus-modified) lysomal/late endosomal vesicles. By showing that MVM release, like entry, is guided by the cytoskeleton and mediated by vesicles, these results challenge the current view that egress of non-enveloped lytic viruses is a passive process

The NS1 protein of the autonomous parvovirus minute virus of mice blocks cellular DNA replication: a consequence of lesions to the chromatin?

The nonstructural protein NS1 of the autonomous parvovirus minute virus of mice interferes with cell division and can cause cell death, depending on the cell transformation state. Upon infection, the synthesis of NS1 protein is massively initiated during S phase. In this article, we show that minute virus of mice-infected cells accumulate in this phase. To investigate the link between NS1 accumulation and S-phase arrest, we have used stably transfected cells in which NS1 expression is under the control of a glucocorticoid-inducible promoter (the long terminal repeat of mouse mammary tumor virus). NS1 expression interferes with cell DNA replication, and consequently, the cell cycle stops in S phase. NS1 expression also induces nicks in the cell chromatin, as detected by an in situ nick translation assay. The nicks are observed several hours before any cell cycle perturbation. As cell cycle arrest is a common consequence of DNA damage, we propose that NS1 exerts its cytostatic activity by inducing lesions in cell chromatin

The cytotoxicity of the autonomous parvovirus minute virus of mice nonstructural proteins in FR3T3 rat cells depends on oncogene expression.

The nonstructural (NS) proteins of the autonomous parvovirus minute virus of mice are involved in viral DNA replication and in the regulation of homologous and heterologous promoters. Moreover, NS products have proved to be cytotoxic, especially for transformed cells. We show here that intracellular accumulation of NS products is not sufficient to kill rat fibroblasts from the established cell line FR3T3, which is phenotypically normal in several respects. FRNS cell lines were obtained by stable transfection of FR3T3 cells by a vector carrying the NS genes under the control of the hormone-inducible long terminal repeat promoter of the mouse mammary tumor virus. In the presence of dexamethasone, the NS proteins were synthesized without associated cell death. Transformation of FRNS cells with the c-Ha-ras oncogene or polyomavirus oncogenes had little effect on their capacity for NS induction, as measured at both concentration and transactivating activity levels, yet the transformants were now dying within a few days in the presence of the inducer. The same results were obtained with cells stably transfected by a vector expressing the NS1 product alone, suggesting that in this system there is no cooperation between NS1 and NS2 for maximal cytopathic effect. Cell mortality after NS protein induction was quantitatively related to the yield of oncogene expression, while NS-1 was not limiting in this respect. Our results show that the NS1 protein is not lethal unless cellular factors that may depend on oncogene expression trigger its cytotoxicity

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

Programmed killing of human cells by means of an inducible clone of parvoviral genes encoding non-structural proteins.

Although its dependence on the target cell type is well established, the cytopathogenicity of parvoviruses has remained elusive to date as far as its mechanism is concerned. However, indirect evidence suggested that parvoviral non-structural (NS) proteins may be the cytotoxic effectors. In order to test this hypothesis, a molecular clone of parvovirus MVMp was modified, by replacing the P4 promoter of the NS transcription unit by the glucocorticoid-inducible promoter of the mouse mammary tumour virus. Clones of neoplastic human cells that had incorporated this construct and that were induced to produce NS proteins by dexamethasone, showed a cytopathic effect and eventually died. Our data strongly suggest that the intracellular accumulation of parvoviral NS products jeopardizes the survival of the cells, which cannot be detected unless a threshold protein concentration is reached. Interestingly, a cell variant could be isolated which resisted dexamethasone-induced killing, although it was fully inducible for the production of NS proteins. This variant was also unusually resistant to infection with MVMp virions, thus confirming the essential role played by the NS proteins in the parvoviral cytotoxicity and indicating that the cytocidal activity of the parvoviral NS products is modulated by cellular factors that may vary from one cell to another