Activation of a helper and not regulatory human CD4+ T cell response by oncolytic H-1 parvovirus.

BACKGROUND: H-1 parvovirus (H-1 PV), a rodent autonomous oncolytic parvovirus, has emerged as a novel class of promising anticancer agents, because of its ability to selectively find and destroy malignant cells. However, to probe H-1 PV multimodal antitumor potential one of the major prerequisites is to decipher H-1 PV direct interplay with human immune system, and so prevent any risk of impairment. METHODOLOGY/PRINCIPAL FINDINGS: Non activated peripheral blood mononuclear cells (PBMCs) are not sensitive to H-1 PV cytotoxic effect. However, the virus impairs both activated PBMC proliferation ability and viability. This effect is related to H-1 PV infection as evidenced by Western blotting detection of H-1 PV main protein NS1. However, TCID50 experiments did not allow newly generated virions to be detected. Moreover, flow cytometry has shown that H-1 PV preferentially targets B lymphocytes. Despite seeming harmful at first sight, H-1 PV seems to affect very few NK cells and CD8+ T lymphocytes and, above all, clearly does not affect human neutrophils and one of the major CD4+ T lymphocyte subpopulation. Very interestingly, flow cytometry analysis and ELISA assays proved that it even activates human CD4+ T cells by increasing activation marker expression (CD69 and CD30) and both effective Th1 and Th2 cytokine secretion (IL-2, IFN-γ and IL-4). In addition, H-1 PV action does not come with any sign of immunosuppressive side effect. Finally, we have shown the efficiency of H-1 PV on xenotransplanted human nasopharyngeal carcinoma, in a SCID mouse model reconstituted with human PBMC. CONCLUSIONS/SIGNIFICANCE: Our results show for the first time that a wild-type oncolytic virus impairs some immune cell subpopulations while directly activating a Helper CD4+ T cell response. Thus, our data open numerous gripping perspectives of investigation and strongly argue for the use of H-1 PV as an anticancer treatment.

Ectopic expression of H-1 parvovirus NS1 protein induces alterations in actin filaments and cell death in human normal MRC-5 and transformed MRC-5 SV2 cells.

When grown in human cell lines, oncolytic H-1 parvovirus (H-1PV) replication preferentially occurs in transformed cells, which ultimately die upon infection. H-1PV-induced cytotoxicity is mainly due to P4 promoter-driven NS1 protein expression. Infection of untransformed cells generally does not induce deleterious effects because the P4 promoter is not activated. Here, we show that ectopic CMV-driven NS1 protein expression in normal human MRC-5 cells results in alterations of actin filaments and cell death, and both effects are prevented by a serine 473 mutation. The same substitution preserves actin filaments of transfected MRC-5 SV2 cells, that are MRC-5 transformed counterparts, but does not impair NS1-induced cytotoxicity.

Parvovirus H-1 induces cytopathic effects in breast carcinoma-derived cultures.

Parvovirus H-1 (H-1 PV) preferentially replicates in malignant cells resulting in their death by cytolysis. It has often been considered a potential candidate for use in novel anticancer therapy. To evaluate its potential in a model of natural tumors, we assayed in vitro the effect exerted by H-1 PV on short-term cultures derived from breast tumor samples freshly excised from patients. Our results show that H-1 PV effectively kills tumor-derived cells, whereas normal tissue-derived cells showed no H-1 PV-induced cytopathic effects (CPE). We also determined that the H-1 PV sensitivity (up to 67% sensitive cultures) is related with the quantities of virus assayed. We further examined the expression and phosphorylation state of the parvoviral nonstructural protein 1 (NS1), known to be associated with parvoviruses-induced CPE. Both appear to be impaired in normal tissue-derived cells and resistant cultures. Finally, we show that H-1 PV sensitivity in cultures correlates significantly with higher tumor grades (Nottingham combined histologic grade 2 or 3). This report confirms that H-1 PV can efficiently induce CPE in primary breast tumor cells in vitro. It identifies tumor characteristics representing potential criteria for recruiting patients for clinical evaluation of H-1 PV antitumor effects.

Hypoxic-response elements in the oncolytic parvovirus Minute virus of mice do not allow for increased vector production at low oxygen concentration.

Vectors derived from the autonomous parvovirus Minute virus of mice, MVM(p), are promising tools for the gene therapy of cancer. The validation of their in vivo anti-tumour effect is, however, hampered by the difficulty to produce high-titre stocks. In an attempt to increase vector titres, host cells were subjected to low oxygen tension (hypoxia). It has been shown that a number of viruses are produced at higher titres under these conditions. This is the case, among others, for another member of the family Parvoviridae, the erythrovirus B19 virus. Hypoxia stabilizes a hypoxia-inducible transcription factor (HIF-1alpha) that interacts with a 'hypoxia-responsive element' (HRE), the consensus sequence of which ((A)/(G)CGTG) is present in the B19 and MVM promoters. Whilst the native P4 promoter was induced weakly in hypoxia, vector production was reduced dramatically, and adding HRE elements to the P4 promoter of the vector did not alleviate this reduction. Hypoxia has many effects on cell metabolism. Therefore, even if the P4 promoter is activated, the cellular factors that are required for the completion of the parvoviral life cycle may not be expressed.

An assay for parvovirus B19 neutralizing antibodies based on human hepatocarcinoma cell lines.

BACKGROUND: Although intravenous immune globulin (IVIG) is used widely for managing parvovirus B19 infections, IVIG products are not monitored routinely for the presence of parvovirus B19 neutralizing antibody. STUDY DESIGN AND METHODS: An assay has been developed to measure parvovirus B19 infectivity and neutralization activity based on two hepatocarcinoma cell lines (HepG2 and HuH7). The sources of parvovirus B19 were B19-DNA-containing plasma samples. Neosynthesized progeny in supernatants of infected cells were quantified by nested polymerase chain reaction. To validate the model, purified rabbit antibodies to different capsid protein sequences and IVIG preparations were tested. RESULTS: The number of parvovirus B19 infectious neovirions in supernatants of infected cells increased with infection time. Both rabbit antibodies and IVIG products inhibited parvovirus B19 infectivity when incubated overnight with virus. The efficacy of IVIG to neutralized parvovirus B19 was product-related. CONCLUSION: This assay for parvovirus B19 neutralization activity provides an improved and more specific method for selecting donors to produce IVIG with a high titer of parvovirus B19 neutralizing activity.

Continuous-flow UVC irradiation: a new, effective, protein activity-preserving system for inactivating bacteria and viruses, including erythrovirus B19.

Despite the increasing number of screening tests being introduced, ensuring the inactivation of blood-borne pathogens in blood-derived therapeutic material is a major concern. Dynamic continuous-flow UVC irradiation is a new way to inactivate a large range of pathogens without adding any photosentizers. The efficacy of different methods was evaluated against the following viruses: murine parvovirus MVMp, human B19, the encephalomyocarditis virus (EMC, a picornavirus used as a model for model for hepatitis A virus), and bovine herpes virus type 1 (BHV, a model for enveloped viruses such as hepatitis B virus). We show that continuous-flow UVC irradiation is very effective, particularly against resistant pathogens (e.g. parvoviruses and bacteria) at UVC doses preserving protein activity. It may be applicable to newly emerging related viruses or variants.