Parvoviruses are inefficient in inducing interferon-β, tumor necrosis factor-α, or interleukin-6 in mammalian cells

To investigate a possible role of cytokines in parvovirus-mediated suppression of tumorigenesis, we tested in cell culture whether parvoviruses are able to induce interferon (IFN)-, tumor necrosis factor (TNF)- or interleukin-6 (IL-6). Infection of rodent or human cells with the parvoviruses minute virus of mice (MVM), H-1 or adeno-associated virus (AAV) types 2 or 5 failed to induce expression of the luciferase or -galactosidase reporter genes transfected into these cells as constructs containing an IFN- promoter. Parvoviruses did weakly induce synthesis of TNF- and of IL-6 in cell culture and could slightly enhance synthesis of these cytokines when induced by other agents. These in vitro data suggest that the rather unspecific tumor-suppressive properties of parvoviruses are unlikely to be attributable to stimulation of the synthesis of IFN, TNF or IL-6.     

Detection of H-1 parvovirus and Kilham rat virus by PCR.

H-1 virus and Kilham rat virus (KRV) are autonomous parvoviruses which generally cause subclinical infections in rats and can cause persistent infections in cell cultures. In this study, primer sets specific for either H-1 or KRV were designed on the basis of DNA sequence comparisons of the rodent parvoviruses. The specificities of the H-1 and KRV-specific primer sets were determined by testing viral preparations of seven different parvoviruses and nine other viruses known to infect rodents. The H-1-specific PCR assay amplified the expected 254-bp product only in the presence of H-1 viral DNA and was able to detect as little as 100 fg of H-1 viral DNA. The KRV-specific PCR assay generated the expected 281-bp product only when KRV viral DNA was used as the template and was able to detect as little as 10 pg of KRV viral DNA. Each assay was able to detect its respective virus in tissues from rats experimentally infected with H-1 or KRV. In contrast, no product was amplified by either assay with tissues from mock-infected rats. Our findings indicate that these PCR assays provide rapid, specific, and sensitive methods for the detection of H-1 or KRV infection in rats and cell culture systems.     

Improving recombinant MVA immune responses: potentiation of the immune responses to HIV-1 with MVA and DNA vectors expressing Env and the cytokines IL-12 and IFN-gamma

Recombinants based on vaccinia virus vectors, especially on the highly attenuated modified vaccinia virus Ankara (MVA) strain, are now being tested in clinical trials for safety and immunogenicity, using prime/boost heterologous regimes of vaccination. Due to the limited replication capacity of MVA, it is necessary to develop procedures that can enhance the specific cellular immune responses to the recombinant antigen delivered by the MVA vector. In this investigation, we have characterized the systemic immune responses in BALB/c mice using interferon-gamma (IFN-gamma) or interleukin-12 (IL-12) in an adjuvant-like manner elicited by MVA recombinants or naked DNA vectors expressing one of those cytokines in combination with the human immunodeficiency virus type 1 (HIV-1) envelope (Env) as antigen. In infected mice, virus gene expression in splenocytes and levels of cytokines IFN-gamma and IL-12 in serum were maximal by 6h post-infection (hpi) with MVA recombinants expressing IFN-gamma (MVAIFN-gamma) or IL-12 (MVAIL-12). In the infected animals, co-expression of HIV-1 env (MVAENV) and either IFN-gamma or IL-12 from MVA recombinants produced a two and three-fold increase of anti-env CD8+ T cell response, respectively. When priming was carried out with DNA vectors expressing HIV-1 env and either IFN-gamma or IL-12, the magnitude of the specific anti-env CD8+ T cell stimulation after MVAENV booster was further enhanced. Our findings revealed that IFN-gamma or IL-12 can be used to potentiate the cellular immune response to HIV-1 env, when delivered either from a single MVA recombinant or from a DNA vector. The increment of the CD8+ T cell response was higher in a DNA/MVA prime/boost protocol. Thus, the immune response of MVA vectors can be improved with the co-delivery of the cytokines IFN-gamma or IL-12.     

The ubiquitin-proteasome machinery is essential for nuclear translocation of incoming minute virus of mice

Minute virus of mice (MVM) infection is disrupted by proteasome inhibitors. Here, we show that inhibition of the ubiquitin-proteasome pathway did not affect viral entry and had influence neither on the natural proteolytic cleavage of VP2 to VP3 nor on the externalization of the N terminal of VP1. In both MG132-treated and untreated cells, MVM particles accumulated progressively in the perinuclear region. However, in MG132-treated cells, MVM was not able to penetrate into the nuclei, remaining blocked in the perinuclear region without capsid disassembly. MVM was similarly sensitive to MG132 in the two cell lines tested, A9 and NB324K. After releasing from the reversible MG132 block, MVM recovered the ability to translocate to the nuclei and replicate. Analysis of viral capsid proteins during internalization showed no evidence of capsid ubiquitination or degradation. We examined the effect of MG132 on two other parvoviruses, canine (CPV) and bovine parvovirus (BPV). Similarly to MVM, CPV infection was sensitive to MG132; however, BPV infection, as previously shown for adeno-associated viruses (AAVs), was not disturbed. These findings suggest that parvoviruses follow divergent strategies for nuclear transport, some of them requiring active proteasomes.     

The parvoviral capsid controls an intracellular phase of infection essential for efficient killing of stepwise-transformed human fibroblasts

Members of the rodent subgroup of the genus Parvovirus exhibit lytic replication and spread in many human tumor cells and are therefore attractive candidates for oncolytic virotherapy. However, the significant variation in tumor tropism observed for these viruses remains largely unexplained. We report here that LuIII kills BJ-ELR 'stepwise-transformed' human fibroblasts efficiently, while MVM does not. Using viral chimeras, we mapped this property to the LuIII capsid gene, VP2, which is necessary and sufficient to confer the killer phenotype on MVM. LuIII VP2 facilitates a post-entry, pre-DNA-amplification step early in the life cycle, suggesting the existence of an intracellular moiety whose efficient interaction with the incoming capsid shell is critical to infection. Thus targeting of human cancers of different tissue-type origins will require use of parvoviruses with capsids that effectively make this critical interaction.     

Parvovirus uncoating in vitro reveals a mechanism of DNA release without capsid disassembly and striking differences in encapsidated DNA stability

The uncoating mechanism of parvoviruses is unknown. Their capsid robustness and increasing experimental data would suggest an uncoating mechanism without capsid disassembly. We have developed an in vitro system to detect and quantify viral DNA externalization and applied the assay on two parvoviruses with important differences in capsid structure, human B19 and minute virus of mice (MVM). Upon briefly treating the capsids to increasing temperatures, the viral genome became accessible in its full-length in a growing proportion of virions. Capsid disassembly started at temperatures above 60 degrees C for B19 and 70 degrees C for MVM. For both viruses, the externalization followed an all-or-nothing mechanism, without transitions exposing only a particular genomic region. However, the heat-induced DNA accessibility was remarkably more pronounced in B19 than in MVM. This difference was also evident under conditions mimicking endosomal acidification (pH 6.5 to 5), which triggered the externalization of B19-DNA but not of MVM-DNA. The externalized ssDNA was a suitable template for the full second-strand synthesis. Immunoprecipitation with antibodies against conformational epitopes and quantitative PCR revealed that the DNA externalized by heat was mostly dissociated from its capsid, however, the low pH-induced DNA externalization of B19 was predominantly capsid-associated. These results provide new insights into parvovirus uncoating suggesting a mechanism by which the full-length viral genome is released without capsid disassembly. The remarkable instability of the encapsidated B19 DNA, which is easily released from its capsid, would also explain the faster heat inactivation of B19 when compared to other parvoviruses.     

Expression patterns of cytokines and chemokines genes in human hepatoma cells

Various cytokines and chemokines play a role in carcinogenesis. However, no study has previously been undertaken to investigate comprehensively the expressions of cytokines and chemokines in hepatoma cells. In this study, we determined which cytokines and chemokines are expressed in hepatoma cells. Recently, it was reported that the expressions of several chemokines could be increased by Fas stimulus in many normal and cancer cells. Therefore, we also investigated whether chemokines expression is regulated by Fas ligation. To address this issue, we performed RNase protection assays upon 13 cytokines and 8 chemokines genes in 10 human hepatoma cell lines, comprising 8 hepatitis B virus (HBV)-associated hepatoma cell lines. Transforming growth factor-beta2 (TGF-beta2) was found to be expressed in 8 HBV-associated hepatoma cell lines, and to be potently expressed in 5 cell lines; however, the mRNA expressions of interleukin-10 (IL-10), IL-12, interferon-gamma(IFN-gamma) and tumor necrosis factor-alpha(TNF-alpha) were not detected in any cell lines examined. Among the chemokines investigated in this study, IL-8 was expressed by 8 HBV- associated hepatoma cell lines, and monocyte chemoattractant protein-1 (MCP-1) by 7 HBV-associated hepatoma cell lines. However, the mRNA expressions of macrophage inflammatory protein-1alpha(MIP-1alpha), MIP-1beta, interferon-inducible protein-10 (IP-10), RANTES, lymphotactin and I-309 were either very weak or undetectable. Fas ligation did not increase chemokines expression in hepatoma cells. Conclusively, TGF-beta2, IL-8 and MCP-1 were overexpressed in HBV-associated hepatoma cells, and the expressions of chemokines were not increased by Fas ligation in human hepatoma cells.     

Expression of human argininosuccinate synthetase after retroviral-mediated gene transfer

The cDNA sequence for human argininosuccinate synthetase (AS) was introduced into plasmid expression vectors with an SV40 promoter or Rous sarcoma virus promoter to construct pSV2-AS and pRSV-AS, respectively, and human enzyme was synthesized after gene transfer into Chinese hamster cells. The functional cDNA was inserted into the retroviral vectors pZIP-NeoSV(X) and pZIP-NeoSV(B). Ecotropic AS retrovirus was produced after calcium-phosphate-mediated gene transfer of these constructions into the packaging cell line -2, and viral liters up to 10⁵ CFU/ml were obtained. Recombinant AS retrovirus was evaluated by detecting G-418-resistant colonies after infection of the rodent cells, XC, NRK, and 3T3. Colonies were also obtained when infected XC cells were selected in citrulline medium for expression of AS activity. Southern blot analysis of infected cells demonstrated that the recombinant retroviral genome was not altered grossly after infecting some rodent cells, while other cells showed evidence of rearrangement. A rapid assay for detecting AS retrovirus was developed based on the incorporation of [¹⁴C]citrulline into protein by intact 3T3 cells or XC cells.     

A colorimetric assay for viral agents that produce cytopathic effects

Many animal viruses produce cytopathic effects in their host cells during a productive infection. While some virus infections can be assayed by the production of plaques, many viruses, while producing cytotoxicity, do not easily form plaques, or do not form plaques at all. Additionally, viruses within families such as the parvoviruses may have different preferred forms of titration making comparative virology difficult even among related groups. Porcine parvovirus (PPV), canine parvovirus (CPV), and minute virus of mice (MVM) are usually titrated using different infectivity assays. A direct comparison of infectious virus titer between these parvoviruses was sought, and a tetrazolium salt assay, MTT has been applied to measure cytopathic effect produced by viral infection for different members of the parvovirus family. Infectious PPV measured using the MTT and the TCID50 assays exhibited excellent correlation and titers for CPV and MVM were consistently duplicated using the MTT assay. The MTT assay was also applied to an unrelated virus, Sindbis, which is routinely titrated by plaque assay. MTT titration of Sindbis virus mutants was found to be valuable for preliminary screening. This assay can be adapted, by correlation to an accepted titration method, to any viral system which produces measurable cytopathic effect.     

Use of replication restricted recombinant vesicular stomatitis virus vectors for detection of antigen-specific T cells

Detection of antigen-specific T cells at the single-cell level by ELISpot or flow cytometry techniques employing intracellular cytokine staining (ICS) is now an indispensable tool in many areas of immunology. When precisely mapped, optimal MHC-binding peptide epitopes are unknown, these assays use antigen in a variety of forms, including recombinant proteins, overlapping peptide sets representing one or more target protein sequences, microbial lysates, lysates of microbially-infected cells, or gene delivery vectors such as DNA expression plasmids or recombinant vaccinia or adenoviruses expressing a target protein of interest. Here we introduce replication-restricted, recombinant vesicular stomatitis virus (VSV) vectors as a safe, easy to produce, simple to use, and highly effective vector for genetic antigen delivery for the detection of human antigen-specific helper and cytotoxic T cells. To demonstrate the broad applicability of this approach, we have used these vectors to detect human T cell responses to the immunodominant pp65 antigen of human cytomegalovirus, individual segments of the yellow fever virus polyprotein, and to various influenza proteins.     

HSV-1-derived recombinant and amplicon vectors for gene transfer and gene therapy

Herpes simplex virus type 1 (HSV-1) is a major human pathogen whose lifestyle is based on a long-term dual interaction with the infected host characterized by the existence of lytic and latent infections. Although in most cell types infection with HSV-1 will induce toxic effects ending in the death of the infected cells, the very deep knowledge we possess on the genetics and molecular biology of HSV-1 has permitted the deletion of most toxic genes and the development of non-pathogenic HSV-1-based vectors for gene transfer. Several unique features of HSV-1 make vectors derived from this virus very appealing for preventive or therapeutic gene transfer. These include (i) the very high transgenic capacity of the virus particle, authorizing to convey very large pieces of foreign DNA to the nucleus of mammalian cells, (ii) the genetic complexity of the virus genome, allowing to generate many different types of attenuated vectors possessing oncolytic activity, and (iii) the ability of HSV-1 vectors to invade and establish lifelong non-toxic latent infections in neurons from sensory ganglia and probably in other neurons as well, from where transgenes can be strongly and long-term expressed. Three different classes of vectors can be derived from HSV-1: replication-competent attenuated vectors, replication-incompetent recombinant vectors, and defective helper-dependent vectors known as amplicons. Each of these different vectors attempts to exploit one or more of the above-mentioned features of HSV-1. In this review we will update the current know-how concerning design, construction, and recent applications, as well as the potential and current limitations of the three different classes of HSV-1-based vectors.     

Replication of minute virus of mice DNA in adenovirus-infected or adenovirus-transformed cells

The effect of adenovirus infection or transformation on the DNA replication of Minute Virus of Mice (MVM) was studied in human fibroblast cell lines. In WI38, HeLa, and 293 cells MVM infection allowed production of viral NS-1 and capsid proteins with or without adenovirus 2 (Ad2) co-infection. However, MVM DNA replication varied markedly. In HeLa cells MVM DNA was replicated weakly in host nucleoli, and replication was increased markedly by Ad2 co-infection as well as recompartmentalized to Ad2 replication factories. In Ad-transformed 293 cells MVM DNA was replicated very efficiently when infected alone or with Ad2 co-infection although recompartmentalization from nucleoli to replication factories was also seen. In WI38 cells MVM DNA was not replicated under any conditions. The variation in DNA replication in WI38, HeLa, and 293 cells despite viral protein production in all cases suggests that MVM DNA replication is uncoupled from viral gene expression and that host factors required for MVM DNA replication are induced or recompartmentalized by adenovirus infection or transformation.     

Characterization of baculovirus-expressed hemagglutinin and fusion glycoproteins of the attenuated measles virus strain AIK-C.

With measles virus cDNA of the avirulent vaccine strain AIK-C, two cDNAs of H or F genes were amplified by the polymerase chain reaction. The amplified cDNAs were inserted respectively to the baculovirus transfer vector pAcYM1 derived from the nuclear polyhedrosis virus of Autographa californica (AcNPV). After co-transfection of the transfer vectors with AcNPV DNA to Spodoptera frugiperda cells, recombinant baculoviruses were screened by plaque assay, and the viruses containing H-cDNA or F-cDNA were named H-AIK or F-AIK, respectively. By Western blot analyses, the band around 80 kDa and some smaller bands were appeared in the H-AIK infected S. frugiperda cells, and the band around 40 kDa was detected in the F-AIK infected cells. Immunofluorescence studies on unfixed S. frugiperda cells infected with H- or F-AIK recombinants showed that both antigens were transported to the cell surface. When green monkey red blood cells were added to the recombinant infected cells, H-AIK infected cells showed haemadsorption, and cells infected with F-AIK lysed the red blood cells. The recombinant proteins elicited the neutralizing antibodies against measles virus.     

A novel method for the titration of recombinant virus stocks by ELISPOT assay

The development of vectors for gene therapy requires the definition of quality control parameters such as titration, contamination, transduction efficiency and biological effects in defined model systems. For most viral vectors, the classical titration by plaque formation is not applicable, because vectors are defective for replication and packaging cell lines are not always available. In particular, for vectors derived from the autonomous parvovirus MVM(p), the titration method used currently is based on the amplification of the viral genome inside an infected cell, which can then be revealed with a specific radioactive probe (J. Virol. 63 (1989) 1023). In situ hybridization allows to titrate wild-type virus as well as vectors, using probes that are specific for the substituted viral genes or for the transgene, respectively. This method is, however, time consuming, making the simultaneous titration of large numbers of samples difficult. The use of a radioactive probe requires an adequate facility. An ELISPOT method that allows for rapid titration of up to 23 vector stocks in one 96 well dish was devised. This method is based on the actual expression of the transgene. Compared to in situ hybridization, titers obtained by the ELISPOT method were in general equivalent or higher. However, for some vector stocks the ELISPOT titers were repeatedly lower, indicating that in situ hybridization does not give an accurate measure of transducing units. Our model system is recombinant parvovirus MVM expressing human IL2, but the method should be adaptable to other vectors expressing transgenes that are secreted and for which antibodies are available.     

Oncolytic parvoviruses. A new approaches for cancer therapy

Parvoviruses such as parvovirus H-1 (H-1PV) may selectively infect and lysis cancer cells. The parvoviruses also induce an immune system to eliminate the tumor cells through the formation of anti-cancer immunity. One of the possible mechanisms of antitumor activity is associated with the direct induction of apoptosis by parvoviral proteins NS1 and 11 kDa. Parvovirus-based vectors are promising for gene therapy of oncological diseases and genetic disorders in humans. Parvoviruses were successfully used for the experimental treatment on animal models of human glioma, neuroblastomas, lymphomas, pancreatic carcinoma, carcinomas and breast tumors. ParvOryx is the first oncolytic preparation constructed on the base of H-1PV; its phase I/IIa clinical trials in patients with glioblastoma multiforme are in process.     

Expression of functional parvoviral NS1 from recombinant vaccinia virus: effects of mutations in the nucleotide-binding motif.

The gene encoding the major replicative protein, NS1, of minute virus of mice (MVM) was transferred into a recombinant vaccinia virus vector in place of the vaccinia thymidine kinase gene. The NS1 gene was placed under control of a bacteriophage T7 promoter and expressed in cells coinfected with another recombinant vaccinia virus, vTF7-3, which encodes the T7 RNA polymerase. Expression of NS1 was further enhanced by the presence of a 5' untranslated region, derived from encephalomyocarditis virus, which allows efficient cap-independent translation. This system was used to produce and analyze wild-type NS1 and two mutant forms of the protein, NS1K405R and NS1K405M, in which the highly conserved lysine codon located in the putative purine triphosphate binding site of NS1 was changed to arginine and methionine, respectively. Full-length NS1 was expressed efficiently in both human and mouse cells infected with each of the three recombinant viruses, and in each case the NS1 was rapidly and efficiently translocated into the nucleus. Wild-type NS1 expressed in this way was biologically active. It was able to trans-activate an MVM P38 promoter located in a host chromosomal site, whereas the two mutant forms of NS1 showed no significant activity in this assay, and it was capable of resolving palindromic junction fragments cloned from multimeric MVM replicative form DNA molecules. These substrates, representing MVM genomic left-end:left-end and right-end:right-end fusions, were resolved in a DNA synthesis-dependent in vitro reaction supplemented with nuclear extracts containing recombinant wild-type NS1. Neither of the two mutant forms of the polypeptide had any detectable activity in this assay.     

Human immunodeficiency virus type 1 envelope-mediated neuropathogenesis: targeted gene delivery by a Sindbis virus expression vector

Sindbis virus (SIN) expression vectors offer the opportunity for studying neuropathogenesis because of their distinct neural cell tropism. Here, we demonstrate that a recombinant SIN vector expressing EGFP (SINrep5-EGFP) infected multiple cell types including neural cells from several species relevant to lentivirus pathogenesis with high levels of transgene expression. Infection of human neurons by a recombinant SIN (SINrep5-JRFL) expressing the full-length envelope from a neurovirulent human immunodeficiency virus type 1 (HIV-1) strain (JRFL) caused increased cytotoxicity compared to infection with SINrep5-EGFP (P < 0.001), while no cytotoxicity was observed among infected human astrocytes or monocytoid cells. Both human monocyte-derived macrophages (MDM) (P < 0.01) and astrocytes (P < 0.001) infected with SINrep5-JRFL released soluble neurotoxins in contrast to SINrep5-EGFP or mock-infected cells, although this was most prominent for the astrocytes. Implantation of SINrep5-JRFL into the brains of SCID/NOD mice induced neuroinflammation, neuronal loss, and neurobehavioral changes characteristic of HIV-1 infection, which were not present in SINrep5-EGFP or mock-infected animals. Thus SIN expression vectors represent novel tools for studying in vitro and in vivo HIV-1 neuropathogenesis because of their high levels of transgene expression in specific cell types within the brain.