Fetal infections of hamsters, rats, and mice induced with the minute virus of mice (MVM)

Implications of infectious agents on results of animal experiments

Report of the Working Group on Hygiene of the Gesellschaft für Versuchstierkunde–Society for Laboratory Animal Science (GV-SOLAS)

GV-SOLAS Working Group on Hygiene: Werner Nicklas (Chairman), Felix R. Homberger, Brunhilde Illgen-Wilcke, Karin Jacobi, Volker Kraft, Ivo Kunstyr, Michael Mähler, Herbert Meyer & Gabi Pohlmeyer-Esch

Induction of an embryonic mouse innate immune response following inoculation in utero with minute virus of mice

We used an embryonic-infection model system to show that MVMp, the prototypic minute virus of mice (MVM) serotype and a member of the genus Protoparvovirus, triggers a comprehensive innate immune response in the developing mouse embryo. Direct inoculation of the midtrimester embryo in utero with MVMp results in a widespread, productive infection. During a 96-h infection course, embryonic beta interferon (IFN-β) and IFN-γ transcription were induced 90- and 60-fold, respectively. IFN-β levels correlated with the embryo viral burden, while IFN-γ levels first increased and then decreased. Production of proinflammatory cytokines, interleukin 1β (IL-1β) and tumor necrosis factor alpha (TNF-α), also increased, but by smaller amounts, approximately 7-fold each. We observed increased levels of downstream antiviral effector molecules, PKR and phosphorylated STAT2. Finally, we showed that there is an immune cell response to the virus infection. Infected tissues in the embryo exhibited an increased density of mature leukocytes compared to the same tissues in uninfected embryos. The responses we observed were almost completely restricted to the infected embryos. Uninfected littermates routinely exhibited small increases in innate immune components that rarely reached statistical significance compared to negative controls. Similarly, the placentae of infected embryos did not show any significant increase in transcription of innate immune cytokines. Since the placenta has both embryonic and maternal components, we suggest there is minimal involvement of the dam in the response to infection.

IMPORTANCE

Interaction between the small single-stranded vertebrate DNA viruses, the protoparvoviruses, and the host innate immune system has been unclear. The issue is important practically given the potential use of these viruses as oncotherapeutic agents. The data reported here stand in contrast to studies of innate immune response during protoparvovirus infection of adult hosts, which invariably reported no or minimal and sporadic induction of an interferon response during infection. We conclude that under conditions of robust and productive MVM infection, a normal murine host is able to mount a significant and broad innate immune response.

Viral Infections of Laboratory Mice

Viral infections of laboratory mice have considerable impact on research results, and prevention of such infections is therefore of crucial importance. This chapter covers infections of mice with the following viruses: herpesviruses, mousepox virus, murine adenoviruses, polyomaviruses, parvoviruses, lactate dehydrogenase-elevating virus, lymphocytic choriomeningitis virus, mammalian orthoreovirus serotype 3, murine hepatitis virus, murine norovirus, murine pneumonia virus, murine rotavirus, Sendai virus, and Theiler’s murine encephalomyelitis virus. For each virus, there is a description of the agent, epizootiology, clinical symptoms, pathology, methods of diagnosis and control, and its impact on research.

Coping with parvovirus infections in mice: health surveillance and control

Parvoviruses of mice, minute virus of mice (MVM) and mouse parvovirus (MPV), are challenging pathogens to eradicate from laboratory animal facilities. Due to the impediment on rodent-based research, recent studies have focused on the assessment of re-derivation techniques and parvoviral potential to induce persistent infections. Summarizing recent data, this review gives an overview on studies associated with parvoviral impact on research, diagnostic methods, parvoviral persistence and re-derivation techniques, demonstrating the complex nature of parvovirus infection in mice and unfolding the challenge of controlling parvovirus infections in laboratory animal facilities.

Host cell specificity of minute virus of mice in the developing mouse embryo

Productive infection by the murine autonomous parvovirus minute virus of mice (MVM) depends on a dividing cell population and its differentiation state. We have extended the in vivo analysis of the MVM host cell type range into the developing embryo by in utero inoculation followed by further gestation. The fibrotropic p strain (MVMp) and the lymphotropic i strain (MVMi) did not productively infect the early mouse embryo but were able to infect overlapping sets of cell types in the mid- or late-gestation embryo. Both MVMp and MVMi infected developing bone primordia, notochord, central nervous system, and dorsal root ganglia. MVMp exhibited extensive infection in fibroblasts, in the epithelia of lung and developing nose, and, to a lesser extent, in the gut. MVMi also infected endothelium. The data indicated that the host ranges of the two MVM strains consist of overlapping sets of cell types that are broader than previously known from neonate and in vitro infection experiments. The correlation between MVM host cell types and the cell types that activate the transgenic P4 promoter is consistent with the hypothesis that activation of the incoming viral P4 promoter by the host cell is one of the host range determinants of MVM.

The P4 promoter of the parvovirus minute virus of mice is developmentally regulated in transgenic P4-LacZ mice

Activation of the minute virus of mice (MVM) P4 promoter is a key step in the life cycle of the virus and is completely dependent on host transcription factors. Since transcription-factor composition varies widely in different cell types, there is the possibility that only some cell types in the host organism have the capacity to initiate expression from the P4 promoter and therefore that the promoter may be a factor in determining the tropism of MVM. In this study, the ability of various cell types to activate P4, independent of the other virus-host interactions, was examined in transgenic mouse lines bearing a beta-galactosidase reporter sequence driven by the P4 promoter. It was found that lacZ was expressed during embryogenesis and in the adult in a cell-type-specific and differentiation-dependent pattern. The data are consistent with cell-type and stage-specific activation of the P4 promoter having a role in determining the host cell-type range of MVM. The ability of some parvoviruses to replicate in, and kill oncogenically transformed cells, and to destroy induced tumors in laboratory animals is the basis of recent approaches to use MVM-based vectors in cancer gene therapy. Since these vectors rely on the activation of the P4 promoter by the target tissues, understanding the promoter dependence on cell-type and differentiation status is important for their design and potential use.

Detection of minute virus of mice using real time quantitative PCR in assessment of virus clearance during the purification of Mammalian cell substrate derived biotherapeutics

A real time quantitative PCR assay has been developed for detecting minute virus of mice (MVM). This assay directly quantifies PCR product by monitoring the increase of fluorescence intensity emitted during enzymatic hydrolysis of an oligonucleotide probe labelled covalently with fluorescent reporting and quenching dyes via Taq polymerase 5'-->3' exonuclease activity. The quantity of MVM DNA molecules in the samples was determined using a known amount of MVM standard control DNA fragment cloned into a plasmid (pCR-MVM). We have demonstrated that MVM TaqMan PCR assay is approximately 1000-fold more sensitive than the microplate infectivity assay with the lowest detection limit of approximately one particle per reaction. The reliable detection range is within 100 to 10(9) molecules per reaction with high reproducibility. The intra assay variation is <2.5%, and the inter assays variation is <6.5% when samples contain >100 particles/assay. When we applied the TaqMan PCR to MVM clearance studies done by column chromatography or normal flow viral filtration, we found that the virus removal factors were similar to that of virus infectivity assay. It takes about a day to complete entire assay processes, thus, the TaqMan PCR assay is at least 10-fold faster than the infectivity assay. Therefore, we concluded that this fast, specific, sensitive, and robust assay could replace the infectivity assay for virus clearance evaluation.

Parvovirus minute virus of mice strain i multiplication and pathogenesis in the newborn mouse brain are restricted to proliferative areas and to migratory cerebellar young neurons

Newborn BALB/c mice intranasally inoculated at birth with a lethal dose of the immunosuppressive strain of the parvovirus minute virus of mice (MVMi) developed motor disabilities and intention tremors with a high incidence by the day 6 postinfection (dpi). These neurological syndromes paralleled the synthesis of virus intermediate DNA replicative forms and yield of infectious particles in the brain, with kinetics that peaked by this time. The preferred virus replicative sites in the brain were established early in the infection (2 dpi) and at the onset of clinical symptoms (6 dpi) and were compared with major regions of cellular proliferative activity found after intraperitoneal injection of bromodeoxyuridine 24 h before encephalons were subjected to immunohistochemistry detection. At 2 dpi, viral capsid antigen was located in the laterodorsal thalamic and the pontine nuclei but not in the extensive proliferative regions of the mouse brain at this postnatal day. At 6 dpi, however, the neurotropism of the MVMi was highlighted by its ability to target the subventricular zone of the ventricles, the subependymal zone of the olfactory bulb, and the dentate gyrus of the hippocampus, which are the three main germinal centers of the cerebrum in mouse postbirth neurogenesis. Unexpectedly, in the cerebellum, the MVMi capsid antigen was confined exclusively to cells that have undergone mitosis and have migrated to the internal granular layer (IGL) and not to the proliferative external granular layer (EGL), which was stained with antiproliferative cell nuclear antigen antibody and is the main target in other parvovirus infections. This result implies temporal or differentiation coupling between MVMi cycle and neuroblast morphogenesis, since proliferative granules of the EGL should primarily be infected but must migrate in a virus carrier state into the IGL in order to express the capsid proteins. During migration, many cells undergo destruction, accounting for the marked hypocellularity specifically found in the IGL and the irregular alignment of Purkinje cell bodies, both consistent histopathological hallmarks of animals developing cerebellar symptoms. We conclude that MVMi impairs postmitotic neuronal migration occurring in the first postnatal week, when, through the natural respiratory route of infection, the virus titer peaks in the encephalon. The results illustrate the intimate connection between MVMi neuropathogenesis and mouse brain morphogenetic stage, underscoring the potential of parvoviruses as markers of host developmental programs.

Potential detrimental effects of rodent viral infections on long-term experiments

Healthy animals are of paramount importance in obtaining meaningful, reliable scientific results. Viral infections of rodents often have a significant impact on various types of biomedical research. Laboratory animal specialists and researchers must be aware of the possible consequences associated with the use of infected animals. The objective of the paper is a discussion of the frequently encountered viral infections that can complicate or invalidate the interpretation of results by altering the host's response.

Electron microscopic localization of virions in developing teeth of young hamsters infected with minute virus of mice

Virus particles were detected within the nuclei and cytoplasm of odontogenic cells in the developing teeth of young hamsters infected with a small DNA virus (MVM). Disturbances of normal cytodifferentiation and organogenesis occurred as a result of viral multiplication. Virions were also observed in dense lysosome-like bodies of activated monocytes within the periodontal ligament and adjacent connective tissues. Fibrolytic and osteolytic lesions in the periodontal ligament and adjacent alveolar bone were associated with the inflammatory cell infiltrate.

Infection of newborn and fetal hamsters induced by inoculation of LuIII parvovirus

The LuIII parvovirus was adapted to the newborn hamster and produced a systemic infection with massive intestinal hemorrhage. Inoculation of pregnant hamsters lead to transplacental infection of the fetuses and abortion. Most fetal deaths were observed in animals inoculated on days 8 and 10 of gestation. Virus was recovered from dead fetuses, placentas, and viable fetuses. Histological lesions were found in the heart, liver, kidney and CNS of infected fetuses.

Hemorrhagic necrosis of the central nervous system. A spontaneous disease of fetal hamsters

During studies of transplacental virus infections in random bred hamsters purchased with timed pregnancies from three commercial dealers, spontaneous hemorrhagic necrosis of the central nervous system was seen in fetuses harvested near term. Ninety-seven pregnant hamsters from three colonies were examined during a 6-month period; this condition was seen in 25 of 41, 19 of 36, and five of 20 litters. Hamsters from another commercial colony were received, housed, and fed under the same conditions, but remained free of the disease. The pathological process was characterized by multiple spreading zones of edema, malacia, and hemorrhage. Lesions were restricted to neural tissues, including the retina and internal ear. Neuroepithelial proliferation with rosette formation, accompanying the destructive process, constituted a striking reparative response. No inflammatory reaction or cytopathic effects suggestive of virus-induced disease were seen. Studies on the cause of this condition were negative at the time when the disease disappeared spontaneously.

Susceptibility of fertilized mouse eggs to minute virus of mice

Fertilized two-celled mouse eggs deprived of their zona pellucida were susceptible to infection with minute virus of mice. The virus had no deleterious effect on development of embryos cultivated in vitro.