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-) and IFN-␥ transcription were induced 90-and 60-fold, respectively. IFN- levels correlated with the embryo viral burden, while IFN-␥ levels first increased and then decreased. Production of proinflammatory cytokines, interleukin 1 (IL-1) and tumor necrosis factor alpha (TNF-␣), 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. IMPORTANCEInteraction 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. In some respects, the developing mammalian embryo should be paradise for viral pathogens-a rapidly dividing population of potential host cells, expressing all the host metabolic functions the virus needs for its own replication, coupled with a complete absence of adaptive immune responses and an innate response that is considered immature and biased toward tolerance.Despite this, fetal viral infection is not considered a major cause of complications during pregnancy compared, for instance, to the various bacterial infections causing fetal inflammatory response syndrome (1). It seems unlikely that virus is more efficiently excluded from the embryonic compartment than bacteria (2), and several studies have identified viral signal in a significant fraction of embryos or amniotic fluid from normal ...
The P4 promoter of the autonomous parvovirus Minute Virus of Mice (MVM) drives the production of its non-structural proteins, NS1 and NS2. The NS2 isoforms are without enzymatic activity but interact with cellular proteins. While NS2 is crucial to the viral life cycle in cultured murine cells, NS2-null mutant virus productively infects transformed host cells of other species. In the mouse, sensitivity to MVM infection is age dependent, exhibiting limited subclinical infections in adults, but sustained and potentially lethal infection in embryos. We therefore questioned whether the species-dependent requirement for NS2 function in vitro would be retained in utero. We report here that it is not. NS2-null mutant MVMp is capable of mounting a productive, albeit much reduced, infection of normal embryonic mouse cells in vivo. Based on the data, we hypothesize that NS2 may bear an as-yet undescribed immunosuppressive function.
The protoparvovirus early promoters, e.g. P4 of Minute Virus of Mice (MVM), play a critical role during infection. Initial P4 activity depends on the host transcription machinery only. Since this is cell-type dependent, it is hypothesized that P4 is a host cell-type range determinant. Yet host range determinants have mapped mostly to capsid, never P4. Here we test the hypothesis using the mouse embryo as a model system. Disruption of the CRE element of P4 drastically decreased infection levels without altering range. However, when we swapped promoter elements of MVM P4 with those from equivalent regions of the closely related H1 virus, we observed elimination of infection in fibroblasts and chondrocytes and the acquisition of infection in skeletal muscle. We conclude that P4 is a host range determinant and a target for modifying the productive infection potential of the virus - an important consideration in adapting these viruses for oncotherapy.
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