Progressive multifocal leukoencephalopathy is a demyelinating infection of the immunosuppressed brain, mediated by the gliotropic polyomavirus JCV. JCV replicates in human glial progenitor cells and astrocytes, which undergo viral T-antigen-triggered mitosis, enabling viral replication. We asked whether JCV spread might therefore be accelerated by glial proliferation. Using both in vitro analysis and a human glial chimeric mouse model of JCV infection, we found that dividing human astrocytes supported JCV propagation to a substantially greater degree than did mitotically quiescent cells. Accordingly, bulk and single-cell RNA-sequence analysis revealed that JCV-infected glia differentially manifested cell cycle-linked disruption of both DNA damage response and transcriptional regulatory pathways. In vivo, JCV infection of humanized glial chimeras was greatly accentuated by cuprizone-induced demyelination and its associated mobilization of glial progenitor cells. Importantly, in vivo infection triggered the death of both uninfected and infected glia, reflecting significant bystander death. Together, these data suggest that JCV propagation in progressive multifocal leukoencephalopathy might be accelerated by glial cell division. As such, the accentuated glial proliferation attending disease-associated demyelination might provide an especially favourable environment for JCV propagation, thus potentiating oligodendrocytic bystander death and further accelerating demyelination in susceptible hosts.
Keywords: chimeric mouse; demyelination; oligodendrocyte; polyoma virus; progressive multifocal leukoencephalopathy; stem cell model.
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