Cytomegalovirus infection lengthens the cell cycle of granule cell precursors during postnatal cerebellar development
Cathy Yea Won Sung, Mao Li, Stipan Jonjic, Veronica Sanchez, William J. Britt
Cathy Yea Won Sung, Mao Li, Stipan Jonjic, Veronica Sanchez, William J. Britt
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Research Article Inflammation Neuroscience

Cytomegalovirus infection lengthens the cell cycle of granule cell precursors during postnatal cerebellar development

Abstract

Human cytomegalovirus (HCMV) infection in infants infected in utero can lead to a variety of neurodevelopmental disorders. However, mechanisms underlying altered neurodevelopment in infected infants remain poorly understood. We have previously described a murine model of congenital HCMV infection in which murine CMV (MCMV) spreads hematogenously and establishes a focal infection in all regions of the brain of newborn mice, including the cerebellum. Infection resulted in disruption of cerebellar cortical development characterized by reduced cerebellar size and foliation. This disruption was associated with altered cell cycle progression of the granule cell precursors (GCPs), which are the progenitors that give rise to granule cells (GCs), the most abundant neurons in the cerebellum. In the current study, we have demonstrated that MCMV infection leads to prolonged GCP cell cycle, premature exit from the cell cycle, and reduced numbers of GCs resulting in cerebellar hypoplasia. Treatment with TNF-α neutralizing antibody partially normalized the cell cycle alterations of GCPs and altered cerebellar morphogenesis induced by MCMV infection. Collectively, our results argue that virus-induced inflammation altered the cell cycle of GCPs resulting in a reduced numbers of GCs and cerebellar cortical hypoplasia, thus providing a potential mechanism for altered neurodevelopment in fetuses infected with HCMV.

Authors

Cathy Yea Won Sung, Mao Li, Stipan Jonjic, Veronica Sanchez, William J. Britt

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Figure 7

BrdU-IdU sequential labeling confirms a longer S phase of the cell cycle in MCMV-infected mice.

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BrdU-IdU sequential labeling confirms a longer S phase of the cell cycle...
(A) Schematic of IdU-BrdU dual-labeling protocol to measure the length of S phase (TS). IdU was injected, followed by BrdU injections at 5.5 and 7.5 hours after IdU injection. Brains were then harvested 30 minutes after the BrdU injection on P8. (B) Representative images with color-coded symbols of cerebellar EGL indicate reduced number of cells that exited S phase in MCMV-infected mice during the inter–injection intervals of 6 or 8 hours. IdU+BrdU+ GCPs are population that remained in S phase (yellow solid circle), and IdU+BrdU GCPs are population that left S phase (green solid star). Scale bar: 30 μm. (C) Percentage of GCPs that left S phase was quantified as IdU+/total IdU+BrdU+ GCPs in the EGL. Refer to Table 1 for cell cycle length (S phase). TS was approximately 5.2 hours longer in GCPs in MCMV-infected mice compared with control mice. Data are shown as mean ± SD, n = 4–6 mice/experimental group of the cerebellum. Images of cerebellar fissure are represented as 2 data points. P values were calculated using 2-tailed t test. ***P < 0.001; ****P < 0.0001.