Pattern of circulation of MCMV mimicking natural infection upon oronasal inoculation

Luciferase-tagged wild-type and tropism-deficient mouse cytomegaloviruses reveal early dynamics of host colonization following peripheral challenge

Cytomegaloviruses (CMVs) establish persistent, systemic infections and cause disease by maternal-foetal transfer, suggesting that their dissemination is a key target for antiviral intervention. Late clinical presentation has meant that human CMV (HCMV) dissemination is not well understood. Murine CMV (MCMV) provides a tractable model. Whole mouse imaging of virus-expressed luciferase has proved a useful way to track systemic infections. MCMV, in which the abundant lytic gene M78 was luciferase-tagged via a self-cleaving peptide (M78-LUC), allowed serial, unbiased imaging of systemic and peripheral infection without significant virus attenuation. Ex vivo luciferase imaging showed greater sensitivity than plaque assay, and revealed both well-known infection sites (the lungs, lymph nodes, salivary glands, liver, spleen and pancreas) and less explored sites (the bone marrow and upper respiratory tract). We applied luciferase imaging to tracking MCMV lacking M33, a chemokine receptor conserved in HCMV and a proposed anti-viral drug target. M33-deficient M78-LUC colonized normally in peripheral sites and local draining lymph nodes but spread poorly to the salivary gland, suggesting a defect in vascular transport consistent with properties of a chemokine receptor.

Difference in replication of low-passage MCMV HaNa1 in BALB/c, C57BL/6 and NOD mice and role of different branches of immunity in susceptibility

Currently, murine cytomegalovirus (MCMV) infections have been studied extensively in inbred mice via intraperitoneal route with highly passaged strains. However, the question how a low-passage MCMV replicates in inbred mice via a natural route remained unanswered. Here, different inbred mice (BALB/c, C57BL/6 and NOD) were inoculated oronasally with a low-passage MCMV strain, HaNa1. Viral replication was evaluated by virus titration and quantitative real-time PCR, and antibody response was assessed by immunoperoxidase cell monolayer assay (IPMA). In BALB/c mice, virus persisted in nasal mucosa (from 3 dpi) and submandibular glands (from 7 dpi) until the end of experiment (49 dpi). In C57BL/6 mice, infectious virus was only detected in nasal mucosa from 3 dpi until 21 dpi; viral genome was still detectable in nasal mucosa until 49 dpi. Although infectious virus was not detected in submandibular glands of C57BL/6 mice, viral genome was detected from 7 dpi until 49 dpi. NOD mice appeared to be even more resistant with absence of any productive infection; viral genome was detected at low levels in nasal mucosa. We demonstrated that there was a strong correlation between on the one hand degree of productive replication and on the other hand the time of first appearance and titer of MCMV-specific IgG antibody. The deficiency of functional T and B cells and interleukin-2 (IL-2) common-γ chain (γc) did not increase the susceptibility to MCMV by the use of NOD.SCID and NSG mice. In addition, using monocytic cells from different inbred mice we found patterns of resistance similar to those seen in vivo, as assessed by viral antigen expression. Taken together, these results demonstrated that upon oronasal inoculation low-passage MCMV HaNa1 replication clearly differs between different inbred mice (BALB/c>C57BL/6>NOD); resistance in vivo to MCMV is partly due to less susceptibility of host target cells and is independent of T, B cells and γc signaling cytokine-dependent NK cell activities.

MCMV exploits the spleen as a transfer hub for systemic dissemination upon oronasal inoculation

Murine cytomegalovirus (MCMV) infection in mice is a commonly used animal model for studying human cytomegalovirus (HCMV) infections. In our previous studies, a mouse model based on an oronasal MCMV infection was set up for mimicking a natural infection, and the spleen was hypothesized to regulate viremia and virus dissemination to distal organs such as submandibular glands. Here, the role of the spleen during an MCMV infection was investigated by the comparison of intact and splenectomized Balb/c mice. Both highly passaged MCMV Smith and low passaged MCMV HaNa1 were used. Various samples were collected at 7, 14, and 21 days post inoculation (dpi) for analyses by virus isolation/titration, co-cultivation and qPCR. The results showed that for both virus strains, 1) cell-associated virus in PBMC (determined by co-cultivation) was detected in intact mice but not in splenectomized mice; 2) the mean viral DNA load in PBMC of splenectomized mice was 4.4-(HaNa1)/2.7-(Smith) fold lower at the peak viremia (7dpi) in contrast to that of intact mice; and 3) infectious virus in the submandibular glands was detected later in splenectomized mice (14dpi) than in intact mice (7dpi). Moreover, the average virus titers in submandibular glands of splenectomized mice were 10-(HaNa1)/7.9-(Smith) fold lower at 14dpi and 1.7-(HaNa1)/2.1-(Smith) fold lower at 21dpi compared with that of intact mice. Upon inoculation with MCMV Smith, infectious virus was found in the kidneys and liver of intact mice, but not in splenectomized mice. Taken together, all these data clearly demonstrate that virus dissemination to distant organs is reduced in splenectomized mice, further confirming the importance of the spleen as a viremia booming site for a natural MCMV infection.