Susceptibility of laboratory mice to intranasal and contact infection with coronaviruses of other species

The susceptibility of laboratory mice to intranasal and contact infection with mouse hepatitis virus (MHV)-related coronaviruses was tested in infant CD1 mice. One day old mouse pups were inoculated intranasally with respiratory MHV-S, enteric MHV-Y, rat sialodacryoadenitis virus (SDAV), human coronavirus OC43 (HCV-OC43) or bovine coronavirus (BCV). Twenty-four hours later, they were placed in direct contact with age matched sham inoculated pups. Indices of infection in virus inoculated mice included lesions by histopathology and viral antigen by immunoperoxidase histochemistry in brain, lung, liver and intestine at 3 days after inoculation. Indices of infection in contact mice included mortality or seroconversion by 21 days after exposure. Infant mice were susceptible to infection with all five viruses. Transmission by direct contact exposure occurred with MHV and SDAV, but not HCV or BCV. Furthermore, adult mice were not susceptible to infection with HCV. Tissue distribution of lesions and antigen varied markedly among viruses, indicating that they do not induce the same disease as MHV. This study demonstrates that although these coronaviruses are antigenically closely related, they are biologically different viruses and disease patterns in susceptible infant mice can be used to differentiate viruses.     

Transmission of sialodacryoadenitis virus (SDAV) from infected rats to rats and mice through handling, close contact, and soiled bedding.

Thirty mice and six rats were exposed through handling, soiled bedding, or close contact to rats previously inoculated with sialodacryoadenitis virus (SDAV). All exposed rats developed coronaviral antibody without clinical signs or lesions of SDAV infection. Exposed mice had no lesions or clinical signs of coronavirus infection. Mice exposed by handling or by soiled bedding did not develop coronavirus antibody. Two of 10 mice exposed to SDAV-inoculated rats by close contact were coronavirus seropositive when tested 3 weeks postexposure. SDAV-inoculated rats and mice developed coronavirus lesions and antibody. These results suggest that rat-to-rat transmission of SDAV is likely via fomites or handling; however, rat-to-mouse transmission is unlikely when animals are housed and husbanded using modern techniques. Results also suggest that coronavirus antibody in mice is due to exposure to mouse coronavirus and not to rat coronaviruses.     

Susceptibility of laboratory and domestic animals to experimental infection with Potiskum virus

The biological characteristics of Potiskum virus, a hitherto undescribed virus isolated in Nigeria from the liver of a giant rat (Cricetomys gambianus), were studied by experimental infections of laboratory and domestic animals. The laboratory animal hosts used included mice, rats, rabbits and chicks. Suckling and weaning mice succumbed to fatal infection when infected with Potiskum virus by intracerebral or intraperitoneal routes. Infected mice had high titres of virus and mild histopathological lesions which were confined to the brain. Chicks also developed a fatal disease following subcutaneous or oral infections with Potiskum virus. In contrast, albino rats and rabbits failed to succumb to overt disease by subcutaneous and intraperitoneal routes of inoculation. Albino rats did not develop antibody but rabbits developed haemagglutination inhibiting, neutralising and complement fixing antibodies.     

Persistent airway hyperresponsiveness after neonatal viral bronchiolitis in rats.

Viral bronchiolitis in human infants has been associated with permanent changes in small airways and gas exchange and an increased incidence of hyperresponsive airways later in life. Respiratory infection by Sendai virus in neonatal rats also has been reported to cause permanent changes in lung morphology and increased numbers of bronchiolar mast cells and eosinophils. We evaluated pulmonary mechanics, gas exchange, and airway responsiveness in rats at 7 and 13-16 wk after neonatal Sendai virus infection. Rats from the virus group had lower arterial PO2 and increased total lung resistance compared with controls. There were no significant differences between groups for arterial PCO2, dynamic lung compliance, quasi-static respiratory system compliance, or vital capacity. Rats from the infected group were significantly more sensitive to aerosolized methacholine than were controls, although both virus and control groups became less sensitive with age. We conclude that neonatal Sendai virus infection in rats results in persistent alterations in lung function and airway responsiveness. This phenomenon may be valuable for the study of the relationships among airway inflammation, lung morphology, and airway hyperresponsiveness, and it may be relevant to human airway disease.     

Epizootiological observations of natural and experimental infection with sialodacryoadenitis virus in rats

The epizootiology of sialodacryoadenitis (SDA) was studied in experimentally and naturally infected rats. The infectivity of SDA virus (SDAV) in intranasally infected rats was lost by seven days after infection as determined by contact transmission. After experimental infection, SN antibody appeared earlier and titers were detectable longer than CF antibody. The prevalence of SN antibody-positive rats in naturally infected colonies remained high, whereas an increase in the prevalence of CF antibody-positive rats appeared to coincide with the introduction or resurgence of SDAV. A SDAV-free colony was established by allowing recovered dams to litter in a separate room. A spontaneous cessation of SDAV infection also was observed in an enzootically-infected colony. Clinical observations indicated that SDA can occur as a mild or asymptomatic disease, and that its clinical expression may vary from one inbred strain to another.     

The cotton rat (Sigmodon hispidus) is a permissive small animal model of human metapneumovirus infection, pathogenesis, and protective immunity

Human metapneumovirus (hMPV) is a newly described paramyxovirus that is an important cause of acute respiratory tract disease. We undertook to develop a small animal model of hMPV infection, pathogenesis, and protection. Hamsters, guinea pigs, cotton rats, and nine inbred strains of mice were inoculated intranasally with hMPV. The animals were sacrificed, and nasal and lung tissue virus yields were determined by plaque titration. None of the animals exhibited respiratory symptoms. The quantity of virus present in the nasal tissue ranged from 4.6 x 10(2) PFU/gram tissue (C3H mice) to greater than 10(5) PFU/gram (hamster). The amount of virus in the lungs was considerably less than in nasal tissue in each species tested, ranging from undetectable (<5 PFU/g; guinea pigs) to 1.8 x 10(5) PFU/gram (cotton rat). The peak virus titer in cotton rat lungs occurred on day 4 postinfection. hMPV-infected cotton rat lungs examined on day 4 postinfection exhibited histopathological changes consisting of peribronchial inflammatory infiltrates. Immunohistochemical staining detected virus only at the luminal surfaces of respiratory epithelial cells throughout the respiratory tract. hMPV-infected cotton rats mounted virus-neutralizing antibody responses and were partially protected against virus shedding and lung pathology on subsequent rechallenge with hMPV. Viral antigen was undetectable in the lungs on challenge of previously infected animals. This study demonstrates that the cotton rat is a permissive small animal model of hMPV infection that exhibits lung histopathology associated with infection and that primary infection protected animals against subsequent infection. This model will allow further in vivo studies of hMPV pathogenesis and evaluation of vaccine candidates.     

新型H7N9病毒在同居小鼠中的传播途径

目的进一步了解新型H7N9流感病毒的致病性、传播能力以及通过何种途径进行传播。方法 H7N9病毒感染小鼠后与同居小鼠合笼,研究同居小鼠的临床变化指征、病毒复制情况、病毒在组织中的分布以及病理变化。以同居小鼠分泌物接种其他小鼠,观察同居小鼠通过何种途径传播病毒。结果 H7N9病毒可以在肺组织、肠组织和脑组织中复制,并可以在同居小鼠中传播。H7N9病毒感染小鼠其咽、眼分泌物以及粪便均具有感染性,其中尤以咽拭子的传播风险最高。结论 H7N9病毒可以不通过适应就感染小鼠,并引起小鼠间传播。被感染小鼠分泌物具有感染性。     

Immunofluorescence for detection of viral antigen in mice infected with Sendai virus

Sendai virus infection transmitted by contact from cagemates was followed by virus titration and immunofluorescence. The virus grew in the respiratory tract and caused macroscopic lesions in all contact mice. The virus grew to a higher titer in the lung than in the trachea. Tracheal smears, however, were found to be the most suitable for the diagnosis of Sendai virus infection by immunofluorescence, since they contained a large number of cells with intense fluorescence. Diagnosis of Sendai virus infection was made by immunofluorescence within a few hours after autopsy made at early stages of infection.     

In Situ Evolution of Virus-Specific Cytotoxic T Cell Responses in the Lung

Cytotoxic T cells (CTL) play a critical role in the clearance of respiratory viral infections, but they also contribute to disease manifestations. In this study, we infected mice with a genetically modified pneumonia virus of mice (PVM) that allowed visualization of virus-specific CTL and infected cells in situ. The first virus-specific T cells entered the lung via blood vessels in the scattered foci of PVM-infected cells, which densely clustered around the bronchi at day 7 after infection. At this time, overall pulmonary virus load was maximal, but the mice showed no overt signs of disease. On days 8 to 9, T cells gained access to the infected bronchial epithelium and to the lung interstitium, which was associated with a reduction in the number of virus-infected cells within the initial clusters but could not prevent further virus spread throughout the lung tissue. Interestingly, recruitment of virus-specific CTL throughout the parenchyma was still ongoing on day 10, when the virus infection was already largely controlled. This also represented the peak of clinical disease. Thus, disease was associated with an exuberant T cell infiltration late in the course of the infection, which may be required to completely eliminate virus at residual foci of infection. PVM-induced immunopathology may thus result from the need to generate widespread T cell infiltrates to complete the elimination of virus-infected cells in a large organ like the lung. This experimental model provides the first insights into the spatiotemporal evolution of pulmonary antiviral T cell immunity in vivo.     

Illumination of parainfluenza virus infection and transmission in living animals reveals a tissue-specific dichotomy

The parainfluenza viruses (PIVs) are highly contagious respiratory paramyxoviruses and a leading cause of lower respiratory tract (LRT) disease. Since no vaccines or antivirals exist, non-pharmaceutical interventions are the only means of control for these pathogens. Here we used bioluminescence imaging to visualize the spatial and temporal progression of murine PIV1 (Sendai virus) infection in living mice after intranasal inoculation or exposure by contact. A non-attenuated luciferase reporter virus (rSeV-luc(M-F*)) that expressed high levels of luciferase yet was phenotypically similar to wild-type Sendai virus in vitro and in vivo was generated to allow visualization. After direct intranasal inoculation, we unexpectedly observed that the upper respiratory tract (URT) and trachea supported robust infection under conditions that result in little infection or pathology in the lungs including a low inoculum of virus, an attenuated virus, and strains of mice genetically resistant to lung infection. The high permissivity of the URT and trachea to infection resulted in 100% transmission to naïve contact recipients, even after low-dose (70 PFU) inoculation of genetically resistant BALB/c donor mice. The timing of transmission was consistent with the timing of high viral titers in the URT and trachea of donor animals but was independent of the levels of infection in the lungs of donors. The data therefore reveals a disconnect between transmissibility, which is associated with infection in the URT, and pathogenesis, which arises from infection in the lungs and the immune response. Natural infection after transmission was universally robust in the URT and trachea yet limited in the lungs, inducing protective immunity without weight loss even in genetically susceptible 129/SvJ mice. Overall, these results reveal a dichotomy between PIV infection in the URT and trachea versus the lungs and define a new model for studies of pathogenesis, development of live virus vaccines, and testing of antiviral therapies.     

Viral respiratory infection increases susceptibility of young rats to hypoxia-induced pulmonary edema

Recentclinical observations of a high incidence of preexisting respiratoryinfections in pediatric cases of high-altitude pulmonary edema promptedus to ask whether such infections would increase the susceptibility tohypoxia-induced pulmonary edema in young rats. We infected weanlingrats with Sendai virus, thus causing a mild respiratory infection.Within 7 days of infection, Sendai virus was essentially undetectableby using viral culture and immunohistochemical techniques. Animals atday 7 of Sendai virus infection werethen exposed to normobaric hypoxia (fraction of inspiredO₂ = 0.1) for 24 h and examinedfor increases in gravimetric lung water and in vascular permeability,as well as for histological evidence of increased lung water.Bronchoalveolar lavage was performed on a separate series of animals.Compared with control groups, infected hypoxic animals showedsignificant increases in perivascular cuffing, gravimetric lung water,and lung protein leak. In addition, infected hypoxic animals hadincreases in lavage fluid cell counts and protein content compared withcontrols. We conclude that young rats, exposed to moderate hypoxiawhile recovering from a mild viral respiratory infection, maydemonstrate evidence of early pulmonary edema formation, a finding ofpotential relevance to human high-altitude pulmonary edema.

     

Leukemogenicity and cell transformation mechanisms in vitro by Gross murine leukemia virus: analysis of virus subpopulations.

The leukemogenic activity of Gross murine leukemia virus adapted to rats was tested in W/Fu rats and NIH/Swiss mice. All animals infected with this virus developed thymic and nonthymic T-cell leukemia with a short latency period. It was observed that cell-free extracts from thymic lymphoma tissue of mice and rats, induced by either Gross murine leukemia virus or Gross murine leukemia virus adapted to rats, consisted of both small-plaque-forming and large-plaque-forming viruses, as determined by the XC plaque test. MCF-type virus was found in these virus complexes. Transformed cell foci were induced in SC-1 cell layers by double infection of the cloned MCF-type virus and an ecotropic virus. SC-1 cells containing transformed cell foci were shown to be tumorigenic upon inoculation into nude mice. The formation of transformed cell foci in mink lung cells was also observed after double infection with the cloned MCF-type virus and a xenotropic virus. The possible mechanism of leukemogenesis by endogenous viruses is discussed.     

Persistent rat virus infection in smooth muscle of euthymic and athymic rats

Rat virus (RV) infection can cause disease or disrupt responses that rely on cell proliferation. Therefore, persistent infection has the potential to amplify RV interference with research. As a step toward determining underlying mechanisms of persistence, we compared acute and persistent RV infections in infant euthymic and athymic rats inoculated oronasally with the University of Massachusetts strain of RV. Rats were assessed by virus isolation, in situ hybridization, and serology. Selected tissues also were analyzed by Southern blotting or immunohistochemistry. Virus was widely disseminated during acute infection in rats of both phenotypes, whereas vascular smooth muscle cells (SMC) were the primary targets during persistent infection. The prevalence of virus-positive cells remained moderate to high in athymic rats through 8 weeks but decreased in euthymic rats by 2 weeks, coincident with seroconversion and perivascular infiltration of mononuclear cells. Virus-positive pneumocytes and renal tubular epithelial cells also were detected through 8 weeks, implying that kidney and lung excrete virus during persistent infection. Viral mRNA was detected in SMC of both phenotypes through 8 weeks, indicating that persistent infection includes virus replication. However, only half of the SMC containing viral mRNA at 4 weeks stained for proliferating cell nuclear antigen, a protein expressed in cycling cells. The results demonstrate that vasculotropism is a significant feature of persistent infection, that virus replication continues during persistent infection, and that host immunity reduces, but does not eliminate, infection.     

Allergic Airway Disease in Mice Alters T and B Cell Responses during an Acute Respiratory Poxvirus Infection

Pulmonary viral infections can exacerbate or trigger the development of allergic airway diseases via multiple mechanisms depending upon the infectious agent. Respiratory vaccinia virus transmission is well established, yet the effects of allergic airway disease on the host response to intra-pulmonary vaccinia virus infection remain poorly defined. As shown here BALB/c mice with preexisting airway disease infected with vaccinia virus developed more severe pulmonary inflammation, higher lung virus titers and greater weight loss compared with mice inoculated with virus alone. This enhanced viremia was observed despite increased pulmonary recruitment of CD8⁺ T effectors, greater IFNγ production in the lung, and high serum levels of anti-viral antibodies. Notably, flow cytometric analyses of lung CD8⁺ T cells revealed a shift in the hierarchy of immunodominant viral epitopes in virus inoculated mice with allergic airway disease compared to mice treated with virus only. Pulmonary IL-10 production by T cells and antigen presenting cells was detected following virus inoculation of animals and increased dramatically in allergic mice exposed to virus. IL-10 modulation of host responses to this respiratory virus infection was greatly influenced by the localized pulmonary microenvironment. Thus, blocking IL-10 signaling in virus-infected mice with allergic airway disease enhanced pulmonary CD4⁺ T cell production of IFNγ and increased serum anti-viral IgG1 levels. In contrast, pulmonary IFNγ and virus-specific IgG1 levels were reduced in vaccinia virus-treated mice with IL-10 receptor blockade. These observations demonstrate that pre-existing allergic lung disease alters the quality and magnitude of immune responses to respiratory poxviruses through an IL-10-dependent mechanism.     

Exposure to ozone reduces influenza disease severity and alters distribution of influenza viral antigens in murine lungs

Exposure to ambient levels of ozone (0.5 ppm) was shown to alter the pathogenesis of respiratory infection after aerosol infection of mice with influenza A virus. A semiquantitative method for determination of the sites of virus replication by direct immunofluorescence indicated that exposure to ozone reduced the involvement of respiratory epithelium in the infectious process and resulted in a less widespread infection of the alveolar parenchyma. Furthermore, the ozone-mediated alteration in viral antigen distribution was consistent with significantly reduced influenza disease mortality and prolonged survival time, but only when the oxidant was present during the course of infection. Reduced disease severity in ozone-exposed animals appeared to be independent of peak pulmonary virus titers, pulmonary interferon titers, and pulmonary and serum-neutralizing antibody titers. These studies suggested that the distribution of influenza virus in the murine lung was a key factor in disease severity.     

Kinetic profile of influenza virus infection in three rat strains

Influenza is a respiratory tract disease of viral origin that can cause major epidemics in humans. The influenza virus infects and damages epithelial cells of the respiratory tract and causes pneumonia. Lung lesions of mice infected with influenza virus resembles those seen in humans with influenza, and can result in severe and even fatal pneumonia. In contrast, experimental infection of rats with the virus induces a milder form of the disease, with no mortality. The purpose of the study reported here was to determine the time course of influenza infection and lung injury in Brown Norway (BN), Fischer-344 (F344), and Sprague-Dawley (SD) rats to ascertain whether genetic background impacts susceptibility to infection and host responses. Rats of each strain were inoculated intranasally with 10,000 plaque-forming units of rat-adapted influenza virus (RAIV), and lungs were assessed at postinoculation hour (PIH) 2, 24, 48, 72, and 144 for viral titer, inflammatory cells, pro-inflammatory cytokines, and biochemical indicators of lung edema (protein) and injury (lactate dehydrogenase [LD] activity). Virus titer peaked at PIH 24, and was 100-fold higher in the F344 and SD, compared with the BN strain. Alveolar macrophages, LD activity, and total protein concentration were higher in the BN rats, whereas neutrophil numbers and interleukin 6 and tumor necrosis factor-alpha activities were greatest in the bronchoalveolar lavage fluid of F344 and SD rats. The results indicate that F344 and SD rats respond in similar manner to viral infection, whereas viral replication was more limited in BN rats and was associated with a different profile of pulmonary cells.     

Exposure to ozone reduces influenza disease severity and alters distribution of influenza viral antigens in murine lungs.

Exposure to ambient levels of ozone (0.5 ppm) was shown to alter the pathogenesis of respiratory infection after aerosol infection of mice with influenza A virus. A semiquantitative method for determination of the sites of virus replication by direct immunofluorescence indicated that exposure to ozone reduced the involvement of respiratory epithelium in the infectious process and resulted in a less widespread infection of the alveolar parenchyma. Furthermore, the ozone-mediated alteration in viral antigen distribution was consistent with significantly reduced influenza disease mortality and prolonged survival time, but only when the oxidant was present during the course of infection. Reduced disease severity in ozone-exposed animals appeared to be independent of peak pulmonary virus titers, pulmonary interferon titers, and pulmonary and serum-neutralizing antibody titers. These studies suggested that the distribution of influenza virus in the murine lung was a key factor in disease severity.     

Endothelin receptor blockade decreases lung water in young rats exposed to viral infection and hypoxia

Viral respiratory infections may increase the susceptibility of young animals to hypoxia-induced pulmonary edema. Because hypoxia stimulates endothelin production, we hypothesized that an increase in lung endothelin contributes to these alterations in lung water. Weanling rats were infected with Sendai virus, causing a mild respiratory infection. At day 7 after infection, animals were exposed to hypoxia (inspired O(2) fraction = 0.1) for 24 h. Exposure to virus plus hypoxia led to increases in lung water compared with control groups (P < 0.001). Lung endothelin levels were significantly higher in the virus plus hypoxia group than in control groups (P < 0.001). A second group of infected animals received bosentan, a nonselective endothelin receptor antagonist, during exposure to hypoxia. Bosentan-treated animals showed less lung water accumulation, less lung lavage fluid protein, and less perivascular fluid cuffing than untreated animals (P < 0.01). We conclude that the combination of a recent viral respiratory infection and exposure to moderate hypoxia led to increases in endothelin in the lungs of young rats and that endothelin receptor blockade ameliorates the hypoxia-induced increases in lung water found in these animals.     

甲型H1N1流感病毒感染小鼠的发病机制

目的甲型H1N1流感病毒A/California/7/2009感染BALB/c小鼠,研究甲型H1N1流感病毒病毒性肺炎发病机制。方法 4～6周龄雌性BALB/c小鼠60只,随机分为2组,实验组和对照组,每组30只。CA7流感病毒滴鼻制备甲流病毒感染小鼠模型。攻毒后第5天解剖实验和对照组小鼠,取肺组织,测定肺组织中IL-2,IL-6,TNF-α含量。结果结果实验组肺组织中IL-6,TNF-α,水平明显高于对照组,IL-2水平明显低于对照组,差异均有显著性（P〈0.05）。结论 IL-6、TNF-α、IL-2这3种细胞因子在感染甲流病毒后的显著性变化与病毒感染后的肺组织病理损伤有密切的关系。     

Cell-mediated immune response to lymphocytic choriomeningitis and vaccinia virus in rats.

The parameters of cell-mediated immune responses of rats to infection with lymphocytic choriomeningitis virus or vaccinia virus were assessed by measuring primary footpad swelling, increased weights of the local lymph nodes, increased numbers of lymphocytes per lymph node, and the course of virus-specific cytolytic activity by these lymphocytes. Except for lack of a defined swelling caused by vaccinia virus injected into the hind footpads of rats, the kinetics of all these responses correlated and were in accord with the usual time course of cellular immune responses. Starting 3 days after infection, peaking at 5 to 7 days, and disappearing after 10 to 12 days, the responses by rats to both viruses were comparable to those found in mice. The phagocytes of these infected rats inhibited the growth of Listeria monocytogenes in vivo, indicating activation of the macrophages by virus-specific cellular immunity. The rat cytotoxic lymphocytes were thymus derived as judged by various criteria: inactivation by an absorbed rabbit anti-rat brain antiserum plus C, susceptibility to anti Thy 1.1 plus C, restriction of the lytic activity within inbred strains and probably by the Ag-B locus, and the kinetics of the response. The cytotoxic T lymphocytes were virus specific since they killed only target cells infected with the same virus but not uninfected cells, or targets that were infected with an unrelated virus.