Experience with mouse hepatitis virus sanitation in three transplantable murine tumour lines

Transmission of viral infection by tumour lines or other biological materials may have confounding effects on research. Many research organizations require screening for viral agents of all cell lines, tumours, sera and other biologicals before implantation or inoculation into animal models. Screening for viral contamination is done by the mouse antibody production (MAP) test, by cell culture, or alternatively by direct detection of the viral agents by polymerase chain reaction (PCR). The description of procedures for sanitation of infected cell lines or tumours is sparse. The present report describes the procedures used for sanitation of three transplantable murine tumour lines, which were transplanted in vivo in a mouse hepatitis virus (MHV)-infected colony of mice at the Department of Experimental Clinical Oncology (DECO). The tumours were frozen and serially transplanted three times in a quarantine colony of syngenic mice. Serological examination of the mice transplanted with tumours as well as their cage mates in the quarantine colony did not detect any antibodies against MHV. After repeated serial transplantation in seronegative animals, tumour material was frozen and thawed tumours were later used for transplantation into the newly established virus-free colony of mice at DECO. PCR-based detection of MHV did not reveal any contamination of the tumour examined by this technique, indicating that this murine tumour apparently did not transmit MHV or that MHV was eliminated from the tissue so fast after the infection that it could not be transmitted by the tumour tissue. It is concluded that MHV infection of mice with transplantable murine tumours does not necessarily cause the tumours to be contaminated.

Experimental infection of Z:ZCLA Mongolian gerbils with human hepatitis E virus

AIM: To investigate whether Z:ZCLA Mongolian gerbils are readily susceptible to infection by human hepatitis E virus (HEV).

METHODS: Z:ZCLA Mongolian gerbils were infected with a clinical HEV strain isolated from an acute hepatitis E patient, and virus pathogenesis was assessed in this host. Non-infected gerbils served as the control group. Feces samples from gerbils were collected weekly for reverse transcription-nested polymerase chain reaction. Serum anti-HEV IgG and alanine aminotransferase (ALT) were detected by enzyme linked immunosorbent assay. At sacrifice, each animal’s liver, spleen and kidney were collected for histopathologic examination.

RESULTS: HEV-infected gerbils showed fatigue, with histopathological changes observed in the liver, spleen and kidney. HEV RNA was detected in fecal samples taken at day 7 after inoculation and the detectable levels lasted out to day 42 after inoculation. Interestingly, ALT levels were only moderately increased in the HEV-infected animals compared with the non-infected control group.

CONCLUSION: Z:ZCLA Mongolian gerbils are susceptible to human HEV.

Transmission of mouse minute virus (MMV) but not mouse hepatitis virus (MHV) following embryo transfer with experimentally exposed in vivo-derived embryos

The present study investigated the presence and location of fluorescent microspheres having the size of mouse hepatitis virus (MHV) and of mouse minute virus (MMV) in the zona pellucida (ZP) of in vivo-produced murine embryos, the transmission of these viruses by embryos during embryo transfer, and the time of seroconversion of recipients and pups. To this end, fertilized oocytes and morulae were exposed to different concentrations of MMVp for 16 h, while 2-cell embryos and blastocysts were coincubated for 1 h. In addition, morulae were exposed to MHV-A59 for 16 h. One group of embryos was washed, and the remaining embryos remained unwashed before embryo transfer. Serological analyses were performed by means of ELISA to detect antibodies to MHV or MMV in recipients and in progeny on Days 14, 21, 28, 42, and 63 and on Days 42, 63, 84, 112, 133, and 154, respectively, after embryo transfer. Coincubation with a minimum of 10⁵/ml of fluorescent microspheres showed that particles with a diameter of 20 nm but not 100 nm crossed the ZP of murine blastocysts. Washing generally led to a 10-fold to 100-fold reduction of MMVp. Washed MMV-exposed but not MHV-exposed embryos led to the production of antibodies independent of embryonic stage and time of virus exposure. Recipients receiving embryos exposed to a minimum of 10⁷ mean tissue culture infective dose (TCID₅₀)/ml of MHV-A59 and 10² TCID₅₀/ml of MMVp seroconverted by Day 42 after embryo transfer. The results indicate that MMV but not MHV can be transmitted to recipients even after washing embryos 10 times before embryo transfer.

Risk assessment of mouse hepatitis virus infection via in vitro fertilization and embryo transfer by the use of zona-intact and laser-microdissected oocytes

The aim of this study was to estimate the risk of mouse hepatitis virus (MHV) transmission by the in vitro fertilization and embryo transfer (IVF-ET) procedure. In addition, resistance to infection of zona-intact and laser-microdissected oocytes was compared. For this purpose, infectious mouse hepatitis virus, a common viral pathogen in mouse facilities, was used. Oocytes having an intact or laser-microdissected zona pellucida were incubated for fertilization in media containing MHV-A59 and resulting embryos were transferred to the oviduct of specific pathogen-free (SPF) Swiss recipients. The oocytes were divided into three experimental groups: 1) zona-intact oocytes continuously exposed to MHV in fertilization (HTF), culture (KSOM), and embryo transfer (M2) media; 2) zona-intact oocytes exposed to MHV in HTF medium and transferred after a standard washing procedure with virus-free KSOM and M2; and 3) laser-microdissected oocytes exposed to MHV in HTF medium and transferred after a standard washing procedure with virus-free KSOM and M2. Respective serum samples of embryo recipients and their offspring were tested for MHV antibodies using ELISA. In experiment 1, 10 out of 14 embryo recipients seroconverted to MHV and only their offspring (8 of 19) received maternal antibodies. In experiments 2 and 3, MHV antibodies were detected neither in the recipients nor in the offspring. These results indicate, for the first time, that even if the zona pellucida is partially disrupted by laser microdissection, the transmission of MHV-A59 can be avoided by correctly performed washing steps in the IVF-ET procedure.

Routes of transmission of swine hepatitis E virus in pigs

Hepatitis E virus (HEV) is believed to be transmitted by the fecal-oral route in pigs. To date, in experiments, HEV has been transmitted successfully only by the intravenous or intrahepatic route. To assess the route of HEV transmission, 27 pigs were separated into nine groups of three pigs. Positive-control pigs were inoculated intravenously with swine HEV and served as the source of HEV for the other groups. Uninoculated contact pigs were placed in the positive-control group. On three consecutive days, naive pigs were inoculated using samples collected from the positive-control pigs at 9, 10, and 11 days postinoculation. The tonsils and nasal mucosa of each positive-control pig were swabbed and that swab was used to rub the tonsils and nasal and ocular mucosa of naive pigs. The positive-control pigs were also injected with bacterin, and the same needle was used to immediately inject naive pigs. Feces were collected from positive controls and fed by oral gavage to naive pigs. Weekly fecal and serum samples from each pig were tested for anti-HEV antibodies and HEV RNA. All positive-control pigs shed the virus in feces; two pigs were viremic and seroconverted to anti-HEV. All contact control pigs shed the virus in feces; two seroconverted and one became viremic. One of three pigs in the fecal-oral exposure group shed the virus in feces and seroconverted. Pigs exposed to the contaminated needles or the tonsil and nasal secretion swabs remained negative. This is the first report of experimental fecal-oral transmission of HEV in swine.

Transmission of enterotropic mouse hepatitis virus from immunocompetent and immunodeficient mice

Mouse hepatitis virus (MHV) is the most prevalent virus that infects mice, and most MHV strains are enterotropic. Experiments were performed to elucidate the duration of enterotropic MHV-Y shedding by immunocompetent BALB/ c and C57BL/6 mice and immunocompromised B and T cell-deficient mice. Although the use of molecular diagnostics to detect MHV infection is increasing, it is unclear whether the viral RNA detected is always infectious. The ability to detect MHV-Y transmission to sentinel mice exposed directly to infected mice or to soil bedding from infected mice was compared with reverse transcriptase-polymerase chain reaction-based detection of viral RNA in the feces. The BALB/c mice developed subclinical intestinal infection, and transmitted MHV-Y for four weeks. The C57BL/6 mice also developed subclinical intestinal infection, but only transmitted virus for two weeks. The T cell-deficient mice developed severe disseminated disease by two weeks and transmitted virus for four weeks. The B cell-deficient mice developed subclinical intestinal infection and transmitted virus for longer than three months, although virus RNA was not detected in feces late in the infection. Viral RNA detected in the feces of infected mice was almost always infectious. Non-infectious RNA was detected in a few mice for several days after transmission had ceased. In addition, constant exposure of naive mice to infected mice, via the use of serial sentinels, prolonged viral transmission.

Experimental infection of pregnant gilts with swine hepatitis E virus

To determine the effect of swine hepatitis E virus (HEV) infection on pregnant gilts, their fetuses, and offspring, 12 gilts were intravenously inoculated with swine HEV. Six gilts, who were not inoculated, served as controls. All inoculated gilts became actively infected and shed HEV in feces, but vertical transmission was not detected in the fetuses. There was no evidence of clinical disease in the gilts or their offspring. Mild multifocal lymphohistiocytic hepatitis was observed in 4 of 12 inoculated gilts. There was no significant effect of swine HEV on fetal size, fetal viability, or offspring birth weight or weight gain. The offspring acquired anti-HEV colostral antibodies but remained seronegative after the antibodies waned by 71 days of age. Swine HEV infection induced subclinical hepatitis in pregnant gilts, but had no effect on the gilts' reproductive performance, or the fetuses or offspring. Fulminant hepatitis associated with HEV infection was not reproduced in gilts.

Hepatitis viruses: a pandora's box?

The term hepatitis virus is reserved for those viruses that are predominantly hepatotropic, although several new agents have been assigned to this category in the absence of hepatotropism and clinical disease. The hepatitis viruses can be broadly divided into those transmitted via the fecal-oral route, and those by blood, blood products and body fluids. Hepatitis A (picornaviridae), hepatitis B (hepadnaviridae) and hepatitis C (flaviviridae) represent the major public health problems. The epidemiology of hepatitis A virus (HAV) and hepatitis B virus (HBV) is changing in response to vaccination. In the case of HAV, older age groups are now deemed at risk, particularly of fulminant hepatitis if exposed over the age of 50. Chronic hepatitis B in some regions is now predominantly of the so-called precore mutant type where high levels of HBV replication persist in the presence of anti-hepatitis B virus (HBe) antibodies. The HBV vaccination is among the most cost-effective health care measures. The epidemiological significance of mutations found increasingly in the HBV S gene isolated from vaccinated children is unclear. Evidence that hepatitis G and TT virus are significant causes of hepatitis is lacking. Of interest, however, is the finding that the related GBV-B agent of monkeys may be a model for developing new antiviral agents against HCV. Animal models of hepatitis infections are providing new insights into the pathogenesis of hepatitis in humans. Indeed it is possible that hepatitis E is primarily an agent of pigs and other domesticated livestock. Intriguingly, the new TT virus shares many properties with the circoviruses, significant pathogens of chickens and pigs. The challenge in the next decade will be to assess the significance of these new agents in terms of public health and resources. Value judgements will have to be made in assessing the risks associated with blood containing trace amounts of these adventitious agents.

Use of TaqMan reverse transcriptase-polymerase chain reaction analysis and serologic testing to eliminate an enzootic infection of mouse hepatitis virus

Elimination of an enzootic infection of mouse hepatitis virus (MHV) from a large population of genetically engineered mice was accomplished by selecting seropositive, non-infective breeders for a newly restored MHV-free breeding colony. An ELISA was used to test for the presence of MHV-specific antibody, and TaqMan reverse transcriptase-polymerase chain reaction (RT-PCR) analysis was used to detect MHV in the feces. After 10 weeks of intentional exposure, approximately 30% of mice with MHV antibodies continued to shed MHV in the feces. A natural transmission study was conducted to validate that positive fecal RT-PCR results indicated presence of infective virus. Sentinel results from the re-instituted breeding colony indicated that MHV was successfully eliminated by use of RT-PCR analysis for selection of non-infective mice.

Assessment of static isolator cages with automatic watering when used with conventional husbandry techniques as a factor in the transmission of mouse hepatitis virus

This study evaluated protection against mouse hepatitis virus (MHV) afforded by static filter-top caging when automatic watering was used with conventional husbandry techniques as a labor-saving option. We fitted one side of a double-sided 72-cage rack with valves external to each cage; cages on the other side were fitted with shielded internal valves. More than 50% of the mice were breeding mice, and 30% were genetically altered. One cage of mice on each shelf on both sides of the rack was infected with MHV-A59. Each row of cages also contained one standard cage (no filter top) of uninoculated mice at various distances from the infected cage. At 2, 4, and 6 weeks after infection of the mice in the test cages, uninoculated mice in 22 cages were tested by serology, and at 8 weeks the uninoculated mice in 54 cages were tested by serology and those in 24 cages were tested by polymerase chain reaction (PCR) amplification of fecal samples to assess transmission of infection. At 8 weeks post-infection, mice in one uninoculated cage (which had a filter top and an internal valve and was adjacent to a cage of inoculated mice) was seropositive. Examination of feces by PCR revealed MHV shedding in mice in nine uninoculated cages (three lacking filter tops but with internal valve cages; two with filter tops and internal valve cages and adjacent to non-filter top cages; two non-filter-top cages with external valves; and two filter-top cages with external valves, of which one was adjacent to a non-filter-top cage). Routine husbandry using either automatic water valve system prevented (with one exception) transmission among filter-top cages for at least 6 weeks. The 10 cages where transmission occurred were non-filter-top cages (n = 5) and filter-top cages adjacent to non-filter top, infected, or sentinel cages (n = 5). These results suggest that the use of filter top-caging with automatic watering may limit MHV transmission for 6 weeks, during which immunocompetent mice would be expected to clear the virus. Our findings also suggest that long-term use of automatic watering in static filter-top cages handled using conventional husbandry techniques may not prevent transmission in the vicinity of high virus concentrations or open caging.

Use of a swine bioassay and a RT-PCR assay to assess the risk of transmission of swine hepatitis E virus in pigs

The objective of this study was to assess the risk of transmission of swine hepatitis E virus (swine HEV) to naïve pigs by inoculation with tissues or feces collected from pigs infected experimentally with swine HEV. Seventy-five, 3-week-old pigs were assigned randomly to 24 groups of 3-4 pigs and inoculated with homogenates of tissues (liver, heart, pancreas, or skeletal muscle) or a suspension of feces from swine HEV-infected pigs collected at 3, 7, 14, 20, 27, or 55 days post inoculation (DPI). Each inoculum was prepared as a 10% suspension (w/v) in PBS buffer and tested by a semi-quantitative RT-PCR for swine HEV RNA and by the swine bioassay. The inoculation route was intravenous for liver, heart and pancreas, and via stomach tube for skeletal muscle and fecal suspension. The liver homogenate inocula and feces collected at 3-7 and 14-20 DPI were positive for swine HEV RNA by RT-PCR. The pigs inoculated with liver homogenates collected at 3-7 and 14-20 DPI developed anti-HEV antibodies and swine HEV RNA was detected in their sera. Pigs inoculated with heart, pancreas, skeletal muscle homogenates or fecal suspensions failed to develop anti-HEV antibodies. These findings suggest that there is a potential risk of transmission of swine HEV via liver tissue from infected pigs in the early stages (3-20 DPI) of infection and the in vitro RT-PCR assay correlates well with the swine bioassay.

Experimental studies on subclinical hepatitis E virus infection in cynomolgus macaques

Serial subclinical transmission among susceptible humans may serve as a reservoir of hepatitis E virus (HEV) in areas in which HEV is endemic. This hypothesis was investigated in an experimental primate model. Four groups of 4 cynomolgus macaques each were inoculated intravenously with 10(4)-10(5) (group 1), 10-100 (group 2), and 1-10 (group 3) cynomolgus macaque HEV infectious doses. All 4 animals in group 1 had clinical disease marked by alanine aminotransferase (ALT) elevation, fecal virus excretion, viremia, and seroconversion. Of the animals in groups 2 and 3, only 1 had evidence of biochemical hepatitis, although most had virus excretion and viremia (3 animals each in groups 2 and 3), and evidence of seroconversion (1 animal in group 2 and 3 animals in group 3). Viral genomic titers in stool specimens of animals with or without ALT elevation were similar. Infectivity studies confirmed the viability and transmission potential of the virus excreted by animals without ALT elevation. These data suggest that subclinical HEV infection may represent an HEV reservoir.

Persistent transmission of mouse hepatitis virus by transgenic mice

Variation in susceptibility to viral infection is well documented across mouse strains. Specific combinations of viral strains and murine hosts may favor viral infection and disease, and could potentially allow the unexpected development of chronic, persistent, or latent infections. In some genetically modified strains of mice, immune function and perhaps other physiologic or metabolic systems may be substantially or marginally impaired. In the case study reported here, we document the apparent persistent transmission of mouse hepatitis virus (MHV) over a two-year period by MHV-seropositive transgenic mice. Transmission occurred via direct contact with seropositive mice and exposure to contaminated bedding. However, MHV was not detected at diagnostic laboratories by use of viral isolation or reverse transcriptase-polymerase chain reaction (RT-PCR) analysis of tissues from MHV-seropositive animals. Our observation, together with the constantly expanding varieties of immune-impaired or poorly characterized murine hosts and the burgeoning dissemination of these animals throughout the biomedical research community, indicate that unexpected pathophysiologic presentations of common murine viral diseases may present new challenges to the biomedical research community in the future.

Molecular epidemiology of viral pathogens and tracing of transmission routes: hepatitis-, calici- and hantaviruses

BACKGROUND

The need to rapidly identify new therapeutic drugs and vaccines for clinically important viral infections has resulted in intensive study of the molecular properties of viruses. Modern molecular techniques have provided tools for tracing infections and studying the evolution of viruses. OBJECTIVE STUDY AND DESIGN: Two examples illustrating how modern molecular techniques can be used in clinical virology and molecular epidemiology (hepatitis and caliciviruses), and one example documenting their importance in basic research (hantaviruses) will be discussed.

RESULTS AND CONCLUSIONS

Water- and food-borne outbreaks caused by the faeco-orally spread hepatitis A virus (HAV) are common in areas lacking proper sanitation, but they are possible also in countries with low seroprevalence. In water epidemics, the sequence comparisons between the virus from patients and from water have been used successfully. Hepatitis B virus variants are clinically important and challenge the diagnostic tests and prophylactic measures. Some hepatitis C (HCV) genotypes appear to be associated with more severe pathology and others respond better to antiviral treatment. Nosocomial and occupational infections are not rare, and the source can be identified by phylogenetic analysis of nucleotide sequences obtained from the infected individuals. The overwhelming role of Norwalk-like caliciviruses (NLV) in adult diarrhoea and especially in food- and water-borne epidemics has become apparent during the last decade. Methods are under development for detecting these viruses, not only from patient samples and water, but also from other environmental samples (e.g. foodstuff and surface swabs). The analysis of the genetic variation and evolution of the Old World hantaviruses in their carrier rodents has shown that the extent of genetic diversity correlates with geographical distance. As a rule, phylogenetic relationships of hantaviruses resemble those of their rodent hosts, suggesting virus-host co-evolution. Exceptional host-switch events allow a study on still radiating hantavirus species. There is suggestive evidence that natural reassortant hantaviruses are involved in human infection.

Experimental infection of nonenveloped DNA virus (TTV) in rhesus monkey

Virus fragments homologous to TTV were detected previously from an enterically transmitted outbreak of non-A-E hepatitis [Luo et al., 1999]. To test the susceptibility of the Rhesus monkey to this virus and to establish its transmission routes, 6 Rhesus monkeys were inoculated, 3 orally and another 3 intravenously. The inoculum was prepared by extracting and filtering feces collected from a patient during the incubation period identified in the described outbreak. A second group of 3 monkeys was used for the passage study. The feces and blood samples were collected for detection of the virus by polymerase chain reaction (PCR). Four animals were subjected to liver biopsies and bile aspiration by open surgery for in situ virus detection. Viremia occurred in 4-7 days after intravenous and 7-10 days after oral inoculation. The virus was excreted in feces a few days after oral infection and simultaneously with viremia after intravenous inoculation. The virus was also detected in bile during the viremic phase. There was a prolonged carrier state with persistent viremia and virus excretion in feces for more than 6 months. Serum transaminase levels were not raised during the infection. The virus was present in both the cytoplasm and nuclei of hepatocytes, but no significant pathology was found. Therefore, the Rhesus monkey is susceptible to TT virus infection, but the virus seems nonpathogenic. Infection of the liver may be established either by oral or parenteral inoculation. The virus may be released from liver into the blood or via bile into feces, so it may be transmitted by both blood and fecal routes.

Occult persistence and lymphotropism of hepadnaviral infection: insights from the woodchuck viral hepatitis model

Hepatitis B virus (HBV) is a major human pathogen that causes chronic infection and life-threatening liver diseases in millions of individuals. While pathological and epidemiological consequences of clinically evident HBV infections are well recognized, there is no similar knowledge on an asymptomatic, silently progressing virus persistence. Contrary to previous opinion, current evidence indicates that a serologically undetectable (occult) HBV carriage is a common outcome of recovery from symptomatic illness and that scanty amounts of the virus are carried by apparently healthy individuals for years after resolution of hepatitis B despite the presence of presumably protective antiviral antibodies. Recent studies on this silent form of hepadnavirus carriage in an experimental woodchuck hepatitis virus (WHV) infection, which is considered to be the closest natural model of HBV disease, revealed that the life-long occult persistence of traces of pathogenic virus is an invariable consequence of recovery after hepadnaviral invasion and that this state always co-exists with a steady low-rate virus replication in both the liver and the lymphatic system. Importantly, this serologically concealed infection can be accompanied by development of hepatocellular carcinoma in convalescent animals and is transmittable from mothers to offspring as an asymptomatic, indefinitely long infection which involves the lymphatic system but not always the liver. This review focuses on the features of hepadnavirus occult persistence and its lymphotropism, and on what is currently understood about the contribution of the lymphatic system in maintaining hepadnavirus carriage based on insights provided by analysis of the woodchuck-WHV experimental system.

Species-specific TT viruses and cross-species infection in nonhuman primates

Viruses resembling human TT virus (TTV) were searched for in sera from nonhuman primates by PCR with primers deduced from well-conserved areas in the untranslated region. TTV DNA was detected in 102 (98%) of 104 chimpanzees, 9 (90%) of 10 Japanese macaques, 4 (100%) of 4 red-bellied tamarins, 5 (83%) of 6 cotton-top tamarins, and 5 (100%) of 5 douroucoulis tested. Analysis of the amplification products of 90 to 106 nucleotides revealed TTV DNA sequences specific for each species, with a decreasing similarity to human TTV in the order of chimpanzee, Japanese macaque, and tamarin/douroucouli TTVs. Full-length viral sequences were amplified by PCR with inverted nested primers deduced from the untranslated region of TTV DNA from each species. All animal TTVs were found to be circular with a genomic length at 3.5 to 3.8 kb, which was comparable to or slightly shorter than human TTV. Sequences closely similar to human TTV were determined by PCR with primers deduced from a coding region (N22 region) and were detected in 49 (47%) of the 104 chimpanzees; they were not found in any animals of the other species. Sequence analysis of the N22 region (222 to 225 nucleotides) of chimpanzee TTV DNAs disclosed four genetic groups that differed by 36.1 to 50.2% from one another; they were 35.0 to 52.8% divergent from any of the 16 genotypes of human TTV. Of the 104 chimpanzees, only 1 was viremic with human TTV of genotype 1a. It was among the 53 chimpanzees which had been used in transmission experiments with human hepatitis viruses. Antibody to TTV of genotype 1a was detected significantly more frequently in the chimpanzees that had been used in transmission experiments than in those that had not (8 of 28 [29%] and 3 of 35 [9%], respectively; P = 0.038). These results indicate that species-specific TTVs are prevalent in nonhuman primates and that human TTV can cross-infect chimpanzees.

Serological and histological findings in infection and transmission of GBV-C/HGV to macaques

Seven healthy macaques were inoculated with the GBV-C/HGV-RNA serum from a non-A-E hepatitis patient. The serology and pathology of the liver in the animals were observed. The results indicated that all inoculated animals were infected with a GBV-C/HGV-RNA viremia and had mildly abnormal alanine transaminase levels during the infectious period. The histology, immuno-histochemistry, and in situ hybridization in the liver tissues of the inoculated animals also showed that there was a very mild hepatitis with the positive antigenic expression and the genome of GBV-C/HGV-NS5 in hepatocytes. The pathological changes in the infected animals appeared to become normal whether or not GBV-C/HGV-RNA viremia persisted. There is a possibility that the mild virulence of the GBV-C/HGV to the host became harmless with time after inoculation. Infection and the transmission of the GBV-C/HGV virus in the macaques provides an appropriate animal model and new information about GBV-C/HGV infection in both humans and animals. It is possible that this virus is a mild and self-limited pathogenic agent to the hepatic cells of primates.

The use of non-human primates as animal models for the study of hepatitis viruses

Hepatitis viruses belong to different families and have in common a striking hepatotropism and restrictions for propagation in cell culture. The transmissibility of hepatitis is in great part limited to non-human primates. Enterically transmitted hepatitis viruses (hepatitis A virus and hepatitis E virus) can induce hepatitis in a number of Old World and New World monkey species, while the host range of non-human primates susceptible to hepatitis viruses transmitted by the parenteral route (hepatitis B virus, hepatitis C virus and hepatitis delta virus) is restricted to few species of Old World monkeys, especially the chimpanzee. Experimental studies on non-human primates have provided an invaluable source of information regarding the biology and pathogenesis of these viruses, and represent a still indispensable tool for vaccine and drug testing.

Adenovirus-mediated gene transfer in rat liver of interleukin 4 but not interleukin 10 produces severe acute hepatitis

Several immune responses are either limited to or concentrated in a given organ. Cytokines produced during ongoing immune responses have organ-localized effects that can be only partially mimicked upon their systemic delivery. Recombinant adenoviruses are efficient vectors to induce transient organ-localized cytokine expression. This allows in vivo analysis of the effects of cytokines produced spatially and temporally in a manner comparable to that observed during immune responses. The authors generated recombinant adenovirus for rat IL-4 (AdIL-4) and IL-10 (AdIL-10) to analyse the in vivo effects of these two important immunoregulatory molecules after gene transfer in the liver. It was first established that AdIL-4 and AdIL-10 were able to direct the production of biologically active cytokines by different rat cell types in vitro. Intraportal injection of doses of up to 10(10) pfu of AdIL-10 or control non-coding recombinant adenovirus were well tolerated, and hepatic histology showed only mild alterations. Conversely, animals receiving more than 2.5 x 10(9) pfu of AdIL-4 showed dose-dependent mortality, with clinical signs of hepatic dysfunction. Liver histology in animals receiving 2.5 x 10(9) pfu of AdIL-4 showed severe acute hepatitis with maximal lesions between day 7 and 14 and almost complete normalization by day 28 after gene transfer. The leukocyte infiltrate was composed primarily of mononuclear cells, but eosinophils and mast cells were significantly increased as compared to control animals. Hepatic function was also altered in animals that received AdIL-4, with kinetics similar to that of histological lesions. Our study describes a model for investigating cytokine function in vivo through liver-localized transgene expression mediated by adenoviral vectors and demonstrates that liver production of IL-4 but not IL-10 results in acute severe hepatitis.

The GB hepatitis viruses

The genomes of three new flavi-like viruses, GBV-A, GBV-B and GBV-C have been identified. Nucleic acid molecules corresponding to the genomes of GBV-A and GBV-B were isolated from tamarins with hepatitis which had been infected with the GB agent. RNA sequences corresponding to GBV-C have been shown to be present in sera from humans with non-A-E hepatitis. Sequence comparisons show that these three viruses are more closely related to each other and to hepatitis C virus (HCV) than to any other known viruses. Together with HCV they appear to form a discrete cluster of related viruses within the larger genus of flaviviridae. The pathological significance of these viruses and their association with hepatitis is currently emerging.

Experimental hepatitis E in pregnant rhesus monkeys: failure to transmit hepatitis E virus (HEV) to offspring and evidence of naturally acquired antibodies to HEV

In an attempt to reproduce experimentally the fulminant hepatitis of pregnant women infected with hepatitis E virus (HEV), 4 nonpregnant and 6 pregnant rhesus monkeys in the first, second, or third trimester of pregnancy were inoculated intravenously with approximately 10(5.5) ID50 of HEV. Comparison of biochemical, histopathologic, and serologic profiles in pregnant and nonpregnant monkeys did not reveal an increase in the severity of hepatitis in the pregnant animals. Hematology and serum clinical chemistry values were in the normal range in all animals during the study. No evidence of neonatal infection with HEV was found in offspring. Two rhesus monkeys (1 pregnant, 1 nonpregnant) had naturally occurring anti-HEV antibodies prior to inoculation as detected by a standard ELISA and confirmed by a competition ELISA with hyperimmune chimpanzee serum. These animals demonstrated an anamnestic response when they were challenged with HEV.

Molecular and serologic analysis in the transmission of the GB hepatitis agents

Two flavivirus-like genomes have recently been cloned from infectious tamarin (Saguinus labiatus) serum, derived from the human viral hepatitis GB strain, which is known to induce hepatitis in tamarins. In order to study the natural history of GB infections, further transmission studies were carried out in tamarins. Reverse-transcription-polymerase chain reaction and enzyme-linked immunosorbant assays were developed for the detection of RNA and antibodies associated with the two agents, GB virus-A and GB virus-B. The infectivity of both of these agents was demonstrated in tamarins to be filterable through a 0.1 micron filter. Two distinct genomes were identified in the serum of eight of the infected tamarins, while in four tamarins, the genomes were detected independently of each other. Although specific antibodies to the GB virus-B epitopes were detected in the serum of animals inoculated with both agents or GB virus-B alone, antibodies to putative epitopes specific to GB virus-A were not detected in any of the animals. All tamarins inoculated with serum containing GB virus-B exhibited an elevation in liver enzyme levels after inoculation. Elevations of serum liver enzyme levels did not occur when GB virus-A was the only agent detected in the serum. Infection with the original infectious tamarin inoculum conferred protection from reinfection with GB virus-B but not with GB virus-A.

The olfactory nerve and not the trigeminal nerve is the major site of CNS entry for mouse hepatitis virus, strain JHM

Several viruses, including mouse hepatitis virus strain JHM (MHV-JHM), enter the brain after intranasal inoculation and spread transneuronally to other parts of the central nervous system (CNS). Both the olfactory and trigeminal nerves innervate the nasal cavity and are potential portals of virus entry into the CNS. To evaluate the relative importance of each nerve for MHV infection, mice were infected under conditions that discriminated between trigeminal and olfactory nerve entry. When olfactory nerve entry was selectively eliminated by surgical removal of both olfactory bulbs or by chemical destruction of the olfactory epithelium, MHV-JHM spread into the CNS was completely prevented. On the other hand, direct inoculation into the olfactory bulb, which eliminates all entry via the trigeminal nerve, had no effect on the pattern of virus infection. Thus MHV-JHM enters the CNS via the olfactory nerve after intranasal inoculation while entry via the trigeminal nerve is an insignificant part of this process.

Natural hosts of hepatitis A virus

The host range for hepatitis A virus (HAV) is limited to man and several species of non-human primates, and involvement of vertebrates other than primates in HAV circulation is unlikely. Spontaneous hepatitis A infection has been reported to occur in captive non-human primates including the great apes (chimpanzee) as well as Old World (cynomolgus, African vervet, stump-tailed) and New World (aotus) monkeys. The presence of anti-HAV antibody in the sera of newly captured monkeys of these species shows that infection may also spread in their natural habitat. HAVs isolated from spontaneously infected monkeys, although antigenically closely related to human HAV, exhibit a significant degree of genomic heterogeneity. There are at least four distinct simian HAVs differing from each other and from all human HAV strains. It is suggested that each virus is native to a given species reflecting evolutionary relationships among HAVs and their hosts in the order of Primates.

Hepatitis of viral origin in Leporidae: introduction and aetiological hypotheses

In less than ten years, two very serious viral hepatic diseases have spread through Leporidae populations (rabbits and hares) in numerous countries. In May 1989, the Office International des Epizooties designated this new disease of rabbits "viral haemorrhagic disease" and entered it as a List B disease in the International Animal Health Code. Clinically, the disease is very similar to the European brown hare syndrome. However, numerous uncertainties prevail today on the true nature of the viruses of the two species. Although they are related, the viruses appear to be different and cross infection between species has given contradictory results. Hepatitis of Leporidae have probably existed in Europe for several years, although their viral aetiology has been demonstrated only recently. The acute form has occurred in hares in Northern Europe since approximately 1980, while the inapparent (or ignored) form has been present in rabbits in Czechoslovakia since 1975. These diseases of Leporidae are true viral hepatitis which, in their fulminating forms, bear a remarkable resemblance to human viral hepatitis (B and non-A non-B) with regard to clinical symptoms, pathological lesions and mode of transmission. The dominant faecal-oral transmission observed for types A and E hepatitis would explain the particular susceptibility of family-kept rabbits, as they are fed potentially contaminated fodder. As the clinically similar fulminating hepatitis in human beings is caused by a diversity of viruses (both RNA and DNA), the disease in Leporidae might also be caused by different viruses.(ABSTRACT TRUNCATED AT 250 WORDS)

Experimental transmission of turkey viral hepatitis to day-old poults and identification of associated viral particles resembling picornaviruses

Turkey viral hepatitis (TVH) was experimentally reproduced in two experiments in 1-day-old poults. In the first experiment, an infectious inoculum was prepared from filtered yolk materials harvested from dead embryonating chicken eggs (ECE) previously inoculated with suspensions of liver and pancreas tissues collected from TVH-affected birds in commercial turkey flocks. One-day-old poults given a yolk-sac inoculation or oral gavage with this preparation developed lesions in the liver and pancreas characteristic of TVH at 20 days postinoculation (PI) in 60% and 14% of the experimentally infected birds, respectively. With the identical inoculum, embryo mortality occurred at 8 and 10 days PI in embryonating turkey eggs (ETE) inoculated into the yolk sac. In the second experiment, an infectious inoculum was prepared from filtered yolk materials from dead ETE harvested in the first experiment. One-day-old poults given a yolk-sac inoculation with this filtered yolk material developed lesions in the liver and pancreas within 5 days PI. At 20 days PI, 67% of the experimentally infected birds had similar lesions. With the inoculum given to these poults, embryo mortality occurred at 6, 8, and 10 days PI in ETE inoculated into the yolk sac. Virus particles 26-28 nm in diameter with icosahedral morphology typical of picornaviruses were identified by EM in the yolk sacs of ETE that died in both experiments, and inoculated ETE that died following passage of filtered suspensions of pancreatic tissues collected from affected birds in the first experiment.

Experimental WHV infection of woodchucks: an animal model of hepadnavirus-induced liver cancer

Woodchuck hepatitis virus (WHV), a member of the Hepadnaviridae, is closely related to HBV in its virus structure, genetic organization and mechanism of replication. Natural infection of woodchucks is associated with chronic liver disease and primary hepatocellular carcinoma (HCC). A concerted effort to develop the woodchuck as an experimental animal model of hepadnavirus-induced disease was initiated in 1980. The experimental studies have established the following: (1) Chronic WHV carriage as an outcome of infection is a function of age of exposure, virus dose and, possibly, virus strain. As in humans, animals infected as newborns develop chronic antigenemia at high rates compared to young adults. (2) WHV causes primary hepatocellular carcinoma (HCC) in woodchucks. Hundred percent of experimentally-induced chronic WHsAg carriers developed HCC within three years; no HCC has occurred in concurrent uninfected control animals born and held in the same laboratory environment. The predictable course of experimental WHV infection leading to liver disease in woodchucks makes this an ideal model in which to study the natural history of hepadnavirus and to develop effective prophylactic and therapeutic strategies.

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.

[Primates in the study of hepatitis viruses]

There is no a conventional tissue culture system for the propagation of the hepatitis viruses and only some of them can be maintain in continuous cell culture in particular conditions. A transmissibility of hepatitis is limited to primates. The narrow host specificity may help to establish the classification of the hepatitis viruses and their mode of transmission. Moreover, the primate animal model provided the most accessible source of viruses and for clinical reasons presents the only opportunity for the studies of pathogenic mechanisms involving cellular immunity with allogenic restriction. The marmosets and chimpanzees susceptible to the hepatitis A and B viruses, respectively are the primates of choice for the experimental models. For the studies on parenterally transmitted NANB hepatitis the chimpanzee and some rhesus monkeys may provide an animal system. At last, most of the primates seem to be susceptible to agent responsible for the water-borne non A non B hepatitis.

Reduced duck hepatitis B virus viraemia in ducklings coinfected with the immunodepressive reticuloendotheliosis virus

Coinfection of avian hosts by duck hepatitis B virus (DHBV) and reticuloendotheliosis virus (REV) was studied to assess the effect of immunodepression by REV on the replication of DHBV. One-day-old ducklings, domestic chickens, and turkey poults were inoculated either with DHBV or DHBV and REV and were bled and weighed at regular intervals. DHBV infection as manifested by viraemia and DHBV DNA in liver was established only in ducklings. All chickens and turkeys were negative for DHBV DNA in serum and liver. However, ducklings coinfected with REV showed a delayed onset and reduced level of viraemia compared to ducklings infected only with DHBV. The narrow host range of DHBV was confirmed even in immunodepressed species. It is suggested that the reduction in DHBV viraemia in ducklings was due to factors not involving the specific immune system.

A new transmissible viral hepatitis of marmosets and tamarins

Callitrichid hepatitis (CH) is a newly recognized, acute, fatal, epizootic disease of New World primates in the family Callitrichidae. Since 1980, 12 outbreaks of CH have occurred in US zoos, involving several callitrichid species including the endangered golden lion tamarin (Leontopithecus rosalia). CH was experimentally transmitted to common marmosets via a bacteria-free filtrate of liver from a naturally infected tamarin. All three inoculated marmosets developed an acute fatal disease with the characteristic clinical and histopathologic findings of CH. Human hepatotropic viruses that can infect the livers of callitrichids were not detected serologically in any of the experimentally infected marmosets. Enveloped viruslike particles 85-105 nm in diameter were observed in the rough endoplasmic reticulum and Golgi complex of hepatocytes from both naturally infected and experimentally inoculated animals. An immunoblot assay was developed using sera from tamarins exposed to natural outbreaks of CH and liver extracts from experimentally infected or control marmosets. A new CH-specific antigen was detected in the livers of naturally infected and experimentally inoculated marmosets but not controls. These results suggest that the etiologic agent of callitrichid hepatitis is a new primate hepatitis virus.

Vertical transmission of woodchuck hepatitis virus

One newborn and 24 fetal woodchuck litters from a woodchuck hepatitis virus (WHV) endemic population were examined for serological or hepatic evidence of WHV. In 18 of 24 fetal litters, there was detectable WHV DNA in the livers, either at explant culture or tissue extract. Most of those WHV DNA-positive liver extracts, which were examined by Southern blot, showed integration of WHV. However, WHV DNA replicative forms without integration were demonstrated in livers of two litters from late gestation. Woodchuck hepatitis surface antigen was detected in the sera of two other fetal litters from the late gestation period. WHV DNA was demonstrated in sera of three litters at different stages of ontogeny.

An experimental transmission of woodchuck hepatitis virus to young Chinese marmots

Fourteen young Chinese marmots (Marmota bobak sibirica Radde) were randomly allocated to two groups of seven each. They were injected intrahepatically with a standard woodchuck hepatitis virus challenge pool or a negative pool, prepared from sera of woodchucks with and without woodchuck hepatitis virus infection, respectively. Marmot No. 2 in the experimental group experienced an episode of seroconversion from woodchuck hepatitis surface antigen to anti-woodchuck hepatitis antibody. Woodchuck hepatitis virus DNA was detected, and woodchuck hepatitis surface antigen particles of both spherical and filamentous forms and intact woodchuck hepatitis virus virions were found in its serum. By contrast, none of the control group animals (receiving the negative pool) produced any marker of woodchuck hepatitis virus. This suggests that young Chinese marmots can get woodchuck hepatitis virus infection.

Mouse hepatitis virus and host determinants of vertical transmission and maternally-derived passive immunity in mice

Transmission of mouse hepatitis virus (MHV) in utero following oronasal inoculation of pregnant mice was found to depend upon MHV strain and host genotype. Virulent, polytropic MHV-JHM was recovered from multiple maternal tissues, including liver and uterus, as well as placenta and fetus in susceptible BALB/cByJ mice. Fetuses were infected during all 3 trimesters of pregnancy. Low virulence, polytropic MHV-S infected fetuses in a low percentage of susceptible BALB/cByJ dams. Infection of resistant CD-1 mice with MHV-JHM was limited, with no fetal infection. Enterotropic MHV-Y was largely restricted to intestine of BALB/cByJ and CD-1 dams, with minimal dissemination and no fetal infection. Maternally-derived MHV IgG antibody was detectable in pup sera through 4 weeks of age. Antibody titers were generally lower in second litters of the same dam. Cross-fostering experiments showed that antibody was transferred via colostrum and not in utero, and that pups were capable of absorption through 2 weeks of age. Pups nursing immune dams were protected against MHV challenge at 1 and 2 weeks of age, compared to pups nursing naive dams. Immunity to MHV challenge was cross-protective against both antigenically homotypic and heterotypic strains of MHV.

Biometrical aspects in the design and analysis of chimpanzees trials assessing hepatitis virus inactivation

Hepatitis virus safety of products derived from blood is achieved by screening of individual blood donations and by production processes efficient in eliminating and inactivating residual amounts of hepatitis viruses. A quantitative measure of process inactivation efficiency is the inactivation factor derived from process overchallenging experiments. A product is safe if the corresponding process inactivation factor is as high as the one of a product whose safety has been clinically established. Reliable information on hepatitis safety cannot be obtained by testing commercial end product samples in chimpanzees.

Serial transmission of a human non A-non B hepatitis viral strain to HBV-protected chimpanzees: successive histological and ultrastructural studies

A NANB agent of human origin was inoculated in HBV-immunized chimpanzees. Infection was proven in two animals and serially passed to two others. The absence of anti-HBc in serum and the absence of HBsAg and HbcAg in liver are arguments against the HBV nature of the transmitted infection. Moreover, the reproducible appearance of the NANBcAg/Ab system at each passage from man to chimpanzee and from chimpanzee to chimpanzee, a response not elicited in control animals, suggests that this reaction may be a specific immunologic marker for the strain. NANB infection was transmitted in all chimpanzees. Distinctive hepatic morphologic features were obtained in the liver biopsies of the human donor and the inoculated chimpanzees: eosinophilic alterations of hepatocytes and numerous inflammatory cells. Inflammation was more prominent than necrosis, appearing earlier and lasting longer, but was not topographically close to the eosinophilic changes. On electron microscopy, particles characteristic of NANB agent were observed in the cytoplasm of the hepatocytes. No particles were demonstrated in the nucleus of these cells.

Maternal transmission of duck hepatitis B virus in pedigree Pekin ducks

A 14-month old female Pekin duck experimentally infected as an embryo with duck hepatitis B virus via the amniotic route has been a chronic carrier of duck hepatitis B virus with very high (P/N) values of DNA polymerase activity since hatching. All the progeny were, on evaluation for congenital infection, found to be duck hepatitis B virus positive by endogenous DNA polymerase reaction and electron microscopy. These offspring remained persistently viremic throughout the study. Maternal transmission therefore bred true to a total of 49 offspring--24 ducklings (less than 24 hr old) and 25 ducks--studied. Six of these 25 ducks matched for age and sex and bled weekly for 6 weeks exhibited fluctuating plasma levels of DNA polymerase activity. Higher DNA polymerase activity was detected in newly hatched ducklings than in older viremic ducks. This observation was corroborated with the results of electron microscopic examination of thin sections of liver. Duck hepatitis B virus particles, located within vesicles of rough endoplasmic reticulum in the cytoplasm of hepatocytes, were more abundant, and therefore more readily observed, in ducklings than in older ducks.

Transmission of ground squirrel hepatitis virus to homologous and heterologous hosts

The infectivity and host range of ground squirrel hepatitis virus (GSHV) have been further examined by animal inoculation experiments. Although carrier squirrel sera usually harbor 10(9) to 10(10) virions per ml as determined by physical measurements, titration of one such serum revealed that squirrel infectivity was lost following dilution of the sample over 10(6)-fold. Infectivity is markedly reduced by NP40 pretreatment of infected serum. GSHV infection cannot be readily transmitted to several related ground squirrel species, but chipmunks can be experimentally infected by GSHV virions or by cloned GSHV DNA, and the resulting infection closely resembles that seen in the normal host.

Pathogenicity of mouse hepatitis virus for preimplantation mouse embryos

Mouse embryos which were hatched from the zona pellucida in vitro in the presence of mouse hepatitis virus (MHV) or outgrown on coverslips and then exposed to MHV were shown by immunohistochemical staining to have virally infected trophoblast cells. Zona-intact embryos incubated with MHV for 48 h (2-cell embryos) or 1.5 h (blastocysts) were resistant to infection. Morulae and early blastocysts collected from donor mice experimentally infected with MHV were not infected, but the medium in which they were flushed from the uterine horns was contaminated with virus. No virus was detected after embryos were washed through three changes of uncontaminated medium. MHV was transmitted to foster mothers when embryos were transferred in medium contaminated with the virus. Fetal and decidual tissues were not infected. We suggest that embryo transfer is an effective and simple alternative to Caesarian rederivation of MHV-contaminated mice.

Transmission of duck hepatitis B virus from Chinese carrier ducks to Japanese ducklings: a study of viral DNA in serum and tissue

Human hepatitis B-like viruses have been found in several animal species, including Chinese ducks. Sera from Chinese carrier ducks which were positive for duck hepatitis B virus (DHBV) were inoculated in 33 Japanese one-day-old ducklings. The same sera were inoculated in four 3-week-old ducklings, and three 3-month-old ducks. Ten uninoculated ducklings served as controls. Hepatitis B e-antigen positive human sera and DNA polymerase-positive woodchuck sera were also inoculated into ducklings. DHBV was demonstrated in serum of all ducklings inoculated at one day of age and persisted for more than 6 months in 17 of 20 ducks. In the three ducks in which viremia disappeared, viral DNA was found in liver tissue. Southern hybridization revealed only free viral DNA in infected ducks. Only 1 of 7 ducklings inoculated at 3 weeks or later developed persistent infection. No cross-infectivity by hepatitis B virus or by woodchuck hepatitis virus was demonstrated. By inoculating DHBV-positive sera into 1-day-old ducklings of a virus-free Japanese flock, we were able to transmit DHBV in all of them and established a chronic carrier state in all ducks which were inoculated at 1 day of age.

Naturally occurring infection of Pekin duck embryos by duck hepatitis B virus

We tested the hypothesis that duck hepatitis B virus (DHBV) is a naturally occurring congenital infection of Pekin duck embryos. Of 219 embryos, 5-25 days after being laid, sera from 30 were found to be positive for endogenous DNA polymerase activity characteristic of hepatitis B-related viruses. The presence of the duck virus was confirmed by hybridization with cloned DHBV DNA. Viral DNA was also found in the livers of embryos incubated for 12 or 18 days. Electrophoretically different forms of DHBV DNA were identified in liver extracts that were not present in serum. These additional liver forms probably represent viral replication intermediates. These observations suggest that the vertical route is a major pathway of DHBV transmission and that viral replication may be initiated by the 12th day of embryonic life.

Biological characterization of acute infection with ground squirrel hepatitis virus

Ground squirrel hepatitis virus (GSHV) is a small DNA virus, structurally and antigenically related to the human hepatitis B virus, which occurs naturally among certain wild populations of ground squirrels (P. L. Marion et al., Proc. Natl. Acad. Sci. U.S.A. 77:2941-2945, 1980). Serum from naturally infected animals was used to transmit GSHV in the laboratory by parenteral inoculation of susceptible squirrels. Sixty percent of recipient animals developed viral surface antigenemia after a latent period of 2 to 3 months; three of these animals have remained viremic for over 9 months. Like hepatitis B virus, GSHV demonstrates marked hepatotropism, with viral DNA detected in significant quantities only in the liver, where an average of 6 X 10(2) to 6 X 10(3) viral DNA molecules per cell were found by molecular hybridization. However, histological signs of liver injury after acute infection are minimal. In contrast to infection of its natural host, parenteral administration of GSHV to rats, mice, guinea pigs, and hamsters did not result in demonstrable antigenemia, suggesting that the host range of GSHV, like that of hepatitis B virus, is narrow.

Effects of experimental infection of the deer mouse (Peromyscus maniculatus) with mouse hepatitis virus

Three deer mice (Peromyscus maniculatus) given 10(4) TCID50 of mouse hepatitis virus -S intranasally all had significant serum neutralization titers to mouse hepatitis virus -S 3 weeks later. Ten other deer mice were given 10(3) TCID50 of mouse hepatitis virus -3 intranasally and placed with sentinel laboratory mice (CF1, C3H/Rv, and nu/nu) and uninoculated deer mice. One inoculated deer mouse died, but mouse hepatitis virus was not isolated. No other inoculated or uninoculated animals exhibited signs of disease. No sentinel animals exhibited serum neutralization titers for mouse hepatitis virus -3. Three of the remaining nine inoculated deer mice had positive antibody titers. It was concluded that deer mice do not develop clinical manifestations of mouse hepatitis virus or transmit the virus to potentially susceptible laboratory mice.