Effect of immunodeficiency on MPV shedding and transmission.

C57BL/6 (B6) mice briefly shed low levels of MPV, and transmission is inefficient. To determine whether deficits in B or T cells or in interferon γ on a B6 background increased the duration of MPV shedding or transmission, B-cell-deficient (Igh), interferon-γ-deficient (Ifnγ), B- and T-cell-deficient (Rag), and B6 mice were inoculated with MPV. At 1 and 2 wk postinoculation (wpi), 11% to 94% of mice shed MPV. From 4 to 18 wpi, 80% to 100% of Rag mice and 0% of B6 and Ifnγ mice shed MPV; Igh mice sporadically shed MPV through 20 wpi. MPV was transmitted from B6 mice and Ifnγ mice at 2 to 4 wpi. Rag and Igh mice transmitted MPV to sentinels at all or most time points, respectively, between 2 to 16 wpi. Once transmission ceased from B6, Ifnγ, and Igh mice, breeding trios were setup and showed that MPV was transmitted to offspring in only one cage of Igh mice. In another experiment, MPV shedding ceased from B6, CD8-deficient (CD8), CD4-deficient (CD4), and T-cell-receptor-deficient (TCR) mice by 2, 6, 8, and 8 wpi, respectively. MPV was transmitted to sentinels only at 1 to 4 wpi. Mesenteric lymph nodes collected from 61% to 100% of B6, Ifnγ, TCR, CD4, CD8, and Rag mice were MPV DNA-positive. In conclusion, MPV transmission did not differ between mice deficient in T cell functions or Ifnγ and B6 mice. In contrast, B-cell deficiency posed an increased risk for MPV transmission in mice.

Transmission of mouse parvovirus by fomites.

The goal of the current studies was to determine the risk of transmission of mouse parvovirus (MPV) by caging and husbandry practices. To determine whether MPV can be transmitted during cage changes in a biologic safety cabinet without the use of disinfectants, 14 cages of Swiss Webster mice were inoculated with MPV. Cages containing infected mice were interspersed among 14 cages housing naïve Swiss Webster mice. At 1, 2, and 4 wk after inoculation of the mice, cages were changed across each row. All naïve mice housed adjacent to infected mice remained seronegative. To determine the risk of environmental contamination, nesting pads that were used to sample the room floor during husbandry procedures at 1, 2, 4, and 6 wk after inoculation of the mice were placed in cages with naïve mice. None of the mice exposed to the pads became MPV seropositive. To determine whether components from cages that had housed MPV-infected mice could transmit MPV, Swiss Webster mice were exposed to soiled bedding or used cages, drinking valves, food, cage bottoms, wire bars and filter tops, nesting material, or shelters. With the exception of drinking valves, all mice exposed to other components became MPV seropositive. Fourteen cages that had housed MPV-infected mice were washed but not autoclaved; mice housed in the washed cages did not become MPV seropositive. In conclusion, all cage components can serve as fomites, with the drinking valve being the least risky. Cage washing alone was sufficient to remove or inactivate MPV.

Transmission of mouse parvovirus to neonatal mice.

To investigate the infection of newborn mice with mouse parvovirus (MPV), a single MPV-infected mouse was added to each of 15 cages, each of which housed an uninfected breeding pair of Swiss Webster mice just before parturition. Seven litters were left with their parents, and the remaining 8 litters were fostered at postpartum day 1. All dams were shedding MPV at 1 and 2 wk after exposure. Soiled-bedding transmission did not differ between cages with and without litters. Half the foster dams but none of the fostered pups seroconverted to MPV. None of the pups left with their birth mothers had MPV DNA in their feces at 3 or 6 wk after exposure, but pups in 6 of 7 litters were MPV seropositive at 6 wk. To investigate MPV infection of older neonatal mice, 9 dams with 7-d-old litters and 9 dams with 14-d-old litters each were exposed to an MPV-infected mouse. At weaning, pups exposed to MPV at 7 or 14 d of age were shedding MPV and were seronegative but became seropositive by 6 wk of age and transmitted the infection to sentinels. In conclusion, fostering of pups had no benefit and may spread infection because the pups may act as fomites, infecting the foster dam. Infection of 7- or 14-d-old mice likely occurred because maternal antibodies had not been transferred to the progeny before they began to ingest MPV-laden feces.

An implantable vascularized protein gel construct that supports human fetal hepatoblast survival and infection by hepatitis C virus in mice.

BACKGROUND: Widely accessible small animal models suitable for the study of hepatitis C virus (HCV) in vivo are lacking, primarily because rodent hepatocytes cannot be productively infected and because human hepatocytes are not easily engrafted in immunodeficient mice. METHODOLOGY/PRINCIPAL FINDINGS: We report here on a novel approach for human hepatocyte engraftment that involves subcutaneous implantation of primary human fetal hepatoblasts (HFH) within a vascularized rat collagen type I/human fibronectin (rCI/hFN) gel containing Bcl-2-transduced human umbilical vein endothelial cells (Bcl-2-HUVEC) in severe combined immunodeficient X beige (SCID/bg) mice. Maturing hepatic epithelial cells in HFH/Bcl-2-HUVEC co-implants displayed endocytotic activity at the basolateral surface, canalicular microvilli and apical tight junctions between adjacent cells assessed by transmission electron microscopy. Some primary HFH, but not Huh-7.5 hepatoma cells, appeared to differentiate towards a cholangiocyte lineage within the gels, based on histological appearance and cytokeratin 7 (CK7) mRNA and protein expression. Levels of human albumin and hepatic nuclear factor 4alpha (HNF4alpha) mRNA expression in gel implants and plasma human albumin levels in mice engrafted with HFH and Bcl-2-HUVEC were somewhat enhanced by including murine liver-like basement membrane (mLBM) components and/or hepatocyte growth factor (HGF)-HUVEC within the gel matrix. Following ex vivo viral adsorption, both HFH/Bcl-2-HUVEC and Huh-7.5/Bcl-2-HUVEC co-implants sustained HCV Jc1 infection for at least 2 weeks in vivo, based on qRT-PCR and immunoelectron microscopic (IEM) analyses of gel tissue. CONCLUSION/SIGNIFICANCE: The system described here thus provides the basis for a simple and robust small animal model of HFH engraftment that is applicable to the study of HCV infections in vivo.

Effect of murine norovirus infection on mouse parvovirus infection.

Enzootic infection with mouse parvovirus (MPV) remains a common problem in laboratory colonies, and diagnosis of MPV infection is complicated by viral and host factors. The effect of an underlying viral infection on MPV infection has not previously been investigated. We assessed the effect of murine norovirus (MNV) infection, the most prevalent infectious agent in laboratory mice, on MPV shedding, tissue distribution and transmission. Fecal MPV shedding persisted longer in BALB/c mice infected with MNV 1 wk prior to MPV infection than in mice infected with MPV only, but transmission of MPV to soiled-bedding sentinels was not prolonged in coinfected mice. MPV DNA levels in coinfected BALB/c mice were higher in mesenteric lymph nodes and spleens at 1 and 2 wk after inoculation and in small intestines at 1 wk after inoculation compared with levels in mice infected with MPV only. In C57BL/6 mice, fecal shedding was prolonged, but no difference in soiled bedding transmission or MPV DNA levels in tissues was detected between singly and coinfected mice. MPV DNA levels in singly and coinfected SW mice were similar. MPV DNA levels were highest in SW, intermediate in BALB/c and lowest in C57BL/6 mice. MPV DNA levels in mesenteric lymph nodes of BALB/c and SW mice exceeded those in small intestines and feces, whereas the inverse occurred in C57BL/6 mice. In conclusion, MNV infection increased the duration of MPV shedding and increased MPV DNA levels in tissues of BALB/c mice.

A PCR-based strategy for detection of mouse parvovirus.

Mouse parvovirus (MPV) infection is difficult to address because it is asymptomatic, persists for as long as 9 wk, and occurs in small subpopulations of mice. The efficacy of a PCR-based cage swabbing strategy for MPV detection was tested. On postinoculation days (PID) 3 through 63, feces were collected from MPV-infected SW mice or the wire bars and cage wall above and below the bedding were swabbed. MPV DNA was detected in all cages in all locations on PID 7 and 14 but only below the bedding on PID 21. Swabbing below the bedding detected MPV in most cages through PID 42. Sentinels exposed to soiled cages on PID 7 and 14 but not on PID 21 seroconverted. MPV was detected in feces from all cages until PID 33 and in at least 1 cage until PID 56. In BALB/c mice, MPV was detected in feces and on cage swabs on PID 5 to 14, and 80% of sentinels exposed to soiled cages on PID 7 and 14 seroconverted. In comparison, MPV infection of C57BL/6 mice was detected in feces on PID 5 to 14 and on swabs on PID 5 and 7, and 30% of sentinels exposed to soiled cages on PID 7 and 14 seroconverted. Swabbing of multiple cages in rows in which only 1 cage contained MPV-infected mice was ineffective. In conclusion, swabbing of individual cages can be used in a genotype-dependent manner as an adjunct to soiled bedding sentinels during the first 2 wk of infection.

Rat hepatocyte engraftment in severe combined immunodeficient x beige mice using mouse-specific anti-fas antibody.

BACKGROUND: Hepatocyte transplantation holds promise as a treatment for acute and chronic liver failure; however, robust model systems needed to study xenogeneic hepatocyte transfer are lacking. Severe combined immunodeficient x beige (SCID/bg) hybrid mice readily accept foreign tissue. Repopulation of C.B-17 SCID/bg mouse liver with rat hepatocytes was studied following induction of mouse hepatocyte apoptosis using an anti-mouse agonistic fas monoclonal antibody (Jo2 mAb) that does not engage xenogeneic fas. METHODS: SCID/bg mice were transplanted with 1 x 10(6) fresh adult rat hepatocytes intrasplenically and treated with various doses, routes and frequencies of Jo2 mAb. Rat cell repopulation was characterized by quantitative immunofluorescent antibody (q-IFA) staining specific for rat dipeptidyl peptidase type IV (DPP-IV) and leucine amino peptidase, amplification of rat genomic DNA using polymerase chain reaction and histopathological and serum biochemistry analyses. RESULTS: Analysis of liver sections from mice treated twice weekly for 12 weeks with 0.4 mg/kg Jo2 mAb intraperitoneally consistently demonstrated >50% rat hepatocytes in the parenchymal mass by q-IFA. Rat hepatocyte engraftment protected mice from Jo2 mAb-mediated liver hemorrhage and hepatocyte apoptosis. Serum liver enzyme levels did not increase in Jo2 mAb-treated mice that were highly engrafted with rat hepatocytes, in contrast to matched non-engrafted mice. At 12 weeks post-engraftment, minimal fibrosis and inflammation were apparent and liver architecture had returned to near normal. Jo2 mAb did not induce histopathological abnormalities in other tissues known to express fas antigen (i.e. heart, lung). CONCLUSIONS: This novel model represents a simple and robust system of xenogeneic hepatocyte transplantation that could be applied to studies of liver biology, regeneration and hepatocyte transplantation.

Efficacy of three microbiological monitoring methods in a ventilated cage rack.

The use of individually ventilated caging (IVC) to house mice presents new challenges for effective microbiological monitoring. Methods that exploit the characteristics of IVC have been developed, but to the authors' knowledge, their efficacy has not been systematically investigated. Air exhausted from the IVC rack can be monitored, using sentinels housed in cages that receive rack exhaust air as their supply air, or using filters placed on the exhaust air port. To aid laboratory animal personnel in making informed decisions about effective methods for microbiological monitoring of mice in IVC, the efficacy of air monitoring methods was compared with that of contact and soiled bedding sentinel monitoring. Mice were infected with mouse hepatitis virus (MHV), mouse parvovirus (MPV), murine rotavirus (agent of epizootic diarrhea of mice [EDIM]), Sendai virus (SV), or Helicobacter spp. All agents were detected using contact sentinels. Mouse hepatitis virus was effectively detected in air and soiled bedding sentinels, and SV was detected in air sentinels only. Mouse parvovirus and Helicobacter spp. were transmitted in soiled bedding, but the efficacy of transfer was dependent on the frequency and dilution of soiled bedding transferred. Results were similar when the IVC rack was operated under positive or negative air pressure. Filters were more effective at detecting MHV and SV than they were at detecting MPV. Exposure of sentinels or filters to exhaust air was effective at detecting several infectious agents, and use of these methods could increase the efficacy of microbiological monitoring programs, especially if used with soiled bedding sentinels. In contemporary mouse colonies, a multi-faceted approach to microbiological monitoring is recommended.

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.

Pathogenesis of enterotropic mouse hepatitis virus in immunocompetent and immunodeficient mice.

Mouse hepatitis virus (MHV) is one of the most prevalent viruses infecting laboratory mice. Most natural infections are caused by enterotropic strains. Experiments were done to compare the pathogenesis of enterotropic strain MHV-Y in immunocompetent BALB/c and C57BL/6 mice with that in B and T cell-deficient mice. In situ hybridization was used to identify sites of virus replication, and reverse transcriptase-polymerase chain reaction analysis was used to detect viral RNA in feces and blood. MHV-Y caused acute subclinical infections restricted to the gastrointestinal tract in BALB/c and C57BL/6 mice. Viral RNA was detected in small intestine and associated lymphoid tissues of immunocompetent mice for 1 week and in cecum and colon for 2 weeks. Infected B cell-deficient mice developed chronic subclinical infection also restricted to the gastrointestinal tract. Viral RNA was detected in the small intestine, cecum, colon, and feces for 7 to 8 weeks. In contrast, infected T cell-deficient mice developed multisystemic lethal infection. During the first week, viral RNA was restricted to the gastrointestinal tract. However, by 2 weeks, mice developed peritonitis, and viral RNA was detected in mesentery and visceral peritoneum. Three to four weeks after virus inoculation, T cell-deficient mice became moribund and viral RNA was detected in multiple organ systems. These results suggest that B cells promote clearance of MHV-Y from intestinal mucosa and that T cells are required to prevent dissemination of MHV-Y from the gastrointestinal tract and associated lymphoid tissues.

Immune responses to the major capsid protein during parvovirus infection of rats.

Rat virus (RV) is a common parvovirus of laboratory rodents which can disrupt rat-based research. Prenatal or perinatal infection can be pathogenic or lead to persistent infection, whereas infection of adult rats is typically self-limiting. Effects on the host immune system have been documented during RV infection, but little is known about immune responses necessary for viral clearance. Our studies were conducted to identify humoral and cellular responses to the predominant capsid protein, VP2, during experimental infection of adult rats. We observed VP2-specific proliferation, gamma interferon production, and an immunoglobulin G2a humoral response that is maintained for at least 35 days following RV infection. These results strongly suggest the induction of virus-specific Th1-mediated immunity.

Validation of an enzyme-linked immunosorbent assay for detection of mouse parvovirus infection in laboratory mice.

PURPOSE: Parvoviruses are among the most prevalent infectious agents in mouse colonies. Infection in laboratory mice is confirmed by detection of serum antibodies to these agents, and most diagnostic tests cannot distinguish serogroup of the infecting agent. The principal objective of the research reported here was to develop and validate a sensitive, serogroup-specific diagnostic test that will distinguish between mouse parvovirus (MPV) and minute virus of mice (MVM) infection. METHODS: The MPV VP2 protein was expressed in bacteria, purified by use of metal-chelation chromatography, and used as antigen in an ELISA. More than 580 sera from uninfected mice and experimentally or naturally infected mice were screened by MPV indirect fluorescent antibody (IFA) test, then were re-tested using the MPV ELISA to define test sensitivity and specificity. An additional 3,700 sera were screened using a variety of tests, including the MPV ELISA and recombinant NS1 ELISA (rNS1 ELISA). RESULTS: Using MPV IFA test results as a benchmark, the MPV ELISA had sensitivity of 92.3% and specificity of 99.8%. In addition, the MPV ELISA detected anti-viral antibodies at a higher dilution of serum than did the IFA test, and confirmed the infecting agent as MPV or MVM. When compared directly in a commercial laboratory, the MPV ELISA had higher sensitivity (90.3% versus 65%) than and similar specificity (98.3% versus 99.6%) to the rNS1 ELISA. CONCLUSION: The MPV VP2 ELISA provides a sensitive, serogroup-specific alternative for diagnosis and classification of parvovirus infection in laboratory mice.