A field strain of minute virus of mice (MVMm) exhibits age- and strain-specific pathogenesis.

The influence of mouse strain, immune competence and age on the pathogenesis of a field strain of minute virus of mice (MVMm) was examined in BALB/c, C3H, C57BL/6 and SCID mice experimentally infected as neonates, weanlings and adults. Sera, bodily excretions and tissues were harvested at 7, 14, 28 and 56 days after inoculation and evaluated by serology, quantitative PCR and histopathology. Seroconversion to recombinant viral capsid protein 2 was consistently observed in all immunocompetent strains of mice, regardless of the age at which they were inoculated, while seroconversion to the viral nonstructural protein 1 was only consistently detected in neonate inoculates. Viral DNA was detected by quantitative PCR in multiple tissues of immunocompetent mice at each time point after inoculation, with the highest levels being observed in neonate inoculates at 7 days after inoculation. In contrast, viral DNA levels in tissues and bodily excretions increased consistently over time in immunodeficient SCID mice, regardless of the age at which they were inoculated, with mortality being observed in neonatal inoculates between 28 and 56 days after inoculation. Overall, productive infection was observed more frequently in immunocompetent mice inoculated as neonates as compared to those inoculated as weanlings or adults, and immunodeficient SCID mice developed persistent, progressive infection, with mortality being observed in mice inoculated as neonates. Importantly, the clinical syndrome observed in experimentally infected SCID neonatal mice recapitulates the clinical presentation reported for the naturally infected immunodeficient NOD µ-chain knockout mice from which MVMm was initially isolated.

Elimination of Pasteurella pneumotropica from a mouse barrier facility by using a modified enrofloxacin treatment regimen.

Multiple NOD. Cg-Prkdc(scid)Il2rg(tm1Wjl)Tg(HLA-A2.1)Enge/Sz (NSG/A2) transgenic mice maintained in a mouse barrier facility were submitted for necropsy to determine the cause of facial alopecia, tachypnea, dyspnea, and sudden death. Pneumonia and soft-tissue abscesses were observed, and Pasteurella pneumotropica biotype Jawetz was consistently isolated from the upper respiratory tract, lung, and abscesses. Epidemiologic investigation within the facility revealed presence of this pathogen in mice generated or rederived by the intramural Genetically Engineered Mouse Model (GEMM) Core but not in mice procured from several approved commercial vendors. Epidemiologic data suggested the infection originated from female or vasectomized male ND4 mice obtained from a commercial vendor and then comingled by the GEMM Core to induce pseudopregnancy in female mice for embryo implantation. Enrofloxacin delivered in drinking water (85 mg/kg body weight daily) for 14 d was sufficient to clear bacterial infection in normal, breeding, and immune-deficient mice without the need to change the antibiotic water source. This modified treatment regimen was administered to 2400 cages of mice to eradicate Pasteurella pneumotropica from the facility. Follow-up PCR testing for P. pneumotropica biotype Jawetz remained uniformly negative at 2, 6, 12, and 52 wk after treatment in multiple strains of mice that were originally infected. Together, these data indicate that enrofloxacin can eradicate P. pneumotropica from infected mice in a less labor-intensive approach that does not require breeding cessation and that is easily adaptable to the standard biweekly cage change schedule for individually ventilated cages.

Experimental infection of mice with hamster parvovirus: evidence for interspecies transmission of mouse parvovirus 3.

Hamster parvovirus (HaPV) was isolated 2 decades ago from hamsters with clinical signs similar to those induced in hamsters experimentally infected with other rodent parvoviruses. Genetically, HaPV is most closely related to mouse parvovirus (MPV), which induces subclinical infection in mice. A novel MPV strain, MPV3, was detected recently in naturally infected mice, and genomic sequence analysis indicates that MPV3 is almost identical to HaPV. The goal of the present studies was to examine the infectivity of HaPV in mice. Neonatal and weanling mice of several mouse strains were inoculated with HaPV. Tissues, excretions, and sera were harvested at 1, 2, 4, and 8 wk after inoculation and evaluated by quantitative PCR and serologic assays specific for HaPV. Quantitative PCR detected viral DNA quantities that greatly exceeded the quantity of virus in inocula in multiple tissues of infected mice. Seroconversion to both nonstructural and structural viral proteins was detected in most immunocompetent mice 2 or more weeks after inoculation with HaPV. In neonatal SCID mice, viral transcripts were detected in lymphoid tissues by RT-PCR and viral DNA was detected in feces by quantitative PCR at 8 wk after inoculation. No clinical signs, gross, or histologic lesions were observed. These findings are similar to those observed in mice infected with MPV. These data support the hypothesis that HaPV and MPV3 are likely variants of the same viral species, for which the mouse is the natural rodent host with rare interspecies transmission to the hamster.

Embryo transfer rederivation of C.B-17/Icr-Prkdc(scid) mice experimentally infected with mouse parvovirus 1.

We determined whether embryos derived from C.B-17/Icr-Prkdc(scid) (SCID) mice infected with mouse parvovirus (MPV) 1b and mated to MPV-naive B6C3F1 mice would transmit virus to naive recipient female mice and rederived progeny. Viral DNA was detected by quantitative PCR (qPCR) in lymphoid tissues, gonad, sperm, and feces of all MPV1b-inoculated SCID mice. Viral DNA was detected in 1 of 16 aliquots of embryos from infected male SCID mice and in 12 of 18 aliquots of embryos from infected female SCID mice. All recipient female mice implanted with embryos from infected SCID male mice and their progeny were negative by serology and qPCR. In contrast, 3 of 5 recipient female mice implanted with embryos from infected SCID female mice and 14 of 15 progeny mice from these recipients were seropositive by multiplex fluorescent immunoassay (MFI) for MPV capsid antigen (rVP2). All of these mice were negative by MFI for parvovirus nonstructural protein antigen (rNS1) and by qPCR, with the exception of 1 recipient female mouse that displayed weak rNS1 seroreactivity and low levels of MPV DNA in lymphoid tissues. Seroreactivity to rVP2 declined over time in all progeny mice from infected SCID female mice until all were seronegative by 20 wk of age, consistent with maternal antibody transfer. Given that the high levels of MPV contamination detected in our experimentally infected SCID mice are unlikely in naturally infected immunocompetent mice, these data indicate that embryo transfer rederivation is effective for the eradication of MPV from infected colonies.

Transmission probabilities of mouse parvovirus 1 to sentinel mice chronically exposed to serial dilutions of contaminated bedding.

Intermittent serodetection of mouse parvovirus (MPV) infections in animal facilities occurs frequently when soiled bedding sentinel mouse monitoring systems are used. We evaluated induction of seroconversion in naïve single-caged weanling ICR mice (n = 10 per group) maintained on 5-fold serially diluted contaminated bedding obtained from SCID mice persistently shedding MPV1e. Soiled bedding from the infected SCID mice was collected, diluted, and redistributed weekly to cages housing ICR mice to represent chronic exposure to MPV at varying prevalence in a research colony. Sera was collected every other week for 12 wk and evaluated for reactivity to MPV nonstructural and capsid antigens by multiplex fluorescent immunoassay. Mice were euthanized after seroconversion, and DNA extracted from lymph node and spleen was evaluated by quantitative PCR. Cumulative incidence of MPV infection for each of the 7 soiled bedding dilution groups (range, 1:5 to 1:78125 [v/v]) was 100%, 100%, 90%, 20%, 70%, 60%, and 20%, respectively. Most seropositive mice (78%) converted within the first 2 to 3 wk of soiled bedding exposure, correlating to viral exposure when mice were 4 to 7 wk of age. Viral DNA was detected in lymphoid tissues collected from all mice that were seropositive to VP2 capsid antigen, whereas viral DNA was not detected in lymphoid tissue of seronegative mice. These data indicate seroconversion occurs consistently in young mice exposed to high doses of virus equivalent to fecal MPV loads observed in acutely infected mice, whereas seroconversion is inconsistent in mice chronically exposed to lower doses of virus.

Temporal transmission studies of mouse parvovirus 1 in BALB/c and C.B-17/Icr-Prkdc(scid) mice.

Fecal shedding and transmission of mouse parvovirus 1 (MPV) to naive sentinels, breeding mates, and progeny were assessed. Neonatal SCID and BALB/c mice inoculated with MPV were evaluated over 24 wk; several mice from each strain were mated once during this period. Fecal MPV loads for each cage were determined weekly by quantitative polymerase chain reaction (PCR) analysis, and all mice were evaluated by quantitative PCR analysis of lymphoid tissues and seroconversion to MPV antigens in immunocompetent mice. Results indicated persistently high fecal shedding of MPV in SCID mice throughout the evaluation period sufficient to allow transmission to sentinels, naive breeding partners, and the progeny of infected male mice and naive partners. Lymphoid tissue viral loads in the progeny of infected female SCID mice were high at weaning but low at 6 wk of age. Infected BALB/c mice shed high levels of MPV in feces for 3 wk postinoculation, with seroconversion only in sentinels exposed during the first 2 wk postinoculation. Thereafter the feces of infected BALB/c mice and the lymphoid tissues of sentinels, naive breeding partners, and progeny intermittently contained extremely low levels of MPV DNA. Although pregnancy and lactation did not increase viral shedding in BALB/c mice, MPV exposure levels were sufficient to induce productive infection in some BALB/c progeny. These data indicate that the adaptive immune response suppresses, but does not eliminate, MPV shedding; this suppression is sufficient to inhibit infection of weanling and adult mice but allows productive infection of some progeny.

Identification of novel murine parvovirus strains by epidemiological analysis of naturally infected mice.

Random-source DNA samples obtained from naturally infected laboratory mice (n=381) were evaluated by PCR and RFLP analysis to determine the prevalence of murine parvovirus strains circulating in contemporary laboratory mouse colonies. Mouse parvovirus (MPV) was detected in 77% of samples, Minute virus of mice (MVM) was detected in 16% of samples and both MVM and MPV were detected in 7% of samples. MVMm, a strain recently isolated from clinically ill NOD-mu chain knockout mice, was detected in 91% of MVM-positive samples, with the Cutter strain of MVM (MVMc) detected in the remaining samples. The prototypic and immunosuppressive strains of MVM were not detected in any of the samples. MPV-1 was detected in 78% of the MPV-positive samples and two newly identified murine parvoviruses, tentatively named MPV-2 and MPV-3, were detected in 21 and 1% of the samples, respectively. The DNA sequence encompassing coding regions of the viral genome and the predicted protein sequences for MVMm, MPV-2 and MPV-3 were determined and compared with those of other rodent parvovirus strains and LuIII parvovirus. The genomic organization for the newly identified viral strains was similar to that of other rodent parvoviruses, and nucleotide sequence identities indicated that MVMm was most similar to MVMc (96.1%), MPV-3 was most similar to hamster parvovirus (HaPV) (98.1%) and MPV-2 was most similar to MPV-1 (95.3%). The genetic similarity of MPV-3 and HaPV suggests that HaPV epizootics in hamsters may result from cross-species transmission, with mice as the natural rodent host for this virus.

Detection of Mycoplasma pulmonis by fluorogenic nuclease polymerase chain reaction analysis.

Mycoplasma pulmonis induces persistent infections in laboratory mice and rats and can contaminate biological materials. We developed a fluorogenic nuclease polymerase chain reaction (fnPCR) assay to detect M. pulmonis specifically. Primer and probe sequences for the assay were targeted to 16S rRNA sequences specific to M. pulmonis. The assay consistently detected the equivalent of fewer than 10 copies of template DNA. When evaluated against a panel of 24 species of bacteria, the M. pulmonis assay detected only M. pulmonis isolates. Evaluation of 10-fold serial dilutions of cultured M. pulmonis showed that the M. pulmonis fnPCR assay and culture on Dutch agar had comparable sensitivity in detecting viable M. pulmonis organisms, whereas the mouse antibody production test displayed positive serologic results at dilutions higher than those in which viable organisms could be detected. Finally, the M. pulmonis fnPCR assay was able to detect M. pulmonis DNA in nasopharyngeal wash fluid and trachea, lung, and uterus tissue collected from mice naturally infected with M. pulmonis but did not detect the organism in similar samples collected from uninfected, negative control mice. The M. pulmonis fnPCR assay provides a high-throughput, PCR-based method to detect M. pulmonis in infected rodents and contaminated biological materials.

Detection of lactate dehydrogenase-elevating virus by use of a fluorogenic nuclease reverse transcriptase-polymerase chain reaction assay.

Lactate dehydrogenase-elevating virus (LDEV) induces persistent infections in laboratory mice, alters in vivo physiology, and is a common contaminant of biological materials such as transplantable tumor cell lines. The fluorogenic nuclease reverse transcriptase polymerase chain reaction (fnRT-PCR) assay combines RT-PCR analysis with an internal fluorogenic hybridization probe, thereby eliminating post-PCR processing and potentially enhancing specificity. An fnRT-PCR assay specific for LDEV was therefore developed by targeting primer and probe sequences to a unique region of the LDEV nucleocapsid (VP1) gene. Using the LDEV fnRT-PCR assay, we detected only LDEV and did not detect other RNA viruses that are capable of naturally infecting rodents. Using this assay, we detected as little as 10 fg of LDEV RNA; the assay was 10-fold less sensitive when directly compared with the mouse bioassay (measurement of serum LD after inoculation), without the problematic false-positive serum LD enzyme elevations associated with the mouse bioassay. Using the fnRT-PCR assay, we also were able to detect viral RNA in numerous tissues and in feces collected from experimentally inoculated C3H/HeN mice, but we did not detect any viral RNA in similar samples collected from age- and strain-matched mock-infected mice. Finally, using the fnRT-PCR assay, we were able to detect LDEV RNA in biological samples that had previously been determined to be contaminated with LDEV by use of the mouse bioassay and an RT-PCR assay at another laboratory. In conclusion, the LDEV fnRT-PCR assay is a potentially high-throughput diagnostic assay for detection of LDEV in mice and contaminated biological materials.

Detection of sendai virus and pneumonia virus of mice by use of fluorogenic nuclease reverse transcriptase polymerase chain reaction analysis.

Sendai virus may induce acute respiratory tract disease in laboratory mice and is a common contaminant of biological materials. Pneumonia virus of mice (PVM) also infects the respiratory tract and, like Sendai virus, may induce a persistent wasting disease syndrome in immunodeficient mice. Reverse transcriptase-polymerase chain reaction (RT-PCR) assays have proven useful for detection of Sendai virus and PVM immunodeficient animals and contaminated biomaterials. Fluorogenic nuclease RT-PCR assays (fnRT-PCR) combine RT-PCR with an internal fluorogenic hybridization probe, thereby potentially enhancing specificity and eliminating post-PCR processing. Therefore, fnRT-PCR assays specific for Sendai virus and PVM were developed by targeting primer andprobe sequences to unique regions of the Sendai virus nucleocapsid (NP) gene and the PVM attachment (G) gene, respectively. The Sendai virus and PVM fnRT-PCR assays detected only Sendai virusand PVM , respectively. Neither assay detected other viruses of the family Paramyxoviridae or other RNA viruses that naturally infect rodents. The fnRT-PCR assays detected as little as 10 fg of Sendai virus RNA and one picogram of PVM RNA, respectively, andthe Sendai virus fnRT-PCR assay had comparable sensitivity when directly compared with the mouse antibody production test. The fnRT-PCR assays were also able to detect viral RNA in respiratory tract tissues and cage swipe specimens collected from experimentally inoculated C.B-17 severe combined immunodeficient mice, but did not detect viral RNA in age- and strain-matched mock-infected mice. In conclusion, these fnRT-PCR assays offer potentially high-throughput diagnostic assays to detect Sendai virus and PVM in immunodeficient mice, and to detect Sendai virus in contaminated biological materials.

Detection of lymphocytic choriomeningitis virus by use of fluorogenic nuclease reverse transcriptase-polymerase chain reaction analysis.

Lymphocytic choriomeningitis virus (LCMV) induces persistent infections in laboratory mice; is a known contaminant of biological materials, such as transplantable tumor cell lines; and is of great concern in animal facilities due to its zoonotic potential. Fluorogenic nuclease reverse transcriptase-polymerase chain reaction (fnRT-PCR) assays combine RT-PCR with an internal fluorogenic hybridization probe, thereby potentially enhancing specificity and eliminating post-PCR processing. An fnRT-PCR assay specific for LCMV was, therefore, developed by targeting primer and probe sequences to a unique region of the LCMV nucleocapsid (NP) gene. The LCMV fnRT-PCR assay detected only LCMV and did not detect other RNA viruses that naturally infect rodents. The fnRT-PCR assay detected as little as one picogram of LCMV RNA, but was 100-fold less sensitive when directly compared with the mouse antibody production test. The fnRT-PCR assay was also able to detect viral RNA in numerous tissues and in feces and cage swipe specimens collected from experimentally inoculated BALB/c mice, but did not detect any viral RNA in similar samples collected from age- and strain-matched mock-infected mice. In conclusion, the LCMV fnRT-PCR assay offers a potentially high-throughput diagnostic assay to detect LCMV in mice and contaminated biological materials.

Detection of rodent coronaviruses by use of fluorogenic reverse transcriptase-polymerase chain reaction analysis.

Reverse transcriptase-polymerase chain reaction (RT-PCR) assays have proved useful for the detection of mouse hepatitis virus (MHV) and rat coronavirus (RCV) in acutely infected animals and contaminated biomaterials. Fluorogenic nuclease RT-PCR assays combine RT-PCR with an internal fluorogenic hybridization probe, thereby eliminating post-PCR processing and potentially enhancing specificity. Consequently, a fluorogenic nuclease RT-PCR assay specific for rodent coronaviruses was developed. Primer and probe sequences were selected from the viral genome segment that encodes the membrane (M) protein that is highly conserved among rodent coronaviruses. Use of the fluorogenic nuclease RT-PCR detected all strains of MHV and RCV that were evaluated, but did not detect other RNA viruses that naturally infect rodents. Use of the assay detected as little as two femtograms of in vitro transcribed RNA generated from cloned amplicon, and when compared directly with mouse antibody production tests, had similar sensitivity at detecting MHV-A59 in infected cell culture lysates. Finally, use of the assay detected coronavirus RNA in tissues, cage swipes, and feces obtained from mice experimentally infected with MHV, and in tissues and cage swipes obtained from rats naturally infected with RCV. These results indicate that the fluorogenic nuclease RT-PCR assay should provide a potentially high-throughput, PCR-based method to detect rodent coronaviruses in infected rodents and contaminated biological materials.