Antigen-reactive cells in normal, immunized, and tolerant mice.

The numbers of antigen-reactive cells (ARC) responding to a purified protein, the polymer of S. adelaide flagellin, have been assayed in cell populations derived from several lymphoid tissues of mice. The assay, which employs the cell transfer into lethally irradiated mice, indicates that there is a response of ARC in bone marrow in the absence of thymus cells. This suggests that the immune response to this protein antigen is not thymus dependent. The presence of relatively large numbers of ARC in Peyer's patches argues for their direct participation in the immune response in the adult mouse. The kinetics of ARC and antibody-forming cells in the early primary response employing the transfer system is described. The numbers of ARC declined during the first 2 days of the immune response, but by day 6 had increased to about five times the number in unprimed spleen cells. The rise is believed to be a result of the primary injection of antigen and therefore may be described as memory; however, these experiments have not been able to further elucidate any specific qualities of the "memory cell." Tolerance induction in C(57)BL/Brad mice produced by repeated injections of a cyanogen bromide digest of the antigen is described. The ARC or its precursor is shown to be the site of the lesion of tolerance by direct investigation.

Cmv-1, a genetic locus that controls murine cytomegalovirus replication in the spleen.

The genetic basis of the control of acute splenic MCMV infection was studied after intraperitoneal inoculation of the virus. Classical Mendelian analyses using C57BL/6 (resistant) and BALB/c (susceptible) parental strains disclosed an autosomal dominant non-H-2 gene that regulates splenic virus replication. The probable location of this gene, to which we have assigned the symbol Cmv-1, is on chromosome 6 as defined by the strain distribution pattern of splenic MCMV replication in CXB recombinant inbred mice. Although there is a similar hierarchy of resistance to MCMV and HSV-1 with respect to the C57BL and BALB genetic backgrounds, the strain distribution pattern of HSV-1 replication in recombinant inbred mice suggests that Cmv-1 is not involved in restricting the spread of this virus. This is the first clear identification of a non-H-2 gene regulating the magnitude of MCMV infection. Elucidation of the function of this gene may be a fundamental step towards understanding the control of systemic CMV infection.

Laboratory strains of murine cytomegalovirus are genetically similar to but phenotypically distinct from wild strains of virus.

Murine cytomegalovirus (MCMV) is widely used to model human cytomegalovirus (HCMV) infection. However, it is known that serially passaged laboratory strains of HCMV differ significantly from recently isolated clinical strains of HCMV. It is therefore axiomatic that clinical models of HCMV using serially passaged strains of MCMV may not be able to fully represent the complexities of the system they are attempting to model and may not fully represent the complex biology of MCMV. To determine whether genotypic and phenotypic differences also exist between laboratory strains of MCMV and wild derived strains of MCMV, we sequenced the genomes of three low-passage strains of MCMV, plus the laboratory strain, K181. We coupled this genetic characterization to their phenotypic characteristics. In contrast to what is seen with HCMV (and rhesus CMV), there were no major genomic rearrangements in the MCMV genomes. In addition, the genome size was remarkably conserved between MCMV strains with no major insertions or deletions. There was, however, significant sequence variation between strains of MCMV, particularly at the genomic termini. These more subtle genetic differences led to considerable differences in in vivo replication with some strains of MCMV, such as WP15B, replicating preferentially in otherwise-MCMV-resistant C57BL/6 mice. CBA mice were no more resistant to MCMV than C57BL/6 mice and for some MCMV strains appeared to control infection less well than C57BL/6 mice. It is apparent that the previously described host resistance patterns of inbred mice and MCMV are not consistently applicable for all MCMV strains.

Biological control of vertebrate pests using virally vectored immunocontraception.

Species-specific viruses are being genetically engineered to produce contraceptive biological controls for pest animals such as mice, rabbits and foxes. The virus vaccines are intended to trigger an autoimmune response in the target animals that interferes with their fertility in a process termed virally vectored immunocontraception. Laboratory experiments have shown that high levels of infertility can be induced in mice infected with recombinant murine cytomegalovirus and ectromelia virus expressing reproductive antigens as well as in rabbits using myxoma virus vectors. The strategies used to produce and deliver species-specific immunocontraceptive vaccines to free-living wildlife are presented in this review. Discussion includes coverage of the likely safety of the proposed vaccines as well as the implications of the approach for fertility control in other species.

Fractionation of cytotoxic cells from tumour-immune rats on derivatized collagen gels.

Incubation at 37 degrees C of spleen cells from rats, immunized with Gross virus-induced lymphoma, on collagen gels coated with membrane extracts of lymphoma cells yielded two different cell populations. The non-adherent cells showed greatly diminished cytotocicity for lymphoma cells compared with unfractionated spleen cell suspensions, whilst the specifically adherent cells which were recovered after collagenase digestion of the gels, showed enrichment of cytotoxic activity.

Standardisation of a microplate in situ ELISA (MISE-test) for the susceptibility testing of herpes simplex virus to acyclovir.

Viral susceptibility testing has been traditionally performed by plaque reduction assay (PRA) which is labour intensive, time consuming and requires subjective input by the reader. An in situ enzyme-linked immunosorbent assay (ELISA) method has been developed with the potential to overcome many of the limitations of PRA, and has been applied to a variety of viruses. Previous reports of ELISA susceptibility assays have shown little standardisation between these methods, or any significant analysis of the variable factors which may influence the outcome of the assay. This study optimised the sensitivity of a microplate in situ ELISA (MISE-test) for the detection of viral growth, manipulated the interaction between cells, virus and acyclovir to determine the effect of their relationship on susceptibility results, and established standard assay conditions based on quality controlled parameters such as assay variability and linear ranges. 33 isolates of HSV-2 were tested for susceptibility to acyclovir by PRA, and the standardised MISE. Factors which were critical to the performance of the MISE included inoculum size, inoculation method, duration of incubation, fixative type, immunoglobulin working strengths and choice of chromogenic substrate. Using the ELISA it was possible to separate sensitive HSV-2 isolates from resistant isolates applying a cutoff ID50 value of 2.0 mg/l. The correlation coefficient between PRA and MISE was 0.65. The standardised microplate in situ ELISA was found to be an acceptable alternative to the plaque reduction assay.

Murine cytomegalovirus binds reversibly to mouse embryo fibroblasts: implications for quantitation and explanation of centrifugal enhancement.

In a study of the infection of mouse embryo fibroblasts with murine cytomegalovirus (MCMV), we found that plaque number is directly related to virus concentration and not to the total amount of virus contained in the inoculum. These results suggested that virus binding was reversible and that during infection a binding equilibrium is established which limits the amount of bound virus. Further analysis revealed three categories of plaque based on reversibility after virus adsorption. One group was removed simply by washing cell monolayers after virus removal. A second group of plaques was lost gradually with time, giving complete reversal after 5 min at 37 degrees C. The rate of reversal was temperature dependent, and probably represented true virus dissociation. The final group was irreversible plaques, the number of which increased with increasing infection time. The number of reversible plaques remained constant with time of infection, and represented about 70% of the total plaques after 1 h of virus adsorption. Centrifugation of the virus inoculum onto the fibroblast monolayer at 1000 X g increased plaque numbers up to 100-fold, but had little effect on plaque number when carried out after the virus inoculum was removed. In contrast centrifugation increased the number of reversible plaques, suggesting an increase in the number of virus particles attached to the cell monolayers. We suggest that centrifugation enhances MCMV infection by three mechanisms related to reversibility of binding: (1), it increases the rate of virus association; (2), it decreases the rate of dissociation; (3), by increasing the length of time each virus particle is bound it increases the probability of virus being taken into the cell.

The potential of murine cytomegalovirus as a viral vector for immunocontraception.

Wild populations of house mice (Mus domesticus) regularly undergo population eruptions in the cereal growing regions of S.E. Australia, causing significant damage to crops. Rodenticides are costly and are of limited usefulness, and the need for a biological control agent is widely recognized. The options for the use of an infectious agent to control mouse populations are considered. The three main types are: infectious agents which establish lethal infection; those which directly interfere with fertility; and recombinant virus vectors encoding fertility-associated proteins such as zona pellucida or sperm antigens in order to induce immunocontraceptive responses in infected mice. Ectromelia, a murine pox virus, has the potential for reducing mouse populations by lethal infection but it is not present in wild mice in Australia. The disadvantages of using ectromelia are that it would pose a significant threat to colonies of laboratory mice, there appears to be substantial innate resistance in Australian wild mice and it may not be entirely mouse-specific, thus placing native rodents at risk. A number of factors influencing the selection of a virus as a vector for immunocontraception are discussed. The mouse-specific murine cytomegalovirus (MCMV) fits most of these criteria. Infection with MCMV is already widespread in Australia with 80-90% of Mus domesticus tested being seropositive. It is a large DNA virus which establishes persistent, non-lethal infection, it is a suitable vector for the insertion of foreign genes and has a number of properties, including the capacity for superinfection, that should assist the recombinant virus to persist in wild mouse populations and induce an immunocontraceptive effect.

Modulation of immunocompetence by cyclosporin A, cyclophosphamide or protein malnutrition potentiates murine cytomegalovirus pneumonitis.

Following intranasal infection with murine cytomegalovirus (MCMV), the levels of viral replication in the lungs of susceptible BALB/c mice were enhanced by treatment with cyclophosphamide (CY), or to a greater extent cyclosporin A (CsA) or the Nu/Nu genotype. Focal inflammation was seen 2-4 days after infection in all groups. This was followed by diffuse interstitial pneumonitis which cleared 12-20 days later in the absence of immunosuppression. Although the initial foci of inflammation were less prominent in infected mice treated with CY or CsA, the most severe interstitial pneumonitis was seen 7 days p.i. in mice given CY, whilst CsA-treatment produced focal and disseminated pneumonitis 7-14 days p.i. and Nu/Nu mice exhibited only the focal response. MCMV-infected mice maintained from weaning on a low protein (4% casein) diet also retained higher titres of virus in their lungs than did normally-fed controls, and displayed more prominent focal pneumonitis.

Genetic control of host resistance to flavivirus infection in animals.

Flaviviruses are small, enveloped RNA viruses which are generally transmitted by arthropods to animals and man. Although flaviviruses cause important diseases in domestic animals and man, flaviviral infection of animals which constitute the normal vertebrate reservoir may be mild or sub-clinical, which suggests that some adaptation between virus and host may have occurred. While this possibility is difficult to study in wild animals, extensive studies using laboratory mice have demonstrated the existence of innate, flavivirus-specific resistance. Resistance is heritable and is attributable to the gene Flvr, which is located on chromosome 5 in this species. The mechanism of resistance is at present unknown, but acts early and limits the replication of flaviviruses in cells. While some evidence supports a role for Flvr in enhancing the production of defective interfering virus, thereby restricting the production of infectious virus, other reports suggest that Flvr interferes with either virus RNA replication or RNA packaging. Recent research suggests that cytoplasmic proteins bind to the viral replication complex and that allelic forms of these proteins in resistant mice may restrict the production of infectious progeny. Apparent resistance to flaviviruses has been described in other vertebrates, although it remains to be seen if this is attributable to a homologue of Flvr. Nonetheless, knowledge gained of the characteristics and function of Flvr in mice should be applicable to other host species, and improvement of resistance to flaviviral infection in domestic animals by selective breeding or gene technology may ultimately be possible.

A serologic survey for viruses and Mycoplasma pulmonis among wild house mice (Mus domesticus) in southeastern Australia.

Plasma samples from 267 wild house mice (Mus domesticus) trapped at 14 sites in southeastern Australia were screened for antibody to 14 viruses normally associated with laboratory-reared rodents and to Mycoplasma pulmonis. Serologic prevalence was high for murine cytomegalovirus (99%, n = 94), murine coronavirus (95%), and murine rotavirus (74%). Samples from mice collected at all sites contained antibody to these viruses. The serologic prevalence was lower for mouse adenovirus, strain K87 (37%), parvovirus (33%), and reovirus type 3 (28%), with substantial site-to-site variation. Plasma from mice collected at 12 sites contained mouse adenovirus or reovirus antibody, and samples from mice at eight sites contained parvovirus antibody. Parvovirus-antibody positive mice were typically from high density populations or from low density populations that had recently declined from high density. Antibody to lymphocytic choriomeningitis virus (LCMV) and Sendai virus occurred at only three sites, and the serologic prevalence was very low (9.6% and 1.8%, respectively). All of the LCMV-positive mice were from northeastern New South Wales. The presence of this zoonotic virus in a mouse plague-prone region raises questions about human health risks resulting from cohabitation with large numbers of mice. It appeared that mouse populations at high density or declining from high density had higher prevalence of viral antibody than populations that had been at low or moderate density for some time. Thus, viral epizootics may occur among high-density populations and may be responsible for or precipitate declines in mouse density. These data raise the possibility of rodent viruses having potential as biological control agents.

Murine viruses in an island population of introduced house mice and endemic short-tailed mice in Western Australia.

House mice (Mus domesticus) were recently introduced to Thevenard Island, off the northwest coast of Western Australia. This island is also habitat for an endangered native rodent, the short-tailed mouse (Leggadina lakedownensis). Concerns have been raised that house mice may pose a threat to L. lakedownensis both through competition and as a source of infection. To assess the threat to L. lakedownensis posed by viral pathogens from M. domesticus, a serological survey was conducted from 1994 to 1996 of both species for evidence of infection with 14 common murine viruses (mouse hepatitis virus, murine cytomegalovirus, lymphocytic choriomeningitis virus, ectromelia virus, mouse adenovirus strains FL and K87, minute virus of mice, mouse parvovirus, reovirus type 3, Sendai virus, Theiler's mouse encephalomyelitis virus, polyoma virus, pneumonia virus of mice, and encephalomyocarditis virus) and Mycoplasma pulmonis. Despite previous evidence that populations of free-living M. domesticus from various locations on the Australian mainland were infected with up to eight viruses, M. domesticus on Thevenard Island were seropositive only to murine cytomegalovirus (MCMV). Antibodies to MCMV were detected in this species at all times of sampling, although seroprevalence varied. Infectious MCMV could be isolated in culture of salivary gland homogenates from seropositive mice. In contrast, L. lakedownensis on Thevenard Island showed no serological evidence of infection with MCMV, any of the other murine viruses, or M. Pulmonis, and no virus could be isolated in culture from salivary gland homogenates. Although MCMV replicated to high titers in experimentally infected inbred BALB/c laboratory mice as expected, it did not replicate in the target organs of experimentally inoculated L. lakedownensis, indicating that the strict host specificity of MCMV may prevent its infection of L. lakedownensis. These results suggest that native mice on Thevenard Island are not at risk of MCMV infection from introduced house mice, and raise interesting questions about the possible selective survival of MCMV in small isolated populations of M. domesticus.

The genome of murine cytomegalovirus is shaped by purifying selection and extensive recombination.

The herpesvirus lifestyle results in a long-term interaction between host and invading pathogen, resulting in exquisite adaptation of virus to host. We have sequenced the genomes of nine strains of murine cytomegalovirus (a betaherpesvirus), isolated from free-living mice trapped at locations separated geographically and temporally. Despite this separation these genomes were found to have low levels of nucleotide variation. Of the more than 160 open reading frames, almost 90% had a dN/dS ratio of amino acid substitutions of less than 0.6, indicating the level of purifying selection on the coding potential of MCMV. Examination of selection acting on individual genes at the codon level however indicates some level of positive selection, with 0.03% of codons showing strong evidence for positive selection. Conversely, 1.3% of codons show strong evidence of purifying selection. Alignments of both genome sequences and coding regions suggested that high levels of recombination have shaped the MCMV genome.

Salmonella infections in Antarctic fauna and island populations of wildlife exposed to human activities in coastal areas of Australia.

Salmonella infections in Antarctic wildlife were first reported in 1970 and in a search for evidence linking isolations with exposure to human activities, a comparison was made of serovars reported from marine fauna in the Antarctic region from 1982-2004 with those from marine mammals in the Northern hemisphere. This revealed that 10 (83%) Salmonella enterica serovars isolated from Antarctic penguins and seals were classifiable in high-frequency (HF) quotients for serovars prevalent in humans and domesticated animals. In Australia, 16 (90%) HF serovars were isolated from marine birds and mammals compared with 12 (86%) HF serovars reported from marine mammals in the Northern hemisphere. In Western Australia, HF serovars from marine species were also recorded in humans, livestock, mussels, effluents and island populations of wildlife in urban coastal areas. Low-frequency S. enterica serovars were rarely detected in humans and not detected in seagulls or marine species. The isolation of S. Enteritidis phage type 4 (PT4), PT8 and PT23 strains from Adélie penguins and a diversity of HF serovars reported from marine fauna in the Antarctic region and coastal areas of Australia, signal the possibility of transient serovars and endemic Salmonella strains recycling back to humans from southern latitudes in marine foodstuffs and feed ingredients.

Species-specificity of a murine immunocontraceptive utilising murine cytomegalovirus as a gene delivery vector.

Cytomegaloviruses are species-specific DNA viruses. Recombinant murine cytomegaloviruse (MCMV) expressing the mouse egg-coat protein zona pellucida 3 (mZP3) has been shown to sterilise female mice by breaking self-tolerance and inducing an immune response against the host ZP3. This virus has the potential to be used for mouse population control, however the effect of this recombinant immunocontraceptive virus in non-host species must be determined. Recombinant MCMV-mZP3, based on both laboratory and wild strains of virus, induced long-lived antibody responses against structural viral proteins and mZP3 when inoculated into laboratory rats, although no viral DNA or replicating virus was identified. The anti-mZP3 antibodies were specific for mouse ZP3, did not cross-react with rat ZP3, and had no effect on the fertility of the rats.

Transmission of two Australian strains of murine cytomegalovirus (MCMV) in enclosure populations of house mice (Mus domesticus).

To control plagues of free-living mice (Mus domesticus) in Australia, a recombinant murine cytomegalovirus (MCMV) expressing fertility proteins is being developed as an immunocontraceptive agent. Real-time quantitative PCR was used to monitor the transmission of two genetically variable field strains of MCMV through mouse populations after 25% of founding mice were infected with the N1 strain, followed by the G4 strain 6 weeks later. Pathogen-free wild-derived mice were released into outdoor enclosures located in northwestern Victoria (Australia). Of those mice not originally inoculated with virus, N1 DNA was detected in more than 80% of founder mice and a third of their offspring and similarly, G4 DNA was detected in 13% of founder mice and in 3% of their offspring. Thus, prior immunity to N1 did not prevent transmission of G4. This result is promising for successful transmission of an immunocontraceptive vaccine through Australian mouse populations where MCMV infection is endemic.

Gross-virus-induced lymphoma in the rat. V. Natural cytotoxic cells are non-T cells.

The cytotoxic cells from the spleens of normal rats, which lyse Gross-virus-induced lymphoma target cells in a short-term 51Cr release test, are predominantly small to medium-sized cells sedimenting at 4-5 mm/h as shown by velocity sedimentation analysis. Their cytotoxic activity is relatively resistant to gamma-radiation, 50% surviving 1,000 rads and 30% remaining after 5,000 rads, and to heat, since 20 min incubation at 48-51 degrees C is required for its abolition. In these properties the natural killer (NK) cells are very similar to the cytotoxic T cells from tumour-immune rats, and they share in addition a requirement for Ca++ ions for cytolysis. They differ in that they are non-T cells as defined by their resistance to anti-T-cell antiserum and complement, and by their presence in T-cell-deprived rats. They lack detectable surface Ig, Fc receptors and phagocytic or adherence properties and belong therefore to that small proportion of lymphoid cells lacking the surface markers of T or B lymphocytes, as do the comparable NK cells of mice. Cytotoxicity appears to involve an autonomous, papain-sensitive recognition structure on the surface of NK cells, rather than acquired cytophilic antibody operating through an antibody-dependent mechanism.