Population Genetic Structure and Potential Incursion Pathways of the Bluetongue Virus Vector Culicoides brevitarsis (Diptera: Ceratopogonidae) in Australia.

Culicoides brevitarsis is a vector of the bluetongue virus (BTV), which infects sheep and cattle. It is an invasive species in Australia with an assumed Asian/South East Asian origin. Using one mitochondrial marker (i.e., part of the cytochrome oxidase subunit I gene) and six nuclear markers, we inferred population genetic structure and possible incursion pathways for Australian C. brevitarsis. Nine mitochondrial haplotypes, with low nucleotide sequence diversity (0.0-0.7%) among these, were identified in a sample of 70 individuals from seven sites. Both sets of markers revealed a homogeneous population structure, albeit with evidence of isolation by distance and two genetically distinct clusters distributed along a north-to-south cline. No evidence of a cryptic species complex was found. The geographical distribution of the mitochondrial haplotypes is consistent with at least two incursion pathways into Australia since the arrival of suitable livestock hosts. By contrast, 15 mitochondrial haplotypes, with up to four times greater nucleotide sequence diversity (0.0-2.9%) among these, were identified in a sample of 16 individuals of the endemic C. marksi (sampled from a site in South Australia and another in New South Wales). A phylogenetic tree inferred using the mitochondrial marker revealed that the Australian and Japanese samples of C. brevitarsis are as evolutionarily different from one another as some of the other Australian species (e.g., C. marksi, C. henryi, C. pallidothorax) are. The phylogenetic tree placed four of the species endemic to Australia (C. pallidothorax, C. bundyensis, C. marksi, C. henryi) in a clade, with a fifth such species (C. bunrooensis) sharing a common ancestor with that clade and a clade comprising two Japanese species (C. verbosus, C. kibunensis).

Molecular and serological analysis of the epidemiology of myxoma virus in rabbits.

The epidemiology of myxoma virus was studied by serology and molecular analysis of restriction fragment length polymorphisms (RFLPs) in genomic DNA. 159 isolates of myxoma virus were made over a period of 5 spring/summer epidemics from 12 field sites in south-eastern Australia. Virus isolates were classified into 10 genetic types using RFLPs detected with a panel of nine restriction endonucleases. Between 3 and 6 different genetic types were found during spring/summer periods across all sites and up to 3 different genetic types were isolated during an epidemic on a single site. The predominant type tended to change each year. A widespread mutation was identified in two genetic types with replacement of the 3' two-thirds of the M009L gene at the left hand inverted terminal repeat junction with a duplication of the region containing the M156R, M154L and M153R genes from the right hand end of the genome. This demonstrated how myxoma virus can potentially evolve by expansion of the inverted terminal repeat boundaries.

Host-specificity of myxoma virus: Pathogenesis of South American and North American strains of myxoma virus in two North American lagomorph species.

The pathogenesis of South American and North American myxoma viruses was examined in two species of North American lagomorphs, Sylvilagus nuttallii (mountain cottontail) and Sylvilagus audubonii (desert cottontail) both of which have been shown to have the potential to transmit the South American type of myxoma virus. Following infection with the South American strain (Lausanne, Lu), S. nuttallii developed both a local lesion and secondary lesions on the skin. They did not develop the classical myxomatosis seen in European rabbits (Oryctolagus cuniculus). The infection at the inoculation site did not resolve during the 20-day time course of the trial and contained transmissible virus titres at all times. In contrast, S. audubonii infected with Lu had very few signs of disseminated infection and partially controlled virus replication at the inoculation site. The prototype Californian strain of myxoma virus (MSW) was able to replicate at the inoculation site of both species but did not induce clinical signs of a disseminated infection. In S. audubonii, there was a rapid response to MSW characterised by a massive T lymphocyte infiltration of the inoculation site by day 5. MSW did not reach transmissible titres at the inoculation site in either species. This might explain why the Californian myxoma virus has not expanded its host-range in North America.

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.

Virulence and pathogenesis of the MSW and MSD strains of Californian myxoma virus in European rabbits with genetic resistance to myxomatosis compared to rabbits with no genetic resistance.

The pathogenesis of two Californian strains of myxoma virus (MSW and MSD) was examined in European rabbits (Oryctolagus cuniculus) that were either susceptible to myxomatosis (laboratory rabbits) or had undergone natural selection for genetic resistance to myxomatosis (Australian wild rabbits). MSW was highly lethal for both types of rabbits with average survival times of 7.3 and 9.4 days, respectively, and 100% mortality. Classical clinical signs of myxomatosis were not present except in one rabbit that survived for 13 days following infection. Previously described clinical signs of trembling and shaking were observed in laboratory but not wild rabbits. Despite the high resistance of wild rabbits to myxomatosis caused by South American strains of myxoma virus, the MSW strain was of such high virulence that it was able to overcome resistance. The acute nature of the infection, relatively low viral titers in the tissues and destruction of lymphoid tissues, suggested that death was probably due to an acute and overwhelming immunopathological response to the virus. No virus was found in the brain. The MSD strain was attenuated compared to previously published descriptions and therefore was only characterized in laboratory rabbits. It is concluded that Californian MSW strain of myxoma virus is at the extreme end of a continuum of myxoma virus virulence but that the basic pathophysiology of the disease induced is not broadly different to other strains of myxoma virus.

Immunocontraceptive effects on female rabbits infected with recombinant myxoma virus expressing rabbit ZP2 or ZP3.

Recombinant myxoma viruses expressing rabbit zona pellucida 2 (rZP2) or rabbit zona pellucida 3 (rZP3) glycoproteins were constructed and tested in domestic rabbits to assess their potential to induce autoimmune infertility. The recombinant virus expressing rZP2 had no effect on fertility or ovarian histology, despite all animals developing antibodies against the rZP2 antigen. However, recombinant viruses expressing rZP3 induced infertility in 70% of animals at the first breeding. Serum antibodies were relatively short-lived, but antibody was bound to zona pellucida of all rabbits from Day 10 onward. There was no obvious correlation between infertility and rZP3 antibody titer. There was a transient inflammatory response in the ovaries of rZP3-immunized rabbits at Day 15 but no T-cell response to rZP3 could be detected at any time. Dysfunctional follicular formation was present in ovaries from rabbits infected with rZP3-expressing viruses 15-40 days postinfection but this had disappeared at later time points. A recombinant myxoma virus expressing a modified rZP3 antigen with the C-terminal hydrophobic putative anchor sequence deleted was also tested. This virus did not induce either infertility or an antibody response against the zona pellucida. Thus, the context of antigen presentation was crucial for an autoimmune response.

Expression of rabbit IL-4 by recombinant myxoma viruses enhances virulence and overcomes genetic resistance to myxomatosis.

Rabbit IL-4 was expressed in the virulent standard laboratory strain (SLS) and the attenuated Uriarra (Ur) strain of myxoma virus with the aim of creating a Th2 cytokine environment and inhibiting the development of an antiviral cell-mediated response to myxomatosis in infected rabbits. This allowed testing of a model for genetic resistance to myxomatosis in wild rabbits that have undergone 50 years of natural selection for resistance to myxomatosis. Expression of IL-4 significantly enhanced virulence of both virulent and attenuated virus strains in susceptible (laboratory) and resistant (wild) rabbits. SLS-IL-4 completely overcame genetic resistance in wild rabbits. The pathogenesis of SLS-IL-4 was compared in susceptible and resistant rabbits. The results support a model for resistance to myxomatosis of an enhanced innate immune response controlling virus replication and allowing an effective antiviral cell-mediated immune response to develop in resistant rabbits. Expression of IL-4 did not overcome immunity to myxomatosis induced by immunization.

Monitoring the spread of myxoma virus in rabbit Oryctolagus cuniculus populations on the southern tablelands of New South Wales, Australia. I. Natural occurrence of myxomatosis.

A survey of rabbit populations in the southern tablelands of New South Wales, Australia, was carried out to establish the pattern of occurrence of myxomatosis in preparation for a deliberate release of myxoma virus. Myxomatosis was first detected in December and cases were found on most sites through to May. The serological profiles of rabbit populations suggested that their susceptibility to myxoma virus was generally low in winter and highest in spring and summer reflecting the presence of increasing numbers of susceptible young rabbits. This was consistent with the pattern of rabbit breeding, as determined from the distribution of births and reproductive activity in females and males, which occurred maximally in spring and early summer. The serology and age structure of rabbit populations on sites suggested that some rabbit populations can escape an annual myxomatosis epizootic. Although fleas were present on rabbits throughout the year and therefore not considered to be a limiting factor in the spread of myxomatosis, their numbers peaked at times coincident with peak rabbit breeding. It was concluded that mid to late spring was an optimal time for a deliberate release.

Monitoring the spread of myxoma virus in rabbit Oryctolagus cuniculus populations on the southern tablelands of New South Wales, Australia. II. Selection of a strain of virus for release.

To be able to study the dynamics of myxoma virus spread following a release in the field, a strain of virus is required that is both highly transmissible and readily differentiated from other field strains. Eight strains of virus of known virulence for laboratory rabbits and with previously mapped and sequenced restriction fragment length polymorphisms, were used to infect groups of seronegative wild rabbits. Based on these trials, and on the nature of the DNA polymorphism, a virus designated Brooklands/2-93 was chosen as a strain suitable for experimental release. These trials confirmed that resistance to myxomatosis within wild rabbit populations continues to be substantial and that some rabbits are highly resistant. These rabbits probably have little role in transmission of virus. Most of the virus strains tested induced very small or invisible primary lesions at the inoculation site. Thus the secondary skin sites such as eyelids, face and ears may be critical for transmission.

Monitoring the spread of myxoma virus in rabbit Oryctolagus cuniculus populations on the southern tablelands of New South Wales, Australia. III. Release, persistence and rate of spread of an identifiable strain of myxoma virus.

An identifiable strain of myxoma virus was introduced into four local populations of wild rabbits Oryctolagus cuniculus on the southern tablelands of New South Wales (NSW) and its spread in the presence of other field strains was monitored for 6 months. The main vector in this region was considered to be the European rabbit flea Spilopsyllis cuniculi. Each population of rabbits was of a high density and living in groups of warrens covering areas from 59 to 87 hectares. Rabbits occupying centrally located warrens were inoculated with the virus in late September or early October (spring) and the subsequent appearance of myxomatosis across the sites monitored by trapping, shooting and visual observations. Samples, taken from rabbits with myxomatosis, were examined by polymerase chain reaction (PCR) that allowed identification of the introduced strain. On all four sites the introduced virus spread from the inoculated rabbits in the centrally located warrens to rabbits in surrounding warrens. On Sites 1 and 3, this spread continued across the entire site persisting for at least 118 and 174 days respectively. On Sites 2 and 4, the virus was detected for 78 and 62 days respectively and the subsequent inability to detect the introduced virus correlated with the appearance of an unrelated field strain. Using three different methods of calculation, rates of spread ranged from 3.7 to 17.8 m d(-1).

Coevolution of host and virus: cellular localization of virus in myxoma virus infection of resistant and susceptible European rabbits.

The coevolution of myxoma virus and the wild European rabbit in Australia and the development of resistance to myxomatosis in wild rabbits have been well described. However, the mechanism of resistance to myxomatosis in wild rabbits is not understood. To determine the basis of resistance, the pathogenesis of the virulent standard laboratory strain (SLS) and the attenuated Uriarra (Ur) strain of myxoma virus were examined in Australian wild rabbits that have been naturally selected in the field for resistance to myxomatosis and in laboratory rabbits which have never been selected for resistance. Virus was localized in tissue sections by immunofluorescence. In all cases virus antigen was initially present in dendritic cells of the dermis before localizing predominantly to the epidermis by Day 6. Antigen-containing cells were detected in the lymph nodes by 24 h after inoculation. Virus replication occurred predominantly in T lymphocytes of the paracortex but SLS also replicated in germinal centers. SLS replication induced loss of most lymphocytes from the lymph nodes of susceptible rabbits. Apoptosis of lymphocytes within the lymph nodes was a major feature of all infections. These apoptotic cells did not contain detectable viral antigen but were often adjacent to infected cells. Ongoing apoptosis of lymphocytes within lymph nodes was also a feature of the recovery phase when very few or no virus-infected cells could be detected. Differences between virulent and attenuated viruses in the wild and laboratory rabbits were predominantly in the degree of tissue pathology in the draining lymph node and distal lymph node and in the type of inflammatory responses, particularly in the skin. SLS infection of laboratory rabbits was associated with a very mild inflammatory response, often distant from the site of virus replication and comprised predominantly of neutrophils. In contrast, Ur-infected rabbits and SLS-infected wild rabbits had an intense inflammatory response adjacent to the site of virus replication and this was comprised predominantly of mononuclear cells. Both the initial infection of dendritic cells and the ongoing destruction of lymphocytes provide obvious mechanisms for the suppression of the immune response by myxoma virus.

The complete cDNA sequences of IL-2, IL-4, IL-6 AND IL-10 from the European rabbit (Oryctolagus cuniculus).

The cDNAs for four rabbit cytokine genes [interleukin 2 (IL-2), IL-4, IL-6 and IL-10] have been cloned from primary lymphocytes by polymerase chain reaction (PCR) methods. IL-2 and IL-10 are both highly conserved between rabbit and other species. IL-4 and IL-6 are less strongly conserved, at both nucleotide and amino acid levels, and exhibit structural differences. An extension of the coding region of rabbit IL-6 relative to all other reported IL-6 genes results from a mutation in the usual stop codon which allows translation to continue for a further 27 amino acids. Analysis of IL-6 from four other lagomorph species suggests that this mutation is specific to the European rabbit. Sequence and structural differences of IL-4 and IL-6, while presumably not altering function, may render them highly species-specific. Several alternatively spliced variants of IL-2 and IL-4 are also reported.

Coevolution of host and virus: the pathogenesis of virulent and attenuated strains of myxoma virus in resistant and susceptible European rabbits.

Myxoma virus was introduced into the European rabbit population of Australia in 1950. Although the virus was initially highly lethal in rabbits, there was rapid selection for less virulent strains of virus and innately resistant rabbits. To investigate the basis of resistance to myxoma virus, we have compared the pathogensis of the virulent strain of myxoma virus originally released into Australia and an attenuated, naturally derived field strain of myxoma virus. This was done in laboratory rabbits, which have not been selected for resistance, and in wild rabbits that have developed significant resistance. Wild rabbits were able to recover from infection with virus that was always lethal in laboratory rabbits. Laboratory rabbits were able to control and recover from infection with attenuated virus. This virus caused a trivial disease in wild rabbits. There was little difference between laboratory and wild rabbits in titers of either virulent or attenuated virus in the skin at the inoculation site. However, resistant wild rabbits had a 10- to 100-fold lower titer of virulent virus within the lymph node draining the inoculation site and controlled virus replication in tissues distal to the draining lymph node. Replication of virus in lymphocytes or fibroblasts cultured from wild and laboratory rabbits demonstrated that resistance was not due to altered cellular permissivity for replication. Neutralizing antibodies were present in both susceptible and resistant rabbits, suggesting that these have no significant role in resistance. We hypothesise that resistance is due to an enhanced innate immune response that allows the rabbit to mount an effective cellular immune response.

Infertility in female rabbits (Oryctolagus cuniculus) alloimmunized with the rabbit zona pellucida protein ZPB either as a purified recombinant protein or expressed by recombinant myxoma virus.

Development of immunocontraceptives for wild rabbit populations requires selection of both effective antigens and effective delivery systems. Recombinant rabbit zona pellucida glycoprotein B (ZPB) produced in eukaryotic cells in vitro was an effective antigen and induced sustained infertility in 70% of female rabbits. This required two boosts and serum antibody titers of 12 800 or greater. Antibody titers in females were low after the initial immunization, as might be expected with a self-antigen; however, male rabbits had a strong antibody response, indicating that the protein was immunologically foreign. To develop a delivery system, ZPB was delivered by infection with a recombinant myxoma virus. In contrast to the results with ZPB protein, infection of rabbits induced a similar serum antibody response to ZPB in both sexes. This indicated that presentation of ZPB in the context of a virus infection was able to overcome tolerance in females. However, the antibody titers were lower than 12 800, and only 25% of female rabbits were infertile. This antibody response was boosted by injections of recombinant ZPB protein, after which 80% of female rabbits were infertile. Infertility was associated with antibody binding to zonae and varying degrees of ovarian pathology characterized by follicular degeneration and substantial depletion of primordial follicles. Oocyte and follicular degeneration appeared to be the principal mechanism of infertility and may be primarily induced by antibodies to ZPB.

Myxoma virus encodes an alpha2,3-sialyltransferase that enhances virulence.

A 4.7-kb region of DNA sequence contained at the right end of the myxoma virus EcoRI-G2 fragment located 24 kb from the right end of the 163-kb genome has been determined. This region of the myxoma virus genome encodes homologs of the vaccinia virus genes A51R, A52R, A55R, A56R, and B1R; the myxoma virus gene equivalents have been given the prefix M. The MA55 gene encodes a protein belonging to the kelch family of actin-binding proteins, while the MA56 gene encodes a member of the immunoglobulin superfamily related to a variety of cellular receptors and adhesion molecules. A novel myxoma virus early gene, MST3N, is a member of the eukaryotic sialyltransferase gene family located between genes MA51 and MA52. Detergent lysates prepared from myxoma virus-infected cell cultures contained a virally encoded sialyltransferase activity that catalyzed the transfer of sialic acid (Sia) from CMP-Sia to an asialofetuin glycoprotein acceptor. Analysis of the in vitro-sialylated glycoprotein acceptor by digestion with N-glycosidase F and by lectin binding suggested that the MST3N gene encodes an enzyme with Galbeta1,3(4)GlcNAc alpha2,3-sialyltransferase specificity for the N-linked oligosaccharide of glycoprotein. Lectin binding assays demonstrated that alpha2,3-sialyltransferase activity is expressed by several known leporipoxviruses that naturally infect Sylvilagus rabbits. The sialyltransferase is nonessential for myxoma virus replication in cell culture; however, disruption of the MST3N gene caused attenuation in vivo. The possible implications of the myxoma virus-expressed sialyltransferase in terms of the host's defenses against infection are discussed.

The effect of buprenorphine on the course of disease in laboratory rabbits infected with myxoma virus.

The only method of assessing the virulence of myxoma virus is to record survival times of rabbits inoculated with the virus. This raises ethical concerns about using animals in experiments where death is the end point. We investigated whether or not the opioid analgesic buprenorphine could be used in rabbits without compromising the myxoma virus virulence assay and on the presumption that animals may suffer pain during the course of the disease. Thirty, 5-month-old New Zealand White rabbits were divided into two groups stratified for weight and gender, and inoculated intradermally with 100 pfu of the Standard Laboratory Strain (SLS) of myxoma virus. At day 6 post infection (p.i.), when eyelid swelling was first seen, each animal in one group was treated with 0.03 mg/kg buprenorphine, subcutaneously, morning and evening until death. Animals in the other group were untreated. Animals were weighed daily and rectal temperatures taken morning and evening. Intake of food and water was assessed as was general demeanor including respiratory effort. There was no significant difference in mean survival time, weight change, or demeanor between the two groups. Increased respiratory effort was seen from day 10 p.i. in animals surviving up to and beyond that time but again there was no difference between groups. Animals treated with buprenorphine refused food and water a day earlier than untreated animals, and had lower temperatures immediately prior to death. It was concluded that the opiate analgesic buprenorphine can be used without compromising the current virulence assay for the SLS of myxoma virus in New Zealand White rabbits but that the clinical signs of myxomatosis that could be attributed to pain were not abrogated.

Myxoma virus in rabbits.

Myxoma virus in European rabbits (Oryctolagus cuniculus) is one of the best documented examples of host-virus co-evolution. In the natural hosts (Sylvilagus brasiliensis or S. bachmani rabbits in the Americas), myxoma virus causes a benign cutaneous fibroma. In European rabbits, however, myxoma virus causes the fulminant disease, myxomatosis. When introduced into wild European rabbit populations in Australia, Europe and Great Britain, the virus was initially highly lethal, killing in excess of 99% of infected rabbits. Development of resistance was encouraged by the emergence of attenuated virus strains which allowed the survival of moderately resistant rabbits. This may have occurred more rapidly in hot climates, as high ambient temperatures increase the survival rate of infected rabbits. Resistant rabbits are less effective transmitters of the virus and this may encourage the emergence of more virulent virus strains. Little is known of the mechanism of resistance. There have been suggestions of non-genetic resistance. However, these are yet to be confirmed experimentally.

A cross-sectional study of private psychiatric practices under a single-payer health care system.

OBJECTIVES: To examine current concerns that in the Canadian single-payer mental health care system, the "rich worried well" (that is, wealthy individuals who are worried yet mentally well) may overuse psychiatric services, while low-income, uninsured mentally ill individuals may remain undertreated. The current study focuses on the mental health care in the Canadian region of Ottawa-Carleton, where a single-payer system provides universal access to mental health services, to assess how psychiatric services are provided by psychiatrists in private practice. METHOD: One hundred and seven private psychiatrists working in the region of Ottawa-Carleton completed a questionnaire which contained questions about the sociodemographic characteristics and background of the psychiatrists themselves and which asked the psychiatrists specific questions about the sociodemographic status, diagnosis, and treatment of each patient seen on November 10, 1994. RESULTS: Approximately 93% of the patients seen met criteria for one or more Axis I disorders, of which mood and anxiety disorders were the most common. Wealthier patients were relatively underrepresented among the patients treated by the private psychiatrists. In addition, we found no significant differences in the distribution of Axis I, Axis II, and Axis III disorders between patients earning below $30,000 per year compared with patients earning above $60,000 per year. CONCLUSIONS: Our results suggest that outpatient psychiatric care delivered by private psychiatrists in a Canadian single-payer system targets primarily individuals with major psychiatric disorders and does not seem to favour "the worried well." Larger epidemiological studies with independent assessments of psychiatric populations are necessary to confirm our findings.

Interstitial orchitis with impaired steroidogenesis and spermatogenesis in the testes of rabbits infected with an attenuated strain of myxoma virus.

The pathogenesis of infertility associated with acute viral orchitis was investigated in a rabbit model. Infection of postpubertal male European rabbits with an attenuated strain of myxoma virus caused systemic disease with viral replication to high titres in the testes. Infected rabbits developed an interstitial orchitis and epididymitis. This was associated with degeneration of the seminiferous epithelium, decreased serum testosterone concentrations and increased serum LH concentrations. Virus was localized within the interstitial cells. Clearance of infectious virus from the testis occurred between day 20 and day 30 after infection, although viral DNA could still be detected by polymerase chain reaction at 120 days. Viral clearance was associated with a return to normal serum testosterone and LH concentrations. Anti-sperm antibodies were present in the serum as early as 5 days after infection and declined during the recovery phase. Rabbits were infertile at 60 days but returned to normal fertility 60-90 days after infection.

Construction of recombinant myxoma viruses expressing foreign genes from different intergenic sites without associated attenuation.

Two myxoma virus transient dominant selection vectors were constructed and used to generate recombinant viruses expressing single and double foreign gene insertions from intergenic sites. The intergenic insertion sites were located between the myxoma virus genes MJ2 (thymidine kinase) and MJ2a, and MA24 (beta-subunit RNA polymerase) and MA27 (fusion protein) located approximately 60 and 113 kb from the left-end of the viral genome, respectively. Recombinant myxoma viruses expressing the lacZ gene from either intergenic insertion site retained wild-type virulence. However, expression of the gus gene reduced the virulence of the recombinant viruses in vivo. Northern blot analysis indicated that the major late mRNAs encoding the viral RNA polymerase subunit and fusion protein are both of discrete size. Insertion of a foreign gene under the control of a synthetic late promoter between the MA24 and MA27 genes results in a specific-sized major late transcript for the inserted foreign gene. The MA27 gene transcripts directed by these recombinant viruses are heterogeneous in size, implying the typical pattern of poxvirus late transcription by random 3'-termination prior to polyadenylation. The transcription studies suggest signals located downstream of the insertion site direct 3'-processing of late transcripts irrespective of the gene immediately upstream.