Selection and characterisation of two attenuated vaccine lines of Eimeria tenella in Australia.

OBJECTIVE: To attenuate two strains of Eimeria tenella by selecting for precocious development and evaluate the strains in characterisation trials and by field evaluation, to choose one precocious line for incorporation into an Australian live coccidiosis vaccine for poultry. DESIGN: Two strains from non-commercial flocks were passaged through chickens while selecting for precocious development. Each strain was characterised for drug sensitivity, pathogenicity, protection against homologous and heterologous challenge, and oocyst output in replicated experiments in which the experimental unit was a cage of three birds. Oocyst output and/or body weight gain data collected over a 10 to 12 day period following final inoculation were measured. Feed conversion ratios were also calculated where possible. RESULTS: Fifteen passages resulted in prepatent periods reduced by 24 h for the Redlands strain (from 144 h to 120 h) and 23 h for the Darryl strain (from 139 h to 116 h). Characterisation trials demonstrated that each precocious line was significantly less pathogenic than its parent strain and each effectively induced immunity that protected chickens against challenge with both the parent strain and other virulent field strains. Both lines had oocyst outputs that, although significantly reduced relative to the parent strains, remained sufficiently high for commercial vaccine production, and both showed susceptibility to coccidiostats. CONCLUSION: Two attenuated lines have been produced that exhibit the appropriate characteristics for use in an Australian live coccidiosis vaccine.

Inter- and intra-strain variation and PCR detection of the internal transcribed spacer 1 (ITS-1) sequences of Australian isolates of Eimeria species from chickens.

The objective of this study was to confirm the presence of seven species of Eimeria involved in chicken coccidiosis in Australia by comparing internal transcribed spacer 1 (ITS-1) sequences, ITS-1 polymerase chain reaction (PCR) methods and to apply phylogenetic analysis to assess evolutionary relationships of Australian isolates. Twenty-two distinct ITS-1 regions of 15 Australian Eimeria isolates were sequenced, and analysed using maximum parsimony, distance and maximum likelihood methods. Poor bootstrap support, resulting from high ITS-1 sequence heterogeneity between all species groups, resulted in polychotomy of the Eimeria species in all three trees generated by these analyses. Percentage identity analyses revealed two distant ITS-1 lineages in both E. mitis and E. maxima at the same levels that separate the two species E. tenella and E. necatrix. One E. maxima lineage consisted of Australian isolates, the other American isolates, with one European sequence (originating from the same isolate) in each lineage. One Australian E. praecox sequence was only distantly related (33% variation) to three E. praecox sequences from Australian and European isolates. Short and long ITS-1 variants were isolated from both E. tenella (cloned line) and E. necatrix isolates with deletions (106 and 73 bp, respectively) in the short variants within the 3' region of the ITS-1 sequence. ITS-1 sequences of strains of both E. brunetti and E. acervulina species varied the least. Apart from E. maxima, all of the ITS-1 sequences of the six remaining individual species clustered to the exclusion of other species in all phylogenetic trees. Published ITS-1 tests for E. necatrix, E. acervulina, E. brunetti and E. tenella, combined with three new tests for E. mitis, E. praecox and Australian E. maxima amplified all respective Australian isolates specifically in a nested format using conserved ITS-1 PCR products as template to improve the sensitivity. All PCR tests were confirmed against a collection of 24 Australian chicken Eimeria isolates and contaminating species were detected in some instances. In conclusion, once the genetic variation between species and strains is determined, the ITS-1 is a good target for the development of species-specific assays, but the ITS-1 sequences alone do not seem suitable for the confirmation of phylogenetic inferences for these species. This study reports the first attempt at the analysis of the phylogeny and sequence comparison of the Eimeria species involved in chicken coccidiosis in Australia.

Application of PCR assays to determine the genotype of Babesia bovis parasites isolated from cattle with clinical babesiosis soon after vaccination against tick fever.

OBJECTIVE: To demonstrate the value of PCR assays to determine the genotypes of Babesia bovis in cattle with clinical signs of babesiosis within 3 weeks after vaccination against tick fever. DESIGN: Samples from 5 cases of babesiosis in cattle soon after vaccination against tick fever were analysed in two PCR assays. PROCEDURE: Parasite DNA was purified from blood taken from cattle with signs of babesiosis within 3 weeks of vaccination against tick fever. DNA was also prepared from the tissues of animals that died of babesiosis. Two PCR assays that amplify repeat sequences of DNA within the B bovis genes, Bv80 and BvVA1, were used to differentiate the genotypes of field isolates and vaccine strains of B bovis. RESULTS: One of the five cases of babesiosis was found to be caused by a vaccine strain, but PCR analyses showed that the predominant isolate in the other four cases was not the vaccine strain. CONCLUSIONS: PCR assays on the DNA of B bovis obtained from the blood or tissues of cattle clinically affected with tick fever within 3 weeks after vaccination are useful to distinguish between vaccine strains and field isolates as the source of infection.

Development of an enzyme-linked immunosorbent assay for detection of antibodies to Babesia bigemina in cattle.

Monoclonal antibodies, directed against a 58-kDa Babesia bigemina merozoite antigen that reacted strongly with immune sera from experimentally and naturally infected cattle in Western blots, were used to develop a competitive-inhibition enzyme-linked immunosorbent assay (ELISA). As based on the testing of 70 antibody-positive sera from experimentally infected cattle and 166 antibody-negative sera collected in non-endemic areas of Australia, the sensitivity and specificity of the ELISA were 95.7% and 97.0%, respectively. In sequential sera collected from six calves during the course of experimental B. bigemina infections the ELISA detected seroconversion at about 10 days post-inoculation. The specificity of the ELISA was not affected by the presence of antibodies to B. bovis, Anaplasma marginale or Theileria buffeli. In 42 sera from cattle experimentally infected with B. bovis but negative for B. bigemina the specificity of the ELISA was 95.2%. The use of a competitive-inhibition ELISA format detecting only antibody directed against a single epitope on the 58-kDa antigen appears to have overcome many of the specificity problems that have plagued serological tests for B. bigemina in the past. The test should be useful for epidemiology studies, particularly in areas where B. bovis and B. bigemina have overlapping distributions.

Detection of Eimeria acervulina using the polymerase chain reaction.

A polymerase chain reaction (PCR)-based assay was developed for the detection of Eimeria acervulina. Primers were designed to amplify a fragment of the EASZ240/160 sporozoite antigen gene. The PCR assay detected as few as 10 E. acervulina oocysts in a mixed population containing a total of 10(6) oocysts. No nonspecific reaction was observed with any other species of avian Eimeria known to occur in Australia. PCR products from genomic DNA were 237 bp larger than predicted from previously reported cDNA sequences. Sequencing of the product revealed the presence of a probable intron. This work demonstrates the potential of PCR-based assays for identification and detection of avian Eimeria. Potential uses include identification of minor species present in mixed infections and quality control in the production of live vaccines.

Isolation and pathogenicity of Australian strains of Eimeria praecox and Eimeria mitis.

OBJECTIVE: To determine the presence of E praecox and E mitis in Australia, to isolate representative strains of these species from chickens and determine their pathogenicity. DESIGN: Morphological, physiological and cross protection studies were undertaken to confirm the identity of Australian isolates of E praecox and E mitis. PROCEDURE: Oocysts were isolated from a backyard flock at Jimboomba, southeastern Queensland and numbers of E praecox and E mitis enriched by passage in chickens immune to five other species of poultry Eimeria. Oocysts of mean conformation and size of the two species were purified by single oocyst passage. Two isolates that closely matched recorded parameters for E praecox and E mitis were selected and designated JP and JM respectively. The cross protection between the isolates and E acervulina was determined by infection and challenge experiments. The virulence of the two isolates was determined by comparing weight gains of groups of birds inoculated with JP isolate or JM isolate with untreated groups. RESULTS: Isolates JP and JM most closely matched recorded parameters of E praecox and E mitis respectively. Groups of chickens, previously infected with JP and JM isolates, showed no significant protection against infection with E acervulina. In a separate trial, groups of susceptible chickens inoculated with 10(5) oocysts of JP and JM isolates showed significantly reduced weight gains compared with untreated controls. CONCLUSION: Isolates JP and JM are E praecox and E mitis respectively, confirming the presence of these species in Australia. These isolates were found capable of causing significant reductions in weight gains in susceptible chickens.

PCR methods for the discrimination of Babesia bovis isolates.

Three different polymerase chain reaction assays for the typing of isolates of Babesia bovis have been developed and compared with a hybridisation based method. Primers were designed within conserved regions flanking the variable length tandem repeats of the Bv80 and BvVA1 genes. For the long array of repeats in BvVA1, up to 7.5 kb, a modified long template PCR method was developed. The assays were compared using ten independent isolates of Babesia bovis. Using the BvVA1 and Bv80 PCR assays, 13 and 10 genotypes could be discriminated, respectively, with some isolates containing several genotypes. Combining the two PCR assays, 17 genotypes were identified within the ten Babesia bovis isolates. Whilst simpler and requiring less DNA, the BvVA1 PCR analysis exhibited significant bias towards some genotypes of the BvVA1 repeats. Further discrimination of BvVA1 PCR products was achieved using AccI digests producing population specific ladders. Genomic DNA fingerprints were also generated by PCR of DNA using an arbitrary primer (randomly amplified polymorphic DNA, RAPD) revealing polymorphic genotypes that were isolate specific. No amplification of host DNA resulted from any of the three PCR procedures. Babesia bigemina DNA was not amplified by the Bv80 or BvVA1 primers. Applications demonstrating changes in composition of populations of Babesia bovis parasites during attenuation and prolonged culture maintenance are described.