Live Eimeria vaccination success in the face of artificial non-uniform vaccine administration in conventionally reared pullets.

Live Eimeria vaccines against coccidiosis in poultry initiate immunity using a vaccine dose containing few oocysts; protection is enhanced through subsequent faecal-oral transmission ("cycling") of parasites in the poultry house. Spray-administered Eimeria vaccines can permit wide variations in doses ingested by individual chicks; some chicks may receive no primary vaccination at all. Consequently, protective immunity for the entire flock depends on successful environmental cycling of vaccine progeny. Pullets missing primary vaccination at day of age can become protected from coccidial challenge through cycling of vaccine progeny oocysts from vaccinated (V) cage mates. This study tested whether 40% cage floor coverage (CFC) with a durable material could improve protection against challenge in these "contact-vaccinated" (CV) or successfully V pullets. The six treatment groups tested were CV, V or sham-vaccinated pullets cage-reared on either 0% or 40% CFC. Oocyst output was measured separately for each group for 30 days following vaccine administration. Lesion scores, body weights and total oocyst outputs were measured to quantify protection at 30 days of age against single or mixed Eimeria species challenge infections. Use of 40% CFC to promote low-level oocyst cycling impacted the flock in two ways: (1) more uniform flock immunity was achieved in the 40% CFC (CV similar to V pullets) compared with 0% CFC and (2) protection was enhanced in the 40% CFC compared with the 0% CFC. The use of CFC is an easily adopted means of improving live Eimeria vaccination of caged pullets.

Molecular phylogenetics of eimeriid coccidia (Eimeriidae, Eimeriorina, Apicomplexa, Alveolata): A preliminary multi-gene and multi-genome approach.

Coccidia possess three distinct genomes: nuclear, mitochondrial, and plastid. Sequences from five genes located on these three genomes were used to reconstruct the phylogenetic relationships of members of the phylum Apicomplexa: 18S rDNA sequences from the nuclear (nu) genome, partial cytochrome c oxidase subunit I sequences from the mitochondrial (mt) genome, and partial 16S and 23S rDNA sequences and RNA polymerase B sequences from plastid (pl) genomes. Maximum parsimony, maximum likelihood, and Bayesian inference were used in conjunction with nuclear substitution models generated from data subsets in the analyses. Major groups within the Apicomplexa were well supported with the mitochondrial, nuclear, and a combination of mitochondrial, nuclear and concatenated plastid gene sequences. However, the genus Eimeria was paraphyletic in phylogenetic trees based on the nuclear gene. Analyses using the individual genes (18S rDNA and cytochrome c oxidase subunit I) resolved the various apicomplexan groups with high Bayesian posterior probabilities. The multi-gene, multi-genome analyses based on concatenated nu 18S rDNA, pl 16S, pl 23S, pl rPoB, pl rPoB1, and mt COI sequences appeared useful in resolving phylogenetic relationships within the phylum Apicomplexa. Genus-level relationships, or higher, appear best supported by 18S rDNA analyses, and species-level analyses are best investigated using mt COI sequences; for parasites for which both loci are available, nuclear 18S rDNA sequences combined with mitochondrial COI sequences provide a compact and informative molecular dataset for inferring the evolutionary relationships taxa in the Apicomplexa.

Simultaneous identification and DNA barcoding of six Eimeria species infecting turkeys using PCR primers targeting the mitochondrial cytochrome c oxidase subunit I (mtCOI) locus.

Species-specific PCR primers targeting the mitochondrial cytochrome c oxidase subunit I (mtCOI) locus were generated that allow for the specific identification of the most common Eimeria species infecting turkeys (i.e., Eimeria adenoeides, Eimeria meleagrimitis, Eimeria gallopavonis, Eimeria meleagridis, Eimeria dispersa, and Eimeria innocua). PCR reaction chemistries were optimized with respect to divalent cation (MgCl2) and dNTP concentrations, as well as PCR cycling conditions (particularly anneal temperature for primers). Genomic DNA samples from single oocyst-derived lines of six Eimeria species were tested to establish specificity and sensitivity of these newly designed primer pairs. A mixed 60-ng total DNA sample containing 10 ng of each of the six Eimeria species was used as DNA template to demonstrate specific amplification of the correct product using each of the species-specific primer pairs. Ten nanograms of each of the five non-target Eimeria species was pooled to provide a non-target, control DNA sample suitable to test the specificity of each primer pair. The amplifications of the COI region with species-specific primer pairs from pooled samples yielded products of expected sizes (209 to 1,012 bp) and no amplification of non-target Eimeria sp. DNA was detected using the non-target, control DNA samples. These primer pairs specific for Eimeria spp. of turkeys did not amplify any of the seven Eimeria species infecting chickens. The newly developed PCR primers can be used as a diagnostic tool capable of specifically identifying six turkey Eimeria species; additionally, sequencing of the PCR amplification products yields sequence-based genotyping data suitable for identification and molecular phylogenetics.

Description of two new Isospora species causing visceral coccidiosis in captive superb glossy starlings, Lamprotornis superbus (Aves: Sturnidae).

Isospora greineri sp. n. and Isospora superbusi sp. n. are described from captive superb glossy starlings, Lamprotornis superbus, from the Toronto Zoo succumbing to visceral coccidiosis. Sequence data from nuclear 18S recombinant DNA (rDNA) and mitochondrial cytochrome c oxidase subunit I (COI) loci from sporulated oocysts and infected tissues (liver, lung, or spleen) demonstrated two distinct Isospora sp. genotypes that varied in their relative abundance. In the tissues of one affected bird, as well as its associated fecal sample, two distinct COI sequences (1.7% divergence) and two distinct 18S rDNA sequences (0.6% divergence) were found at almost the same abundance; in other specimens, one of the 18S and one of the COI sequences were less abundant than the other. In the tissues of some birds, only a single COI and single 18S sequence were present. In all cases, the same pair of 18S rDNA and COI sequences fluctuated in abundance in parallel, indicating that there were two distinct species present rather than one species with more than one COI or 18S locus. The oocysts of these new species cannot be differentiated morphologically. Sporulated oocysts of both were spherical to subspherical measuring 17.7 ± 0.22 µm by 17.1 ± 0.20 µm with a mean L/W ratio of 1.03 ± 0.004. Sporocysts were ovoid measuring 13.5 ± 0.17 µm by 9.3 ± 0.15 µm with a mean L/W ratio of 1.4 ± 0.02. Sporocysts had a small Stieda body with indistinct sub-Stieda body; each sporocyst had a compact residuum. Two morphologically similar but genetically divergent Isospora species were shown to cause simultaneous enteric and extraintestinal infections in captive superb glossy starlings.

The complete mitochondrial genome sequences of two Isospora species (Eimeriidae, Eucoccidiorida, Coccidiasina, Apicomplexa) causing coccidiosis in superb glossy starlings, Lamprotornis superbus (Aves: Sturnidae).

Complete mitochondrial genomes are reported for two Isospora species causing systemic coccidiosis in Superb Glossy Starlings (Aves: Sturnidae). The A/T rich (34.7% G/C) genomes were 6223 bp in length for Isospora greineri and 6217 bp for Isospora superbusi. Each encoded 3 protein-coding genes, (COI, COIII and CytB) plus 18 LSU and 14 SSU rDNA fragments. Arrangement of protein- and rRNA-coding regions was identical to known Eimeria sp. mt genomes; start codon usage was conventional. The mitochondrial genome structures of Isospora and Eimeria species are conserved and reflect the close phylogenetic association between these eimeriid genera of apicomplexan parasites.

The complete mitochondrial genome sequence of Hepatozoon catesbianae (Apicomplexa: Coccidia: Adeleorina), a blood parasite of the green frog, Lithobates (formerly Rana) clamitans.

A complete mitochondrial genome for the blood parasite Hepatozoon catesbianae (Alveolata; Apicomplexa; Coccidia; Adeleorina; Hepatozoidae) was obtained through PCR amplification and direct sequencing of resulting PCR products. The mitochondrial genome of H. catesbianae is 6,397 bp in length and contains 3 protein-coding genes (cytochrome c oxidase subunit I [COI]; cytochrome c oxidase subunit III [COIII]; and cytochrome B [CytB]). Sequence similarities to previously published mitochondrial genomes of other apicomplexan parasites permitted annotation of 23 putative rDNA fragments in the mitochondrial genome of H. catesbianae, 14 large subunit rDNA fragments, and 9 small subunit rDNA fragments. Sequences corresponding to rDNA fragments RNA5, RNA8, RNA11, and RNA19 of Plasmodium falciparum were not identified in the mitrochondrial genome sequence of H. catesbianae. Although the presence of 3 protein-coding regions and numerous putative rDNA fragments is a feature typical for apicomplexan mitochondrial genomes, the mitochondrial genome of H. catesbianae possesses a structure and gene organization that is distinct among the Apicomplexa. This is the first complete mitochondrial genome sequence obtained from any apicomplexan parasite in the suborder Adeleorina.

Divergent nuclear 18S rDNA paralogs in a turkey coccidium, Eimeria meleagrimitis, complicate molecular systematics and identification.

Multiple 18S rDNA sequences were obtained from two single-oocyst-derived lines of each of Eimeria meleagrimitis and Eimeria adenoeides. After analysing the 15 new 18S rDNA sequences from two lines of E. meleagrimitis and 17 new sequences from two lines of E. adenoeides, there were clear indications that divergent, paralogous 18S rDNA copies existed within the nuclear genome of E. meleagrimitis. In contrast, mitochondrial cytochrome c oxidase subunit I (COI) partial sequences from all lines of a particular Eimeria sp. were identical and, in phylogenetic analyses, COI sequences clustered unambiguously in monophyletic and highly-supported clades specific to individual Eimeria sp. Phylogenetic analysis of the new 18S rDNA sequences from E. meleagrimitis showed that they formed two distinct clades: Type A with four new sequences; and Type B with nine new sequences; both Types A and B sequences were obtained from each of the single-oocyst-derived lines of E. meleagrimitis. Together these rDNA types formed a well-supported E. meleagrimitis clade. Types A and B 18S rDNA sequences from E. meleagrimitis had a mean sequence identity of only 97.4% whereas mean sequence identity within types was 99.1-99.3%. The observed intraspecific sequence divergence among E. meleagrimitis 18S rDNA sequence types was even higher (approximately 2.6%) than the interspecific sequence divergence present between some well-recognized species such as Eimeria tenella and Eimeria necatrix (1.1%). Our observations suggest that, unlike COI sequences, 18S rDNA sequences are not reliable molecular markers to be used alone for species identification with coccidia, although 18S rDNA sequences have clear utility for phylogenetic reconstruction of apicomplexan parasites at the genus and higher taxonomic ranks.