Genomic analysis of the causative agents of coccidiosis in domestic chickens

Reid, Adam J.; Blake, Damer P.; Ansari, Hifzur Rahman; Billington, Karen; Browne, Hilary P.; Bryant, Josephine M.; Dunn, Matthew; Hung, Stacy; Kawahara, Fumiya; Miranda‐Saavedra, Diego; Malas, Tareq B.; Mourier, Tobias; Naghra, Hardeep; Nair, Mridul; Otto, Thomas D.; Rawlings, Neil D.; Rivailler, Pierre; Sánchez-Flores, Alejandro; Sanders, Mandy; Subramaniam, Chandra; Tay, Yea-Ling; Woo, Yong; Wu, Xikun; Barrell, Bart; Dear, Paul H.; Doerig, Christian; Gruber, Arthur; Ivens, Alasdair; Parkinson, John; Rajandream, Marie‐Adèle; Shirley, M. W.; Wan, Kiew Lian; Berriman, Matthew; Tomley, Fiona M.; Pain, Arnab

doi:10.1101/gr.168955.113

Cited by 176 publications

(276 citation statements)

References 59 publications

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“…Examples of naturally occurring genetic diversity have been reliably overcome by the inclusion of more than one "strain" of a single species in some vaccine formulations (11). Each Eimeria species expresses between 6,000 and 9,000 proteins throughout its lifecycle (13), exposing the host to a complex portfolio of antigens. Genetic mapping studies with Eimeria maxima indicated that at least six loci associate absolutely with susceptibility to strong natural immune responses, and additional loci under partial selection also were detectable (14).…”

Section: Significancementioning

confidence: 99%

“…More cost-effective subunit vaccines composed of a small number of Eimeria antigens are needed for the mass broiler market; however, these vaccines are likely to induce more focused immune selection, which potentially could drive rapid selection of vaccine-resistant populations. Eimeria tenella is considered one of the most important species because it is widespread and highly pathogenic (13,15). It also is the best-studied species and therefore was selected as the exemplar in these studies.…”

Section: Significancementioning

confidence: 99%

See 1 more Smart Citation

Population, genetic, and antigenic diversity of the apicomplexanEimeria tenellaand their relevance to vaccine development

Blake

Clark

Macdonald

et al. 2015

Proc. Natl. Acad. Sci. U.S.A.

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The phylum Apicomplexa includes serious pathogens of humans and animals. Understanding the distribution and population structure of these protozoan parasites is of fundamental importance to explain disease epidemiology and develop sustainable controls. Predicting the likely efficacy and longevity of subunit vaccines in field populations relies on knowledge of relevant preexisting antigenic diversity, population structure, the likelihood of coinfection by genetically distinct strains, and the efficiency of cross-fertilization. All four of these factors have been investigated for Plasmodium species parasites, revealing both clonal and panmictic population structures with exceptional polymorphism associated with immunoprotective antigens such as apical membrane antigen 1 (AMA1). For the coccidian Toxoplasma gondii only genomic diversity and population structure have been defined in depth so far; for the closely related Eimeria species, all four variables are currently unknown. Using Eimeria tenella, a major cause of the enteric disease coccidiosis, which exerts a profound effect on chicken productivity and welfare, we determined population structure, genotype distribution, and likelihood of crossfertilization during coinfection and also investigated the extent of naturally occurring antigenic diversity for the E. tenella AMA1 homolog. Using genome-wide Sequenom SNP-based haplotyping, targeted sequencing, and single-cell genotyping, we show that in this coccidian the functionality of EtAMA1 appears to outweigh immune evasion. This result is in direct contrast to the situation in Plasmodium and most likely is underpinned by the biology of the direct and acute coccidian life cycle in the definitive host.Eimeria | coccidiosis | population structure | chickens | food security

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Section: Significancementioning

confidence: 99%

Section: Significancementioning

confidence: 99%

Population, genetic, and antigenic diversity of the apicomplexanEimeria tenellaand their relevance to vaccine development

Blake

Clark

Macdonald

et al. 2015

Proc. Natl. Acad. Sci. U.S.A.

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“…Self-recognition proteins have also been described for gamete fertilization in Plasmodium; namely, members of an amplified gene family which encodes glycophosphatidyl inositol (GPI)-linked proteins composed of 6-cys domains (Van Dijk et al 2010) and the HAP2 protein which functions in membrane fusion (Liu et al 2008). The 6-cys domain proteins are related to the Toxoplasma and Eimeria GPI-linked surface coat SAG proteins, and have been proposed to have originated via lateral transfer of metazoan ephrin proteins (Gerloff et al 2005;Arredondo et al 2012;Reid et al 2014). Ten members of the family are present in Plasmodium and appear to have roles in multiple stages of the lifecycle, including hepatocyte and intraerythrocytic stages (Ishino et al 2005;Sanders et al 2005;Annoura et al 2014).…”

Section: Introductionmentioning

confidence: 99%

Diversity of extracellular proteins during the transition from the ‘proto-apicomplexan’ alveolates to the apicomplexan obligate parasites

Templeton

Pain

2015

Parasitology

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S U M M A R YThe recent completion of high-coverage draft genome sequences for several alveolate protozoans -namely, the chromerids, Chromera velia and Vitrella brassicaformis; the perkinsid Perkinsus marinus; the apicomplexan, Gregarina niphandrodes, as well as high coverage transcriptome sequence information for several colpodellids, allows for new genome-scale comparisons across a rich landscape of apicomplexans and other alveolates. Genome annotations can now be used to help interpret fine ultrastructure and cell biology, and guide new studies to describe a variety of alveolate life strategies, such as symbiosis or free living, predation, and obligate intracellular parasitism, as well to provide foundations to dissect the evolutionary transitions between these niches. This review focuses on the attempt to identify extracellular proteins which might mediate the physical interface of cell-cell interactions within the above life strategies, aided by annotation of the repertoires of predicted surface and secreted proteins encoded within alveolate genomes. In particular, we discuss what descriptions of the predicted extracellular proteomes reveal regarding a hypothetical last common ancestor of a pre-apicomplexan alveolate -guided by ultrastructure, life strategies and phylogenetic relationships -in an attempt to understand the evolution of obligate parasitism in apicomplexans.

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“…HAARs of this type, encoding strings of at least seven amino acids, were found in 57 % of E. tenella genes. Reid et al (2014) found that glutamine HAARs occurred mainly in regions with medium to high solvent accessibility. Due to the glutamine repeats, the N-terminus of the Eimeria apicortins is predicted to be disordered with the highest, near 100 %, probability, which provides, indeed, high solvent accessibility.…”

Section: Figmentioning

confidence: 97%

“…Eimeria protein-coding sequences are known to be extremely rich in homopolymeric amino acid repeats (HAARs), the extent of which is greater in Eimeria than in any other organism sequenced to date (Reid et al 2014). The most common repeat in Eimeria genus is the trinucleotide CAG, which occurs mostly in coding sequences, and encodes preferentially alanine or glutamine.…”

Section: Figmentioning

confidence: 99%

Wider than Thought Phylogenetic Occurrence of Apicortin, A Characteristic Protein of Apicomplexan Parasites

Orosz

2016

J Mol Evol

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Genomic analysis of the causative agents of coccidiosis in domestic chickens

Cited by 176 publications

References 59 publications

Population, genetic, and antigenic diversity of the apicomplexanEimeria tenellaand their relevance to vaccine development

Population, genetic, and antigenic diversity of the apicomplexanEimeria tenellaand their relevance to vaccine development

Diversity of extracellular proteins during the transition from the ‘proto-apicomplexan’ alveolates to the apicomplexan obligate parasites

Wider than Thought Phylogenetic Occurrence of Apicortin, A Characteristic Protein of Apicomplexan Parasites

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