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The purpose of this study was to determine if Eimeria oocyst concentrations and species composition in commercial broiler house litter changed during different cycles of anticoccidial drug (ACD) or live Eimeria oocyst vaccine (VAC) control programs and if there was a correlation between Eimeria oocyst levels and broiler performance. Litter samples were collected from a total of 15 different broiler farms encompassing a total of 45 individual houses during at least one complete grow-out cycle over a 21-mo period. Of these 15 broiler farms, three were followed for the entire 21-mo period spanning three ACD and four VAC cycles. Samples were collected at 2, 4, and 7–8 wk of grow-out corresponding to starter, grower, and withdraw periods of the ACD cycle. On a number of occasions, litter samples were obtained just prior to chick placement. Eimeria oocysts were isolated from all samples, counted by microscopy, and extracted for DNA to identify Eimeria species by ITS1 PCR. In general, Eimeria oocyst concentration in litter reached peak levels at 2–4 wk of grow-out regardless of coccidiosis control measure being used. However, peak oocyst numbers were sometimes delayed until 7–8 wk, indicating some level of Eimeria spp. drug resistance or incomplete vaccine coverage. Eimeria maxima, Eimeria acervulina, Eimeria praecox, and Eimeria tenella were generally present in all samples, and no difference in the species composition was noted between houses on a particular farm. While Eimeria species composition was similar among houses, Eimeria spp. oocyst levels exhibited sporadic peaks in one house of a given location's houses. Of particular interest was the observed correlation between E. maxima oocyst abundance and chick mortality. However, no correlation was observed in E. maxima oocyst levels, and the performance parameters adjusted feed conversion ratio and average daily weight gain. This study showed that understanding the dynamics of Eimeria spp. oocyst levels and species composition in litter during ACD or VAC programs may provide insight into the effectiveness of coccidiosis control measures in commercial broiler production.

Background Poultry coccidiosis is a parasitic enteric disease with a highly negative impact on chicken production. In-feed chemoprophylaxis remains the primary method of control, but the increasing ineffectiveness of anticoccidial drugs, and potential future restrictions on their use has encouraged the use of commercial live vaccines. Availability of such formulations is constrained by their production, which relies on the use of live chickens. Several experimental approaches have been taken to explore ways to reduce the complexity and cost of current anticoccidial vaccines including the use of live vectors expressing relevant Eimeria proteins. We and others have shown that vaccination with transgenic Eimeria tenella parasites expressing Eimeria maxima Apical Membrane Antigen-1 or Immune Mapped Protein-1 ( Em AMA1 and Em IMP1) partially reduces parasite replication after challenge with a low dose of E. maxima oocysts. In the present study, we have reassessed the efficacy of these experimental vaccines using commercial birds reared at high stocking densities and challenged with both low and high doses of E. maxima to evaluate how well they protect chickens against the negative impacts of disease on production parameters. Methods Populations of E. tenella parasites expressing Em AMA1 and Em IMP1 were obtained by nucleofection and propagated in chickens. Cobb500 broilers were immunised with increasing doses of transgenic oocysts and challenged two weeks later with E. maxima to quantify the effect of vaccination on parasite replication, local IFN-γ and IL-10 responses (300 oocysts), as well as impacts on intestinal lesions and body weight gain (10,000 oocysts). Results Vaccination of chickens with E. tenella expressing Em AMA1, or admixtures of E. tenella expressing Em AMA1 or Em IMP1, was safe and induced partial protection against challenge as measured by E. maxima replication and severity of pathology. Higher levels of protection were observed when both antigens were delivered and was associated with a partial modification of local immune responses against E. maxima , which we hypothesise resulted in more rapid immune recognition of the challenge parasites. Conclusions This study offers prospects for future development of multivalent anticoccidial vaccines for commercial chickens. Efforts should now be focused on the discovery of additional antigens for incorporation into such vaccines.

Parasitic infections caused by Eimeria species are responsible for most economic losses in poultry production. Prevalence studies can adequately assist the design of prophylaxis strategies for disease control. Therefore, stool samples from 251 flocks of broilers from 28 to 48 days old were collected in 21 municipalities in the state of Santa Catarina, Brazil, to detect and examine the prevalence of Eimeria acervulina, Eimeria maxima, Eimeria tenella, Eimeria mitis, Eimeria praecox, Eimeria necatrix, and Eimeria brunetti. The oocysts were recovered and quantified, and the species were identified by a multiplex PCR technique. Amplicons of seven Eimeria species originating from the PCR-positive samples were cloned. Microscopy studies demonstrated that 96% of the farms were positive for the Eimeria. Seven species were identified, as follows: E. maxima (63.7%) and E. acervulina (63.3%) were the most prevalent species, followed by E. tenella (54.6%), E. mitis (38.6%), E. praecox (25.1%), E. necatrix (24.3%), and E. brunetti (13.1%). The average number of species detected per farm was 2.96, and the most common were E. acervulina, E. maxima, and E. tenella (9.16%). The sequencing of the clones confirmed the specificity and effectiveness of multiplex PCR for the identification of seven species of Eimeria, so this tool can be useful in studying circulating species in poultry farms, thereby assisting prophylactic measures against coccidiosis.

Prevalence studies can adequately assist in the design of prophylaxis strategies for disease control. Here, the prevalence of Eimeria species in chickens was investigated in Anhui province, China, from July to September 2016. A total of 171 samples were tested by microscopic examination and molecular methods. The prevalence of coccidiosis in Anhui province was found to be 87.75% (150/171). Eimeria tenella was the most prevalent species (80.67%, 121/150), and Eimeria necatrix , Eimeria mitis , Eimeria maxima , Eimeria brunetti and Eimeria acervulina were 68% (102/150), 55.33% (83/150), 54.67% (82/150), 44.67% (67/150) and 2.67% (4/150), respectively. Eimeria praecox was not detected at all. The most common combinations are E . tenella , E . maxima , E . necatrix , E . brunetti and E . mitis (26.67%, 40/150), followed by E . tenella , E . maxima and E . necatrix (19.33%, 29/150). Eimeria necatrix exhibited the highest participation in multiple infections. The results of the present study suggested that Eimeria infection is mixed, severe and widespread in chickens, Therefore, integrated strategies should be performed to prevent and control coccidial infection in chickens in Anhui province.

Identifying Eimeria spp. circulating in a poultry flock assists in designing vaccine preventive programs, as different species do not cross-protect. Because species differ in anticoccidial drug susceptibility, species identification can also be used to optimize anticoccidial medication. In the present study, we designed pan-Eimeria–specific primers for the 18S rDNA and the cytochrome oxidase I (COI) genes, and tested whether next-generation sequencing of their amplicons allowed reliable identification of Eimeria spp. in samples of isolated oocysts. For each gene, two sets of primers to be used in a nested PCR (nPCR) system were designed. In silico evaluation of the primers using published sequences showed that nucleotide sequence identities of the nested amplicons were less than 97% between most species, while only identities of 18S rDNA genes of Eimeria necatrix and Eimeria tenella and between the COI genes of Eimeria mitis and Eimeria mivati were higher than 97%. Three vaccines and five Eimeria samples from chickens in backyard flocks were investigated by nPCRs and by direct PCRs (dPCR) using the nested (inner) primers with genomic DNA as the template. Seventeen further Eimeria samples from chickens in backyard flocks and three Eimeria samples from commercial broiler flocks were investigated only by nPCR. Sequencing nPCR products tended to detect more species than sequencing dPCR products and sequencing 18S rDNA products tended to detect more species than sequencing COI products. Regarding the detected species, there was a clear difference between the commercial broiler flocks and the backyard flocks. Eimeria acervulina, Eimeria maxima, and E. tenella/E. necatrix were the only species detected in broiler flocks, while the population in the backyard flocks was more varied, with Eimeria brunetti and E. mitis/E. mivati and the previously described operational taxonomic unit Y being more prevalent. Several sequences having less than 97% identity with one of the sequences used for clustering were detected in samples from backyard flocks. In conclusion, next-generation amplicon sequencing can be a useful tool to determine which Eimeria spp. are circulating in chicken flocks.

Background Avian coccidiosis is often caused by co-infection with several species of Eimeria worldwide. Developing a multivalent vaccine with an antigen common to multiple Eimeria species is a promising strategy for controlling clinical common co-infection of Eimeria . In the previous study, 14–3-3 was identified as one of the immunogenic common antigen in E. tenella , E. acervulina and E. maxima . The aim of the present study was to evaluate the immunogenicity and protective efficacy of Ea14–3-3 in the form of DNA vaccine against infection with three species of Eimeria both individually and simultaneously. Results After vaccination with pVAX-Ea14–3-3, the Ea14–3-3 gene was transcribed and expressed in the injected muscles. Vaccination with pVAX-Ea14–3-3 significantly increased the proportion of CD4 + and CD8 + T lymphocytes and produced a strong IgY response in immunized chickens. Similarly, pVAX-Ea14–3-3 stimulated the chicken’s splenocytes to produce high levels of Th1-type (IFN-γ, IL-2) and Th2-type (IL-4) cytokines. The vaccine-induced immune response was responsible to increase weight gain, decreased the oocyst output, and alleviated enteric lesions significantly in immunized chickens as compared to control group, in addition to induce moderate anti-coccidial index (ACI). Conclusion These results indicate that Ea14–3-3 is highly immunogenic and capable to induce significant immune responses. Furthermore, Ea14–3-3 antigen can provide effective protection against infection with Eimeria tenella , Eimeria acervulina , Eimeria maxima both individually and in combination with three Eimeria species . Significant outcomes of our study provide an effective candidate antigen for developing a multivalent Eimeria vaccine against mixed infection with various Eimeria species under natural conditions.

Coccidiosis is a common disease of camels, and camels are important for the economy of Asia and the Arabian Peninsula. Little is known regarding the prevalence of coccidian parasites in camels in Egypt. Fecal samples collected from the rectums of 200 camels at the Cairo slaughterhouse were processed using the sucrose flotation technique. Eimeria species oocysts were found in 38%. Three Eimeria species were identified: Eimeria cameli–like in 31%, Eimeria rajasthani in 18%, and Eimeria dromedarii in 14%. The morphology of E. rajasthani and E. dromedarii oocysts was identical to that in literature. However, there was great variability in size and structure among E. cameli oocysts; oocysts were 70–100 lm long and truncate to ovoid. Four morphotypes (types 1 to 4) were recognized. Types 1 and 2 oocysts had similar truncate ovoid shape and were dark brown, but their shape indices were different. Both types could be easily distinguished from type 3 (elongate ovoid and light brown). All oocysts were enclosed in a transparent outer covering (capsule), although this capsule was barely seen in types 3 and 4. An extension from the capsule situated in front of the micropyle, referred to as polar cap–like structure (PCL), was characteristic for types 1 and 2. The PCL of type 1 resembled the crown, while in type 2 it looked like a small thickening with a smooth top. The PCL was absent in types 3 and 4 oocysts. The latter was found only in a single oocyst. Experimental infections with E. cameli oocysts and molecular studies are needed to determine whether the monotypes described here are different species or strain variations or both.

Avian coccidiosis is a huge problem worldwide. Heavily infected animals that show severe clinical signs and coccidiostat resistance are causing important economic losses. The present study aimed to update the recent cases of coccidiosis in Central Java, Indonesia, and to show the importance of the disease in the region. A total of 699 samples were obtained from different chicken breed. Different Eimeria species were detected in 175 individuals (25.04%). Three different groups of chicken breed were considered: local chicken (autochthonous chickens of Sentul and Jawa), commercial broiler, and layer. Broiler chickens showed the highest prevalence of infection (34%), followed by layer (26.26%) and local chickens (10.45%). Mild to severe clinical signs of avian coccidiosis were observed in 42% of the infected animals, while 58% of the infected animals showed no clinical signs other than low feed conversion rates. Seven different Eimeria species were identified: E. tenella was the most prevalent (43.3%), followed by E. maxima (26.3%), E. necatrix (15.7%), E. acervulina (8%), E. praecox (3.1%), E. mitis (2.2%), and E. brunetti (1.3%). Coinfections with several Eimeria species were diagnosed. With this study we found massive usage of coccidiostat in the region even though its usage cannot guarantee coccidiosis-free chicken production.

Background Avian coccidiosis is a widespread, economically significant disease of poultry, caused by several Eimeria species. These parasites have complex and diverse life-cycles that require invasion of their host cells. This is mediated by various proteins secreted from apical secretory organelles. Apical membrane antigen 1 (AMA1), which is released from micronemes and is conserved across all apicomplexans, plays a central role in the host cell invasion. In a previous study, some putative Et AMA1-interacting proteins of E. tenella were screened. In this study, we characterized one putative Et AMA1-interacting protein, E. tenella Eimeria -specific protein ( Et Esp). Methods Bimolecular fluorescence complementation (BiFC) and glutathione S-transferase (GST) fusion protein pull-down (GST pull-down) were used to confirm the interaction between Et AMA1 and Et Esp in vivo and in vitro. The expression of Et Esp was analyzed in different developmental stages of E. tenella with quantitative PCR and western blotting. The secretion of Et Esp protein was tested with staurosporine when sporozoites were incubated in complete medium at 41 °C. The localization of Et Esp was analyzed with an immunofluorescence assay (IFA). An in vitro invasion inhibition assay was conducted to assess the ability of antibodies against Et Esp to inhibit cell invasion by E. tenella sporozoites. Results The interaction between Et AMA1 and Et Esp was confirmed with BiFC and by GST pull-down. Our results show that Et Esp is differentially expressed during distinct phases of the parasite life-cycle. IFA showed that the Et Esp protein is mainly distributed on the parasite surface, and that the expression of this protein increases during the development of the parasite in the host cells. Using staurosporine, we showed that Et Esp is a secreted protein, but not from micronemes. In inhibition tests, a polyclonal anti-r Et Esp antibody attenuated the capacity of E. tenella to invade host cells. Conclusion In this study, we show that Et Esp interacts with Et AMA1 and that the protein is secreted protein, but not from micronemes. The protein participates in sporozoite invasion of host cells and is maybe involved in the growth of the parasite. These data have implications for the use of Et AMA1 or Et AMA1-interacting proteins as targets in intervention strategies against avian coccidiosis.

Sixty billion chickens are produced worldwide each year, and all are at risk from Eimeria , parasites that cause coccidiosis. Control relies widely on chemoprophylaxis, but pressure to reduce drug use in farming urges development of cost-effective vaccines. Antigens such as apical membrane antigen 1 (AMA1) offer promise as anticoccidial vaccine candidates, but experience with related apicomplexans such as Plasmodium , in which pre-existing antigenic diversity and incompatible population structure have undermined vaccine development, tempers confidence. Parasite genotyping identified enormous region-specific variation in haplotype diversity for Eimeria tenella but a contrastingly low level of polymorphism for Et AMA1. Although high levels of polyclonal Eimeria infection and hybridization indicate an ability to disseminate vaccine resistance rapidly, the low level of Et AMA1 diversity promotes vaccine development. 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 cross-fertilization 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 Et AMA1 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.