Statistical Prediction of the Peak Point (Time) Required for Release of Maximum Number of Sporocysts after Eimeria Tenella Oocyst Excystation

Cha, JO; Shim, KS; Lee, HW; Kim, HC

doi:10.1590/1806-9061-2020-1415

ABSTRACT

The excystation of sporozoites from the oocyst of genus Eimeria is essential for conducting successful in vitro assays on the parasite. We tried to find the most efficient excystation conditions using glass beads for the in vitro excystation of E. tenella oocysts. The oocyst suspension was mixed with glass beads in a ratio of 1:1, and vortexed by various combinations of vortexing times and speeds in a Vortex Mixer. We analyzed the sporocyst-release data by regression analysis, and the peak point (duration) of excystation was predicted after differentiation of the obtained regression equation. The results indicated that the 1-mm glass beads at 2,000 rpm could release the maximum number of sporocysts in 1.64 min. Thus, excystation of E. tenella oocysts was considered to be the most effective under these conditions. Our data presented the best conditions for efficient excystation of E. tenella oocysts.

Keywords:
Eimeria tenella; Glass bead; Excystation; Statistical prediction

INTRODUCTION

Apicomplexan parasites belonging to the genus Eimeria, the causal agents of coccidiosis, have huge impact on livestock, particularly on the poultry industry (Marugan-Hernandez et al., 2017Marugan-Hernandez V, Long E, Blake D, Crouch C, Tomley F. Eimeria tenella protein trafficking: differential regulation of secretion versus surface tethering during the life cycle. Scientific Reports 2017;7(1):4557.; Shirley et al., 2004Shirley MW, Ivens AI, Gruber A, et al. The Eimeria genome projects: a sequence of events. Trends Parasitology 2004;20(5):199-201.). Coccidiosis is the most common parasitic disease that affects the broiler industry, and the lack of prevention is estimated to cause worldwide losses of about $ 3 billion per year (Williams, 1999Williams RB. A compartmentalised model for the estimation of the cost of coccidiosis to the world's chicken production industry. International Journal of Parasitology 1999;29(8):1209-1229.; Noack et al., 2019Noack S, Chapman HD, Selzer PM. Anticoccidial drugs of the livestock industry. Parasitology Research 2019;118(7):2009-2026.). Seven species of Eimeria have been identified as the causal agents of coccidiosis in chickens (Shirley et al., 2007); these seven species develop in specific parts of the chicken’s intestines, and their pathogenicity is different for each species (Williams, 1999; Shirley et al., 2013). E. acervulina, E. maxima, and E. tenella are the most commonly found species in intensively reared chickens, and E. tenella is considered to be the predominant species that causes serious damage to chickens (Shirley et al., 2013; Macdonald et al., 2017Macdonald SE, Nolan MJ, Harman K, et al. Effects of Eimeria tenella infection on chicken caecal microbiome diversity, exploring variation associated with severity of pathology. PLoS One 2017;12(9):e0184890.).

Because coccidiosis is one of the most dangerous and economically burdening poultry diseases worldwide, over the past few decades extensive research on Eimeria has been carried out for various purposes (Shirley et al., 2013; Blake et al., 2011Blake DP, Oakes R, Smith AL. A genetic linkage map for the apicomplexan protozoan parasite Eimeria maxima and comparison with Eimeria tenella. International Journal of Parasitology 2011;41(2):263-270.; Lee et al., 2011Lee SH, Lillehoj HS, Jang SI, et al. Effects of dietary supplementation with phytonutrients on vaccine-stimulated immunity against infection with Eimeria tenella. Veterinary Parasitology 2011;181(2-4):97-105.). For the successful in vitro study of the parasite, excystation of sporozoites from Eimeria oocyst constitutes the first step. Therefore, many researchers have been conducting mechanical disruption of Eimeria oocysts.

However, Eimeria oocyst wall has a robust biological structure, which makes the release of sporocysts and sporozoites difficult (Belli et al., 2006Belli SI, Smith NC, Ferguson DJP. The coccidian oocyst: a tough nut to crack! Trends in Parasitology 2006;22(9):416-423.; Stotish et al., 1978Stotish RL, Wang CC, Meyenhofer M. Structure and composition of the oocyst wall of Eimeria tenella. Journal of Parasitology 1978;64(6):1074-1081.). Usually Teflon-coated tissue homogenizers (Krücken et al., 2008Krücken J, Hosse RJ, Mouafo AN, Entzeroth R, Bierbaum S, Marinovski P, et al. Excystation of Eimeria tenella sporozoites impaired by antibody recognizing gametocyte/oocyst antigens GAM22 and GAM56. Eukaryot Cell 2008;7(2):202-211.; Chai et al., 1989Chai JI, Lee SH, Kim WH, Yun CK. Development of Eimeria tenella in MDBK cell culture with a note on enhancing effect of preincubation with chicken spleen cells. Korean Journal Parasitology 1989;27(2):87-100.) or glass beads (Blake et al., 2011Blake DP, Oakes R, Smith AL. A genetic linkage map for the apicomplexan protozoan parasite Eimeria maxima and comparison with Eimeria tenella. International Journal of Parasitology 2011;41(2):263-270.; Haug et al., 2007Haug A, Thebo P, Mattsson JG. A simplified protocol for molecular identification of Eimeria species in field samples. Veterinary Parasitology 2007;146(1-2):35-45.; Tomley 1997Tomley F. Techniques for isolation and characterization of apical organelles from Eimeria tenella sprorozoites. Methods 1997;13(2):171-176.; Velkers et al., 2010Velkers FC, Blake DP, Graat EAM, Vernooij JCM, Bouma A, Jong MCM, et al. Quantification of Eimeria acervulina in faeces of broilers: comparison of McMaster oocyst counts from 24 h faecal collections and single droppings to real-time PCR from cloacal swabs. Veterinary Parasitology 2010;169(1-2):1-7.) are used to crush the oocyst wall. Glass beads are an effective tool for oocyst excystation. In the case of E. acervulina, excystation is done by vortexing glass beads, irrespective of their size, at 3,000 rpm for 5 min (Cha et al., 2014). The excystation of E. tenella is the most effective upon vortexing with 1-mm glass beads for 30 s to 1 min (You, 2014You MJ. Effects of different sizes of glass beads on the release of sporocysts from Eimeria tenella oocysts. Korean Journal Parasitology 2014;52(3):317-319.). Thus, for optimal oocyst excystation, it is necessary to optimize the size of glass beads, vortexing durations, and speed for each species of Eimeria. In this study, we describe the efficacy of different sizes of glass beads with various vortexing speeds and durations on the excystation of E. tenella oocysts.

MATERIALS AND METHODS

Parasite

Pure line E. tenella oocysts (GenBank: FJ447468.1) were amplified and sporulated in our laboratory according to standard procedures (Holdsworth et al., 2004Holdsworth PA, Conway DP, McKenzie ME, Dayton AD, Chapman HD, Mathis GF, et al. World Association for the Advancementof Veterinary Parasitology (WAAVP) guidelines for evaluating the efficacy of anticoccidial drugs in chickens and turkeys. Veterinary Parasitology 2004;121(3-4):189-212.). Only the normal forms of sporulated oocysts were selected. The oocysts were counted using a hematocytometer, which was adjusted to contain 1.5 × 10⁶ oocysts in 300 µL, and they were transferred to a 2 mL microcentrifuge tube. A total of 250 sample tubes were prepared for this experiment. The sporulated oocysts in each tube were physically excysted by varying the size of glass beads, vortexing speed, and vortexing durations (Table 1).

Oocyst excystation and counting

The oocyst suspension was mixed with the glass beads at a ratio of 1:1, and vortexed in a Vortex Mixer with selective mixing modes and variable speed control options (Model-VM 96B, Jeio Tech, South Korea) by adjusting the vortexing time and speed according to the combinations given in Table 1. Oocysts and excysted sporocysts were counted according to the method of Cha et al. (2014Cha JO, Talha AFSM, Lim CW, Kim B. Effects of glass bead size, vortexing speed and duration on Eimeria acervulina oocyst excystation. Experimental Parasitology 2014;138:18-24.). The experiments were repeated four times to obtain an average value.

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Table 1
Glass bead size, vortexing speed and duration used in the present experiment.

Determination of sporozoite viability

E. tenella oocysts were crushed with glass beads to obtain free sporocysts. The sporocysts were washed once in PBS and then incubated for 90 min at 40°C in a hybridization oven (MS major science, USA) with an enzyme solution [Porcine Trypsin (Sigma) 25 mg and Sodium taurodeoxycholate hydrate (Sigma) 75 mg dissolved in 10 mL PBS]. After excystation, the free sporozoites were centrifuged at 3,000 rpm for 10 min and resuspended with pre-warmed PBS. The viability of the sporozoites was determined by trypan blue dye exclusion method (Holdsworth et al., 2011).

Statistical analyses

Data obtained in this study were analyzed by Scheffe’s Test with ANOVA and progressing regression using SAS^® ver. 9.2.

Predicted peak point (time) of sporocyst number after excystation

Sporocyst data after excystation were analyzed and a functional equation was developed using regression in SAS. The peak point (vortexing duration time) was calculated by differentiation of the equation for each glass bead size and vortexing speed. The sporocyst number at the peak point was calculated by substituting the calculated peak point (vortexing duration time) in the functional equation (Barnett et al., 2008Barnett RA, Ziegler MR, Byleen KE. College mathematics for business, economics, life science, and social sciences. 11th ed. New Jersey: Pearson Education; 2008. p.79-81.).

RESULTS

Oocysts crushing with various sized glass beads, vortexing duration and speed

We observed that the rupture of E. tenella oocysts increased with increasing vortexing speed and duration, regardless of the size of the glass beads (p<0.01). At a vortexing speed of 1,000 rpm, large number of oocysts remained uncrushed, but at vortexing speeds of 2,000 and 3,000 rpm, the number of normal oocysts was significantly reduced with increasing vortexing duration (p<0.01). Our results also demonstrated that the oocysts were most effectively crushed when 1-mm glass beads were used (Table 2).

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Table 2
Changing pattern of oocyst number after crushing with different sized glass beads through specified vortexing duration and speed.

The best results were obtained under the following conditions: 1-mm glass beads at 2,000 rpm vortex speed for 1 min. For glass beads of all sizes, a relatively small number of sporocysts were released at 1,000 rpm compared to the number released by the vortex speeds of 2,000 and 3,000 rpm, regardless of all vortexing duration. We found that 1-mm glass beads released the highest number of intact sporocysts at 2,000 rpm with a vortexing period of 1 to 2 min compared to the number released by other glass beads under the same condition. In addition, in case of 0.5, 2 and 2.5 mm glass beads, a relatively higher number of sporocysts was released at 2,000 rpm compared to other vortex speeds. We found that the vortexing speed of 2,000 rpm was efficient for releasing intact sporocysts with glass beads of all sizes (Table 3).

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Table 3
Changing pattern of sporocyst number after crushing with different sized glass beads through specified vortexing duration and speed.

Predicted peak point of sporocyst number after excystation

At 2,000 rpm, the 1-mm glass bead data were calculated using the following regression equation: $Y = - 39.116 x^{2} + 128.43 x + 665.76 (R^{2} = 0.94341)$ (Fig. 1). The predicted peak point of vortexing duration for 1-mm glass beads was 1.64 min, and the regression equation predicted that 771 sporocysts would be released at this peak point (Table 4). The predicted peak point was the most efficient vortexing duration for sporocyst excystation using 1-mm glass beads at 2,000rpm.

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Table 4
Result of peak point (duration time) and sporocyst number calculated by analysed regression equation at 2,000 rpm each glass bead size.

Viability of released sporozoites

Trypan blue dye exclusion, the method which consists in placing the oocysts with trypan blue solution in hematocytometer and counting the dyed ones, was used to ascertain the viability of the released sporozoites (Cha et al., 2014Cha JO, Talha AFSM, Lim CW, Kim B. Effects of glass bead size, vortexing speed and duration on Eimeria acervulina oocyst excystation. Experimental Parasitology 2014;138:18-24.). The E. tenella oocysts were crushed with 1-mm glass beads at 2,000 rpm for 30 s, 1 min, 2 min, 3 min, and 5 min to acquire intact sporocysts. We found that the sporozoites had a viability exceeding 98% at all five time points (i.e., 30 s, 1, 2, 3, and 5 min), and there was no difference (data not shown).

Figure 1
Regression analysis for each glass bead size at 2,000 rpm vortexing speed. (A: 0.5mm, B: 1mm, C: 2mm and D: 2.5mm).

DISCUSSION

The excystation of sporulated Eimeria spp. oocysts is of great importance for molecular, biochemical, immunological and in vitro experiments for studies related to this parasite (Cha et al., 2014Cha JO, Talha AFSM, Lim CW, Kim B. Effects of glass bead size, vortexing speed and duration on Eimeria acervulina oocyst excystation. Experimental Parasitology 2014;138:18-24.; López-Osorio et al., 2020López-Osorio S, Silva LMR, Chaparro-Gutierréz JJ, Velásquez ZD, Taubert A, Hermosilla C. Optimized excystation protocol for ruminant Eimeria bovis- and Eimeria arloingi-sporulated oocysts and ?rst 3D holotomographic microscopy analysis of differing sporozoite egress. Parasitology International 2020;76:102068.). Therefore, the development of an efficient excystation method for oocysts of Eimeria spp. is essential. Various methods have been used to disrupt the walls of the oocysts of Eimeria spp., among which glass beads have proven to be the most effective (You, 2014You MJ. Effects of different sizes of glass beads on the release of sporocysts from Eimeria tenella oocysts. Korean Journal Parasitology 2014;52(3):317-319.; Zhao et al., 2001Zhao X, Duszynski DW, Loker ES. A simple method of DNA extraction for Eimeria species. Journal of Microbiological Methods 2001;44(2):131-137.).

Previous reports say that the release of sporocysts of E. tenella was most efficient when the duration of the treatment was 30 s to 1 min with 1-mm glass beads (You, 2014You MJ. Effects of different sizes of glass beads on the release of sporocysts from Eimeria tenella oocysts. Korean Journal Parasitology 2014;52(3):317-319.). In the case of E. acervulina, the highest number of intact sporocysts were released upon treatment with 1-mm glass beads at 2,000 rpm for 3 min (Cha et al., 2014Cha JO, Talha AFSM, Lim CW, Kim B. Effects of glass bead size, vortexing speed and duration on Eimeria acervulina oocyst excystation. Experimental Parasitology 2014;138:18-24.). In the current study, we tried to determine the most effective size of the glass beads, and the vortexing speed and duration for the excystation of E. tenella oocysts. To achieve a large number of viable sporozoites using glass beads, care and precision is required to avoid cracking the sporocysts while crushing the oocysts. In the present study, we observed that the 1-mm glass beads released the highest number of intact sporocysts with vortexing at 2,000 rpm for 1 min (Table 3, Fig. 1). In order to determine the future outcomes of the different sizes of glass beads on safe release of intact sporocysts, we analyzed the sporocyst-release data by regression analysis to ascertain the peak point (duration time) and calculated the number of sporocysts released at the predicted peak point. We only analyzed the data obtained at the vortexing speed of 2,000 rpm because this speed displayed the highest number of sporocysts (Table 4). The regression analysis revealed that the maximum number of sporocysts could be released in 1.64 min at 2,000 rpm by the 1-mm glass beads.

Our calculation using regression for 3,000 rpm could not provide the peak sporocyst production point for the 0.5, 1, and 2 mm glass beads, as there were continuous decrements in the number of sporocysts from the initial vortexing duration, i.e., 30 s.

Notably, at the vortexing speed of 3,000 rpm with relatively longer vortexing duration (3 and 5 min), the larger glass beads (2 and 2.5 mm) released a small number of sporocysts (Table 3), while crushing most of the oocysts (Table 2). These results signified that this combination is advantageous for extracting DNA, but disadvantageous for obtaining intact sporocysts. For DNA extraction (more crushing is required) all glass beads acted efficiently upon vortexing at 3,000 rpm for 5 min. The four different-sized glass beads provided enough extracted DNA for subsequent PCR amplification and species identification, so they could be used for this purpose at 3,000 rpm for 5 min or more. Based on our results, we recommend 1-mm glass beads, as the 1-mm-sized glass beads were efficient in crushing all oocysts at 3,000 rpm in 2 min (Table 2).

The viability of the E. tenella sporozoites released from the sporocysts was also verified. The viability assay was conducted after crushing the oocysts with 1-mm glass beads and releasing the sporozoites from the sporocysts. Trypan blue dye exclusion method revealed that at each time point, the viability of sporozoites was >98%, indicating that the use of 2,000 rpm vortexing speed was safe for obtaining live sporozoites.

CONCLUSION

Conclusively, E. tenella oocysts should be mixed 1:1 with 1mm glass beads and vortexed at 2,000rpm for 1.64 min to release the highest number of sporocysts.

ACKNOWLEDGEMENTS

This study was supported by the Kangwon National University in 2016.

REFERENCES

Barnett RA, Ziegler MR, Byleen KE. College mathematics for business, economics, life science, and social sciences. 11th ed. New Jersey: Pearson Education; 2008. p.79-81.
Belli SI, Smith NC, Ferguson DJP. The coccidian oocyst: a tough nut to crack! Trends in Parasitology 2006;22(9):416-423.
Blake DP, Oakes R, Smith AL. A genetic linkage map for the apicomplexan protozoan parasite Eimeria maxima and comparison with Eimeria tenella. International Journal of Parasitology 2011;41(2):263-270.
Cha JO, Talha AFSM, Lim CW, Kim B. Effects of glass bead size, vortexing speed and duration on Eimeria acervulina oocyst excystation. Experimental Parasitology 2014;138:18-24.
Chai JI, Lee SH, Kim WH, Yun CK. Development of Eimeria tenella in MDBK cell culture with a note on enhancing effect of preincubation with chicken spleen cells. Korean Journal Parasitology 1989;27(2):87-100.
Dong X, Abdelnabi GH, Lee SH, Li G, Jin H,Lillehoj HS, et al. Enhanced egress of intracellular Eimeria tenella sporozoites by splenic lymphocytes from coccidian-infected chickens. Infection and Immunity 2011;79(8):3465-3470.
Gyorke A, Pop L, Cozma V. Prevalence and distribution of Eimeria species in broiler chicken farms of different capacities. Parasite 2013;20:50.
Haug A, Thebo P, Mattsson JG. A simplified protocol for molecular identification of Eimeria species in field samples. Veterinary Parasitology 2007;146(1-2):35-45.
Holdsworth PA, Conway DP, McKenzie ME, Dayton AD, Chapman HD, Mathis GF, et al. World Association for the Advancementof Veterinary Parasitology (WAAVP) guidelines for evaluating the efficacy of anticoccidial drugs in chickens and turkeys. Veterinary Parasitology 2004;121(3-4):189-212.
Krücken J, Hosse RJ, Mouafo AN, Entzeroth R, Bierbaum S, Marinovski P, et al. Excystation of Eimeria tenella sporozoites impaired by antibody recognizing gametocyte/oocyst antigens GAM22 and GAM56. Eukaryot Cell 2008;7(2):202-211.
Lee SH, Lillehoj HS, Jang SI, et al. Effects of dietary supplementation with phytonutrients on vaccine-stimulated immunity against infection with Eimeria tenella. Veterinary Parasitology 2011;181(2-4):97-105.
López-Osorio S, Silva LMR, Chaparro-Gutierréz JJ, Velásquez ZD, Taubert A, Hermosilla C. Optimized excystation protocol for ruminant Eimeria bovis- and Eimeria arloingi-sporulated oocysts and ?rst 3D holotomographic microscopy analysis of differing sporozoite egress. Parasitology International 2020;76:102068.
Macdonald SE, Nolan MJ, Harman K, et al. Effects of Eimeria tenella infection on chicken caecal microbiome diversity, exploring variation associated with severity of pathology. PLoS One 2017;12(9):e0184890.
Marugan-Hernandez V, Long E, Blake D, Crouch C, Tomley F. Eimeria tenella protein trafficking: differential regulation of secretion versus surface tethering during the life cycle. Scientific Reports 2017;7(1):4557.
Noack S, Chapman HD, Selzer PM. Anticoccidial drugs of the livestock industry. Parasitology Research 2019;118(7):2009-2026.
Shirley MW, Ivens AI, Gruber A, et al. The Eimeria genome projects: a sequence of events. Trends Parasitology 2004;20(5):199-201.
Shirley MW, Smith AL, Blake DP. Challenges in the successful control of the avian coccidia. Vaccine 2007;25(30):5540-5547.
Stotish RL, Wang CC, Meyenhofer M. Structure and composition of the oocyst wall of Eimeria tenella. Journal of Parasitology 1978;64(6):1074-1081.
Tomley F. Techniques for isolation and characterization of apical organelles from Eimeria tenella sprorozoites. Methods 1997;13(2):171-176.
Velkers FC, Blake DP, Graat EAM, Vernooij JCM, Bouma A, Jong MCM, et al. Quantification of Eimeria acervulina in faeces of broilers: comparison of McMaster oocyst counts from 24 h faecal collections and single droppings to real-time PCR from cloacal swabs. Veterinary Parasitology 2010;169(1-2):1-7.
Williams RB. A compartmentalised model for the estimation of the cost of coccidiosis to the world's chicken production industry. International Journal of Parasitology 1999;29(8):1209-1229.
You MJ. Effects of different sizes of glass beads on the release of sporocysts from Eimeria tenella oocysts. Korean Journal Parasitology 2014;52(3):317-319.
Zhao X, Duszynski DW, Loker ES. A simple method of DNA extraction for Eimeria species. Journal of Microbiological Methods 2001;44(2):131-137.

Publication Dates

Publication in this collection
10 Sept 2021
Date of issue
2021

History

Received
30 Dec 2020
Accepted
08 Apr 2021

This is an open-access article distributed under the terms of the Creative Commons Attribution License

[1] Barnett RA, Ziegler MR, Byleen KE. College mathematics for business, economics, life science, and social sciences. 11th ed. New Jersey: Pearson Education; 2008. p.79-81.

[2] Belli SI, Smith NC, Ferguson DJP. The coccidian oocyst: a tough nut to crack! Trends in Parasitology 2006;22(9):416-423.

[3] Blake DP, Oakes R, Smith AL. A genetic linkage map for the apicomplexan protozoan parasite Eimeria maxima and comparison with Eimeria tenella. International Journal of Parasitology 2011;41(2):263-270.

[4] Cha JO, Talha AFSM, Lim CW, Kim B. Effects of glass bead size, vortexing speed and duration on Eimeria acervulina oocyst excystation. Experimental Parasitology 2014;138:18-24.

[5] Chai JI, Lee SH, Kim WH, Yun CK. Development of Eimeria tenella in MDBK cell culture with a note on enhancing effect of preincubation with chicken spleen cells. Korean Journal Parasitology 1989;27(2):87-100.

[6] Dong X, Abdelnabi GH, Lee SH, Li G, Jin H,Lillehoj HS, et al. Enhanced egress of intracellular Eimeria tenella sporozoites by splenic lymphocytes from coccidian-infected chickens. Infection and Immunity 2011;79(8):3465-3470.

[7] Gyorke A, Pop L, Cozma V. Prevalence and distribution of Eimeria species in broiler chicken farms of different capacities. Parasite 2013;20:50.

[8] Haug A, Thebo P, Mattsson JG. A simplified protocol for molecular identification of Eimeria species in field samples. Veterinary Parasitology 2007;146(1-2):35-45.

[9] Holdsworth PA, Conway DP, McKenzie ME, Dayton AD, Chapman HD, Mathis GF, et al. World Association for the Advancementof Veterinary Parasitology (WAAVP) guidelines for evaluating the efficacy of anticoccidial drugs in chickens and turkeys. Veterinary Parasitology 2004;121(3-4):189-212.

[10] Krücken J, Hosse RJ, Mouafo AN, Entzeroth R, Bierbaum S, Marinovski P, et al. Excystation of Eimeria tenella sporozoites impaired by antibody recognizing gametocyte/oocyst antigens GAM22 and GAM56. Eukaryot Cell 2008;7(2):202-211.

[11] Lee SH, Lillehoj HS, Jang SI, et al. Effects of dietary supplementation with phytonutrients on vaccine-stimulated immunity against infection with Eimeria tenella. Veterinary Parasitology 2011;181(2-4):97-105.

[12] López-Osorio S, Silva LMR, Chaparro-Gutierréz JJ, Velásquez ZD, Taubert A, Hermosilla C. Optimized excystation protocol for ruminant Eimeria bovis- and Eimeria arloingi-sporulated oocysts and ?rst 3D holotomographic microscopy analysis of differing sporozoite egress. Parasitology International 2020;76:102068.

[13] Macdonald SE, Nolan MJ, Harman K, et al. Effects of Eimeria tenella infection on chicken caecal microbiome diversity, exploring variation associated with severity of pathology. PLoS One 2017;12(9):e0184890.

[14] Marugan-Hernandez V, Long E, Blake D, Crouch C, Tomley F. Eimeria tenella protein trafficking: differential regulation of secretion versus surface tethering during the life cycle. Scientific Reports 2017;7(1):4557.

[15] Noack S, Chapman HD, Selzer PM. Anticoccidial drugs of the livestock industry. Parasitology Research 2019;118(7):2009-2026.

[16] Shirley MW, Ivens AI, Gruber A, et al. The Eimeria genome projects: a sequence of events. Trends Parasitology 2004;20(5):199-201.

[17] Shirley MW, Smith AL, Blake DP. Challenges in the successful control of the avian coccidia. Vaccine 2007;25(30):5540-5547.

[18] Stotish RL, Wang CC, Meyenhofer M. Structure and composition of the oocyst wall of Eimeria tenella. Journal of Parasitology 1978;64(6):1074-1081.

[19] Tomley F. Techniques for isolation and characterization of apical organelles from Eimeria tenella sprorozoites. Methods 1997;13(2):171-176.

[20] Velkers FC, Blake DP, Graat EAM, Vernooij JCM, Bouma A, Jong MCM, et al. Quantification of Eimeria acervulina in faeces of broilers: comparison of McMaster oocyst counts from 24 h faecal collections and single droppings to real-time PCR from cloacal swabs. Veterinary Parasitology 2010;169(1-2):1-7.

[21] Williams RB. A compartmentalised model for the estimation of the cost of coccidiosis to the world's chicken production industry. International Journal of Parasitology 1999;29(8):1209-1229.

[22] You MJ. Effects of different sizes of glass beads on the release of sporocysts from Eimeria tenella oocysts. Korean Journal Parasitology 2014;52(3):317-319.

[23] Zhao X, Duszynski DW, Loker ES. A simple method of DNA extraction for Eimeria species. Journal of Microbiological Methods 2001;44(2):131-137.

Glass bead size (mm)	Duration (min)	1,000 rpm	2,000 rpm	3,000 rpm
Glass bead size (mm)	Duration (min)	Oocysts number	Oocysts number	Oocysts number
	0.5	294.75± 18.87 ^bA	290.50±28.03^aA	32.00± 4.69^aB
	1	273.25±193.26^bA	231.25±35.32^bB	12.00± 3.37^bC
0.5	2	252.00± 16.41^bA	119.00± 8.76^cB	1.75± 1.71^cC
	3	444.25± 44.49^aA	88.00±16.87^cdB	0.25± 0.50^cC
	5	391.50± 16.54 ^aA	43.50± 9.95 ^dB	0.00± 0.00^cC
	0.5	335.00± 11.37^A	129.25±20.76^aB	20.75± 3.95^aC
1	1	319.00± 30.47^A	62.00± 3.92^bB	1.50± 0.58^bC
	2	313.25± 43.12^A	4.50± 1.91^cB	0.00± 0.00^bB
	3	391.50± 18.36^A	3.00± 1.15^cB	0.00± 0.00^bB
	5	337.25± 51.21^A	0.00± 0.00 ^cB	0.00± 0.00^bB
	0.5	248.00± 34.55ab^A	174.50±36.46^aB	88.00±18.31^aC
2	1	282.75± 15.97a^A	100.75±21.36^bB	28.00± 7.12^bC
	2	228.25± 21.09ab^A	50.50± 6.56^cB	2.00± 2.45^cC
	3	259.75± 19.81a^A	16.25± 3.40^cdB	1.25± 0.50^cB
	5	190.00± 30.30b^A	2.00± 1.41^dB	0.00± 0.00^cB
	0.5	346.50± 25.83^A	222.00±30.88^aB	133.75±29.43^aC
2.5	1	344.75± 63.33^A	162.25±26.34^bB	63.75± 6.65^bC
	2	352.00± 46.21^A	45.50± 6.56^cB	18.00± 7.79^cB
	3	265.75± 19.22^A	31.00± 5.23^cB	8.00± 4.08^cC
	5	279.00± 45.28^A	6.75± 2.63^cB	0.25± 0.50^cB

Glass bead size (mm)	Duration (min)	1,000 rpm	2,000 rpm	3,000 rpm
Glass bead size (mm)	Duration (min)	Sporocysts number	Sporocysts number	Sporocysts number
	0.5	48.25±14.77^C	367.75±5.13^cB	664.50±33.51^aA
	1	31.00± 4.55^B	408.00±1.14^bA	405.00±24.24^bA
0.5	2	45.50±17.18^C	507.25±9.36^aA	103.50± 7.55^cB
	3	64.00±33.46^B	445.50±5.10^abA	22.75± 1.26^dB
	5	42.25±19.19^B	313.25±2.28^dA	2.50± 0.58^dC
	0.5	84.00± 3.16^cC	679.50±8.91^bB	759.25±65.99^aA
1	1	96.25±17.56^cC	805.25±9.43^aA	554.75±50.40^bB
	2	103.00±9.42^cC 198.00±20.80^bB 348.00±21.40^aA	785.00±2.10^aA	237.25±54.88^cB
	3	198.00±20.80^bB	662.00±3.38^bA	136.25± 7.63^cdC
	5	348.00±21.40^aA	338.75±4.99^cA	34.75± 4.19^dB
	0.5	46.75±23.44^cC	345.25±1.37^cB	497.00±23.12^aA
2	1	49.00±15.77^cB	571.25±2.37^aA	554.25±75.95^aA
	2	147.50±13.43^bC	630.50±2.12^aA	369.25±33.18^bB
	3	168.00±15.56^abC	575.25±1.28^aA	246.25±15.00^cB
	5	207.25±19.52^aB	447.75±0.50^bA	108.50±14.39^dC
	0.5	46.00± 8.37^dC	341.75±7.11^dB	505.25±42.75^abA
2.5	1	80.25±14.95^bB	525.75±7.31^bA	546.50±23.46^aA
	2	98.50±18.57^bC	630.25±8.14^aA	506.75±20.69^abB
	3	56.00± 8.76^cC	681.00±6.38^aA	444.75±24.51^bB
	5	142.50±13.10^aC	483.25±4.25^bA	279.75±22.13^cB

	Size of glass bead (mm)	Statistical predicted peak point (vortexing duration: min)	Number of calculated sporocysts at predicted peak point	Significant difference for regression equation
A	0.5	2.50	479.5163	P<0.01
B	1	1.64	771.1788	P<0.01
C	2	2.82	631.7654	P<0.01
D	2.5	2.99	689.6122	P<0.01

Brasil

Brasil

Statistical Prediction of the Peak Point (Time) Required for Release of Maximum Number of Sporocysts after Eimeria Tenella Oocyst Excystation

ABSTRACT

INTRODUCTION

MATERIALS AND METHODS

Parasite

Oocyst excystation and counting

Determination of sporozoite viability

Statistical analyses

Predicted peak point (time) of sporocyst number after excystation

RESULTS

Oocysts crushing with various sized glass beads, vortexing duration and speed

Predicted peak point of sporocyst number after excystation

Viability of released sporozoites

DISCUSSION

CONCLUSION

ACKNOWLEDGEMENTS

REFERENCES

Publication Dates

History