Eimeria tenella: incomplete excystation in the presence of EDTA in a taurodeoxycholate-based medium

Normally, sporozoites of Eimeria tenella are efficiently excysted in vitro with trypsin and bile salts. However, a one hour treatment at 40 degrees C with a chelator-supplemented excystation medium (purified trypsin and chymotrypsin, taurodeoxycholate and ethylenediaminetetraacetic acid in buffered saline) produced incomplete excystation. The treatment removed the sporocyst plug and left an opened sporocyst containing motile sporozoites, but the release of sporozoites was greatly reduced (less than 12% release). Some of the sporozoites extended a portion of their anterior end through the sporocyst opening then retracted it into the sporocyst. Sporozoites were released when magnesium was added to the chelator-supplemented medium. Manganese was less effective and calcium was ineffective in producing release. Also, sporozoites were released when the incompletely excysted sporocysts were transferred to buffered saline with albumin and this became the basis for a new assay. The assay demonstrated that ethylenediaminetetraacetic acid reduced release in the presence of taurodeoxycholate but not in its absence. Hydrophobic and hydrophilic chelators were tested in the assay. Ethylene-dioxy diethylene-dinitrilotetraacetic acid and 8-hydroxyquinoline were inactive. The chelator 1,10-phenanthroline did not require bile salt to reduce release. The inhibitory effects by phenanthroline were eliminated in the presence of magnesium or manganese, while calcium had no effect. Thus, although certain chelators can inhibit release, a consistent correlation between chelation and inhibition of release has not been established. The application of ethylenediaminetetraacetic acid with taurodeoxycholate as a reversible inhibitor of release is discussed.     

The use of sodium taurodeoxycholate for excystation of Eimeria tenella sporozoites

As an in vitro excystor, sodium taurodeoxycholate (TDC) released 80--90% Eimeria tenella sporozites, in contrast to 0--15% excystation by six other bile salts or bile extracts, and pooled chicken bile in 90 min at 37 C with continuous agitation. Pooled chicken bile required 4 to 4 1/2 hr to excyst similar percentages of sporozoites. Prolonged incubation with other bile salts and bile extracts excysted most sporozoites, but killed them. When the incubation temperature was raised to 44 C, TDC excysted 100% of the sporozoites in 60 min. In all other bile salts or bile extracts, the percentage of excystation increased greatly at 44 C, but none equalled that of TDC. The molecular similarity of TDC to a naturally occurring bile salt of chickens is presented as an explanation for the superior performance of TDC as an excystor. Data are examined to minimize the possibility that excysting activity of TDC can be attributed to other bile salts present at impurities.     

Ultrastructure of Excystment of Toxoplasma gondii Oocysts*

SYNOPSIS. The excystation of sporozoites from intact Toxoplasma gondii oocysts or mechanically released sporocysts was studied by light and electron microscopy. Both intact oocysts and free sporocysts excysted in 5% bovine bile in 0.9% NaCl solution after 30–60 min incubation at 37 C. Sporozoites were first activated in either intact sporocysts or oocysts within 2–12 min of incubation in bile. Sporozoites escaped from sporocysts through 4 plate-like sutures in the sporocyst wall, and from the oocyst as the oocyst wall ruptured at one or more points.     

The Effects of pH,Buffers, Bile and Bile Acids on Excystation of Sporozoites of Various Eimeria Species*

SYNOPSIS. Oocysts of Eimeria bovis were found to undergo excystation when subjected at 39 C to a pretreatment consisting of exposure for 24 hr to CO₂ and air (50–50), and a treatment for 7 hr with a mixture of bile and trypsin. At pH's of 6.0 thru 10.0 with tris-maleate buffer, excystation occurred over the entire range of pH tested, with the highest levels at pH 7.5-8.5. No adverse or inhibitive effect on excystation or the viability of the sporozoites was observed. Disintegration of sporozoites occurred within the sporocysts of intact oocysts at each of the pH levels studied when boric acid-borax, ammediol, and glycine-sodium hydroxide buffers were used in the treatment medium. Phosphate buffer inhibited excystation when used in the excysting medium. Excystation occurred at levels above 90% in all dilutions of taurocholic, glycocholic, glycotaurocholic, and cholic acids included in the study (0.5-10.0%) except for the 10% and 5% dilutions of cholic acid and the 10% dilution of glycotaurocholic acid. In the latter 3 dilutions, sporozoites within the sporocysts of intact oocysts disintegrated. Excystation levels above 90% were observed in the 50% and 10% dilutions of fresh bovine bile, and in the 5% dilution of lyophilized bovine bile. Lower levels of excystation occurred in greater dilutions of both kinds of bile. No excystation occurred when any of the bile acids, fresh bovine bile or lyophilized bile were used without trypsin, except for fresh bile that contained a heavy suspension of bacteria and fungi. In a medium containing trypsin and heat-treated bile, heat-treated bile acids, or no bile, 2.5–8% of the oocysts excysted. The findings indicate that satisfactory excystation can be obtained with a treatment medium containing tris-maleate at pH 7.5–8.5, 0.25% trypsin, and 1% of one of the bile acids.     

In Vitro Excystation of Caryospora simplex (Apicomplexa: Eimeriorina)1

In vitro excystation of sporozoites of the heteroxenous coccidian Caryospora simplex Léger, 1904 (Apicomplexa: Eimeriorina) is described. Sporocysts freed mechanically from oocysts released a maximum of 51% of their sporozoites within 45 min at 25°C and a maximum of 74% within 20 min at 37°C when incubated in a 0.25% (w/v) trypsin–0.75% (w/v) sodium taurocholate (bile salt) excystation solution. At emergence from sporocysts, sporozoites were weakly motile then became highly active after about 2 min in excystation solution. Sporozoites within sporocysts exposed to bile salt only became highly motile within 25 min at 25°C and within 15 min at 37°C but did not excyst. When exposed only to trypsin at the above temperatures, the Stieda body dissolved; the substieda body remained intact, and the sporozoites exhibited only limited motility within sporocysts; only a few excysted. Intact, sporulated oocysts incubated at 25° or 37°C in 0.02 M cysteine-HC1 and a 50% CO₂ atmosphere for 18 h had no morphologic changes in the oocyst wall. Further incubation of these intact oocysts in excystation solution for 30 min at 37°C caused neither motility of sporozoites within sporocysts nor excystation. Grinding oocysts for 30 sec in a motor-driven, teflon-coated tissue grinder caused motility of some sporozoites within sporocysts but did not result in excystation.     

The Effects of Reducing Conditions, Medium, pH, Temperature, and Time on in Vitro Excystation of Cryptosporidium

ABSTRACT. Whereas excystation of sporozoites from oocysts of most coccidian species requires exposure to reducing conditions followed by pancreatic enzymes and bile salts, sporozoites of a bovine isolate of Cryptosporidium excysted without exposure to either reducing conditions or to pancreatic enzymes and bile salts. Without prior exposure to reducing conditions, a high percent excysted after incubation in a mixture of trypsin and bile salts in Ringer's solution; fewer excysted after incubation in tap water, even fewer after incubation in salt solutions, and none after incubation in saliva. Excystation, generally greater at pH 7.6 than at pH 6.0 and at 37°C than at 20°C, was observed as early as 1 h after incubation in water or the trypsin-bile mixture. These findings provide circumstantial evidence that oocysts of Cryptosporidium can excyst in extraintestinal sites and liberate sporozoites that can initiate autoinfection.     

The effects of reducing conditions, medium, pH, temperature, and time on in vitro excystation of Cryptosporidium

Whereas excystation of sporozoites from oocysts of most coccidian species requires exposure to reducing conditions followed by pancreatic enzymes and bile salts, sporozoites of a bovine isolate of a bovine isolate of Cryptosporidium excysted without exposure to either reducing conditions or to pancreatic enzymes and bile salts. Without prior exposure to reducing conditions, a high percent excysted after incubation in a mixture of trypsin and bile salts in Ringer's solution; fewer excysted after incubation in tap water, even fewer after incubation in salt solutions, and none after incubation in saliva. Excystation, generally greater at pH 7.6 than at pH 6.0 and at 37 degrees C than at 20 degrees C, was observed as early as 1 h after incubation in water or the trypsin-bile mixture. These findings provide circumstantial evidence that oocysts of Cryptosporidium can excyst in extraintestinal sites and liberate sporozoites that can initiate autoinfection.     

Chemical and physical factors affecting the excystation of Cryptosporidium parvum oocysts.

Cryptosporidium parvum oocysts were examined to ascertain excystation requirements and the effects of gamma irradiation. Oocysts and excysted sporozoites were examined for dye permeability and infectivity. Maximum excystation occurred when oocysts were pretreated with acid and incubated with bile salts, and potassium or sodium bicarbonate. Pretreatment with Hanks' balanced salt solution or NaCl lowered excystation; however, this effect was overcome with acid. Sodium ions were replaceable with potassium ions, and sodium bicarbonate was replaceable with sodium phosphate. Oocysts that received 200 krad irradiation excysted at the same rates as nonirradiated oocysts (95%), the excystation rates were lowered (50%) by 2,000 krad, and no excystation was observed by 5,000 krad. No differences were observed between the propidium iodide (PI) permeability of untreated oocysts and oocysts treated with 200 krad, while 92% of oocysts were PI positive after 2,000 krad. Most of the sporozoites exposed to 2,000 krad were not viable as indicated by the dye permeability assay. The oocysts irradiated with 200 and 2,000 krad infected cells, but no replication was observed. The results suggest that gamma-irradiated oocysts may still be capable of excystation and apparent infection; however, because the sporozoites could not reproduce they must not have been viable.     

Scanning electron microscopy and chemical excystation of Fascioloides magna (Trematoda) metacercariae

Scanning electron microscopy was used to study encysted metacercariae and newly excysted juveniles of Fascioloides magna. The outer cyst was rough, coarse and discontinuous in the ventral aspect; the inner cyst was smooth. The newly excysted metacercaria was plump and contained numerous tegumentary spines; large dome-shaped papillae were prominent around the oral sucker and on the rim of the acetabulum. Encysted metacercariae with outer cysts were excysted in an alkaline bile salts-trypsin medium at an elevated temperature in the absence of acid saline or acid pepsin pretreatment. Pretreatment in acid saline slightly decreased subsequent excystation, while pretreatment in acid pepsin slightly enhanced subsequent excystation in the alkaline bile salts-trypsin medium.     

In vitro excystation of Cryptosporidium baileyi from chickens

Release of sporozoites from the oocysts of Cryptosporidium baileyi is described from Nomarski interference-contrast microscopy. Just prior to excystation, the four sporozoites became motile and rearranged themselves within the oocyst. The sporozoites were then rapidly expelled through an opening that formed in the oocyst wall, and the residuum was either released or retained within the oocyst. Excysted sporozoites were crescent shaped and measured 5.0-9.0 microns X 1.0-1.6 micron (mean = 6.8 X 1.1 microns). Excystation occurred when sodium taurocholate or a mixture of trypsin and sodium taurocholate was present in the incubation medium. High levels of excystation occurred at 37 degrees or 40 degrees C, but excystation did not occur at 4 degrees C. The ability of biles from two avian and two mammalian hosts to produce excystation of C. baileyi was also studied. After a 2-h incubation at 40 degrees C, the percentages of excystation were 69.5% in goat bile, 45.0% in pig bile, 33.0% in chicken bile, and 34.5% in turkey bile.     

In Vitro Excystation of Cryptosporidium baileyi from Chickens1

Release of sporozoites from the oocysts of Cryptosporidium baileyi is described from Nomarski interference-contrast microscopy. Just prior to excystation, the four sporozoites became motile and rearranged themselves within the oocyst. The sporozoites were then rapidly expelled through an opening that formed in the oocyst wall, and the residuum was either released or retained within the oocyst. Excysted sporozoites were crescent shaped and measured 5.0–9.0 μm × 1.0–1.6 μm (x?= 6.8 × 1.1 μm). Excystation occurred when sodium taurocholate or a mixture of trypsin and sodium taurocholate was present in the incubation medium. High levels of excystation occurred at 37° or 40°C, but excystation did not occur at 4°C. The ability of biles from two avian and two mammalian hosts to produce excystation of C. baileyi was also studied. After a 2-h incubation at 40°C, the percentages of excystation were 69.5% in goat bile, 45.0% in pig bile, 33.0% in chicken bile, and 34.5% in turkey bile.     

In vitro excystation of Echinostoma paraensei (Digenea: Echinostomatidae) metacercariae assessed by light microscopy,morphometry and confocal laser scanning microscopy

Trypsin and bile salts have been identified as important triggers for excystation of Echinostoma metacercariae. Although excystation in trematodes is a well-known phenomenon, some morphological developmental changes remain to be elucidated. In order to gain further insight into the in vitro development of metacercariae, we assayed different cultivating conditions: 0.5% trypsin and 0.5% bile salts; 1% trypsin and 1% bile salts; 1% trypsin and 0.5% bile salts; 0.5% bile salts; or 0.5% trypsin. By means of light microscopy and confocal microscopy, we characterized each encysted, activated, breached and excysted stage based on the morphological features. However, breached and excysted stages were not revealed in both bile salts and trypsin-free medium. Excretory concretions (25 ± 3.9) were visualized within excretory tubules, close to the ventral sucker and genital anlage. The oral sucker armed with spines and digestive system was similar to those of adult worms. The reproductive system is composed of a genital anlage and the cirrus sac primordium. In short, trypsin and bile salts associated were fundamental for the in vitro metacercariae excystation of Echinostoma paraensei. This article presents the first detailed information of all stages of metacercariae excystation obtained through light and confocal microscopy.     

Comparative Excystation of Four Species of Poultry Coccidia

SYNOPSIS. Examination of the crop, gizzard, and intestinal contents of chickens fed suspensions of either Eimeria acervulina or E. tenella oocysts and turkeys fed either E. meleagrimitis or E. gallopavonis oocysts indicated that, in all 4 species, (1) oocysts apparently remained unchanged while in the crop, (2) sporocysts were liberated from oocysts while the latter were passing through the gizzard, (3) sporozoites were activated and escaped from liberated sporocysts after they had reached the small intestine, and (4) sporozoites within intact oocysts in the crop, gizzard, and intestines were not activated.
In vitro , trypsin 1–300 alone caused a small percentage of sporozoites to excyst from mechanically liberated sporocysts. The percentage of excystation increased greatly when trypsin was added to sodium taurocholate and increased even more when it was combined with chicken or turkey bile.
The two duodenal species ( E. acervulina and E. meleagrimitis ) differed both in vivo and in vitro from the two cecal species ( E. tenella and E. gallopavonis ). The duodenal species excysted in less time and farther anteriorly in the small intestine than did the cecal species. In addition, sporozoites of the two cecal species survived much longer in media containing trypsin plus bile or sodium taurccholate than did those of the two duodenal species.     

In vitro excystation of Sarcocystis capracanis, Sarcocystis cruzi and Sarcocystis tenella (Apicomplexa)

Improved rates of in vitro excystation of sporozoites from sporocysts of Sarcocystis capracanis, Sarcocystis cruzi, and Sarcocystis tenella were obtained by pretreating sporocysts with an aqueous sodium hypochlorite (NaOCl) solution followed by incubation in excysting fluid (EF). After pretreatment with NaOCl, sporocysts were washed 4 times in Hanks' balanced salt solution and then incubated in various EF (pH 7.4) at 38.5 C in 5% CO2-95% air. Maximum rates of excystation (free sporozoites/(sporozoites in sporocysts + free sporozoites) X 100) for all 3 species of Sarcocystis occurred at 4 hr after incubation in EF. These rates were 17% for S. capracanis after incubation in EF containing 2% trypsin + 10% caprine bile; 90% for S. cruzi in 2% trypsin + 10% bovine bile; and 20% for S. tenella in 2% trypsin + 10% caprine bile. Only a 40% excystation rate occurred in sporocysts of S. cruzi that had been stored previously for 14 days in aqueous potassium dichromate. Excysted sporozoites of S. capracanis, S. cruzi, and S. tenella penetrated and developed to mature meronts in bovine pulmonary artery endothelial cells or bovine monocytes.     

Proteomics analysis and protein expression during sporozoite excystation of Cryptosporidium parvum (Coccidia, Apicomplexa)

Cryptosporidiosis, caused by coccidian parasites of the genus Cryptosporidium, is a major cause of human gastrointestinal infections and poses a significant health risk especially to immunocompromised patients. Despite intensive efforts for more than 20 years, there is currently no effective drug treatment against these protozoa. This study examined the zoonotic species Cryptosporidium parvum at two important stages of its life cycle: the non-excysted (transmissive) and excysted (infective) forms. To increase our understanding of the molecular basis of sporozoite excystation, LC-MS/MS coupling with a stable isotope N-terminal labeling strategy using iTRAQ reagents was used on soluble fractions of both non-excysted and excysted sporozoites, i.e. sporozoites both inside and outside oocysts were examined. Sporozoites are the infective stage that penetrates small intestinal enterocytes. Also to increase our knowledge of the C. parvum proteome, shotgun sequencing was performed on insoluble fractions from both non-excysted and excysted sporozoites. In total 303 C. parvum proteins were identified, 56 of which, hitherto described as being only hypothetical proteins, are expressed in both excysted and non-excysted sporozoites. Importantly we demonstrated that the expression of 26 proteins increases significantly during excystation. These excystation-induced proteins included ribosomal proteins, metabolic enzymes, and heat shock proteins. Interestingly three Apicomplexa-specific proteins and five Cryptosporidium-specific proteins augmented in excysted invasive sporozoites. These eight proteins represent promising targets for developing vaccines or chemotherapies that could block parasite entry into host cells.     

Excystation of the Poultry Coccidium, Eimeria acervulina

SYNOPSIS. Using intervals up to 5 hours, attempts to excyst sporozoites of Eimeria acervulina from intact oocysts in vitro were unsuccessful.
Examination of crop, gizzard, and intestinal contents of chicks fed large numbers of sporulated oocysts indicated that (1) no obvious change in the oocysts occurred in the crop, (2) a high percentage of the sporocysts were quickly released from the oocysts in the gizzard, (3) the sporozoites escaped from the liberated sporocysts in the duodenum and jejunum, and (4) the action of the digestive juice was apparently on the sporocysts rather than on the oocysts.
In vitro attempts to excyst sporozoites from free sporocysts with various pancreatic preparations in the absence of bile produced low or insignificant percentages of excystation. In the presence of bile, bile salts, and other surface-active agents, the action of the pancreatic preparations was greatly increased. The heaviest suspension of motile, nonaggregating sporozoites was obtained with 0.25% trypsin 1–300 in 5% chicken bile at pH 7.6.     

Pancreatic chymotrypsin as the essential enzyme for excystation of Eimeria tenella.

Sporocysts from the protozoan parasite, Eimeria tenella, were isolated, preincubated with sodium taurocholate, and treated with various preparations of pancreatic enzymes. Crude trypsin, crude lipase, and purified alpha-chymotrypsin all could break the shells of sporocysts and release sporozoites. Purified trypsin was much less active than crude trypsin and purified lipase showed no activity at all. Specific inhibitors of chymotrypsin, tosyl-L-phenylalanyl chloromethane, diphenylcarbamyl chloride, and chymostatin inhibited the release of sporozoites by all the enzyme samples, whereas tosyl-L-lysyl chloromethane, a specific inhibitor of trypsin, exerted no inhibitory effect. It is thus postulated that chymotrypsin, not trypsin, is an essential enzyme involved in excystation of E. tenella. Purified chymotrypsin is recommended to replace crude trypsin in the vitro excystation of E. tenella as a likely improved procedure.     

Eimeria ahtanumensis n. sp. from the Northwestern Fence Lizard Sceloporus occidentalis in Central Washington

SYNOPSIS Eimeria ahtanumensis n. sp. is described from the northwestern fence lizard Sceloporus occidentalis. The sporulated oocysts are generally cylindrical with rounded ends, averaging 34.2 by 19.7 μ. No oocyst residuum or micropyle is present. The ellipsoidal sporocysts average 10.5 by 8.8 μ; each has a distinct sporocyst residuum composed of spherical granules located against the sides of the sporocysts. The elongate sporozoites, lying head to tail in the sporocyst, average 16.5 by 2.5 μ when excysted. Endogenous development occurs in the epithelial lining of the gall bladder and bile duct. E. ahtanumensis is compared to other similar lizard coccidia.     

The utilization of sodium taurocholate in excystation of Cryptosporidium parvum and infection of tissue culture.

The present work deals with optimization of excystation of Cryptosporidium parvum oocysts and the infection process of tissue culture cells by the parasite. It was shown that presence of the bile salt sodium taurocholate in the incubation medium expedited excystation of the tested GCH1 isolate and enhanced it, as compared with bleaching of the oocysts. This bile salt had no effect on the viability of tissue culture cell lines MDBK and HCT-8 at the tested concentration of 0.375% for up to 2 hr of coincubation. Infection studies conducted on tissue culture cells showed higher infection rates in the presence of sodium taurocholate than with bleached oocysts in the absence of this bile salt. It may be concluded that, at least as regards the GCH1 strain of C. parvum, the whole infection process can be performed in the presence of sodium taurocholate, and does not require separation and cleaning of the excysted sporozoites before their application to tissue culture cells.     

A simple and reliable method of producing in vitro infections of cryptosporidium parvum (apicomplexa)

Abstract A variety of techniques have been used to infect cell monolayers in culture with the protozoan, Cryptosporidium parvum . However, most of these methods rely on the use of trypsin and/or bile salts to excyst sporozoites in vitro, followed by washing sporozoites free of excystation solution prior to their addition to subconfluent monolayers. This method not only increases the amount of time required to establish infections in vitro, but also results in prolonged exposure of free sporozoites to environmental conditions. Here we report a simple, fast, and efficient method of obtaining consistent infections of C. parvum in cell monolayers. This technique relies on the ability of the parasite to excyst at 37°C but not at room temperature following pretreatment with sodium hypochlorite. By adding surface-sterilized oocysts directly to monolayers, sporozoites have access to host cells immediately upon excystation.