Experimental infections of Eimeria alpacae and Eimeria punoensis in llamas (Lama glama).

Four llamas (Lama glama) ranging in age from 1.5 yr to 7 yr each were inoculated orally with 10,000 (n = 2) or 50,000 (n = 2) sporulated oocysts of Eimeria alpacae (25%) and Eimeria punoensis (75%). The prepatent period for E. aplacae was 16-18 days, and it was 10 days for E. punoensis. Patent periods for E. alpacae and E. punoensis were approximately 9 days and 24 days, respectively. Although large numbers of oocysts were present in feces, no clinical sign of coccidiosis was observed. Based on ths experiment, E. alpacae and E. punoensis at the numbers given are not likely pathogenic in healthy llamas older than 1 yr.     

Cryptosporidium serpentis oocysts and microsporidian spores in feces of captive snakes

Fecal smears of 90 snakes, 29 lizards, and 8 turtles and tortoises were tested for Cryptosporidium spp. oocysts and microsporidian spores. Microsporidian spores measured mean = 3.7 microm in length and mean = 2.3 microm in width and were present in feces of 19 snakes and 1 lizard (16%); 13 of these snakes also shed Cryptosporidium serpentis oocysts. The oocysts were numerous in all positive samples, whereas microsporidian spores were always sparse, irrespective if whether fecal samples contained the oocysts. Retrospective examination of reptile clinical records revealed that all animals shedding microsporidian spores died naturally due to diseases, pathologic conditions, and clinical problems or were killed due to severe cryptosporidiosis. The present study indicates that microsporidian infections in reptiles have the features of an opportunistic infection.     

Multiple leucine aminopeptidases in the oocysts of Eimeria tenella and their changes during sporulation

• 1.1. There was little neutral protease activity but high levels of leucine aminopeptidases (LAP) in the oocysts of Eimeria tenella.
• 2.2. By electrophoretic analysis, there were three apparent LAP isozymes I, II and III in unsporulated oocysts.
• 3.3. They all diminished with the simultaneous emergence of a new, fast-moving isozyme V during late phase of sporulation.
• 4.4. The enzyme V was unlikely to have resulted from de novo protein synthesis and was predominantly in the cytoplasm surrounding the sporocysts.
• 5.5. It differed from the other isozymes by a slightly higher pH optimum, more dependence on Mn²⁺ or Mg²⁺ in the assay and higher susceptibility to chelating agents.
• 6.6. The possible biological function of these isozymes remain unknown. Since they were not found in sporozoites or merozoites of E. tenella, they may be needed only for sporulation and, possibly, excystation.

     

Optimized excystation protocol for ruminant Eimeria bovis- and Eimeria arloingi-sporulated oocysts and first 3D holotomographic microscopy analysis of differing sporozoite egress

Successful excystation of sporulated Eimeria spp. oocysts is an important step to acquire large numbers of viable sporozoites for molecular, biochemical, immunological and in vitro experiments for detailed studies on complex host cell-parasite interactions. An improved method for excystation of sporulated oocysts and collection of infective E. bovis- and E. arloingi-sporozoites is here described. Eimeria spp. oocysts were treated for at least 20 h with sterile 0.02 M _L-cysteine HCl/0.2 M NaHCO₃ solution at 37 °C in 100% CO₂ atmosphere. The last oocyst treatment was performed with a 0.4% trypsin 8% sterile bovine bile excystation solution, which disrupted oocyst walls with consequent activation of sporozoites within oocyst circumplasm, thereby releasing up to 90% of sporozoites in approximately 2 h of incubation (37 °C) with a 1:3 (oocysts:sporozoites) ratio. Free-released sporozoites were filtered in order to remove rests of oocysts, sporocysts and non-sporulated oocysts. Furthermore, live cell imaging 3D holotomographic microscopy (Nanolive®) analysis allowed visualization of differing sporozoite egress strategies. Sporozoites of both species were up to 99% viable, highly motile, capable of active host cell invasion and further development into trophozoite- as well as macroment-development in primary bovine umbilical vein endothelial cells (BUVEC). Sporozoites obtained by this new excystation protocol were cleaner at the time point of exposure of BUVEC monolayers and thus benefiting from the non-activation status of these highly immunocompetent cells through debris. Alongside, this protocol improved former described methods by being is less expensive, faster, accessible for all labs with minimum equipment, and without requirement of neither expensive buffer solutions nor sophisticated instruments such as ultracentrifuges.     

Cross-transmission studies with Eimeria arizonensis, E. arizonensis-like oocysts and Eimeria langebarteli: host specificity at the genus and species level within the Muridae

Cross-transmission experiments were done using sporulated oocysts of Eimeria arizonensis from Peromyscus truei and Peromyscus maniculatus, and oocysts of 2 putative species that resemble E. arizonensis, i.e., Eimeria albigulae from Neotoma albigula, and Eimeria onychomysis from Onychomys leucogaster. Oocysts of each species were inoculated into representatives of P. maniculatus and the latter 2 rodent species. Other experiments were conducted wherein oocysts of Eimeria langebarteli from Peromyscus leucopus were given to P. truei and P. maniculatus. Oocysts of E. arizonensis from P. truei and P. maniculatus could be transmitted only to P. maniculatus; likewise, oocysts of E. albigulae and E. onychomysis produced patent infections only in N. albigula and O. leucogaster, respectively. Oocysts of E. langebarteli from P. leucopus could be transmitted to P. truei, but not P. maniculatus. These results indicate that E. arizonensis, and the morphologically similar E. albigulae and E. onychomysis, are distinct species that are not transmissible between the genera of their respective hosts (Peromyscus, Neotoma, Onychomys), and that some isolates of E. langebarteli, reported from 6 species of Peromyscus and Reithrodontomys megalotis, may not always be infective to P. maniculatus.     

Effect of the anticoccidial arprinocid on production, sporulation, and infectivity of Eimeria oocysts

Medication of broilers with arprinocid [MK-302, 9-(2-chloro-6-fluorbenzyl adenine)] had 3 distinct effects on oocysts; (1) the number of oocysts produced was decreased, (2) fewer of the oocysts sporulated, and (3) those oocysts which did sporulate were less infective than those from unmedicated birds. The drug level necessary to prevent passage of oocysts depended on the species and strain of coccidia. To essentially eliminate oocyst production (less than 5% of controls) required medication with the following levels of arprinocid: 70 ppm with Eimeria maxima; 60 ppm with E. mivati, E. E. necatrix, and E. brunetti; and 50 ppm with E. tenella. With E. acervulina, oocysts were completely eliminated by 60 ppm of arprinocid with one field strain but were still numerous at 70 ppm with a second field strain. Oocysts recovered from birds on medication often failed to sporulate. No sporulation was seen at drug levels of 30 ppm or above with E. maxima and E. mivati. The level of arpinocid required to prevent sporulation with other species depended on the strain being studied, but varied from 30 ppm to 70 ppm. The oocysts of E. acervulina, E. mivati, E. tenella, and E. brunetti recovered from medicated birds that subsequently sporulated, were less infective when inoculated into susceptible birds, than oocysts from unmedicated birds. Oocysts from low medication level with E. necatrix (30 ppm) and E. maxima (10 ppm), once sporulated, were as infective as oocysts from unmedicated control birds, even though the numbers produced were less. No differences were detected in the time oocysts were produced between medicated and unmedicated birds infected with E. acervulina, E. maxima, E. brunetti, and E. tenella.     

Further studies on the development of gamonts and oocysts of Eimeria magna in cultured cells

Monolayer, cell-line cultures of embryonic bovine trachea, Madin-Darby bovine kidney (MDBK), and monolayers (RK-1) or aggregates of primary rabbit kidney cells were inoculated with merozoites obtained from rabbits that had been inoculated 3 to 5 1/2 days earlier with Eimeria magna. Merozoites obtained from from rabbits 3 days entered cells and underwent only merogony, whereas 3 1/2-5 1/2-day-old merozoites formed gamonts as well as meronts. Merozoites arising from the first or second meront generation in culture formed another meront generation or gamonts. Third-generation merozoites formed only gamonts. Most merozoites remained within the parasitophorous vacuole of the original host cell and transformed into macro- or microgamonts or meronts. Some such macro- and microgamonts then fused with each other to form larger multinucleated bodies. Such microgamonts formed microgametes, but multinucleate macrogamonts did not form oocysts. Mature microgamonts were 34 microns in diameter, and contained several hundred biflagellate microgametes. Mature macrogamonts measured 29.1 x 21.5 microns, unsporulated oocysts were 31.2 x 22 microns, and sporulated oocysts were 32 x 23.1 microns. Oocysts obtained from cell cultures were sporulated and then inoculated by gavage into rabbits, which passed E. magna oocysts 6--10 days later. Sporozoites, obtained from oocysts produced in culture or from rabbits that had been inoculated with the vitro-produced oocysts, developed to first- and second-generation meronts in MDBK or RK-1 cultures.     

Isolation of amylopectin granules and identification of amylopectin phosphorylase in the oocysts of Eimeria tenella.

Amylopectin granules were purified from Eimeria tenella oocysts following digestion with sodium dodecyl sulfate and pronase. The oval granules had a uniform size of 0.5 X 0.7 mum, and consisted of only glucose polymers. alpha-Amylase treatment yielded 235 nmoles of maltose from the granules from 10(6) unsporulated oocysts and 93 nmoles maltose from those from 10(6) sporulated oocysts. Amylopectin phosphorylase activity was detected in the cytoplasm of unsporulated oocysts of E. tenella. It had a specific activity of 13 U/mg protein in crude extracts, and a pH optimum of 6.0. The Km values determined were 9.1 mM for glucose-1-phosphate and 5.6 mM for glucose end groups in potato amylopectin. Enzyme activity declined at a linear rate during sporulation, sporulated oocysts containing less than 8% of the activity of unsporulated oocysts. No amylase-type activity was found in the parasite.     

Ultrastructural localization of antigenic sites on sporozoites, sporocysts, and oocysts of Eimeria acervulina and Eimeria tenella by monoclonal IgG and IgM antibodies

Immunoelectron microscopy was used to study the localization of monoclonal IgG (13.9 and 15.84) and IgM (10.84) antibodies generated against Eimeria tenella sporozoites on sporozoites, sporocysts, and oocysts of Eimeria acervulina and E. tenella. A uniform layer of ferritin was present on sporozoites of E. tenella fixed chemically before the addition of 10.84, 13.90, or 15.84 (called prefixed), whereas postfixed (fixed chemically after exposure to monoclonal antibody) sporozoites lacked ferritin, indicating that the latter had capped immune complexes. Patches of ferritin were present on prefixed and postfixed sporozoites of E. acervulina exposed to 15.84, indicating that immune complexes containing 15.84 were not capped. Sporocysts of E. tenella exposed to 10.84 had a uniform layer of ferritin on their outer surface; ferritin was localized in patches on those exposed to 13.90 or 15.84. In E. acervulina sporocysts exposed to 15.84, ferritin was widely scattered on the outer surface but formed a uniform layer on the inner surface of the sporocyst wall. Patches of ferritin occurred on the inner layer of the oocyst walls of E. tenella and E. acervulina exposed to 10.84, 13.90, or 15.84. These findings indicate the shared antigen detected by 15.84 differed in relative amount, spatial distribution, and structural location in sporozoites and sporocysts of E. acervulina and E. tenella.