The Life Cycle of Cryptosporidium baileyi n. sp. (Apicomplexa, Cryptosporidiidae) Infecting Chickens

ABSTRACT. The life cycle and morphology of a previously undescribed species of Cryptosporidium isolated from commercial broiler chickens is described. The prepatent period for Cryptosporidium baileyi n. sp. was three days post oral inoculation (PI) of oocysts, and the patent period was days 4–24 PI for chickens inoculated at two days of age and days 4–14 for chickens inoculated at one and six months of age. During the first three days PI, most developmental stages of C. baileyi were found in the microvillous region of enterocytes of the ileum and large intestine. By day 4 PI, most parasites occurred in enterocytes of the cloaca and bursa of Fabricius (BF). Mature Type I meronts with eight merozoites first appeared 12 h PI and measured 5.0 × 4.9 μm. Mature Type II meronts with four merozoites and a large granular residuum first appeared 48 h PI and measured 5.1 × 5.1 μm. Type I meronts with eight short merozoites and a large homogeneous residuum first appeared 72 h PI and measured 5.2 × 5.1 μm. Microgamonts (4.0 × 4.0 μm) produced 16 micro-gametes that penetrated into macrogametes (4.7 × 4.7 μm). Macrogametes gave rise to two types of oocysts that sporulated within the host cells. Most were thick-walled oocysts (6.3 × 5.2 μm), the resistant forms that passed unaltered in the feces. Some were thin-walled oocysts whose wall (membrane) readily ruptured upon release from the host cell. Sporozoites from thin-walled oocysts were observed penetrating enterocytes in mucosal smears. The presence of thin-walled, autoinfective oocysts and the recycling of Type I meronts may explain why chickens develop heavy intestinal infections lasting up to 21 days. Oocysts of C. baileyi were inoculated orally into several animals to determine its host specificity. Cryptosporidium baileyi did not produce infections in suckling mice and goats or in two-dayold or two-week-old quail. One of six 10-day-old turkeys had small numbers of asexual stages only in the BF. Four of six one-day-old turkeys developed mild infections only in the BF, and sexual stages of the parasite were observed in only one of the four. All seven one-day-old ducks and seven two-day-old geese developed heavy infections only in the BF with all known developmental stages present.     

True Intermediate Hosts for Eimeria funduli (Apicomplexa) from Estuarine Fishes1

Grass shrimp (Palaemonetes pugio) fed liver containing sporulated oocysts of Eimeria funduli permitted development of sporozoites that became infective to a variety of killifishes. The shrimp's gastric mill mechanically ruptured the oocysts. Sporozoites then excysted through an opening in the sporocyst, and by 12 and 13 h postinfection (p.i.) numerous empty sporocysts and free sporozoites occurred extracellularly in the intestine of the grass shrimp. Even at 5, 7, 8, 11, 46, 79, and 83 days p.i., and presumably for many months, numerous sporozoites still occurred free in the alimentary tract or between intestinal cells. The coccidium did not infect killifish at either 2 or 4 days p.i., but did at 5 days; after release from the sporocyst, it became more elongate with a distinct nucleus and two relatively large refractile bodies. Infections of E. funduli resulted in about one half of the fish that were fed either entire hepatopancreas or tips of hepatopancreas from experimentally infected shrimp. Feeding either the entire alimentary tract proximal to the first abdominal segment or any portion of that section from experimentally infected shrimp produced infections in nearly all tested fish. Feeding portions of the cephalothorax without any attached hepatopancreas or alimentary tract failed to produce an infection. Feeding killifish with wild grass shrimp from an enzootic area produced infections in only a fourth of the fish sample; however, feeding experimentally infected wild, laboratory-reared, and juvenile grass shrimp produced infections in nearly all fish. Palaemonid shrimps other than P. pugio also can serve as intermediate hosts for E. funduli, and these shrimps include Palaemonetes vulgaris, P. paludosus, P. kadiakensis, and Macrobrachium ohione. In contrast, a penaeid shrimp, mysidacean, amphipod, and crab fed liver with sporulated oocysts did not produce infections when fed to killifish.     

Ovine coccidiosis: pathology of Eimeria ovinoidalis infection

Doses of sporulated oocysts of Eimeria ovinoidalis ranging from 10² to 5 × 10⁶ were given to 25 housed lambs aged between 5 and 13 weeks, most of which had been reared coccidia-free. Some had received an “immunizing” dose 3–4 weeks earlier. Lambs were killed between 8 and 21 days after inoculation (DAI) and the tissues were examined histologically. Doses higher than 10⁶ caused extensive loss of epithelial cells in the lower jejunum both from the surface and from the crypts at 10 DAI when first-generation meronts were mature. Doses of 10³ oocysts or more caused diarrhoea from about 13 DAI in both first and second infections; this was associated with massive invasion of the caecal epithelium by second-generation meronts and gamonts. Destruction of crypt stem cells by these stages led to denudation of the caecal mucosa, resulting in haemorrhagic enteritis, dehydration and delayed healing or death.     

The Results of Parenteral Injections of Sporulated or Unsporulated Oocysts of Eimeria bovis in Calves

SYNOPSIS. Five experiments using newborn Holstein-Friesian and weaner Hereford calves were conducted to observe the effects caused by parenteral injections of oocysts of Eimeria bovis . Sporulated oocysts were given intraperitoneally (IP), subcutaneously (SC), intramuscularly (IM) and intravenously (IV). Unsporulated oocysts or merozoites were given IP or IM.
Coccidiosis developed in calves in three experiments after they were inoculated IP with sporulated oocysts. Immunity to reinfection resulted from these infections. No infections occurred at any time after SC, IM or IV inoculation with sporulated oocysts or after IP or IM inoculation with unsporulated oocysts or merozoites.
Coccidiosis failed to occur in two experiments when special precautions were used to prevent puncture of the intestines during IP inoculations. There was no detectable immunological response to any of the inoculations unless intestinal infections occurred.
In one experiment sporulated oocysts were exposed to 60,000 r irradiation by x-ray in an attempt to attenuate the oocysts. Calves became infected when given orally administered oocysts irradiated at this level.     

Infection of llamas with stored Eimeria macusaniensis oocysts obtained from guanaco and alpaca feces

Oocysts obtained from a guanaco and an alpaca with natural infections were identified as Eimeria macusaniensis and evaluated for host specificity and infectivity over time. In 3 separate trials conducted over 4 yr, 4 adult llamas were fed 500-5,000 sporulated oocysts obtained from guanaco feces stored under laboratory conditions for 41-84 mo. Infections with prepatent periods of 36-41 days and patent periods of 38-55 days developed in 4/4 llamas. In a fourth trial, 3 adult llamas and 1 alpaca were each fed 1,000 sporulated E. macusaniensis oocysts obtained from alpaca feces stored in the laboratory for 3 mo. Infections with prepatent periods of 33-34 days and patent periods of 14-20 days developed in 3/3 llamas. Infection in the alpaca had a prepatent period of 58 days and a patent period of 1 day. Clinical signs associated with infection, if any, were minimal and included increased fecal mucus and occasional soft feces. These results provide evidence that E. macusaniensis is a single species transmissible amongst alpacas, llamas, and guanacos and that oocysts of this species can remain infective for many years.     

Extraintestinal Development of Caryospora simplex (Apicomplexa: Eimeriidae) in Experimentally Infected Mice,Mus musculus1

Developmental stages of Caryospora simplex were found in connective tissue of the cheek, tongue, and nose of Swiss-Webster and C57 BL/6 mice (Mus musculus) from 8 through 70 days after oral inoculation with 50,000 or 250,000 oocysts, or 60,000 free sporocysts of the same species obtained from an Ottoman viper, Vipera xanthina xanthina. The earliest developmental stages were seen on day 8 post-inoculation (PI) and consisted of two types of meronts and gamonts (undifferentiated sexual stages). Gamonts, microgametocytes, macrogametes, and unsporulated oocysts were found on days 10 and 12 PI. Fully sporulated, thin-walled oocysts containing eight sporozoites surrounded by a thin sporocyst membrane were first seen 12 days PI. Monozoic cysts (caryocysts) were first seen 12 days PI and appeared fully viable throughout the duration of the study, 70 days PI. Four mice injected intra-peritoneally with 150,000 free sporozoites and killed 12 days PI contained unsporulated and sporulated oocysts in connective tissues of the cheek, tongue, and nose, suggesting that sporozoites may be carried to the site of infection via the lymphatic/circulatory system. Four cotton rats, Sigmodon hispidus, inoculated orally with 250,000 oocysts all had unsporulated and sporulated oocysts of C. simplex in connective tissue of the cheek, tongue, and nose when killed on day 12 PI, indicating extraintestinal development in the secondary host is not species specific. This is the first report of a heteroxenous coccidium with both asexual and sexual development in the primary (predator) and secondary (prey) hosts.     

Life Cycle of Eimeria christenseni Levine,Ivens & Fritz, 1962 from the Domestic Goat,Capra hircus L.1

The endogenous development of Eimeria christenseni was studied in 10 two- to four-week-old kids inoculated with 10⁶-10⁷ sporulated oocysts. They were killed at intervals from two to 26 days after inoculation, and their tissues were examined for endogenous stages of the coccidian by light microscopy. Such stages were found in the small intestine and mesenteric lymph nodes. In the sexual cycle, two generations of meronts were found. The first generation developed in endothelial cells of lacteals in the jejunun and ileum and mesenteric lymph nodes, and mature meronts were first seen 14 days after inoculation. The second generation developed in epithelial cells of the glands of Lieberkuehn in the jejunum and ileum and in mesenteric lymph nodes, and its mature meronts were first seen by 16 days. Sexual stages were present mostly in epithelial cells of the tips and sides of the villi and less frequently in crypt cells of the jejunum and ileum. Mature macrogametes and microgamonts and oocysts were also first seen by 16 days. The prepatent period was 17 (14-23) days; the patent ranged from 8 to more than 30 days. Sporulation time was 3-4 days at 30°C. E. christenseni was found to be pathogenic, kids inoculated with 1-5 × 10⁵ sporulated oocysts exhibited the following signs: severe diarrhea, anorexia, polydipsia, poor hair coat, and extreme weakness. They recovered about a month later, but their growth rates appeared to be lower than those of uninoculated animals kept under the same conditions. One kid died 20 days after inoculation with 10⁷ oocysts.     

Host and Parasite Interactions During Single and Concurrent Infections with Eimeria nieschulzi and E. separata in the Rat1

SYNOPSIS. Some effects of 2 species of Eimeria in the rat were studied in single and concurrent infections. Groups included singly infected E. nieschulzi and E. separata controls (15 rats each) and 4 groups of 5 rats each infected with E. separata (shorter life cycle) at different days of an established E. nieschulzi infection. Experiments were conducted using inoculations of approximately 3,000, 5,000, and 7,000 sporulated oocysts of each species. Hosts showed consistently poor weight gain on day 3 postinoculation (PI) in E. separata infections and usually showed weight loss on days 7 and/or 8 PI in E. nieschulzi infections. Spleen weights indicated that the hosts responded immunologically to both parasites. Small intestine weights increased during E. nieschulzi infections as did cecum-colon weights during E. separata infections. In severe infections both species seemed to cause pathologic change in tissues at a distance from the site of endogenous development. Fecal collections were made at 24-hr intervals from the time of 1st inoculation till the end of patency. Patency usually began on day 7 PI for E. nieschulzi and on day 4 PI for E. separata with oocyst discharge peaking on days 8 and 5, respectively. In 2 instances, a biphasic pattern of oocyst discharge was found for E. separata during concurrent infections. The occurrence of interspecific interactions was indicated by an increased discharge of oocysts of E. separata, including those with the ability to sporulate, in doubly-infected animals as compared with those in singly-infected controls. It was suggested that the increased oocyst discharges may have resulted from additional production of merozoites during schizogony. Concurrent infections weakened the host more than single infections and this seemingly allowed more multiplication of the parasites.     

Development of Eimeria meleagrimitis Tyzzer from Sporozoites and Merozoites in Turkey Kidney Cell Cultures*

SYNOPSIS. Sporozoites and 1st-, 2nd-, and 3rd-generation merozoites of Eimeria meleagrimitis were inoculated into primary cultures of turkey kidney cells. In vitro-excysted sporozoites developed into mature macrogamonts in 8 days; in vivo-excysted sporozoites developed into 2nd- or 3rd-generation schizonts within 5 to 7 days. First-generation merozoites obtained from infected turkeys produced mature 2nd-generation schizonts within 24 h. Second-generation merozoites from turkeys produced mature macrogamonts and oocysts within 72 h, whereas 3rd-generation merozoites produced these stages within 48 h. The oocysts that developed from 3rd-generation merozoites sporulated at 25 C and were infective for turkeys. The timing of the early stages and the intervals between schizogonic generations in cultures were comparable with those in turkeys. Morphologic parameters, however, indicated that some differences existed between in vitro and in vivo development. Second- and 3rd-generation schizonts and gamonts that developed after inoculation of cultures with merozoites were similar to stages in turkeys. Oocysts, however, were significantly smaller (P < 0.05) in cultures. All stages that developed after inoculation of cultures with sporozoites were smaller (P < 0.05) than their in vivo counter parts.     

The life cycle of Cryptosporidium baileyi n. sp. (Apicomplexa, Cryptosporidiidae) infecting chickens

The life cycle and morphology of a previously undescribed species of Cryptosporidium isolated from commercial broiler chickens is described. The prepatent period for Cryptosporidium baileyi n. sp. was three days post oral inoculation (PI) of oocysts, and the patent period was days 4-24 PI for chickens inoculated at two days of age and days 4-14 for chickens inoculated at one and six months of age. During the first three days PI, most developmental stages of C. baileyi were found in the microvillous region of enterocytes of the ileum and large intestine. By day 4 PI, most parasites occurred in enterocytes of the cloaca and bursa of Fabricius (BF). Mature Type I meronts with eight merozoites first appeared 12 h PI and measured 5.0 x 4.9 micrometers. Mature Type II meronts with four merozoites and a large granular residuum first appeared 48 h PI and measured 5.1 x 5.1 micrometers. Type III meronts with eight short merozoites and a large homogeneous residuum first appeared 72 h PI and measured 5.2 x 5.1 micrometers. Microgamonts (4.0 x 4.0 micrometers) produced approximately 16 microgametes that penetrated into macrogametes (4.7 x 4.7 micrometers). Macrogametes gave rise to two types of oocysts that sporulated within the host cells. Most were thick-walled oocysts (6.3 x 5.2 micrometers), the resistant forms that passed unaltered in the feces. Some were thin-walled oocysts whose wall (membrane) readily ruptured upon release from the host cell. Sporozoites from thin-walled oocysts were observed penetrating enterocytes in mucosal smears. The presence of thin-walled, autoinfective oocysts and the recycling of Type I meronts may explain why chickens develop heavy intestinal infections lasting up to 21 days. Oocysts of C. baileyi were inoculated orally into several animals to determine its host specificity. Cryptosporidium baileyi did not produce infections in suckling mice and goats or in two-day-old or two-week-old quail. One of six 10-day-old turkeys had small numbers of asexual stages only in the BF. Four of six one-day-old turkeys developed mild infections only in the BF, and sexual stages of the parasite were observed in only one of the four. All seven one-day-old ducks and seven two-day-old geese developed heavy infections only in the BF with all known developmental stages present.     

Effects of Carbon Dioxide on Coccidian Oocysts from 6 Host Species*

SYNOPSIS Activation of sporozoites in oocysts of Eimeria acervulina (chicken), E. intricata (sheep), and E. scabra (swine) occurred after pretreatment in aqueous 0.02 M cysteine hydrochloride under an atmosphere of CO₂, followed by incubation in a trypsin-bile mixture. Sporozoites of E. stiedae (rabbit), E. bilamellata (squirrel), and Isospora canis (dog) became activated when incubated in trypsin and bile with or without prior CO₂-pretreatment of oocysts; however, when CO₂-pretreatment was used, activation of these species in trypsin and bile was greatly enhanced. For E. acervulina, 12% of the oocysts were activated after 4 hr CO₂-pretreatment and 10 hr incubation in trypsin and bile at 43 C; higher temperatures or longer pretreatment times did not cause greater activation. Eimeria intricata oocysts became activated after 1 hr pretreatment and 10 hr incubation in trypsin and bile at 37, 39 or 41 C, respectively. The highest activation (31%) occurred after 20 hr pretreatment and 10 hr incubation in trypsin and bile at 41 C. Ninety percent of E. scabra oocysts contained active sporozoites after 1 hr CO₂-pretreatment and 10 hr incubation in trypsin and bile at 37 C. At 39 or 41 C, 100% activation occurred with this species after similar pretreatment and treatment periods. With E. bilamellata, 64% activation occurred in nonpretreated oocysts incubated 10 hr in trypsin and bile at 41 C, whereas 100% activation occurred if oocysts were pretreated with CO₂ for 1 hr before treatment with trypsin and bile. Thirty-one, 35, and 36% of CO₂-pretreated E. stiedae oocysts were activated after 1 hr incubation in trypsin and bile at 37, 39 or 41 C, respectively, whereas 1, 2, and 20% activation occurred in nonpretreated oocysts incubated at the same temperatures. Sporozoites in 99-100% of I. canis oocysts were activated after 10 hr treatment in trypsin and bile with or without 1 hr CO₂-pretreatment at 23, 37, 39 or 41 C.     

The Oocysts of Eimeria vermiformis sp. n. and E. papillata sp. n. (Protozoa: Eimeriidae) from the Mouse Mus musclus

SYNOPSIS. Eimeria vermiformis sp. n. and E. papillata sp. n. are described from the mouse Mus musculus. The sporulated oocysts of E. vermiformis are 18–26 by 15–21 μ (mean 23.1 by 18.4 μ); its sporocysts are 11–14 by 6–10 μ (mean 12.8 by 7.9 p). The sporulated oocysts of E. papillata are 18–26 by 16–24 μ (mean 22.4 by 19.2 μ); its sporocysts are 10–13 by 6–9 μ (mean 11.2 by 8.0 μ). A substiedal body is present in E. papillata sporocysts. Patent infections were produced in white laboratory mice with both species. Fourteen species of Eimeria have now been described from the genus Mus.     

Complete Development of Caryospora bigenetica (Apicomplexa: Eimeriidae) In Vitro1

The development of Caryospora bigenetica in vitro is described by light microscopy. Sporozoites from snake-derived oocysts were purified and inoculated onto cultures of primary testicle cells of the cotton rat, cotton rat kidney cells, and human fetal lung cells. Intracellular sporozoites were observed one and two days postinoculation (DPI). Motile, extracellular first-generation merozoites were present 3 DPI, and second-generation merozoites were present 5 DPI. Mature gamonts were observed 9 DPI and developed into unsporulated oocysts by 10 DPI. Oocysts sporulated in vitro, and excystation was observed. Cells that were penetrated by in vitro-produced sporozoites formed caryocysts by 16 DPI. To test infectivity of in vitro-derived stages, merozoites were removed from cultured cells 5 DPI and inoculated intraperitoneally into a mouse; infection resulted. Sporulated oocysts removed from cell cultures 12 DPI produced facial swelling in an orally inoculated cotton rat.     

Coccidian Parasites (Apicomplexa: Eimeriidae) from Insectivores. IV. Four New Species in Talpa europaea from England1

ABSTRACT. Moles from England were examined for coccidian oocysts and all 64 Talpa europaea were infected; of 64 infected hosts, 56 (88%) had multiple infections representing two to six coccidian species when examined. Oocysts in 31 of the 64 samples remained unsporulated. Three eimerians and one isosporan were studied from the 33 fecal samples that had sporulated oocysts and these are described as new species; Cyclospora talpae Pellérdy & Tanyi, 1968, and Isospora sofiae (Golemansky, 1978) Levine & Ivens, 1979, are redescribed; and Cyclospora sp., similar to C. talpae, is discussed. Sporulated oocysts of C. talpae are ellipsoidal, 14.3 × 9.6 (12–19 × 6–13) μm with sporocysts ovoid, 9.4 × 5.7 (6–13 × 4–8) μm; it was found in 21 of the 33 (63.6%) sporulated samples. Sporulated oocysts of Cyclospora sp. are subspheroidal to ellipsoidal, 12.5 × 8.9 (10–14 × 6–12) μm with sporocysts ovoid, 8.6 × 5.3 (6–10 × 4–6) μm; it was found in 21 of the 33 (63.6%) sporulated samples. Sporulated oocysts of Eimeria avonensis n. sp. are elongate-ellipsoidal, 15.0 × 9.6 (13–20 × 7–12) μm with sporocysts ovoid, 6.6 × 3.6 (5–9 × 3–7) μm; it was found in 15 of the 33 (45.5%) sporulated samples. Sporulated oocysts of Eimeria berea n. sp. are subspheroidal, 12.1 × 10.5 (10–15 × 8–14) μm with sporocysts ovoid, 6.3 × 3.9 (5–10 × 2–5) μm; it was found in 8 of the 33 (24.2%) sporulated samples. Sporulated oocysts of Eimeria globula n. sp. are spheroidal, 20.9 × 19.9 (19–24 × 17–21) μm with sporocysts elongate-ovoid, 11.5 × 6.9 (9–16 × 6–9) μm; it was found in 3 of the 33 (9.1%) sporulated samples. Sporulated oocysts of Isospora sporopointaea n. sp. are subellipsoidal to ellipsoidal, 17.1 × 11.4 (13–21 × 8–14) μm with sporocysts ellipsoidal with both ends pointed, 11.9 × 5.9 (9–16 × 4–8) μm; it was found in 27 of the 33 (81.8%) sporulated samples. Sporulated oocysts of I. sofiae are spheroidal to subspheroidal, 12.2 × 11.0 (9–16 × 8–15) μm with sporocysts ovoid, 9.1 × 5.2 (6–13 × 3–8) μm; it was found in 25 of the 33 (75.8%) sporulated samples. To date, the coccidian parasites of talpids include two cyclosporans, 12 eimerians, and six isosporans, exclusive of the four new species described here.     

Development and application of different methods for the detection of Toxoplasma gondii in water

Two methods, centrifugation and flocculation, were evaluated to determine their efficiencies of recovery of Toxoplasma gondii oocysts from contaminated water samples. Demineralized and tap water replicates were inoculated with high numbers of sporulated or unsporulated T. gondii oocysts (1 x 10(5) and 1 x 10(4) oocysts). The strain, age, and concentration of the seeded oocysts were recorded. Oocysts were recovered either by centrifugation of the contaminated samples at various g values or by flocculation with two coagulants, Fe(2)(SO(4))(3) and Al(2)(SO(4))(3). The recovery rates were determined with the final pellets by phase-contrast microscopy. Sporulated oocysts were recovered more effectively by flocculation with Al(2)(SO(4))(3) (96.5% +/- 21.7%) than by flocculation with Fe(2)(SO(4))(3) (93.1% +/- 8.1%) or by centrifugation at 2,073 x g (82.5% +/- 6.8%). For the unsporulated oocysts, flocculation with Fe(2)(SO(4))(3) was more successful (100.3% +/- 26.9%) than flocculation with Al(2)(SO(4))(3) (90.4% +/- 19.1%) or centrifugation at 2,565 x g (97.2% +/- 12.5%). The infectivity of the sporulated oocysts recovered by centrifugation was confirmed by seroconversion of all inoculated mice 77 days postinfection. These data suggest that sporulated Toxoplasma oocysts purified by methods commonly used for waterborne pathogens retain their infectivity after mechanical treatment and are able to induce infections in mammals. This is the first step in developing a systematic approach for the detection of Toxoplasma oocysts in water.     

Enzyme variation of Eimeria arizonensis from Peromyscus truei and P. boylii

Cricetid rodents, Peromyscus truei and P. boylii, were inoculated with sporulated oocysts of Eimeria arizonensis collected from wild P. truei maintained in the lab. In P. truei the prepatent period was 4-5 days, the patent period was 9-11 days, and sporulated oocysts were 21.5 x 25.0 (20-23 x 24-26) microns with sporocysts 7.7 x 12.0 (6-8 x 10-13) microns. In P. boylii the prepatent period was 6-7 days, the patent period was 8-9 days, and sporulated oocysts were 20.1 x 23.2 (18-22 x 21-24) microns with sporocysts 6.8 x 10.0 (5-8 x 9-12) microns. Sporulated oocysts from both host species were used in direct side-by-side comparison of isozyme banding patterns using protein electrophoresis. The parasite has polytypic loci for leucine aminopeptidase (LAP), lactate dehydrogenase (LDH), and 6-phosphogluconate dehydrogenase (6-PGD). In oocysts from P. truei, LAP showed one band with fast migration and LDH and 6-PGD each showed two bands, one with fast and one with slow migration. In oocysts from P. boylii, LAP and LDH each had one band with slow migration and 6-PGD had one band with moderate migration. Oocysts of E. arizonensis collected from P. boylii were used to inoculate P. truei. The prepatent and patent periods, structural measurements, and isozyme banding patterns of the resultant oocysts were the same as those from P. truei when inoculated with oocysts from P. truei.     

Development and Application of Different Methods for the Detection of Toxoplasma gondii in Water

Two methods, centrifugation and flocculation, were evaluated to determine their efficiencies of recovery of Toxoplasma gondii oocysts from contaminated water samples. Demineralized and tap water replicates were inoculated with high numbers of sporulated or unsporulated T. gondii oocysts (1 × 10⁵ and 1 × 10⁴ oocysts). The strain, age, and concentration of the seeded oocysts were recorded. Oocysts were recovered either by centrifugation of the contaminated samples at various g values or by flocculation with two coagulants, Fe₂(SO₄)₃ and Al₂(SO₄)₃. The recovery rates were determined with the final pellets by phase-contrast microscopy. Sporulated oocysts were recovered more effectively by flocculation with Al₂(SO₄)₃ (96.5% ± 21.7%) than by flocculation with Fe₂(SO₄)₃ (93.1% ± 8.1%) or by centrifugation at 2,073 × g (82.5% ± 6.8%). For the unsporulated oocysts, flocculation with Fe₂(SO₄)₃ was more successful (100.3% ± 26.9%) than flocculation with Al₂(SO₄)₃ (90.4% ± 19.1%) or centrifugation at 2,565 × g (97.2% ± 12.5%). The infectivity of the sporulated oocysts recovered by centrifugation was confirmed by seroconversion of all inoculated mice 77 days postinfection. These data suggest that sporulated Toxoplasma oocysts purified by methods commonly used for waterborne pathogens retain their infectivity after mechanical treatment and are able to induce infections in mammals. This is the first step in developing a systematic approach for the detection of Toxoplasma oocysts in water.     

Effect of gamma-irradiation on oocysts of Eimeria necatrix.

Effect of gamma radiation on oocysts of Eimeria necatrix was investigated. It was observed that oocysts exposed to 200 kR or above did not sporulate. Irratiation at 10-150 kR caused a progressive decrease in sporulation. Irradiation affected normal development of unsporulated oocysts as the zygote protoplasm divided into unequal masses or was shattered into granules. Increase in the intensity of irradiation of sporulated oocysts resulted in the progressive decrease in severity of the resultant infections in chicks and their effects - mortality, type of lesions developed, total oocyst production and immunity produced - were comparable with infections induced by decreasing the number of unirradiated oocysts. Infection produced by 1000 unirradiated oocysts was comparable with that resulting from 50 000 oocysts irradiated at 25 kR. Infection obtained with 20 000 unexposed oocysts approximated to that produced by 50 000 oocysts irradiated at 2-5 kR. It was concluded that irradiation abolished infectivity of the oocysts/sporozoites rather than bringing about attenuation of the parasite.     

Experimental cryptosporidiosis in fetal lambs

Fetal lambs were infected in utero with purified sporulated oocysts of Cryptosporidium parvum in order to study pathogenesis and host cellular response to the enteropathogen. Ileal loops (IL) of fetuses, 124-130 days of gestation, were inoculated with 1-4 x 10(6) oocysts usually via cannulae in the abdominal wall of the ewe. Oocysts, both free and phagocytosed, were observed in the IL content as early as day 1 post-inoculation (PI). The percentage of oocysts phagocytosed by the host's polymorphonuclear neutrophils (PMN's) and mononuclear cells remained high up to day 13, the last day of examination. Numerous parasites were observed at days 6, 7, and 12 PI in the microvilli of the ileum with hypercellularity of the lamina propria, which consisted of a mixed infiltration of PMN's, mononuclear cells, including lymphoid cells, and a few eosinophils. Cytolysis and extrusion of epithelial cells, often heavily parasitized by various stages of the parasite, as well as inflammatory cells, were prominent in luminal contents. Germinal centers were prominent in mesenteric lymph nodes draining the infected loops by day 12 PI. Depletion of lymphoid cells was already present in Peyer's patches by day 4 PI.     

Life Cycles of Leucocytozoon dubreuili Mathis and Leger, 1911 and L. fringillinarum Woodcock, 1910 (Haemosporidia: Leucocytozoidae)*

SYNOPSIS The development of Leucocytozoon dubreuili and L. fringillinarum was studied on successive days in simuliid and avian hosts. Sporogony of both parasites is completed in at least 5 species of sylvatic Simuliidae in a minimum of 4-5 days at 21 C. The pattern of development of the 2 species is similar but the size of the oocysts and the number of sporozoites differ. Sporozoites of L. dubreuili and L. fringillinarum were injected into uninfected robins (Turdus m. migratorius) and grackles (Quiscalus quiscula versicolor), respectively. Hepatic biopsies were performed on some of the injected birds. These and others were killed at intervals following inoculation and their tissues examined to detect stages of schizogony. Blood and macerated tissues from birds injected with sporozoites were transferred to uninfected birds to determine whether asexual stages would develop in the latter as a result of the inoculations. The 1st asexual cycle of L. dubreuili is completed in hepatic parenchymal cells in a minimum of 84 hr. Merozoites produced by the hepatic schizonts apparently follow one of 3 courses: invade hepatic parenchymal cells to initiate another cycle; penetrate blood cells and become gametocytes; penetrate tubular cells of the kidneys and grow into renal schizonts. The minimum prepatent period in infections with L. fringillinarum is 76 hr. The 1st asexual cycle occurs in hepatic parenchymal cells and in tubular cells of the kidney. A schizogonic cycle is completed in a minimum of 72 hr in the former and 96 hr in the kidney. Merozoites from the primary hepatic schizonts apparently give rise to (a) gametocytes; (b) secondary hepatic schizonts; (c) renal schizonts. Thus the schizogonic cycles of L. dubreuili and L. fringillinarum differ from each other and from those of L. simondi in ducks.