In vitro cultivation of the vascular phase of Sarcocystis capracanis and Sarcocystis tenella

Sporozoites of Sarcocystis capracanis and S. tenella (Apicomplexa) penetrated all four cell types tested (bovine monocytes, BM; bovine pulmonary artery endothelial cells, CPA; Madin-Darby bovine kidney; and ovine monocytes). Sporozoites of S. tenella developed to meronts in BM and CPA; those of S. capracanis developed to meronts in BM only. Both species of Sarcocystis developed to large first-generation meronts followed by small meronts. At 40 to 50 days after inoculation (DAI) of sporozoites, considerably more merozoites of S. tenella were harvested from CPA (24.9 X 10(6) merozoites/75-cm2 flask; n = 4) than from BM (1.9 X 10(6) merozoites/75-cm2 flask; n = 4). Merozoites of S. capracanis were most numerous in BM at 88 to 100 DAI during which time 2.1 X 10(6) merozoites/75-cm2 flask (n = 4) were harvested.     

In Vitro Cultivation of the Vascular Phase of Sarcocystis capracanis and Sarcocystis tenella1

ABSTRACT. Sporozoites of Sarcocystis capracanis and S. tenella (Apicomplexa) penetrated all four cell types tested (bovine monocytes, BM; bovine pulmonary artery endothelial cells, CPA; Madin-Darby bovine kidney; and ovine monocytes). Sporozoites of S. tenella developed to meronts in BM and CPA; those of S. capracanis developed to meronts in BM only. Both species of Sarcocystis developed to large first-generation meronts followed by small meronts. At 40 to 50 days after inoculation (DAI) of sporozoites, considerably more merozoites of S. tenella were harvested from CPA (24.9 × 10⁶ merozoites/75-cm² flask; n = 4) than from BM (1.9 × 10⁶ merozoites/75-cm² flask; n = 4). Merozoites of S. capracanis were most numerous in BM at 88 to 100 DAI during which time 2.1 × 10⁶ merozoites/75-cm² flask (n = 4) were harvested.     

Development of Hammondia heydorni in cultured bovine and ovine cells

Sporozoites were excysted from oocysts of Hammondia heydorni obtained from a naturally-infected dog and inoculated into monolayer cultures of bovine pulmonary artery endothelial cells (CPA), Madin-Darby bovine kidney (MDBK) cells, bovine monocytes (M617), or ovine monocytes (WOMO). Sporozoites penetrated all four cell lines and underwent asexual reproduction by endodyogeny (as determined by electron microscopy) to form cyst-like structures at four to nine days after sporozoite inoculation (DAI). At 4-10 DAI, considerably more zoites were harvested from M617 cultures (80.1 x 10(6) zoites) than from CPA (17.4 x 10(6], MDBK (47.3 x 10(6], and WOMO (53.5 x 10(6]. Little or no parasite multiplication occurred at 10-16 DAI. Zoites harvested at 7 DAI and transferred to freshly prepared cultures did not penetrate cells nor develop further.     

Development of the swine coccidium Eimeria debliecki Douwes, 1921 in mammalian cell cultures

Sporozoites of Eimeria debliecki entered human fetal lung and porcine kidney cells grown in cultures and underwent one merogenous cycle, terminating in the production of second-generation trophozoites. Sporozoites were intracellular 1 h post-inoculation (PI) and developed into sporozoite-shaped meronts at 40 h PI. These meronts, one of which was motile, had from two to ten nuclei. Sporozoite-shaped meronts then developed into elongate or spheroidal meronts with 10 to 24 nuclei by two days PI. Ten to 26 first-generation merozoites were formed by budding from the meront surface. Mature first-generation merozoites were most numerous three days PI. Most meronts had ruptured and released nonmotile merozoites into the culture medium by four days PI. Merozoites that were not released became rounded and developed into second-generation trophozoites. Refractile bodies were present in all developmental stages. No further development was observed five through eight days PI.     

Development of the Swine Coccidium Eimeria debliecki Douwes, 1921 in Mammalian Cell Cultures1

Sporozoites of Eimeria debliecki entered human fetal lung and porcine kidney cells grown in cultures and underwent one merogenous cycle, terminating in the production of second-generation trophozoites. Sporozoites were intracellular 1 h post-inoculation (PI) and developed into sporozoite-shaped meronts at 40 h PI. These meronts, one of which was motile, had from two to ten nuclei. Sporozoite-shaped meronts then developed into elongate or spheroidal meronts with 10 to 24 nuclei by two days PI. Ten to 26 first-generation merozoites were formed by budding from the meront surface. Mature first-generation merozoites were most numerous three days PI. Most meronts had ruptured and released nonmotile merozoites into the culture medium by four days PI. Merozoites that were not released became rounded and developed into second-generation trophozoites. Refractile bodies were present in all developmental stages. No further development was observed five through eight days PI.     

Continuous in vitro cultivation of Sarcocystis cruzi

Sporozoites of Sarcocystis cruzi were inoculated onto monolayer cultures of bovine pulmonary artery endothelial (CPA) cells. Sporozoites entered the cells, formed large and small multinucleate schizonts, and produced large numbers of merozoites. Continuous cultivation from the original sporozoite inoculum has been maintained for more than 1,320 days by subinoculating merozoites onto new cultures of CPA cells. During this time, the capacity to produce both types of schizonts was preserved, and schizogony was the only form of reproduction that was observed.     

Endogenous development of Eimeria minasensis in experimentally infected goats

The endogenous development of Eimeria minasensis was studied in 9 coccidia-free goat kids inoculated with 10(5) sporulated oocysts/kg body weight. Kids were killed 4, 7 (2 animals), 10, 13, 16, 18, 19, and 22 days after inoculation (DAI). In tissue sections of the intestines stained with hematoxylin and eosin and examined by light microscopy, 2 generations of meronts, gamonts, gametes, and oocysts were found. The first generation of meronts developed in cells deep in the lamina propria of the jejunum and ileum. Mature giant meronts (299.4x243.8 microm) found 16 DAI were visible to the naked eye and contained a large number of crescent-shaped merozoites. The second generation of meronts developed in the epithelial cells of crypts of the ileum and above the host cell nuclei. Mature meronts (11.5x10.1 microm) with 18-28 comma-shaped merozoites were first seen 16 DAI. Gametogenesis took place in epithelial cells of the crypts and villi of the terminal part of the ileum, cecum, and colon. Macrogametes (27.8x17.6 microm), mature microgamonts (21.3x17.0 microm), microgametes, and oocysts (30.5x19.4 microm) were found 19 DAI. Sexual stages were below the host cell nucleus.     

Observations on the endogenous stages of Eimeria crandallis in domestic lambs (Ovis aries)

Lambs reared coccidia-free were inoculated orally with various numbers of sporulated oocysts of E. crandallis and were killed between 1 and 22 days after inoculation; tissues were examined histologically. Sporozoites were seen 1, 2 and 3 days after inoculation (DAI) in crypt epithelial cells in the mid-jejunum. Infected cells migrated into the lamina propria where the parasite within them developed into a firstgeneration meront containing about 250,000 merozoites at 10 DAI. A second generation of meronts was seen at 10–12 DAI, each containing up to about 10 merozoites, situated mainly at the bases of crypts in the jejunum and ileum but also in the caecum. From 11 DAI pro-gamonts were seen which were enveloped by the host cell nucleus and which divided in synchrony with the host cell for an undetermined number of generations. Mature gamonts began to develop from them by 16 DAI. Oocyst output began at 16 DAI and rose to a peak at about 22 DAI. Up to 10⁸ oocysts were produced per oocyst inoculated. They showed wide variation in size and colour.     

Observations on the endogenous stages of Eimeria crandallis in domestic lambs (Ovis aries)

Lambs reared coccidia-free were inoculated orally with various numbers of sporulated oocysts of E. crandallis and were killed between 1 and 22 days after inoculation; tissues were examined histologically. Sporozoites were seen 1, 2 and 3 days after inoculation (DAI) in crypt epithelial cells in the mid-jejunum. Infected cells migrated into the lamina propria where the parasite within them developed into a firstgeneration meront containing about 250,000 merozoites at 10 DAI. A second generation of meronts was seen at 10–12 DAI, each containing up to about 10 merozoites, situated mainly at the bases of crypts in the jejunum and ileum but also in the caecum. From 11 DAI pro-gamonts were seen which were enveloped by the host cell nucleus and which divided in synchrony with the host cell for an undetermined number of generations. Mature gamonts began to develop from them by 16 DAI. Oocyst output began at 16 DAI and rose to a peak at about 22 DAI. Up to 10⁸ oocysts were produced per oocyst inoculated. They showed wide variation in size and colour.     

Development of Hammondia heydorni in Cultured Bovine and Ovine Cells1

Sporozoites were excysted from oocysts of Hammondia heydorni obtained from a naturally-infected dog and inoculated into monolayer cultures of bovine pulmonary artery endothelial cells (CPA), Madin-Darby bovine kidney (MDBK) cells, bovine monocytes (M617), or ovine monocytes (WOMO). Sporozoites penetrated all four cell lines and underwent asexual reproduction by endodyogeny (as determined by electron microscopy) to form cyst-like structures at four to nine days after sporozoite inoculation (DAI). At 4–10 DAI, considerably more zoites were harvested from M617 cultures (80.1 times 10⁶ zoites) than from CPA (17.4 times 10⁶), MDBK. (47.3 times 10⁶), and WOMO (53.5 times 10⁶). Little or no parasite multiplication occurred at 10–16 DAI. Zoites harvested at 7 DAI and transferred to freshly prepared cultures did not penetrate cells nor develop further.     

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.     

A comparative study of the development of Eimeria nieschulzi in vitro under aerobic and reducing conditions

Sporozoites of the rat coccidian, Eimeria nieschulzi Dieben, 1924 (Apicomplexa: Eimeriidae), were inoculated onto monolayers of normal rat kidney (NRK) fibroblasts and cultured either under aerobic (5% CO2/95% air) or reducing (desiccator jars modified into candle jars) conditions in RPMI-1640 supplemented with 5% fetal bovine serum, sodium bicarbonate, and antibiotics. Under aerobic conditions, first-generation meronts were observed at 2 days postinoculation (DPI) and, except for individual third-generation meronts that were seen at 5 and 6 DPI, no further development was noted. Under reducing conditions, however, first-generation meronts observed at 2-5 DPI underwent additional development to form second-generation meronts (3-5 DPI), third-generation meronts (3-7 DPI), and a small number of fourth-generation meronts (5-8 DPI). Both second- and third-generation meronts were abnormal, exhibiting gigantism although the merozoites produced appeared normal. The gradual degeneration of cell monolayers under reducing conditions prevented further observations beyond 8 DPI. These results suggest that atmospheric conditions play an important role in the development of E. nieschulzi and maintenance of reducing conditions may be one key to achieving enhanced development of some species of coccidia in vitro.     

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.     

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.     

Biology and pathogenicity of Eimeria spinosa Henry, 1931 in experimentally infected pigs.

A single-species isolate of E. spinosa from a diarrheic weaned pig was used to determine the endogenous development and pathogenicity of this swine coccidium. Seven out of 14 inoculated pigs developed endogenous stages or passed oocysts of E. spinosa in their feces. Immunosuppressive treatment with cyclophosphamide had no effect on the susceptibility to infection with E. spinosa in young pigs. The endogenous stages developed within the apical cytoplasm of the enterocytes lining the distal part of the villi in the posterior jejunum. The asexual development comprised three generations of meronts, which were seen at 5, 7 and 9 days post-infection (DPI). Meronts of the first generation measured 6-8 microns and produced 10-14 merozoites 4-6 microns in length. The second generation of meronts measured 6-8 microns and contained 10-20 merozoites 4-6 microns in length. Third generation mature meronts (8-10 microns) on DPI 9 contained 12-20 merozoites measuring 5-7 microns, which were more crescent-shaped and less blunt than the merozoites at 5 and 7 DPI. Merogony continued after formation of the gametes and the first fully developed macrogametes (10-14 microns), microgametes (9-12 microns), and oocysts were also seen at 9 DPI. The prepatent period was 8 or 9 days, but the patent period was not determined. In the present study E. spinosa infection did not produce overt clinical signs. Pathological changes consisted of an inflammatory infiltration in the lamina propria of the posterior jejunum, Peyer's patches activation and sporadic erosions scattered at the villous tips. No villous atrophy in association with a large number of endogenous stages was observed.     

Life cycle of Isospora rivolta (Grassi, 1879) in cats and mice

The endogenous development of Isospora rivolta (Grassi) was studied in cats fed oocysts, and was compared with the endogenous cycle after feeding them mice infected with I. rivolta. For the mouse-induced cycle, 14 newborn cats were killed 12 to 240 h after having been fed mesenteric lymph nodes and spleens ofmice. Asexual and sexual development occurred throughout the small intestine, in epithelial cells of the villi and glands of Lieberkühn. The number of asexual generations was not determined with certainty, but there were at least 3 structurally different meronts. Type I meronts appeared at 12-48 h postinoculation (HPT). They were 8.5(6-13) x 5.1(3-6) micrometer, contained 2-8 merozoites, and divide by binary division or endodyogeny. Type II meronts were multinucleate merozoite-shaped meronts within a single parasitophorous vacuole. They were found at 48-172 HPI and measured 12.6(9-18) x 9.8(9-13) micrometer. Individual multinucleate merozoite-shaped meronts were 7-13 x 3-5 micrometer in sections and contained 2-30 slender (5.5 x 1.0 micrometer) merozoites. Type III meronts occurred at 72-192 HPI and gamonts at 72-96 HPI. Mature microgamonts measured 11.3(9-15) x 8.0(6-9) micrometer in sections and up to 21.5 x 14 micrometer in smears, and contained up to 70 microgametes. Macrogamonts measured 13.3(11-18) x 9.0(5-13) micrometer in sections and 18 x 16 micrometer in smears, and contained up to 70 microgametes. Macrogamonts measured 13.3(11-18) x 9.0(5-13) micrometer. Sporulation was completed within 24 h at 22-26 C. For the study of the oocyst-induced cycle in cats, 18 newborn cats were killed between 6 and 192 HPI. The endogenous development was essentially similar to the mouse-induced cycle, but merogony and gametogony occurred 12-48 h later than in the latter cycle. Isospora rivolta was pathogenic for newborn but not for weaned cats. Newborn cats fed 10(6) sporocysts or infected mice usually developed diarrhea 3-4 days after inoculation. Microscopically, desquamation of the tips of the villi and cryptitis were seen in the ilium and cecum in association with meronts and gamonts. For the study of the development of I. rivolta in mice, mice were killed from day 1 to 23 months after having been fed 10(5)-10(6) sporocysts, and their tissues were examined for the parasites microscopically, and by feeding to cats. The following conclusions were drawn. (A) Isospora rivolta most freqeuntly invaded the mesenteric lymph nodes ofmice and remained there for 23 months at least. Ii also invaded the spleen, liver, and skeletal muscles of mice. This species could not be passed from mouse to mouse. Sporozoites increased in size from approximately 6.8 x 4.9 micrometer on day 1 to approximately 13.4 x 6.9 micrometer on day 31 postinoculation. Division was not seen. Prepatent period was 4-7 days and patent periods ranged from 2 to several weeks.     

A comparison of endogenous development of three isolates of Cryptosporidium in suckling mice

Suckling mice were used as a model host to compare the endogenous development of three different isolates of Cryptosporidium: one from a naturally infected calf, one from an immunocompetent human with a short-term diarrheal illness, and one from a patient with acquired immune deficiency syndrome (AIDS) and persistent, life-threatening, gastrointestinal cryptosporidiosis. After oral inoculation of mice with oocysts, no differences were noted among developmental stages of the three isolates in their sites of infection, times of appearance, and duration, morphology, and fine structure. Sporozoites excysted within the lumen of the duodenum and ileum, penetrated into the microvillous region of villous enterocytes, and developed into type I meronts with six or eight merozoites. Type I merozoites penetrated enterocytes and underwent cyclic development as type I meronts or they became type II meronts with four merozoites. Type II merozoites did not exhibit cyclic development but developed directly into sexual forms. Microgamonts produced approximately 16 small, bullet-shaped microgametes, which were observed attaching to and penetrating macrogametes. Approximately 80% of the oocysts observed in enterocytes had a thick, two-layered wall. After sporulating within the parasitophorous vacuole, these thick-walled oocysts passed through the gut unaltered and were the resistant forms that transmitted the infection to a new host. Approximately 20% of the oocysts in enterocytes consisted of four sporozoites and a residuum surrounded only by a single oocyst membrane that ruptured soon after the parasite was released from the host cell. The presence of thin-walled, autoinfective oocysts and recycling of type I meronts may explain why a small oral inoculum can produce an overwhelming infection in a suitable host and why immune deficient persons can have persistent, life-threatening cryptosporidiosis in the absence of repeated oral exposure to thick-walled oocysts.     

A Comparison of Endogenous Development of Three Isolates of Cryptosporidium in Suckling Mice1

ABSTRACT. Suckling mice were used as a model host to compare the endogenous development of three different isolates of Cryptosporidium: one from a naturally infected calf, one from an immunocompetent human with a short-term diarrheal illness, and one from a patient with acquired immune deficiency syndrome (AIDS) and persistent, life-threatening, gastrointestinal cryptosporidiosis. After oral inoculation of mice with oocysts, no differences were noted among developmental stages of the three isolates in their sites of infection, times of appearance, and duration, morphology, and fine structure. Sporozoites excysted within the lumen of the duodenum and ileum, penetrated into the microvillous region of villous enterocytes, and developed into type I meronts with six or eight merozoites. Type I merozoites penetrated enterocytes and underwent cyclic development as type I meronts or they became type II meronts with four merozoites. Type II merozoites did not exhibit cyclic development but developed directly into sexual forms. Microgamonts produced £16 small, bullet-shaped microgametes, which were observed attaching to and penetrating macrogametes. Approximately 80% of the oocysts observed in enterocytes had a thick, two-layered wall. After sporulating within the parasitophorous vacuole, these thick-walled oocysts passed through the gut unaltered and were the resistant forms that transmitted the infection to a new host. Approximately 20% of the oocysts in enterocytes consisted of four sporozoites and a residuum surrounded only by a single oocyst membrane that ruptured soon after the parasite was released from the host cell. The presence of thin-walled, autoinfective oocysts and recycling of type I meronts may explain why a small oral inoculum can produce an overwhelming infection in a suitable host and why immune deficient persons can have persistent, life-threatening cryptosporidiosis in the absence of repeated oral exposure to thick-walled oocysts.     

Complete development of Cryptosporidium parvum in host cell-free culture

The present study describes the complete in vitro development of Cryptosporidium parvum (cattle genotype) in RPMI-1640 maintenance medium devoid of host cells. This represents the first report in which Cryptosporidium is shown to multiply, develop and complete its life cycle without the need for host cells. Furthermore, cultivation of Cryptosporidium in diphasic medium consisting of a coagulated new born calf serum base overlaid with maintenance medium greatly increased the total number of Cryptosporidium stages. Type I and II meronts were detected giving rise to two morphologically different merozoites. Type I meronts, which appear as grape-like clusters as early as 48 h post culture inoculation, release merozoites, which are actively motile, and circular to oval in shape. Type II meronts group in a rosette-like pattern and could not be detected until day 3 of culturing. Most of the merozoites released from type II meronts are generally spindle-shaped with pointed ends, while others are rounded or pleomorphic. In contrast to type I, merozoites from type II meronts are less active and larger in size. Sexual stages (micro and macrogamonts) were observed within 6-7 days of culturing. Microgamonts were darker than macrogamonts, with developing microgametes, which could be seen accumulating at the periphery. Macrogamonts have a characteristic peripheral nucleus and smooth outer surface. Oocysts at different levels of sporulation were seen 8 days post culture inoculation. Cultures were terminated after 4 months when the C. parvum life cycle was still being perpetuated with the presence of large numbers of excysting and intact oocysts. Culture-derived oocysts obtained after 46 days p.i. were infective to 7- to 8-day-old ARC/Swiss mice. The impact of C. parvum developing in cell-free culture is very significant and will facilitate many aspects of Cryptosporidium research.     

Comparative development and merozoite production of two isolates of Sarcocystis neurona and Sarcocystis falcatula in cultured cells

The development and merozoite production of Sarcocystis falcatula and 2 isolates (SN6 and SN2) of Sarcocystis neurona were studied in various cultured cell lines inoculated with culture-derived merozoites. All 3 parasites underwent multiple cycles of schizogony in VERO cells, bovine monocytes (M617 cells), and bovine pulmonary artery endothelial cells (CPA). Sarcocystis neurona strains SN6 and SN2 formed schizonts in rat myoblasts (L6) but not in quail myoblasts (QM7); S. falcatula formed schizonts in QM7 cells but not in L6 cells. Merozoites did not develop to sarcocysts in the myoblast cells lines. During a 47-day culture period in VERO cells, SN6 produced substantially more merozoites than did SN2 or S. falcatula. M617 cells produced substantially more merozoites of SN6 than did VERO or CPA cells. During a 17-day culture period of SN6, M617 cells produced mean totals of 4.7 x 10(8) merozoites, VERO cells produced 1.9 x 10(8) merozoites, and CPA cells produced 5.9 x 10(7) merozoites. At 4-12 days after inoculation of cultured cells with SN6, M617 cells cultured in the presence of 10% fetal bovine serum (FBS) produced a mean merozoite total of 5.1 x 10(8) compared to 3.6 x 10(8) for culture medium containing 1% FBS.