Localization of protective 143/140 kDa antigens of Plasmodium knowlesi by the use of antibodies and ultracryomicrotomy

Immune sera from mice immunized with the 143/140 kDa protein have been shown to partially block erythrocyte invasion by P. knowlesi merozoites. Therefore, immunoelectron microscopy utilizing ultracryomicrotomy, antibody to 143/140 kDa protein, and protein A gold particles were used to determine the precise localization of this protein in malarial parasites. Gold particles were not seen associated with young trophozoites but appeared in the parasite cytoplasm as the parasites grew to multi-nucleate schizonts. In presegmenter-schizonts, gold particles were associated with the well-developed endoplasmic reticulum, the parasite plasma membrane, and the parasitophorous vacuole membrane. The surface of merozoites was covered with gold particles. Maurer's clefts, which appeared in Plasmodium infected erythrocytes, were also associated with gold particles. These observations suggest that 143/140 kDa protective malarial proteins may be synthesized in the endoplasmic reticulum of P. knowlesi schizonts before being transported to the surface of the schizonts and merozoites. Shedding of the merozoite surface coat may be responsible for the presence of the 143/140 kDa proteins in the parasitophorous vacuole and Maurer's clefts.     

Ca2+‐mediated exocytosis of subtilisin‐like protease 1: a key step in egress of Plasmodium falciparum merozoites

Egress of Plasmodium falciparum merozoites from host erythrocytes is a critical step in multiplication of blood‐stage parasites. A cascade of proteolytic events plays a major role in degradation of membranes leading to egress of merozoites. However, the signals that regulate the temporal activation and/or secretion of proteases upon maturation of merozoites in intra‐erythrocytic schizonts remain unclear. Here, we have tested the role of intracellular Ca²⁺ in regulation of egress of P. falciparum merozoites from schizonts. A sharp rise in intracellular Ca²⁺ just before egress, observed by time‐lapse video microscopy, suggested a role for intracellular Ca²⁺ in this process. Chelation of intracellular Ca²⁺ with chelators such as BAPTA‐AM or inhibition of Ca²⁺ release from intracellular stores with a phospholipase C (PLC) inhibitor blocks merozoite egress. Interestingly, chelation of intracellular Ca²⁺ in schizonts was also found to block the discharge of a key protease PfSUB1 (subtilisin‐like protease 1) from exonemes of P. falciparum merozoites to parasitophorous vacuole (PV). This leads to inhibition of processing of PfSERA5 (serine repeat antigen 5) and a block in parasitophorous vacuolar membrane (PVM) rupture and merozoite egress. A complete understanding of the steps regulating egress of P. falciparum merozoites may provide novel targets for development of drugs that block egress and limit parasite growth.     

Selective inhibition of a two-step egress of malaria parasites from the host erythrocyte

Escape from the host erythrocyte by the invasive stage of the malaria parasite Plasmodium falciparum is a fundamental step in the pathogenesis of malaria of which little is known. Upon merozoite invasion of the host cell, the parasite becomes enclosed within a parasitophorous vacuole, the compartment in which the parasite undergoes growth followed by asexual division to produce 16-32 daughter merozoites. These daughter cells are released upon parasitophorous vacuole and erythrocyte membrane rupture. To examine the process of merozoite release, we used P. falciparum lines expressing green fluorescent protein-chimeric proteins targeted to the compartments from which merozoites must exit: the parasitophorous vacuole and the host erythrocyte cytosol. This allowed visualization of merozoite release in live parasites. Herein we provide the first evidence in live, untreated cells that merozoite release involves a primary rupture of the parasitophorous vacuole membrane followed by a secondary rupture of the erythrocyte plasma membrane. We have confirmed, with the use of immunoelectron microscopy, that parasitophorous vacuole membrane rupture occurs before erythrocyte plasma membrane rupture in untransfected wild-type parasites. We have also demonstrated selective inhibition of each step in this two-step process of exit using different protease inhibitors, implicating the involvement of distinct proteases in each of these steps. This will facilitate the identification of the parasite and host molecules involved in merozoite release.     

Plasmodium falciparum antigens synthesized by schizonts and stabilized at the merozoite surface when schizonts mature in the presence of protease inhibitors

Schizonts of Plasmodium falciparum were cultured in medium containing a mixture of 10 micrograms/ml each of leupeptin, chymostatin, pepstatin, and antipain. The protease inhibitors did not inhibit macromolecular synthesis but were associated with decreased reinvasion of red cells and the accumulation of well preserved merozoites clustered around pigment granules (PCM, protease inhibitor clusters of merozoites). The parasite pellet from PCM cultures contained increased amounts of merozoite antigens, particularly at Mr 83, 73, 66, 45, and 17 kDa. The increases of the Mr 83, 73, and 45 kDa surface antigens observed in PCM had been observed also in similar merozoite clusters obtained by culturing schizonts in the presence of inhibitory antibodies. These three antigens are processed products of the abundant Mr 195 kDa schizont surface antigen. Liquid-phase double immunofluorescence of PCM demonstrated a residual red cell membrane through which monoclonal antibodies passed and reacted with the Mr 83, 73, and 45 kDa merozoite surface antigens or their precursors. The processes associated with normal reinvasion apparently involve protease(s), which plays a role(s) in the breakdown of the red cell membrane and the shedding of merozoite surface antigens. Interference with these processes by protease inhibitors is useful in increasing recoveries of merozoite antigens, as well as in elucidating mechanisms of reinvasion.     

Ultrastructural differentiation of Toxoplasma gondii schizonts (types B to E) and gamonts in the intestines of cats fed bradyzoites

The ultrastructural characterisitics of four types of Toxoplasma gondii schizonts (types B, C, D and E) and their merozoites, microgamonts and macrogamonts were compared in cats killed at days 1, 2, 4 and 6 after feeding tissues cysts from the brains of mice. Schizonts, merozoites and gamonts contained most of the ultrastructural features characteristic of the phylum Apicomplexa. All four types of schizonts developed within enterocytes or intraepithelial lymphocytes. Occasionally, type B and C schizonts developed within enterocytes that were displaced beneath the epithelium into the lamina propria. Type D and E schizonts and gamonts developed exclusively in the epithelium. Tachyzoites occurred exclusively within the lamina propria. Type B schizonts formed merozoites by endodyogeny, whereas types C to E developed by endopolygeny. The parasitophorous vacuoles surrounding type B and C schizonts consisted of a single membrane, whereas those surrounding types D and E schizonts were comprised of two to four electron-dense membranes. The parasitophorous vacuole of type B schizonts had an extensive tubulovesicular membrane network (TMN); the TMN was reduced or absent in type C schizonts and completely absent in types D and E schizonts and gamonts. Type B merozoites were ultrastructurally similar to tachyzoites, except that they were slightly larger. Type C merozoites exhibited a positive periodic acid-Schiff reaction by light microscopy and ultrastructurally contained amylopectin granules. Rhoptries were labyrinthine in type B merozoites but were electron-dense in types C-E. The development of microgamonts, macrogamont and oocysts is also described.     

In vitro development from sporozoites to first-generation merozoites in Eimeria contorta Haberkorn, 1971. A fine structural study.

The asexual development of Eimeria contorta from sporozoites to first-generation merozoites in tissue culture was investigated with the electron microscope. Sporozoites with a three-layered pellicle, 26 subpellicular microtubules, a conoid, 4-7 rhoptries, and an abundance of micronemes actively entered host cells and showed direct contact to the host cell's cytoplasm. Shortly after penetration, small vacuoles surrounding the parasite merged into a parasitophorous vacuole. Inside this vacuole, sporozoites assumed a definite U-shape before transformation into schizonts took place. This process was characterised by the occurrence of subpellicular microtubules exclusively in the anterior half of the sporozoite, by a degeneration of the 2 inner pellicular membranes, by an outpocketing of the parasite's surface, and by the arrangement of microtubules in clusters. About 25 merozoites were formed at the surface of mature schizonts, to which they remained attached at their posterior pole. A polar ring was present at that area. Anterior and posterior refractile bodies were conspicuous in merozoites and showed close association with mitochondria. The significance of a fibrillar substructure in rhoptries and micronemes is discussed, and special attention is drawn to the pathway of nutrient transport from host cell mitochondria and dictyosomes through intravacuolar folds, parasitophorous vacuole and crescent body into the parasite's food vacuoles.     

The fine structure of secretion by Plasmodium knowlesi merozoites during red cell invasion

The secretory organelles of Plasmodium knowlesi were studied ultrastructurally to examine their mode of action during invasion. The formation of lamellar structures in merozoite rhoptries within late stage schizonts is prevented by the protease inhibitors chymostatin and leupeptin. Under normal conditions vesicles lined by 6-nm membranes are formed in rhoptries during erythrocyte invasion. Stereoscopic viewing of tilted sections shows that where the merozoite apex contacts the parasitophorous vacuole (PV) membrane during invasion, a domed elevation of the PV surface lies within the mouth of the rhoptry duct in contact with the secretory matrix. The membrane of the early invasion pit is thinner (6 nm) than the red cell membrane elsewhere, and sheets of lamellar material are frequently present on the invasion pit surface. These findings support the proposal that the rhoptry-microneme complex is capable of generating membranous material and inserting it into the red cell surface in a controlled manner to create the parasitophorous vacuole. On the basis of this model, measurements from serial sections show that the rhoptries could provide enough material to create a membrane lining the parasitophorous vacuole, and, with the contribution of the microspheres, could double it to accommodate the early ring stage of the parasite.     

The Fine Structure of Secretion by Plasmodium knowlesi Merozoites during Red Cell Invasion

The secretory organelles of Plasmodium knowlesi were studied ultrastructurally to examine their mode of action during invasion. The formation of lamellar structures in merozoite rhoptries within late stage schizonts is prevented by the protease inhibitors chymostatin and leupeptin. Under normal conditions vesicles lined by 6-nm membranes are formed in rhoptries during erythrocyte invasion. Stereoscopic viewing of tilted sections shows that where the merozoite apex contacts the parasitophorous vacuole (PV) membrane during invasion, a domed elevation of the PV surface lies within the mouth of the rhoptry duct in contact with the secretory matrix. The membrane of the early invasion pit is thinner (6 nm) than the red cell membrane elsewhere, and sheets of lamellar material are frequently present on the invasion pit surface. These findings support the proposal that the rhoptry-microneme complex is capable of generating membranous material and inserting it into the red cell surface in a controlled manner to create the parasitophorous vacuole. On the basis of this model, measurements from serial sections show that the rhoptries could provide enough material to create a membrane lining the parasitophorous vacuole, and, with the contribution of the microspheres, could double it to accommodate the early ring stage of the parasite.     

Primary structure of a Plasmodium falciparum malaria antigen located at the merozoite surface and within the parasitophorous vacuole

DNA encoding an antigen of 101,000 apparent molecular weight from the human malaria parasite Plasmodium falciparum was cloned and sequenced. Genomic DNA from the Camp strain covering the complete coding region along with cDNA from the FCR3 strain covering 81% of the coding region were obtained. The cloned DNA specified a full-length protein of 743 amino acids which included two tandemly repeated regions, one near the amino terminus containing eight hexapeptide repeats of sequence TVNDEDED, and the second near the carboxyl terminus containing primarily KE and KEE repeats. The latter repeated region is encoded by a 174-base stretch of mRNA containing only a single pyrimidine. Except for a putative leader sequence located at the amino terminus of the protein, the protein is hydrophilic and highly charged with a calculated isoelectric point of 5.6. Sequences from the Camp and FCR3 strains are very close and are also nearly identical to the partial cDNA sequence of the acidic basic repeated antigen (ABRA) protein from the FC27 strain (Stahl, H.D., Bianco, A.E., Crewther, R.F., Anders, R.F., Kyne, A.P., Coppel, R. L., Mitchell, G.F., Kemp, D.J., and Brown, G.V. (1986) Mol. Biol. Med. 3, 351-368). ABRA was previously shown to be located at the merozoite surface and in the parasitophorous vacuole. Because of its location and because it becomes complexed to merozoites when schizonts rupture in the presence of immune serum, ABRA is a candidate component of a malaria vaccine.     

贝氏隐孢子虫在北京鸭体内发育的超微结构研究

贝氏隐孢子虫各期虫体均位于宿主粘膜上皮细胞的带虫空泡中。在虫体与上皮细胞接触处,虫体表膜反复折迭形成营养器。子孢子或裂殖子与粘膜上皮细胞接触后,逐步过渡为球形的滋养体;滋养体经2—3次核分裂、产生含4或8个裂殖子的两代裂殖体,裂殖体以外出芽方式产生裂殖子;裂殖子无微孔,顶端表皮形成3—4个环嵴,裂殖子进一步发育成为配子体;大配子体含有两种类型的成囊体。小配子呈楔形,无鞭毛和顶体,有一个致密的长椭圆形细胞核,小配子表膜内侧有9根膜下微管;孢子化卵囊内含四个裸露的子孢子和一个大残体。本文是有关鸭体内隐孢子虫超微结构的首次报导。     

Subcellular discharge of a serine protease mediates release of invasive malaria parasites from host erythrocytes

The most virulent form of malaria is caused by waves of replication of blood stages of the protozoan pathogen Plasmodium falciparum. The parasite divides within an intraerythrocytic parasitophorous vacuole until rupture of the vacuole and host-cell membranes releases merozoites that invade fresh erythrocytes to repeat the cycle. Despite the importance of merozoite egress for disease progression, none of the molecular factors involved are known. We report that, just prior to egress, an essential serine protease called PfSUB1 is discharged from previously unrecognized parasite organelles (termed exonemes) into the parasitophorous vacuole space. There, PfSUB1 mediates the proteolytic maturation of at least two essential members of another enzyme family called SERA. Pharmacological blockade of PfSUB1 inhibits egress and ablates the invasive capacity of released merozoites. Our findings reveal the presence in the malarial parasitophorous vacuole of a regulated, PfSUB1-mediated proteolytic processing event required for release of viable parasites from the host erythrocyte.     

Ultrastructural localization of protective and nonprotective Plasmodium falciparum proteins using serum samples from vaccinated Aotus monkeys

Postembedding immunoelectron microscopy, using pooled serum samples from a recent vaccination experiment involving Aotus monkeys, was used to localize immune targets in Plasmodium falciparum-infected erythrocytes and free merozoites. Serum samples from Aotus monkeys, protected completely by immunization with the P. falciparum merozoite surface coat precursor protein, identified immune targets on the surface of free and intracellular merozoites as well as the cytoplasm, plasma membrane, and parasitophorous vacuole membrane of immature schizonts. Serum samples from unprotected monkeys, which had been immunized with a complex of 143-kDa, 132-kDa, and 102-kDa polypeptides reacted specifically with the rhoptries of immature schizonts and mature merozoites.     

Life Cycle of Isospora canis Nemeséri, 1959 in the Dog*

The life cycle of I. canis Nemeséri, 1959 was studied in experimentally infected dogs. Freshly sporulated oocysts were ovoid and 34–40 × 28–32 μm. The endogenous stages were found directly beneath the epithelium of the distal portion of the small intestinal villi. Most of the endogenous stages were in the lower 1/3 of the small intestine, but occasionally they were found in other portions of the small intestine. Three asexual generations were present. First-generation schizonts were 16–38 × 11–23 μm and contained 4–24 merozoites; mature 1st-generation merozoites were 8–11 × 3–5 μm. First-generation schizogony lasted up to 7 days after inoculation. Second-generation schizonts were 12–18 × 8–13 μm and contained up to 12 merozoites which were 11–13 × 3–5 μm. Second-generation schizogony was present on postinoculation days 6 and 7. Third-generation schizonts were formed by nuclear division of 2nd-generation merozoites. Most 2nd-generation merozoites underwent nuclear division without leaving the parasitophorous vacuole of the 2nd-generation schizont. Mature 3rd-generation schizonts were 13–38 × 8–24 μm and contained 6–72 merozoites. Third-generation merozoites were 8–13 × 1–3 μm. Third-generation schizogony was present on days 6–8 after inoculation. Mature macrogametes were 22–29 × 14–23 μm. Mature microgametocytes were 20–38 × 14–26 μm. Gametes were present on postinoculation days 7–10. Oocysts were present in tissue sections on postinoculation days 8–10 and 12. The prepatent period was 9–11 days.     

Plasmodium berghei Δp52&p36 Parasites Develop Independent of a Parasitophorous Vacuole Membrane in Huh-7 Liver Cells

The proteins P52 and P36 are expressed in the sporozoite stage of the murine malaria parasite Plasmodium berghei. Δp52&p36 sporozoites lacking expression of both proteins are severely compromised in their capability to develop into liver stage parasites and abort development soon after invasion; presumably due to the absence of a parasitophorous vacuole membrane (PVM). However, a small proportion of P. berghei Δp52&p36 parasites is capable to fully mature in hepatocytes causing breakthrough blood stage infections. We have studied the maturation of replicating Δp52&p36 parasites in cultured Huh-7 hepatocytes. Approximately 50% of Δp52&p36 parasites developed inside the nucleus of the hepatocyte but did not complete maturation and failed to produce merosomes. In contrast cytosolic Δp52&p36 parasites were able to fully mature and produced infectious merozoites. These Δp52&p36 parasites developed into mature schizonts in the absence of an apparent parasitophorous vacuole membrane as shown by immunofluorescence and electron microscopy. Merozoites derived from these maturing Δp52&p36 liver stages were infectious for C57BL/6 mice.     

Life Cycle of Eimeria ferrisi Levine & Ivens, 1965 in the Mouse, Mus musculus

SYNOPSIS. The life cycle of Eimeria ferrisi is described from experimentally infected Mus musculus. The prepatent period was 3 days and the patent period was 3–4 days. The endogenous stages were found only in the cecum and colon. Three generations of schizonts were found. Mature 1st-generation schizonts first seen 24 hr postinoculation (PI) measured 10.9 (7–14) × 10.2 (6–13) μm and had 9.6 (7–14) merozoites. Some 2nd-generation schizonts had uninucleate merozoites and others had multinucleate merozoites. The former were first seen in small numbers 36 hr PI and were most abundant 48 hr PI. They measured 9.6 (5–13) × 7.9 (6–12) μm and had 18 (6–25) merozoites. Schizonts with multinucleate merozoites were seen 72 hr PI. Mature 3rd-generation schizonts were seen 72 hr PI. They measured 14.0 (12–18) × 11-0 (9–13) μm and had 12.5 (5–16) merozoites. Macrogamonts were first seen in 72 hr sections. Each young macrogamont had a large nucleus with a prominent nucleolus. Only one type of cytoplasmic granule appeared to be involved in the formation of the oocyst wall. Mature macrogamonts were 11.0 (5–14) × 10.0 (6–13) μm. Crescent-shaped bodies were observed in the parasitophorous vacuole of trophozoites and young macrogamonts. Early microgamonts were first recognized at 96 hr by the presence of darkly stained and irregularly shaped nuclei. Usually, mature microgametes were arranged in long, narrow whorls at the periphery of the microgamont or in whorls at the surface of 2–5 compartments.     

Truncation of merozoite surface protein 3 disrupts its trafficking and that of acidic-basic repeat protein to the surface of Plasmodium falciparum merozoites

Merozoite surface protein 3 (MSP3), an important vaccine candidate, is a soluble polymorphic antigen associated with the surface of Plasmodium falciparum merozoites. The MSP3 sequence contains three blocks of heptad repeats that are consistent with the formation of an intramolecular coiled-coil. MSP3 also contains a glutamic acid-rich region and a putative leucine zipper sequence at the C-terminus. We have disrupted the msp3 gene by homologous recombination, resulting in the expression of a truncated form of MSP3 that lacks the putative leucine zipper sequence but retains the glutamic acid-rich region and the heptad repeats. Here, we show that truncated MSP3, lacking the putative leucine zipper region, does not localize to the parasitophorous vacuole or interact with the merozoite surface. Furthermore, the acidic-basic repeat antigen (ABRA), which is present on the merozoite surface, also was not localized to the merozoite surface in parasites expressing the truncated form of MSP3. The P. falciparum merozoites lacking MSP3 and ABRA on the surface show reduced invasion into erythrocytes. These results suggest that MSP3 is not absolutely essential for blood stage growth and that the putative leucine zipper region is required for the trafficking of both MSP3 and ABRA to the parasitophorous vacuole.     

Monoclonal antibody characterization of Plasmodium falciparum antigens in immune complexes formed when schizonts rupture in the presence of immune serum

When Plasmodium falciparum parasites are cultured with some immune sera, merozoites are agglutinated by antibodies to form immune clusters of merozoites and prevent their invasion into erythrocytes. Within these immune clusters of merozoites, several antigens that are normally found in the soluble fraction after detergent extraction accumulate in relatively insoluble immune complexes. From mice immunized with these immune complexes, we obtained hybridomas secreting monoclonal antibodies (mAb) that react with various immune clusters of merozoites antigens, including mAb 3D5, which recognizes a 101-kDa antigen (p101) and mAb, 5E3, which recognizes a 113-kDa antigen (p113). Both mAb reacted with antigens at the surface of schizonts, in the vacuolar space, and at the surface of merozoites before their release from schizont-infected cells. Both p101 and p113 were synthesized by mature trophozoites and young schizonts. In pulse-chase experiments, p113 was processed to 100-, 70-, 55-, and 50-kDa products. Both p101 and p113 appeared in the culture medium when schizont rupture occurred in normal culture medium but were found in immune complexes when schizont rupture occurred in the presence of immune serum. Antibodies in immune complexes, when dissociated with acid and used to probe immunoblots, reacted with affinity-purified p101 and p113. Antigens such as these, which are accessible at the parasite surface and react with antibodies present in immune serum that inhibits parasite invasion, are logical candidates to study in the search for a vaccine against the erythrocytic stages of malaria.     

Development of Hepatozoon griseisciuri in Cultured Squirrel Cells*

Sporocysts of Hepatozoon griseisciuri obtained from laboratory-reared spiny rat mites (Echinolaelaps echidninus) and laboratory-reared squirrel mites (Haemogamasus reidi) were made bacteria-free and incubated in trypsin-bile for 30 min at 37 C to release sporozoites. Hepatozoon griseisciuri sporozoites were inoculated into monolayer cultures of primary adult squirrel kidney (PSK) cells and cell line cultures of neonatal squirrel kidney (SK), heart (SH), and spleen (SS) cells. Extracellular sporozoites underwent flexing, gliding, and pivoting movements similar to other coccidian sporozoites. Sporozoites entered cells in all the cultures used and were found intracellularly as early as 1 hr and as late as 10 days after inoculation. In SK, SH, and SS cells, development proceeded only to the trophozoite stage. In PSK cells, immature schizonts and mature schizonts containing 12–40 merozoites were present from 5 through 10 days after inoculation. The finding of pairs of intracellular organisms within a single parasitophorous vacuole in PSK cells suggested that endodyogeny or limited schizogony had occurred.     

A multifunctional serine protease primes the malaria parasite for red blood cell invasion

The malaria parasite Plasmodium falciparum replicates within an intraerythrocytic parasitophorous vacuole (PV). Rupture of the host cell allows release (egress) of daughter merozoites, which invade fresh erythrocytes. We previously showed that a subtilisin-like protease called PfSUB1 regulates egress by being discharged into the PV in the final stages of merozoite development to proteolytically modify the SERA family of papain-like proteins. Here, we report that PfSUB1 has a further role in ‘priming' the merozoite prior to invasion. The major protein complex on the merozoite surface comprises three proteins called merozoite surface protein 1 (MSP1), MSP6 and MSP7. We show that just before egress, all undergo proteolytic maturation by PfSUB1. Inhibition of PfSUB1 activity results in the accumulation of unprocessed MSPs on the merozoite surface, and erythrocyte invasion is significantly reduced. We propose that PfSUB1 is a multifunctional processing protease with an essential role in both egress of the malaria merozoite and remodelling of its surface in preparation for erythrocyte invasion.     

The Life Cycle of Isospora felis Wenyon, 1923, a Coccidium of the Cat*

SYNOPSIS. A pure strain of Isospora felis derived from a single oocyst was used to study the endogenous cycle. One and a half to two-month-old laboratory-reared, coccidia-free kittens were used thruout the study. The endogenous stages occurred in the epithelial cells of the distal parts of the villi in the ileum and occasionally duodenum and jejunum. All stages lay above the host cell nucleus. There were 3 asexual generations. The 1st generation schizonts were 11–30 by 10–23 μ when mature and contained 16–17 banana-shaped merozoites 11–15 by 3–5 μ. They became mature in 96 or sometimes in 120 hours. The 1st generation merozoites entered new host cells, rounded up and formed 2nd generation schizonts. These formed within themselves 2–10 or more spindle-shaped bodies resembling 1st generation merozoites in shape and size. These were 2nd generation merozoites. They were uninucleate 120 hours after inoculation, but by 144 hours they became larger, multinucleate and some lost their elongate shape and became ovoid. They were then 3rd generation schizonts. They were 12–16 by 4–5 μ. Each formed up to 6 or more banana-shaped merozoites 6–8 by 1–2 μ. The 3rd generation schizonts and merozoites developed within the same host cell and parasitophorous vacuole as the 2nd generation schizonts and merozoites. Mature schizonts containing only 3rd generation merozoites appeared 144 hours after inoculation, were most abundant 168 hours after inoculation, and might be present as late as 216 hours after inoculation. They were 14–36 by 13–22 μ and contained 36 to more than 70 merozoites. The 3rd generation merozoites entered the sexual cycle. The mature microgametocytes were 24–72 by 18–32 μ and contained a central residuum and a large number of microgametes 5–7 by 0.8 μ with 2 posteriorly-directed flagella. The mature macrogametes were 16–22 by 8–13 μ. Gametogony occurred 144–216 hours after inoculation. The prepatent period was 168–192 hours and the patent period 10–11 days. Peak oocyst production occurred on the 6th day of the patent period.