Adherence Patterns of <Emphasis Type="Italic">Histoplasma capsulatum</Emphasis> Yeasts to Bat Tissue Sections

The adherence of Histoplasma capsulatum yeasts to lung, spleen, liver, gut, and trachea cryosections of Artibeus hirsutus bats and inbred BALB/c mice (control) was studied after in vitro yeast-tissue incubations. Candida albicans yeasts were used as a well-known adherent fungal model in the mice host, and latex beads were used as a negative adherence control. Adhered yeast cells were identified by using crystal violet staining and the immunoperoxidase method with specific antibodies. H. capsulatum yeasts adhered to all tissues tested, mainly in the lung. Moreover, H. capsulatum yeasts adhered preferentially to white and red spleen pulp, in contrast to the dispersed distribution of C. albicans yeasts. H. capsulatum yeasts were mostly found on the sinusoidal face of hepatocytes. In general, the gut showed a higher number of adhered H. capsulatum yeasts than the trachea in both bats and mice. H. capsulatum and C. albicans yeasts developed high selectivity for the lamina propria of the gut. In addition, H. capsulatum yeasts interacted better with the lamina propria and adventitia of the trachea. The number of H. capsulatum yeast cells that adhered to each tissue section type was always greater than the corresponding number of C. albicans yeast cells, and latex beads never adhered to the tissue sections. Controls with anti-H. capsulatum and normal rabbit sera showed a significant blockage of H. capsulatum yeast adherence to lung tissue. This is the first study describing the patterns of H. capsulatum yeast adherence to different bat and mouse tissues.     

Experimental histoplasmosis capsulati in athymic nude mice

Granuloma formation in nude (nu/nu) mice and their heterozygous littermates (nu/+ mice) against Histoplasma capsulatum var. capsulatum infection was studied.A culture of H. capsulatum var. capsulatum, isolated from a granuloma in the nasal cavity of a Japanese patient, was used in this experiment. Sixteen specific-pathogen-free male nu/nu and 32 nu/+ mice were used in this study.The nu/+ mice were divided into two groups. Sixteen nu/+ mice in one group and 16 nu/nu mice were inoculated intraperitoneally with 10⁶ yeast cells of the fungus, those in the other group of nu/+ mice were inoculated intravenously with the same number of the yeast cells. Two mice out of each group were sacrificed 2, 3, 7, 11, 14, 18, 25 and 30 days after inoculation, and each of their organs was examined histopathologically. In addition, pieces of these tissues were cultured on Sabouraud's dextrose agar slants.In the nu/+ mice inoculated intraperitoneally, although the fungus was recovered from the spleen, kidney and lymph nodes during the initial course of the infection, lesions were not detected in their histopathological sections. In the nu/+ mice inoculated intravenously, colonies were recovered from all of the organs examined, other than the brain and thymus, 7 days after inoculation.Histopathologically, a few microfoci consisting chiefly of mononuclear cells with or without yeast cells were found in the liver sections 4 days after inoculation. Seven and 11 days after inoculation the number of lesions had increased. They had large accumulations of mononuclear cells. From day 14 on, almost all of the yeast cells had lost most of their staining affinity or were destroyed in the granuloma. From day 25 on, the granulomatous lesions changed gradually to fibrous tissue.In the nu/nu mice the fungus was readily recovered from the spleen, liver, kidney and lymph nodes. Histopathologically, a few microfoci consisting of mononuclear cells were present in the liver sections 4 days after inoculation. That is to say, during the initial course of infection granulomas were formed. In the liver, from day 7 on, the lesions were large and their number increased. However, there was a definite difference between the nu/nu and nu/+ mice. In the former, the yeast cells were not killed, and they continued to multiply within the granulomas. These granulomas were never transformed into fibrous tissue.     

Invasion and Early Development of Sarcocystis muris (Apicomplexa,Sarcocystidae) in Tissue Cultures1

Ultrastructural observations on the invasion and early development of merozoites (bradyzoites) of Sarcocystis muris in Madin-Darby canine kidney (MDCK) cells are presented. Invading merozoites cause the host cell plasmalemma to invaginate; they form a membrane junction (moving junction) and move into the host cell where they are enclosed in a primary parasitophorous vacuole (PV). Within 30–45 min after becoming intracellular, merozoites begin to vacate the newly established primary PV and move, forming a new membrane junction, into a secondary PV. Simultaneously with the movement of the parasite, the contents of dense granules in the apical part of the merozoites are shed by exocytosis into the lumen of the developing secondary PV. A lamella of the endoplasmic reticulum of the host cell becomes attached to the PV membrane, forming a PV limited by three host cell membranes.     

Effect of Conditioned Media from Several Cell Types on Invasion by Eimeria adenoeides Sporozoites1

ABSTRACT. The effect of conditioned media (media aspirated from a variety of cell cultures after 4 d of growth) on cellular invasion by sporozoites of the turkey coccidium, Eimeria adenoeides, was examined. Conditioned medium from turkey kidney cells and baby hamster kidney cells failed to alter invasion. However, conditioned medium from turkey cecal cell cultures produced a significant (P ≤ 0.05), two-fold increase in invasion over control medium in a variety of cell types. Retentates of conditioned medium from the turkey cecal cells that were passed through microconcentrators having molecular mass cutoffs of 50, 100, and 300 kDa similarly enhanced invasion over retentates from control medium. However, retentates from microconcentrators with a cutoff of 1,000 kDa failed to enhance invasion. Pretreatment in conditioned medium, followed by washing of sporozoites prior to inoculation into cultures, did not result in enhanced invasion. Moreover, when the interval between inoculation of sporozoites into cells and fixation of cultures was reduced to less than 3 h, no enhancement of invasion occurred. Conditioned medium from turkey cecal cells that were grown in the presence of ³⁵S-translabel had at least two labeled bands at 150 kDa and > 200 kDa that were absent in conditioned media from turkey kidney and baby hamster kidney cells.     

Development of First-Generation Schizonts of Eimeria bovis in Cultured Bovine Cells

SYNOPSIS. Monolayer primary and secondary cultures of embryonic bovine kidney, spleen, intestinal and testicle cells, and secondary cultures of embryonic bovine thymus, maintained in lactalbumin hydrolysate, Earle's balanced salt solution and ovine serum were observed for a maximum of 21 days after inoculation of E. bovis sporozoites. The sporozoites entered the cells in all of these cultures but underwent development only in primary cultures of kidney and intestinal cells and in secondary cultures of kidney, spleen, thymus, intestinal, and testicle cells. In acellular media, the sporozoites retained motility no longer than 21 hr. In the cell cultures, free motile sporozoites were seen for as long as 18 days after inoculation. Sporozoites entered cells anterior end first; the process of penetration required a few seconds to about a minute. Sporozoites were also observed leaving host cells. Intracellular sporozoites were first seen 3 min after inoculation; they were observed at various intervals up to 18 days after inoculation. In transformation of sporozoites into trophozoites a marked change in size and appearance of the nucleus took place before the change in shape of the body occurred. Trophozoites were first found 7 days after inoculation, multinucleate schizonts after 8 days, and schizonts with merozoites after 14 days. Schizonts containing merozoites were seen only in kidney, spleen, and thymus cells. The mature schizonts were smaller and represented a much lower proportion of the total number than in comparable stages of infections in calves. Schizonts with many nuclei occurred in intestinal cells; the most advanced stage seen in testicle cells was the binucleate schizont. Nuclear and cytoplasmic changes were observed in the infected cells.     

Development of Eimeria auburnensis in Cell Cultures

SYNOPSIS. Monolayer established cell line cultures of bovine kidney (Madin-Darby) and human intestine (Intestine 407), as well as embryonic bovine tracheal and embryonic spleen cell line cultures were inoculated with E. auburnensis sporozoites and observed for a maximum of 22 days. Mature 1st generation schizonts developed in the kidney, tracheal and spleen cells. In the intestine cells, trophozoites were seen in 3 of 4 experiments, but schizonts were not found. Sporozoites penetrated cells, beginning within a few minutes after inoculation. Penetration was usually accomplished within 10 seconds, and the body of the sporozoite underwent a slight constriction as it passed thru the host cell membrane. Some sporozoites left cells. Numerous intracellular sporozoites were observed in kidney, tracheal and spleen cultures. Crescent bodies were seen in the parasitophorous vacuole as early as 1 day after inoculation. At this time, the nuclei of most intracellular sporozoites had changed from vesicular to compact. Beginning 4 days after inoculation, enlarged sporozoites and parasites having a sporozoite shape, but with 2-5 nuclei, were frequently seen. These enlarged sporozoites and sporozoite-shaped schizonts evidently transformed into trophozoites and spheroidal schizonts by means of lateral outpocketings. Few trophozoites were seen. More immature schizonts developed in kidney cells than in the other cell types. The numbers of mature schizonts observed in kidney and tracheal cells were similar, but development occurred less consistently in the latter. Few immature and mature schizonts developed in spleen cells. Mature schizonts, first seen 9 days after inoculation, were considerably smaller than those reported from calves. Some motile merozoites were seen; evidently no development beyond these occurred. The nucleus and nucleolus of host cells were enlarged; this enlargement was not as pronounced as in infections in calves. Multiple host cell nuclei were frequently observed. Degenerative changes in the cultured cells and in the parasites usually occurred, beginning 9-17 days after inoculation; these were more pronounced in the spleen cells than in the others.     

Histoplasma capsulatum‐induced extracellular DNA trap release in human neutrophils

Neutrophils are leukocytes that are capable of eliminating both intra‐ and extracellular pathogens by mechanisms such as phagocytosis, degranulation, and release of neutrophil extracellular traps (NETs). Histoplasma capsulatum var. capsulatum (H. capsulatum) is a dimorphic fungus with a global distribution that causes histoplasmosis, a disease that is endemic in different geographic areas and is spreading worldwide. The release of NETs has been described as an important host defense mechanism against different fungi; however, there are no reports demonstrating that this process is implicated in neutrophil response to H. capsulatum infection. Therefore, the aim of this work is to investigate whether isolated human neutrophils release NETs in response to H. capsulatum and the potential mechanisms involved, as well as delineate the NETs antifungal activity. Using both confocal fluorescence and scanning electron microscopy techniques, we determined that NETs are released in vitro in response to H. capsulatum via an oxidative mechanism that is downstream of activation of the Syk and Src kinase pathways and is also dependent on CD18. NETs released in response to H. capsulatum yeasts involve the loss of neutrophil viability and are associated with elastase and citrullinated histones, however also can occur in a PAD4 histone citrullination independent pathway. This NETs also presented fungicidal activity against H. capsulatum yeasts. Our findings may contribute to the understanding of how neutrophils recognize and respond as immune effector cells to H. capsulatum, which may lead to better knowledge of histoplasmosis pathophysiology and treatment.     

牛支原体LRR5蛋白原核表达及其在牛支原体入侵宿主细胞过程中的作用分析

致病性支原体具有入侵宿主细胞的能力,这是其发挥致病作用的关键。介导支原体入侵宿主细胞的自身功能蛋白可能是一种潜在的药物或疫苗靶标。【目的】克隆表达牛支原体(Mycoplasmabovis) MBOVPG45_0564基因编码蛋白(命名为LRR5蛋白),并探究其在M. bovis入侵宿主细胞过程中的作用。【方法】利用NCBI数据库对MBOVPG45_0564基因进行同源性分析,用Discovery Studio Client系统对LRR5蛋白进行蛋白结构预测;原核表达LRR5蛋白并制备其小鼠多克隆抗体,利用免疫电镜对LRR5蛋白进行亚细胞定位;通过平板计数、激光共聚焦显微镜观察LRR5抗体封闭后M. bovis对胎牛肺(embryonic bovine lung, EBL)细胞入侵率的变化;将LRR5蛋白偶联至荧光微球表面后,以激光共聚焦显微镜及高内涵活细胞成像系统观察微球进入EBL细胞情况。【结果】MBOVPG45_0564基因在牛支原体属中为保守基因,其编码蛋白LRR5为膜相关蛋白,空间构象呈典型的月牙状,多个重复的亮氨酸基序以超螺旋方式组装并形成螺线管蛋白质结构单元。LRR5抗体封闭后,M. bovis对EBL细胞的入侵率显著降低(P<0.05),荧光微球偶联LRR5蛋白后,荧光微球可成功进入EBL细胞。【结论】MBOVPG45_0564基因编码的LRR5蛋白定位在M. bovis膜上,在M. bovis入侵宿主细胞过程中发挥着重要作用。     

Cross-protection between Histoplasma capsulatum and Oidiodendron kalrai in mice

Summary Cross-protection studies were carried out by immunizing mice intraperitoneally with live and formalin killed yeast cells ofHistoplasma capsulatum andOidiodendron kalrai. Immunized and non-immunized mice were challenged intravenously 21 days later with the yeast cells ofHistoplasma capsulatum. The greatest protection was observed in mice immunized with live cells ofH. capsulatum and was definitely superior to that obtained with killed cells ofH. capsulatum. Significant protection against challenge byH. capsulatum was observed in mice immunized with killed but not with live cells ofO. kalrai.This work was supported from a research grant from the Bremer Foundation.The authors wish to thank Professor CharlotteC. Campbell for the supply ofHistoplasma capsulatum culture.     

Herpesvirus simiae infection in Macaca radiata

Forty of 79 bonnet macaques (Macaca radiata) housed in an outdoor structure became infected with a respiratory disease, and 16 died. The most conspicuous lesions were those of hemorrhagic interstitial lobar pneumonia and focal hepatic necrosis with monocytic infiltration and eosinophilic intranuclear inclusions. A virus, in high titer, was obtained from the lung and liver of two fatal cases (10⁷ TCID₅₀ × gram of tissue) by inoculating tissue homogenates in primary vervet monkey kidney, BSC-1, and MA104 cell cultures. The cytopathic effect was identical with that induced by Herpesvirus simiae in the same cell cultures. Similar cellular changes were seen in LLC-MK2 cell cultures. Infected cells contained eosinophilic intranuclear inclusions, and intranuclear herpes-like virus particles were seen by electron microscopy. The virus could not be passed serially in mice by the intracerebral route of inoculation. Bonnet monkeys (herpes antibody-free), inoculated intravenously with the virus, developed vesicular lesions on the arms, face, hands, and soles of the feet; and the virus was recovered from the vesicular fluid. All lesions disappeared within three weeks after inoculation, and the animals later recovered. On the basis of host range, cytopathic effect, electron microscopy, mouse susceptibility, and the results of neutralization tests in tissue cultures, the virus was identified as Herpesvirus simiae.     

Reduced Invasion of Cultured Cells Pretreated With A Monoclonal Antibody Elicited Against Refractile Body Antigens of Avian Coccidial Sporozoites

The effect of a monoclonal antibody (1209-C2) elicited against sporozoite refractile-body antigen on invasion of cultured baby hamster kidney cells by avian Eimeria species was examined in vitro. Pretreatment of sporozoites with 1209-C2 for 45 min before inoculation into cultures or simultaneous introduction of sporozoites and 1209-C2 into cultures had no significant effect on invasion. However, pretreatment of cultures for 45 min with 1209-C2 (also with media from other cloned 1209 cell lines) significantly inhibited invasion by sporozoites of Eimeria tenella and E. adenoeides. Pretreatment of cultures with 2 unrelated monoclonal antibodies with the same isotype as 1209-C2 did not inhibit invasion by E. tenella. There was a significant correlation between time of exposure of the cultures to 1209-C2 and invasion (r = -0.80924; p = 0.0001), with inhibition of invasion occurring after 20 min exposure, but not after 10 min. There was also a significant correlation between the titer of 1209-C2 and invasion (r = 0.62291; p = 0.0305). Monoclonal antibody 1209-C2 cross-reacted with epitopes of baby hamster kidney cells by both immunofluorescence and Western blot. The fluorescent labeling of the cells differed according to the fixative that was used. In formalin-fixed cultures labeled with 1209-C2, fluorescent foci were distributed over the entire cell; after methanol fixation, 1209-C2 reacted with only discrete foci in the nucleus. On Western blots of sporozoites, 1209-C2 reacted with antigens having molecular sizes of approximately 8, 17, 23, 30, and 45-60 kDa, and with several minor bands. On baby hamster kidney cells, the antibody reacted primarily with bands of approximately 30, 45-60, and slightly with other bands. The data suggest that interactions among similar molecules in the sporozoites and host cells may play a role in cellular invasion.     

Invasion and early development of Sarcocystis muris (Apicomplexa, Sarcocystidae) in tissue cultures

Ultrastructural observations on the invasion and early development of merozoites (bradyzoites) of Sarcocystis muris in Madin-Darby canine kidney (MDCK) cells are presented. Invading merozoites cause the host cell plasmalemma to invaginate; they form a membrane junction (moving junction) and move into the host cell where they are enclosed in a primary parasitophorous vacuole (PV). Within 30-45 min after becoming intracellular, merozoites begin to vacate the newly established primary PV and move, forming a new membrane junction, into a secondary PV. Simultaneously with the movement of the parasite, the contents of dense granules in the apical part of the merozoites are shed by exocytosis into the lumen of the developing secondary PV. A lamella of the endoplasmic reticulum of the host cell becomes attached to the PV membrane, forming a PV limited by three host cell membranes.     

Contamination Expérimentale In Vivo et In Vitro par Aggregata eberthi: Etude Ultrastructurale1

The mechanism of host invasion by Aggregata has been experimentally investigated both in vivo (in the crab), and in vitro (in mollusc cell cultures) and followed by electron microscopy. A few hours after the infesting meal, sporozoites escaped from sporocysts in the crab stomach: then they reached the small intestine. There, they pussed through the epithelium, making their way between the cells. Perforation of the thick basal lamina was induced by means of the elaboration of a dense product, probably an enzyme. Sporozoites stretched themselves passing through the basal lamina and entered the connective tissue surrounding the digestive tract. Damages inflicted on the host were minimal. In vitro, merozoites were able to enter cells from several molluscs by penetrating the cell's plasmalemma. A nucleolus appeared in the nuclei of intracellular merozoites.     

Immunocytochemical staining of Histoplasma capsulatum at the electron microscopic level

Summary Rabbits were immunized with histoplasmin emulsified in Freund's complete adjuvant. Antibody raised in these rabbits was exposed to Histoplasma capsulatum yeast cells, either in tissue culture medium, or after in vitro or in vivo phagocytosis by mouse macrophages. The sites of antibody binding were identified using an immunoperoxidase technique. At least two sites of antibody binding were identified, one to the fungal cell wall and the other to the outer cell membrane. Within 6 h after phagocytosis by macrophages, fungal cell walls appeared roughened, with what appeared to be cell wall antigen released into the phagolysosome, appearing associated with the phagolysosome membrane, and possibly adjacent macrophage cytoplasm. Similar staining of fungal antigen was noted in alveolar macrophages which had ingested Histoplasma capsulatum after a respiratory challenge. This method may be useful in detailing the host/pathogen interactions which occur in human pulmonary histoplasmosis.     

Development of Eimeria ninakohlyakimovae from Sheep In Cell Cultures*

SYNOPSIS. Monolayer cell line cultures of ovine trachea, thyroid, thymus, and kidney cells, as well as an established cell line (Madin-Darby) of bovine kidney cells, were inoculated with sporozoites of Eimeria ninakohlyakimovae and observed for a maximum of 24 days. Sporozoites were seen penetrating cells within 5 minutes after inoculation, as well as 2 and 3 days after inoculation, and leaving cells 3 days after inoculation. Transformation from sporozoites to trophozoites occurred by a widening or by a lateral outpocketing of the sporozoite body. Trophozoites and schizonts were first seen 3 days after inoculation in all ovine cell types. Large numbers of immature schizonts were observed, but only an estimated 0.4–4.3% of these became mature in the different kinds of cells. Usually, mature schizonts were first seen 10–11 days after inoculation in the ovine cells, but they sometimes occurred as early as 8 days. More mature schizonts were seen in the ovine kidney and trachea cells than in the others; the smallest number occurred in the bovine cells. The nucleoli of cells harboring large schizonts in each type of culture were enlarged and the chromatin clumps normally seen in the nuclei of non-infected cells were not visible. The cytoplasm of some infected cells was vacuolated. The formation of merozoites occurred by a budding process from blastophores, from the surface of schizonts, and/or from infoldings and invaginations of this surface. Merozoites were observed leaving host cells, but were not seen penetrating new cells. Intracellular first-generation merozoites were observed 13 and 15 days after inoculation in lamb trachea and kidney cells, respectively. No evidence of further development of such merozoites was found.     

Role of sipA in the early stages of Salmonella typhimurium entry into epithelial cells

Salmonella virulence depends on an ability to invade host cells, which is in turn dependent on a type III protein secretion system encoded in Salmonella pathogenicity island 1 (SPI1). Several protein targets of the SPI1‐encoded secretion system are translocated into host cells, where they subvert cellular processes that contribute to bacterial invasion, actin rearrangement, membrane ruffling and other aspects of virulence. We examined the role of sipA (encoding the translocated protein SipA) and found that a sipA mutant was significantly less invasive in Madin–Darby canine kidney (MDCK) cells than in its parental strain at the earliest stages of infection (5 min). The invasion defect associated with sipA was no longer apparent after 15 min of infection. Confocal microscopy of F‐actin in tetramethyl rhodamine isothiocyanate (TRITC)–phalloidin‐stained MDCK cells revealed no difference in either the frequency or the morphology of membrane ruffles induced by wild‐type and sipA mutant strains of S. typhimurium. Time‐lapse phase‐contrast microscopy of membrane ruffle propagation in live cells confirmed that the sipA mutant induced membrane ruffles as efficiently as the wild‐type bacteria. These studies also revealed that, after ruffle propagation, individual sipA mutant S. typhimurium either invaded more slowly than wild‐type bacteria or failed to invade at all. Furthermore, although wild‐type S. typhimurium typically maintained a position central to the developing membrane ruffle, sipA mutant bacteria frequently moved initially to the periphery of the spreading ruffle and were sometimes observed to detach from it. A wild‐type pattern of invasion was restored to the sipA mutant after the introduction of sipA on a plasmid. Together, these data indicate that loss of sipA significantly decreases the efficiency of S. typhimurium invasion at the early stages of infection without affecting its ability to induce membrane ruffles. It thus appears that the secreted effector protein SipA promotes invasion by a previously unrecognized mechanism separate from the induction of membrane ruffling per se.     

Effects of bacterial physiological states and bacterial species on host–microbe interactions

Abstract

This study investigated how the physiological states of Aggregatibacter actinomycetemcomitans (Aa) and Streptococcus mitis affect their intracellular invasion capabilities and the resulting host cell responses. The physiological states included two forms of planktonic states, floating or sedimented (by centrifugation) and the biofilm state (with centrifugation). Confluent epithelial Ca9-22 cells were challenged with floating or sedimented planktonic cultures, or with 24-h biofilms for 3?h. The results show that intracellular invasion efficiencies were clearly affected by the bacterial physiological states. For both bacterial species, the sedimented-cells displayed 2–10 times higher invasion efficiency than the floating-cells (p?<?0.05). The invasion efficiency of Aa biofilms was three fold lower than sedimented cells, whereas those of S. mitis biofilms were similar to sedimented cells. Unlike invasion, the metabolic activities of Ca9-22 were unaffected by different bacterial physiological states. However, Aa biofilms induced higher IL-1β expression than planktonic cultures. In conclusion, different bacterial physiological states can affect the outcomes of (in vitro) host–microbe interaction in different ways.     

Development of Eimeria alabamensis from Cattle in Mammalian Cell Cultures*

SYNOPSIS. Monolayer primary cultures of cells from bovine embryonic intestine (BEInt), kidney (BEK), spleen (BES), and thyroid (BETy) and cell line cultures of embryonic bovine trachea (EBTr) and synovium (BESy) as well as established cell line cultures of bovine kidney (Madin-Darby, MDBK), human intestine (Int 407) and Syrian hamster kidney (BHK) were inoculated with freshly excysted sporozoites of Eimeria alabamensis and observed for 4–5 days. Sporozoites penetrated all cell types; during the 1st 24 hr, intracellular sporozoites, trophozoites and binucleate schizonts were seen in all cell cultures. Mature schizonts were more numerous in BES and MDBK cells than in the others. Large schizonts, 14.2 (11–18.5) by 10.2 μ (8.5–11), with 6–14 short, stubby merozoites (each with 2 refractile bodies) occurred at 2 and 3 days in all cells except BESy, Int 407, and BHK. Small schizonts, 9.7 (5.5–13) by 6 μ (5–8.5), with 6–10 long, slender merozoites (each with 2 refractile bodies) were found 3 days after inoculation in all cell types. At 4 days, some intracytoplasmic merozoites and a few intranuclear 2nd generation trophozoites were found. After 4 days post-inoculation, intracellular parasites were rarely seen and these were apparently degenerate. Development within the host cell nucleus, the normal site of development in the host animal, was observed infrequently in cell cultures. Intranuclear sporozoites, found no earlier than 2 days after inoculation, developed similarly to those in the cytoplasm, and small intranuclear schizonts with 6–10 merozoites (each with 2 refractile bodies) occurred after 3 days in culture.     

Effects of Cationized Ferritin and Neuraminidase on Invasion of Cultured Cells by Eimeria meleagrimitis Sporozoites

Primary turkey kidney cells and Eimeria meleagrimitis sporozoites were treated with cationized ferritin (CF) or neuraminidase (NANase), and the effects on the invasion of the cells by the sporozoites were measured. Cultures of host cells pretreated with either compound contained significantly fewer intracellular sporozoites than did control cultures. There was little additive effect if cultures were first treated with NANase and then with CF. In contrast, pretreatment of sporozoites with CF or low concentrations of NANase had no effect on invasion. The inhibition of invasion was apparently due to an interaction between treatment substances and host cell surface rather than to direct effect on the sporozoites. The CF bound to the randomly distributed anionic sites on the surfaces of both host cells and sporozoites and then rapidly aggregated. Sporozoites, probably in the process of invading cells, were invariably found with the conoid in close association with aggregates of CF on the host cell membrane. The CF on the sporozoites was apparently shed before or during invasion because all intracellular sporozoites were completely devoid of the label.