Journal of Histochemistry and Cytochemistry, Vol. 49, 445-454, April 2001, Copyright © 2001, The Histochemical Society, Inc.


ARTICLE

Calmodulin Distribution and the Actomyosin Cytoskeleton in Toxoplasma gondii

Nathalie Pezzella–D'Alessandroa, Hervé Le Moala, Annie Bonhommea, Audrey Valerea, Christophe Kleinb, Jorge Gomez–Marinc, and Jean-Michel Pinona
a UPRES EA 2070 "Interactions cellules-cellules et cellules-parasites," IFR 53, Reims, France
b UPRES EA 2063 "Médicaments anticancéreux: interactions moléculaires et cellulaires," IFR 53, Reims, France
c Grupo Patologia Infecciosa, Hospital San Juan de Dios, Universidad Nacional de Bogota, Bogota, Colombia

Correspondence to: Annie Bonhomme, UPRES EA 2070, IFR, 53-51 rue Cognacq Jay, 51095 Reims Cedex, France. E-mail: annie.bonhomme@univ-reims.fr


  Summary
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Materials and Methods
Results
Discussion
Literature Cited

The gliding motility of the protozoan parasite Toxoplasma gondii and its invasion of cells are powered by an actin–myosin motor. We have studied the spatial distribution and relationship between these two cytoskeleton proteins and calmodulin (CaM), the Ca2+-dependent protein involved in invasion by T. gondii. A 3D reconstruction using labeling and tomographic studies showed that actin was present as a V-like structure in the conoidal part of the parasite. The myosin distribution overlapped that of actin, and CaM was concentrated at the center of the apical pole. We demonstrated that the actomyosin network, CaM, and myosin light-chain kinases are confined to the apical pole of the T. gondii tachyzoite. MLCK could act as an intermediate molecule between CaM and the cytoskeleton proteins. We have developed a model of the organization of the actomyosin–CaM complex and the steps of a signaling pathway for parasite motility.

(J Histochem Cytochem 49:445–453, 2001)

Key Words: T. gondii, calmodulin, actomyosin complex, MLCK, confocal microscopy, 3D reconstruction


  Introduction
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Summary
Introduction
Materials and Methods
Results
Discussion
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THE COCCIDIAN Toxoplasma gondii, belonging to the phylum Apicomplexa, can infect almost any warm-blooded vertebrate. It is a major cause of severe congenital disease in humans and is one of the main opportunistic pathogens in AIDS. T. gondii is an obligate intracellular parasite and so must be able to enter the host cell. The invasion process of T. gondii differs from endocytotic uptake, and penetration is an active function of the tachyzoite (the invasive stage of T. gondii). The parasite has no specialized structures for movement, and motility and invasion are powered by the cytoskeleton. T. gondii is highly polarized and has a complex cytoskeleton with an apical cone-like structure or conoid connecting to 22 singlet microtubules that extend two thirds of the length of the parasite (Nichols and Chiappino 1987 ). Tachyzoites glide over a substrate with a peculiar spiraling motion produced by the interaction of the microtubules with the internal membrane complex. The conoid can be extended and retracted by an actin–myosin motor to probe the surface of the host cell before penetration. Motility and invasion are blocked by inhibitors of actin and myosin function (cytochalasin D, an actin inhibitor, BDM, a myosin–ATPase inhibitor, and KT5926, a myosin light-chain kinase inhibitor) (Dobrowolski and Sibley 1996 ; Dobrowolski et al. 1997a , Dobrowolski et al. 1997b ). The core of the conoid complex is occupied by the terminal ducts of rhoptries, which secrete substances such as PLA2 (Gomez-Marin et al. 1996 ) that modify components of the host cell cortex and thus help the tachyzoite to penetrate.

As we have recently demonstrated (Pezzella et al. 1997b ), invasion by T. gondii is calcium-dependent. Calcium channel blockers and calmodulin antagonists significantly reduce the invasion index. The ubiquitous regulatory protein calmodulin plays an important role in processing calcium signals. Ca–CaM complexes bind to and regulate many functions, including cell secretion, cell motility, the organization of the cytoskeleton, and the activation of enzymes. Calmodulin is present in T. gondii (Pezzella et al. 1997a , Pezzella et al. 1997b ) and may be involved in cytoskeletal movement and conoid extrusion. However, unlike actin (Cintra and de Souza 1985 ; Yasuda et al. 1988 ; Dobrowolski et al. 1997b ), no pattern for CaM distribution has been reported. The functional significance of the distribution of CaM in relation to tachyzoite structures remains to be studied. Our recent work on CaM distribution during tachyzoite invasion of KB cells (human epidermoid carcinoma epithelium cell line 86103004; ECA CC, Salisbury, UK) showed that CaM accumulates at the apical pole of the parasite (Pezzella et al. 1997a , Pezzella et al. 1998 ). This indicates that tachyzoite calmodulin plays a part in cytoskeletal movements during invasion.


  Materials and Methods
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Materials and Methods
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Parasites
Tachyzoites of the T. gondii RH strain were maintained by serial passages at 3–4-day intervals in a culture of THP1 cells (myelomonocytic cell line; American Type Culture Collection, Rockville, MD, non-adherent cells) in RPMI medium supplemented with 10% fetal calf serum, 2 mM glutamine, 100 U/ml penicillin, and 100 µg/ml streptomycin. Tachyzoites were removed when the THP1 cells were lysed, centrifuged at 500 x g for 15 min, and suspended in RPMI medium.

Cells
KB cells (human epidermoid carcinoma epithelium cell line 86103004) were grown in RPMI-1640 medium supplemented with 10% heat-inactivated fetal calf serum, 2 mM glutamine, and streptomycin–penicillin (100 µg/ml–100 U/ml) at 37C in an atmosphere of saturated 5% CO2/95% air. The cells were harvested by trypsination (0.05% trypsin–0.02% EDTA) and seeded at 5.105 cells/25-ml flask.

Infection of KB Cells
KB cells were plated on coverslips (104 cells) for 48 hr to obtain a subconfluent culture. The coverslips were then placed in 24-well microtiter plates (Nunc; Polylabo Block, Strasbourg, France) containing 1 ml RPMI per well. The monolayers of KB cells were then infected with washed tachyzoites with a cell:parasite ratio of 1:10 and were left in contact for 24–96 hr.

Fluorescent Immunolabeling of Actin
Extracellular tachyzoites were placed on glass slides. Intracellular tachyzoites in their KB host cells plated on coverslips were treated by permeabilizing the host cell membrane by immersion for 3 min in 0.1% Triton X-100 and then fixed in 3% paraformaldehyde in PBS, pH 7.2, for 30 min. The cells were first incubated for 30 min with PBS containing 0.2% gelatin, 3% BSA, and then with a rabbit polyclonal anti-actin (chicken back muscle) antibody (Chemicon; Euromedex, Souffelweyersheim, France) diluted 1:30 in the same buffer for 1 hr at room temperature (RT). Tested in Western blotting with tachyzoite homogenate, this antibody recognized particularly a band around 40 kD. The samples were then washed six times with PBS–gelatin–BSA and incubated with biotinylated donkey anti-rabbit IgG antibody (diluted 1:50 in the same buffer) for 1 hr at RT. Cells were washed three times in PBS–gelatin–BSA and three times in PBS and then incubated with streptavidin–Texas Red (diluted 1:50 in PBS) for 15 min in the dark, and washed again with PBS. Their nuclei were stained with 150 mM MgCl2 and 100 µM chromomycin A3 for 15 min in the dark, and finally with MgCl2. The cells were treated with Citifluor and examined by confocal microscopy (microscope Zeiss Axioplan, confocal part: MRC 600).

Fluorescent Immunolabeling of Myosin
Myosin was labeled in the same way as actin, except that the cells were first fixed using 3% paraformaldehyde before permeabilization with 0.1% Triton X-100. The primary antibody was a rabbit polyclonal anti-(bovine uterus smooth muscle) myosin antibody (diluted 1:50) (Valbiotech; Paris, France). This antibody recognized particularly two bands at 120 kD and 110 kD and a more intense band at 90 kD when tested by Western blotting with a tachyzoite homogenate. These seem to correspond to TgM-C, TgM-B, and TgM-A.

Fluorescent Immunolabeling of Calmodulin
This experiment was performed using the myosin protocol, except that the primary antibody was a mouse monoclonal anti-(Dictyostelium, bovine, rat, and chicken) calmodulin antibody (Tebu; Le Perray en Yvelines, France) diluted 1:80 (Amersham; Les Ulis, France) and the secondary antibody was a biotinylated sheep anti-mouse IgG antibody diluted 1:50 (Amersham).

Fluorescent Immunolabeling of Myosin Light-chain Kinases
MLCK was labeled according to the CaM labeling protocol. The primary antibody was a mouse monoclonal anti-chicken MLCK antibody (Sigma; St Quentin Fallavier, France) diluted 1:50 and the secondary antibody was a biotinylated sheep anti-mouse IgG antibody diluted 1:50 (Amersham.

Controls without the primary antibody were prepared in four experiments.

Double Calmodulin–Actin Immunolabeling in Extracellular Tachyzoites. The main problem with this experiment was to balance the detergent extraction before fixation (for the cytoskeleton protein) against calmodulin removal (calmodulin being a soluble protein). We used extraction for 1 min before fixation to keep the CaM in place. We first labeled the CaM using the protocol used for CaM immunodetection alone (see above). Actin was then labeled by incubating the samples with rabbit polyclonal anti-actin (diluted 1:30), then with a digoxigenin sheep anti-rabbit IgG F(ab')2 fragment (diluted 1:100) for 1 hr, and finally with a fluorescein sheep anti-digoxigenin Fab fragment (diluted:150) for 30 min.

Double Calmodulin–Myosin Immunolabeling in Extracellular Tachyzoites. Cells were fixed with 3% paraformaldehyde in PBS, permeabilized with 0.1% Triton X-100, and CaM was immunolabeled, followed by myosin. Labeling was performed according to the CaM–actin double-labeling protocol.

Confocal Microscopy, Optical Sections, and 3D Reconstruction
Specimens were examined with an MRC 600 (BioRad; Richmond, CA) confocal laser scanning microscope equipped with two lasers (argon and helium–neon) mounted on a Zeiss Axioplan microscope (Zeiss; Thornwood, NY). The Texas red fluorophore was visualized with the 543-nm excitation wavelength of a helium–neon laser and the chromomycin A3 with the 457-nm excitation wavelength of an argon laser. Images were preprocessed with the Comos software package (BioRad) to increase the contrast and to merge the two labelings. Photomicrographs of the double labeling (protein–nucleus) were obtained by direct visualization, which corresponds to the fluorescence emission from one plane of the object. Serial optical sections (around 20) (Z-series) were processed on specimens at 0.2-µm steps. Three-dimensional reconstruction was performed by converting the 2D images of a Z-series into a volume in which we could make virtual cuts of the reconstructed labeling. The 3D reconstruction was performed with Analyze software (Analyze Mayo Bir; CN Software, Southwater, West Sussex, UK) on a Sun Microsystems workstation (Sun Microsystems; Velizy, France). This software makes it possible to move the 3D-reconstructed objects around and to present the most informative viewing angles.


  Results
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Materials and Methods
Results
Discussion
Literature Cited

Localization of Actin, Myosin, Calmodulin, and Myosin Light-chain Kinases of T. gondii
Nuclei stained with chromomycin A3 appeared as green fluorescence. The apical pole of the parasite was at the opposite end from the nucleus.

Actin. Actin was mainly located in the anterior third of the parasite, with a circumferential pattern beneath the parasite membrane complex. The labeling at the apical end appeared to lie under the membrane with a specific V structure (Fig 1A1). The intracellular parasites had similar staining at their apical end (Fig 1A2).



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Figure 1. Immunolocalization of actin, myosin, calmodulin, and MLCK by confocal microscopy. (A1,B1,C1,D1). Extracellular tachyzoites; (A2,B2,C2,D2) tachyzoites in KB host cells. (A) Immunolabeling of actin with a rabbit polyclonal anti-actin antibody. (B) Immunolabeling of myosin with a rabbit polyclonal anti-myosin antibody. (C) Immunolabeling of calmodulin with a mouse monoclonal anti-calmodulin antibody. (D) Immunolabeling of MLCK with a mouse monoclonal anti-MLCK antibody. Proteins revealed by streptavidin–Texas Red appear in red. Nuclei stained with chromomycin A3 appear green (A–D). Controls without primary antibody showed no labeling. There was no change in actin and myosin locations between the extracellular state of the tachyzoites and the intracellular state. Calmodulin was prominent at the apical pole during the extracellular state and became circumferential during the intracellular state of the tachyzoites. MLCK was also delocalized after the internalization of the parasites. Bars = 5 µm.

Myosin. Extracellular T. gondii were diffusely stained with the rabbit polyclonal anti-myosin antibody in the broad anterior third of the parasite, with the greatest intensity at the periphery of the conoid (Fig 1B1). Intracellular parasites (Fig 1B2) had a similar myosin distribution.

Calmodulin. Most of the CaM immunostaining was at the pole opposite the green nucleus, the apical end (Fig 1C1). The CaM in intracellular tachyzoites (Fig 1C2) was always prominent at the apical end, but was also distributed beneath the length of the membrane complex of the parasites (arrowed).

Myosin Light-chain Kinases. The red fluorescence was less intense but essentially at the apical pole of the extracellular parasite; it was redistributed in the cytosol of the intracellular parasites (Fig 1D1 and 1D2).

Examination of the controls (without primary antibody) showed no labeling, except for the nuclei stained with chromomycin A3.

Extracellular parasites stained with antibodies to actin (Fig 2A1) and CaM (Fig 2A2) showed both CaM and actin at the anterior pole of the tachyzoites. The specific V structure seen in the single labeling was not observed, probably because of the treatment used for the double immunolabeling (the rapid extraction before fixation needed to keep CaM in place made it impossible to detect the V structure).



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Figure 2. Double immunolabeling of actin (A1)–calmodulin (A2), actin–calmodulin (A3); double immunolabeling of myosins (B1)-calmodulin (B2), myosins–calmodulin (B3). The yellow fluorescence corresponds to the co-localization of these proteins and appears at the apical extremity of the parasites. Bars = 5 µm.

Fig 2B shows the labeling for myosin (Fig 2B1) and CaM (Fig 2B2), with both proteins at the apical end of the extracellular parasites.

Superimposition of the two images (Fig 2A3 and 2B3) showed a co-localization (actin–calmodulin, myosin–calmodulin) which appeared in yellow fluorescence at the apical extremity of the parasites.

Reconstruction of Optical Sections and Visualization of the Labeling
The optical sections of a Z-series were reconstructed to form the volume of the labeled object. The numbers in Fig 3 give an overall view of the reconstructed labeling (1), and a slice (2) in the volume to show the internal part of the object labeling. Orthosections were prepared (4) from a single optical section (3) according to X and Y axes.



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Figure 3. 3D fluorescence reconstruction of actin, myosin and calmodulin. (A) actin; (B) myosin; (C) calmodulin. (1) Global view of reconstructed labeling. (2) A slice through the volume. (3) A single optical section. (4) Orthosections according to X and Y axes. Diagram of planes of view. Arrows (A1) indicate short "bow" structures of actin on the whole tachyzoite; arrows (A2) indicate the specific V structure of actin at the apical pole on a slice through the volume of the tachyzoite. (A4) Circumferential distribution of actin. (B2,B3) Pronounced labeling of the myosin at the periphery of the conoid. (C2–C4) A strong concentration of CaM in the center of the apical pole. Bars = 1 µm.

The 3D reconstruction of the actin labeling in the extracellular parasites (Fig 3A1) confirmed the apical concentration of this protein, as well as the circumferential actin distribution over the entire tachyzoite with "bow structures" (arrows). The apical end of the parasite appeared to be "hooded" by this cytoskeleton protein. A slice through the object (Fig 3A2) revealed that most of the apical actin labeling was in the periphery, with the specific V structure (arrows), without inner labeling. We conclude that T. gondii actin lies below the membrane. The single optical section (Fig 3A3) and orthosections in the anterior pole along the X and Y axes (Fig 3A4) gave the same circumferential distribution of actin (as a ring) with punctate staining.

The overall 3D visualization of myosin (Fig 3B1) suggested that it was concentrated at the anterior pole of the parasite with a more diffuse pattern. A slice (Fig 3B2) showed differences in the gray scale labeling of intensity in the apical staining, indicating that myosin is distributed along a concentration gradient, with pronounced labeling at the periphery (light gray scale) and weaker labeling in the center (dark gray scale). Orthosections confirmed the diffuse labeling of myosin with a circumferential accumulation (Fig 3B3 and 3B4)

Calmodulin (Fig 3C1) was concentrated in the apical end of the parasite. A slice through the global volume (Fig 3C2) showed that the apical CaM labeling was compact and entire. The resulting CaM concentration gradient showed most CaM in the center, inside the apical end (light gray scale) and less towards the outside. This was supported by the X–Y orthosections showing CaM staining in the shape of an intense full sphere (Fig 3C3 and 3C4).


  Discussion
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Materials and Methods
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The actomyosin system generates biochemical forces for cell movement and cytokinesis. The motility of T. gondii is critically dependent on actin filaments and is driven by a myosin motor. Previous studies using heterologous antisera or actin-specific antibodies have indicated that actin is essentially confined to the apical end of the T. gondii tachyzoite (Cintra and de Souza 1985 ; Endo et al. 1988 ; Yasuda et al. 1988 ). It also occurs faintly throughout the cytoplasm and is more intense at the perimeter (Dobrowolski et al. 1997b ). Three-dimensional reconstruction of labeled tachyzoites showed a discontinuous submembranous distribution of the actin throughout the extracellular parasite, with a pronounced accumulation at the apical end where actin formed a "cap." There is an intense apical V structure of actin. Some investigations of T. gondii actin have given controversial results. Invasion by T. gondii is inhibited by cytochalasins, which disrupt actin filaments (Dobrowolski and Sibley 1996 ). However, no microfilaments have been detected in extra- or intracellular parasites (Russel and Sinden 1981 ; Cintra and de Souza 1985 ). This suggests that T. gondii actin exists primarily in a globular form (Dobrowolski et al. 1997b ). DNase I staining of extracellular tachyzoites revealed G-actin at the apical end, beneath the membrane complex, and in punctate staining scattered throughout the cytoplasm. This is more pronounced in intracellular parasites (Pezzella et al. 1997a , Pezzella et al. 1998 ). An actin depolymerization factor (ADF) located beneath the plasma membrane was not found at the apical end of T. gondii (Allen et al. 1997 ). The depolymerization of actin may be very rapid, and F-actin might be transient. T. gondii may contain actin-binding proteins that sequester monomeric actin and control the assembly of actin filaments, such as toxofilin (Poupel et al. 2000 ). The organization of actin filaments in cells, as well as their changes in response to [Ca2+]i and other intracellular signals, depends on the interactions of various actin-binding proteins. Such proteins may also determine where in the cell myosin can attach to actin filaments. Five myosins have been identified in T. gondii, three around 90 kD (including TgM-A), one at 114 kD (TgM-B), and one at 125 kD (TgM-C). These three unconventional myosins described by Heintzelman and Schwartzman 1997 , Heintzelman and Schwartzman 1999 , have the head domain responsible for generating mechanochemical forces along actin filaments using energy derived from ATP hydrolysis. These myosins have sequences similar to those of Plasmodium falciparum myosin, and they are both concentrated in the apical part of the parasite (Pinder et al. 1998 ). TgM-A is concentrated in the apical pole, TgM-C is present in the juxtanuclear region towards this apical pole, and the other unconventional myosins have not been yet localized (Heintzelman and Schwartzman 1999 ). Our 3D reconstruction of the myosin labeling shows a more diffuse pattern than for actin, with a concentration in the anterior third of the tachyzoite and greater intensity at the periphery of the conoid (confirmed by the orthosections). We also find an actin–myosin network inside the apical pole, with myosin overlapping the distribution of the actin, which is essentially peripheral, with a V form. One of the proteins associated with the cytoskeleton system, MLCK, stimulates the contractile activity of myosin at high [Ca2+] in a CaM-dependent fashion. The primary task of MLCK is to phosphorylate the 20-kD light chain of myosin (shown for a subset of the myosin IIs) and to regulate the actin–myosin crossbridge cycling. According to Heintzelman and Schwartzman 1997 , whereas TgM-A has no light chain binding domain, TgM-B and TgM-C have a single well-conserved IQ motif, that indicates a putative light chain-binding site. Because MLCK is present in the conoid and because KT5926 clearly inhibits both the motility and invasion of T. gondii, then MLCK might be the link between the actomyosin motor and CaM, the universal calcium-dependent regulator, in the tachyzoite. The distribution of CaM reflects its function. CaM resides in the locomotion organelles of the ciliates Tetrahymena (Schultz et al. 1983 ), Paramecium (Momayesi et al. 1986 ), and the flagellates Trypanosoma rhodesiense and T. congolense (Ruben et al. 1984 ). As in P. falciparum merozoites (Scheibel et al. 1987 ), CaM is confined to the apical pole of the T. gondii tachyzoite. This suggests that T. gondii calmodulin is mobilized during parasite invasion.

The CaM inhibitors calmidazolium and trifluoperazine significantly reduce the parasite invasion index in vitro (Pezzella et al. 1997b ) and prompt tachyzoites to undergo shape changes. However, the distribution of CaM is not significantly modified, suggesting that the production of CaM by T. gondii is not affected. Our results also reveal a redistribution of the T. gondii CaM from extracellular to intracellular, CaM being redistributed from its normal apical location into a circumferential pattern. Changes in CaM distribution in other parasitic protozoans are associated with their metabolite state as dense granular secretions, a Ca–CaM-dependent process. This is found in Entamoeba histolytica during invasion (De Lourdes-Munoz et al. 1992 ) and during excystation of Giardia lamblia (Bernal et al. 1998 ). Changes in CaM distribution can be linked to the secretory state in T. gondii. We suggest that CaM regulates the conoid extrusion (a Ca2+-dependent process; Mondragon and Frixione 1996 ) and also the secretion of lytic enzymes from rhoptries (the exocytosis of which is Ca2+-dependent; Lycke et al. 1975 ) such as PLA2 (Saffer et al. 1989 ; Gomez-Marin et al. 1996 ) to fluidize the host cell plasma membrane when the extracellular tachyzoites attach to their host cell. Second, the redistribution of CaM in a circumferential pattern when T. gondii has entered the host cell could be implicated in the regulation of dense granule secretion (like GRA3, a Ca-dependent protein). Third, when T. gondii attaches to its host cell, particularly via microneme secretion (such as MIC2, a transmembrane protein of the TRAP family adhesins; Sibley et al. 1998 ), myosins (TgM-B, TgM-C) might become associated with this protein and might be activated by phosphorylation of the light chains by a CaM-dependent MLCK. KT5926 also reduces the attachment to host cells, particularly by blocking MIC secretion (Dobrowolski et al. 1997a ). Activated myosin could move along the newly formed actin filament. The actin–myosin motor and the free energy of actin polymerization would provide sufficient driving force for conoid extrusion and then for the penetration of the parasite into the host cell. We suggest that a series of signals (Fig 4A) could lead to the activation of the actomyosin system via Ca2+ and calmodulin, and we have developed a model (Fig 4B) of the organization of cytoskeletal actomyosin and calmodulin in the apical part of the parasite when it is attached to its host cell.



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Figure 4. (A) A proposed signaling pathway in the activation of the actin–myosin system. (B) A proposed model of the organization of actin–myosin and calmodulin at the apex of the tachyzoite just before invasion begins. The attachment of T. gondii to its host cell causes myosins (TgM-B, TgM-C) to become associated with MIC2 and to be activated by the phosphorylation of the light chains by a CaM-dependent MLCK. They might then move along the newly formed actin filament. Therefore, the actin–myosin motor could provide force for conoid extrusion, allowing tachyzoite penetration.


  Acknowledgments

We thank Hervé Kaplan and Francis Deligny for technical assistance and Dr Owen Parkes for revising the English text.

Received for publication October 17, 2000; accepted October 18, 2000.


  Literature Cited
Top
Summary
Introduction
Materials and Methods
Results
Discussion
Literature Cited

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