The parasitophorous vacuole membrane surrounding intracellular Toxoplasma gondii functions as a molecular sieve

Location of a constriction in the lumen of a transmembrane pore by targeted covalent attachment of polymer molecules

Few methods exist for obtaining the internal dimensions of transmembrane pores for which 3-D structures are lacking or for showing that structures determined by crystallography reflect the internal dimensions of pores in lipid bilayers. Several approaches, involving polymer penetration and transport, have revealed limiting diameters for various pores. But, in general, these approaches do not indicate the locations of constrictions in the channel lumen. Here, we combine cysteine mutagenesis and chemical modification with sulfhydryl-reactive polymers to locate the constriction in the lumen of the staphylococcal alpha-hemolysin pore, a model protein of known structure. The rates of reaction of each of four polymeric reagents (MePEG-OPSS) of different masses towards individual single cysteine mutants, comprising a set with cysteines distributed over the length of the lumen of the pore, were determined by macroscopic current recording. The rates for the three larger polymers (1.8, 2.5, and 5.0 kD) were normalized with respect to the rates of reaction with a 1.0-kD polymer for each of the seven positions in the lumen. The rate of reaction of the 5.0-kD polymer dropped dramatically at the centrally located Cys-111 residue and positions distal to Cys-111, whether the reagent was applied from the trans or the cis side of the bilayer. This semi-quantitative analysis sufficed to demonstrate that a constriction is located at the midpoint of the pore lumen, as predicted by the crystal structure, and although the constriction allows a 2.5-kD polymer to pass, transport of a 5.0-kD molecule is greatly restricted. In addition, PEG chains gave greater reductions in pore conductance when covalently attached to the narrower regions of the lumen, permitting further definition of the interior of the pore. The procedures described here should be applicable to other pores and to related structures such as the vestibules of ion channels.

Erythrocytic vacuolar rafts induced by malaria parasites

Studies in the past year displaced long-standing dogmas and provided many new molecular insights into how proteins and solutes move between the erythrocyte plasma membrane and the malarial vacuole. Highlights include a demonstration that (1) detergent-resistant membrane (DRM) rafts exist in the red cell membrane and their resident proteins are detected as rafts in the plasmodial vacuole, (2) a voltage-gated channel in the infected red cell membrane mediates uptake of extracellular nutrient solutes, and (3) intraerythrocytic membranes transport a parasite-encoded adherence antigen to the red cell surface.

Ionophore-resistant mutants of Toxoplasma gondii reveal host cell permeabilization as an early event in egress

Toxoplasma gondii is an obligate intracellular pathogen within the phylum Apicomplexa. Invasion and egress by this protozoan parasite are rapid events that are dependent upon parasite motility and appear to be directed by fluctuations in intracellular [Ca(2+)]. Treatment of infected host cells with the calcium ionophore A23187 causes the parasites to undergo rapid egress in a process termed ionophore-induced egress (IIE). In contrast, when extracellular parasites are exposed to this ionophore, they quickly lose infectivity (termed ionophore-induced death [IID]). From among several Iie(-) mutants described here, two were identified that differ in several attributes, most notably in their resistance to IID. The association between the Iie(-) and Iid(-) phenotypes is supported by the observation that two-thirds of mutants selected as Iid(-) are also Iie(-). Characterization of three distinct classes of IIE and IID mutants revealed that the Iie(-) phenotype is due to a defect in a parasite-dependent activity that normally causes infected host cells to be permeabilized just prior to egress. Iie(-) parasites underwent rapid egress when infected cells were artificially permeabilized by a mild saponin treatment, confirming that this step is deficient in the Iie(-) mutants. A model is proposed that includes host cell permeabilization as a critical part of the signaling pathway leading to parasite egress. The fact that Iie(-) mutants are also defective in early stages of the lytic cycle indicates some commonality between these normal processes and IIE.

Proteolytic activation of leishporin: evidence that Leishmania amazonensis and Leishmania guyanensis have distinct inactive forms

Crude extracts of Leishmania amazonensis, but not of L. guyanensis, are lytic to erythrocytes and nucleated cells, including macrophages. L. amazonensis-mediated lysis is caused by a membrane-associated pore-forming protein, named a-leishporin. Here we show that L. amazonensis, but not L. guyanensis, promastigote extracts increase their hemolytic activity when kept at 4 degrees C for a few days or at 37 degrees C for a few hours. We show that the activation in the extracts is mediated by a cytosolic serine-protease. Although L. guyanensis extracts are hemolytically inactive and unable to generate hemolytic activity, their membrane fraction becomes hemolytic in the presence of the cytosolic fraction of L. amazonensis, also by the action of a serine-protease. This suggests that L. guyanensis contains a potential lytic molecule, named here g-leishporin. The cytosolic fraction of L. guyanensis is unable to activate either a- or g-leishporin, indicating that this species does not possess the protease(s) that activate(s) the cytolysin. Trypsin, chymotrypsin, collagenase, Pronase and proteinase K, are also effective in activating a-leishporin but not g-leishporin. This suggests that the inactive forms of a-leishporin and g-leishporin are distinct in structure and/or are activated by different mechanisms. We are considering two hypotheses for the activation of leishporins: (1) proteolysis of an inactive precursor and (2) dissociation and/or proteolytic degradation of an inhibitory oligopeptide. The present data and preliminary results argue for the second hypothesis. We speculate that leishporin could be activated in the protease-rich, low pH, and dissociating environment of parasitophorous vacuole contributing for the release of the parasites from the macrophage.

Lytic cycle of Toxoplasma gondii

Toxoplasma gondii is an obligate intracellular pathogen within the phylum Apicomplexa. This protozoan parasite is one of the most widespread, with a broad host range including many birds and mammals and a geographic range that is nearly worldwide. While infection of healthy adults is usually relatively mild, serious disease can result in utero or when the host is immunocompromised. This sophisticated eukaryote has many specialized features that make it well suited to its intracellular lifestyle. In this review, we describe the current knowledge of how the asexual tachyzoite stage of Toxoplasma attaches to, invades, replicates in, and exits the host cell. Since this process is closely analogous to the way in which viruses reproduce, we refer to it as the Toxoplasma "lytic cycle."

Coinfection of fibroblasts with Coxiella burnetti and Toxoplasma gondii: to each their own

Intracellular pathogens have evolved distinct strategies to subvert host cell defenses. At diametrically opposed ends of the spectrum with regard to the host endosomal/lysosomal defenses are the obligate intracellular protozoan Toxoplasma gondii and the bacterium Coxiella burnetti. While the intracellular replication of T. gondii requires complete avoidance of the host endocytic cascade, C. burnetti actively subverts it. This results in these organisms establishing and growing in very different vacuolar compartments. In this study we examined the potential interaction between these distinct compartments following coinfection of mammalian fibroblasts. When present within the same cell, these organisms exhibit minimal interaction with each other. Colocalization of T. gondii and C. burnetti within the same vacuole occurs at a low frequency in doubly infected cells. In such instances only one of the organisms appears to be replication competent, emphasizing the different requirements for survival and/or intracellular growth. The potential basis for both the lack of interaction between these distinct pathogen-containing compartments, and the mechanisms to address their low frequency of colocalization are discussed in the context of our understanding of the biology of the organisms and membrane traffic in eukaryotic cells.

Toxoplasma gondii exploits host low-density lipoprotein receptor-mediated endocytosis for cholesterol acquisition

The obligate intracellular protozoan Toxoplasma gondii resides within a specialized parasitophorous vacuole (PV), isolated from host vesicular traffic. In this study, the origin of parasite cholesterol was investigated. T. gondii cannot synthesize sterols via the mevalonate pathway. Host cholesterol biosynthesis remains unchanged after infection and a blockade in host de novo sterol biosynthesis does not affect parasite growth. However, simultaneous limitation of exogenous and endogenous sources of cholesterol from the host cell strongly reduces parasite replication and parasite growth is stimulated by exogenously supplied cholesterol. Intracellular parasites acquire host cholesterol that is endocytosed by the low-density lipoprotein (LDL) pathway, a process that is specifically increased in infected cells. Interference with LDL endocytosis, with lysosomal degradation of LDL, or with cholesterol translocation from lysosomes blocks cholesterol delivery to the PV and significantly reduces parasite replication. Similarly, incubation of T. gondii in mutant cells defective in mobilization of cholesterol from lysosomes leads to a decrease of parasite cholesterol content and proliferation. This cholesterol trafficking to the PV is independent of the pathways involving the host Golgi or endoplasmic reticulum. Despite being segregated from the endocytic machinery of the host cell, the T. gondii vacuole actively accumulates LDL-derived cholesterol that has transited through host lysosomes.

Microtubules, but not actin filaments, drive daughter cell budding and cell division in Toxoplasma gondii

We have used drugs to examine the role(s) of the actin and microtubule cytoskeletons in the intracellular growth and replication of the intracellular protozoan parasite, Toxoplasma gondii. By using a 5 minute infection period and adding the drugs shortly after entry we can treat parasites at the start of intracellular development and 6–8 hours prior to the onset of daughter cell budding. Using this approach we found, somewhat surprisingly, that reagents that perturb the actin cytoskeleton in different ways (cytochalasin D, latrunculin A and jasplakinolide) had little effect on parasite replication although they had the expected effects on the host cells. These actin inhibitors did, however, disrupt the orderly turnover of the mother cell organelles leading to the formation of a large residual body at the posterior end of each pair of budding parasites. Treating established parasite cultures with the actin inhibitors blocked ionophore-induced egression of tachyzoites from the host cells, demonstrating that intracellular parasites were susceptible to the effects of these inhibitors. In contrast, the anti-microtubule drugs oryzalin and taxol, and to a much lesser extent nocodazole, which affect microtubule dynamics in different ways, blocked parasite replication by disrupting the normal assembly of the apical conoid and the microtubule inner membrane complex (IMC) in the budding daughter parasites. Centrosome replication and assembly of intranuclear spindles, however, occurred normally. Thus, daughter cell budding per se is dependent primarily on the parasite microtubule system and does not require a dynamic actin cytoskeleton, although disruption of actin dynamics causes problems in the turnover of parasite organelles.

Transport and trafficking: Toxoplasma as a model for Plasmodium

Like Plasmodium, the protozoan parasite Toxoplasma gondii is a member of the phylum Apicomplexa, and an obligate intracellular pathogen. Unlike Plasmodium, however, Toxoplasma is highly amenable to experimental manipulation in the laboratory. The development of molecular transformation protocols for T. gondii has provided both scientific precedent and practical selectable markers for Plasmodium. Beyond the feasibility of molecular biological experimentation now possible in both systems, the high frequency of stable transformation in Toxoplasma allows this parasite to be used for molecular genetic analysis. The ability to control homologous vs. non-homologous recombination in T. gondii permits gene knockouts/allelic replacements at previously cloned loci, and saturation insertional mutagenesis of the entire parasite genome (and cloning of the tagged loci). T. gondii also exhibits unusual ultrastructural clarity, facilitating cell biological analysis. The accessibility of Toxoplasma as an experimental system allows this parasite to be used as a surrogate for asking many questions that cannot easily be addressed in Plasmodium itself. T. gondii also serves as a model system for genetic exploration of parasite biology and host-parasite interactions. Success stories include: biochemical analysis of antifolate resistance mechanisms; pharmacological studies on the mechanisms of macrolide activity; genetic identification of nucleobase/nucleoside transporters and metabolic pathways; and cell biological characterization of the apicomplexan plastid. As with any model system, not all questions of interest to malariologists can be addressed in Toxoplasma; differentiating between sensible and foolish questions requires familiarity with the biological similarities and differences of these systems.

Redirection of host vesicle trafficking pathways by intracellular parasites

Bacterial and protozoon intracellular parasites have evolved diverse mechanisms for evasion of host cellular defenses associated with adaptations for survival in distinct intracellular compartments. As the reagents identifying discrete steps in vesicle maturation and trafficking have become increasingly available, it has become clear that the vacuoles occupied by intracellular parasites are much more diverse than had been previously appreciated. Many parasites induce selective fusion competence with the vacuoles they occupy, without affecting vesicular trafficking elsewhere in the cell. A likely means of controlling vesicular interactions is modification of the parasitophorous vacuole membrane by the insertion of parasite-specific proteins. A rapidly expanding class of bacterial proteins that modify the vacuolar membrane are the chlamydial inclusion membrane proteins. Although the functions of most of these proteins remain to be defined, the majority are expressed early in the infectious process, suggesting that modification of the vacuole is critical to the outcome of the host-parasite interaction.

Cell invasion by un-palatable parasites

While some intracellular pathogens invade and replicate exclusively in phagocytic host cells, others have evolved mechanisms to stimulate their uptake by cells not equipped with a well-developed phagocytic machinery. A common mechanism utilized by bacteria involves the induction of macropinocytosis, or of other F-actin-driven processes which result in engulfment of the pathogen through formation of a plasma membrane-derived vacuole. Interestingly, this type of "induced phagocytosis" mechanism does not appear to be utilized by protozoan parasites, which are significantly larger than bacteria in size (about 5-10 microns in average length). Intracellular protozoa either restrict themselves to infecting "professional" phagocytes (one example is the trypanosomatid Leishmania), or utilize highly unusual mechanisms for gaining access to the intracellular environment. Here we discuss what has been revealed in recent years about the remarkable cell invasion strategies of two highly successful intracellular parasites: Toxoplasma gondii and Trypanosoma cruzi. Toxoplasma utilizes a distinct form of actin/myosin-dependent gliding motility to propel itself into mammalian cells, while T. cruzi invades by subverting a Ca(2+)-regulated lysosomal exocytic pathway.

Mycobacterial infection of macrophages results in membrane-permeable phagosomes

Cell-mediated immunity is critical for host resistance to tuberculosis. T lymphocytes recognizing antigens presented by the major histocompatibility complex (MHC) class I and class II molecules have been found to be necessary for control of mycobacterial infection. Mice genetically deficient in the generation of MHC class I and class Ia responses are susceptible to mycobacterial infection. Although soluble protein antigens are generally presented by macrophages to T cells through MHC class II molecules, macrophages infected with Mycobacterium tuberculosis or bacille Calmette-Guerin have been shown to facilitate presentation of ovalbumin through the MHC class I presentation pathway via a TAP-dependent mechanism. How mycobacteria, thought to reside within membrane-bound vacuoles, facilitate communication with the cytoplasm and enable MHC class I presentation presents a paradox. By using confocal microscopy to study the localization of fluorescent-tagged dextrans of varying size microinjected intracytoplasmically into macrophages infected with bacille Calmette-Guerin expressing the green fluorescent protein, molecules as large as 70 kilodaltons were shown to gain access to the mycobacterial phagosome. Possible biological consequences of the permeabilization of vacuolar membranes by mycobacteria would be pathogen access to host cell nutrients within the cytoplasm, perhaps contributing to bacterial pathogenesis, and access of microbial antigens to the MHC class I presentation pathway, contributing to host protective immune responses.

The adenosine transporter of Toxoplasma gondii. Identification by insertional mutagenesis, cloning, and recombinant expression

Purine transport into the protozoan parasite Toxoplasma gondii plays an indispensable nutritional function for this pathogen. To facilitate genetic and biochemical characterization of the adenosine transporter of the parasite, T. gondii tachyzoites were transfected with an insertional mutagenesis vector, and clonal mutants were selected for resistance to the cytotoxic adenosine analog adenine arabinoside (Ara-A). Whereas some Ara-A-resistant clones exhibited disruption of the adenosine kinase (AK) locus, others displayed normal AK activity, suggesting that a second locus had been tagged by the insertional mutagenesis plasmid. These Ara-A(r) AK+ mutants displayed reduced adenosine uptake capability, implying a defect in adenosine transport. Sequences flanking the transgene integration point in one mutant were rescued from a genomic library of Ara-A(r) AK+ DNA, and Southern blot analysis revealed that all Ara-A(r) AK+ mutants were disrupted at the same locus. Probes derived from this locus, designated TgAT, were employed to isolate genomic and cDNA clones from wild-type libraries. Conceptual translation of the TgAT cDNA open reading frame predicts a 462 amino acid protein containing 11 transmembrane domains, a primary structure and membrane topology similar to members of the mammalian equilibrative nucleoside transporter family. Expression of TgAT cRNA in Xenopus laevis oocytes increased adenosine uptake capacity in a saturable manner, with an apparent K(m) value of 114 microM. Uptake was inhibited by various nucleosides, nucleoside analogs, hypoxanthine, guanine, and dipyridamole. The combination of genetic and biochemical studies demonstrates that TgAT is the sole functional adenosine transporter in T. gondii and a rational target for therapeutic intervention.

Experimental approaches to understanding virulence in toxoplasmosis

Toxoplasma gondii is a widespread protozoan parasite that causes severe disease only in immunocompromised individuals. Equipped with excellent animal models and relatively advanced systems for genetics, T. gondii provides an excellent system for understanding pathogenesis. Resistance to toxoplasmosis is governed by rapid innate and adaptive immunity that is characterized by a Th1 type profile of cytokines. Despite this effective response, acute infections can cause considerable damage and the parasite effectively establishes a long-term chronic infection that predisposes the host to reactivation and provides a means of eventual transmission. This complex interaction is brought about by the differentiation of the parasite from a rapidly replicating, lytic form (known as the tachyzoite) to a slow-growing form (known as the bradyzoite) that gives rise to chronic infection. The population structure of T. gondii is remarkably clonal, consisting of just three predominant lineages that are geographically widespread and found in a variety of hosts including humans. Acute virulence is strongly associated with the type I genotype which exhibits an enhanced replication rate in vitro and higher tissue burdens in vivo relative to non-virulent lineages. The pathology associated with acute infection appears to be due to excessive production of acute inflammatory mediators, suggesting that disease is partly due to over-response of the host immune system. A combination of refined animal models and newly developed genetic tools for establishing the relative contribution of genes to pathogenesis will enable a comprehensive analysis of the molecular basis of virulence in toxoplasmosis.

Controlling the maturation of pathogen-containing vacuoles: a matter of life and death

Once considered to be contained, infectious diseases of bacterial origin are now making a comeback. A lack of innovative therapies and the appearance of drug-resistant pathogens are becoming increasingly serious problems. A better understanding of pathogen-host interactions at the cellular and molecular levels is necessary to define new targets in our fight against microorganisms. In the past few years, the merging of cell biology and microbiology has started to yield critical and often surprising new information on the interactions that occur between various pathogens and their mammalian host cells. Here we focus on the intracellular routing of vacuoles containing microorganisms, as well as on the bacterial effectors and their host-cell targets that control vacuole maturation. We also describe new approaches for isolating microorganism-containing vacuoles and analysing their molecular composition, which will help researchers to define the molecules and mechanisms governing vacuole biogenesis.

Signaling during the invasion of host cells by Toxoplasma gondii

Invasion of host cells is essential for the pathogenicity of Toxoplasma gondii. This review examines the signal transduction pathways that lead to the internalization of T. gondii. We demonstrate that extra- and intracellular Ca(2+) mobilization, Ca(2+)-calmodulin complex and phospholipase A(2) activities are required for T. gondii entry. T. gondii also causes the activation of mitogen-activated protein kinase in infected cells and modifies its ionic environment during its intracellular state. Thus, many of the signaling systems found in other eukaryotes are operative in Toxoplasma invasion.

Cytokines, nitric oxide, heat shock proteins and virulence in Toxoplasma

Elucidating the factors that play important roles in the expression of virulence by parasites is crucial to understanding disease pathogenesis and to developing control strategies rationally. Here, Kate Miller, Nick Smith and Alan Johnson, using Toxoplasma gondii as a model, argue that the interactions between the immune system and 70 kDa heat shock proteins of apicomplexan parasites profoundly influence parasite virulence.

Metabolism and selective toxicity of 6-nitrobenzylthioinosine in Toxoplasma gondii

The purine nucleoside analogue NBMPR (nitrobenzylthioinosine or 6-[(4-nitrobenzyl)thio]-9-beta-D-ribofuranosylpurine) was selectively phosphorylated to its nucleoside 5'-monophosphate by Toxoplasma gondii but not mammalian adenosine kinase (EC 2.7.1.20). NBMPR was also cleaved in toxoplasma to its nucleobase, nitrobenzylmercaptopurine. However, nitrobenzylmercaptopurine was not a substrate for either adenosine kinase or hypoxanthine-guanine-xanthine phosphoribosyltransferase (EC 2.4.2.8). Because of this unique and previously unknown metabolism of NBMPR by the parasite, the effect of NBMPR as an antitoxoplasmic agent was tested. NBMPR killed T. gondii grown in human fibroblasts in a dose-dependent manner, with a 50% inhibitory concentration of approximately 10 microM and without apparent toxicity to host cells. Doses of up to 100 microM had no significant toxic effect on uninfected host cells. The promising antitoxoplasmic effect of NBMPR led to the testing of other 6-substituted 9-beta-D-ribofuranosylpurines, which were shown to be good ligands of the parasite adenosine kinase (M. H. Iltzsch, S. S. Uber, K. O. Tankersley, and M. H. el Kouni, Biochem. Pharmacol. 49:1501-1512, 1995), as antitoxoplasmic agents. Among the analogues tested, 6-benzylthioinosine, p-nitrobenzyl-6-selenopurine riboside, N(6)-(p-azidobenzyl)adenosine, and N(6)-(p-nitrobenzyl)adenosine, like NBMPR, were selectively toxic to parasite-infected cells. Thus, it appears that the unique characteristics of purine metabolism in T. gondii render certain 6-substituted 9-beta-D-ribofuranosylpurines promising antitoxoplasmic drugs.

Differential membrane targeting of the secretory proteins GRA4 and GRA6 within the parasitophorous vacuole formed by Toxoplasma gondii

Following secretion into the parasitophorous vacuole, dense granule proteins, referred to as GRA proteins, are targeted to different locations including a complex of tubular membranes that are connected with the vacuolar membrane. To further define the formation of this intravacuolar network, we have investigated the secretion, trafficking and membrane association of GRA4 and GRA6 within the parasitophorous vacuole. In extracellular parasites, GRA4 and GRA6 were found exclusively in dense secretory granules where they were packaged primarily as soluble proteins. Following release into the vacuole, GRA6 was rapidly translocated to the posterior end of the parasite where, like previously reported for GRA2, it bound to a cluster of multi-lamellar vesicles that give rise to the network. In contrast, GRA4 was distributed throughout the lumen of the vacuole and only later became associated with the mature network that is found dispersed throughout the vacuole. Cell fractionation and treatment with denaturing agents established that the association of GRA4 with the network membranes was mediated by strong protein-protein interactions. In contrast, GRA6 was predominantly influenced by hydrophobic interactions, and a phosphorylated form of this protein present within the vacuole showed increased association with the network membranes. Cross-linking studies established that GRA4 and GRA6 specifically interact with GRA2 to form a multimeric complex that is stably associated with the intravacuolar network. Formation of this protein complex, which is based on both protein-protein and hydrophobic interactions, may participate in nutrient or protein transport within the vacuole.

Identification and characterization of a Chlamydia trachomatis early operon encoding four novel inclusion membrane proteins

Chlamydia trachomatis is a bacterial obligate intracellular parasite that replicates within a vacuole, termed an inclusion, that does not fuse with lysosomes. Within 2 h after internalization, the C. trachomatis inclusion ceases to interact with the endocytic pathway and, instead, becomes fusogenic with exocytic vesicles containing exogenously synthesized NBD-sphingomyelin. Both fusion of exocytic vesicles and long-term avoidance of lysosomal fusion require early chlamydial gene expression. Modification of the chlamydial inclusion probably occurs through the expression and insertion of chlamydial protein(s) into the inclusion membrane. To identify candidate inclusion membrane proteins, antisera were raised against a total membrane fraction purified from C. trachomatis-infected HeLa cells. By indirect immunofluorescence, this antisera recognized the inclusion membrane and, by immunoblot analysis, recognized three chlamydial-specific antigens of approximate molecular weights 15, 18 and 21 kDa. IncG, encoding an 18 kDa and 21 kDa doublet chlamydial antigen, was identified by screening a C. trachomatis, serovar L2, genomic expression library. Three additional genes, incD, incE and incF, were co-transcribed with incG. Monospecific antisera against each of the four genes of this operon demonstrated that the gene products were localized to the chlamydial inclusion membrane. Immediately downstream from the operon containing incD-G was the C. trachomatis homologue of incA. Like IncD, E, F and G, C. trachomatis IncA is also localized to the inclusion membrane. Reverse transcriptase-polymerase chain reaction (RT-PCR) analysis demonstrated that IncD-G, but not incA, are transcribed within the first 2 h after internalization, making them candidates for chlamydial factors required for the modification of the nascent chlamydial inclusion.

Intracellular life

Intracellular parasites and endosymbionts are present in almost all forms of life, including bacteria. Some eukaryotic organelles are believed to be derived from ancestral endosymbionts. Parasites and symbionts show several adaptations to intracellular life. A comparative analysis of their biology suggests some general considerations involved in adapting to intracellular life and reveals a number of independently achieved strategies for the exploitation of an intracellular habitat. Symbioses mainly based on a form of syntrophy may have led to the establishment of unique physiological systems. Generally, a symbiont can be considered to be an attenuated pathogen. The combination of morphological studies, molecular phylogenetic analyses, and palaeobiological data has led to considerable improvement in the understanding of intracellular life evolution. Comparing host and symbiont phylogenies could lead to an explanation of the evolutionary history of symbiosis. These studies also provide strong evidences for the endosymbiogenesis of the eukaryotic cell. Indeed, an eubacterial origin for mitochondria and plastids is well accepted and is suggested for other organelles. The expansion of intracellular living associations is presented, with a particular emphasis on peculiar aspects and/or recent data, providing a global evaluation.

Transmembrane insertion of the Toxoplasma gondii GRA5 protein occurs after soluble secretion into the host cell

The intracellular parasite Toxoplasma gondii resides within a specialized compartment, the parasitophorous vacuole (PV), that resists fusion with host cell endocytic and lysosomal compartments. The PV is extensively modified by secretion of parasite proteins, including the dense granule protein GRA5 that is specifically targeted to the delimiting membrane of the PV (PVM). We show here that GRA5 is present both in a soluble form and in hydrophobic aggregates. GRA5 is secreted as a soluble form into the PV after which it becomes stably associated with the PVM. Topological studies demonstrated that GRA5 was inserted into the PVM as a transmembrane protein with its N-terminal domain extending into the cytoplasm and its C terminus in the vacuole lumen. Deletion of 8 of the 18 hydrophobic amino acids of the single predicted transmembrane domain resulted in the failure of GRA5 to associate with the PVM; yet it remained correctly packaged in the dense granules and was secreted as a soluble protein into the PV. Collectively, these studies demonstrate that the secretory pathway in Toxoplasma is unusual in two regards; it allows soluble export of proteins containing typical transmembrane domains and provides a mechanism for their insertion into a host cell membrane after secretion from the parasite.

The expression and distribution of dense granule proteins in the enteric (Coccidian) forms of Toxoplasma gondii in the small intestine of the cat

The expression and distribution of dense granule proteins in the enteric (coccidian) forms of Toxoplasma gondii in the small intestine of the cat. Experimental Parasitology 91, 203-211. The expression and location of the dense granule proteins (GRA1-6 and NTPase) in the merozoite and during asexual and sexual development of Toxoplasma gondii in the small intestine of the cat (definitive host) was examined by immuno-light and electron microscopy. This was compared with that of tachyzoites and bradyzoites present in the intermediate host. It was found that the merozoite contained the characteristic apical organelles plus a few large dense granules. By immunocytochemistry, dense granules in merozoites were negative for GRA proteins 1 to 6 in contrast to both tachyzoites and bradyzoites in which dense granules were positive for all six proteins. The GRA proteins were associated with the parasitophorous vacuole (PV) during tachyzoite and bradyzoite development but were absent from the PV of the enteric stages. However, the merozoite dense granules were positive for NTPase, which was similar to the tachyzoite while this antigen was down regulated in the bradyzoite. The apparent release of the NTPases into the PV formed by merozoites was also similar to that described for the tachyzoite, possibly reflecting the relative metabolic activity of the various stages. This study shows that the majority of GRA proteins have a similar stage-specific expression, which is independent of NTPases expression. These observations are consistent with T. gondii having a different host parasite relationship in the enteric forms, which does not involve the GRA proteins 1-6.

Parasitophorous vacuoles of Leishmania mexicana acquire macromolecules from the host cell cytosol via two independent routes

The intracellular parasite Leishmania survives and proliferates in host macrophages. In this study we show that parasitophorous vacuoles of L. mexicana gain access to cytosolic material via two different routes. (1) Small anionic molecules such as Lucifer Yellow are rapidly transported into the vacuoles by an active transport mechanism that is sensitive to inhibitors of the host cell's organic anion transporter. (2) Larger molecules such as fluorescent dextrans introduced into the host cell cytosol are also delivered to parasitophorous vacuoles. This transport is slower and sensitive to modulators of autophagy. Infected macrophages were examined by two novel assays to visualize and quantify this process. Immunoelectron microscopy of cells loaded with digoxigenin-dextran revealed label in multivesicular endosomes, which appeared to fuse with parasitophorous vacuoles. The inner membranes of the multivesicular vesicles label strongly with antibodies against lysobisphosphatidic acid, suggesting that they represent a point of confluence between the endosomal and autophagosomal pathways. Although the rate of autophagous transfer was comparable in infected and uninfected cells, infected cells retained hydrolyzed cysteine proteinase substrate to a greater degree. These data suggest that L. mexicana-containing vacuoles have access to potential nutrients in the host cell cytosol via at least two independent mechanisms.

Targeted reduction of nucleoside triphosphate hydrolase by antisense RNA inhibits Toxoplasma gondii proliferation

Nucleoside triphosphate hydrolase (NTPase) is a very abundant protein secreted by the obligate intracellular parasite Toxoplasma gondii shortly after invasion of the host cell. When activated by dithiols, NTPase is one of the most potent apyrases known to date, but its physiological function remains unknown. The genes encoding NTPase have been cloned (Bermudes, D., Peck, K. R., Afifi-Afifi, M., Beckers, C. J. M., and Joiner, K. A. (1994) J. Biol. Chem. 269, 29252-29260). We have recently shown that the enzyme is tightly controlled within the vacuolar space and may influence parasite exit from the host cell (Silverman, J. A., Qi, H., Riehl, A., Beckers, C., Nakaar, V., and Joiner, K. A (1998) J. Biol. Chem. 273, 12352-12359). In the present study, we have generated an antisense NTP RNA construct in which the 3'-untranslated region is replaced by a hammerhead ribozyme. The constitutive synthesis of the chimeric antisense RNA-ribozyme construct in parasites that were stably transfected with this construct resulted in a dramatic reduction in the steady-state levels of NTPase. This inhibition was accompanied by a decrease in the capacity of the parasites to replicate. The reduction in parasite proliferation was due to a specific effect of antisense NTP RNA, since a drastic inhibition of hypoxanthine-xanthine-guanine phosphoribosyl transferase (HXGPRT) expression by a chimeric antisense HXGPRT RNA-ribozyme construct did not alter NTPase expression nor compromise parasite replication. These data implicate NTPase in an essential parasite function and suggest that NTPase may have more than one function in vivo. These results also establish that it is possible to study gene function in apicomplexan parasites using antisense RNA coupled to ribozymes.

Zoite migration during infection: parasite adaptation to host defences

The apicomplexan parasite Eimeria tenella has evolved a number of strategies for migration into different compartments of the intestinal tissue during its life cycle. These migration events are associated intricately with pathogenesis and are currently of great interest to coccidiologists. Using evidence from in vivo studies and recent work on the dynamics of gut cell turnover, Peter Daszak suggests that E. tenella zoite migration might be viewed as parasite evolutionary adaptation to evade the host innate immune responses (resistance) and deal with the complex, dynamic nature of gut epithelial tissue.

Cytotoxic T lymphocytes in resistance to tuberculosis

Recent experimental evidence has suggested T cells recognizing antigens in the context of both classical MHC class I and nonclassical class I-like molecules contribute to protective responses against Mycobacterium tuberculosis (MTB) infection. Our aims were to characterize both types of T cells, and to explore the basis of communication between the tubercle bacilli and the MHC class I pathway of the host macrophage. A model system was developed using exogenously added ovalbumin as a surrogate antigen to study presentation by MTB-infected macrophages. Viable, virulent MTB and closely related mycobacterial species facilitated the presentation of ovalbumin on MHC class I molecules to CD8+ cytolytic T cells that was dependent upon the cytosolic transport of peptides, implying communication between the MTB phagosome and the host cell cytoplasm. MHC class I presentation of soluble antigens was mimicked by Listeria monocytogenes, which grows within the host cell cytoplasm, as well as its purified hemolysin. We have also characterized T cells that recognize nonpeptide MTB antigens presented by CD1 molecules. CD1-restricted T cells demonstrated to lyse macrophages infected with virulent MTB were divided into distinct subsets based on surface phenotype (CD4-CD8- versus CD8-) and cytotoxicity mechanism (Fas receptor-mediated versus granule exocytosis). A functional consequence of these two mechanisms was observed that while both subsets lysed infected macrophages, only those T cells utilizing the granule exocytosis pathway were able to reduce viability of intracellular MTB.

Basis for substrate specificity of the Toxoplasma gondii nucleoside triphosphate hydrolase

The Toxoplasma gondii nucleoside triphosphate hydrolase is the most active E-type ATPase yet identified, and was the first member of this new gene family to be cloned (Bermudes D, Peck KR, Afifi-Afifi M, Beckers CJM, Joiner KA. J Biol Chem 1994;269:29252-29260. Previous work also identified two isoforms of the enzyme in the virulent RH strain, and demonstrated that internal fragments of the genes encoding these isoforms were found differentially in virulent versus avirulent organisms (Asai T, Miura S, Sibley D, Okabayashi H, Tsutomu T, J Biol Chem 1995;270:11391-11397). We now show that the NTPase 1 isoform is expressed in avirulent strains, whereas virulent strains express both the NTPase 1 and NTPase 3 isoforms. The avirulent PLK strain lacks the gene for NTPase 3, explaining the absence of expression. Despite the fact that NTPase 1 and NTPase 3 are 97% identical at the amino acid level, recombinant NTPase 1 is a true apyrase, whereas recombinant NTPase 3 cleaves predominantly nucleotide triphosphates. Furthermore, native and recombinant NTPase 3 but neither native nor recombinant NTPase 1 bind to ATP-agarose, further distinguishing the two isoforms. Using chimeras between the NTP1 and NTP3 genes, we show that a block of twelve residues at the C-terminus dictates substrate specificity. These residues lie outside the regions conserved among other E-ATPases, and therefore provide new insight into substrate recognition by this class of enzymes.

Regulation and function of T-cell-mediated immunity during Toxoplasma gondii infection

The intracellular protozoan Toxoplasma gondii is a widespread opportunistic parasite of humans and animals. Normally, T. gondii establishes itself within brain and skeletal muscle tissues, persisting for the life of the host. Initiating and sustaining strong T-cell-mediated immunity is crucial in preventing the emergence of T. gondii as a serious pathogen. The parasite induces high levels of gamma interferon (IFN-gamma) during initial infection as a result of early T-cell as well as natural killer (NK) cell activation. Induction of interleukin-12 by macrophages is a major mechanism driving early IFN-gamma synthesis. The latter cytokine, in addition to promoting the differentiation of Th1 effectors, is important in macrophage activation and acquisition of microbicidal functions, such as nitric oxide release. During chronic infection, parasite-specific T lymphocytes release high levels of IFN-gamma, which is required to prevent cyst reactivation. T-cell-mediated cytolytic activity against infected cells, while easily demonstrable, plays a secondary role to inflammatory cytokine production. While part of the clinical manifestations of toxoplasmosis results from direct tissue destruction by the parasite, inflammatory cytokine-mediated immunopathologic changes may also contribute to disease progression.

Paromomycin and geneticin inhibit intracellular Cryptosporidium parvum without trafficking through the host cell cytoplasm: implications for drug delivery

Cryptosporidium parvum, which causes intractable diarrhea and lethal wasting in people with AIDS, occupies an unusual intracellular but extracytoplasmic niche. No reliable therapy for cryptosporidiosis exists, though the aminoglycoside paromomycin is somewhat effective. We report that paromomycin and the related compound geneticin manifest their major in vitro anti-C. parvum activity against intracellular parasites via a mechanism that does not require drug trafficking through the host cell cytoplasm. We used both normal and transformed aminoglycoside-resistant Caco-2 or MDBK cells in these studies. Timed-exposure experiments demonstrated that these drugs inhibit intracellular but not extracellular parasites. Apical but not basolateral exposure of infected cells to these drugs led to very significant parasite inhibition, indicating an apical topological restriction of action. We estimated intracytoplasmic concentrations of paromomycin, using an intracellular bacterial killing assay, and found that C. parvum infection did not lead to increased paromomycin concentrations compared to those in uninfected cells. Global [3H]paromomycin uptake by Caco-2 cells was approximately 200-fold higher than the estimated intracytoplasmic paromomycin concentration, suggestive of host cell vesicular uptake and concentration (as has been reported with other cell lines). However, preinfection exposure of Caco-2 cells to paromomycin did not result in subsequent inhibition of parasite development, indicating that if exogenous paromomycin enters the infected host cell vesicular compartment, it does not effectively communicate with the parasite. Thus, the apical membranes overlying the parasite and parasitophorous vacuole may be the unsuspected major route of entry for paromomycin and may be of importance in the design and discovery of novel drug therapies for the otherwise untreatable C. parvum.

The amphipathic alpha helices of the toxoplasma protein GRA2 mediate post-secretory membrane association

The Toxoplasma gondii protein GRA2 is secreted into the parasite-containing vacuole where it is rapidly and specifically targeted to a network of membranous tubules that connect with the vacuolar membrane. To examine the molecular basis of this association, we expressed an HA9 epitope-tagged form of GRA2 by stable transformation of Toxoplasma. GRA2-HA9 was correctly packaged inside the dense granules, secreted into the PV and targeted to the network, as shown by immunoelectron microscopy, immunofluorescence and cell fractionation. Expression of deletion mutants of GRA2-HA9 lacking either of two amphipathic alpha helices resulted in the production and secretion of soluble proteins which were unable to stably associate with the network. A mutant in which the amino acids of the first alpha helix were rearranged to a non-amphipathic pattern localized correctly to the network but failed to remained stably associated with the membrane. Collectively, these results demonstrate that targeting and membrane association occur by separate mechanisms and that the combination of both alpha helices is essential for stable localization of GRA2 to the network.

Apical organelles and host-cell invasion by Apicomplexa

Host-cell invasion by apicomplexan parasites involves the successive exocytosis of three different secretory organelles; namely micronemes, rhoptries and dense granules. The findings of recent studies have extended the structural homologies of each set of organelles between most members of the phylum and suggest shared functions of each set. Micronemes are apparently used for host-cell recognition, binding, and possibly motility; rhoptries for parasitophorous vacuole formation; and dense granules for remodeling the vacuole into a metabolically active compartment. In addition, gene cloning and sequencing have demonstrated conserved domains, which are likely to serve similar functions in the invasion process. This is especially true for microneme proteins containing thrombospondin-like domains, which are likely to be involved in binding to sulphated glycoconjugates. One such protein was recently shown to be required for the motility of Plasmodium sporozoites. These molecules have been shown to be shed on the parasite and/or cell surfaces during the invasion process in Plasmodium, Toxoplasma and Eimeria. For rhoptries and dense granules, the association between exocytosed proteins and the parasitophorous vacuole membrane had been analyzed extensively in Toxoplasma, as these proteins are likely to play a crucial role in metabolic interactions between the parasites and their host cells. The development of parasite transformation by gene transfection has provided powerful tools to analyze the fate and function(s) of the corresponding proteins.

Structure and function of the parasitophorous vacuole in Eimeria species

The intracellular life-cycle of Eimeria are located in the host cell within a membrane-bound parasitophorous vacuole. The invasion process and the formation of the parasitophorous vacuole are mediated by characteristic organelles within the apical complex. During invasion, the parasitophorous-vacuole membrane is manipulated by the parasite and functions later in the development cycle as a molecular sieve, allowing the exchange of metabolites between parasite and host cell. Unlike the cyst-forming coccidia, there is little evidence of parasitophorous-vacuole membrane transformation in the later stages of the lifecycle of Eimeria species. Compared with the human pathogens Plasmodium and Toxoplasma, rather little is known about the parasitophorous vacuole and parasitophorous-vacuole membrane of animal pathogens of the genus Eimeria.

The parasitophorous vacuole membrane surrounding Plasmodium and Toxoplasma: an unusual compartment in infected cells

Plasmodium and Toxoplasma belong to a group of unicellular parasites which actively penetrate their respective mammalian host cells. During the process of invasion, they initiate the formation of a membrane, the so-called parasitophorous vacuolar membrane, which surrounds the intracellular parasite and which differs substantially from endosomal membranes or the membrane of phagolysosomes. The biogenesis and the maintenance of the vacuolar membrane are closely related to the peculiar cellular organization of these parasites and are unique phenomena in cell biology. Here we compare biological similarities and differences between the two parasites, with respect to: (i) the formation, (ii) the maintenance, and (iii) the biological role of the vacuolar membrane. We conclude that most differences between the organisms primarily reflect the different biosynthetic capacities of the host cells they invade.

Induced activation of the Toxoplasma gondii nucleoside triphosphate hydrolase leads to depletion of host cell ATP levels and rapid exit of intracellular parasites from infected cells

The nucleoside triphosphate hydrolase of Toxoplasma gondii is a potent apyrase. The protein is synthesized in large amounts and transported through the secretory pathway of the parasite and into the vacuolar space in an oxidized and thereby enzymatically inactive form. Complete activation of the purified enzyme is known to require dithiols (e.g. DTT); subcellular fractionation demonstrates that little if any (<5%) of the enzyme in the vacuolar space is active in the absence of DTT. Both native and epitope-tagged nucleoside triphosphate hydrolase (NTPase) were partially activated during immunoprecipitation, precluding precise assessment of enzyme activity in the vacuolar space but suggesting that protein-protein interactions may trigger activation. When infected cells were treated with DTT, the NTPase was activated in a dose-response fashion, as assessed by migration on SDS-polyacrylamide gel electrophoresis and by an increase in enzymatic activity. After activation, enzyme activity decreased with time in the presence of DTT; this inactivation was slowed by the presence of excess ATP. A rapid fall in host cell ATP was accompanied by an abrupt exit of parasites from cells. These results demonstrate that the oxidation/reduction status of the NTPase, the only parasite dense granule protein that contains disulfide bonds, is tightly controlled within the vacuolar space and may influence parasite exit from cells.

Upstream elements required for expression of nucleoside triphosphate hydrolase genes of Toxoplasma gondii

Nucleoside triphosphate hydrolase is an abundant protein secreted by the obligate protozoan parasite Toxoplasma gondii. The protein has apyrase activity, degrading ATP to the di- and mono-phosphate forms. Because T. gondii is incapable of de novo synthesis of purines, it is postulated that NTPase may be used by the parasite to salvage purines from the host cell for survival and replication. To elucidate the molecular mechanisms of NTP gene expression, we isolated from the virulent RH strain of T. gondii the putative promoter region of three tandemly repeated NTP genes (NTP1, 2, 3). Using deletion constructs linked to the chloramphenicol acetyl transferase (CAT) reporter gene, we defined an active promoter within the first 220 bp. Sequence analysis of this region reveals the lack of a TATA box, but the promoter region is associated with a sequence which resembles an initiator element (Inr) in the NTP1 and NTP3 genes. This sequence which is similar to other Inrs known to regulate the expression of a wide variety of RNA polymerase II genes, is required for NTP expression. The NTP3 promoter contains sufficient information for developmentally regulated expression of CAT activity when the actively replicating stage tachyzoite differentiates into the dormant bradyzoite form.

Functional properties and physiological roles of organic solute channels

Membrane channels provide routes for the rapid, passive movement of solutes across plasma and intracellular membranes. It is generally assumed that the major physiological role of membrane channels is to transport inorganic ions for processes such as transepithelial salt absorption and secretion, cell volume regulation, signal transduction, and control of membrane electrical properties. Increasing evidence indicates, however, that channels play an important role in organic solute transport in a wide variety of cell types and organisms. Some of the major physiological roles of organic solute channels include uptake of nutrients, excretion of metabolic waste products, volume-regulatory organic osmolyte transport, and control of mitochondrial metabolism. This article reviews the functions and characteristics of channels that participate in the transport and regulation of both charged and electroneutral organic solutes.

Structures of Toxoplasma gondii tachyzoites, bradyzoites, and sporozoites and biology and development of tissue cysts

Infections by the protozoan parasite Toxoplasma gondii are widely prevalent world-wide in animals and humans. This paper reviews the life cycle; the structure of tachyzoites, bradyzoites, oocysts, sporocysts, sporozoites and enteroepithelial stages of T. gondii; and the mode of penetration of T. gondii. The review provides a detailed account of the biology of tissue cysts and bradyzoites including in vivo and in vitro development, methods of separation from host tissue, tissue cyst rupture, and relapse. The mechanism of in vivo and in vitro stage conversion from sporozoites to tachyzoites to bradyzoites and from bradyzoites to tachyzoites to bradyzoites is also discussed.

Characterization and cloning of the gene encoding the vacuolar membrane protein EXP-2 from Plasmodium falciparum

As a contribution to the characterization of the parasitophorous vacuolar membrane from Plasmodium falciparum we have begun the identification of vacuolar membrane proteins. Exported protein-2 (EXP-2) is a vacuolar membrane protein exposed into the vacuolar space. To further characterize EXP-2, it was purified, and the 45 N-terminal amino acids were determined by micro-sequencing. Based on this information, partial cDNA and genomic fragments were amplified by PCR and used as probes for the isolation of complete cDNA and genomic DNA clones. The single copy gene is located on chromosome 14, and is transcribed during the ring stage of parasite development. The open reading frame encodes an N-terminal signal sequence which is cleaved from the mature protein. The amino acid composition of EXP-2 is characterized by charged amino acids, with a high abundance of aspartate residues in the C-terminal portion of the protein. In contrast to EXP-1, an integral protein of the vacuolar membrane, EXP-2 lacks a typical hydrophobic transmembrane domain. We suggest that EXP-2 may associate with the vacuolar membrane via an amphipathic helix located in the N-terminal half of the protein.

Vacuolar-type H+-ATPase regulates cytoplasmic pH in Toxoplasma gondii tachyzoites

Cytoplasmic pH (pHi) regulation was studied in Toxoplasma gondii tachyzoites by using the fluorescent dye 2',7'-bis-(2-carboxyethyl)-5(6)-carboxyfluorescein. Their mean baseline pHi (7.07+/-0.06; n=5) was not significantly affected in the absence of extracellular Na+, K+ or HCO3(-) but was significantly decreased in a dose-dependent manner by low concentrations of N, N'-dicyclohexylcarbodi-imide (DCCD), N-ethylmaleimide (NEM) or bafilomycin A1. Bafilomycin A1 also inhibited the recovery of tachyzoite pHi after an acid load with sodium propionate. Similar concentrations of DCCD, NEM and bafilomycin A1 produced depolarization of the plasma membrane potential as measured with bis-(1,3-diethylthiobarbituric)trimethineoxonol (bisoxonol), and DCCD prevented the hyperpolarization that accompanies acid extrusion after the addition of propionate, in agreement with the electrogenic nature of this pump. Confocal laser scanning microscopy indicated that, in addition to being located in cytoplasmic vacuoles, the vacuolar (V)-H+-ATPase of T. gondii tachyzoites is also located in the plasma membrane. Surface localization of the V-H+-ATPase was confirmed by experiments using biotinylation of cell surface proteins and immunoprecipitation with antibodies against V-H+-ATPases. Taken together, the results are consistent with the presence of a functional V-H+-ATPase in the plasma membrane of these intracellular parasites and with an important role of this enzyme in the regulation of pHi homoeostasis in these cells.

The diverse habitats of obligate intracellular parasites

Bacterial obligate intracellular parasites have evolved diverse mechanisms for evasion of host cellular defenses. These mechanisms involve adaptations for survival in distinct intracellular compartments. Intracellular niches inhabited by obligate intracellular parasites include the cytoplasm, arrested early endosomes, lysosomes, and vesicles that do not fuse with the endosomal compartment but intersect with an exocytic pathway.

Evidence for pore-forming ability by Legionella pneumophila

Legionella pneumophila is the cause of Legionnaires' pneumonia. After Internalization by macrophages, it bypasses the normal endocytic pathway and occupies a replicative phagosome bound by endoplasmic reticulum. Here, we show that lysis of macrophages and red blood cells by L. pneumophila was dependent on dotA and other loci known to be required for proper targeting of the phagosome and replication within the host cell. Cytotoxicity occurred rapidly during a high-multiplicity infection, required close association of the bacteria with the eukaryotic cell and was a form of necrotic cell death accompanied by osmotic lysis. The differential cytoprotective ability of high-molecular-weight polyethylene glycols suggested that osmotic lysis resulted from insertion of a pore less than 3 nm in diameter into the plasma membrane. Results concerning the uptake of membrane-impermeant fluorescent compounds of various sizes are consistent with the osmoprotection analysis. Therefore, kinetic and genetic evidence suggested that the apparent ability of L. pneumophila to insert a pore into eukaryotic membranes on initial contact may play a role in altering endocytic trafficking events within the host cell and in the establishment of a replicative vacuole.

Toxoplasma gondii sporozoites form a transient parasitophorous vacuole that is impermeable and contains only a subset of dense-granule proteins

Toxoplasma gondii sporozoites form two parasitophorous vacuoles during development within host cells, the first (PV1) during host cell invasion and the second (PV2) 18 to 24 h postinoculation. PV1 is structurally distinctive due to its large size, yet it lacks a tubulovesicular network (C. A. Speer, M. Tilley, M. Temple, J. A. Blixt, J. P. Dubey, and M. W. White, Mol. Biochem. Parasitol. 75:75-86, 1995). Confirming the finding that sporozoites have a different electron-dense-granule composition, we have now found that sporozoites within oocysts lack the mRNAs encoding the 5' nucleoside triphosphate hydrolases (NTPase). NTPase first appears 12 h postinfection. Other tachyzoite dense-granule proteins, GRA1, GRA2, GRA4, GRA5, and GRA6, were detected in oocyst extracts, and antibodies against these proteins stained granules in the sporozoite cytoplasm. In contrast to tachyzoite invasion of host cells, however, sporozoites did not exocytose the dense-granule proteins GRA1, GRA2, or GRA4 during PV1 formation. Even after NTPase induction, these proteins were retained within cytoplasmic granules rather than being secreted into PV1. Only GRA5 was secreted by the sporozoite during host cell invasion, becoming associated with the membrane surrounding PV1. Microinjection of sporozoite-infected cells with fluorescent dyes showed that PV1 is impermeable to fluorescent dyes with molecular masses as small as 330 Da, indicating that PV1 lacks channels through which molecules can pass from the host cytoplasm into the vacuole. By contrast, lucifer yellow rapidly diffused into PV2, demonstrating the presence of molecular channels. These studies indicate that PV1 and PV2 are morphologically, immunologically, and functionally distinct, and that PV2 appears to be identical to the tachyzoite vacuole. The inaccessibility of PV1 to host cell nutrients may explain why parasite replication does not occur in this vacuole.

Safe haven: the cell biology of nonfusogenic pathogen vacuoles

Our understanding of both membrane traffic in mammalian cells and the cell biology of infection with intracellular pathogens has increased dramatically in recent years. In this review, we discuss the cell biology of the host-microbe interaction for four intracellular pathogens: Chlamydia spp., Legionella pneumophila, Mycobacterium spp., and the protozoan parasite Toxoplasma gondii. All of these organisms reside in vacuoles inside cells that have restricted fusion with host organelles of the endocytic cascade. Despite this restricted fusion, the vacuoles surrounding each pathogen display novel interactions with other host cell organelles. In addition to the effect of infection on host membrane traffic, we focus on these novel interactions and relate them where possible to nutrient acquisition by the intracellular organisms.

Targeting the secretory pathway of Toxoplasma gondii

Little is known about the extent of conservation in the organization of the secretory pathway in organisms as different as prokaryotes, eukaryotes, and humans. The protozoan parasite Toxoplasma gondii allows easy genetic manipulations, and numerous vectors for selection of transgenic parasites have been developed. One approach to study the molecular mechanism of protein sorting and trafficking is the expression of foreign proteins. Here we describe the design and application of a vector that targets proteins to the secretory pathway of T. gondii and yields high-level expression of Escherichia coli reporter proteins. The general strategies and potential problems in expressing foreign proteins in T. gondii are discussed.