The loss of cytoplasmic potassium upon host cell breakdown triggers egress of Toxoplasma gondii.

The ability of intracellular parasites to monitor the viability of their host cells is essential for their survival. The protozoan parasite Toxoplasma gondii actively invades nucleated animal cells and replicates in their cytoplasm. Two to 3 days after infection, the parasite-filled host cell breaks down and the parasites leave to initiate infection of a new cell. Parasite egress from the host cell is triggered by rupture of the host plasma membrane and the ensuing reduction in the concentration of cytoplasmic potassium. The many other changes in host cell composition do not appear be used as triggers. The reduction in the host cell [K(+)] appears to activate a phospholipase C activity in Toxoplasma that, in turn, causes an increase in cytoplasmic [Ca(2+)] in the parasite. The latter appears to be necessary and sufficient for inducing egress, as buffering of cytoplasmic Ca(2+) blocks egress and calcium ionophores circumvent the need for a reduction of host cell [K(+)] and parasite phospholipase C activation. The increase in [Ca(2+)](C) brings about egress by the activation of at least two signaling pathways: the protein kinase TgCDPK1 and the calmodulin-dependent protein phosphatase calcineurin.

The microneme protein MIC3 of Toxoplasma gondii is a secretory adhesin that binds to both the surface of the host cells and the surface of the parasite.

Assay of the adhesion of cultured cells on Toxoplasma gondii tachyzoite protein Western blots identified a major adhesive protein, that migrated at 90 kDa in non-reducing gels. This band comigrated with the previously described microneme protein MIC3. Cellular binding on Western blots was abolished by MIC3-specific monoclonal and polyclonal antibodies. The MIC3 protein affinity purified from tachyzoite lysates bound to the surface of putative host cells. In addition, T. gondii tachyzoites also bound to immobilized MIC3. Immunofluorescence analysis of T. gondii tachyzoite invasion showed that MIC3 was exocytosed and relocalized to the surface of the parasite during invasion. The cDNA encoding MIC3 and the corresponding gene have been cloned, allowing the determination of the complete coding sequence. The MIC3 sequence has been confirmed by affinity purification of the native protein and N-terminal sequencing. The deduced protein sequence contains five partially overlapping EGF-like domains and a chitin binding-like domain, which can be involved in protein-protein or protein-carbohydrate interactions. Taken together, these results suggest that MIC3 is a new microneme adhesin of T. gondii.

The protozoan parasite Toxoplasma gondii targets proteins to dense granules and the vacuolar space using both conserved and unusual mechanisms.

All known proteins that accumulate in the vacuolar space surrounding the obligate intracellular protozoan parasite Toxoplasma gondii are derived from parasite dense granules. To determine if constitutive secretory vesicles could also mediate delivery to the vacuolar space, T. gondii was stably transfected with soluble Escherichia coli alkaline phosphatase and E. coli beta-lactamase. Surprisingly, both foreign secretory reporters were delivered quantitatively into parasite dense granules and efficiently secreted into the vacuolar space. Addition of a glycosylphosphatidylinositol membrane anchor rerouted alkaline phosphatase to the parasite surface. Alkaline phosphatase fused to the transmembrane domain and cytoplasmic tail from the endogenous dense granule protein GRA4 localized to dense granules. The protein was secreted into a tuboreticular network in the vacuolar space, in a fashion dependent upon the cytoplasmic tail, but not upon a tyrosine-based motif within the tail. Alkaline phosphatase fused to the vesicular stomatitis virus G protein transmembrane domain and cytoplasmic tail localized primarily to the Golgi, although staining of dense granules and the intravacuolar network was also detected; truncating the cytoplasmic tail decreased Golgi staining and increased delivery to dense granules but blocked delivery to the intravacuolar network. Targeting of secreted proteins to T. gondii dense granules and the plasma membrane uses general mechanisms identified in higher eukaryotic cells but is simplified and exaggerated in scope, while targeting of secreted proteins beyond the boundaries of the parasite involves unusual sorting events.

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.

The expression of Toxoplasma proteins in Neospora caninum and the identification of a gene encoding a novel rhoptry protein.

Genes for the Toxoplasma gondii dense granule and rhoptry proteins nucleoside triphosphate hydrolase 3 and ROP2 were expressed at high levels in the closely related parasite N. caninum. The protein products were processed appropriately and were targeted to their correct secretory organelles. NTPase 3 was secreted into the parasitophorous vacuole. The utility of this system was demonstrated in the analysis of a new open reading frame identified upstream of two identical copies of the ROP2 gene. The unknown open reading frame was introduced into Neospora, and transfected parasites were analyzed by immunoblot with antibodies to known T. gondii rhoptry protein families. The transfected Neospora expressed a novel 52 kDa protein, designated ROP8, which localized in the rhoptries. These results illustrate that transfection of known Toxoplasma genes into N. caninum can be used to study their expression, processing and targeting in an immunologically distinct background. They also illustrate the usefulness of N. caninum transfection in the identification and subcellular distribution of proteins encoded by previously uncharacterized Toxoplasma genes.

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.

Inhibition of cytoplasmic and organellar protein synthesis in Toxoplasma gondii. Implications for the target of macrolide antibiotics.

We investigated potential targets for the activity of protein synthesis inhibitors against the protozoan parasite Toxoplasma gondii. Although nanomolar concentrations of azithromycin and clindamycin prevent replication of T. gondii in both cell culture and in vivo assays, no inhibition of protein labeling was observed in either extracellular or intracellular parasites treated with up to 100 microM drug for up to 24 h. Quantitative analysis of > 300 individual spots on two-dimensional gels revealed no proteins selectively depleted by 100 microM azithromycin. In contrast, cycloheximide inhibited protein synthesis in a dose-dependent manner. Nucleotide sequence analysis of the peptidyl transferase region from genes encoding the large subunit of the parasite's ribosomal RNA predict that the cytoplasmic ribosomes of T. gondii, like other eukaryotic ribosomes, should be resistant to macrolide antibiotics. Combining cycloheximide treatment with two-dimensional gel analysis revealed a small subset of parasite proteins likely to be synthesized on mitochondrial ribosomes. Synthesis of these proteins was inhibited by 100 microM tetracycline, but not by 100 microM azithromycin or clindamycin. Ribosomal DNA sequences believed to be derived from the T. gondii mitochondrial genome predict macrolide/lincosamide resistance. PCR amplification of total T. gondii DNA identified an additional class of prokaryotic-type ribosomal genes, similar to the plastid-like ribosomal genes of the Plasmodium falciparum. Ribosomes encoded by these genes are predicted to be sensitive to the lincosamide/macrolide class of antibiotics, and may serve as the functional target for azithromycin, clindamycin, and other protein synthesis inhibitors in Toxoplasma and related parasites.

Infection with Listeria monocytogenes impairs sialic acid addition to host cell glycoproteins.

Listeria monocytogenes is a facultative intracellular bacterium that causes severe disease in neonates and immunocompromised adults. Although entry, multiplication, and locomotion of Listeria in the cytosol of infected cells are well described, the impact of such infection on the host cell is unknown. In this report, we investigate the effect of L. monocytogenes infection on MHC class I synthesis, processing, and intracellular trafficking. We show that L. monocytogenes infection interferes with normal processing of N-linked oligosaccharides on the major histocompatibility complex (MHC) class I heavy chain molecule, H-2Kd, resulting in a reduced sialic acid content. The glycosylation defect is more pronounced as the infection progresses and results from interference with the addition of sialic acid rather than its removal by a neuraminidase. The effect is found in two different cell lines and is not limited to MHC class I molecules since CD45, a surface glycoprotein, and LGP120, a lysosomal glycoprotein, are similarly affected by L. monocytogenes infection. The glycosylation defect is specific for infection by L. monocytogenes since neither Trypanosoma cruzi nor Yersinia enterocolitica, two other intracellular pathogens, reproduces the effect. The resultant hyposialylation of H-2Kd does not impair its surface expression in infected cells. Diminished sialic acid content of surface glycoproteins may enhance host-defense by increasing susceptibility to lysis and promoting clearance of Listeria-infected cells.

Tandemly repeated genes encode nucleoside triphosphate hydrolase isoforms secreted into the parasitophorous vacuole of Toxoplasma gondii.

The obligate intracellular parasite Toxoplasma gondii produces a nucleoside triphosphate hydrolase (NTPase) (nucleoside-triphosphatase, EC 3.6.1.15) activable by dithiol-containing compounds. We have isolated the genomic DNA for the NTPase from the RH strain of Toxoplasma and determined the nucleotide sequence of three tandemly arranged open reading frames termed NTP1, NTP2, and NTP3. We have also isolated and sequenced cDNAs for NTP1 and NTP3; no cDNA for NTP2 was obtained. The two cDNA clones encode proteins that are more than 97% identical at the amino acid level but significantly differ within two small domains, indicating the presence of NTPase isoforms. Both possess N-terminal signal sequences and two regions with partial homology to certain known ATP binding motifs: the glycine-rich loop common to many ATP binding proteins and the beta-phosphate binding domain found in the hexokinase-actin-hsp70 family. Antiserum against a NTP1-fusion protein immunoprecipitated NTPase activity from extracellular parasites that was increased in activity by treatment with dithiothreitol, confirming the identity of the cloned genes. By immunofluorescence, the NTPase is located in vesicular structures within the parasite, and in infected cells it is secreted into the vacuolar space and becomes partially associated with the parasitophorous vacuolar membrane. Since the vacuolar membrane is freely permeable to small molecules of < 1300 Da, host cell ATP may serve as a substrate for the NTPase and supply the energy for parasite-directed processes in the vacuolar space.

The Toxoplasma gondii rhoptry protein ROP 2 is inserted into the parasitophorous vacuole membrane, surrounding the intracellular parasite, and is exposed to the host cell cytoplasm.

The origin of the vacuole membrane surrounding the intracellular protozoan parasite Toxoplasma gondii is not known. Although unique secretory organelles, the rhoptries, discharge during invasion of the host cell and may contribute to the formation of this parasitophorous vacuole membrane (PVM), no direct evidence for this hypothesis exists. Using a novel approach we have determined that parasite-encoded proteins are present in the PVM, exposed to the host cell cytoplasm. In infected cells incubated with streptolysin-O or low concentrations of digitonin, the host cell plasma membrane was selectively permeabilized without significantly affecting the integrity of the PVM. Antisera prepared against whole parasites or a parasite fraction enriched in rhoptries and dense granules reacted with the PVM in these permeabilized cells, indicating that parasite-encoded antigens were exposed on the cytoplasmic side of the PVM. Parasite antigens responsible for this staining of the PVM were identified by fractionating total parasite proteins by SDS-PAGE and velocity sedimentation, and then affinity purifying "fraction-specific" antibodies from the crude antisera. Proteins responsible for the PVM-staining, identified with fraction-specific antibodies, cofractionated with known rhoptry proteins. The gene encoding one of the rhoptry proteins, ROP 2, was cloned and sequenced, predicting and integral membrane protein. Antibodies specific for ROP 2 reacted with the intact PVM. These results provide the first direct evidence that rhoptry contents participate in the formation of the PVM of T. gondii and suggest a possible role of ROP 2 in parasite-host cell interactions.

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

The obligate intracellular protozoan parasite Toxoplasma gondii creates and enters into a unique membrane-bounded cytoplasmic compartment, the parasitophorous vacuole, when invading mammalian host cells. By microinjecting polar fluorescent molecules into individual T. gondii-infected fibroblasts, we show here that the parasitophorous vacuole membrane (PVM) surrounding the parasite functions as a molecular sieve. Lucifer yellow (457 Da) displayed free bidirectional flux across the PVM and distinctly outlined the parasites, which did not take up the dye, within the vacuole. This dye movement was not appreciably delayed by pretreatment of cells with 5 mM probenecid or chilling the monolayer to 5 degrees C, suggesting that dye movement was due to passive permeation through a membrane pore rather than active transport. Calcein, fluo-3, and a series of fluorescein isothiocyanate-labeled peptides up to 1291 Da crossed the PVM in a size-restricted fashion. A labeled peptide of 1926 Da and labeled dextrans and proteins (> or = 3000 Da) failed to transit the PVM. This putative channel in the PVM therefore allows exchange of molecules up to 1300-1900 Da between the host cell cytoplasm and the parasitophorous vacuolar space.

Individual subunits of bacterial luciferase are molten globules and interact with molecular chaperones.

We have studied the assembly of a large heterodimeric protein, bacterial luciferase, by mixing purified subunits expressed separately in bacteria. The individual subunits alpha and beta contain much (66% and 50%, respectively) of the alpha-helix content of the native heterodimer as measured by circular dichroism, yet the alpha subunit lacks observable tertiary structure as measured by NMR. These results are consistent with the alpha subunit existing in a molten globule or collapsed form prior to assembly. The molecular chaperone GroEL binds reversibly to both subunits prior to assembly. Since these observations were obtained under physiological conditions, we propose that the molten globule exists as a stable form during folding or assembly in the cell. Either the molten globule form of the subunits is an authentic folding intermediate or it is in rapid equilibrium with one. GroEL may function by facilitating assembly through stabilization of these incompletely folded subunits.

Binding of coatomer to Golgi membranes requires ADP-ribosylation factor.

Coatomer, a complex of seven proteins, appears to be the precursor of the coat structure of non-clathrin-coated Golgi-derived vesicles. Another component of this vesicle coat is the cytosolic protein ADP-ribosylation factor (ARF). Like coatomer, ARF appears to reversibly associate with Golgi membranes. We now report that ARF is required for coatomer binding to Golgi membranes and that myristoylated, but not non-myristoylated, ARF is the required species. We utilize an antibody directed against the beta-subunit of coatomer (beta-COP) to follow coatomer binding. ARF and beta-COP bind stoichiometrically to Golgi membranes. ARF-dependent beta-COP binding requires a membrane-associated protein, is saturable, and is enhanced in the presence of stable GTP analogues like guanosine 5'-O-(3-thiotriphosphate) (GTP gamma S). ARF and beta-COP bind sequentially to Golgi membranes, since beta-COP can be bound to reisolated membranes that had been previously incubated with ARF and GTP gamma S. We conclude that membrane-bound ARF confers to Golgi membranes all of the requirements for specific beta-COP binding.

Sequential transport of protein between the endoplasmic reticulum and successive Golgi compartments in semi-intact cells.

The vectorial transport of vesicular stomatitis virus (VSV) G protein between the ER and the cis and medial Golgi compartments has been reconstituted using semi-intact (perforated) cells. The transport of VSV-G protein between successive compartments is measured by the sequential processing of the two N-linked oligosaccharide chains present on VSV-G protein to the endoglycosidase (endo) H-resistant structures which have unique electrophoretic mobilities during sodium dodecyl sulfate-gel electrophoresis. The appearance of a form of VSV-G which contains only one endo H-resistant oligosaccharide chain (GH1) is kinetically and biochemically indistinguishable from the appearance of the Man5, endo D-sensitive form (GD), the latter being a processing reaction diagnostic of transport from the ER to the cis Golgi compartment. These results provide evidence that the cis Golgi compartment may contain in addition to alpha-1,2-mannosidase I, both N-acetylglueosamine transferase I and alpha-1,2-mannosidase II. VSV-G protein is subsequently processed to the form which contains two endo H-resistant oligosaccharides (GH2) after a second wave of vesicular transport. Processing of GH1 to GH2 in vitro occurs only after a lag period following the appearance of GH1; processing is sensitive to N-ethylmaleimide, guanosine-5'-O-(3-thiotriphosphate), and a synthetic peptide homologous to the rab1 protein effector domain, and processing is inhibited in the absence of free Ca2+ (in the presence of EGTA), reagents which potently inhibit ER to cis Golgi transport. These results suggest that VSV-G protein proceeds through at least two rounds of vesicular transport from the ER to the medial Golgi compartment for processing to the GH2 form, providing a model system to study the regulation of the vectorial membrane fission and fusion events involved in vesicular trafficking and organelle dynamics in the early stages of the secretory pathway.

Sequential intermediates in the transport of protein between the endoplasmic reticulum and the Golgi.

Semi-intact cells, a cell population in which the plasma membrane is perforated to expose intact intracellular organelles (Beckers, C. J. M., Keller, D. S., and Balch, W. E. (1987) Cell 50, 523-534), efficiently reconstitute vesicular trafficking of protein from the endoplasmic reticulum (ER) to the cis Golgi compartment. We now extend these studies to biochemically dissect transport of protein between the ER and the Golgi into a series of sequential intermediate steps involved in the budding and fusion of carrier vesicles. At least two broad categories of transport intermediates can be detected, those that involve early steps in transport and those involved in late, fusion-related events. Early transport steps require the transport of protein through a novel intermediate compartment in which protein accumulates at reduced temperature (15 degrees C). We demonstrate that both entry and exit from this 15 degrees C compartment can be successfully reconstituted in vitro. A late step in delivery of protein to the cis Golgi compartment requires Ca2+ (pCa7) and is coincident with a step which is sensitive to a peptide analog which blocks interaction between the Rab family of small GTP-binding proteins and a downstream effector protein(s) (Plutner, H., Schwaninger, R., Pind, S., and Balch, W. E. (1990) EMBO J. 9, 2375-2384). The combined results suggest that a single round of vesicular transport between the ER and the Golgi involves a rapid transit through N-ethylmaleimide-sensitive, guanosine 5'-(3-O-thio)triphosphate-sensitive, ATP- and cytosol-dependent step(s) involved in vesicle formation or transport to a novel intermediate compartment, followed by a regulated fusion event triggered in the presence of Ca2+ and functional components interacting with member(s) of the Rab gene family.

Vesicular transport between the endoplasmic reticulum and the Golgi stack requires the NEM-sensitive fusion protein.

An N-ethylmaleimide-sensitive fusion protein (NSF) has been purified on the basis of its ability to catalyse vesicular transport within the Golgi stack. We report here that this same protein is required for transport from the endoplasmic reticulum to the Golgi stack in semi-intact cells. This transport process is inhibited by a monoclonal antibody against NSF. Furthermore, pretreatment of semi-intact cells with N-ethylmaleimide, a sulphydryl alkylating reagent, inhibits transport. Addition of highly purified NSF largely restores transport from endoplasmic reticulum to Golgi. These results suggest that NSF is a general component of the transport machinery required for membrane fusion at multiple stages of the secretory pathway.