Penetration-enhancing factor extracted from Toxoplasma gondii which increases its virulence for mice

Fractionation of extracts of disintegrated Toxoplasma gondii resulted in preparations which, when tested in cell cultures, enhanced penetration of host cells by this parasite. The influence of the preparations on the virulence of the RH strain and on two naturally avirulent strains for mice was studied simultaneously with the in vitro studies. It was demonstrated that the preparations increased the virulence of Toxoplasma. Mice inoculated with the preparation plus Toxoplasma suffered earlier morbidity and had a greater mortality rate than the control animals. There was a direct correlation between the effect of the preparations on the cell-penetrating capacity of the parasites and the increase in virulence for mice, indicating that the same mechanism is operative in both the in vivo and in vitro systems observed.     

Toxoplasma gondii-vertebrate cell interactions. I. The influence of bicarbonate ion, CO2, pH and host cell culture age on the invasion of vertebrate cells in vitro.

A controlled-environment culture system was used to show that both physical and biologic parameters can influence the penetration of vertebrate cells by Toxoplasma gondii. The optimum bicarbonate ion concentration for the penetration of bovine embryo skeletal muscle (BESM) cells is 36.25 mM. Higher or lower bicarbonate ion concentrations are increasingly inhibitory to penetration. As CO2 increases in the range from 0.5-3.7 mM, penetration is progressively inhibited. No relationship was found between penetration and pH in the pH range of 6.949-7.765. The culture age of the BESM cells directly influenced the ability of the parasites to penetrate the cells. Older BESM cells were more refractory to penetration than younger cells.     

Toxoplasma gondii-Vertebrate Cell Interactions. I. The Influence of Bicarbonate Ion, CO2, pH and Host Cell Culture Age on the Invasion of Vertebrate Cells In Vitro

SYNOPSIS A controlled-environment culture system was used to show that both physical and biologic parameters can influence the penetration of vertebrate cells by Toxoplasma gondii. The optimum bicarbonate ion concentration for the penetration of bovine embryo skeletal muscle (BESM) cells is 36.25 mM. Higher or lower bicarbonate ion concentrations are increasingly inhibitory to penetration. As CO₂ increases in the range from 0.5–3.7 mM, penetration is progressively inhibited. No relationship was found between penetration and pH in the pH range of 6.949–7.765. The culture age of the BESM cells directly influenced the ability of the parasites to penetrate the cells. Older BESM cells were more refractory to penetration than younger cells.     

Review: Toxoplasma gondii cellular invasion.

Toxoplasma gondii, the etiologic agent of toxoplasmosis, is a ubiquitous protozoan parasite that requires an intracellular site for growth and replication. The invasive process involves six steps: a) cellular recognition, b) parasite movements by means of a subpellicular microtubule cytoskeleton, c) cell to cell adhesion, d) rhoptry secretion of penetrating enhancing factor (PEF) with Ca++ and Ca++ activated ATPase dependence, e) conoid penetration, f) induction of a parasitophorous vacuole, a protective and exchange site, interiorization of the parasite. The invasion is an active, oriented and specific process depending on chemical factors as energy sources, cations, as well as microviscosity and membrane structures. Toxoplasma gondii stimulates T cell subsets and induces lymphokine (IFN gamma, IL2) release.     

Lysosomes of Toxoplasma gondii and Their Possible Relation to the Host-Cell Penetration of Toxoplasma Parasites

Lysosome-like structures of Toxoplasma gondii were observed by means of vital staining with acridine orange and by the Gomori technique. These structures were found scattered over the cytoplasm but were often located at one end of the parasite. In comparison with parasites of the inoculum used for infecting HeLa cell cultures, the toxoplasma which had penetrated the HeLa cells revealed a markedly lower percentage of parasites showing lysosomal staining. After the penetration, the number of parasites with demonstrable lysosomes increased successively and, at the time for release of newly formed parasites (at 24 hr), the majority of the parasites demonstrated lysosome-like bodies in the cytoplasm. The observations are discussed with special reference to the mechanism of host-cell penetration.     

Disintegration of layer-by-layer assemblies composed of 2-iminobiotin-labeled poly(ethyleneimine) and avidin

A layer-by-layer thin film composed of avidin and 2-iminobiotin-labeled poly(ethyleneimine) (ib-PEI) was prepared and their sensitivity to the environmental pH and biotin was studied. The avidin/ib-PEI multilayer assemblies were stable at pH 8-12, whereas the assemblies were decomposed at pH 5-6 due to the low affinity of the protonated iminobiotin residue to avidin. The avidin/ib-PEI assemblies can be disintegrated upon addition of biotin and analogues in the solution as a result of the preferential binding of biotin or analogues to the binding site of avidin. The decomposition rate was arbitrarily controlled by changing the type of stimulant (biotin or analogues) and its concentration. The avidin/ib-PEI assemblies were disintegrated rapidly by the addition of biotin or desthiobiotin, whereas the rate of decomposition was rather slow upon addition of lipoic acid or 2-(4'-hydroxyphenylazo)benzoic acid. The present system may be useful for constructing the stimuli-sensitive devices that can release drug or other functional molecules.     

Investigating the activity of 2-substituted alkyl-6-(2,5-dioxopyrrolidin-1-yl)hexanoates as skin penetration enhancers

Skin penetration enhancers are used in the formulation of transdermal delivery systems for drugs that are otherwise not sufficiently skin-permeable. We generated two series of esters by multi-step synthesis with substituted 6-aminohexanoic acid as potential transdermal penetration enhancers by multi-step synthesis. The synthesis of all newly prepared compounds is presented here. Structure confirmation of all generated compounds was accomplished by (1)H NMR, (13)C NMR, IR and MS spectroscopy. All the prepared compounds were analyzed using RP-HPLC and their lipophilicity (logk) was determined. The hydrophobicity (logP/ClogP) of the studied compounds was also calculated using two commercially available programs and 3D structures of the selected compounds were investigated by means of ab initio calculations of geometry and molecular dynamic simulations. All the synthesized esters were tested for their in vitro transdermal penetration-enhancing activity and showed higher enhancement ratios than oleic acid. The highest enhancement ratios were exhibited by compound 5f (C((2)) substituted with piperidine-2-one, C(11) ester chain) and 5a (C((2)) substituted with piperidine-2-one, C(6) ester chain). The series with a ω-lactam ring (piperidin-2-one; 5a-g), showed slightly higher activities than those with morpholine (6a-6g). All of the agents showed minimal anti-proliferative activity (IC(50) >6.25μM), indicating they would have low cytotoxicity when administered as chemical penetration enhancers. The relationships between the lipophilicity and the chemical structure of the studied compounds, as well as the correlation between their chemical structure and transdermal penetration-enhancing activity, are discussed.     

The influence of alkali and heat treatment on yeast protein

The soluble components in disintegrated cells of Saccharomyces cereivisiae have been characterized by means of extraction, centrifugation, dialysis, and gel filtration. The influence of alkali and heat treatment on the protein and RNA in the soluble fraction from disintegrated yeast cells and on functional properties of protein concentrates have been studied. After water extraction and centrifugation at 100000 g 42% of the nitrogen containing components of the disintegrated cells were recovered in the supernatant. By extraction at pH 11.5 an additional 31% of the nitrogen was solubilized. Half of the water-soluble nitrogen-containing components has a molecular weight lower than 5000. In the water- and alkali-soluble fractions about 80% of each amino acid was recovered The water-soluble protein was separated into 3 fractions by gel filtration on Sephadex G 200. The major portion of the protein had a molecular weight about 100,000. The amount of protein in this fraction was decreased after treatment at increasing pH and temperature. No degradation of protein to low molecular peptides occurred. The amount of RNA in the soluble fraction was only slightly influenced by alkali treatment and by heat treatment at pH 7.5 in the presence of 5% NaCl. RNA was not degraded to low molecular components of the treatments. The solubility of protein concentrates decreased after treatment at alkaline pH and after heat precipitation.     

The relationship between the fate of the agent of toxoplasmosis, Toxoplasma gondii, in macrophages cultivated in vitro and the virulence of the parasites]

Comparative light microscopic and electron microscopic studies of development of a highly-virulent RH strain and a less virulent Lagrave strain of Toxoplasma cultivated in macrophages in vitro were made. Contrary to active multiplication of the highly virulent strain most of toxoplasmas of a less virulent strain disintegrated the first hours, degenerating completely in 24-48 hours after the penetration into the macrophages. Submicroscopic study showed no marked cytological changes of macrophages infected with a less virulent strain in comparison with the marked changes of the nuclei in macrophages infected with the RH strain. Disintegration of parasites within the phagosome was accompanied by a gradual transformation of an originally double (or triple) vacuolar membrane to a single membrane and by the disappearance of an additional layer of mitochondria and endoplasmic reticulum elements surrounding the vacuolar membrane. It is likely that the capacity of toxoplasma to develop in macrophages in vitro could become an additional marker to its virulence for albino mice.     

Penetration of human skin by the cercariae of Schistosoma mansoni: an investigation of the effect of multiple cercarial applications

It has previously been postulated that L-arginine emitted by penetrating Schistosoma mansoni cercariae serves as an intraspecific signal guiding other cercariae to the penetration site. It was suggested that penetrating in groups offers a selective advantage. If this hypothesis is correct and group penetration at one site on the host offers an advantage, it would follow that at such a site, successive groups of cercariae would be able to penetrate skin in either greater numbers or at a faster rate. This prediction was tested by the use of an in vitro model of cercarial penetration based on the Franz cell and using human skin. It was demonstrated that there was no increase in the percentage of cercariae able to penetrate the skin with subsequent exposures. Consequently, it seems unlikely that the release of L-arginine by cercariae during penetration could have evolved as a specific orientation system based on a selective advantage offered by group penetration.     

The toxoplasma micronemal protein MIC4 is an adhesin composed of six conserved apple domains

The initial stage of invasion by apicomplexan parasites involves the exocytosis of the micronemes-containing molecules that contribute to host cell attachment and penetration. MIC4 was previously described as a protein secreted by Toxoplasma gondii tachyzoites upon stimulation of micronemes exocytosis. We have microsequenced the mature protein, purified after discharge from micronemes and cloned the corresponding gene. The deduced amino acid sequence of MIC4 predicts a 61-kDa protein that contains 6 conserved apple domains. Apple domains are composed of six spacely conserved cysteine residues which form disulfide bridges and are also present in micronemal proteins from two closely related apicomplexan parasites, Sarcocystis muris and Eimeria species, and several mammalian serum proteins, including kallikrein. Here we show that MIC4 localizes in the micronemes of all the invasive forms of T. gondii, tachyzoites, bradyzoites, sporozoites, and merozoites. The protein is proteolytically processed both at the N and the C terminus only upon release from the organelle. MIC4 binds efficiently to host cells, and the adhesive motif maps in the most C-terminal apple domain.     

Focus on the ringleader: the role of AMA1 in apicomplexan invasion and replication

Apicomplexan parasites exhibit an unusual mechanism of host cell penetration. A central player in this process is the protein apical membrane antigen 1 (AMA1). Although essential for invasion, the precise functional roles AMA1 plays have been unclear. Several recent studies have provided important functional insight into its role within the multiprotein complex that comprises the moving junction (MJ). Initially formed at the apical tip of the invading parasite, the MJ represents a ring-like region of contact between the surfaces of the invading parasite and the host cell as the invaginated host plasma membrane is forced inward by the penetrating parasite. This review discusses these and other recent insights into AMA1 with particular emphasis on studies conducted in Plasmodium and Toxoplasma.     

Investigation of substituted 6-aminohexanoates as skin penetration enhancers

Skin penetration enhancers are compounds used to facilitate the transdermal delivery of drugs that are otherwise not sufficiently permeable. Through a synthetic route implementing two series of esters, we generated transdermal penetration enhancers by a multi-step reaction with substituted 6-aminohexanoic acid. We present the synthesis of all newly prepared compounds here with structural confirmation accomplished by (1)H NMR, (13)C NMR, IR and mass spectroscopy (MS). The lipophilicity (logk) of all compounds was determined via RP-HPLC and their hydrophobicity (logP/ClogP) was also calculated using two commercially available programs. Ab initio calculations of geometry and molecular dynamic simulations were employed to investigate the 3-dimensional structures of selected compounds. The transdermal penetration-enhancing activity of all the synthesized esters were examined in vitro and demonstrated higher enhancement ratios than oleic acid. Compounds 2e (C(10) ester chain) and 2f (C(11) ester chain) exhibited the highest enhancement ratios. It can be concluded that the series non-substituted at the C((2)) position by a ω-lactam ring showed significantly higher activity than those with azepan-2-one. None of the prepared compounds penetrated through the skin. All of the investigated agents demonstrated minimal anti-proliferative activity using the SK-N-MC neuroepithelioma cell line (IC(50)>6.25μM), suggesting these analogs would have a low cytotoxic profile when administered in vivo as chemical penetration enhancers. The correlation between the chemical structure of the studied compounds and their lipophilicity is discussed in regards to transdermal penetration-enhancing activity.     

Modes of entry of Toxoplasma gondii trophozoites into normal mouse peritoneal macrophage and HeLa cell monolayers. A phase-contrast microcinematographic study (author's transl)]

The mode of entry of living trophozoites of Toxoplasma gondii (RH strain) into normal mouse peritoneal macrophage and HeLa cell monolayers was studied by phase-contrast microcinematography. The results have shown that Toxoplasma can enter into macrophages either by phagocytosis (Figs. 1 and 2) and/or by active penetration (Fig. 3). Only the latter process was observed with normally non-phagocytic HeLa cells (Fig. 4). During this process the parasites actively moved towards the host-cells by flexion and penetrated them always through their sharpest end. Active penetration was a rapid phenomenon (about 20 s at 37 degrees C) and was accompanied by a series of morphological changes, i.e., elongation of the anterior end, contraction and swelling of the parasite body. Contrasting with phagocytosis, toxoplasmas which had penetrated into the cell were not immediately isolated from the host-cytoplasm by a microscopically discernable vacuole. The nature of the process of penetration (pressure and/or perforation of the plasma membrane) is discussed.     

Toxoplasma gondii: characterization of monoclonal antibodies that recognize rhoptries

We have previously reported on a series of monoclonal antibodies that recognize the rhoptries of Toxoplasma gondii and that interfere with the action of penetration enhancing factor. The antibodies immunoprecipitate several related antigens from [35S]methionine-labeled parasites that range in size from 60 to 43 kDa. By immunoblot, one of the antibodies reacts with the 60 kDa protein in the presence of protease inhibitors. Trypsin digestion of the antigen destroyed antigenic reactivity indicating that the 60 kDa antigen is a protein. The antigen was stable to periodate oxidation and failed to react with Schiff's reagent, indicating that the antigen contains little or no carbohydrate. Two-dimensional gel electrophoresis followed by immunoblot showed that the antigen recognized by Tg 49 was an acidic protein with an approximate pI of 5.8.     

综述——纳米材料与药物输递：经皮给药中纳米制剂与皮肤的质构效关系

皮肤是人体最大的器官,也为药物的递送提供了重要途径。经皮给药是药物以皮肤为媒介,透过皮肤吸收的途径。因此,皮肤角质层是经皮给药的最大限速障碍。纳米经皮给药系统,具有提高透皮效率、缓释性、避免药物肝首过效应、减少副作用等优点,是通过纳米制剂与皮肤组织之间的相互作用实现的。其中,纳米制剂的结构和组分与其发挥皮肤促渗效用密切相关。对纳米制剂与皮肤质构效关系深入透彻的了解,有助于新型透皮纳米制剂的设计,并利用综合手段构建安全、高效、实用的经皮给药系统。     

Migration of Toxoplasma gondii across biological barriers

The molecular mechanisms underlying migration of pathogens across biological barriers remain poorly characterized. Following oral infection, the apicomplexan parasite Toxoplasma gondii actively crosses non-permissive biological barriers such as the intestine, the blood-brain barrier and the placenta, thereby gaining access to tissues where it causes severe pathology. Recently, enhanced migration was found to be associated with virulent strains of Toxoplasma, suggesting that this phenotype contributes to pathogenesis. The migratory machinery appears to be morphologically and functionally well conserved within the phylum of apicomplexan parasites, however, the mechanisms for cellular traffic to breach biological barriers remain to be elucidated. As penetration of host tissue is a prerequisite for the establishment of infections by most apicomplexan parasites, understanding parasite migration is crucial for the development of new approaches to combat disease.     

Release of indomethacin from pH-sensitive pullulan acetate microsphere

We studied the pH-sensitive indomethacin (IND) delivery system using pullulan. Hydrophobic pullulan acetate was prepared by chemical modification of hydrophilic pullulan and pullulan acetate microsphere was made by a solvent evaporation method. The size of microspheres was below 5 μm, and the drug loading efficiencies of microspheres were approximately 78 and 65% at the initial amount of drug 40 and 80 mg, respectively. The microsphere showed pH-sensitive swelling behavior in PBS buffer. After 15 hrs, the swelling of the microsphere at pH 7.4 was approximately 20 times greater than that at pH1.2. The pH of the medium significantly influenced on thein vitro release rate. The released amount of drug at pH 7.2 was approximately 90 times greater than that at pH 1.2. The shape of microspheres at pH 1.2 were maintained sphere forms, but at pH 7.4 were disintegrated. The pH-sensitive IND release pattern was due both to the pH-sensitive diffusion of IND from the microspheres and to the release of the drug from the surface which underwent disintegration after swelling, due to the chemical composition of the microspheres and the pH of the release media.     

On the entry of semliki forest virus into BHK-21 cells

The pathway by which semliki forest virus (SFV), a membrane-containing animal virus, enters BHK-21 cells was studied morphologically and biochemically. After attaching to the cell surface, the majority of viruses was rapidly trapped into coated pits, internalized by endocytosis in coated vesicles, and sequestered into intracellular vacuoles and lysosomes. Direct penetration of viruses through the plasma membrane was never observed. To assess the possible involvement of lysosomes in the release of the genome into the cytoplasm, the effect of five lysosomotropic agents, known to increase the lysosomal pH, was tested. All of these agents inhibited SFV infectivity and one, chloroquine (the agent studied in most detail), inhibited a very early step in the infection but had no effect on binding, endocytosis, or intracellular distribution of SFV. Thus, the inhibitory effect was concluded to be either on penetration of the nucelocapsid into the cytoplasm or on uncoating of the viral RNA. Possible mechanisms for the penetration of the genome into the cytoplasm were studied in vitro, using phospholipids-cholesterol liposomes and isolated SFV. When the pH was 6.0 or lower, efficient fusion of the viral membranes and the liposomal membranes occurred, resulting in the transfer of the nucleocapsid into the liposomes. Infection of cells could also be induced by brief low pH treatment of cells with bound SFV under conditions where the normal infection route was blocked. The results suggest that the penetration of the viral genome into the cytosol takes place intracellularly through fusion between the limiting membrane of intracellular vacuoles and the membrane of viruses contained within them. The low pH required for fusion together with the inhibitory effect of lysosomotropic agents implicate lysosomes, or other intracellular vacuoles with sufficiently low pH, as the main sites of penetration.     

Sucrose release from soybean leaf slices

The release of photosynthate from leaf slices of soybean [ Glycine max (L.) Merr. cv. Ransom II], to a bathing medium was studied to ascertain how p -chloromercuribenzenesulfonic acid (PCMBS) can both stimulate and inhibit sucrose release. Soybean leaf slices released photosynthate to a bathing medium at a rate that was approximately linear with time. The photosynthate released was about 20% ionic and 80% non-ionic, and sucrose represented about 75% of the total. Removal of Ca²⁺ from the medium increased the rate of release of all fractions, but amino acid release showed the largest increase. Sucrose was released at a rate estimated to be about 20% of the normal transport rate in intact leaves. The rate of sucrose uptake from 5 m M sucrose into soybean leaf slices was optimum at pH 6.3, and the rate of sucrose release was lowest at the same pH. However, sucrose uptake was found to be insignificant during release experiments. Sucrose release, but not amino acid release, was inhibited 75% by 1 m M PCMBS.
The data support two components of sucrose release in leaves. The first is insensitive to the addition of PCMBS. This component probably represents leakage from phloem tissue. The second component is inhibited by PCMBS and probably represents release from the mesophyll. By comparing sucrose release from leaf slices of 12 different species of plants, 2 groups were found. In the first group, sucrose release was inhibited between 60 and 80% by PCMBS, and in the second group between 0% and 40%. The difference in the two groups can be explained by a relative difference in the size of the two components of sucrose release for each species.