On cell organelles in Tetrahymena. With special reference to mitochondria and peroxisomes

Antioxidant Effects of Argan Oil and Olive Oil against Iron-Induced Oxidative Stress: In Vivo and In Vitro Approaches

Recently, the study of the protective powers of medicinal plants has become the focus of several studies. Attention has been focused on the identification of new molecules with antioxidant and chelating properties to counter reactive oxygen species (ROS) involved as key elements in several pathologies. Considerable attention is given to argan oil (AO) and olive oil (OO) due to their particular composition and preventive properties. Our study aimed to determine the content of AO and OO on phenolic compounds, chlorophylls, and carotenoid pigments and their antioxidant potential by FRAP and DPPH tests. Thus, several metallic elements can induce oxidative stress, as a consequence of the formation of ROS. Iron is one of these metal ions, which participates in the generation of free radicals, especially OH from H2O2 via the Fenton reaction, initiating oxidative stress. To study the antioxidant potential of AO and OO, we evaluated their preventives effects against oxidative stress induced by ferrous sulfate (FeSO4) in the protozoan Tetrahymena pyriformis and mice. Then, we evaluated the activities of the enzymatic (superoxide dismutase (SOD), glutathione peroxidase (GPx)) and metabolite markers (lipid peroxidation (MDA) and glutathione (GSH)) of the antioxidant balance. The results of the antioxidant compounds show that both oils contain phenolic compounds and pigments. Moreover, AO and OO exhibit antioxidant potential across FRAP and DPPH assays. On the other hand, the results in Tetrahymena pyriformis and mice show a variation in the level of iron-changed SOD and GPx activities and MDA and GSH levels. By contrast, treating Tetrahymena pyriformis and mice with argan and olive oils shows significant prevention in the SOD and GPx activities. These results reveal that the iron-changed ROS imbalance can be counteracted by AO and OO, which is probably related to their composition, especially their high content of polyphenols, sterols, and tocopherols, which is underlined by their antioxidant activities.

Intracellular bioaccumulation of the rare earth element Gadolinium in ciliate cells resulting in biogenic particle formation and excretion

Ciliates are abundant unicellular organisms capable of resisting high concentrations of metal ions in the environment caused by various anthropogenic activities. Understanding the cellular pathways involved in resistance to and detoxification of elements is required to predict the impact of ciliates on environmental element cycles. Here, we investigated the so far unknown process of tolerance, cellular uptake and bioaccumulation of the emerging rare earth element gadolinium (Gd) in the common ciliate Tetrahymena pyriformis. Gd treatment results in the intracellular formation and excretion of biogenic Gd-containing particles. This cellular process effectively removes dissolved Gd from the organic growth medium by 53.37% within 72 h. Based on light and electron microscopic observations, we postulate a detoxification pathway: Cells take up toxic Gd³⁺ ions from the medium by endocytosis, process them into stable Gd-containing particles within food vacuoles, and exocytose them. Stable biogenic particles can be isolated, which are relatively homogeneous and have a diameter of about 3 µm. They consist of the elements Gd, C, O, P, Na, Mg, K, and Ca. These findings broaden the view of metal ion accumulation by protists and are of relevance to understand environmental elemental cycles and may inspire approaches for metal recovery or bioremediation.

Importance of protozoa Tetrahymena in toxicological studies: A review

Tetrahymena is a single-cell eukaryotic organism present in all aquatic environments and can easily be maintained in laboratory conditions in a cost-effective manner. This review gives a brief description of the physiology of Tetrahymena, culture handling, and maintenance of Tetrahymena species. The review article focuses on various toxicological bioassays at different biological organizational (biochemical, individual, population, and community) levels. Furthermore, some techniques such as single cell gel electrophoresis (SCGE) and microcalorimetry assay are also available to investigate the effect of xenobiotics on the integrity of DNA and metabolic state of Tetrahymena species respectively. The article also discusses how the general physiology, behavioural activities and different organelles of Tetrahymena could be useful in toxicological studies. The strength and limitations of Tetrahymena over other model organisms are also discussed. This article also provides suggestions to overcome some problems related to toxicity assessment. Various aspects associated with variability in results, toxicity endpoints, characteristics of organisms and responses against xenobiotic substances (old and new emerging toxicants) are considered.

Involvement of Tetrahymena pyriformis and selected fungi in the elimination of anthracene, and toxicity assessment of the biotransformation products

Anthracene (AC) is a non-mutagenic and non-carcinogenic, low-molecular-weight polycyclic aromatic hydrocarbon present in the environment. Its toxicity can be dramatically increased after solar-light exposure. Biotransformation capacities of AC by Tetrahymena pyriformis and a selection of eight micromycetes were studied, and the ability of these microorganisms to detoxify the polluted ecosystems was assessed. We showed that T. pyriformis was able to accumulate high amounts of AC without any transformation. In contrast, the fungi Cunninghamella elegans, Absidia fusca, Absidia cylindrospora, Rhodotorula glutinis, and Aspergillus terreus were able to transform AC with a high efficiency. Cytotoxicity assays conducted on HeLa cells and T. pyriformis showed that crude extract from A. fusca culture medium obtained after AC biotransformation was not toxic. For A. fusca and A. cylindrospora, 1-4 dihydroxyanthraquinone was shown to be the major product during the biotransformation process. This compound seemed to be a dead-end metabolite at least for the Absidia strains. The cytotoxicity of 1-4 dihydroxyanthraquinone was higher than that of AC to T. pyriformis but lower to HeLa cells. On the whole our results showed that the microorganisms studied were all able to decontaminate an AC-polluted ecosystem, either by accumulating or transforming the compound. A possible detoxification process resulting from AC biotransformation can be considered only using the human cell model.

Assessment of anthracene toxicity toward environmental eukaryotic microorganisms: Tetrahymena pyriformis and selected micromycetes

The toxicity of anthracene, a nonmutagenic, noncarcinogenic, low-molecular-weight polycyclic aromatic hydrocarbon present in the environment, was assessed using a ciliated protozoan, Tetrahymena pyriformis, and a selection of 10 micromycetes from different taxonomic groups living in two environmental compartments, namely aquatic and soil ecosystems. With T. pyriformis, a concentration-dependent inhibitory effect was shown on the cell proliferation rate, IC(50) = 33.40+/-4.84 mg/L (kinetic method). Phagocytosis of nonsoluble anthracene was confirmed by the presence of digestive vacuoles with photon microscopy. In fungi, anthracene did not exhibit a fungicide effect but showed a fungistatic action. Except for Absidia fusca and Cladosporium herbarum, the micromycetes showed a concentration-dependent decrease in growth. From IC(50) values determined by endpoint or kinetic methods, Rhodotorula glutinis and all of the Ascomycotina (except for Penicillium chrysogenum) were the most sensitive species, while Phanerochaete chrysosporium, P. chrysogenum, and the two Deuteromycotina were more resistant to anthracene. Our discussion focuses on the evaluation of toxicity by the two methods used for the calculation of the IC(50) values (endpoint and kinetic), the advantages of studying growth by a kinetic method (the dynamic aspect), and a comparison of toxicity to T. pyriformis and the different micromycetes.

Extrusomes in Ciliates: Diversification, Distribution, and Phylogenetic Implications

Exocytosis is, in all likelihood, an important communication method among microbes. Ciliates are highly differentiated and specialized micro-organisms for which versatile and/or sophisticated exocytotic organelles may represent important adaptive tools. Thus, in ciliates, we find a broad range of different extrusomes, i.e ejectable membrane-bound organelles. Structurally simple extrusomes, like mucocysts and cortical granules, are widespread in different taxa within the phylum. They play the roles in each case required for the ecological needs of the organisms. Then, we find a number of more elaborate extrusomes, whose distribution within the phylum is more limited, and in some way related to phylogenetic affinities. Herein we provide a survey of literature and our data on selected extrusomes in ciliates. Their morphology, distribution, and possible function are discussed. The possible phylogenetic implications of their diversity are considered.

Cytotoxicity assessment of three therapeutic agents, cyclosporin-A, cisplatin and doxorubicin, with the ciliated protozoan Tetrahymena pyriformis

Cyclosporin-A, a drug possessing potent immunosuppressive properties, is used to prevent allograft rejection. Cisplatin and doxorubicin are two of the pharmaceutical drugs most widely used in cancer chemotherapy. In this study, the cytotoxicological impact of these three therapeutic agents was determined using bioassays performed with a unicellular eukaryote, the ciliated protozoan Tetrahymena pyriformis. For this purpose we used the population growth impairment test and the non-specific esterase activities test. We also examined some morphological effects. The results show that these three agents are toxic towards T. pyriformis. A concentration-dependent inhibitory effect on the cell proliferation rate of T. pyriformis populations was found for the three drugs. The IC(50) values were, respectively, 42.03+/-4.64, 124.37+/-7.47 and 74.62+/-6.12 microM for cyclosporin-A, cisplatin and doxorubicin. Non-specific esterase activities were also modified compared with untreated cells. The IC(50) values were, respectively, 88.32+/-8.35 and 44.61+/-3.33 microM for cisplatin and doxorubicin. Exposure of T. pyriformis to these drugs caused the prompt appearance of digestive vacuoles concentrating particulate elements. This phenomenon was more pronounced at higher concentrations. We also observed deformed cells with cisplatin. T. pyriformis bioassays can offer an alternative in vitro method to cell cultures for the risk assessment of potentially toxic drugs.

Tetrahymena pyriformis: a tool for toxicological studies. A review

Among protozoa, Tetrahymena pyriformis is the most commonly ciliated model used for laboratory research. After a brief description of the morphology and biology of Tetrahymena pyriformis, this article focuses on the most important and recent investigations performed with this species in toxicology and ecotoxicology. The methodological features of its culture, and main tests, based on cell growth rate, biochemical markers, behavioral changes and motility, are discussed. Examples of xenobiotics (organic and inorganic substances, pharmaceutical drugs, water pollutants) tested with Tetrahymena pyriformis are also given.

pH-dependent effects of 2,4-dinitrophenol (DNP) on proliferation, endocytosis, fine structure and DNP resistance in Tetrahymena

In view of the importance of external pH on cytotoxic effects of ionizable agents, the pH-dependent effects of 2,4-dinitrophenol (DNP) were investigated. As uncoupler of oxidative phosphorylation, DNP interferes with the proton gradient across the inner mitochondrial membrane. DNP was added to proliferating Tetrahymena pyriformis in media of different initial pH. Effects studied were rates of cell proliferation and endocytosis, and fine structure. Findings correlated with the calculated concentration of undissociated DNP, taking into account that pH changes with time and cell density in Tetrahymena cultures. A linear relationship thus emerged between initial concentrations of undissociated DNP and lengths of the lag preceding cell proliferation. Once resumed, the rate of proliferation corresponded to that of control cells, even in different concentrations of undissociated DNP, presumably indicating an adaptation mechanism. Endocytosis was elevated throughout a wide range of undissociated DNP concentrations with a sharp transition towards inhibition at high DNP concentrations causing lethality with time. Changes in fine structure of DNP-treated cells (mitochondria, peroxisomes, nucleoli) also depended on the concentration of undissociated DNP.

Ultrastructural and cytochemical identification of peroxisomes in the ciliate Ichthyophthirius multifiliis

The peroxisomes of the parasitic ciliate Ichthyophthirius multifiliis were studied, using ultrastructural and cytochemical techniques. In this ciliate most peroxisomes possess a circular or oval section less than 0.6 micron in diameter. However, some dumbbell-shaped and elongated peroxisomes could also be observed. These organelles were frequently associated with the mitochondria and were more abundant in the cell cortex than in the center of the ciliate. Small vesicles and dense nucleoids were usually present in the ultrathin sections of these peroxisomes. Peroxisomal vesicles and tubular structures were selectively impregnated with osmium tetroxide. Catalase was detected by cytochemical techniques in I. multifiliis peroxisomes.

Does chloroquine, an antimalarial drug, affect autophagy in Tetrahymena pyriformis?

The effect of chloroquine (CQ) on autophagy was studied in starved Tetrahymena pyriformis. When a proliferating Tetrahymena culture is transferred to a starvation medium, autophagy commences although cells most advanced in the cell cycle will divide. The drug was added to 1-h starved cells at different pH values because CQ affects pH dependently. The CQ concentration blocking all cell divisions was determined as the lowest toxic, but sublethal, concentration. Hence, the highest tolerated concentrations at pH 6.8, 7.1, and 7.7 were 1.0, 0.3, and 0.03 mM CQ, respectively. Lower CQ concentrations had a dose-dependent effect on cell increment and higher concentrations induced cell mortality. Rates of cell motility and decreases in cell volume were affected by the drug, while the capacity for endocytosis was unaffected in low concentrations but affected dose dependently in high concentrations. Light microscopically, all drug-treated cells contained small refractive bodies, but in toxic concentrations they also contained conspicuously large vacuoles. After 1 h and 4 h in CQ, fine structure analysis showed autophagosomes with electron-dense material in cells in tolerated concentrations and of enlarged size, but decreased number, in toxic concentrations. The contents of autophagosomes revealed cell organelles in different stages of disintegration. The conclusion is that the drug enhances autophagy in Tetrahymena in a pH-, dose-, and time-dependent manner.

The influence of growth phase and culture conditions of Tetrahymena on effects of cadmium

The batch culture system is used in the majority of toxicity studies employing protozoa and other cell cultures, although it is known that metal toxicity may vary depending on the age and therefore on the physiological state of the culture. The ciliate Tetrahymena was exposed to cadmium during short-term incubations at different stages of the growth cycle. In cultures with cells proliferating at a high rate (log phase cells) the toxicity of cadmium was found to increase with increasing initial cell density. However, in the subsequent stationary growth phase with decreased rate of cell proliferation, the sensitivity against cadmium again decreases. Thus the effect of a given concentration of cadmium depends on the initial cell density of the culture. This effect of cadmium may be explained either by changes in the chemical composition of the culture medium during the growth cycle or by a changed cellular metabolism. Furthermore, it is shown that the cadmium concentration of the medium decreases during prolonged exposure when the cells are grown in batch cultures. Some of the problems associated with the toxicity bioassay performed in a static system may be overcome by using a continuous flow system. In such a system, Tetrahymena can be kept under optimal growth conditions with a generation time of less than 3 h, and any cell density may be maintained for extended periods of time. Furthermore, the cadmium concentration of the medium remained constant during prolonged exposure when maintaining a cell density of about 50 x 10(3) cells/ml. This illustrates the great advantage of using a continuous flow system in such investigations, where for example, long-term adaptations of the organism to a metal may be studied under constant conditions.

Variation in the growth medium during the culture cycle of Tetrahymena: with special reference to ammonia (NH3), ammonium (NH4+), and pH1

The ciliate Tetrahymena pyriformis was grown in a peptone medium without added glucose. The interrelationship between increasing cell density and pH of the growth medium was studied from mid-log to the stationary phase, i.e. from 50,000 to 1,000,000 cells/ml, by continuous registration of the pH of the growth medium. The present findings correlate with the known physiological, biochemical, and structural changes occurring in Tetrahymena as it passes through the culture cycle. The ammonia production of the cells and the buffer capacity of the growth medium were determined throughout the growth cycle. The results revealed that the ammonia excreted by the cells can explain the increase in pH of the medium from 6.8 to about 8.3 normally seen during the culture cycle. Moreover, neither the increased pH nor the raised level of ammonia were found to be the responsible factor for cessation of cell proliferation in the stationary growth phase although these factors may affect cell proliferation in concentrations well beyond the range found in normal cultures.

Light and electron microscope observation of virus-induced Tetrahymena pyriformis in newborn mice (Mus musculus albinicus) brain

Newborn mice were infected intracerebrally with abacterial cultures of the GL strain of Tetrahymena pyriformis, induced experimentally six years ago in vitro with Coxsackie B-5 virus. In the brain of the test animals there were pathologic changes similar to those found in the primary investigation of the pathogenicity of this strain, i.e., after 96 h of contact with the virus. Thus, the pathogenicity acquired by T. pyriformis, as well as the persistence of Coxsackie B-5 virus in this ciliate, can be considered stable. Despite such specific changes in the biological properties of T. pyriformis, the changes were not reflected in the morphology of the protozoon, which was investigated by means of light and electron microscopy.

Biochemical and ultrastructural data on Tetrahymena pyriformis treated with copper and cadmium

The addition of copper (10 micrograms ml-1) or cadmium (5 micrograms ml-1) to the medium is well tolerated by Tetrahymena pyriformis GL. Both metals are accumulated by cells, cadmium to a greater extent than copper. The growth rate is not affected and from the micrographs it is evident that the ultrastructure is not altered by the treatments. After 3 days of culture the macronucleus contains dense masses of chromatin and numerous nucleolar fusion bodies. Granules, cytolysomes and many food vacuoles are present in both control and treated cells. Cadmium induces the formation of a chelating protein; the amino acid analyses and the ultraviolet spectrum indicate that it is similar to the metallothionein isolated by higher organisms. The molecular weight of native protein is about 27,000. After treatment by sulphitolysis or oxidation we obtained a peak of molecular weight at about 6,000. The treatment with copper does not appear to induce metallothioneins or other chelatins. The high tolerance of Tetrahymena towards cadmium is believed to be due to the formation of a Cd-Zn metallothionein. The different chelating proteins induced by copper and cadmium in other groups of Protozoa and the different detoxification mechanisms present in these organisms are discussed.

Development of peroxisomes in amphibians. III. Study on liver, kidney, and intestine during thyroxine-induced metamorphosis

This investigation was undertaken to study the ontogeny of hepatic, renal, and intestinal peroxisomes and/or microperoxisomes during thyroxine-induced anuran metamorphosis. Catalase activity was localized cytochemically after incubation in DAB medium, and studied biochemically by a spectrophotometric method. Our morphological and biochemical investigations suggest the formation of a new population of peroxisomes during the hormonal treatment. This is obvious especially for microperoxisomes of the intestinal epithelium since the larval tissue is completely replaced by a new layer during thyroxine-induced metamorphosis. For the peroxisomes of hepatocytes and kidney proximal tubule cells, our assumption is based on the following observations: 1) The number of peroxisomes increases in liver and kidney during thyroxine treatment; 2) this proliferation is accompanied by an enlargement of renal peroxisomes; and 3) 16 days after the beginning of the hormonal treatment, 5.4- and 2.4-fold increases are found for the specific activities of hepatic and renal catalase, respectively. A temporal coordination exists between the structure and the metabolism of peroxisomes and mitochondria during thyroxine-induced metamorphosis.