Tritrichomonas foetus infection in cat - first detection in Poland.

Tritrichomonas foetus, a parasite of cattle reproductive system, has been recently discovered as a cause of disease in cats in many countries. T. foetus infects and colonizes cat's ileum, caecum, colon and can lead to enteritis. This paper presents the first clinical case of cat intestinal trichomonosis caused by T. foetus in Poland. The material for this study was a smear collected from a 6-month-old male British Shorthair cat. The presence of parasitic protozoan was determined via microscopic examination and confirmed by amplification of T. foetus rDNA using polymerase chain reaction (PCR) technique. In the first PCR reaction, a DNA of Trichomonadidae was identified and in the second PCR, T. foetus was detected. The T. foetus positive products from the second PCR reaction were sequenced. Interpretation of the sequencing results of obtained amplicons by comparing them with the GenBank database proved that the causative agent, in this case, was T. foetus.

Changes in the structural organization of the cytoskeleton of Tritrichomonas foetus during trophozoite-pseudocyst transformation.

Tritrichomonas foetus is a parasite that causes bovine trichomonosis, a major sexually transmitted disease in cattle. It grows in axenic media as a trophozoite with a pear-shaped body, three anterior flagella, and one recurrent flagellum. However, under some well-controlled experimental conditions in vitro, as well as in vivo in infected bulls, the parasite acquires a spherical or elliptical shape, and the flagella are internalized but the cells do not display a cyst wall. This form, known as the endoflagellar or pseudocystic form, is viable, and can be transformed back to trophozoites with pear-shaped body. We used confocal laser scanning microscopy, and high resolution scanning electron microscopy to examine the changes that take place in the protozoan cytoskeleton during trophozoite-pseudocyst transformation. Results confirmed previous studies and added new structural information to the organization of cytoskeletal structures during the transformation process. We observed that changes take place in the pseudocysts' axostyle and costa, which acquired a curved shape. In addition, the costa of multinucleated/polymastigont pseudocysts took variable conformations while curved. The costa accessory structure, as well as a network of filaments connecting this structure to the region where the recurrent flagellum associates to the protozoan body, was not seen in pseudocysts. In addition, the axostyle was fragmented during trophozoite-pseudocyst transformation.

Photodynamic therapy in the cattle protozoan Tritrichomonas foetus cultivated on superhydrophilic carbon nanotube.

Superhydrophilic vertically aligned carbon nanotubes (VACNT-O2) were used for the first time as scaffolds for photodynamic therapy (PDT) to induce inhibition of cell division in eukaryotic cells. VACNT-O2 scaffolds were produced on Ti substrates using plasma enhanced chemical vapor deposition technique and functionalized by oxygen plasma. Scanning electron microscopy (SEM) analysis was performed to characterize the surface changes of the protozoan and interaction with VACNT-O2. Characterization of lipid and total protein expression was performed with protozoa that were or not treated with PDT. Quantification of protein was conducted using Qubit fluorometer and separated on a polyacrylamide gel. SEM analysis showed the release of lipid vesicles by protozoa after the PDT. These vesicles were characterized by the PKH26 fluorescent probe. The results demonstrated a greater amount of protein released after PDT than in the control. When analyzing the protein material in polyacrylamide gel, a significant protein expression of approximately 65 kDa was found. A model identified the programmed death of Tritrichomonas foetus after the PDT was also proposed.

The biology and control of Giardia spp and Tritrichomonas foetus.

The biology and control of Giardia spp in dogs and cats, and Tritrichomonas foetus in cats is reviewed, including nomenclature, morphology, life cycle, epidemiology, pathogenic process, clinical signs, diagnosis, treatment and control, and public health aspects. These surprisingly similar protozoan pathogens are both clinically significant in veterinary clinical medicine.

Tritrichomonas foetus: budding from multinucleated pseudocysts.

Tritrichomonas foetus is a flagellated protozoan parasite that causes trichomoniasis, a major sexually transmitted disease in cattle. T. foetus presents a simple life cycle, exhibiting only the trophozoitic form. However, under unfavorable growth conditions, the trophozoites, which are polar and flagellated, can round up and internalize their flagella forming pseudocysts. In this form no cyst wall surrounds the cell and it also displays a distinct mitosis when compared with the trophozoite form. In pseudocyst mitosis, the cell proceeds with duplication of cytoskeletal and mastigont structures; nuclear division occurs but without the corresponding cytoplasm division. Thus, giant multinucleated cells which present many mastigont structures are formed (approximately 62% of the population). These polymastigont/multinucleated cells are maintained when the cells are under stress conditions. When environmental conditions become favorable, the flagella are externalized and new flagellated trophozoites one by one, gradually bud from the multinucleated cell. Thus, in order to better understand the pseudocyst mitosis, the polymastigont formation and the generation of new cells by this budding process, video microscopy and other complementary techniques, such as immunofluorescence and transmission electron microscopy were used.

Tritrichomonas foetus pseudocysts adhere to vaginal epithelial cells in a contact-dependent manner.

Tritrichomonas foetus is a parasitic protist of the urogenital tract of cattle. It presents the trophozoite stage, a motile elongated form that constitutes most of the cells in a normal population, and a pseudocyst stage, an immotile rounded form that appears under unfavourable environmental conditions. In the present report pseudocysts were studied in natural conditions and after induction by chemicals or cycles of cooling and warming of cultures. The capacity of T. foetus to adhere to vaginal epithelial cells (VECs) was compared for both trophozoite and pseudocyst forms. By the use of video-enhanced-contrast microscopy, scanning and transmission electron microscopy, and immunofluorescence microscopy techniques, we present evidence that: (1) T. foetus easily internalizes the flagella and forms pseudocysts under several unfavourable conditions; (2) T. foetus in both pseudocyst and trophozoite forms is able to adhere to VECs; (3) the adhesion rate is higher for pseudocysts than for trophozoites; (4) the adhesin Tf190 is expressed in both forms during interaction; (5) the adhesion process of pseudocysts seems to occur in a contact-dependent manner. Thus, we propose that the pseudocyst stage is not a degenerative form, but a functional life form that is able to interact with and firmly adhere to VECs.

The effect of drugs on cell structure of Tritrichomonas foetus.

The effects of the microtubule affecting drugs taxol, nocodazole and colchicine on the cell cycle and ultrastructure of Tritrichomonas foetus, a protist parasite of cattle, were studied. Alterations in the cytoskeleton, motility and organellar ultrastructure were followed using anti-tubulin antibodies and fluorescence microscopy, scanning- and transmission-electron microscopy. Flow cytometry was also used to analyze the effect of the drugs on the cell cycle. T. foetus was treated with 10 microM taxol, 15 microM nocodazole or 1.5 mM colchicine for 12 h. The first effect observed was pseudocyst formation and alterations in cell motility. The cell cycle was affected and the cells have blocked cytokinesis, but not karyokinesis. The behavior of Golgi, hydrogenosomes and vacuoles was analyzed. The following effects were seen following drug treatments: (1) cell motility was altered and flagella internalized; (2) microtubules of the pelta-axostyle complex were not depolymerized and the axostyle assumed a curved form; (3) hydrogenosomes were of abnormal size and shape; (4) cells became multinucleate; (5) the division process was blocked in cytokinesis; (6) autophagic vacuoles containing a large amount of microtubules were seen; (7) axoneme organization was altered; (8) zoids were formed; (9) signs of cell death, such as membrane blebbing, were observed.

Hydrogenosome behavior during the cell cycle in Tritrichomonas foetus.

The hydrogenosome is an unusual organelle found in several trichomonad species and other protists living in oxygen poor or anoxic environments. The hydrogenosome behavior in the protist Tritrichomonas foetus, parasite of the urogenital tract of cattle, is reported here. The hydrogenosomes were followed by light and transmission electron microscopy during the whole cell cycle. Videomicroscopy, immunofluorescence microscopy, and immunocytochemistry were also used. It is shown that the hydrogenosomes divide at any phase of the cell cycle and that the organellar division is not synchronized. During the interphase the hydrogenosomes are distributed mainly along the axostyle and costa, and at the beginning of mitosis migrate to around the nucleus. Three forms of hydrogenosome division were seen: (1). segmentation, where elongated hydrogenosomes are further separated by external membranous profiles; (2). partition, where rounded hydrogenosomes, in a bulky form, are further separated by a membranous internal septum and, (3). a new dividing form: heart-shaped hydrogenosomes, which gradually present a membrane invagination leading to the organelle division. The hydrogenosomes divide at any phase of the cell cycle. A necklace of intramembranous particles delimiting the outer hydrogenosomal membrane in the region of organelle division was observed by freeze-etching. Similarities between hydrogenosomes and mitochondria behavior during the cell cycle are discussed.

Tritrichomonas foetus: the role played by iron during parasite interaction with epithelial cells.

The aim of this work was to investigate the role played by iron during interaction of Tritrichomonas foetus with cultured epithelial cells. We have observed that the growth rate of T. foetus is influenced by the amount of iron available into culture medium. When organisms maintained for 24h in iron-depleted medium were transferred to an iron-rich one, many protozoan cells exhibited a cytokinesis blockage. Parasites maintained in iron-depleted medium exhibited a significant increase in cytoadhesion when compared with both controls and parasites that had been cultured in medium in which iron was replaced. T. foetus collected from iron-depleted medium also exhibited a reduction in its ability to destroy epithelial cell monolayers and a reduction in the activity of several cysteine proteases. Taken together, the results presented here demonstrate that iron may be an extracellular signal, which seems to modulate the ability of T. foetus to interact with host epithelial cells.

Ultrastructural localization of glycoconjugates in Tritrichomonas foetus.

We have probed Tritrichomonas foetus, a protozoan parasite of the urogenital tract of cattle, with gold-labeled and fluorescent lectins, for the localization of glycoconjugates, at the cell surface and in internal cell compartments. The following lectins were used: Con A, PNA, WGA, BSI, BSII, HPA, WFA, SBA, LFA, HPA, and LCA. Carbohydrates were also localized using the Thiéry's technique. Carbohydrate residues were observed in the Golgi and vesicles with all lectins used. However, the labeling pattern varied among the cisternae. A high heterogeneity of cell labeling was detected in the same preparation. The nucleus and the nuclear envelope were labeled with Con A, WGA, BSI, and UEA I, suggesting the presence of D-Man, and/or D-glucose, L-fucose, and GlcNAc. Lysosomes were labeled with Con A and intensely labeled with HPA. The intensity of labeling of the plasma and flagellar membranes varied according to the lectin used.

Rational design of selective submicromolar inhibitors of Tritrichomonas foetus hypoxanthine-guanine-xanthine phosphoribosyltransferase.

All parasitic protozoa lack the ability to synthesize purine nucleotides de novo, relying instead on purine salvage enzymes for their survival. Hypoxanthine-guanine-xanthine phosphoribosyltransferase (HGXPRT) from the protozoan parasite Tritrichomonas foetus is a rational target for antiparasitic drug design because it is the primary enzyme the parasite uses to salvage purine bases from the host. The study presented here is a continuation of our efforts to use the X-ray structure of the T. foetus HGXPRT-GMP complex to design compounds that bind tightly to the purine pocket of HGXPRT. The goal of the current project was to improve the affinity and selectivity of previously identified HGXPRT inhibitor TF1 [4-(3-nitroanilino)phthalic anhydride]. A virtual library of substituted 4-phthalimidocarboxanilides was constructed using methods of structure-based drug design, and was implemented synthetically on solid support. Compound 20 [(4'-phthalimido)carboxamido-3-benzyloxybenzene] was then used as a secondary lead for the second round of combinatorial chemistry, producing a number of low-micromolar inhibitors of HGXPRT. One of these compounds, TF2 [(4'-phthalimido)carboxamido-3-(4-bromobenzyloxy)benzene], was further characterized as a competitive inhibitor of T. foetus HGXPRT with respect to guanine with a K(I) of 0.49 microM and a 30-fold selectivity over the human HGPRT. TF2 inhibited the growth of cultured T. foetus cells in a concentration-dependent manner with an ED(50) of 2.8 microM, and this inhibitory effect could be reversed by addition of exogenous hypoxanthine. These studies underscore the efficiency of combining structure-based drug design with combinatorial chemistry to produce effective species-specific enzyme inhibitors of medicinal importance.

Purification and biochemical characterization of the hydrogenosomes of the flagellate protozoan Tritrichomonas foetus.

A highly purified hydrogenosomal fraction was obtained from Tritrichomonas foetus by differential and Percoll gradient centrifugations. Transmission electron microscopy and assay of the malic enzyme activity were used to evaluate the isolation method and the integrity of the organelle. The isolated hydrogenosomes showed the same morphology as observed in intact cells, including the presence of a peripheral vesicle with an electron-dense content. SDS-PAGE revealed the presence of several protein bands, with those of 120, 66, 60, 59, 48, 45, and 35 kDa as the major ones. The hydrogenosome membrane was solubilized with Triton X-100 leaving a fraction containing its matrix attached to the peripheral vesicle. Further treatment with proteinase K solubilized the matrix components, leaving a pure peripheral vesicle fraction. Enzymatic assay during all procedures suggested that malate dehydrogenase was localized in the hydrogenosomal membrane. SDS-PAGE showed that proteins of 66, 45 and 32 kDa were localized in the peripheral vesicle. Western blot analysis of all fractions using alkaline phosphatase-conjugated wheat germ agglutinin revealed the presence of glycoproteins, with a major one of 45 kDa, in the peripheral vesicle of the hydrogenosome.

Partial characterization of cytoplasmic compartments involved in the endocytic process of Tritrichomonas foetus.

The endocytic pathway of Tritrichomonas foetus, a parasitic protozoan of cattle, was studied using (a) vital dyes, such as Lucifer yellow, neutral red and acridine orange, (b) cationized ferritin, (c) gold-labeled lactoferrin and lectins: HPA, UEA, PNA and LPA, and (d) DAMP (3-(2,4-dinitroanilino) 3' amino-N-methyldipropylamine). Light and confocal laser microscopy as well as transmission electron microscopy were used in this study. Assays were monitored by fluorescence and electron microscopy after exposing the parasites to different conditions. Cells that were incubated at 15 degrees C or 20 degrees C with gold-labeled lactoferrin and processed for electron microscopy show that of 15 degrees C this ligand is found only in an early endosomal compartment and at 20 degrees C it is found in late endosomes but not in lysosomes. Immunocytochemical data from cryosections using DAMP as a pH probe show that T. foetus has acidic compartments, with a pH range of 5.2 to 6.6, with variable morphology, localization and size. Lectin-binding sites and anionic sites were also internalized and appear to be associated with membranes lining the vacuoles. Images of patching and shedding of these sites were also observed when HPA and UEA were used.

Morphogenesis of the hydrogenosome: an ultrastructural study.

The morphogenesis of hydrogenosomes in several trichomonad species (Tritrichomonas foetus, Trichomonas vaginalis, Tritrichomonas suis, Trichomonas gallinae, Tritrichomonas augusta and Monocercomonas sp) was investigated by transmission electron microscopy of thin sections and freeze-fracture replicas of whole cells or the isolated organelle. Close proximity, and even continuity, between endoplasmic reticulum and hydrogenosomes was observed. Structures were seen connecting hydrogenosomes to each other and to cytoplasmic structures. Morphological evidence is presented showing that in all the trichomonads here studied, hydrogenosomes, like mitochondria, may divide by two distinct processes: segmentation and partition. In the segmentation process, the hydrogenosome grows, becoming enlongated with the appearance of a constriction in the central portion. Microfibrillar structures appear to help the furrowing process, ending with a total fission of the organelle. In the partition process, the division begins by an invagination of the inner hydrogenosome membrane, forming a transversal septum, separating the organelle matrix into two compartments. We suggest that myelin-like structures seen either in close contact with or in the vicinity of the hydrogenosomes may be a source of membrane lipids for hydrogenosome growth.