Cysteine protease activity of feline Tritrichomonas foetus promotes adhesion-dependent cytotoxicity to intestinal epithelial cells.

Trichomonads are obligate protozoan parasites most renowned as venereal pathogens of the reproductive tract of humans and cattle. Recently, a trichomonad highly similar to bovine venereal Tritrichomonas foetus but having a unique tropism for the intestinal tract was recognized as a significant cause of colitis in domestic cats. Despite a high prevalence, worldwide distribution, and lack of consistently effective drugs for treatment of the infection, the cellular mechanisms of T. foetus pathogenicity in the intestinal tract have not been examined. The aims of this study were to determine the pathogenic effect of feline T. foetus on porcine intestinal epithelial cells, the dependence of T. foetus pathogenicity on adhesion of T. foetus to the intestinal epithelium, and the identity of mediators responsible for these effects. Using an in vitro coculture approach to model feline T. foetus infection of the intestinal epithelium, these studies demonstrate that T. foetus promotes a direct contact-dependent activation of intestinal epithelial cell apoptosis signaling and progressive monolayer destruction. Moreover, these pathological effects were demonstrated to be largely dependent on T. foetus cell-associated cysteine protease activity. Finally, T. foetus cysteine proteases were identified as enabling cytopathic effects by promoting adhesion of T. foetus to the intestinal epithelium. The present studies are the first to examine the cellular mechanisms of pathogenicity of T. foetus toward the intestinal epithelium and support further investigation of the cysteine proteases as virulence factors in vivo and as potential therapeutic targets for ameliorating the pathological effects of intestinal trichomonosis.

New insights on the Golgi complex of Tritrichomonas foetus.

Tritrichomonas foetus is a protist that causes bovine trichomoniasis and presents a well-developed Golgi. There are very few studies concerning the Golgi in trichomonads. In this work, monoclonal antibodies were raised against Golgi of T. foetus and used as a tool on morphologic and biochemical studies of this organelle. Among the antibodies produced, one was named mAb anti-Golgi 20.3, which recognized specifically the Golgi complex by fluorescence and electron microscopy. By immunoblotting this antibody recognized two proteins with 60 and 66 kDa that were identified as putative beta-tubulin and adenosine triphosphatase, respectively. The mAb 20.3 also recognized the Golgi complex of the Trichomonas vaginalis, a human parasite. In addition, the nucleotide coding sequences of these proteins were identified and included in the T. foetus database, and the 3D structure of the proteins was predicted. In conclusion, this study indicated: (1) adenosine triphosphatase is present in the Golgi, (2) ATPase is conserved between T. foetus and T. vaginalis, (3) there is new information concerning the nucleic acid sequences and protein structures of adenosine triphosphatase and beta-tubulin from T. foetus and (4) the mAb anti-Golgi 20.3 is a good Golgi marker and can be used in future studies.

Tritrichomonas foetus: characterisation of ecto-phosphatase activities in the endoflagelar form and their possible participation on the parasite's transformation and cytotoxicity.

The protist parasite Tritrichomonas foetus displays a pear-shaped (PS) and a pseudocystic or endoflagellar form (EFF). Here, we characterised the ecto-phosphatase activity on the surface of EFF and compare its biochemical properties to that of the PS regarding rate of substrate hydrolysis, pH activation profile and sensitivity to well-known phosphatases inhibitors. Two strains exhibiting low- and high-cytotoxicity were used. The enzyme activities of PS and EFF exhibited similar characteristics of protein tyrosine phosphatases (PTP). However, the ecto-phosphatase activities for both forms presented distinct kinetic parameters and different inhibition patterns by PTP inhibitors, suggesting the presence of distinct ecto-enzyme activities between PS and EFF, as well, between both strains. Ultrastructural cytochemistry confirmed the differential distribution of the ecto-phosphatase activity during the EFF transformation. An increase in the percentage of the EFF resulted in a proportional increase in the ecto-phosphatase activity. During EFF reversion, ecto-phosphatase activity decreased and was restored to the level found in the parasites before EFF induction. PS and EFF from the high-cytotoxic strain exhibited higher ecto-phosphatase activities than PS and EFF from the low-cytotoxic strain, respectively. In both strains, the EFF was more cytotoxic and exhibited higher ecto-phosphatase activity when compared to the PS. A large part of the ecto-phosphatase activities of EFF from both strains and PS from the high-cytotoxic strain was irreversibly inhibited when the parasites were pre-treated with a specific antibody against amoebic PTP (anti-EhPRL). Immunoreaction assays revealed that the anti-EhPRL antibody cross-reacted with a 24-kDa protein differentially expressed on the cell surface of PS and EFF T. foetus. A positive correlation was observed between the surface expression of 24-kDa protein and ecto-phosphatase activity. Irreversible inhibition of a part of the ecto-phosphatase activities partially blocked the EFF induction and the cytotoxic effects exerted by both forms. These results suggest that the ecto-phosphatase activities could play a role on the EFF transformation and cytotoxicity of T. foetus.

Unexpected properties of NADP-dependent secondary alcohol dehydrogenase (ADH-1) in Trichomonas vaginalis and other microaerophilic parasites.

Our previous observation that NADP-dependent secondary alcohol dehydrogenase (ADH-1) is down-regulated in metronidazole-resistant Trichomonas vaginalis isolates prompted us to further characterise the enzyme. In addition to its canonical enzyme activity as a secondary alcohol dehydrogenase, a pronounced, so far unknown, background NADPH-oxidising activity in absence of any added substrate was observed when the recombinant enzyme or T. vaginalis extract were used. This activity was strongly enhanced at low oxygen concentrations. Unexpectedly, all functions of ADH-1 were efficiently inhibited by coenzyme A which is a cofactor of a number of key enzymes in T. vaginalis metabolism, i.e. pyruvate:ferredoxin oxidoreductase (PFOR). These observations could be extended to Entamoeba histolytica and Tritrichomonas foetus, both of which have a homologue of ADH-1, but not to Giardia lamblia which lacks an NADP-dependent secondary alcohol dehydrogenase. Although we could not identify the substrate of the observed background activity, we propose that ADH-1 functions as a major sink for NADPH in microaerophilic parasites at low oxygen tension.

The Cys319 loop modulates the transition between dehydrogenase and hydrolase conformations in inosine 5'-monophosphate dehydrogenase.

X-ray crystal structures of enzyme-ligand complexes are widely believed to mimic states in the catalytic cycle, but this presumption has seldom been carefully scrutinized. In the case of Tritrichomonas foetus inosine 5'-monophosphate dehydrogenase (IMPDH), 10 structures of various enzyme-substrate-inhibitor complexes have been determined. The Cys319 loop is found in at least three different conformations, suggesting that its conformation changes as the catalytic cycle progresses from the dehydrogenase step to the hydrolase reaction. Alternatively, only one conformation of the Cys319 loop may be catalytically relevant while the others are off-pathway. Here we differentiate between these two hypotheses by analyzing the effects of Ala substitutions at three residues of the Cys319 loop, Arg322, Glu323, and Gln324. These mutations have minimal effects on the value of k(cat) (≤5-fold) that obscure large effects (>10-fold) on the microscopic rate constants for individual steps. These substitutions increase the equilibrium constant for the dehydrogenase step but decrease the equilibrium between open and closed conformations of a mobile flap. More dramatic effects are observed when Arg322 is substituted with Glu, which decreases the rates of hydride transfer and hydrolysis by factors of 2000 and 130, respectively. These experiments suggest that the Cys319 loop does indeed have different conformations during the dehydrogenase and hydrolase reactions as suggested by the crystal structures. Importantly, these experiments reveal that the structure of the Cys319 loop modulates the closure of the mobile flap. This conformational change converts the enzyme from a dehydrogenase into hydrolase, suggesting that the conformation of the Cys319 loop may gate the catalytic cycle.

Purification and analysis of DNases of Tritrichomonas foetus: evidence that these enzymes are glycoproteins.

Tritrichomonas foetus is the causative agent of trichomoniasis. In cattle, infection results in economic losses to the beef and dairy industries due to abortion and infertility. Soluble DNases of T. foetus that play a role in pathogenesis and are potential therapeutic targets, were extracted and purified utilising lectin affinity chromatography. The DNases were bound to and eluted from Concanavalin A (Con A)-sepharose indicating that they are glycoproteins with alpha-linked mannose or glucose residues. The nature of the glycans carried on the eluted proteins in the fraction containing DNase activity was assessed using an enzyme-linked lectin assay. The lectin binding studies predict the presence of both N- and O-type glycans. Manganese was a potent (33%) activator of the DNase(s) whereas zinc inhibited enzyme activity by approximately 66%. The DNase(s) had a pH optimum of 4 and a molecular weight of 160 kDa. The DNase(s) were able to completely degrade DNA from animal, plant, fungal, yeast and bacterial sources, but did not significantly degrade RNA.

Characterization of a cysteine protease from Tritrichomonas foetus that induces host-cell apoptosis.

Tritrichomonas foetus is a serious veterinary pathogen, causing bovine trichomoniasis and affecting cattle herds world-wide, resulting in inflammation of the genital tract, infertility and huge economic losses. The parasite secretes a cysteine protease (CP8), which induces cytotoxicity and apoptosis in bovine vaginal and uterine epithelial cells. Mallinson et al. [D.J. Mallinson, J. Livingstone, K.M. Appleton, S.J. Lees, G.H. Coombs, M.J. North, Microbiology 1995, 141 (12) 3077-3085.] originally reported a partial DNA sequence of T. foetus CP8 based on PCR cloning of T. foetus genomic DNA. Here we report the biochemical properties of the CP8 enzyme. Kinetic properties and the substrate specificity profile of T. foetus CP8 were studied using positional scanning synthetic combinatorial libraries and Michaelis-Menten kinetic analysis of three synthetic fluorogenic substrates. The preferred substrate Z-Leu-Arg-MCA prevented host-cell death/apoptosis induced by CP8. In addition, the DNA sequence was completed by 3' and 5' rapid amplification of cDNA ends (RACE) and the full-length amino acid sequence was obtained.

Cysteine protease 30 (CP30) contributes to adhesion and cytopathogenicity in feline Tritrichomonas foetus.

Tritrichomonas foetus (T. foetus) is a flagellated protozoan parasite that is recognized as a significant cause of diarrhea in domestic cats with a prevalence rate as high as 30%. No drugs have been shown to consistently eliminate T. foetus infection in all cats. Cysteine proteases (CPs) have been identified as mediators of T. foetus-induced adhesion-dependent cytotoxicity to the intestinal epithelium. These CPs represent novel targets for the treatment of feline trichomonosis. However, cats also produce CPs that are part of life-critical systems. Thus, parasitic CPs need to be selectively targeted to reduce the potential for host toxicity. Previous studies have demonstrated the importance of a specific CP, CP30, in mediating bovine and human trichomonad cytopathogenicity. This CP has also recently been identified in feline T. foetus, although the function of this protease in the feline genotype remains unknown. Therefore, the study objectives were to characterize the presence of CP30 in feline T. foetus isolates and to evaluate the effect of targeted inhibition of CP30 on feline T. foetus-induced adhesion dependent cytotoxicity. The presence of CP30 in feline T. foetus isolates was identified by In gel zymography and proteomic analysis, indirect immunofluorescence (IF), and flow cytometry using a rabbit polyclonal antibody that targets bovine T. foetus CP30 (α-CP30). The effect of inhibition of CP30 activity on T. foetus adhesion and cytotoxicity was determined using CFSE-labeled feline T. foetus and crystal violet spectrophotometric assays in a previously validated co-culture model. CP30 expression was confirmed in all feline T. foetus isolates tested by all assays. Targeted inhibition of feline T. foetus CP30 resulted in decreased T. foetus adhesion to and cytotoxicity towards IPEC-J2 monolayers compared to rabbit IgG-treated T. foetus isolates. These studies establish that CP30 is expressed by feline T. foetus isolates and may be an important virulence factor in the cytopathogenicity of feline T. foetus. The results of these studies provide strong evidence-based justification for investigation of CP30 as a novel target for the treatment of feline trichomonosis.

Solution structure of the low-molecular-weight protein tyrosine phosphatase from Tritrichomonas foetus reveals a flexible phosphate binding loop.

Eukaryotic low-molecular-weight protein tyrosine phosphatases (LMW PTPs) contain a conserved serine, a histidine with an elevated pKa, and an active site asparagine that together form a highly conserved hydrogen bonding network. This network stabilizes the active site phosphate binding loop for optimal substrate binding and catalysis. In the phosphatase from the bovine parasite Tritrichomonas foetus (TPTP), both the conserved serine (S37) and asparagine (N14) are present, but the conserved histidine has been replaced by a glutamine residue (Q67). Site-directed mutagenesis, kinetic, and spectroscopic experiments suggest that Q67 is located near the active site and is important for optimal catalytic activity. Kinetic experiments also suggest that S37 participates in the active site/hydrogen bonding network. Nuclear magnetic resonance spectroscopy was used to determine the three-dimensional structure of the TPTP enzyme and to further examine the roles of S37 and Q67. The backbone conformation of the TPTP phosphate binding loop is nearly superimposable with that of other tyrosine phosphatases, with N14 existing in a strained, left-handed conformation that is a hallmark of the active site hydrogen bonding network in the LMW PTPs. As expected, both S37 and Q67 are located at the active site, but in the consensus structure they are not within hydrogen bonding distance of N14. The hydrogen bond interactions that are observed in X-ray structures of LMW PTPs may in fact be transient in solution. Protein dynamics within the active site hydrogen bonding network appear to be affected by the presence of substrate or bound inhibitors such as inorganic phosphate.

Sialic acid-specific lectin from Tritrichomonas foetus.

A novel sialic acid-specific lectin (TFL) was isolated from Tritrichomonas foetus culture supernatant and purified by erythrocyte adsorption followed by fetuin-agarose affinity chromatography. According to gel filtration TFL is a protein of 728 kDa, different from the two sialidases of 853 and 254 kDa, secreted by T. foetus into the medium. The lectin is formed by multimeric complexes of 66 kDa subunit according to SDS-PAGE under reducing conditions. TFL is glycosylated with 4.2% of carbohydrates, half of which is represented by glucose. The lectin reacts equally with N-acetyl and N-glycolyl neuraminic acid, free, in alpha2,3- or alpha2,6-linkage. TFL has 7-fold weaker affinity to alpha2,8-linked N-acetylneuraminic acid (Neu5Ac) in colominic acid. Horse erythrocytes containing 4-O-acetyl Neu5Ac are agglutinated equally as compared to the human cells. TFL affinity to 9-O-acetyl Neu5Ac is 4-fold weaker as documented by hemagglutination inhibition with de-O-acetylated bovine submaxillary mucin, and ovine submaxillary mucin. A panel of mono- and oligosaccharides other than Neu5Ac do not inhibit TFL activity at 200 mM. The lectin does not require bivalent cations for activity, shows optimal reactivity at neutral pH and is stable at 4 degrees C. Anti-TFL antibodies identify membrane positivity on T. foetus, suggesting that the lectin functions in adhesion of the parasites. These findings, together with good stability and immunogenicity, make TFL a prospective candidate for further studies, especially in searching for efficient diagnostics and prevention of bovine trichomoniasis.

Crystal structures of Tritrichomonasfoetus inosine monophosphate dehydrogenase in complex with substrate, cofactor and analogs: a structural basis for the random-in ordered-out kinetic mechanism.

The enzyme inosine monophosphate dehydrogenase (IMPDH) is responsible for the rate-limiting step in guanine nucleotide biosynthesis. Because it is up-regulated in rapidly proliferating cells, human type II IMPDH is actively targeted for immunosuppressive, anticancer, and antiviral chemotherapy. The enzyme employs a random-in ordered-out kinetic mechanism where substrate or cofactor can bind first but product is only released after the cofactor leaves. Due to structural and kinetic differences between mammalian and microbial enzymes, most drugs that are successful in the inhibition of mammalian IMPDH are far less effective against the microbial forms of the enzyme. It is possible that with greater knowledge of the structural mechanism of the microbial enzymes, an effective and selective inhibitor of microbial IMPDH will be developed for use as a drug against multi-drug resistant bacteria and protists. The high-resolution crystal structures of four different complexes of IMPDH from the protozoan parasite Tritrichomonas foetus have been solved: with its substrate IMP, IMP and the inhibitor mycophenolic acid (MPA), the product XMP with MPA, and XMP with the cofactor NAD(+). In addition, a potassium ion has been located at the dimer interface. A structural model for the kinetic mechanism is proposed.

In vitro cytopathic effects of a cysteine protease of Tritrichomonas foetus on cultured bovine uterine epithelial cells.

OBJECTIVE: To evaluate the cytopathic effects of Tritrichomonas foetus and a purified cysteine protease (ie, CP30) of T foetus on cultured bovine uterine epithelial cells (BUECs) in vitro. SAMPLE POPULATION: 10 reproductive tracts were obtained from late-term bovine fetuses at a commercial abattoir. PROCEDURE: An in vitro culture system of BUECs was developed to study the cytopathic effects of T foetus and purified CP30 of T foetus on host cells. Cytotoxicity of T foetus or CP30 on exposed BUECs was determined. Fluorescence microscopy and flow cytometry analyses were used to detect apoptosis. A fluorometric assay was used to detect BUEC caspase 3 activation. The CP inhibitor E-64 and a caspase inhibitor were used to inhibit apoptosis. RESULTS: Cytopathic effects were observed in BUECs treated with parasites or CP30 and were concentration and time dependent. The BUECs underwent apoptosis in the presence of parasites or CP30. The specific CP inhibitor E-64 abolished the induction of apoptosis in BUECs by CP30. The caspase inhibitor reduced the amount of apoptosis in BUECs. CONCLUSIONS AND CLINICAL RELEVANCE: T foetus and its CP30 induce apoptosis in cultured BUECs in vitro. Induction of apoptosis by CP30 is correlated with protease activity. Endometrial cell death as a result of a T foetus infection is likely to be more important in mediating infertility than a direct effect on the conceptus. Provoking an apoptotic reaction in the host may mitigate an inflammatory reaction or immune response and therefore favor survival of the parasite in a chronic infection.

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.

IMP dehydrogenase : structural aspects of inhibitor binding.

Inosine monophosphate dehydrogenase (IMPDH, E.C. 1.1.1.205) is recognized as an important target for both antileukemic and immunosuppressive therapy. IMPDH catalyzes the NAD-dependent oxidation of inosine 5 monophosphate (IMP) to xanthosine 5 monophosphate. Several classes of IMPDH inhibitors are now in use or under development. These include agents that bind at either the substrate site (e.g. ribavirin and mizoribine) or at the NAD site (mycophenolic acid and thiazole-4-carboxamide adenine dinucleotide). All suffer from some degree of toxicity and/or susceptibility to metabolic inactivation. The finding that IMPDH exists as two isoforms, one of which (type II) is induced in tumor cells, has led to the search for potentially more effective isoform-specific agents. Recently, a number of crystal structures of IMPDH have become available. These include structures of the human type II, hamster, Tritrichomonas foetus, Streptococcus pyogenes and Borrelia burgdorferi enzymes. Each structure crystallizes as a tetramer of a/b barrels, with the active site located partly at the monomer-monomer interface. The substrate and cofactor bind in a continuous cleft on the C-terminal face of each barrel. The IMP base is well positioned to stack against the NAD nicotinamide ring to facilitate hydride transfer. The active site cleft is further bounded by a highly flexible flap and loop. These structures reveal enzyme-ligand interactions which suggest strategies for the design of improved inhibitors.

Differential signatures of bacterial and mammalian IMP dehydrogenase enzymes.

IMP dehydrogenase (IMPDH) is an essential enzyme of de novo guanine nucleotide synthesis. IMPDH inhibitors have clinical utility as antiviral, anticancer or immunosuppressive agents. The essential nature of this enzyme suggests its therapeutic applications may be extended to the development of antimicrobial agents. Bacterial IMPDH enzymes show biochemical and kinetic characteristics that are different than the mammalian IMPDH enzymes, suggesting IMPDH may be an attractive target for the development of antimicrobial agents. We suggest that the biochemical and kinetic differences between bacterial and mammalian enzymes are a consequence of the variance of specific, identifiable amino acid residues. Identification of these residues or combination of residues that impart this mammalian or bacterial enzyme signature is a prerequisite for the rational identification of agents that specifically target the bacterial enzyme. We used sequence alignments of IMPDH proteins to identify sequence signatures associated with bacterial or eukaryotic IMPDH enzymes. These selections were further refined to discern those likely to have a role in catalysis using information derived from the bacterial and mammalian IMPDH crystal structures and site-specific mutagenesis. Candidate bacterial sequence signatures identified by this process include regions involved in subunit interactions, the active site flap and the NAD binding region. Analysis of sequence alignments in these regions indicates a pattern of catalytic residues conserved in all enzymes and a secondary pattern of amino acid conservation associated with the major phylogenetic groups. Elucidation of the basis for this mammalian/bacterial IMPDH signature will provide insight into the catalytic mechanism of this enzyme and the foundation for the development of highly specific inhibitors.

IMP dehydrogenase: mechanism of action and inhibition.

Inosine monophosphate dehydrogenase (IMPDH) catalyzes the conversion of IMP to XMP with the concomitant reduction of NAD to NADH. This reaction is the rate-limiting step in guanine nucleotide biosynthesis. IMPDH is a proven target for immunosuppressive, anticancer and antiviral chemotherapy, and may also be a target for antimicrobial agents. IMPDH is activated by monovalent cations, and one monovalent cation binding site appears to have been identified. The mechanism of IMPDH involves formation and hydrolysis of a covalent enzyme intermediate (E-XMP*) in a reaction reminiscent of glyceraldehyde-3-phosphate dehydrogenase. Substrates bind to IMPDH in a random order, hydride transfer is fast and NADH release precedes hydrolysis of E-XMP*. The hydrolysis of E-XMP* is at least partially rate-limiting. Two inhibitors, mizoribine-monophosphate and a fat base nucleotide appear to act as transition state analogs. In contrast, MPA inhibits by sequestering E-XMP.

The hypoxanthine-guanine-xanthine phosphoribosyltransferase from Tritrichomonas foetus has unique properties.

Tritrichomonas foetus, an anaerobic, flagellated protozoan parasite, is incapable of de novo purine nucleotide synthesis, and depends primarily on the salvage of purine bases from the host. The hypoxanthine-guanine-xanthine phosphoribosyltransferase (HGXPRTase) from this organism has been purified to homogeneity by ammonium sulfate precipitation and Sephacryl-HR100 gel filtration, followed by anion exchange FPLC. Hypoxanthine, guanine and xanthine phosphoribosyltransferase activities co-eluted in all the purification steps, suggesting that they are associated with the same enzyme protein. The molecular mass of the native protein, as estimated by gel filtration, is 24 kDa. The molecular mass estimated from sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS-PAGE) is also 24 kDa. Non-denaturing polyacrylamide gel electrophoresis of the purified protein, followed by activity staining with either [14C]hypoxanthine, [14C]guanine or [14C]xanthine, also demonstrates that the enzyme is a monomer of 24 kDa. This monomeric structure is distinctive from all the other reported PRTases which are either dimers or tetramers. Furthermore, unlike the mammalian HGPRTase, which is heat stable, the T. foetus enzyme is heat labile. Kinetic studies with the purified T. foetus HGXPRTase showed that the apparent Kms for hypoxanthine, guanine and xanthine were 4.1 microM, 3.8 microM and 52.4 microM respectively. This recognition of xanthine as a substrate by the parasite enzyme with only about a 10-fold higher Km value than those for hypoxanthine and guanine distinguishes it from the mammalian HGPRTase, which cannot use xanthine as a substrate, as well as the HGXPRTases of Eimeria tenella and Plasmodium falciparum, which are dimers, with xanthine about 100-times less proficient as a substrate.(ABSTRACT TRUNCATED AT 250 WORDS)

Isolation, sequencing and expression of the gene encoding hypoxanthine-guanine-xanthine phosphoribosyltransferase of Tritrichomonas foetus.

We have cloned and expressed the full-length gene encoding the hypoxanthine-guanine-xanthine phosphoribosyltransferase (HGXPRTase) from the anaerobic protozoan parasite Tritrichomonas foetus. This enzyme is essential in nucleic acid metabolism of T. foetus because the parasite is unable to synthesize purine nucleotides de novo and relies on the HGXPRTase activities for its purine requirements. Initially, a cDNA clone encoding part of the HGXPRTase was isolated by complementation of an Escherichia coli mutant, SO609, with a cDNA library of T. foetus. Northern blot analysis identified a single mRNA band of approximately 700-800 bases. The full-length genomic clone was then isolated and identified to have an open reading frame of 549 bp encoding an 183-amino acid sequence with an estimated size of 21.1 kDa. The sequence is only 27.3% identical to that of the human HGPRTase. The T. foetus HGXPRTase gene was subsequently cloned into the pBAce vector for expression in E. coli. This construct yields completely soluble and enzymatically active recombinant T. foetus HGXPRTase, which constitutes approximately 20% of the total cellular protein of the transformed E. coli. It has the same molecular weight as the authentic native enzyme, and the N-terminal amino acid sequence of the recombinant enzyme is identical to that predicted from the open reading frame. The high expression of this apparently native T. foetus HGXPRTase will provide large quantities of purified protein, necessary for detailed kinetic and structural analysis of this enzyme for its potential value as a target for antitrichomonial chemotherapy. To our knowledge, this is also the first time a gene from T. foetus was cloned and expressed.

Identification, purification and separation of different isozymes of NADP-specific malic enzyme from Tritrichomonas foetus.

Tritrichomonas foetus was found to contain NADP-specific malic enzyme. The activity was present in the cytosolic fraction and was about 5-fold higher in extracts of a metronidazole-resistant strain (KV1-1MR-100) than of the parent strain (KVc1). Electrophoresis under non-denaturing conditions and activity staining indicated the existence of 3 isozymes termed I, II and III in order of increasing electrophoretic mobility. Isozymes I and II were much less active than isozyme III in the parent strain, whereas all three isozymes had comparable activities in the resistant strain. NADP-malic enzymes were purified from the cytosolic fraction of the resistant strain to apparent homogeneity and were identified by SDS-PAGE as polypeptides of 41.5 kDa (I), 40.5 kDa (III) and as a mixture of both in equal amounts (II). The molecular mass of the three holoenzymes was about 180 kDa, as determined by gel-filtration on Sephacryl S-300 HR, indicating a tetrameric structure. Isozyme III was also purified from parent strain and shown to consist of the 40.5-kDa polypeptide. Km values for malate were 0.31, 0.65 and 1.35 mM for isozyme I, II and III, respectively. From these results we conclude that T. foetus+, which is required for the formation of ethanol by alcohol dehydrogenase, an NADP-specific enzyme in this species. This is particularly important for the resistant strain, in which ethanol is the major end-product of glucose metabolism.

Identification of a neutrophil chemotactic factor from Tritrichomonas foetus as superoxide dismutase.

Antibodies to a neutrophil chemotactic factor from Tritrichomonas foetus were used to screen a T. foetus cDNA expression library in lambda gt11. All positive clones were identified as homologs of iron-containing superoxide dismutase (SOD). Native gel electrophoresis showed that the antibodies indeed recognized T. foetus antigens with SOD activity. Two SOD genes were found in T. foetus, and cloned and sequenced as parts of larger genomic segments of 3844 and 4089 base pairs. Transcription initiated between the first and second methionine codons of each genomic open reading frame, generating mRNAs with 5' untranslated regions of 11-15 bases, and encoding proteins of 195 amino acids. The two SOD coding sequences lacked obvious introns. They were 79% identical at both the nucleotide and amino acid levels. Both SOD genes were inserted into a eukaryotic expression vector and stably expressed in mammalian cells; both proteins were recognized by the antibodies, and both assumed a cytosolic, extranuclear distribution in these cells. Histidine-tagged forms of both T. foetus SODs were expressed in E. coli and after purification, found to have neutrophil chemotactic activity similar to the non-recombinant factor purified from T. foetus. Identification of this neutrophil chemotactic factor as SOD provides additional insight into the host-parasite interaction.