Comparative proteomics of excretory-secretory proteins released by the liver fluke Fasciola hepatica in sheep host bile and during in vitro culture ex host

Livestock infection by the parasitic fluke Fasciola hepatica causes major economic losses worldwide. The excretory-secretory (ES) products produced by F. hepatica are key players in understanding the host-parasite interaction and offer targets for chemo- and immunotherapy. For the first time, subproteomics has been used to compare ES products produced by adult F. hepatica in vivo, within ovine host bile, with classical ex host in vitro ES methods. Only cathepsin L proteases from F. hepatica were identified in our ovine host bile preparations. Several host proteins were also identified including albumin and enolase with host trypsin inhibitor complex identified as a potential biomarker for F. hepatica infection. Time course in vitro analysis confirmed cathepsin L proteases as the major constituents of the in vitro ES proteome. In addition, detoxification proteins (glutathione transferase and fatty acid-binding protein), actin, and the glycolytic enzymes enolase and glyceraldehyde-3-phosphate dehydrogenase were all identified in vitro. Western blotting of in vitro and in vivo ES proteins showed only cathepsin L proteases were recognized by serum pooled from F. hepatica-infected animals. Other liver fluke proteins released during in vitro culture may be released into the host bile environment via natural shedding of the adult fluke tegument. These proteins may not have been detected during our in vivo analysis because of an increased bile turnover rate and may not be recognized by pooled liver fluke infection sera as they are only produced in adults. This study highlights the difficulties identifying authentic ES proteins ex host, and further confirms the potential of the cathepsin L proteases as therapy candidates.     

An optimized enzyme-linked immunosorbent assay for quantitative diagnosis of bovine fascioliasis

An optimized immunoassay for detection of antibody to Fasciola hepatica antigen in cattle was developed through the adaptation of a kinetics-dependent, enzyme-linked immunosorbent assay (k-ELISA) to a microplate format. Enhanced sensitivity and a strict quantitative nature were achieved with the utilization of enzyme kinetics. With this k-ELISA, significant (P less than 0.01) elevations in anti-F. hepatica antibody could be detected as early as 2 wk post-infection in experimentally infected calves. Furthermore, fluke-burden related differences in anti-F. hepatica antibody levels between 3 different levels of fluke infection were evident.     

Production and processing of a recombinant Fasciola hepatica cathepsin B-like enzyme (FhcatB1) reveals potential processing mechanisms in the parasite

The liver fluke, Fasciola hepatica, apparently uses a number of cysteine proteases during its life cycle, most likely for feeding, immune evasion and invasion of tissues. A cathepsin B-like enzyme (herein referred to as FhcatB1) appears to be a major enzyme secreted by the invasive, newly excysted juvenile flukes of this parasite. To examine the processing mechanisms for this enzyme, a recombinant form was expressed in Pichia pastoris and purified to yield a homogenous pool of the enzyme. The purified enzyme could be autoactivated at low pH via a bi-molecular mechanism, a process that was greatly accelerated by the presence of large, negatively charged molecules such as dextran sulfate. The enzyme could also apparently be processed to the correct size by an asparaginyl endopeptidase via cleavage in an unusual insertion N-terminal to the normal cleavage site used to yield the active form of the enzyme. Thus, there appear to be a number of ways in which this enzyme can be processed to its optimally active form prior to secretion by F. hepatica.     

Characterisation of Fasciola hepatica cytochrome c peroxidase as an enzyme with potential antioxidant activity in vitro.

Cytochrome c peroxidase oxidises hydrogen peroxide using cytochrome c as the electron donor. This enzyme is found in yeast and bacteria and has been also described in the trematodes Fasciola hepatica and Schistosoma mansoni. Using partially purified cytochrome c peroxidase samples from Fasciola hepatica we evaluated its role as an antioxidant enzyme via the investigation of its ability to protect against oxidative damage to deoxyribose in vitro. A system containing FeIII-EDTA plus ascorbate was used to generate reactive oxygen species superoxide radical, H2O2 as well as the hydroxyl radical. Fasciola hepatica cytochrome c peroxidase effectively protected deoxyribose against oxidative damage in the presence of its substrate cytochrome c. This protection was proportional to the amount of enzyme added and occurred only in the presence of cytochrome c. Due to the low specific activity of the final partially purified sample the effects of ascorbate and calcium chloride on cytochrome c peroxidase were investigated. The activity of the partially purified enzyme was found to increase between 10 and 37% upon reduction with ascorbate. However, incubation of the partially purified enzyme with 1 mM calcium chloride did not have any effect on enzyme activity. Our results showed that Fasciola hepatica CcP can protect deoxyribose from oxidative damage in vitro by blocking the formation of the highly toxic hydroxyl radical (.OH). We suggest that the capacity of CcP to inhibit .OH-formation, by efficiently removing H2O2 from the in vitro oxidative system, may extend the biological role of CcP in response to oxidative stress in Fasciola hepatica.     

Properties and application to immunoassay of monoclonal antibodies to neuron-specific γγ enolase

Two monoclonal antibodies to human and bovine neuron-specific γγ enolase have been produced in the isolated hybrid cell lines, which were obtained by fusion between γγ-immunized mouse spleen cells and mouse myeloma cells (P3-NS-1/1-Ag4-1), followed by a screening procedure with an enzyme immunoassay. The monoclonal antibody to human γγ enolase (E1-G3) and that to bovine γγ enolase (B1-D6) consisted of γ2a/κ and γl/κ immunoglobulin chains, respectively. Both antibodies could bind with the respective antigen with a molar ratio of about 1:1, and were found to be specific for the γ subunit of enolase, showing reactivities with human γγ and αγ, rat γγ and αγ, and bovine γγ enolases. However, the antibodies did not cross-react with the α or β subunit of human and rat enolase isozymes. Both antibodies could partially inhibit the activity of γγ and αγ enolases. E1-G3 antibody inhibited γγ and αγ enolase activity by 70 and 30%, respectively, and B1-D6 antibody, by 90 and 40%, respectively. Both antibodies had no effect on the activity of αα and ββ enolases of human and rat origins. The applicability of E1-G3 and B1-D6 antibodies to the sandwich-type enzyme immunoassay for neuron-specific enolase (enolase γ subunit) was examined, and it was found that the assay system using E1-G3 and B1-D6 as the labeled antibodies were sufficiently sensitive for the assay of serum neuron-specific enolase concentrations.     

Role of the prosegment of Fasciola hepatica cathepsin L1 in folding of the catalytic domain

The N-terminal propeptides of cysteine proteinases play regulatory roles in the folding and stability of their catalytic domains, as well as being potent and highly specific inhibitors of their parental mature enzymes. Cysteine proteinases play a major role in the biology of the parasitic trematode Fasciola hepatica; in particular, this organism secretes significant amounts of cathepsin L enzymes. The isolated propeptide of F. hepatica cathepsin L1 functioned as a chaperone for the mature enzyme in renaturation experiments. A double point mutation (N701/F721) within the GxNxFxD motif of the propeptide affected its conformation and markedly decreased its affinity for the mature enzyme. When this mutation was introduced into preprocathepsin L1 expressed in yeast, the secretion of active enzyme dropped dramatically. However, significant enzyme activity was recovered from the culture supernatants after denaturation and renaturation in the presence of native propeptide. Thus, the variant prosegment gave rise to an enzyme with altered conformation, which could be refolded to the active form with the assistance of the native propeptide.     

Phylogenetic Distribution of Neuron-Specific Enolase

: Neurons and neuroendocrine cells contain a unique isoenzyme of the glycolytic enzyme enolase which is not found in other cells. This acidic enolase isoenzyme has been designated neuron specific enolase or NSE and is easily identified by its elution on DEAE sephadex. The present study shows that brain tissue from species such as yeast, fish and frog do not contain appreciable amounts of acidic “NSE-like” enolase suggesting that lower species do not have this neuronal isoenzyme.     

Antigenicity of a proteolytic enzyme of Fasciola hepatica

The possibility was examined of using a haemoglobinase released during in vitro incubation of adult Fasciola hepatica for immunodiagnosis of fascioliasis. By SDS gel electrophoresis the enzyme appeared as two closely migrating bands with a molecular weight of approximately 27,000 daltons. After Western blotting the bands reacted with serum from rats infected with F. hepatica and mice infected with Schistosoma mansoni. The enzyme was therefore not a good antigen for immunodiagnosis.     

Phosphorylation of Escherichia coli enolase

In vivo labeling of Escherichia coli JA200 pLC 11-8 resulted in 32P incorporation into enolase as demonstrated by immunoaffinity chromatography and electrophoresis followed by autoradiography. Complete acid hydrolysis, followed by thin layer chromatography was employed for determination of the phosphoamino acid residue. Comparison with phosphoamino acid standards resulted in the identification of a labeled residue corresponding to phosphoserine. In vitro labeling of cell extracts from glucose and acetate grown cells resulted in differential labeling of enolase. When specific radioactivities of in vivo labeled enolase were compared, 7 times more label was incorporated at late log phase in glucose grown cells than in late log acetate grown cells. At stationary phase, only 2.5 times more label was incorporated into glucose compared to acetate. When 32P-labeled enolase from glucose grown cells was subjected to treatment with potato acid phosphatase, dephosphorylation of the enzyme could be observed. Monitoring enzyme activity during the acid phosphatase treatment revealed a 70% decrease for the forward enzyme reaction, and a 3-fold increase, followed by a gradual decrease to almost zero, for the reverse enzyme reaction. Complete reversal of the changes in activity was possible by adding an aliquot of partially purified enolase kinase plus ATP.     

Use of hydrostatic pressure to produce 'native' monomers of yeast enolase.

The effects of hydrostatic pressure on yeast enolase have been studied in the presence of 1 mm Mn(2+). When compared with apo-enolase, and Mg-enolase, the Mn-enzyme differs from the others in three ways. Exposure to hydrostatic pressure does not inactivate the enzyme. If the experiments are performed in the presence of 1 mm Mg(2+), or with apo-enzyme, the enzyme is inactivated [Kornblatt, M.J., Lange R., Balny C. (1998) Eur. J. Biochem 251, 775-780]. The UV spectra of the high pressure forms of the Mg(2+)- and apo-forms of enolase are identical and distinct from the spectrum of the form obtained in the presence of 1 mm Mn(2+); this suggests that Mn(2+) remains bound to the high pressure form of enolase. With Mn-enolase, the various spectral changes do not occur in the same pressure range, indicating that multiple processes are occurring. Pressure experiments were performed as a function of [Mn(2+)] and [protein]. One of the changes in the UV spectra shows a dependence on protein concentration, indicating that enolase is dissociating into monomers. The small changes in the UV spectrum and the retention of activity lead to a model in which enolase, in the presence of high concentrations of Mn(2+), dissociates into native monomers; upon release of pressure, the enzyme is fully active. Although further spectral changes occur at higher pressures, there is no inactivation as long as Mn(2+) remains bound. We propose that the relatively small and polar nature of the subunit interface of yeast enolase, including the presence of several salt bridges, is responsible for the ability of hydrostatic pressure to dissociate this enzyme into monomers with a native-like structure.     

Interactions of enolase isoforms with tubulin and microtubules during myogenesis

Enolase is a glycolytic enzyme, expressed as cell-type specific isoforms in higher vertebrates. Herein we demonstrated for the first time that enolase isoforms interact with microtubules during muscle satellite cell differentiation. While in undifferentiated myoblasts the ubiquitous alphaalpha enolase isoform, expressed at high level, exhibited extensive co-localization with microtubules, the muscle-specific betabeta isoform, expressed at low level, did not. During differentiation, the level of beta subunit increased significantly; the alpha and beta enolase immunoreactivities were detected both in cytosol and along the microtubules. We identified tubulin from muscle extract as an interacting protein for immobilized betabeta enolase. ELISA and surface plasmon resonance measurements demonstrated the direct binding of enolase isoforms to tubulin with an apparent KD below the micromolar range, and indicated that the presence of 0.8 mM 2-phosphoglycerate abolished the interaction. Our data showed that, at various stages of myogenic differentiation, microtubules were decorated by different enolase isoforms, which was controlled by the abundance of both partners. We suggest that the binding of enolase to microtubules could contribute to the regulation of the dynamism of the cytoskeletal filaments known to occur during the transition from myoblast to myotubes.     

An octamer of enolase from Streptococcus suis

Enolase is a conserved cytoplasmic metalloenzyme existing universally in both eukaryotic and prokaryotic cells. The enzyme can also locate on the cell surface and bind to plasminogen, via which contributing to the mucosal surface localization of the bacterial pathogens and assisting the invasion into the host cells. The functions of the eukaryotic enzymes on the cell surface expression (including T cells, B cells, neutrophils, monocytoes, neuronal cells and epithelial cells) are not known. Streptococcus suis serotype 2 (S. suis 2, SS2) is an important zoonotic pathogen which has recently caused two large-scale outbreaks in southern China with severe streptococcal toxic shock syndrome (STSS) never seen before in human sufferers. We recently identified the SS2 enolase as an important protective antigen which could protect mice from fatal S.suis 2 infection. In this study, a 2.4-angstrom structure of the SS2 enolase is solved, revealing an octameric arrangement in the crystal. We further demonstrated that the enzyme exists exclusively as an octamer in solution via a sedimentation assay. These results indicate that the octamer is the biological unit of SS2 enolase at least in vitro and most likely in vivo as well. This is, to our knowledge, the first comprehensive characterization of the SS2 enolase octamer both structurally and biophysically, and the second octamer enolase structure in addition to that of Streptococcus pneumoniae. We also investigated the plasminogen binding property of the SS2 enzyme.     

Developmental studies with the 14-3-2 antigen and the neuron specific enolase (NSE) associated activities—I

We have compared the rodent developmental pattern of the 14-3-2 antigen estimated by a microcomplement fixation technique with that of the cerebral enolases. Chromatographic separation of enolase isozymes on microcolumns demonstrates that the embryonic neuron specific enolase is firstly and mostly represented by the αγ isozyme. The most important increase in 14-3-2 antigen and γγ enolase occurs between post-natal days 7th and 15th. By post-natal day 30, adult levels have been reached. An interesting observation is—during embryonic development—the decrease in the specific activity of the cerebral enolase isozyme αα. This could be explained by the replacement—in neuroblasts—of αα enolase by neuron specific enolase. A comparison between 14-3-2 antigen and neuron specific enolase (γγ) purified by completely different methods is presented. The 14-3-2 antigen exhibits an enolase specific activity comparable to that of purified enzyme and has the same electrophoretic mobility. Antibodies raised against either antigen have an identical specificity. Pre and post-natal developmental pattern in rodent brains are similar for both proteins. Thus neuron specific 14-3-2 antigen is identical to neuron specific enolase.Thus we have precisely described the ontogenic transition between the three cerebral enolase isozymes at the tissue level. This study is completed by the analysis of these transitions at the neuronal cell level, using homogenous cell lines (Part II of this paper).     

In vivo regulation of phosphorylation level and activity of phosphofructokinase by serotonin in Fasciola hepatica

The level of phosphorylation and activation of phosphofructokinase by serotonin (5-hydroxytryptamine) was studied in intact liver flukes Fasciola hepatica. The enzyme was immunoprecipitated with antiserum prepared against pure enzyme from the liver flukes. The resuspended immunoprecipitated enzyme retained most of its original activity and its kinetic properties. The level of phosphorylation was determined by a "back phosphorylation" technique. According to this technique, the immunoprecipitated phosphofructokinase was phosphorylated with the catalytic subunit of pure cAMP-dependent protein kinase. Incubation of intact liver flukes with serotonin caused an increase in the level of enzyme phosphorylation which was concomitant with an increase in enzyme activity. The level of phosphorylation was increased by 0.08 mol per protomer as a result of maximal activation by serotonin. It is proposed that phosphorylation plays, at least in part, a functional role in the regulation of phosphofructokinase from the liver fluke F. hepatica under in vivo conditions.     

Kinetic characterization, structure modelling studies and crystallization of Trypanosoma brucei enolase.

In this article, we report the results of an analysis of the glycolytic enzyme enolase (2-phospho-d-glycerate hydrolase) of Trypanosoma brucei. Enolase activity was detected in both bloodstream-form and procyclic insect-stage trypanosomes, although a 4.5-fold lower specific activity was found in the cultured procyclic homogenate. Subcellular localization analysis showed that the enzyme is only present in the cytosol. The T. brucei enolase was expressed in Escherichia coli and purified to homogeneity. The kinetic properties of the bacterially expressed enzyme showed strong similarity to those values found for the natural T. brucei enolase present in a cytosolic cell fraction, indicating a proper folding of the enzyme in E. coli. The kinetic properties of T. brucei enolase were also studied in comparison with enolase from rabbit muscle and Saccharomyces cerevisiae. Functionally, similarities were found to exist between the three enzymes: the Michaelis constant (Km) and KA values for the substrates and Mg2+ are very similar. Differences in pH optima for activity, inhibition by excess Mg2+ and susceptibilities to monovalent ions showed that the T. brucei enolase behaves more like the yeast enzyme. Alignment of the amino acid sequences of T. brucei enolase and other eukaryotic and prokaryotic enolases showed that most residues involved in the binding of its ligands are well conserved. Structure modelling of the T. brucei enzyme using the available S. cerevisiae structures as templates indicated that there are some atypical residues (one Lys and two Cys) close to the T. brucei active site. As these residues are absent from the human host enolase and are therefore potentially interesting for drug design, we initiated attempts to determine the three-dimensional structure. T. brucei enolase crystals diffracting at 2.3 A resolution were obtained and will permit us to pursue the determination of structure.     

Is 2-phosphoglycerate-dependent automodification of bacterial enolases implicated in their export?

We observed that in vivo and in vitro a small fraction of the glycolytic enzyme enolase became covalently modified by its substrate 2-phosphoglycerate (2-PG). In modified Escherichia coli enolase, 2-PG was bound to Lys341, which is located in the active site. An identical reversible modification was observed with other bacterial enolases, but also with enolase from Saccharomyces cerevisiae and rabbit muscle. An equivalent of Lys341, which plays an important role in catalysis, is present in enolase of all organisms. Covalent binding of 2-PG to this amino acid rendered the enzyme inactive. Replacement of Lys341 of E.coli enolase with other amino acids prevented the automodification and in most cases strongly reduced the activity. As reported for other bacteria, a significant fraction of E.coli enolase was found to be exported into the medium. Interestingly, all Lys341 substitutions prevented not only the automodification, but also the export of enolase. The K341E mutant enolase was almost as active as the wild-type enzyme and therefore allowed us to establish that the loss of enolase export correlates with the loss of modification and not the loss of glycolytic activity.     

Leishmania mexicana: molecular cloning and characterization of enolase

The gene of Leishmania mexicana enolase was cloned and overexpressed in Escherichia coli as an active enzyme; the protein was biochemically analyzed. This enolase shares with enolases from other trypanosomatids the presence of three atypical residues, each with a reactive side group, near the active site, already described for the enzyme from Trypanosoma brucei. The natural enzyme was purified, using a three-step procedure, from a cytosolic fraction of L. mexicana promastigotes. The kinetic properties of the purified recombinant enzyme were similar to those of the natural enzyme. Both the recombinant and natural enzyme were inhibited by inorganic pyrophosphate. Subcellular localization analysis after differential centrifugation showed that the enzyme activity is only associated with the cytosolic fraction. However, an apparently inactive form of enolase was detected by Western blots in the microsomal fraction. Digitonin treatment of parasites and immunofluorescence studies with permeabilized and non-permeabilized parasites showed that enolase is also associated with membranes and it was found at the external face of the plasma membrane.     

Identification of coenzyme M biosynthetic phosphosulfolactate synthase: a new family of sulfonate-biosynthesizing enzymes

The hyperthermophilic euryarchaeon Methanococcus jannaschii uses coenzyme M (2-mercaptoethanesulfonic acid) as the terminal methyl carrier in methanogenesis. We describe an enzyme from that organism, (2R)-phospho-3-sulfolactate synthase (ComA), that catalyzes the first step in coenzyme M biosynthesis. ComA catalyzed the stereospecific Michael addition of sulfite to phosphoenolpyruvate over a broad range of temperature and pH conditions. Substrate and product analogs moderately inhibited activity. This enzyme has no significant sequence similarity to previously characterized enzymes; however, its Mg(2+)-dependent enzyme reaction mechanism may be analogous to one proposed for enolase. A diverse group of microbes and plants have homologs of ComA that could have been recruited for sulfolactate or sulfolipid biosyntheses.     

The H159A mutant of yeast enolase 1 has significant activity

The function of His159 in the enolase mechanism is disputed. Recently, Vinarov and Nowak (Biochemistry (1999) 38, 12138-12149) prepared the H159A mutant of yeast enolase 1 and expressed this in Escherichia coli. They reported minimal (ca. 0.01% of the native value) activity, though the protein appeared to be correctly folded, according to its CD spectrum, tryptophan fluorescence, and binding of metal ion and substrate. We prepared H159A enolase using a multicopy plasmid and expressed the enzyme in yeast. Our preparations of H159A enolase have 0.2-0.4% of the native activity under standard assay conditions and are further activated by Mg(2+) concentrations above 1 mM to 1-1.5% of the native activity. Native enolase 1 (and enolase 2) are inhibited by such Mg(2+) concentrations. It is possible that His159 is necessary for correct folding of the enzyme and that expression in E. coli leads to largely misfolded protein.     

Differential susceptibility of Plasmodium falciparum versus yeast and mammalian enolases to dissociation into active monomers

In the past, several unsuccessful attempts have been made to dissociate homodimeric enolases into their active monomeric forms. The main objective of these studies had been to understand whether intersubunit interactions are essential for the catalytic and structural stability of enolases. Further motivation to investigate the properties of monomeric enolase has arisen from several recent reports on the involvement of enolase in diverse nonglycolytic (moonlighting) functions, where it may occur in monomeric form. Here, we report successful dissociation of dimeric enolases from Plasmodium falciparum, yeast and rabbit muscle into active and isolatable monomers. Dimeric enolases could be dissociated into monomers by high concentrations ( approximately 250 mm) of imidazole and/or hydrogen ions. Two forms were separated using Superdex-75 gel filtration chromatography. A detailed comparison of the kinetic and structural properties of monomeric and dimeric forms of recombinant P. falciparum enolase showed differences in specific activity, salt-induced inhibition and inactivation, thermal stability, etc. Furthermore, we found that enolases from the three species differ in their dimer dissociation profiles. Specifically, on challenge with imidazole, Mg(II) protected the enolases of yeast and rabbit muscle but not of P. falciparum from dissociation. The observed differential stability of the P. falciparum enolase dimer interface with respect to mammalian enolases could be exploited to selectively dissociate the dimeric parasite enzyme into its catalytically inefficient, thermally unstable monomeric form. Thus enolase could be a novel therapeutic target for malaria.