We have isolated a cDNA clone of the glycolytic enzyme, triosephosphate isomerase (TPI) from Entamoeba histolytica. Degenerate oligonucleotides obtained by reverse translation of conserved polypeptide sequences, derived from TPIs of other organisms, were used to amplify a 450-bp fragment using E. histolytica cDNA as a template. The fragment was used to screen a cDNA library. The isolated cDNA, encoding a protein of 261 amino acids, shares 43-52.6% positional identity with other known protozoan TPIs. The catalytic residues were conserved ; nevertheless, several indels occurred at other regions in the protein sequence. The complete coding sequence of the E. histolytica TPI gene was cloned into the expression vector pRSET and expressed as a wild-type TPI enzyme (E. histolytica TPI) and as a fusion protein with an N-terminal tail of six histidine residues E. histolytica TPI-His,) ; both recombinant proteins were purified.Molecular modeling of E. histolytica TPI showed an identical topology to the known structures of other TPI molecules, but with a remarkable feature; more than 10 inserted residues are located in the same region of the molecular surface. Studies were performed to detect possible changes that might be caused by the inserted amino acids. The catalytic activity and oligomeric state of the purified protein were similar to that reported for TPI from other sources. In contrast, stability towards dilution, as well as thermal inactivation and unfolding assays, showed that E. histolytica TPI is significantly more stable towards denaturation than Trypanosoma brucei TPI.
A Taenia solium glutathione-S-transferase fraction (SGSTF) was isolated from a metacestode crude extract by affinity chromatography on reduced glutathione (GSH)-sepharose. The purified fraction displayed a specific glutathione S-transferase (GST) activity of 2.8 micromol/min/mg and glutathione peroxidase selenium-independent activity of 0.22 micromol/min/mg. Enzymatic characterization of the fraction suggested that the activity was closer to the mammalian mu-class GSTs. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis, gel filtration, and enzyme activity analysis showed that the fraction was composed of a major band of Mr = 26 kd and that the active enzyme was dimeric. Immunohistochemical studies using specific antibodies against the major 26-kd band of the SGSTF indicated that GST protein was present in the tegument, parenchyma, protonephridial, and tegumentary cytons of the T. solium metacestode. Antibodies generated against the SGSTF tested in western blot showed cross-reactivity against GSTs purified from Taenia saginata, T. taeniaeformis, and T. crassiceps, but did not react with GSTs from Schistosoma mansoni, or mice, rabbit, and pig liver tissue. Furthermore, immunization of mice with SGSTF reduced the metacestode burden up to 74.2%. Our findings argue in favor of GST having an important role in the survival of T. solium in its hosts.
A Taenia solium 2-Cys peroxiredoxin (Ts2-CysPrx) clone was isolated from a T. solium adult cDNA library. The clone encodes a polypeptide comprising 197 amino acids with a predictive Mr = 21,836. It has the 2 classical cysteine domains from the typical 2-Cys peroxiredoxins, and its primary amino acid sequence shows higher identity with 2 Echinococcus 2-Cys peroxiredoxins. Northern and Southern blot hybridizations exhibit an mRNA with a size of -1.0 kb, encoded by 1 gene. Ts2-CysPrx was expressed in Escherichia coli and purified by anion-exchange chromatography. Biochemical analysis showed Ts2-CysPrx is a dimer composed by monomers of -22 kDa that presented activity with hydrogen peroxide (H2O2) and cumene hydroperoxide. It presented the catalytic mechanism for a typical 2-CysPrx because the homodimeric oxidized form is reduced to a monomeric form by thioredoxin (Trx) and by dithiothreitol (DTT) and was converted to a homodimeric oxidized form by H2O2. Western blot studies using antibodies against Ts2-CysPrx revealed that the protein is expressed during the entire T. solium life cycle, as in other Taenia species. Immunohistochemical studies indicated that Ts2-CysPrx is localized on the tegument and in tegumentary and muscle cells of cysticerci. We also show that T. crassiceps cysticerci can tolerate H2O2 levels of 2.5 mM for 2.5 hr.
We produced the Taenia solium triosephosphate isomerase (TPI) in Escherichia coli and compared its biochemical and immunological properties with those of the commercial TPI from Sus scrofa. Taenia solium TPI is a homodimer composed of two 27-kDa monomers, with a specific activity of 5,683 U/mg and a Km value of 0.758, and S. scrofa TPI is also dimeric with similar monomeric molecular weight, specific activity of 4,227 U/mg, and a Km value of 0.51. The catalytic parameters for the isomerization of glyceraldehyde 3-phosphate, affinity between TPI monomers, and kinetic thermal denaturation and inactivation were similar for both enzymes. Anti-T. solium TPI antibodies cross-react weakly with Schistosoma mansoni TPI but do not cross-react with S. scrofa, human, or protozoan TPIs. These antibodies inhibited T. solium TPI activity but did not affect S. scrofa enzymatic activity. Immunizations with 1 microg of the T. solium TPI reduced 52% of cysticerci in a mouse-Taenia crassiceps model 1 mo after challenge. Our findings show that T. solium and S. scrofa TPIs possess similar biochemical and enzymatic properties but do not share immunological properties because anti-T. solium TPI antibodies did not recognize S. scrofa TPI. Inhibition of enzyme activity by anti-TPI antibodies suggests that they can be used as inhibitors of the enzyme.
Glutathione (GSH) transferase (GST) is an essential enzyme in cestodes for the detoxification of xenobiotics. In Taenia solium, two GSTs (Ts25GST and Ts26GST kDa) were isolated as a fraction (SGSTF) by GSH-Sepharose-4B. Both are located on the tegument. Immunization assays with SGSTF reduced up to 90% of the parasitic load in a murine model of cysticercosis. It prompted us to investigate how SGSTF induces this protective immune response. To test it, we exposed peritoneal macrophages to SGSTF for 24 h; such exposure favored the production of IL-12, TNF, and IL-10 as well as the expression of nitric oxide synthase 2 inducible (Nos2) and CD86, but did not induce the expression of chitinase-like 3 (Chil3). Confocal microscopy showed that the macrophages internalize the SGSTF which co-localized after 1 h with MHC-II in their plasma membranes. Macrophages exposed to SGSTF and co-cultured with anti-CD3 pre-activated T CD4+ cells, enhanced the proliferation of CD4+ cells, induced high interferon-γ (IFN-γ) secretion, and elevated the expression of CD25 and CD69, molecules associated with cell activation. Similar assay using T CD4+ cells from DO11.10 mice and ovalbumin (OVA) peptide+SGSTF as stimuli, showed enhanced cell proliferation and OVA-specific IFN-γ secretion. These data are in-line with those indicating that the P1, P5, and P6 peptides of Schistosoma japonicum 28GST highly promote T-cell proliferation and Th1 response in vitro. We found that such peptides are also present on Ts25GST and Ts26GST. It suggests that SGSTF activates peritoneal macrophages to a classically activated-like phenotype, and that these macrophages induce the differentiation of T CD4+ cells toward a Th1-type response.
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