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ABSTRACT: An amylosucrase gene was subjected to high-rate segmental random mutagenesis, which was directed toward a segment encoding amino acids that influence the interaction with substrate molecules in subsites -1 to +3. A screen was used to identify enzyme variants with compromised glucan chain elongation. With an average mutation rate of about one mutation per targeted codon, a considerable fraction (82%) of the clones that retained catalytic activity were deficient in this trait. A detailed characterization of selected variants revealed that elongation terminated when chains reached lengths of only two or three glucose moieties. Sequencing showed that the amylosucrase derivatives had an average of no more than two amino acid substitutions and suggested that predominantly exchanges of Asp394 or Gly396 were crucial for the novel properties. Structural models of the variants indicated that steric interference between the amino acids introduced at these sites and the growing oligosaccharide chain are mainly responsible for the limitation of glucosyl transfers. The variants generated may serve as biocatalysts for limited addition of glucose moieties to acceptor molecules, using sucrose as a readily available donor substrate.
Applied and environmental microbiology 10/2009; 75(23):7453-60. · 3.69 Impact Factor
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ABSTRACT: It is shown that exchanges of single invariant amino acids in two C-terminal catalytic domain segments of the glucosyltransferase R (GtfR) strongly affect its catalytic properties. Drastic decreases of activity through re- or displacements of Tyr965 demonstrate a crucial role of this residue. Similarly, exchanges of amino acids Asp1004, Val1006, and Tyr1011 profoundly influenced catalytic parameters. These results are interpreted on the basis of a homology model of the catalytic domain. They are consistent with the view that Tyr965 is a constituent of the substrate-binding pocket and directly contacts the sucrose molecule, whereas the other critical residues contribute to the required positioning of Tyr965 and other active site residues.
FEBS Letters 03/2008; 582(4):491-6. · 3.54 Impact Factor
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ABSTRACT: Tryparedoxin peroxidases (TXNPx) catalyze hydroperoxide reduction by tryparedoxin (TXN) by an enzyme substitution mechanism presumed to involve three catalytic intermediates: (i) a transient oxidation state having C52 oxidized to a sulfenic acid, (ii) the stable oxidized form with C52 disulfide-bound to C173', and (iii) a semi-reduced intermediate with C40 of TXN disulfide-linked to C173' from which the ground state enzyme is regenerated by thiol/disulfide reshuffling. This kinetically unstable form was mimmicked by a dead-end intermediate generated by cooxidation of TXNPx of Trypanosoma brucei brucei with an inhibitory mutein of TXN in which C43 was replaced by serine (TbTXNC43S). Cleavage of the isolated dead-end intermediate by trypsin plus chymotrypsin yielded a fragment that complied in size with the TbTXNC43S sequence 36 to 44 disulfide-linked to the TbTXNPx sequence 169 to 177. The presumed nature of the proteolytic fragment was confirmed by MS/MS sequencing. The results provide direct chemical evidence for the assumption that the reductive part of the catalysis is initiated by an attack of the substrate's solvent-exposed C40 on C173' of the oxidized peroxidase and, thus, confirm the hypothesis on the interaction of 2-Cys-peroxiredoxins with their proteinaceous substrates.
Biological Chemistry 10/2003; 384(9):1305-9. · 2.96 Impact Factor
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ABSTRACT: Tryparedoxin peroxidases (TXNPx) are peroxiredoxin-type enzymes that detoxify hydroperoxides in trypanosomatids. Reduction equivalents are provided by trypanothione [T(SH)2] via tryparedoxin (TXN). The T(SH)2-dependent peroxidase system was reconstituted from TXNPx and TXN of T. brucei brucei (TbTXN-Px and TbTXN). TbTXNPx efficiently reduces organic hydroperoxides and is specifically reduced by TbTXN, less efficiently by thioredoxin, but not by glutathione (GSH) or T(SH)2. The kinetic pattern does not comply with a simple rate equation but suggests negative co-operativity of reaction centers. Gel permeation of oxidized TbTXNPx yields peaks corresponding to a decamer and higher aggregates. Electron microscopy shows regular ring structures in the decamer peak. Upon reduction, the rings tend to depolymerise forming open-chain oligomers. Co-oxidation of TbTXNPx with TbTXNC43S yields a dead-end intermediate mimicking the catalytic intermediate. Its size complies with a stoichiometry of one TXN per subunit of TXNPx. Electron microscopy of the intermediate displays pentangular structures that are compatible with a model of a decameric TbTXNPx ring with ten bound TbTXN molecules. The redox-dependent changes in shape and aggregation state, the kinetic pattern and molecular models support the view that, upon oxidation of a reaction center, other subunits adopt a conformation that has lower reactivity with the hydroperoxide.
Biological Chemistry 05/2003; 384(4):619-33. · 2.96 Impact Factor
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ABSTRACT: Peroxiredoxins constitute a family of peroxidases that lack prosthetic groups or catalytically active heteroatoms. Instead, their peroxidatic activity is due to a strictly conserved cysteine that is activated within a novel catalytic triad in which the cysteine thiol is coordinated to an arginine and a threonine or serine residue. Donor substrates are thiol compounds which differ between subtypes of peroxiredoxins and species. In pathogenic trypanosomatids that lack heme- or seleno-peroxidases peroxiredoxins have been shown to represent the major devices to detoxify hydroperoxides and an equivalent role may be assumed for other protozoal parasites and many bacterial pathogens. In mammals equipped with more efficient peroxidases the peroxiredoxins appear to be responsible for the redox regulation of diverse metabolic processes. The substantial differences in the cosubstrate requirements of the peroxiredoxins of pathogenic microorganisms and their mammalian host may be exploited to selectively inhibit the antioxidant defense of pathogens. Thereby, the pathogen would be more readily eliminated by the innate immune response of the host's phagocytes.
BioFactors 02/2003; 19(1-2):3-10. · 4.93 Impact Factor
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ABSTRACT: In Kinetoplastida, comprising the medically important parasites Trypanosoma brucei, T. cruzi, and Leishmania species, 2-Cys peroxiredoxins described to date have been shown to catalyze reduction of peroxides by the specific thiol trypanothione using tryparedoxin, a thioredoxin-related protein, as an immediate electron donor. Here we show that a mitochondrial peroxiredoxin from L. infantum (LimTXNPx) is also a tryparedoxin peroxidase. In an heterologous system constituted by nicotinamide adenine dinucleotide phosphate (NADPH), T. cruzi trypanothione reductase, trypanothione and Crithidia fasciculata tryparedoxin (CfTXN1 and CfTXN2), the recombinant enzyme purified from Escherichia coli as an N-terminally His-tagged protein preferentially reduces H(2)O(2) and tert-butyl hydroperoxide and less actively cumene hydroperoxide. Linoleic acid hydroperoxide and phosphatidyl choline hydroperoxide are poor substrates in the sense that they are reduced weakly and inhibit the enzyme in a concentration- and time-dependent way. Kinetic parameters deduced for LimTXNPx are a k(cat) of 37.0 s(-1) and K(m) values of 31.9 and 9.1 microM for CfTXN2 and tert-butyl hydroperoxide, respectively. Kinetic analysis indicates that LimTXNPx does not follow the classic ping-pong mechanism described for other TXNPx (Phi(1,2) = 0.8 s x microM(2)). Although the molecular mechanism underlying this finding is unknown, we propose that cooperativity between the redox centers of subunits may explain the unusual kinetic behavior observed. This hypothesis is corroborated by high-resolution electron microscopy and gel chromatography that reveal the native enzyme to preferentially exist as a homodecameric ring structure composed of five dimers.
Free Radical Biology and Medicine 01/2003; 33(11):1563-74. · 5.42 Impact Factor
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Leopold Flohé,
Heike Budde,
Karsten Bruns,
Helena Castro,
Joachim Clos, Birgit Hofmann,
Sonia Kansal-Kalavar,
Dirk Krumme,
Ulrich Menge,
Karin Plank-Schumacher,
Helena Sztajer,
Joseph Wissing,
Claudia Wylegalla,
Hans-Jürgen Hecht
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ABSTRACT: Tryparedoxin peroxidase (TXNPx) of Trypanosomatidae is the terminal peroxidase of a complex redox cascade that detoxifies hydroperoxides by NADPH (Nogoceke et al., Biol. Chem. 378, 827-836, 1997). A gene putatively coding for a peroxiredoxin-type TXNPx was identified in L. donovani and expressed in Escherichia coli to yield an N-terminally His-tagged protein (LdH6TXNPx). LdH6TXNPx proved to be an active peroxidase with tryparedoxin (TXN) 1 and 2 of Crithidia fasciculata as cosubstrates. LdH6TXNPx efficiently reduces H2O2, is moderately active with t-butyl and cumene hydroperoxide, but only marginally with linoleic acid hydroperoxide and phosphatidyl choline hydroperoxide. The enzyme displays ping-pong kinetics with a k(cat) of 11.2 s(-1) and limiting K(m) values for t-butyl hydroperoxide and CfTXN1 of 50 and 3.6 microM, respectively. Site-directed mutagenesis confirmed that C52 and C173, as in related peroxiredoxins, are involved in catalysis. Exchanges of R128 against D and T49 against S and V, supported by molecular modelling, further disclose that the SH group of C52 builds the center of a novel catalytic triad. By hydrogen bonding with the OH of T49 and by the positive charge of R128 the solvent-exposed thiol of C52 becomes deprotonated to react with ROOH. Molecular models of oxidized TXNPx show C52 disulfide-bridged with C173' that can be attacked by C41 of TXN2. By homology, the deduced mechanism may apply to most peroxiredoxins and complements current views of peroxiredoxin catalysis.
Archives of Biochemistry and Biophysics 02/2002; 397(2):324-35. · 2.93 Impact Factor
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Methods in Enzymology 02/2002; 347:244-58. · 2.04 Impact Factor
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ABSTRACT: Present knowledge on peroxiredoxins is reviewed with special emphasis on catalytic principles, specificities and biological function. Peroxiredoxins are low efficiency peroxidases using thiols as reductants. They appear to be fairly promiscuous with respect to the hydroperoxide substrate; the specificities for the donor substrate vary considerably between the subfamilies, comprising GSH, thioredoxin, tryparedoxin and the analogous CXXC motifs in bacterial AhpF proteins. Peroxiredoxins are definitely responsible for antioxidant defense in bacteria (AhpC), yeast (thioredoxin peroxidase) and trypanosomatids (tryparedoxin peroxidase). They are considered to determine virulence of mycobacteria and trypanosomatids. In higher plants they are involved in balancing hydroperoxide production during photosynthesis. In higher animals peroxiredoxins appear to be involved in the redox-regulation of cellular signaling and differentiation, displaying in part opposite effects.
Biological Chemistry 383(3-4):347-64. · 2.96 Impact Factor
