Your search keyword '"Loewen, P C"' showing total 9 results

1. The role of distal tryptophan in the bifunctional activity of catalase-peroxidases.

Author

Regelsberger G, Jakopitsch C, Furtmüller PG, Rueker F, Switala J, Loewen PC, and Obinger C

Subjects

Binding Sites, Catalysis, Cyanobacteria genetics, Cytochrome-c Peroxidase chemistry, Cytochrome-c Peroxidase metabolism, Escherichia coli genetics, Heme metabolism, Hydrogen Peroxide metabolism, Kinetics, Multienzyme Complexes chemistry, Multienzyme Complexes genetics, Multienzyme Complexes metabolism, Mutation genetics, Oxidation-Reduction, Peroxidases chemistry, Peroxidases genetics, Protein Binding, Spectrophotometry, Tryptophan genetics, Yeasts enzymology, Bacterial Proteins, Cyanobacteria enzymology, Escherichia coli enzymology, Peroxidases metabolism, Tryptophan metabolism

Abstract

Catalase-peroxidases are bifunctional peroxidases exhibiting an overwhelming catalase activity and a substantial peroxidase activity. Here we present a kinetic study of the formation and reduction of the key intermediate compound I by probing the role of the conserved tryptophan at the distal haem cavity site. Two wild-type proteins and three mutants of Synechocystis catalase-peroxidase (W122A and W122F) and Escherichia coli catalase-peroxidase (W105F) have been investigated by steady-state and stopped-flow spectroscopy. W122F and W122A completely lost their catalase activity whereas in W105F the catalase activity was reduced by a factor of about 5000. However, the mutations did not influence both formation of compound I and its reduction by peroxidase substrates. It was demonstrated unequivocally that the rate of compound I reduction by pyrogallol or o-dianisidine sometimes even exceeded that of the wild-type enzyme. This study demonstrates that the indole ring of distal Trp in catalase-peroxidases is essential for the two-electron reduction of compound I by hydrogen peroxide but not for compound I formation or for peroxidase reactivity (i.e. the one-electron reduction of compound I).

Published

2001

2. Active site structure of the catalase-peroxidases from Mycobacterium tuberculosis and Escherichia coli by extended X-ray absorption fine structure analysis.

Author

Powers L, Hillar A, and Loewen PC

Subjects

Binding Sites, Catalase genetics, Electron Probe Microanalysis, Escherichia coli genetics, Fourier Analysis, Heme chemistry, Models, Molecular, Mutagenesis, Site-Directed, Mutation, Mycobacterium tuberculosis genetics, Peroxidases genetics, Bacterial Proteins, Catalase chemistry, Escherichia coli enzymology, Mycobacterium tuberculosis enzymology, Peroxidases chemistry

Abstract

The catalase-peroxidase encoded by katG of Mycobacterium tuberculosis is a more effective activator of the antibiotic isoniazid than is the equivalent enzyme from Escherichia coli. The environment of the heme iron was investigated using X-ray absorption spectroscopy to determine if differences in this region were associated with the differences in reactivity. The variation in the distal side Fe-ligand distances between the two enzymes was the same within experimental error indicating that it was not the heme iron environment that produced the differences in reactivity. Analysis of variants of the E. coli catalase-peroxidase containing changes in active site residues Arg102 and His106 revealed small differences in Fe-water ligand distance including a shorter distance for the His106Tyr variant. The Arg102Leu variant was 5-coordinate, but His106Cys and Arg102Cys variants showed no changes within experimental error. These results are compared with those reported for other peroxidases.

Published

2001

3. Structure of catalase HPII from Escherichia coli at 1.9 A resolution.

Author

Bravo J, Mate MJ, Schneider T, Switala J, Wilson K, Loewen PC, and Fita I

Subjects

Amino Acid Sequence, Binding Sites, Crystallography, X-Ray, Heme chemistry, Hydrogen Bonding, Models, Molecular, Molecular Sequence Data, NADP chemistry, Protein Conformation, Water chemistry, Bacterial Proteins chemistry, Catalase chemistry, Escherichia coli enzymology

Abstract

Catalase HPII from Escherichia coli, a homotetramer of subunits with 753 residues, is the largest known catalase. The structure of native HPII has been refined at 1.9 A resolution using X-ray synchrotron data collected from crystals flash-cooled with liquid nitrogen. The crystallographic agreement factors R and R(free) are respectively 16.6% and 21.0%. The asymmetric unit of the crystal contains a whole molecule that shows accurate 222-point group symmetry. The structure of the central part of the HPII subunit gives a root mean square deviation of 1.5 A for 477 equivalencies with beef liver catalase. Most of the additional 276 residues of HPII are located in either an extended N-terminal arm or in a C-terminal domain organized with a flavodoxin-like topology. A small number of mostly hydrophilic interactions stabilize the relative orientation between the C-terminal domain and the core of the enzyme. The heme component of HPII is a cis-hydroxychlorin gamma-spirolactone in an orientation that is flipped 180 degrees with respect to the orientation of the heme found in beef liver catalase. The proximal ligand of the heme is Tyr415 which is joined by a covalent bond between its Cbeta atom and the Ndelta atom of His392. Over 2,700 well-defined solvent molecules have been identified filling a complex network of cavities and channels formed inside the molecule. Two channels lead close to the distal side heme pocket of each subunit suggesting separate inlet and exhaust functions. The longest channel, that begins in an adjacent subunit, is over 50 A in length, and the second channel is about 30 A in length. A third channel reaching the heme proximal side may provide access for the substrate needed to catalyze the heme modification and His-Tyr bond formation. HPII does not bind NADPH and the equivalent region to the NADPH binding pocket of bovine catalase, partially occluded in HPII by residues 585-590, corresponds to the entrance to the second channel. The heme distal pocket contains two solvent molecules, and the one closer to the iron atom appears to exhibit high mobility or low occupancy compatible with weak coordination.

Published

1999

4. Intracellular location of catalase-peroxidase hydroperoxidase I of Escherichia coli.

Author

Hillar A, Van Caeseele L, and Loewen PC

Subjects

Escherichia coli growth & development, Immunohistochemistry, Bacterial Proteins metabolism, Catalase metabolism, Cytoplasm enzymology, Escherichia coli enzymology, Escherichia coli Proteins

Abstract

The catalase-peroxidase hydroperoxidase I of Escherichia coli has been confirmed to be located in the cytoplasm using two independent methods. Catalase activity was found predominantly (> 95%) in the cytoplasmic fraction following spheroplast formation. The cytoplasmic enzyme glucose-6-phosphate dehydrogenase and the periplasmic enzyme alkaline phosphatase were used as controls. The second method of immunogold staining for the enzyme in situ revealed an even distribution of the enzyme across the cell.

Published

1999

5. Regulation in the rpoS regulon of Escherichia coli.

Author

Loewen PC, Hu B, Strutinsky J, and Sparling R

Subjects

Bacterial Proteins metabolism, Base Sequence, DNA, Bacterial genetics, Escherichia coli metabolism, Gene Expression Regulation, Bacterial, Genes, Bacterial, Holoenzymes biosynthesis, Promoter Regions, Genetic, Protein Biosynthesis, Protein Processing, Post-Translational, Sigma Factor metabolism, Bacterial Proteins genetics, Escherichia coli genetics, Regulon, Sigma Factor genetics

Abstract

In Escherichia coli, the transcription factor sigma s, encoded by rpoS, controls the expression of a large number of genes involved in cellular responses to a diverse number of stresses, including starvation, osmotic stress, acid shock, cold shock, heat shock, oxidative DNA damage, and transition to stationary phase. A list of over 50 genes under the control of rpoS has been compiled. The transcription factor sigma s acts predominantly as a positive effector, but it does have a negative effect on some genes. The synthesis and accumulation of sigma s are controlled by mechanisms affecting transcription, translation, proteolysis, and the formation of the holoenzyme complex. Transcriptional control of rpoS involves guanosine 3',5'-bispyrophosphate (ppGpp) and polyphosphate as positive regulators and the cAMP receptor protein-cAMP complex (CRP-cAMP) as a negative regulator. Translation of rpoS mRNA is controlled by a cascade of interacting factors, including Hfq, H-NS, dsrA RNA, LeuO, and oxyS RNA that seem to modulate the stability of a region of secondary structure in the ribosome-binding region of the gene's mRNA. The transcription factor sigma s is sensitive to proteolysis by ClpPX in a reaction that is promoted by RssB and inhibited by the chaperone DnaK. Despite the demonstrated involvement of so many factors, arguments have been presented suggesting that sensitivity to proteolysis may be the single most important modulator of sigma s levels. The activity of sigma s may also be modulated by trehalose and glutamate, which activate holoenzyme formation and promote holoenzyme binding to certain promoters.

Published

1998

6. Identification and analysis of the rpoS-dependent promoter of katE, encoding catalase HPII in Escherichia coli.

Author

Tanaka K, Handel K, Loewen PC, and Takahashi H

Subjects

Amino Acid Sequence, Base Sequence, Molecular Sequence Data, Polymerase Chain Reaction, Promoter Regions, Genetic, Bacterial Proteins genetics, Catalase genetics, Escherichia coli genetics, Sigma Factor genetics

Abstract

The rpoS gene of Escherichia coli encodes an alternative sigma factor of RNA polymerase sigma38 (or sigma(s)) that is required for transcription of katE encoding catalase HPII. The transcription start site of the single katE transcript identified by ribonuclease protection has been determined by primer extension analysis to be either 53 or 54 bp (depending on the strain used) upstream of the open reading frame. A series of promoter fragments were constructed and fused to lacZ to confirm the start site location. A - 10 sequence similar to that found in other sigma70- and sigma38-dependent E. coli promoters was identified 8 or 7 bp upstream of the start site but a sigma70-dependent -35 sequence was not evident.

Published

1997

7. Crystal structure of catalase HPII from Escherichia coli.

Author

Bravo J, Verdaguer N, Tormo J, Betzel C, Switala J, Loewen PC, and Fita I

Subjects

Amino Acid Sequence, Animals, Bacterial Proteins genetics, Binding Sites, Catalase genetics, Cattle, Crystallography, X-Ray, Escherichia coli enzymology, Escherichia coli genetics, Fungal Proteins chemistry, Heme chemistry, Hydrogen Bonding, Liver enzymology, Micrococcus enzymology, Molecular Sequence Data, Penicillium enzymology, Proteus mirabilis enzymology, Sequence Alignment, Sequence Homology, Amino Acid, Structure-Activity Relationship, Bacterial Proteins chemistry, Catalase chemistry, Models, Molecular, Protein Conformation

Abstract

Background: Catalase is a ubiquitous enzyme present in both the prokaryotic and eukaryotic cells of aerobic organisms. It serves, in part, to protect the cell from the toxic effects of small peroxides. Escherichia coli produces two catalases, HPI and HPII, that are quite distinct from other catalases in physical structure and catalytic properties. HPII, studied in this work, is encoded by the katE gene, and has been characterized as an oligomeric, monofunctional catalase containing one cis-heme d prosthetic group per subunit of 753 residues., Results: The crystal structure of catalase HPII from E. coli has been determined to 2.8 A resolution. The asymmetric unit of the crystal contains a whole molecule, which is a tetramer with accurate 222 point group symmetry. In the model built, that includes residues 27-753 and one heme group per monomer, strict non-crystallographic symmetry has been maintained. The crystallographic agreement R-factor is 20.1% for 58,477 reflections in the resolution shell 8.0-2.8 A., Conclusions: Despite differences in size and chemical properties, which were suggestive of a unique catalase, the deduced structure of HPII is related to the structure of catalase from Penicillium vitale, whose sequence is not yet known. In particular, both molecules have an additional C-terminal domain that is absent in the bovine catalase. This extra domain contains a Rossmann fold but no bound nucleotides have been detected, and its physiological role is unknown. In HPII, the heme group is modified to a heme d and inverted with respect to the orientation determined in all previously reported heme catalases. HPII is the largest catalase for which the structure has been determined to almost atomic resolution.

Published

1995

8. The role of the sigma factor sigma S (KatF) in bacterial global regulation.

Author

Loewen PC and Hengge-Aronis R

Subjects

Bacteria genetics, Bacterial Proteins genetics, Genes, Bacterial, Regulon genetics, Sigma Factor genetics, Transcription, Genetic, Bacterial Proteins physiology, Gene Expression Regulation, Bacterial genetics, Sigma Factor physiology

Abstract

The protein encoded by katF (also known as nur, appR, csi-2, abrD, and rpoS in various alleles) has been biochemically confirmed to be an alternate sigma transcription factor and renamed sigma S. Its synthesis is controlled transcriptionally and posttranscriptionally by as yet undefined mechanisms that are active well into stationary phase. sigma S controls a regulon of 30 or more genes expressed in response to starvation and during the transition to stationary phase. Proteins in the regulon, many of which have not been characterized, enhance long-term survival in nutrient-deficient medium and have a diverse group of functions including protection against DNA damage, the determination of morphological changes, the mediation of virulence, osmoprotection, and thermotolerance. Differential expression of subfamilies of genes within the regulon is effected by supplementary regulatory factors, working both individually and in combination to modulate activity of different sigma S-dependent promoters.

Published

1994

9. KatF (sigma S) synthesis in Escherichia coli is subject to posttranscriptional regulation.

Author

Loewen PC, von Ossowski I, Switala J, and Mulvey MR

Subjects

Bacteriophage lambda genetics, Base Sequence, Codon, DNA Mutational Analysis, Escherichia coli growth & development, Molecular Sequence Data, Plasmids genetics, Promoter Regions, Genetic genetics, Protein Biosynthesis, RNA Processing, Post-Transcriptional, Recombinant Proteins biosynthesis, Transcription, Genetic, beta-Galactosidase biosynthesis, beta-Galactosidase genetics, Bacterial Proteins genetics, Escherichia coli genetics, Gene Expression Regulation, Bacterial, Sigma Factor genetics

Abstract

A transcriptional fusion of katF to the lacZ gene was expressed at increasingly higher levels throughout the exponential phase, but a translational fusion was expressed at low levels during exponential-phase growth and was induced 160-fold during the transition to stationary phase, implicating a posttranscriptional mechanism in the regulation of KatF synthesis. Mutational analyses suggested that the initiation codon of katF is the second ATG in the previously identified open reading frame.

Published

1993