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102. Total synthesis of the structural gene for the precursor of a tyrosine suppressor transfer RNA from Escherichia coli. 11. Enzymatic joining to form the total DNA duplex.

Author

Kleppe, R, primary, Sekiya, T, additional, Loewen, P C, additional, Kleppe, K, additional, Agarwal, K L, additional, Büchi, H, additional, Besmer, P, additional, Caruthers, M H, additional, Cashion, P J, additional, Fridkin, M, additional, Jay, E, additional, Kumar, A, additional, Miller, R C, additional, Minamoto, K, additional, Panet, A, additional, RajBhandary, U L, additional, Ramamoorthy, B, additional, Sidorova, N, additional, Takeya, T, additional, van de Sande, J H, additional, and Khorana, H G, additional

Published
1976
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113. Structures and Dynamics of G Protein Coupled Receptors

Author

Klein‐Seetharaman, Judith and Loewen, Michele C.

Abstract

ChemInform is a weekly Abstracting Service, delivering concise information at a glance that was extracted from about 200 leading journals. To access a ChemInform Abstract, please click on HTML or PDF.

Published
2006
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116. Determination of the sequences of 18 nucleotides from the 5'-end of the 1-strand and 15 nucleotides from the 5'-end of the r-strand of T7 DNA

Author

Loewen, Peter C.

Abstract

The sequences of 18 nucleotides from the 5′-end of the 1-strand and 15 nucleotides from the 5′-end of the γ-strand of T7 bacteriophage DNA have been determined to be pT-C-T-C-A-C-A-G-T-G-T-A-C-G-T-C-C-C (1-strand) and pA-G-G-G-A-C-A-C-A-G-C-G-C-T-C (r-strand)*. The 5′-termini of whole DNA or separated strands were kinased using polynucleotide kinase and (γ-32P; rATP. The DNA was partially digested with pancreatic DNase and the fragments were separated by two dimensional electrophoresis and homochromatography. To complete the sequence, snake venom phosphodiesterase digestions of these fragments were carried out. The relationship of these sequences to the proposed cleavage of concatemeric DNA during DNA replication is discussed.

Published
1975
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117. Nucleotide sequence of katF of Escherichia coli suggests KatF protein is a novel {sigma} transcription factor

Author

Mulvey, Michael R. and Loewen, Peter C.

Abstract

The katF gene of Escherichia coli has been sequenced revealing a 1086 base pair open reading frame from which the sequence of a 362 amino acid protein has been deduced. The direction of transcription of katF was confirmed by expression of the gene cloned in both directions behind a T7 promoter. The KatF protein expressed in vitro migrates with an apparent size of 42 kDa. Comparison of the katF sequence to the sequence of rpoD, which encodes the sigma subunit of RNA polymerase, revealed a 181 bp region with 65% homology and a 38 bp segment that was 87% homologous. A 62 amino acid region of the predicted KatF protein sequence was found to be 85% homologous to the corresponding sequence of a including σ70, including segment implicated in core polymerase binding. Homology was also observed with the heat shock regulatory protein encoded by htpR.

Published
1989
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118. Crystallization and preliminary X-ray analysis of clade I catalases from Pseudomonas syringae and Listeria seeligeri.

Author

Carpena X, Perez R, Ochoa WF, Verdaguer N, Klotz MG, Switala J, Melik-Adamyan W, Fita I, and Loewen PC

Subjects
Crystallization, Crystallography, X-Ray, Protein Conformation, Catalase chemistry, Listeria enzymology, Pseudomonas enzymology
Abstract

Haem-containing catalases are homotetrameric molecules that degrade hydrogen peroxide. Phylogenetically, the haem-containing catalases can be grouped into three main lines or clades. The crystal structures of seven catalases have been determined, all from clades II and III. In order to obtain a structure of an enzyme from clade I, which includes all plant, algae and some bacterial enzymes, two bacterial catalases, CatF from Pseudomonas syringae and Kat from Listeria seeligeri, have been crystallized by the hanging-drop vapour-diffusion technique, using PEG and ammonium sulfate as precipitants, respectively. Crystals of P. syringae CatF, with a plate-like morphology, belong to the monoclinic space group P2(1), with unit-cell parameters a = 60.6, b = 153.9, c = 109.2 A, beta = 102.8 degrees. From these crystals a diffraction data set to 1.8 A resolution with 98% completeness was collected using synchrotron radiation. Crystals of L. seeligeri Kat, with a well developed bipyramidal morphology, belong to space group I222 (or I2(1)2(1)2(1)), with unit-cell parameters a = 74.4, b = 121.3, c = 368.5 A. These crystals diffracted beyond 2.2 A resolution when using synchrotron radiation, but presented anisotropic diffraction, with the weakest direction perpendicular to the long c axis.

Published
2001
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119. 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
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120. Modulation of the activities of catalase-peroxidase HPI of Escherichia coli by site-directed mutagenesis.

Author

Hillar A, Peters B, Pauls R, Loboda A, Zhang H, Mauk AG, and Loewen PC

Subjects
Amino Acid Substitution genetics, Bacterial Proteins, Binding Sites genetics, Catalase antagonists & inhibitors, Catalysis, Electron Spin Resonance Spectroscopy, Enzyme Activation genetics, Enzyme Inhibitors pharmacology, Escherichia coli genetics, Heme chemistry, Leucine genetics, Mass Spectrometry, Peroxidases antagonists & inhibitors, Phenylalanine genetics, Recombinant Proteins chemistry, Substrate Specificity genetics, Tryptophan genetics, Catalase chemistry, Catalase genetics, Escherichia coli enzymology, Escherichia coli Proteins, Mutagenesis, Site-Directed, Peroxidases chemistry, Peroxidases genetics
Abstract

Catalase-peroxidases have a predominant catalatic activity but differ from monofunctional catalases in exhibiting a substantial peroxidatic reaction which has been implicated in the activation of the antitubercular drug isoniazid in Mycobacterium tuberculosis. Hydroperoxidase I of Escherichia coli encoded by katG is a catalase-peroxidase, and residues in its putative active site have been the target of a site directed-mutagenesis study. Variants of residues R102 and H106, on the distal side of the heme, and H267, the proximal side ligand, were constructed, all of which substantially reduced the catalatic activity and, to a lesser extent, the peroxidatic activity. In addition, the heme content of the variants was reduced relative to the wild-type enzyme. The relative ease of heme loss from HPI and a mixture of tetrameric enzymes with 2, 3, and 4 hemes was revealed by mass spectrometry analysis. Conversion of W105 to either an aromatic (F) or aliphatic (I) residue caused a 4-5-fold increase in peroxidatic activity, coupled with a >99% inhibition of catalatic activity. The peroxidatic-to-catalatic ratio of the W105F variant was increased 2800-fold such that compound I could be identified by both electronic and EPR spectroscopy as being similar to the porphyrin cation radical formed in other catalases and peroxidases. Compound I, when generated by a single addition of H(2)O(2), decayed back to the native or resting state within 1 min. When H(2)O(2) was generated enzymatically in situ at low levels, active compound I was evident for up to 2 h. However, such prolonged treatment resulted in conversion of compound I to a reversibly inactivated and, eventually, to an irreversibly inactivated species, both of which were spectrally similar to compound I.

Published
2000
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121. Catalase HPII from Escherichia coli exhibits enhanced resistance to denaturation.

Author

Switala J, O'Neil JO, and Loewen PC

Subjects
Catalase genetics, Circular Dichroism, Enzyme Activation genetics, Enzyme Stability genetics, Guanidine, Hot Temperature, Models, Molecular, Mutagenesis, Site-Directed, Protein Denaturation, Sodium Dodecyl Sulfate, Urea, Catalase chemistry, Catalase metabolism, Escherichia coli enzymology
Abstract

Catalase HPII from Escherichia coli is a homotetramer of 753 residue subunits. The multimer displays a number of unusual structural features, including interwoven subunits and a covalent bond between Tyr415 and His392, that would contribute to its rigidity and stability. As the temperature of a solution of HPII in 50 mM potassium phosphate buffer (pH 7) is raised from 50 to 92 degrees C, the enzyme begins to lose activity at 78 degrees C and 50% inactivation has occurred at 83 degrees C. The inactivation is accompanied by absorbance changes at 280 and 407 nm and by changes in the CD spectrum consistent with small changes in secondary structure. The subunits in the dimer structure remain associated at 95 degrees C and show a significant level of dissociation only at 100 degrees C. The exceptional stability of the dimer association is consistent with the interwoven nature of the subunits and provides an explanation for the resistance to inactivation of the enzyme. For comparison, catalase-peroxidase HPI of E. coli and bovine liver catalase are 50% inactivated at 53 and 56 degrees C, respectively. In 5.6 M urea, HPII exhibits a coincidence of inactivation, CD spectral change, and dissociation of the dimer structure with a midpoint of 65 degrees C. The inactive mutant variants of HPII which fold poorly during synthesis and which lack the Tyr-His covalent bond undergo spectral changes in the 78 to 84 degrees C range, revealing that the extra covalent linkage is not important in the enhanced resistance to denaturation and that problems in the folding pathway do not affect the ultimate stability of the folded structure.

Published
1999
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122. Role of the lateral channel in catalase HPII of Escherichia coli.

Author

Sevinc MS, Maté MJ, Switala J, Fita I, and Loewen PC

Subjects
Alanine genetics, Base Sequence, Binding Sites, Biopolymers, Catalase antagonists & inhibitors, Catalase chemistry, Catalase genetics, DNA Primers, Enzyme Inhibitors pharmacology, Mutagenesis, Site-Directed, NADP metabolism, Protein Conformation, Catalase metabolism, Escherichia coli enzymology
Abstract

The heme-containing catalase HPII of Escherichia coli consists of a homotetramer in which each subunit contains a core region with the highly conserved catalase tertiary structure, to which are appended N- and C-terminal extensions making it the largest known catalase. HPII does not bind NADPH, a cofactor often found in catalases. In HPII, residues 585-590 of the C-terminal extension protrude into the pocket corresponding to the NADPH binding site in the bovine liver catalase. Despite this difference, residues that define the NADPH pocket in the bovine enzyme appear to be well preserved in HPII. Only two residues that interact ionically with NADPH in the bovine enzyme (Asp212 and His304) differ in HPII (Glu270 and Glu362), but their mutation to the bovine sequence did not promote nucleotide binding. The active-site heme groups are deeply buried inside the molecular structure requiring the movement of substrate and products through long channels. One potential channel is about 30 A in length, approaches the heme active site laterally, and is structurally related to the branched channel associated with the NADPH binding pocket in catalases that bind the dinucleotide. In HPII, the upper branch of this channel is interrupted by the presence of Arg260 ionically bound to Glu270. When Arg260 is replaced by alanine, there is a threefold increase in the catalytic activity of the enzyme. Inhibitors of HPII, including azide, cyanide, various sulfhydryl reagents, and alkylhydroxylamine derivatives, are effective at lower concentration on the Ala260 mutant enzyme compared to the wild-type enzyme. The crystal structure of the Ala260 mutant variant of HPII, determined at 2.3 A resolution, revealed a number of local structural changes resulting in the opening of a second branch in the lateral channel, which appears to be used by inhibitors for access to the active site, either as an inlet channel for substrate or an exhaust channel for reaction products.

Published
1999
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123. 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
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124. 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
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125. 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
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126. Identification of a novel bond between a histidine and the essential tyrosine in catalase HPII of Escherichia coli.

Author

Bravo J, Fita I, Ferrer JC, Ens W, Hillar A, Switala J, and Loewen PC

Subjects
Amino Acid Sequence, Binding Sites, Catalase isolation & purification, Catalase metabolism, Crystallography, X-Ray, Models, Molecular, Molecular Sequence Data, Peptide Fragments chemistry, Spectrometry, Mass, Matrix-Assisted Laser Desorption-Ionization, Thermodynamics, Trypsin, Catalase chemistry, Escherichia coli enzymology, Histidine, Protein Conformation, Tyrosine
Abstract

A bond between the N delta of the imidazole ring of His 392 and the C beta of the essential Tyr 415 has been found in the refined crystal structure at 1.9 A resolution of catalase HPII of Escherichia coli. This novel type of covalent linkage is clearly defined in the electron density map of HPII and is confirmed by matrix-assisted laser desorption/ionization mass spectrometry analysis of tryptic digest mixtures. The geometry of the bond is compatible with both the sp3 hybridization of the C beta atom and the planarity of the imidazole ring. Two mutated variants of HPII active site residues, H128N and N201H, do not contain the His 392-Tyr 415 bond, and their crystal structures show that the imidazole ring of His 392 was rotated, in both cases, by 80 degrees relative to its position in HPII. These mutant forms of HPII are catalytically inactive and do not convert heme b to heme d, suggesting a relationship between the self-catalyzed heme conversion reaction and the formation of the His-Tyr linkage. A model coupling the two processes and involving the reaction of one molecule of H2O2 on the proximal side of the heme with compound 1 is proposed.

Published
1997
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127. Reaction of E. coli catalase HPII with cyanide as ligand and as inhibitor.

Author

Maj M, Nicholls P, Obinger C, Hillar A, and Loewen PC

Subjects
Animals, Catalase antagonists & inhibitors, Catalase genetics, Cattle, Kinetics, Ligands, Liver enzymology, Mutagenesis, Site-Directed, Spectrum Analysis, Catalase metabolism, Cyanides metabolism, Escherichia coli enzymology
Abstract

Cyanide forms an inhibitory complex with the haem d-containing E. coli catalase HPII, spectrally similar to the cyanide complex of beef liver enzyme but with absorption bands shifted 90 nm towards the red end of the spectrum. Both the Kd and Ki values are approximately 7 microM in the wild-type enzyme. The cyanide reaction is slow, with a bimolecular 'on' constant approx. 2000 x smaller than that of eukaryotic enzyme, and an 'off' constant diminished by a similar amount. Catalases with a mutated distal histidine (H128) fail to bind cyanide at cyanide concentrations below 50 mM. Catalases with a mutated distal asparagine (N201) show only small changes in cyanide affinity from the wild type. The major fraction of HPII N201A has a Kd approximately 40 microM, and a minor fraction has a lower cyanide affinity; the major fraction of HPII N201Q has a Kd approximately 15 microM. The Kd and Ki for HPII N201D is approximately 8 microM, essentially identical with that of the wild type but N201D appears to bind cyanide somewhat more rapidly than does wild-type enzyme. The HPII mutant N201H can be obtained in both haem d and protohaem forms; it exhibits two types of cyanide binding behaviour. In its protohaem form it binds cyanide poorly (Kd > or = 0.25 mM). After peroxide treatment converts t into haem d or a closely related species it binds cyanide with a much higher affinity (Kd approximately 15 microM). Cyanide binding to HPII requires a distal histidine to provide hydrogen-bonding stability, but not a distal asparagine. Rates of cyanide binding and release are controlled by haem group accessibility through the channel leading to the outside. In HPII N201H channel opening may depend upon oxidation of the haem from the starting protohaem to the final haem d form.

Published
1996
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128. 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
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129. The cysteines of catalase HPII of Escherichia coli, including Cys438 which is blocked, do not have a catalytic role.

Author

Sevinc MS, Ens W, and Loewen PC

Subjects
Base Sequence, Catalase physiology, Cysteine, Molecular Sequence Data, Mutagenesis, Site-Directed, Peroxides pharmacology, Structure-Activity Relationship, Sulfhydryl Reagents pharmacology, tert-Butylhydroperoxide, Catalase chemistry, Escherichia coli enzymology
Abstract

Site-directed mutagenesis of the katE gene of Escherichia coli was used to change, individually and in combination, Cys438 and Cys669 to serine in catalase HPII. The Cys438-->Ser mutation caused a 30% reduction in the specific activity of the enzyme, whereas the Cys669-->Ser mutation did not affect enzyme activity. The titration of free sulfhydryl groups in HPII revealed that Cys669 was reactive whereas Cys438 was unreactive. Properties of the modification on Cys438 included alkali lability, insensitivity to methylamine, hydroxylamine or reducing agents, and a mass determined by mass spectrometry to be approximately 43 +/- 2 Da. A hemithioacetal structure is consistent with these properties. Although free sulfhydryl groups do not play a significant role in the stability or catalytic mechanism of HPII, the sulfhydryl agent 2-mercaptoethanol caused a 50% inactivation of HPII along with an irreversible change in the absorption spectrum of the protein. Other sulfhydryl agents, including dithiothreitol, cysteine and glutathione, and the organic peroxide, t-butylhydroperoxide, which cannot directly access the active site, do not affect HPII activity, but they do cause a small reversible change in the absorption spectrum, possibly by a mechanism involving superoxide.

Published
1995

130. 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
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131. The active site structure of E. coli HPII catalase. Evidence favoring coordination of a tyrosinate proximal ligand to the chlorin iron.

Author

Dawson JH, Bracete AM, Huff AM, Kadkhodayan S, Zeitler CM, Sono M, Chang CK, and Loewen PC

Subjects
Binding Sites, Catalase chemistry, Circular Dichroism, Electron Spin Resonance Spectroscopy, Isoenzymes chemistry, Protein Conformation, Tyrosine, Catalase metabolism, Escherichia coli enzymology, Isoenzymes metabolism, Porphyrins
Abstract

E. coli produces 2 catalases known as HPI and HPII. While the heme prosthetic group of the HPII catalase has been established to be a dihydroporphyrin or chlorin, the identity of the proximal ligand to the iron has not been addressed. The magnetic circular dichroism (MCD) spectrum of native ferric HPII catalase is very similar to those of a 5-coordinate phenolate-ligated ferric chlorin complex, a model for tyrosinate proximal ligation, as well as of chlorin-reconstituted ferric horseradish peroxidase, a model for 5-coordinate histidine ligation. However, further MCD comparisons of chlorin-reconstituted myoglobin with parallel ligand-bound adducts of the catalase clearly rule out histidine ligation in the latter, leaving tyrosinate as the best candidate for the proximal ligand.

Published
1991
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132. Homology among bacterial catalase genes.

Author

Switala J, Triggs-Raine BL, and Loewen PC

Subjects
Blotting, Southern, DNA Probes, Enterobacteriaceae genetics, Escherichia coli genetics, Nucleic Acid Hybridization, Sequence Homology, Nucleic Acid, Catalase genetics, DNA, Bacterial analysis, Enterobacteriaceae enzymology, Escherichia coli enzymology
Abstract

Catalase activities in crude extracts of exponential and stationary phase cultures of various bacteria were visualized following gel electrophoresis for comparison with the enzymes from Escherichia coli. Citrobacter freundii, Edwardsiella tarda, Enterobacter aerogenes, Klebsiella pneumoniae, and Salmonella typhimurium exhibited patterns of catalase activity similar to E. coli, including bifunctional HPI-like bands and a monofunctional HPII-like band. Proteus mirabilis, Erwinia carotovora, and Serratia marcescens contained a single band of monofunctional catalase with a mobility intermediate between the HPI-like and HPII-like bands. The cloned genes for catalases HPI (katG) and HPII (katE) from E. coli were used as probes in Southern hybridization analyses for homologous sequences in genomic DNA of the same bacteria. katG was found to hybridize with fragments from C. freudii, Ent. aerogenes, Sal. typhimurium, and K. pneumoniae but not at all with Ed. tarda, P. mirabilis, S. marcesens, or Er. carotovora. katE hybridized with C. freundii and K. pneumoniae DNAs and not with the other bacterial DNAs.

Published
1990
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133. Molecular characterization of three mutations in katG affecting the activity of hydroperoxidase I of Escherichia coli.

Author

Loewen PC, Switala J, Smolenski M, and Triggs-Raine BL

Subjects
Base Sequence, Catalase drug effects, Catalase metabolism, Chromosome Mapping, Cloning, Molecular, Enzyme Activation, Escherichia coli genetics, Hydrogen Peroxide, Hydrogen-Ion Concentration, Kinetics, Molecular Sequence Data, Mutation, Nitrosoguanidines, Spectrum Analysis, Structure-Activity Relationship, Catalase genetics, Escherichia coli enzymology, Escherichia coli Proteins
Abstract

Hydroperoxidase I (HPI) of Escherichia coli is a bifunctional enzyme exhibiting both catalase and peroxidase activities. Mutants lacking appreciable HPI have been generated using nitrosoguanidine and the gene encoding HPI, katG, has been cloned from three of these mutants using either classical probing methods or polymerase chain reaction amplification. The mutant genes were sequenced and the changes from wild-type sequence identified. Two mutants contained G to A changes in the coding strand, resulting in glycine to aspartate changes at residues 119 (katG15) and 314 (katG16) in the deduced amino acid sequence of the protein. A third mutant contained a C to T change resulting in a leucine to phenylalanine change at residue 139 (katG14). The Phe139-, Asp119-, and Asp314-containing mutants exhibited 13, less than 1, and 18%, respectively, of the wild-type catalase specific activity and 43, 4, and 45% of the wild-type peroxidase specific activity. All mutant enzymes bound less protoheme IX than the wild-type enzyme. The sensitivities of the mutant enzymes to the inhibitors hydroxylamine, azide, and cyanide and the activators imidazole and Tris were similar to those of the wild-type enzyme. The mutant enzymes were more sensitive to high temperature and to beta-mercaptoethanol than the wild-type enzyme. The pH profiles of the mutant catalases were unchanged from the wild-type enzyme.

Published
1990
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134. Crystallization and preliminary X-ray diffraction analysis of catalase HPII from Escherichia coli.

Author

Tormo J, Fita I, Switala J, and Loewen PC

Subjects
Crystallization, X-Ray Diffraction, Catalase, Escherichia coli enzymology
Abstract

Green crystals of the hexameric catalase HPII from Escherichia coli have been obtained by the hanging-drop method. The crystals belong to the monoclinic space group P2 with a = 123 A, b = 132 A, c = 93 A, beta = 112.5 degrees. There are three subunits in the asymmetric unit. The crystals diffract at least to 3.2 A resolution and are suitable for further X-ray diffraction studies.

Published
1990
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138. Purification and characterization of spore-specific catalase-2 from Bacillus subtilis.

Author

Loewen PC and Switala J

Subjects
Amino Acids analysis, Bacillus subtilis physiology, Bacterial Proteins analysis, Catalase analysis, Molecular Weight, Spectrophotometry, Spores, Bacterial enzymology, Bacillus subtilis enzymology, Catalase isolation & purification
Abstract

Catalase-2, the catalase found in spores of Bacillus subtilis, has been purified to homogeneity from a nonsporulating strain. The apparent native molecular weight is 504,000. The enzyme appears to be composed of six identical protomers with a molecular weight of 81,000 each. The amino acid composition is similar to the composition of other catalases. Like most catalases, catalase-2 exhibits a broad pH optimum from pH 4 to pH 12 and is sensitive to cyanide, azide, thiol reagents, and amino triazole. The apparent Km for H2O2 is 78 mM. The enzyme exhibits extreme stability, losing activity only slowly at 93 degrees C and remaining active in 1% SDS-7 M urea. The green-colored enzyme exhibits a spectrum like heme d with a Soret absorption at 403 nm and a molar absorptivity consistent with one heme per subunit. The heme cannot be extracted with acetone-HCl or ether, suggesting that it is covalently bound to the protein.

Published
1988
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139. Detection of p-aminobenzoylpoly(gamma-glutamates) using fluorescamine.

Author

Furness RA and Loewen PC

Subjects
4-Aminobenzoic Acid analysis, Animals, Bacteria analysis, Glutamates analysis, Glutamic Acid, Hydrogen-Ion Concentration, Polyglutamic Acid analogs & derivatives, Rats, Spectrometry, Fluorescence, Fluorescamine, Peptides analysis, Polyglutamic Acid analysis, Spiro Compounds
Published
1981
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140. Physical characterization of katG, encoding catalase HPI of Escherichia coli.

Author

Triggs-Raine BL and Loewen PC

Subjects
Catalase metabolism, Chromosome Deletion, DNA Restriction Enzymes, DNA Transposable Elements, Escherichia coli enzymology, Genotype, Plasmids, Promoter Regions, Genetic, Transcription, Genetic, Catalase genetics, Escherichia coli genetics, Genes, Genes, Bacterial, Peroxidases genetics
Abstract

The gene encoding the bifunctional catalase-peroxidase HPI from Escherichia coli was located on a 3.8-kb HindIII fragment of the Clarke and Carbon plasmid pLC36-19 using transposon Tn5 insertions. This fragment was subcloned into the HindIII site of pAT153 to create pBT22. The size of the insert was reduced by BAL 31 digestion of one end to an apparent minimum size for catalase expression of approx. 2.5 kb as determined by complementation and expression in maxicell strains. Further reduction in size or digestion from the opposite end inactivated the gene. The location and orientation of the promoter at the 0 kb end of the insert in pBT22 was confirmed by cloning a 320-bp BglII fragment into the promoter-cloning vector pKK232-8. Differences in the Southern blots of genomic DNA from a wild-type strain and a katG17::Tn10 mutant digested with HincII and probed with pBT22 confirmed that the transposon previously mapped in katG was located in the 2.5-kb coding region for HPI.

Published
1987
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141. Inhibition of sugar uptake by ascorbic acid in Escherichia coli.

Author

Loewen PC and Richter HE

Subjects
Biological Transport, Active drug effects, Deoxyglucose metabolism, Escherichia coli drug effects, Kinetics, Methylglucosides metabolism, Oxidation-Reduction, Ascorbic Acid pharmacology, Escherichia coli metabolism, Glucose metabolism
Abstract

The uptake of glucose by the glucose phosphotransferase system in Escherichia coli was inhibited greater than 90% by ascorbate. The uptake of the nonmetabolizable analog of glucose, methyl-alpha-glucoside, was also inhibited to the same extent, confirming that it was the transport process that was sensitive to ascorbate. Similarly, it was the transport function of mannose phosphotransferase for which mannose and nonmetabolizable 2-deoxyglucose were substrates that was partially inhibited by ascorbate. Other phosphotransferase systems, including those for the uptake of sorbitol, fructose and N-acetylglucosamine, but not mannitol, were also inhibited to varying degrees by ascorbate. The inhibitory effect on the phosphotransferase systems was reversible, required the active oxidation of ascorbate, was sensitive to the presence of free-radical scavengers, and was insensitive to uncouplers. Because ascorbate was not taken up by E. coli, it was concluded that the active inhibitory species was the ascorbate free radical and that it was interacting reversibly with a membrane component, possibly the different enzyme IIB components of the phosphotransferase systems. Ascorbate also inhibited other transport systems causing a slight reduction in the passive diffusion of glycerol, a 50% inhibition of the shock-sensitive uptake of maltose, and a complete inhibition of the proton-symport uptake of lactose. Radical scavengers had little or no effect on the inhibition of these systems.

Published
1983
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142. Purification and characterization of catalase-1 from Bacillus subtilis.

Author

Loewen PC and Switala J

Subjects
Amino Acids analysis, Bacillus subtilis growth & development, Heme analysis, Hydrogen-Ion Concentration, Kinetics, Macromolecular Substances, Molecular Weight, Spectrum Analysis, Bacillus subtilis enzymology, Catalase isolation & purification
Abstract

The catalase activity produced in vegetative Bacillus subtilis, catalase-1, has been purified to homogeneity. The apparent native molecular weight was determined to be 395,000. Only one subunit type with a molecular weight of 65,000 was present, suggesting a hexamer structure for the enzyme. In other respects, catalase-1 was a typical catalase. Protoheme IX was identified as the heme component on the basis of the spectra of the enzyme and of the isolated hemochromogen. The ratio of protoheme/subunit was 1. The enzyme remained active over a broad pH range of 5-11 and was only slowly inactivated at 65 degrees C. It was inhibited by cyanide, azide, and various sulfhydryl compounds. The apparent Km for hydrogen peroxide was 40.1 mM. The amino acid composition was typical of other catalases in having relatively low amounts of tryptophan and cysteine.

Published
1987
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143. Identification and physical characterization of a Col E1 hybrid plasmid containing a catalase gene of Escherichia coli.

Author

Loewen PC, Triggs BL, Klassen GR, and Weiner JH

Subjects
Base Sequence, Catalase isolation & purification, DNA Restriction Enzymes, Escherichia coli enzymology, Gene Amplification, Molecular Weight, Species Specificity, Bacteriocin Plasmids, Catalase genetics, Escherichia coli genetics, Genes, Genes, Bacterial, Plasmids
Abstract

A hybrid Escherichia coli: Col E1 plasmid, pLC36-19, containing a catalase gene has been identified in the Clarke and Carbon colony bank. Catalase activity was amplified two- to three-fold in the pLC36-19-containing strain relative to other hybrid-plasmid-containing strains and this activity could be induced three- or four-fold by hydrogen peroxide or ascorbic acid. The plasmid was transferred to a strain chromosomally deficient in catalase synthesis, resulting in a strain with high and inducible levels of catalase. The plasmid was also transferred to a minicell-producing strain and minicells harbouring the plasmid were found to synthesize a labelled protein with a molecular weight of 84 000 characteristic of catalase from E. coli. A catalase activity was also synthesized by the plasmid-containing minicells. Two catalase activities with associated peroxidase activities coded for by the plasmid were separable by polyacrylamide gel electrophoresis and migrated coincident with chromosomally encoded catalase-peroxidase activities. A third catalase activity which did not have an associated peroxidase activity was not coded for by the plasmid. A physical map of the 25.5-kilobase pair plasmid was constructed by restriction nuclease analysis and the relative positions of 38 restriction sites were defined.

Published
1983
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144. Catalases HPI and HPII in Escherichia coli are induced independently.

Author

Loewen PC, Switala J, and Triggs-Raine BL

Subjects
Ascorbic Acid pharmacology, Catalase genetics, Citrate (si)-Synthase metabolism, Culture Media, Electron Transport, Electrophoresis, Polyacrylamide Gel, Enzyme Induction, Glucose pharmacology, Lactose pharmacology, Malate Dehydrogenase metabolism, Mutation, Peroxidases metabolism, Succinates pharmacology, Succinic Acid, Catalase biosynthesis, Escherichia coli enzymology
Abstract

Three strains of Escherichia coli differing only in the catalase locus mutated by transposon Tn10 were constructed. These strains produced only catalase HPI (katE::Tn10 and katF::Tn10 strains) or catalase HPII (katG::Tn10). HPI levels increased gradually about twofold during logarithmic growth but did not increase during growth into stationary phase in rich medium. HPII levels, which were initially threefold lower than HPI levels, did not change during logarithmic growth but did increase tenfold during growth into stationary phase. HPI levels increased in response to ascorbate or H2O2 being added to the medium but HPII levels did not. In minimal medium, any carbon source derived from the tricarboxylic acid cycle caused five- to tenfold higher HPII levels during logarithmic growth but had very little effect on HPI levels. Active electron transport did not affect either HPI or HPII levels.

Published
1985
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145. Identification of a coenzyme A--glutathione disulfide (DSI), a modified coenzyme A disulfide (DSII), and a NADPH-dependent coenzyme A--glutathione disulfide reductase in E. coli.

Author

Loewen PC

Subjects
Coenzyme A isolation & purification, Coenzyme A metabolism, Escherichia coli growth & development, Glutathione analogs & derivatives, Coenzyme A analogs & derivatives, Escherichia coli metabolism, NADH, NADPH Oxidoreductases metabolism
Abstract

The nucleotides DSI and DSII induced during a slowdown in growth of E. coli have been characterized using chemical and biochemical analysis and by enzymic and alkaline fragmentation. DSI consists a coenzyme A and glutathione joined by a disulfide linkage. DSI could be isolated either containing Fe(III) with an A250:260 ratio of 1.05 or not containing iron with an A250:260 of 0.87. DSII (isolated in 10% the yield of DSI) is a coenzyme A disulfide dimer that also contains two molecules of glutamic acid. DSI was a substrate for NADPH-dependent CoAS-SG reductase (EC 1.6.4.6) which was present in crude extracts of E. coli. The specific activity of CoAS-SG reductase increased during growth from early log phase into stationary phase and during a shift from aerobic to anaerobic growth.

Published
1977
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146. Equine parvovirus: initial isolation and partial characterization.

Author

Wong FC, Spearman JG, Smolenski MA, and Loewen PC

Subjects
Abortion, Veterinary etiology, Animals, Female, Hemagglutination Inhibition Tests, Hemagglutination, Viral, Horse Diseases etiology, Horses microbiology, Liver microbiology, Parvoviridae immunology, Parvoviridae pathogenicity, Parvoviridae ultrastructure, Parvoviridae Infections microbiology, Pregnancy, Swine, Abortion, Veterinary microbiology, Fetus microbiology, Horse Diseases microbiology, Parvoviridae isolation & purification, Parvoviridae Infections veterinary
Abstract

A viral agent was isolated from the fetal liver of an aborted equine fetus. The isolate hemagglutinated red blood cells from guinea pig, rhesus monkey and rooster. By hemagglutination inhibition tests, the isolate was shown to be antigenically distinct from parvoviruses of bovine and canine origin. Specific hemagglutination inhibiting antibody against the viral isolate was exhibited by 26 of 136 horse sera tested. The isolated virus showed properties compatible with those of an autonomous parvovirus including size, morphology, stability to ether treatment and heating to 56 degrees C, the presence of a 5300 base DNA genome, characteristic protein composition and density (1.405 g/mL). The virus was classified as an equine parvovirus.

Published
1985

147. Partial characterization of the mode of inhibition of Escherichia coli RNA polymerase by the mixed disulfide, CoASSG.

Author

Bees WC and Loewen PC

Subjects
Coenzyme A pharmacology, Glutathione pharmacology, Iron pharmacology, Kinetics, Rifampin pharmacology, Structure-Activity Relationship, Templates, Genetic, Transcription, Genetic, Coenzyme A analogs & derivatives, DNA-Directed RNA Polymerases antagonists & inhibitors, Escherichia coli enzymology, Glutathione analogs & derivatives
Abstract

The coenzyme A-glutathione mixed disulfide (CoASSG), when complexed with iron, is capable of inhibiting the RNA polymerase of Escherichia coli. A modified procedure involving a short time of exposure to high salt allowed the reliable preparation of CoASSG-Fe which was active in inhibiting RNA polymerase. The CoASSG-Fe complex acted as a noncompetitive inhibitor for the incorporation of all four nucleoside triphosphates but had a greater effect on GMP and CMP incorporation than AMP and UMP incorporation. Neither temperature nor ionic-strength changes affected CoASSG-Fe inhibition, and the use of rifampicin showed that CoASSG-Fe did not inhibit either the initiation or elongation processes of the polymerase. CoASSG-Fe was a more effective inhibitor at low DNA-template concentrations and it was more effective in inhibiting the incorporation of CMP and GMP on simple dG-dC containing templates and the asymmetric polymer poly d(T-C) . poly d(G-A). The inhibition of transcription of poly d(I-C) was less effective than the inhibition of transcription of poly d(G-C). Equilibrium dialysis in microdialysis cells showed that CoASSG-Fe could associate with DNA in the absence of RNA polymerase.

Published
1979
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148. Purification and characterization of catalase HPII from Escherichia coli K12.

Author

Loewen PC and Switala J

Subjects
Catalase isolation & purification, Catalase metabolism, Isoenzymes metabolism, Kinetics, Macromolecular Substances, Molecular Weight, Peroxidase, Peroxidases metabolism, Escherichia coli enzymology, Isoenzymes isolation & purification, Peroxidases isolation & purification
Abstract

Catalase (hydroperoxidase II or HPII) of Escherichia coli K12 has been purified using a protocol that also allows the purification of the second catalase HPI in large amounts. The purified HPII was found to have equal amounts of two subunits with molecular weights of 90,000 and 92,000. Only a single 92,000 subunit was present in the immunoprecipitate created when HPII antiserum was added directly to a crude extract, suggesting that proteolysis was responsible for the smaller subunit. The apparent native molecular weight was determined to be 532,000, suggesting a hexamer structure for the enzyme, an unusual structure for a catalase. HPII was very stable, remaining maximally active over the pH range 4-11 and retaining activity even in a solution of 0.1% sodium dodecyl sulfate and 7 M urea. The heme cofactor associated with HPII was also unusual for a catalase, in resembling heme d (a2) both spectrally and in terms of solubility. On the basis of heme-associated iron, six heme groups were associated with each molecule of enzyme or one per subunit.

Published
1986
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149. Levels of coenzyme A--glutathione mixed disulfide in Escherichia coli.

Author

Loewen PC

Subjects
Ammonia administration & dosage, Culture Media, Disulfides metabolism, Escherichia coli growth & development, Fermentation, Glucose administration & dosage, Oxygen, Coenzyme A metabolism, Escherichia coli metabolism, Glutathione metabolism
Abstract

The pool of coenzyme A--glutathione mixed disulfide (CoASSG) rapidly increased 2.0 times in response to oxygen starvation and 1.5 times in response to glucose starvation but did not change following ammonia starvation. The increase in the CoASSG pool resulted from an increase in the CoASSG fraction of the CoA pool from 42 to 66--93%. Fluoride, cyanide, chloramphenicol, and rifampicin all caused similar increases. Aerobic growth on fermentable sugars resulted in CoASSG making up 40--55% of the CoA pool while growth on nonfermentable carbon sources or anaerobic fermentation resulted in CoASSG replacing acetyl CoA and free CoA to make up 85--95% of the CoA pool. The CoASSG:ATP ratio varied inversely with the growth rate in two groupings of carbon sources made up of either fermentable or nonfermentable molecules. Cultures grown aerobically on fermentable sugars exhibited a lower CoASSG:ATP ratio reflecting the lower proportion of CoASSG in the CoA pool.

Published
1978
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150. Cloning and physical characterization of katE and katF required for catalase HPII expression in Escherichia coli.

Author

Mulvey MR, Sorby PA, Triggs-Raine BL, and Loewen PC

Subjects
Bacteriophage lambda genetics, Escherichia coli enzymology, Genotype, Nucleic Acid Hybridization, Plasmids, Catalase genetics, Cloning, Molecular methods, Escherichia coli genetics, Genes, Genes, Bacterial, Isoenzymes genetics
Abstract

Two genes, katE and katF, affecting the synthesis of catalase HPII in Escherichia coli, have been cloned. The multistep cloning protocol involved: screening for the tet gene in a transposon interrupting the genes, selecting DNA adjacent to the transposon, and using it to probe a library of wild-type DNA to select clones from which katE and katF were subcloned into pAT153. The clones were physically characterized and the presence of the genes confirmed by complementation of their respective mutations. The location of the transposon insertions in the two genes was determined by Southern blotting of genomic digests to further confirm the identity of the cloned genes. A 93-kDa protein, the same size as the subunit of HPII, was encoded by the katE plasmid, indicating that katE was the structural gene for HPII. A 44-kDa protein was encoded by the katF plasmid.

Published
1988
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