Your search keyword '"H. Knauer"' showing total 4 results

1. Escherichia coli NusG Links the Lead Ribosome with the Transcription Elongation Complex

Author

Bingxin Shen, Max E. Gottesman, Ming Sun, Stefan H. Knauer, Joachim Frank, Wen Li, Robert S. Washburn, Yaser Hashem, Sho Harvey, and Philipp K. Zuber

Subjects

chemistry.chemical_compound, Transcription elongation, Structural biology, Chemistry, Transcription (biology), RNA polymerase, medicine, Translation (biology), Conclusive evidence, medicine.disease_cause, Ribosome, Escherichia coli, Cell biology

Abstract

It has been known for more than 50 years that transcription and translation are physically coupled in bacteria, but whether or not this coupling may be mediated by the two-domain protein N-utilization substance (Nus) G in Escherichia coli is still heavily debated. Here, we combine integrative structural biology and functional analyses to provide conclusive evidence that NusG can physically link transcription with translation by contacting both RNA polymerase and the ribosome. We present a cryo-electron microscopy structure of a NusG:70S ribosome complex and nuclear magnetic resonance spectroscopy data revealing simultaneous binding of NusG to RNAP and the intact 70S ribosome, providing the first direct structural evidence for NusG-mediated coupling. Furthermore, in vivo reporter assays show that recruitment of NusG occurs late in transcription and strongly depends on translation. Thus, our data suggest that coupling occurs initially via direct RNAP: ribosome contacts and is then mediated by NusG.

Published

2020

2. Determinants of Substrate Binding and Protonation in the Flavoenzyme Xenobiotic Reductase A

Author

Holger Dobbek, Sophia Mende, Stefan H. Knauer, Olivia Spiegelhauer, and Tobias Werther

Subjects

Models, Molecular, Stereochemistry, Coenzymes, Flavin group, Reductase, Redox, Xenobiotics, Bacterial Proteins, Structural Biology, Oxidoreductase, Binding site, Molecular Biology, chemistry.chemical_classification, Binding Sites, Flavoproteins, biology, Pseudomonas putida, Substrate (chemistry), Active site, NAD, Protein Structure, Tertiary, Amino Acid Substitution, chemistry, Mutagenesis, Site-Directed, biology.protein, NADPH binding, Mutant Proteins, Oxidoreductases, Oxidation-Reduction, NADP, Protein Binding

Abstract

Xenobiotic reductase A (XenA) from Pseudomonas putida 86 catalyzes the NAD(P)H-dependent reduction of various α,β-unsaturated carbonyl compounds and is a member of the old yellow enzyme family. The reaction of XenA follows a ping-pong mechanism, implying that its active site has to accommodate and correctly position the various substrates to be oxidized (NADH/NADPH) and to be reduced (different α,β-unsaturated carbonyl compounds) to enable formal hydride transfers between the substrate and the isoalloxazine ring. The active site of XenA is lined by two tyrosine (Tyr27, Tyr183) and two tryptophan (Trp302, Trp358) residues, which were proposed to contribute to substrate binding. We analyzed the individual contributions of the four residues, using site-directed mutagenesis, steady-state and transient kinetics, redox potentiometry and crystal structure analysis. The Y183F substitution decreases the affinity of XenA for NADPH and reduces the rate of the oxidative half-reaction by two to three orders of magnitude, the latter being in agreement with its function as a proton donor in the oxidative half-reaction. Upon reduction of the flavin, Trp302 swings into the active site of XenA (in-conformation) and decreases the extent of the substrate-binding pocket. Its exchange against alanine induces substrate inhibition at elevated NADPH concentrations, indicating that the in-conformation of Trp302 helps to disfavor the nonproductive NADPH binding in the reduced state of XenA. Our analysis shows that while the principal catalytic mechanism of XenA, for example, type of proton donor, is analogous to that of other members of the old yellow enzyme family, its strategy to correctly position and accommodate different substrates is unprecedented.

Published

2010

3. Cysteine as a Modulator Residue in the Active Site of Xenobiotic Reductase A: A Structural, Thermodynamic and Kinetic Study

Author

Sophia Mende, Olivia Spiegelhauer, Holger Dobbek, Frank Dickert, G. Matthias Ullmann, and Stefan H. Knauer

Subjects

Protein Conformation, Stereochemistry, Molecular Sequence Data, Flavin group, Reductase, Substrate Specificity, Xenobiotics, Coumarins, Structural Biology, Oxidoreductase, Serine, Amino Acid Sequence, Cysteine, Molecular Biology, Alanine, chemistry.chemical_classification, Binding Sites, biology, Pseudomonas putida, Substrate (chemistry), Active site, NAD, biology.organism_classification, Kinetics, Amino Acid Substitution, chemistry, Mutagenesis, Site-Directed, biology.protein, Thermodynamics, Oxidoreductases, Oxidation-Reduction, NADP

Abstract

Xenobiotic reductase A (XenA) from Pseudomonas putida 86 catalyzes the NADH/NADPH-dependent reduction of various substrates, including 2-cyclohexenone and 8-hydroxycoumarin. XenA is a member of the old yellow enzyme (OYE) family of flavoproteins and is structurally and functionally similar to other bacterial members of this enzyme class. A characteristic feature of XenA is the presence of a cysteine residue (Cys25) in the active site, where in most members of the OYE family a threonine residue is found that modulates the reduction potential of the FMN/FMNH – couple. We investigated the role of Cys25 by studying two variants in which the residue has been exchanged for a serine and an alanine residue. While the exchange against alanine has a remarkably small effect on the reduction potential, the reactivity and the structure of XenA, the exchange against serine increases the reduction potential by +82 mV, increases the rate constant of the reductive half-reaction and decreases the rate constant in the oxidative half-reaction. We determined six crystal structures at high to true atomic resolution ( d min 1.03–1.80 A) of the three XenA variants with and without the substrate coumarin bound in the active site. The atomic resolution structure of XenA in complex with coumarin reveals a compressed active site geometry in which the isoalloxazine ring is sandwiched between coumarin and the protein backbone. The structures further reveal that the conformation of the active site and substrate interactions are preserved in the two variants, indicating that the observed changes are due to local effects only. We propose that Cys25 and the residues in its place determine which of the two half-reactions is rate limiting, depending on the substrate couple. This might help to explain why the genome of Pseudomonas putida encodes multiple xenobiotic reductases containing either cysteine, threonine or alanine in the active site.

Published

2010

4. High-performance liquid chromatography of ions

Author

D. Wilk, I. Molnar, and H. Knauer

Subjects

inorganic chemicals, Chromatography, Aqueous solution, Chemistry, Organic Chemistry, Analytical chemistry, food and beverages, Ionic bonding, General Medicine, Conductivity, Biochemistry, High-performance liquid chromatography, Analytical Chemistry, Ion, Column chromatography, Phase (matter), Solvophobic

Abstract

Summary High-performance liquid chromatography of ions (ion-HPLC) can be performed with columns packed with non-polar (or solvophobic) stationary phases often at much higher efficiencies than with ion-exchange resins. The use of suppressor columns which decrease the conductivity of the eluent can increase sensitivity of conductivity detection. Ion-HPLC is possible also without a suppressor column, if specially designed, sensitive conductivity detectors are used. Reversed-phase chromatography using secondary equilibria in the mobile phase and conductivity detectors offers a new way of investigating the properties of ionic species in aqueous and organic solvents. The separation of Na+, K+, NH4+ and Ca2+, and of F−, Cl−, SO42−, NO2−, Br−, Cr2O72−, NO3−, I−, etc., is demonstrated on RP-18 columns. Conductivity detectors can be of assistance in HPLC to characterize and determine ionic equilibria in chemistry, the life sciences and in qualitative and quantitative ion analysis.

Published

1980