Brownian dynamics study of cytochrome f / Rieske interactions with cytochrome c6 and plastocyanin

Jafari haddadian, Esmael

24 August 2005

No description available.

cyt

cyt c6

RIESKE

PC and cyt

reinhardtii

PC

C6

Structural Driving Factors for the Coupled Electron and Proton Transfer Reactions in Mitochondrial Cytochrome BC1 Complex: Binding Geometries of Substrates and Protonation States of Ionizable Amino Acid Side Chains Near Qi and Qo Sites

Nguyen, Bao Linh Tran

16 April 2014

Coupled electron and proton transfer (CEPT) events are fundamental for many bioenergetic conversions that involve redox reactions. Understanding the details underlying CEPT processes will advance our knowledge of (1) how nature regulates energy conversion; (2) our strategies for achieving renewable energy sources; (3) how to cope with CEPT dysfunction diseases. Studies of the detailed mechanism(s) of CEPT in biological systems is challenging due to their complex nature. Consequently, controversies between the concerted and sequential mechanism of CEPT for many systems remain. This dissertation focuses on the bovine mitochondrial cytochrome bc1 complex. CEPT in the bc1 complex operates by a modified "Q-cycle"(1) and catalyzes electron transfer from ubiquinol (QH2), to cyt c via an iron sulfur cluster (ISC) and to the low potential hemes of cyt b, where it reduces ubiquinone (UQ). The electron transfer is coupled to the translocation of protons across the mitochondrial inner membrane, generating a proton gradient that drives ATP synthesis. Although the Q-cycle is widely accepted as the model that best describes how electrons and protons flow in bc1, detailed binding geometries at the Qo site (QH2 oxidation site) and Qi site (UQ reduction site) remain controversial. The binding geometries play critical roles in the thermodynamic and/or kinetic control of the reaction and protonatable amino acid side chains can participate in the proton transfer. The central focuses of this dissertation are molecular dynamics simulations of cofactor binding geometries near the Qo and Qi sites, calculations of the pKa values of ionizable amino acid side chains implicated in cofactor binding, especially the ISC-coordinated histidines, and implications for the proposed mechanism(s) of CEPT. For the first time, pKa values of the ISC-coordinated histidines are differentiated. The computed pKa values of 7.8±0.5 for His141 and 9.1±0.6 for His161 agree well with experiment (7.63±0.15 and 9.16±0.28). Thus, His161 should be protonated at physiological pH and cannot be the first proton acceptor in the QH2 oxidation. Water mediated hydrogen bonds between substrate models and the protein and water accessibility to the Qo and Qi sites were maintained in simulations, implying that water molecules are likely the proton donors and acceptors. / Bayer School of Natural and Environmental Sciences; / Chemistry and Biochemistry / PhD; / Dissertation;

Metabolism, enzymology, and genetic characterization of caffeine degradation by pseudomonas putida CBB5

Summers, Ryan Michael

01 July 2011

A novel caffeine-degrading bacterium, Pseudomonas putida CBB5 was isolated from the soil by an enrichment procedure using caffeine as the sole source of carbon and nitrogen. CBB5 grew not only on caffeine, theobromine, paraxanthine, and 7-methylxanthine as sole carbon and nitrogen sources, but also on theophylline and 3-methylxanthine. Analyses of metabolites in spent media, resting cell suspensions, and crude cell extracts confirmed that CBB5 degraded caffeine via N-demethylation to theobromine (major metabolite) and paraxanthine (minor metabolite). These dimethylxanthines were further N-demethylated to xanthine via 7-methylxanthine. A previously unreported pathway for N-demethylation of theophylline to 1- and 3-methylxanthines, followed by further N-demethylation to xanthine, was also discovered in CBB5. A 240 kDa, Fe2+-dependent N-demethylase (Ndm) was purified from CBB5 by traditional chromatographic techniques. Ndm was composed of NdmA (40 kDa) and NdmB (35 kDa), which could not be resolved further. Ndm was active only in the presence of a partially purified protein which exhibited cytochrome c reductase activity (Ccr). Ccr transfered reducing equivalents from NAD(P)H to Ndm, which catalyzed an oxygen-dependent N-demethylation of methylxanthines to xanthine, formaldehyde and water. Ndm displayed N-demethylation activity toward all substrates in the caffeine and theophylline metabolic pathways. Ndm was deduced to be a Rieske [2Fe-2S]-domain-containing non-heme iron oxygenase base on its distinct absorption spectrum and significant identity of NdmA and NdmB sequences of other Rieske non-heme iron proteins. The ndmA- and ndmB- gene sequences were determined and cloned individually into the pET32a expression vector as C-terminal His-tagged proteins. Both NdmA-His and NdmB-His proteins were purified using a Ni-NTA column. NdmA-His, in conjunction with Ccr, was capable of N-demethylating caffeine, theophylline, paraxanthine, and 1-methylxanthine to theobromine, 3-methylxanthine, 7-methylxanthine, and xanthine, respectively, suggesting that NdmA-His is a specific N-1-demethylase. Similarly, NdmB-His was determined to be a specific N-3-demethylase, as it was capable of N-demethylating caffeine, theophylline, theobromine, and 3-methylxanthine to paraxanthine, 1-methylxanthine, 7-methylxanthine, and xanthine, respectively. N-demethylation activity of 7-methylxanthine to xanthine (putative NdmC) co-eluted with the partially purified Ccr fraction. This is the first report of multiple, highly positional-specific, Rieske, non-heme iron N-demethylase enzymes for bacterial metabolism of purine alkaloids.

caffeine metabolism

N-demethylase

NdmA

NdmB

Pseudomonas putida CBB5

Rieske oxygenase

Chemical Engineering

Spectroscopic and kinetic studies of mononuclear molybdenum enzymes of the DMSO reductase family

Cobb, Nathan Jeremy

19 April 2005

No description available.

Chemistry, Biochemistry

DMSOR

DMSO reductase

arsenite oxidase

arsenite

arsenate

EPR

resonance Raman

DMSO

TMAO

3Fe-4S

Rieske

Mo(V)

Protein Coevolution and Coadaptation in the Vertebrate bc1 Complex

Baer, Kimberly Kay

16 July 2007

The cytochrome bc1 complex of the mitochondrial electron transport chain accomplishes the enzymatic reaction known as the modified Q-cycle. In the Q-cycle the bc1 complex transports protons from the matrix to the intermembrane space of the mitochondria, creating the proton gradient used to make ATP. The energy to move these protons is obtained by shuttling electrons from the coenzyme ubiquinol (QH2) to coenzyme ubiquinone (Q) and the mobile cytochrome c. This well studied complex is ideal for examining molecular adaptation because it consists of ten different subunits, it functions as a dimer, and it includes at least five different active sites. The program TreeSAAP was used to characterize molecular adaptation in the bc1 complex and identify specific amino acid sites that experienced positive destabilizing (radical) selection. Using this information and three-dimensional structures of the protein complex, selection was characterized in terms of coevolution and coadaptation. Coevolution is described as reciprocal local biochemical shifts based on phylogenetic location and results in overall maintenance. Coadaptation, on the other hand, is more dynamic and is described as coordinated local biochemical shifts based on phylogenetic location which results in overall adaptation. In this study both coevolution and coadaptation were identified in various locations on the protein complex near the active sites. Sites in the pore region of cyt c1 were shown to exhibit coevolution, in other words maintenance, of many biochemical properties, whereas sites on helix H of cyt b, which flanks the active sites Qo and Qi, were shown to exhibit coadaptation, in other words coordinated shifts in the specific properties equilibrium constant and solvent accessible reduction ratio. Also, different domains of the protein exhibited significant shifts in drastically different amino acid properties: the protein imbedded in the membrane demonstrated shifts in mainly functional properties, while the part of the complex in the intermembrane space demonstrated shifts in conformational, structural, and energetic properties.

cytochrome bc1 complex

protein coadaptation

protein coevolution

cytochrome b

cytochrome c1

rieske iron sulfur protein

coenzyme q

TreeSAAP

physicochemical amino acid properties

biochemical adaptation

Biology

New Biomimetic Analogues of Functional [2Fe-2S] Proteins / Neue biomimetische Analoga von funktionellen [2Fe-2S] Proteinen

Ballmann, Hans Joachim

29 October 2008

No description available.

540 Chemie

Mathematics and Computer Science

Bioanorganische Chemie

Eisen-Schwefel Cluster

Modellverbindungen

Rieske

[2Fe-2S]

bioinorganic chemistry

iron-sulfur clusters

model compounds

Rieske

[2Fe-2S]

35.42

35.43

35.79

STR 200: Eisen {Anorganische Chemie}

STO 250: Schwefel {Anorganische Chemie}

SOC 250: Metallkomplexe

Chelate {Chemie: Verbindungstypen}