Your search keyword '"Marritt SJ"' showing total 3 results

1. Protein-protein interaction regulates the direction of catalysis and electron transfer in a redox enzyme complex.

Author

McMillan DG, Marritt SJ, Firer-Sherwood MA, Shi L, Richardson DJ, Evans SD, Elliott SJ, Butt JN, and Jeuken LJ

Subjects

Biocatalysis, Cytochrome c Group metabolism, Electron Transport, Models, Molecular, Oxidation-Reduction, Protein Binding, Shewanella enzymology, Cytochrome c Group chemistry

Abstract

Protein-protein interactions are well-known to regulate enzyme activity in cell signaling and metabolism. Here, we show that protein-protein interactions regulate the activity of a respiratory-chain enzyme, CymA, by changing the direction or bias of catalysis. CymA, a member of the widespread NapC/NirT superfamily, is a menaquinol-7 (MQ-7) dehydrogenase that donates electrons to several distinct terminal reductases in the versatile respiratory network of Shewanella oneidensis . We report the incorporation of CymA within solid-supported membranes that mimic the inner membrane architecture of S. oneidensis . Quartz-crystal microbalance with dissipation (QCM-D) resolved the formation of a stable complex between CymA and one of its native redox partners, flavocytochrome c3 (Fcc3) fumarate reductase. Cyclic voltammetry revealed that CymA alone could only reduce MQ-7, while the CymA-Fcc3 complex catalyzed the reaction required to support anaerobic respiration, the oxidation of MQ-7. We propose that MQ-7 oxidation in CymA is limited by electron transfer to the hemes and that complex formation with Fcc3 facilitates the electron-transfer rate along the heme redox chain. These results reveal a yet unexplored mechanism by which bacteria can regulate multibranched respiratory networks through protein-protein interactions.

Published

2013

2. Concentrating membrane proteins using asymmetric traps and AC electric fields.

Author

Cheetham MR, Bramble JP, McMillan DG, Krzeminski L, Han X, Johnson BR, Bushby RJ, Olmsted PD, Jeuken LJ, Marritt SJ, Butt JN, and Evans SD

Subjects

Cell Membrane chemistry, Electricity, Lipid Bilayers chemistry, Membrane Proteins isolation & purification

Abstract

Membrane proteins are key components of the plasma membrane and are responsible for control of chemical ionic gradients, metabolite and nutrient transfer, and signal transduction between the interior of cells and the external environment. Of the genes in the human genome, 30% code for membrane proteins (Krogh et al. J. Mol. Biol.2001, 305, 567). Furthermore, many FDA-approved drugs target such proteins (Overington et al. Nat. Rev. Drug Discovery 2006, 5, 993). However, the structure-function relationships of these are notably sparse because of difficulties in their purification and handling outside of their membranous environment. Methods that permit the manipulation of membrane components while they are still in the membrane would find widespread application in separation, purification, and eventual structure-function determination of these species (Poo et al. Nature 1977, 265, 602). Here we show that asymmetrically patterned supported lipid bilayers in combination with AC electric fields can lead to efficient manipulation of charged components. We demonstrate the concentration and trapping of such components through the use of a "nested trap" and show that this method is capable of yielding an approximately 30-fold increase in the average protein concentration. Upon removal of the field, the material remains trapped for several hours as a result of topographically restricted diffusion. Our results indicate that this method can be used for concentrating and trapping charged membrane components while they are still within their membranous environment. We anticipate that our approach could find widespread application in the manipulation and study of membrane proteins., (© 2011 American Chemical Society)

Published

2011

3. Spectroelectrochemical characterization of a pentaheme cytochrome in solution and as electrocatalytically active films on nanocrystalline metal-oxide electrodes.

Author

Marritt SJ, Kemp GL, Xiaoe L, Durrant JR, Cheesman MR, and Butt JN

Subjects

Catalysis, Electrochemistry, Electrodes, Oxidation-Reduction, Solutions, Spectrum Analysis, Cytochrome c Group chemistry, Nanoparticles chemistry, Thermodynamics, Tin Compounds chemistry

Abstract

The pentaheme containing cytochrome, NrfA, from Escherichia coli catalyzes the six-electron reduction of nitrite and the five-electron reduction of nitric oxide. Crystallographic and spectroscopic studies have provided a structural framework for these mechanisms. The active site includes a high-spin heme, and four low-spin, bis-his coordinated hemes are positioned to facilitate intra- and intermolecular electron exchange. However, despite the use of protein film voltammetry to provide kinetic descriptions of NrfA catalysis at graphite and gold electrodes, the thermodynamic descriptions of heme redox activity remain incomplete. Here we rectify this situation with the observation of nonturnover signals from NrfA adsorbed on mesoporous SnO2 electrodes. Simultaneous cyclic voltammetry and electronic absorption spectroscopy define reduction potentials for the high- and low-spin hemes. These reduction potentials are shown to be similar to those exhibited by the enzyme in solution and defined by electrodic reduction monitored by magnetic circular dichroism. Thus, NrfA is shown to undergo minimal perturbation of its electronic and thermodynamic properties on adsorption giving confidence to correlations of properties deduced from various methods and in approaches that may well facilitate studies of other oxidoreductases where catalytic protein film voltammetry is well-defined but nonturnover signals elusive.

Published

2008