Your search keyword '"Simon J. George"' showing total 4 results

1. Temperature-dependent iron motion in extremophile rubredoxins – no need for ‘corresponding states’

Author

Francis E. Jenney, Hongxin Wang, Simon J. George, Jin Xiong, Yisong Guo, Leland B. Gee, Juan José Marizcurrena, Susana Castro-Sowinski, Anna Staskiewicz, Yoshitaka Yoda, Michael Y. Hu, Kenji Tamasaku, Nobumoto Nagasawa, Lei Li, Hiroaki Matsuura, Tzanko Doukov, and Stephen P. Cramer

Subjects

Rubredoxin, Iron-Sulfur, Extremophile, Hyperthermophile, Psychrophile, Corresponding States, Medicine, Science

Abstract

Abstract Extremophile organisms are known that can metabolize at temperatures down to − 25 °C (psychrophiles) and up to 122 °C (hyperthermophiles). Understanding viability under extreme conditions is relevant for human health, biotechnological applications, and our search for life elsewhere in the universe. Information about the stability and dynamics of proteins under environmental extremes is an important factor in this regard. Here we compare the dynamics of small Fe-S proteins – rubredoxins – from psychrophilic and hyperthermophilic microorganisms, using three different nuclear techniques as well as molecular dynamics calculations to quantify motion at the Fe site. The theory of ‘corresponding states’ posits that homologous proteins from different extremophiles have comparable flexibilities at the optimum growth temperatures of their respective organisms. Although ‘corresponding states’ would predict greater flexibility for rubredoxins that operate at low temperatures, we find that from 4 to 300 K, the dynamics of the Fe sites in these homologous proteins are essentially equivalent.

Published

2024

2. Cell-free H-cluster synthesis and [FeFe] hydrogenase activation: all five CO and CN⁻ ligands derive from tyrosine.

Author

Jon M Kuchenreuther, Simon J George, Celestine S Grady-Smith, Stephen P Cramer, and James R Swartz

Subjects

Medicine, Science

Abstract

[FeFe] hydrogenases are promising catalysts for producing hydrogen as a sustainable fuel and chemical feedstock, and they also serve as paradigms for biomimetic hydrogen-evolving compounds. Hydrogen formation is catalyzed by the H-cluster, a unique iron-based cofactor requiring three carbon monoxide (CO) and two cyanide (CN⁻) ligands as well as a dithiolate bridge. Three accessory proteins (HydE, HydF, and HydG) are presumably responsible for assembling and installing the H-cluster, yet their precise roles and the biosynthetic pathway have yet to be fully defined. In this report, we describe effective cell-free methods for investigating H-cluster synthesis and [FeFe] hydrogenase activation. Combining isotopic labeling with FTIR spectroscopy, we conclusively show that each of the CO and CN⁻ ligands derive respectively from the carboxylate and amino substituents of tyrosine. Such in vitro systems with reconstituted pathways comprise a versatile approach for studying biosynthetic mechanisms, and this work marks a significant step towards an understanding of both the protein-protein interactions and complex reactions required for H-cluster assembly and hydrogenase maturation.

Published

2011

3. High-yield expression of heterologous [FeFe] hydrogenases in Escherichia coli.

Author

Jon M Kuchenreuther, Celestine S Grady-Smith, Alyssa S Bingham, Simon J George, Stephen P Cramer, and James R Swartz

Subjects

Medicine, Science

Abstract

BACKGROUND: The realization of hydrogenase-based technologies for renewable H(2) production is presently limited by the need for scalable and high-yielding methods to supply active hydrogenases and their required maturases. PRINCIPAL FINDINGS: In this report, we describe an improved Escherichia coli-based expression system capable of producing 8-30 mg of purified, active [FeFe] hydrogenase per liter of culture, volumetric yields at least 10-fold greater than previously reported. Specifically, we overcame two problems associated with other in vivo production methods: low protein yields and ineffective hydrogenase maturation. The addition of glucose to the growth medium enhances anaerobic metabolism and growth during hydrogenase expression, which substantially increases total yields. Also, we combine iron and cysteine supplementation with the use of an E. coli strain upregulated for iron-sulfur cluster protein accumulation. These measures dramatically improve in vivo hydrogenase activation. Two hydrogenases, HydA1 from Chlamydomonas reinhardtii and HydA (CpI) from Clostridium pasteurianum, were produced with this improved system and subsequently purified. Biophysical characterization and FTIR spectroscopic analysis of these enzymes indicate that they harbor the H-cluster and catalyze H(2) evolution with rates comparable to those of enzymes isolated from their respective native organisms. SIGNIFICANCE: The production system we describe will facilitate basic hydrogenase investigations as well as the development of new technologies that utilize these prolific H(2)-producing enzymes. These methods can also be extended for producing and studying a variety of oxygen-sensitive iron-sulfur proteins as well as other proteins requiring anoxic environments.

Published

2010

4. Reductive activation of nitrate reductases.

Author

Sarah J. Field, Nicholas P. Thornton, Lee J. Anderson, Andrew J. Gates, Ann Reilly, Brian J. N. Jepson, David J. Richardson, Simon J. George, Myles R. Cheesman, and Julea N. Butt

Published

2005