Investigating [NiFe]-hydrogenases in gamma-Proteobacteria

Finney, Alexander

January 2019

A multitude of microorganisms possess the ability to metabolise molecular hydrogen (H2). The major enzyme family involved in hydrogen metabolism are Hydrogenases. These enzymes catalyse the reversible conversion of molecular hydrogen to protons and electrons (H2 ↔ 2H+ + 2e-). These enzymes have the potential to be utilised for biotechnological applications such as hydrogen fuel cells, but they also represent promising drug targets for inhibition of bacterial energy metabolism both within the gastrointestinal tract and after infection. Therefore, further understanding and discoveries made in the hydrogenase field warrants progression into applied medical and biotechnological research areas. Hydrogenases are also interesting due to their phylogeny and physiology in a large number of microbial species. These enzymes are categorised by their active site architecture. One well studied, ancient group is termed the [NiFe]-hydrogenases, which all harbour a complex NiFe(CN-)2CO active site in the 'large' catalytic subunit and usually have three iron-sulfur clusters within a 'small' electron transferring partner subunit. [NiFe]-hydrogenases have undergone massive diversification, with four major phylogenetic subgroups arising. The major part of this Thesis concerns work on a Group 4 [NiFe]-hydrogenase that functions in partnership with a formate dehydrogenase as a formate hydrogenlyase (FHL). This FHL complex generates H2 and CO2 from the disproportionation of formate (CHOO- + H+ ↔ H2 + CO2). In this Thesis, genetic and biochemical characterisation of Pectobacterium atrosepticum SCRI1043, a potato pathogen, led to the identification of a novel FHL complex. The [NiFe]-hydrogenase in this organism is similar to that of Escherichia coli Hydrogenase-4, with an extended membrane domain similar to that of respiratory Complex I. Importantly, the P. atrosepticum formate dehydrogenase is selenium-free, while previously characterised FHL complexes have selenocysteine-containing formate dehydrogenases. Using genetic and biochemical approaches it was shown that the [NiFe]-hydrogenase and a formate dehydrogenase were vital for H2 production by P. atrosepticum. Using plant infection assays it was also shown that the gene encoding the formate dehydrogenase was important for full infective ability of P. atrosepticum in potato plants and tubers. The latter part of this Thesis focuses on developing genetic tools to study this novel FHL from P. atrosepticum as well as Hydrogenase-1 and -2 from E. coli.

579

Hydrogen production in Escherichia coli : Genetic engineering of the formate hydrogenlyase complex

Hjersing, Charlotte

January 2011

Biofuels that are renewable and environmentally benign constitute an important area of research, as the supply of fossil fuels decreases and the amount of green house gases in the atmosphere increases. Biohydrogen is not as well explored as other biofuels, but its properties render it a promising complement, as it is clean and can be used directly in fuel cells to generate electricity, the only waste products being water and heat. Hydrogenproducing microorganisms have the potential to be used to recycle industrial waste, such as carbohydrates from food manufacturing. Hence the cost of waste disposal could be reduced whilst biofuel is being produced through microbial processes. Escherichia coli is a well-known microorganism that produces hydrogen under fermentative conditions, through the conversion of formate to hydrogen gas and carbon dioxide, via an enzyme complex called formate hydrogenlyase (FHL). The complex is anchored to the inner cell membrane and consists of seven subunits: a formate dehydrogenase, a [Ni-Fe] hydrogenase, three electron carrier proteins, which together make up a large ‘hydrophilic domain’, and two integral membrane proteins (the ‘membrane domain’). Even though the entire bacterial genome is known, the FHL complex remains little understood and has proven difficult to isolate and characterise. During this project, a genetically modified strain producing only the hydrophilic domain of FHL was constructed, and the resultant sub-complex was purified. It was hoped that, if a stable and homogenous core complex could be isolated, it might be subjected to further analysis, such as elucidating the subunit stoichiometry and solving the structure. Furthermore, FHL is notoriously oxygen labile, which hampers its study and technological development. However, oxygen tolerance is a natural feature found in some other [Ni-Fe] hydrogenases, and recent research shows that this property is likely dependent on the presence of extra cysteine residues near an important metal cluster in the enzyme. These cysteines are not present in FHL and a complex that could be active in both aerobic and anaerobic conditions may be a useful tool in optimising microbial biohydrogen processes. Thus, three strains that each expressed a modified FHL variant carrying single Cysteine-for-Glycine substitutions were constructed. The modified FHL complexes proved to remain active in vivo, and can serve as the basis of genetically engineering oxygen tolerance into this important enzyme.

Escherichia coli

Formate hydrogenlyase

Hydrogenase

Oxygen tolerance

Other bioengineering

Övrig bioteknik