Deciphering Electron Transfer Pathways in Bacteria. Enzyme catalysed oxidation reactions are key players in the production of naturally occurring biologically active molecules. These processes are tightly regulated by their electron transfer partners. This project aims to characterise new electron transfer ferredoxin proteins from a metabolically diverse bacterium. These ferredoxins, important in many bacteria, contain different non-cysteine amino acids in their iron-sulfur cluster binding motif ....Deciphering Electron Transfer Pathways in Bacteria. Enzyme catalysed oxidation reactions are key players in the production of naturally occurring biologically active molecules. These processes are tightly regulated by their electron transfer partners. This project aims to characterise new electron transfer ferredoxin proteins from a metabolically diverse bacterium. These ferredoxins, important in many bacteria, contain different non-cysteine amino acids in their iron-sulfur cluster binding motifs and are poorly defined. The outcomes will advance understandings of electron transfer, a fundamental process. This will allow strategies to combat human and plant pathogens and unlock the potential of these systems as biocatalysts for the green chemical synthesis of complex and valuable chemicals.Read moreRead less
Understanding the mechanism of two important cytochrome P450 catalysed reactions: dehydrogenation and C-C cleavage. Cytochromes P450 are enzymes that play key roles in drug metabolism and biosynthesis. P450s often catalyse hydroxylation but also carry out important transformations such as dehydrogenation or carbon-carbon bond cleavage. Such reactions are pivotal in many biological pathways. This work will elucidate the mechanism of these transformations and the factors that facilitate their occu ....Understanding the mechanism of two important cytochrome P450 catalysed reactions: dehydrogenation and C-C cleavage. Cytochromes P450 are enzymes that play key roles in drug metabolism and biosynthesis. P450s often catalyse hydroxylation but also carry out important transformations such as dehydrogenation or carbon-carbon bond cleavage. Such reactions are pivotal in many biological pathways. This work will elucidate the mechanism of these transformations and the factors that facilitate their occurrence. This will mainly entail the synthesis of small organic mechanistic probes and determining the structure and stereochemistry of the product of enzymic oxidation. Understanding these mechanisms will allow us to predict when such reactions will occur, enabling their utilisation in for example drug design in the avoidance of the formation of toxic metabolites.Read moreRead less