Addition of an external electron donor to in vitro assays of cysteine dioxygenase precludes the need for exogenous iron.

Cysteine dioxygenase (CDO) utilizes a 3-His facial triad for coordination of its metal center. Recombinant CDO present in cellular lysate exists primarily in the ferrous form and exhibits significant catalytic activity. Removal of CDO from the reducing cellular environment during purification results in the loss of bound iron and oxidation of greater than 99% of the remaining metal centers. The as-isolated recombinant enzyme has comparable activity as the background level of L-cysteine oxidation confirming that CDO is inactive under the aerobic conditions required for catalysis. Including exogenous ferrous iron in assays resulted in non-enzymatic product formation; however, addition of an external reductant in assays of the purified protein resulted in the recovery of CDO activity. EPR spectroscopy of CDO in the presence of a reductant confirms that the recovered activity is consistent with reduction of iron to the ferrous form. The as-isolated enzyme in the presence of L-cysteine was nearly unreactive with the dioxygen analog, but had increased affinity when pre-incubated with an external reductant. These studies shed light on the discrepancies among reported kinetic parameters for CDO and also juxtapose the stability of the 3-His and 2-His/1-carboxylate ferrous enzymes in the presence of dioxygen.

Distribution and properties of the genes encoding the biosynthesis of the bacterial cofactor, pyrroloquinoline quinone.

Pyrroloquinoline quinone (PQQ) is a small, redox active molecule that serves as a cofactor for several bacterial dehydrogenases, introducing pathways for carbon utilization that confer a growth advantage. Early studies had implicated a ribosomally translated peptide as the substrate for PQQ production. This study presents a sequence- and structure-based analysis of the components of the pqq operon. We find the necessary components for PQQ production are present in 126 prokaryotes, most of which are Gram-negative and a number of which are pathogens. A total of five gene products, PqqA, PqqB, PqqC, PqqD, and PqqE, are identified as being obligatory for PQQ production. Three of the gene products in the pqq operon, PqqB, PqqC, and PqqE, are members of large protein superfamilies. By combining evolutionary conservation patterns with information from three-dimensional structures, we are able to differentiate the gene products involved in PQQ biosynthesis from those with divergent functions. The observed persistence of a conserved gene order within analyzed operons strongly suggests a role for protein-protein interactions in the course of cofactor biosynthesis. These studies propose previously unidentified roles for several of the gene products, as well as identifying possible new targets for antibiotic design and application.

Interaction of PqqE and PqqD in the pyrroloquinoline quinone (PQQ) biosynthetic pathway links PqqD to the radical SAM superfamily.

pqqD is one of six genes required for PQQ production in Klebsiella pneumoniae. Herein, we demonstrate that PqqD interacts specifically with the radical SAM enzyme PqqE, causing a perturbation in the electronic environment around the [4Fe-4S](+) clusters. This interaction redirects the role for PqqD in PQQ biosynthesis.