Loretta M. Murphy

Remediation of chromium(VI) by a methane-oxidizing bacterium

Methane-oxidizing bacteria are ubiquitous in the environment and are globally important in oxidizing the potent greenhouse gas methane. It is also well recognized that they have wide potential for bioremediation of organic and chlorinated organic pollutants, thanks to the wide substrate ranges of the methane monooxygenase enzymes that they produce. Here we have demonstrated that the well characterized model methanotroph Methylococcus capsulatus (Bath) is able to bioremediate chromium(VI) pollution over a wide range of concentrations (1.4-1000 mg L(-1) of Cr(6+)), thus extending the bioremediation potential of this major group of microorganisms to include an important heavy-metal pollutant. The chromium(VI) reduction reaction was dependent on the availability of reducing equivalents from the growth substrate methane and was partially inhibited by the metabolic poison sodium azide. X-ray spectroscopy showed that the cell-associated chromium was predominantly in the +3 oxidation state and associated with cell- or medium-derived moieties that were most likely phosphate groups. The genome sequence of Mc. capsulatus (Bath) suggests at least five candidate genes for the chromium(VI) reductase activity in this organism.

A critical assessment of the evidence from XAFS and crystallography for the breakage of the imidazolate bridge during catalysis in CuZn superoxide dismutase

BACKGROUND Copper-zinc superoxide dismutase (CuZn SOD) protects cells from the toxic effects of superoxide radicals. Key steps in the catalytic mechanism of CuZn SOD are thought to be the breakage of the imidazolate bridge between copper and zinc upon reduction of the copper site and the subsequent proton donation from the bridging histidine. This view has been recently challenged by a crystallographic study at 1.9 A resolution where evidence for a five-coordinate copper site in the reduced enzyme was provided. In contrast, a crystallographic study of yeast CuZn SOD at 1.7 A has confirmed the breaking of the bridging histidine in reduced crystals. We have examined the nature of the changes in metal coordination which result upon reduction of the enzyme using the X-ray absorption fine structure (XAFS) technique. RESULTS The copper and zinc K-edge XAFS data of bovine SOD, recorded in the buffer systems used in the two crystallographic studies, were analyzed by constrained refinement using fast curved wave theory, taking full account of multiple-scattering effects. The study confirms that in the oxidized form of the enzyme the copper atom is five coordinate, with four histidine ligands at 1.99 +/- 0.02 A and a water molecule at 2.18 +/- 0.03 A. In the reduced form of the enzyme, one of the histidine ligands and the water molecule are lost from the inner coordination sphere of the copper, with the three remaining histidines ligated at 1.97 +/- 0.02 A. The X-ray absorption near edge structure (XANES) of the reduced enzyme is consistent with an approximate trigonal planar geometry at the copper site. The XAFS at the zinc K-edge is essentially identical in both the oxidized and reduced enzyme and is accounted for by three histidines coordinated at 2.01 +/- 0.02 A and an aspartate ligand at 1.96 +/- 0.03 A. CONCLUSIONS The existence of a three-coordinate cuprous ion in bovine CuZn SOD is demonstrated and is a key feature of catalytic degradation of superoxide substrate by SOD involving alternate Cu(I) and Cu(II) states of the enzyme. Only subtle changes in the zinc K-edge XAFS take place upon reduction. Thus the reaction mechanism which involves breakage of the bridging histidine is unambiguously supported by the XAFS data.

Experimental aspects of biological X-ray absorption spectroscopy.

Spectroscopic techniques, like X-ray absorption spectroscopy, will provide important input for integrated biological projects in genomics and proteomics. This contribution summarizes technical requirements and typical set-ups for both simple and complex biological XAS experiments. An overview on different strategies for sample preparation is discussed in detail. Present and future BioXAS spectrometers are presented to help potential users in locating the spectrometer required for their biological application.

Crystal Structure of the LasA Virulence Factor from Pseudomonas aeruginosa: Substrate Specificity and Mechanism of M23 Metallopeptidases

Pseudomonas aeruginosa is an opportunist Gram-negative bacterial pathogen responsible for a wide range of infections in immunocompromized individuals and is a leading cause of mortality in cystic fibrosis patients. A number of secreted virulence factors, including various proteolytic enzymes, contribute to the establishment and maintenance of Pseudomonas infection. One such is LasA, an M23 metallopeptidase related to autolytic glycylglycine endopeptidases such as Staphylococcus aureus lysostaphin and LytM, and to DD-endopeptidases involved in entry of bacteriophage to host bacteria. LasA is implicated in a range of processes related to Pseudomonas virulence, including stimulating ectodomain shedding of the cell surface heparan sulphate proteoglycan syndecan-1 and elastin degradation in connective tissue. Here we present crystal structures of active LasA as a complex with tartrate and in the uncomplexed form. While the overall fold resembles that of the other M23 family members, the LasA active site is less constricted and utilizes a different set of metal ligands. The active site of uncomplexed LasA contains a five-coordinate zinc ion with trigonal bipyramidal geometry and two metal-bound water molecules. Using these structures as a starting point, we propose a model for substrate binding by LasA that explains its activity against a wider range of substrates than those used by related lytic enzymes, and offer a catalytic mechanism for M23 metallopeptidases consistent with available structural and mutagenesis data. Our results highlight how LasA is a structurally distinct member of this endopeptidase family, consistent with its activity against a wider range of substrates and with its multiple roles in Pseudomonas virulence.

Structural Characterisation of Azurin from Pseudomonas aeruginosa and some of Its Methionine-121 Mutants

Azurin from Pseudomonas aeruginosa and two mutants where the methionine ligand has been mutated have been studied in order to directly investigate the functional and structural significance of this ligand in the blue copper proteins. Redox potentials, x-ray absorption fine structure (XAFS), electron paramagnetic resonance (EPR) and optical spectra are obtained in an attempt to provide a direct correlation between the spectrochemical properties and the immediate structure of this redox centre.

Characterization of cycP Gene Expression in Achromobacter xylosoxidans NCIMB 11015 and High-Level Heterologous Synthesis of Cytochrome c′ in Escherichia coli

The cycP gene encoding a periplasmic cytochrome c′ from the denitrifying β-proteobacterium Achromobacter xylosoxidans was characterized. The genes flanking cycP encode components of a mobile genetic element characteristic of the β-proteobacteria, suggesting that cycP has inserted within a transposon or insertion element. The gene therefore does not form part of a denitrification operon or gene cluster. The level of expression of the cycP gene and the level of synthesis of its corresponding gene product were found to increase by maximally 3-fold anaerobically. Expression of cycP appears to occur mainly by non-specific read-through transcription from portions of the insertion element. Conditions were developed for high-level overproduction of cytochrome c′ in Escherichia coli, which resulted in signal peptide cleavage concomitant with secretion of the protein into the periplasm. Using a single-step purification, 20–30 mg of pure protein were isolated from a 1-litre culture. Based on UV-visible spectrophotometry the dimeric protein was shown to have a full complement of haem and to be indistinguishable from the native protein purified from A. xylosoxidans. This system provides an excellent platform to facilitate biochemical and structural dissection of the mechanism underlying the novel specificity of NO binding to the proximal face of the haem.

Subtle shifts in microbial communities occur alongside the release of carbon induced by drought and rewetting in contrasting peatland ecosystems

Peat represents a globally significant pool of sequestered carbon. However, peatland carbon stocks are highly threatened by anthropogenic climate change, including drought, which leads to a large release of carbon dioxide. Although the enzymatic mechanisms underlying drought-driven carbon release are well documented, the effect of drought on peatland microbial communities has been little studied. Here, we carried out a replicated and controlled drought manipulation using intact peat ‘mesocosm cores’ taken from bog and fen habitats, and used a combination of community fingerprinting and sequencing of marker genes to identify community changes associated with drought. Community composition varied with habitat and depth. Moreover, community differences between mesocosm cores were stronger than the effect of the drought treatment, emphasising the importance of replication in microbial marker gene studies. While the effect of drought on the overall composition of prokaryotic and eukaryotic communities was weak, a subset of the microbial community did change in relative abundance, especially in the fen habitat at 5 cm depth. ‘Drought-responsive’ OTUs were disproportionately drawn from the phyla Bacteroidetes and Proteobacteria. Collectively, the data provide insights into the microbial community changes occurring alongside drought-driven carbon release from peatlands, and suggest a number of novel avenues for future research.

Crystallization and preliminary crystallographic data for the azurin mutant End-121 from Pseudomonas aeruginosa

Pseudomonas aeruginosa azurin has been crystallized from a mutant where residues from Met 121 to Lys128 have been deleted from the protein. The crystals form pale-blue well formed prisms in the orthorhombic space group P2(1)2(1)2(1), with cell dimensions a = 60.79 (5), b = 123.47 (5), c = 187.77 (5) A. The crystals diffract to 3.0 A and there are eight molecules in the asymmetric unit.