Stephan Bathe scite author profile

Biological sulfide oxidation is a reaction occurring in all three domains of life. One enzyme responsible for this reaction in many bacteria has been identified as sulfide:quinone oxidoreductase (SQR). The enzyme from Rhodobacter capsulatus is a peripherally membrane-bound flavoprotein with a molecular mass of approximately 48 kDa, presumably acting as a homodimer. In this work, SQR from Rb. capsulatus has been modified with an N-terminal His tag and heterologously expressed in and purified from Escherichia coli. Three cysteine residues have been shown to be essential for the reductive half-reaction by site-directed mutagenesis. The catalytic activity has been nearly completely abolished after mutation of each of the cysteines to serine. A decrease in fluorescence on reduction by sulfide as observed for the wild-type enzyme has not been observed for any of the mutated enzymes. Mutation of a conserved valine residue to aspartate within the third flavin-binding domain led to a drastically reduced substrate affinity, for both sulfide and quinone. Two conserved histidine residues have been mutated individually to alanine. Both of the resulting enzymes exhibited a shift in the pH dependence of the SQR reaction. Polysulfide has been identified as a primary reaction product using spectroscopic and chromatographic methods. On the basis of these data, reaction mechanisms for sulfide-dependent reduction and quinone-dependent oxidation of the enzyme and for the formation of polysulfide are proposed.

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PCR-SSCP comparison of 16S rDNA sequence diversity in soil DNA obtained using different isolation and purification methods

Stach

et al. 2001

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This study compared different methods of direct DNA extraction and purification from a silt loam soil and investigated the relationship between DNA quantity and sequence diversity. Five extraction methods and four purification techniques were investigated. Quantities of DNA extracted were between 3.4+/-0.55 and 54.3+/-8.18 &mgr;g g(-1) (dry wt) of soil with OD(260)/OD(230) purity ratios between 0.80 and 1.15. Analysis of sequence diversity in all extracts was conducted using PCR-single strand conformation polymorphism (SSCP). Profiles generated using universal 16S rDNA primers (Com1/Com2) were found to be identical when used to amplify 16S rDNA extracted directly from soil. The genus Pseudomonas was targeted in order to reduce profile complexity, which was apparent when using universal 16S rDNA primers, and which hindered direct comparison of sequence diversity. A Pseudomonas culture library and non-cultured Pseudomonas 16S rDNA genes were used to provide a background count of Pseudomonas operational taxonomic units present in the soil. Cloning and sequencing of amplicons generated using a Pseudomonas-specific (Ps-for) and a universal 16S rDNA (Com2) primer, coupled with nested amplification (Com1/Com2 amplification from Ps-for/Ps-rev amplicons), used in conjunction with SSCP, revealed that environmental contaminants co-extracted with DNA, such as humic acid, significantly reduced primer specificity. SSCP was sensitive enough to reveal template bias in different primer sets. PCR-restriction fragment length-SSCP of Pseudomonas 16S rDNA amplified from soil-extracted DNA revealed distinct differences in sequence representation between extraction methods and showed that greater DNA yield is not synonymous with higher sequence diversity. We, therefore, suggest that DNA extractions from soil should be evaluated not only in terms of quantity and purity, but also in terms of the sequence diversity present. SSCP proved to be a valuable tool for the assessment of the methodologies commonly used in PCR-mediated microbial ecology studies.

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Ferrous Iron- and Sulfur-Induced Genes in Sulfolobus metallicus

Bathe

Norris

2007

Appl Environ Microbiol

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Genes of Sulfolobus metallicus that appeared to be upregulated in relation to growth on either ferrous iron or sulfur were identified using subtractive hybridization of cDNAs. The genes upregulated during growth on ferrous iron were found in a cluster, and most were predicted to encode membrane proteins. Quantitative reverse transcription-PCR of cDNA showed upregulation of most of these genes during growth on ferrous iron and pyrite compared to results during growth on sulfur. The highest expression levels observed included those for genes encoding proteins with similarities to cytochrome c oxidase subunits and a CbsA-like cytochrome. The genes identified here that may be involved in oxidation of ferrous iron by S. metallicus are termed fox genes. Of three available genomes of Sulfolobus species (S. tokodaii, S. acidocaldarius, and S. solfataricus), only that of S. tokodaii has a cluster of highly similar open reading frames, and only S. tokodaii of these three species was also able to oxidize ferrous iron. A gene encoding sulfur oxygenase-reductase was identified as the source of the dominant transcript in sulfur-grown cells of S. metallicus, with the predicted protein showing high identities to the previously described examples from S. tokodaii and species of Acidianus.

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Stephan Bathe

Mechanism of Sulfide-Quinone Reductase Investigated Using Site-Directed Mutagenesis and Sulfur Analysis^,

PCR-SSCP comparison of 16S rDNA sequence diversity in soil DNA obtained using different isolation and purification methods

Ferrous Iron- and Sulfur-Induced Genes in Sulfolobus metallicus

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Stephan Bathe

Mechanism of Sulfide-Quinone Reductase Investigated Using Site-Directed Mutagenesis and Sulfur Analysis,

PCR-SSCP comparison of 16S rDNA sequence diversity in soil DNA obtained using different isolation and purification methods

Ferrous Iron- and Sulfur-Induced Genes in Sulfolobus metallicus

Contact Info

Product

Resources

About

Mechanism of Sulfide-Quinone Reductase Investigated Using Site-Directed Mutagenesis and Sulfur Analysis^,