Bacteria oxidation

Oxidizing bacteria Any substance such as oxygen (Oj) and chlorine (Clj),... [Pg.621]

Iron-Oxidizing Bacteria. These are aerobic organisms capable of growing in systems with less than 0.5 ppm oxygen. They oxidize iron from ferrous to the ferric state by the following mechanism ... [Pg.1299]

The carbon dioxide produced can contribute to the corrosion of metal. The deposits of ferric hydroxide that precipitate on the metal surface may produce oxygen concentration cells, causing corrosion under the deposits. Gallionalla and Crenothrix are two examples of iron-oxidizing bacteria. [Pg.1300]

Sulfur-Oxidizing Bacteria. These are aerobic bacteria that oxidize sulfur or sulfur-bearing compounds to sulfuric acid according to the following equation ... [Pg.1300]

Nitrous oxide Bacteria and fungi About 100 years... [Pg.52]

Kersters, K., Auling, G., De-Ley, J., 1989. Hydrogenophaga, a new genus of hydrogen-oxidizing bacteria that includes H. flava comb. nov. (formerly Pseudomonas flava), H. palleronii (formerly Pseudomonas palleronii), H. pseudoflava (formerly Pseudomonas pseudoflava and P. carboxydoflava), H. taeniospiralis (formerly P. taeniospiralis). Sys. Bacteriol. 39, 319-333. [Pg.60]

Rieske proteins are constituents of the be complexes that are hydro-quinone-oxidizing multisubunit membrane proteins. All be complexes, that is, bci complexes in mitochondria and bacteria, b f complexes in chloroplasts, and corresponding complexes in menaquinone-oxidizing bacteria, contain three subunits cytochrome b (cytochrome 6e in b f complexes), cytochrome Ci (cytochrome f in b(,f complexes), and the Rieske iron sulfur protein. Cytochrome 6 is a membrane protein, whereas the Rieske protein, cytochrome Ci, and cytochrome f consist of water-soluble catalytic domains that are bound to cytochrome b through a membrane anchor. In Rieske proteins, the membrane anchor can be identified as an N-terminal hydrophobic sequence (13). [Pg.86]

This key enzyme of the dissimilatory sulfate reduction was isolated from all Desulfovibrio strains studied until now 135), and from some sulfur oxidizing bacteria and thermophilic Archaea 136, 137). The enzymes isolated from sulfate-reducing bacteria contain two [4Fe-4S] clusters and a flavin group (FAD) as demonstrated by visible, EPR, and Mossbauer spectroscopies. With a total molecular mass ranging from 150 to 220 kDa, APS reductases have a subunit composition of the type 012)32 or 02)3. The subunit molecular mass is approximately 70 and 20 kDa for the a and )3 subunits, respectively. Amino-acid sequence data suggest that both iron-sulfur clusters are located in the (3 subunit... [Pg.382]

Manganese and iron oxidation are coupled to cell growth and metabolism of organic carbon. Microbially deposited manganese oxide on stainless and mild steel alters electrochemical properties related to the potential for corrosion. Iron-oxidizing bacteria produce tubercles of iron oxides and hydroxides, creating oxygen-concentration cells that initiate a series of events that individually or collectively are very corrosive. [Pg.208]

A simplification of the polarization resistance technique is the linear polarization technique in which it is assumed that the relationship between E and i is linear in a narrow range around E . Usually only two points ( , 0 are measured and B is assumed to have a constant value of about 20 mV. This approach is used in field tests and forms the basis of commercial corrosion rate monitors. Rp can also be determined as the dc limit of the electrochemical impedance. Mansfeld et al. used the linear polarization technique to determine Rp for mild steel sensors embedded in concrete exposed to a sewer environment for about 9 months. One sensor was periodically flushed with sewage in an attempt to remove the sulfuric acid produced by sulfur-oxidizing bacteria within a biofilm another sensor was used as a control. A data logging system collected Rp at 10-min intervals simultaneously for the two corrosion sensors and two pH electrodes placed at the concrete surface. Figure 2 shows the cumulative corrosion loss (Z INT) obtained by integration of the MRp time curves as ... [Pg.211]

Ammonia-oxidizing bacteria including Nitrosomonas europaea... [Pg.53]

Bowien B, HG Schlegel (1981) Physiology and biochemistry of hydrogen-oxidizing bacteria. Annu Rev Microbiol 35 405-452. [Pg.79]

Giiven D et al. (2005) Propionate oxidation by and methanol inhibition of anaerobic ammonium-oxidizing bacteria. Appl Environ Microbiol 71 1066-1071. [Pg.82]

Meyer O, HG Schlegel (1983) Biology of aerobic carbon monoxide-oxidizing bacteria. Annu Rev Microbiol 37 277-310. [Pg.85]

Wackett LP, GA Brusseau, SR Householder, RS Hanson (1989) Survey of microbial oxygenases trichloroethylene degradation by propane-oxidizing bacteria. Appl Environ Microbiol 55 2960-2964. [Pg.90]

Steffan RJ, K McClay, S Vainberg, CW Condee, D Zhang (1997) Biodegradation of the gasoline oxygenates methyl ferf-butyl ether, ethyl ferf-butyl ether, and amyl tcrt-butyl ether by propane-oxidizing bacteria. Appl Environ Microbiol 63 4216-4222. [Pg.145]

Tal Y, JEM Watts, HJ Svchreier (2005) Anaerobic ammonia-oxidizing bacteria and related activity in Baltimore inner harbor sediment. Appl Environ Microbiol 71 1816-1821. [Pg.161]

Stams AIM, JB van Dijk, C Dijkema, CM Plugge (1993) Growth of syntrophic propionate-oxidizing bacteria with fumarate in the absence of methanogenic bacteria. Appl Environ Microbiol 59 1114-1119. [Pg.293]

Leahy JG, AM Byrne, RH Olsen (1996) Comparison of factors influencing trichloroethylene degradation by toluene-oxidizing bacteria. Appl Environ Microbiol 62 825-833. [Pg.373]

Streger SH, CW Condee, AP Togna, ME Deflaun (1999) Degradation of halohydrocarbons and brominated compounds by methane- and propane-oxidizing bacteria. Environ Sci Technol 33 4477-4482. [Pg.376]

Erwin DP, IK Erickson, ME Delwiche, FS Colwell, JL Strap, RL Crawford (2005) Diversity of oxygenase genes from methane- and ammonia-oxidizing bacteria in the Eastern Snake River plain aquifer. Appl... [Pg.634]

Probably, iron of biogenic magnetite was originated from hydrothermal solution. It is considered that ferric iron of hydrothermal solution was oxidized by iron oxidizing bacteria to form magnetite. [Pg.222]

G. A. Kowalchuk, J. R. Stephen, W. DeBoer, J. 1. Prosser, T. M. Embley, and J. W. Woldendorp, Analysis of ammonia-oxidizing bacteria of the beta subdivision of the class Proteobacteria in coastal sand dunes by denaturing gradient gel electrophoresis and sequencing of PCR-amplified I6S ribosomal DNA fragments. Appl. Environ. Microbiol. 6.1 1489 (1997). [Pg.408]

Koops, H.P. and Chritian, U., The lithotrophic ammonia-oxidizing bacteria, in Variations in Autotrophic Life, Shively, J.M. and Burton, L.L., Eds., Harcourt Brace Jovanovich Pub., New York, 1991. [Pg.778]

Steffan, R.J., Farhan, H.H., and Condee, C.W., Bioremediation at a New Jersey site using propane-oxidizing bacteria, in MTBE Remediation Handbook, Moyer, E.E. and Kostecki, P.T., Eds, Amherst Scientific Publishers, Amherst, MA, 2003. [Pg.1052]

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