AuCl(4)(-) has been extracted into the membrane via ion-exchange

AuCl(4)(-) has been extracted into the membrane via ion-exchange and has been subsequently reduced by L-ascorbic acid, tri-sodium citrate, NaBH(4) or EDTA to form Au NPs.

EDTA at pH 6.0 has been shown to be an effective reducing agent capable of forming a uniform monolayer of Au NPs of average size 20 nm on the surface of the membrane. The other reagents have formed Au NPs of sizes depending on the reagent type and these have been embedded in the bulk of the membrane and not concentrated at the surface.\n\nThe main factors influencing the formation of the surface Au NPs when EDTA is used as the reducing agent have been studied. A 24 h membrane exposure to the EDTA solution has ensured complete surface coverage with Au NPs. Vactosertib solubility dmso It has been observed that as the concentration of EDTA, the solution temperature and shaking rate increase, the size of Au NPs decreases. BEZ235 manufacturer Therefore, these factors

can be used to control the size of Au NPs on the membrane surface.\n\nThe coated with Au NPs membranes are expected to be of interest in optical sensing and catalytic applications. (C) 2011 Elsevier B.V. All rights reserved.”
“Lateral gene transfer (LGT)uwhich transfers DNA between two non-vertically related individuals belonging to the same or different speciesuis recognized as a major force in prokaryotic evolution, and evidence of its impact on eukaryotic evolution is ever increasing. LGT has attracted much public attention for its potential to transfer pathogenic elements and antibiotic resistance in bacteria, and to transfer pesticide resistance from genetically modified crops to other plants. In a wider perspective, there is a growing body of studies highlighting the role of LGT in enabling organisms to occupy new niches or adapt VX-809 datasheet to environmental changes. The challenge LGT poses to the standard tree-based conception of evolution is also being debated. Studies of LGT have, however, been severely limited

by a lack of computational tools. The best currently available LGT algorithms are parsimony-based phylogenetic methods, which require a pre-computed gene tree and cannot choose between sometimes wildly differing most parsimonious solutions. Moreover, in many studies, simple heuristics are applied that can only handle putative orthologs and completely disregard gene duplications (GDs). Consequently, proposed LGT among specific gene families, and the rate of LGT in general, remain debated. We present a Bayesian Markov-chain Monte Carlo-based method that integrates GD, gene loss, LGT, and sequence evolution, and apply the method in a genome-wide analysis of two groups of bacteria: Mollicutes and 3 Cyanobacteria. Our analyses show that although the LGT rate between distant species is high, the net combined rate of duplication and close-species LGT is on average higher.

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