Transacetylation of carbohydrates in organic solvent catalysed by O-acetylpeptidoglycan esterase from Neisseria gonorrhoeae

The potential of the Neisseria gonorrhoeae O-acetylpeptidoglycan esterase (Ape1a) for catalysing transacetylations in organic solvents with a number of carbohydrate acceptors was investigated. The performance of the enzyme was observed to improve as the polarity index of the solvent increased. The best transacetylation conditions were determined to be a 1:6 phosphate buffer/ethyl acetate system, where Ape1a catalysed approximately 28% acetylation of 4-methylumbelliferyl-N-acetylglucosamine using p-nitrophenyl acetate as donor. Further analysis of the acetylated products by reverse phase HPLC and ESI-mass spectrometry confirmed the presence of monoacetylated 4-methylumbelliferyl-N-acetylglucosamine. Under identical reaction conditions, the enzyme also performed transacetylations using ethyl acetate or vinyl acetate as donor. These results demonstrated the feasibility of using the bacterial cell wall enzyme Ape1a to generate hitherto unattainable compounds which may be used as antagonists of peptidoglycan-metabolizing enzymes.     

The molecular path to inorganic materials - Zinc oxide and beyond

In the current article, we present a concept for the synthesis of complex nanoscaled materials. The synthetic strategy involves a stepwise assembly of materials starting from special molecular precursors possessing multiple information. Therefore, the article focuses on a strong pervasion of inorganic materials chemistry, solid-state chemistry and molecular chemistry. The concept introduced is finally highlighted by examples from our current research in the field of zinc oxide materials.     

The propagation and dispersal of misinformation in ecology: Is there a relationship between citation accuracy and journal impact factor?

The biological and physico-chemical structure of near bottom habitats located under densely growing submerged vegetation, and their significance in the functioning of whole aquatic ecosystems, are very little known due to difficulties in sampling. Corer-type samplers, believed to be the best in littoral studies, do not work properly in such places, because their tube opening is easily clogged by plant shoots, acting as a stopper. In order to overcome this problem, an alteration to the shape of the tube ending is proposed. This can be done by its trimming at an accurate angle, or by fitting (permanently or interchangeably) a metal collar made of stainless steel to its end, so that the ending would resemble the shape of a needle. The modification can be applied to virtually all corer samplers. It was found to be efficient while sampling sediment cores for the purposes of both hydrobiological and paleolimnological studies on heavily overgrown macrophyte-dominated water ecosystems.     

Teratological pollen of Circaea canadensis ssp. canadensis (Onagraceae: Circaeeae)

Pollen morphology of Circaea canadensis (L.) Hill ssp. canadensis collected from sites in Oklahoma differs from that described in earlier reports on this taxon. The samples we observed had poorly developed viscin threads, many with slender connecting points. In the equatorial zones between apertures there were randomly dispersed and elevated tectal components. These features may be due to arrested development since they are present in early stages of development in related taxa.     

Boron- and nitrogen-doped carbon nanotubes and graphene

Multi-walled, single-walled and double-walled carbon nanotubes as well as graphene can be doped with boron and nitrogen. B₂H₆ has been generally used as the boron source while NH₃ or pyridine is employed as the nitrogen source. Doping carbon nanotubes and graphene with boron and nitrogen brings about significant changes in the electronic structure and properties. Such doping not only results in desirable properties but also allows manipulation of properties for specific purposes. Doping with boron- and nitrogen-causes marked changes in the Raman spectra of the carbon nanostructures. In this article, we present the synthesis, characterization and properties of boron- and nitrogen-doped carbon nanotubes and graphene.