Ultrastructural and electron energy-loss spectroscopic analysis of an extracellular filamentous matrix of an environmental bacterial isolate.
Average rating
Cast your vote
You can rate an item by clicking the amount of stars they wish to award to this item.
When enough users have cast their vote on this item, the average rating will also be shown.
Star rating
Your vote was cast
Thank you for your feedback
Thank you for your feedback
Issue Date
2007-09
Metadata
Show full item recordAbstract
Strain F8, a bacterial isolate from 'river snow', was found to produce extracellular fibres in the form of a filamentous network. These extracellular filaments, which were previously shown to be composed of DNA, have been studied for the first time by ultrastructural and electron energy-loss spectroscopy in the present work. 'Whole mount' preparations of strain F8 indicate these polymers are ultrastructurally homogeneous and form a network of elemental filaments, which have a width of 1.8-2.0 nm. When incubated at pH 3.5 with colloidal cationic ThO(2) tracers they become intensely stained (electron dense), affording direct evidence that the fibres are negatively charged and thus acidic chemically. Elemental analysis of the extracellular filaments by Energy-filtered Transmission Electron Microscopy revealed phosphorus to be the main element present and, because pretreatment of F8 cells with DNase prevented thorium labelling, the fibres must be composed of extracellular DNA (eDNA). Neither ultrathin sections nor 'whole mount negative stain' caused DNA release by general cell lysis. Additionally, cells infected with phages were never observed in ultrathin sections and phage particles were never detected in whole mount samples, which rules out the possibility of phages being directly involved in eDNA release.Citation
Ultrastructural and electron energy-loss spectroscopic analysis of an extracellular filamentous matrix of an environmental bacterial isolate. 2007, 9 (9):2137-44 Environ. Microbiol.Affiliation
Department of Environmental Microbiology, Technical University Berlin, Franklin Str. 29, 10587 Berlin, Germany. uta.boeckelmann@tu-berlin.deJournal
Environmental microbiologyPubMed ID
17686013Type
ArticleLanguage
enISSN
1462-2912ae974a485f413a2113503eed53cd6c53
10.1111/j.1462-2920.2007.01325.x
Scopus Count
The following license files are associated with this item: