Laboratory maintenance and cultivation of bacteroides species.

Bacteroides species are Gram-negative, obligate anaerobic bacteria. They are the predominant indigenous bacterial species in the human intestinal tract, where they play an important role in the normal physiology of the host, but they can also be significant opportunistic pathogens. The fact that these are obligate anaerobes is the prevailing feature that affects the methodology used for their cultivation. Several techniques are described for anaerobic culturing; the anaerobic glove box and anaerobic jars are the two techniques most adaptable to a range of research needs. Straightforward methods are presented for propagation on solid media and in broth cultures, and for the long-term storage and maintenance of stock cultures. The Bacteroides species are saccharolytic, which is the second feature of their physiology that impacts cultivation methodology. Several flexible media formulations, including a defined minimal media, are provided that allow the researcher to choose the carbon source best suited for his or her work.

Analysis of the zinc finger domain of TnpA, a DNA targeting protein encoded by mobilizable transposon Tn4555.

The mobilizable transposon Tn4555, found in Bacteroides spp., is an important antibiotic resistance element encoding a broad spectrum beta-lactamase. Tn4555 is mobilized by conjugative transposons such as CTn341 which can transfer the transposon to a wide range of bacterial species where it integrates into preferred sites on the host chromosome. Selection of the preferred target sites is mediated by a DNA-binding protein TnpA which has a prominent zinc finger motif at the N-terminus of the protein. In this report the zinc finger motif was disrupted by site directed mutagenesis in which two cysteine residues were changed to serine residues. Elemental analysis indicated that the wild-type protein but not the mutated protein was able to coordinate zinc at a molar ration of 1/1. DNA binding electrophoretic mobility shift assays showed that the ability to bind the target site DNA was not significantly affected by the mutation but there was about a 50% decrease in the ability to bind single stranded DNA. Consistent with these results, electrophoretic mobility shift assays incorporating zinc chelators did not have a significant on affect the binding of DNA target. In vivo, the zinc finger mutation completely prevented transposition/integration as measured in a conjugation assay. This was in contrast to results in which a TnpA knockout was still able to insert into host genomes but there was no preferred target site selection. The phenotype of the zinc finger mutation was not effectively rescued by providing wild-type TnpA in trans. Taken together these results indicated that the zinc finger is not required for DNA binding activity of TnpA but that it does have an important role in transposition and it may mediate protein/protein interactions with integrase or other Tn4555 proteins to facilitate insertion into the preferred sites.

Analysis of chromosomal insertion sites for Bacteroides Tn4555 and the role of TnpA.

Tn4555, a mobilizable transposon carrying cefoxitin resistance, is directed to a preferred target site in the Bacteroides fragilis chromosome by a transposon-encoded targeting protein TnpA. In an effort to characterize target site selection for Tn4555, the existence of preferred target sites in other species of Bacteroides and in Escherichia coli was examined. For these analyses a Tn4555 mini element, pFD660, was transferred from E. coli donors to Bacteroides thetaiotaomicron or Bacteroides ovatus recipients and the resulting sites of insertion analyzed. A similar construct, pFD794 was used to determine insertion sites in E. coli, and preferred sites were found in all bacteria tested. Also the ability of TnpA to bind to various targets was examined in mobility shift assays. Although TnpA bound to all tested sequences, it displayed higher affinity for the target sites. The binding characteristics of TnpA and the lack of significant base sequence homology between targets suggested that secondary structure of the sites was important for TnpA binding. Circular permutation tests supported the idea that TnpA targets bent DNA.