ALBERT

Notizen: The consequences of using anti-microbial agents in a complex ecosystem like the animal intestine can be difficult to predict. We have looked at effects of modulations in growth of competing intestinal bacteria on transfer and establishment of new genetic elements in the intestinal microflora. For this purpose, we used tetracycline, which gradually reduces the growth rate of tetracycline-sensitive bacteria, as the concentration of this drug is increased. The effect of tetracycline on transfer and establishment of the plasmid RP4, which encodes resistance to this drug, in populations of Escherichia coli BJ4 colonizing the intestine was investigated. A tetracycline-sensitive E. coli BJ4 strain was allowed to establish in the gastrointestinal tract of mice, where after an isogenic E. coli BJ4 carrying RP4 was given to the mice per os. Tetracycline in the drinking water given to the animals was kept in concentrations that allowed the sensitive recipient strain to colonize the gut. A given ‘window’ between the highest and the lowest antibiotic doses tested was shown to be optimal for the establishment of transconjugants in the intestine. These observations are important for the evaluation of the effect of a given drug on the intestinal ecosystem. A reduced potential for growth of a given bacterial species, caused by the presence of sub-inhibitory concentrations of a bacteriostatic antibiotic, will facilitate establishment of competing (i.e. closely related) organisms, which have acquired resistance genes and therefore grow well in the presence of the drug.

Notizen: Single-cell localization and activity of Pseudomonas fluorescens F113, colonizing alfalfa roots, were monitored using fusions of the Escherichia coli rrnBP1 ribosomal promoter and gfp genes encoding green fluorescent protein (Gfp) of different stability. The monitoring systems permitted non-destructive in situ detection of F113rifpcb cells on the entire root system grown in both the presence and absence of 3-chlorobiphenyl (PCB-2). The root tip and sites of lateral root emergence were found to be hotspots for fast-growing cells. In addition, a reporter strain of P. fluorescens F113rifpcb for degradation of chlorinated biphenyl was constructed, using another gfp fusion with the meta-pathway Pm promoter from Pseudomonas putida (TOL plasmid). Expression of this promoter, which is strongly induced by the PCB-2 degradation product, 3-chlorobenzoate, was tested in vitro and subsequently monitored in vivo on alfalfa roots using the P. fluorescens F113rifpcb reporter. A small but distinct fraction of the introduced bacteria activated the Pm promoter and thus appeared to sense a PCB-2 degradation product in the alfalfa rhizosphere. The degrading cells, which by design were identical to the sensing cells, were located in distinct microcolonies on the root surface or in intercellular crevices between the root epidermal cells. However, PCB-degrading cells were not observed in the root areas containing fast-growing cells, indicating that PCB degradation was not linked to high cellular activity.

Notizen: An efficient approach for the insertion of fluorescent marker genes with sequence specificity into conjugative plasmids in Escherichia coli is described. For this purpose, homologous recombination of linear double-stranded targeting DNA was mediated by the bacteriophage λ recombination functions using very short regions of homology. Initial manipulation of the IncFII target plasmids R1 and R1drd19 indicated that the linear targeting DNA should be devoid of all extraneous homologies to the target molecule for optimal insertion specificity. Indeed, a simple recombination assay proved that in the presence of additional homologous regions in the targeting DNA, strand exchanges occurred exclusively within the longest regions of homology. A versatile panel of vectors was created to facilitate convenient PCR amplification of targeting DNAs containing various combinations of different antibiotic resistance genes and fluorescent markers. The choice of 5′ non-homologous extensions in primer pairs used for amplifying the marker cassettes determines the site specificity of the targeting DNA. This methodology is applicable to the modification of all plasmids that replicate in E. coli and is not restricted by plasmid size.

Notizen: Recombinant derivatives of Pseudomonas putida strain KT2440 are of potential interest as microbial inoculants to be deliberately released for agricultural applications. To facilitate tracking of this strain and its derivatives after introduction into the environment, a mini-Tn5-′luxAB transposon was introduced into the chromosome of P. putida KT2440, yielding strain P. putida S1B1. Sequencing of the DNA region located upstream of the ′luxAB genes and similarity search with the P. putida KT2440 genome sequence, localized the transposon within a 3021-bp open reading frame (ORF), whose translated sequence showed significant similarity with the hypothetical YdiJ proteins from Escherichia coli and Haemophilus influenzae. A second ORF adjacent to and divergent from the ydiJ sequence was also found and showed significant homology with various LysR-type transcriptional activator proteins from several bacteria. Disruption of the ydiJ locus in P. putida S1B1 did not affect the survival of the strain in unvegetated or vegetated soils. Bioluminescent detection of P. putida S1B1 cells enriched in selective media directly from soil allowed detection of culturable cells in soil samples over a period of at least 8 months. The addition of the luxAB biomarker facilitates tracking in the root system of several plant species grown under sterile and non-sterile conditions. The correlation of the bioluminescent phenotype with the growth activity of P. putida S1B1 cells colonizing the root system of barley and corn plants was estimated by monitoring ribosomal contents using quantitative hybridization with fluorescence-labeled ribosomal RNA probes. A correlation between inoculum density, light output, and ribosomal contents was found for P. putida cells colonizing the root system of barley seedlings grown under sterile conditions. Although ribosomal contents, and therefore growth activity, of P. putida S1B1 cells extracted from the rhizosphere of corn plants grown in non-sterile soil were similar to those found in starved cells, the luminescent system permitted non-destructive in situ detection of the strain in the upper root system.