Michael Stiens scite author profile

Plasmid-encoded quinolone resistance was previously reported for different bacteria isolated from patients not only in the United States and Asia but also in Europe. Here we describe the isolation, by applying a new selection strategy, of the quinolone resistance plasmid pGNB2 from an activated sludge bacterial community of a wastewater treatment plant in Germany. The hypersensitive Escherichia coli strain KAM3 carrying a mutation in the multidrug efflux system genes acrAB was transformed with total plasmid DNA preparations isolated from activated sludge bacteria and subsequently selected on medium containing the fluoroquinolone norfloxacin. This approach resulted in the isolation of plasmid pGNB2 conferring decreased susceptibility to nalidixic acid and to different fluoroquinolones. Analysis of the pGNB2 nucleotide sequence revealed that it is 8,469 bp in size and has a G؉C content of 58.2%. The plasmid backbone is composed of a replication initiation module (repA-repC) belonging to the IncQ-family and a two-component mobilization module that confers horizontal mobility to the plasmid. In addition, plasmid pGNB2 carries an accessory module consisting of a transposon Tn1721 remnant and the quinolone resistance gene, qnrS2, that is 92% identical to the qnrS gene located on plasmid pAH0376 from Shigella flexneri 2b. QnrS2 belongs to the pentapeptide repeat protein family and is predicted to protect DNA-gyrase activity against quinolones. This is not only the first report on a completely sequenced plasmid mediating quinolone resistance isolated from an environmental sample but also on the first qnrS-like gene detected in Europe.Quinolones and especially fluoroquinolones are among the most often prescribed antimicrobial drugs worldwide (1). As a consequence, high resistance rates have developed due to the persisting selection pressure. Resistances are mainly attributed to chromosomal mutations in the genes gyrA and parC, which encode, respectively, subunit A of DNA-gyrase (GyrA) and topoisomerase IV (ParC), representing the target enzymes for quinolones (25). Nevertheless, plasmid-encoded quinolone resistance is of great concern since these resistance determinants potentially can be disseminated among bacteria due to plasmid mobility. The isolation of the multiresistance plasmid pMG252 from a clinical strain of Klebsiella pneumoniae in Birmingham, Alabama, in 1994 was the first documented discovery of a plasmid-encoded resistance to quinolones (19). The quinolone resistance gene qnrA, located on pMG252, encodes a 218-amino-acid protein of the pentapeptide repeat family. Members of this protein family are characterized by the repetition of the consensus sequence (C/A)-(D/N)-(L/F)-X-X (3). It was shown that Qnr protects DNA-gyrase and topoisomerase IV activity against inhibition by quinolones (38-40). Recently, other qnr genes, namely, qnrS and qnrB, were identified on plasmids originating from clinical isolates (12, 16).Several multiresistance plasmids were previously isolated from the activated sludge bacterial com...

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Sequence Analysis of the 144-Kilobase Accessory Plasmid pSmeSM11a, Isolated from a DominantSinorhizobium melilotiStrain Identified during a Long-Term Field Release Experiment

Stiens

Schneiker

Keller

et al. 2006

Appl Environ Microbiol

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The genome of Sinorhizobium meliloti type strain Rm1021 consists of three replicons: the chromosome and two megaplasmids, pSymA and pSymB. Additionally, many indigenous S. meliloti strains possess one or more smaller plasmids, which represent the accessory genome of this species. Here we describe the complete nucleotide sequence of an accessory plasmid, designated pSmeSM11a, that was isolated from a dominant indigenous S. meliloti subpopulation in the context of a long-term field release experiment with genetically modified S. meliloti strains. Sequence analysis of plasmid pSmeSM11a revealed that it is 144,170 bp long and has a mean G؉C content of 59.5 mol%. Annotation of the sequence resulted in a total of 160 coding sequences. Functional predictions could be made for 43% of the genes, whereas 57% of the genes encode hypothetical or unknown gene products. Two plasmid replication modules, one belonging to the repABC replicon family and the other belonging to the plasmid type A replicator region family, were identified. Plasmid pSmeSM11a contains a mobilization (mob) module composed of the type IV secretion system-related genes traG and traA and a putative mobC gene. A large continuous region that is about 42 kb long is very similar to a corresponding region located on S. meliloti Rm1021 megaplasmid pSymA. Single-base-pair deletions in the homologous regions are responsible for frameshifts that result in nonparalogous coding sequences. Plasmid pSmeSM11a carries additional copies of the nodulation genes nodP and nodQ that are responsible for Nod factor sulfation. Furthermore, a tauD gene encoding a putative taurine dioxygenase was identified on pSmeSM11a. An acdS gene located on pSmeSM11a is the first example of such a gene in S. meliloti. The deduced acdS gene product is able to deaminate 1-aminocyclopropane-1-carboxylate and is proposed to be involved in reducing the phytohormone ethylene, thus influencing nodulation events. The presence of numerous insertion sequences suggests that these elements mediated acquisition of accessory plasmid modules.

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The complete genome sequence of the dominant Sinorhizobium meliloti field isolate SM11 extends the S. meliloti pan-genome

Schneiker-Bekel

Wibberg

Bekel

et al. 2011

Journal of Biotechnology

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Prevalence of pSmeSM11a-like plasmids in indigenous Sinorhizobium meliloti strains isolated in the course of a field release experiment with genetically modified S. meliloti strains

Kühn

Stiens

Pühler

et al. 2008

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Plasmid pSmeSM11a, residing in the indigenous Sinorhizobium meliloti strain SM11 originating from a field in Strassmoos (Bavaria, Germany), was analysed previously at the genomic level. Thirty-seven indigenous S. meliloti strains, originating from two different locations in Germany, were screened for genes identified previously on pSmeSM11a. Seven of these strains harbour accessory plasmids that are very similar to pSmeSM11a. The identified pSmeSM11a-like plasmids are c. 130-150 kb in size and possess nearly identical restriction profiles. Up to 30 genes identified previously on pSmeSM11a could be detected on these plasmids by hybridisation experiments, e.g., the nodulation genes nodP and nodQ, the ethylene level modulation gene acdS and the taurine metabolism gene tauD. A few pSmeSM11a genes were also detected on other plasmids. The reference plasmid pSmeSM11a contains a region that is similar to a segment of S. meliloti strain Rm1021 pSymA. Regions with similarity to pSymA were also detected on the aforementioned seven pSmeSM11a-like plasmids. The specifications of these regions are nearly identical to the one on pSmeSM11a and differ from Rm1021 pSymA as determined by nucleotide sequence analysis. Two further plasmids similar to pSmeSM11a completely lack the pSymA-region. Those strains carrying accessory plasmids that contain the acdS gene encoding 1-aminocyclopropane-1-carboxylate deaminase are able to grow on 1-aminocyclopropane-1-carboxylate as the sole source of nitrogen, demonstrating functionality of the acdS gene product. About 36% of the analysed plasmids, including three pSmeSM11a-like plasmids, could be transferred to another S. meliloti recipient strain, allowing for their dissemination in S. meliloti populations.

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Michael Stiens

Mobilizable IncQ-Related Plasmid Carrying a New Quinolone Resistance Gene, qnrS2 , Isolated from the Bacterial Community of a Wastewater Treatment Plant

Sequence Analysis of the 144-Kilobase Accessory Plasmid pSmeSM11a, Isolated from a DominantSinorhizobium melilotiStrain Identified during a Long-Term Field Release Experiment

The complete genome sequence of the dominant Sinorhizobium meliloti field isolate SM11 extends the S. meliloti pan-genome

Prevalence of pSmeSM11a-like plasmids in indigenous Sinorhizobium meliloti strains isolated in the course of a field release experiment with genetically modified S. meliloti strains

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