Draft Genome Sequence of Sphingobacterium sp. Strain PM2-P1-29, a Tetracycline-Degrading TetX-Expressing Aerobic Bacterium Isolated from Agricultural Soil.

The genome of Sphingobacterium sp. strain PM2-P1-29 was sequenced. The bacterium contains a physiologically active tet(X) gene, encoding a tetracycline-degrading monooxygenase. To our knowledge, this is the only bacterium naturally harboring tet(X) for which tetracycline degradation has been demonstrated.

GENOME ANNOUNCEMENT

The Sphingobacterium genus belongs to the Bacteroidetes phylum, previously regarded as part of the Cytophaga-Flavobacterium-Bacteroides group. The members of this genus are widely distributed in soil, plants, and animal guts. We sequenced and assembled the genome of Sphingobacterium sp. strain PM2-P1-29, isolated from soil near the pig pen of a small farm (1). The genomic sequences of 6 other members of the Sphingobacterium genus are available; among them, Sphingobacterium spiritivorum ATCC 33300 and ATCC 33861 (2), both clinical isolates, have the closest 16S rRNA gene sequence identity (93.5%) to PM2-P1-29. Strain PM2-P1-29, however, has a greater 16S rRNA gene sequence identity (98.5%) to Sphingobacterium faecium NBCR 15299T, isolated from cattle feces, whose genome is not available.

PM2-P1-29 contains the tet(X) gene encoding monooxygenase-degrading tetracycline, and it transforms tetracycline in vivo (3). The tet(X) gene is widely detected in the environment and commensal Bacteroides spp., where it is nonfunctional (4, 5). In recent years, tet(X) has been reported in a duck pathogen (6) and in diverse clinical isolates (7). The TetX enzyme can transform all known tetracyclines, including tigecycline; thus, the increasing prevalence of tet(X) is of great concern (8, 9). To our knowledge, PM2-P1-29 remains the only bacterium harboring tet(X) with demonstrated TetX activity in its native host. The sequencing of the genome of this bacterium was carried out with the objective of learning more about its genomic organization and the presence of other antibiotic resistance genes.

PM2-P1-29 was grown aerobically at 30°C in Luria-Bertani growth medium (containing 10 g/liter tryptone, 5 g/liter yeast extract, 10 g/liter NaCl). The cells were harvested after overnight growth, and DNA was extracted using the DNeasy blood and tissue kit (Qiagen, Venlo, the Netherlands). Genomic DNA was submitted to the University of Minnesota Genomics Center (UMGC) (Minneapolis, MN) for library preparation and Illumina MiSeq 2 × 250 bp sequencing. DNA from PM2-P1-29 was multiplexed with genomic DNA from 23 other bacterial isolates. The raw reads were trimmed at UMGC to remove library tags and bases of CD-HIT (12) and were removed.

The contigs were annotated by Genoscope (13). The number of contigs in the draft genome is 189, with the largest contig containing about 4.1 Mb of DNA. The total length of the genome is 5.4 Mb. PM2-P1-29 has two copies of the tet(X) gene, both on a putative mobile element, and it contains numerous regions characteristic of mobile genetic elements. While PM2-P1-29 is resistant to several antibiotics and contains multiple predicted resistance genes, the only other known resistance gene is aadS (3).

Nucleotide sequence accession numbers.

The draft whole-genome sequence has been submitted to the European Nucleotide Archive (ENA) under accession numbers LK931673 to LK931861 and is mirrored in GenBank.