Jorge Lalucat

Reclassification of Shewanella putrefaciens Owen's genomic group II as Shewanella baltica sp. nov.

The taxonomic relationship between several Shewanella putrefaciens isolates from the Baltic Sea and reference strains of this species is presented in this study. Results from DNA-DNA hybridization using a newly developed non-radioactive detection system and from 16S rRNA gene sequencing demonstrated that S. putrefaciens is a heterogeneous species containing more than a single genomic group. The genomic group II was phylogenetically, genotypically and phenotypically distant enough from the species type strain to be classified as a single species within the genus Shewanella. Therefore, we propose to reclassify Owens genomic group II as Shewanella baltica sp. nov. with the type strain NCTC 10735.

Taxonomic Note: A Pragmatic Approach to the Nomenclature of Phenotypically Similar Genomic Groups

Occasionally, genomic groups (DNA groups, genomic species) that have been delimited by DNA-DNA pairing may be phenotypically so similar that they cannot be differentiated for the time being. In these situations it seems best to allow a nomenspecies to contain more than one genomic group and to refer to genomic groups of a nomenspecies as genomovars.

Genotypic and Phenotypic Diversity of Pseudomonas stutzeri

Summary A total of 49 strains of Pseudomonas stutzeri including reference strains from culture collections were phenotypically and genotypically studied. They were isolated from clinical sources, marine sediments, waste-water treatment plants and soil. DNA-DNA hybridization using the thermal melting point of the hybrids as parameter established seven genomic groups, four of them containing less than three strains. The G+C content ranged from 60.9–64,9 mol%. Phenotypical investigation using 102 characters demonstrated a considerable heterogeneity within the genomic groups. Because of the lack of useful differential tests there is still no sound basis for division of P. stutzeri at the species level. It is proposed that the term ‘genomovar’ be used to denote genomic groups of a nomenspecies.

16S rRNA gene sequence analysis relative to genomovars of Pseudomonas stutzeri and proposal of Pseudomonas balearica sp. nov.

We compared the 16S rRNA gene sequences of 14 strains of Pseudomonas stutzeri, including type strain CCUG 11256 and strain ZoBell (= ATCC 14405), which represented the seven P. stutzeri genomovars (DNA-DNA similarity groups) that have been described. Our sequence analysis revealed clusters which were highly correlated with genomovar clusters derived from DNA-DNA hybridization data. In addition, we identified signature nucleotide positions for each genomovar. We found that the 16S rRNA gene sequences of genomovar 6 strains SP1402T (T = type strain) and LS401 were different enough from the sequence of the type strain of P. stutzeri that these organisms should be placed in a new species, Pseudomonas balearica. The type strain of P. balearica is strain SP1402 (= DSM 6083).

Phylogenomics and systematics in Pseudomonas

The genus Pseudomonas currently contains 144 species, making it the genus of Gram-negative bacteria that contains the largest number of species. Currently, multilocus sequence analysis (MLSA) is the preferred method for establishing the phylogeny between species and genera. Four partial gene sequences of housekeeping genes (16S rRNA, gyrB, rpoB, and rpoD) were obtained from 112 complete or draft genomes of strains related to the genus Pseudomonas that were available in databases. These genes were analyzed together with the corresponding sequences of 133 Pseudomonas type strains of validly published species to assess their correct phylogenetic assignations. We confirmed that 30% of the sequenced genomes of non-type strains were not correctly assigned at the species level in the accepted taxonomy of the genus and that 20% of the strains were not identified at the species level. Most of these strains had been isolated and classified several years ago, and their taxonomic status has not been updated by modern techniques. MLSA was also compared with indices based on the analysis of whole-genome sequences that have been proposed for species delineation, such as tetranucleotide usage patterns (TETRA), average nucleotide identity (ANIm, based on MUMmer and ANIb, based on BLAST) and genome-to-genome distance (GGDC). TETRA was useful for discriminating Pseudomonas from other genera, whereas ANIb and GGDC clearly separated strains of different species. ANIb showed the strongest correlation with MLSA. The correct species classification is a prerequisite for most diversity and evolutionary studies. This work highlights the necessity for complete genomic sequences of type strains to build a phylogenomic taxonomy and that all new genome sequences submitted to databases should be correctly assigned to species to avoid taxonomic inconsistencies.

An rpoD-based PCR procedure for the identification of Pseudomonas species and for their detection in environmental samples.

A polymerase chain reaction-based approach was developed for species identification of Pseudomonas strains and for the direct detection of Pseudomonas populations in their natural environment. A highly selective set of primers (PsEG30F and PsEG790R), giving an amplicon of 760 nucleotides in length, was designed based on the internal conserved sequences of 33 selected rpoD gene sequences (the sigma 70 factor subunit of the DNA polymerase) of Pseudomonas type strains, representing the entire intrageneric phylogenetic clusters described in the genus. The utility of the primer set was verified on 96 Pseudomonas type strains and on another 112 recognised Pseudomonas strains. The specificity of the primer set was also tested against strains from species not belonging to the genus Pseudomonas. These primers were also shown to be useful for the direct detection of Pseudomonas species in environmental DNA after a cloning procedure. These results were compared in parallel with other cloning procedures described previously, based on the analysis of other genes (16S rDNA and ITS1) and also by using primers designed for rpoD on sequences from gamma-proteobacteria. All of the cultured Pseudomonas strains tested could be amplified with these novel primers, indicating that this method is also a useful tool for the specific analysis of Pseudomonas populations from environmental samples without the need for cultivation.

Utility of internally transcribed 16S-23S rDNA spacer regions for the definition of Pseudomonas stutzeri genomovars and other Pseudomonas species.

Bacteria identified and classified as Pseudomonas stutzeri, on the basis of traditional criteria, are recognized to be markedly heterogeneous, such that a systematic phenotypic characterization has not been correlated with genotypic groupings (i.e. genomovars) based upon DNA-DNA similarities. The internally transcribed 16S-23S rDNA spacer (ITS1) regions of P. stutzeri were analysed with respect to the ability of these nucleic acid regions to differentiate and identify the genomic groups (i.e. genomovars) of P. stutzeri. The ITS1s of 34 strains of P. stutzeri were amplified by PCR and the PCR product was subjected to RFLP analysis, which allowed the differentiation and identification of the strains to their respective genomovars. Sequence determination and analysis of ITS1s supported further the results obtained by RFLP, i.e. nucleotide signatures were identified in strains belonging to different genomovars. The ITS1s of all strains of P. stutzeri contained the tandem tRNA(Ile)/tRNA(Ala) genes and did not exhibit distinct sequence heterogeneity between different operons of a strain. Phylogenetically informative variable sites were located, exclusively, in non-coding regions. The results of the RFLP and sequence analysis of ITS1s supported and correlated with the phylogenetic relationships estimated from 16S rRNA gene sequence comparisons and DNA-DNA hybridizations, offering an alternative tool for genomovar and species differentiation.

Genome Organization of Pseudomonas stutzeri and Resulting Taxonomic and Evolutionary Considerations

In order to determine the genome variability within Pseudomonas stutzeri, 20 strains representing the seven described genomovars and strain JM300 were analyzed by using various resolution levels of rare cutting enzymes. XbaI and SpeI fingerprints revealed a high degree of heterogeneity of restriction patterns that did not correlate with the division into genomovars. However, a fragment pattern comparison led to the establishment of several groups of clonal variants within genomovars. One circular chromosome ranging in size from 3.75 to 4.64 Mb constitutes the genome of P. stutzeri strains. The I-CeuI, PacI, and SwaI low-resolution map of P. stutzeri type strain CCUG 11256 shows the locations of 12 genes, including rrn operons and the origin of replication. I-CeuI digests of the 20 strains studied plus the positions of six genes allowed a comparison of the rrn backbone organization within genomovars; the four rrn operons seemed to be at similar locations with respect to the origin of replication, as did the rest of the genes. However, a comparison of I-CeuI cleavage maps of the genomovar reference strains revealed a diverse genome organization in the genomovars relative to rrn operons and gene locations. In most genomovars, rrn operons are not arranged around the origin of replication but are equally distributed on the chromosome. Strain JM300 does not belong to any described genomovar, as determined from the organization of its genome. Large chromosomal rearrangements seem to be responsible for the differences in superordinate genome structure and must have played an important role in P. stutzeri diversification and niche colonization. An ancestral chromosome is suggested, and some plausible pathways for the generation of the various genome structures are proposed.

Comparative Genetic Diversity of Pseudomonas stutzeri Genomovars, Clonal Structure, and Phylogeny of the Species

A combined phylogenetic and multilocus DNA sequence analysis of 26 Pseudomonas stutzeri strains distributed within the 9 genomovars of the species has been performed. Type strains of the two most closely related species (P. balearica, former genomovar 6, and P. mendocina), together with P. aeruginosa, as the type species of the genus, have been included in the study. The extremely high genetic diversity and the clonal structure of the species were confirmed by the sequence analysis. Clustering of strains in the consensus phylogeny inferred from the analysis of seven nucleotide sequences (16S ribosomal DNA, internally transcribed spacer region 1, gyrB, rpoD, nosZ, catA, and nahH) confirmed the monophyletic origin of the genomovars within the Pseudomonas branch and is in good agreement with earlier DNA-DNA similarity analysis, indicating that the selected genes are representative of the whole genome in members of the species.

Bacterial Community Dynamics during Bioremediation of Diesel Oil-Contaminated Antarctic Soil

The effect of nutrient and inocula amendment in a bioremediation field trial using a nutrient-poor Antarctic soil chronically contaminated with hydrocarbons was tested. The analysis of the effects that the treatments caused in bacterial numbers and hydrocarbon removal was combined with the elucidation of the changes occurring on the bacterial community, by 16S rDNA-based terminal restriction fragment length polymorphism (T-RFLP) typing, and the detection of some of the genes involved in the catabolism of hydrocarbons. All treatments caused a significant increase in the number of bacteria able to grow on hydrocarbons and a significant decrease in the soil hydrocarbon content, as compared to the control. However, there were no significant differences between treatments. Comparison of the soil T-RFLP profiles indicated that there were changes in the structure and composition of bacterial communities during the bioremediation trial, although the communities in treated plots were highly similar irrespective of the treatment applied, and they had a similar temporal dynamics. These results showed that nutrient addition was the main factor contributing to the outcome of the bioremediation experiment. This was supported by the lack of evidence of the establishment of inoculated consortia in soils, since their characteristic electrophoretic peaks were only detectable in soil profiles at the beginning of the experiment. Genetic potential for naphthalene degradation, evidenced by detection of nahAc gene, was observed in all soil plots including the control. In treated plots, an increase in the detection of catechol degradation genes (nahH and catA) and in a key gene of denitrification (nosZ) was observed as well. These results indicate that treatments favored the degradation of aromatic hydrocarbons and probably stimulated denitrification, at least transiently. This mesocosm study shows that recovery of chronically contaminated Antarctic soils can be successfully accelerated using biostimulation with nutrients, and that this causes a change in the indigenous bacterial communities and in the genetic potential for hydrocarbon degradation.