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Description of Roseateles aquatilis sp. nov. and Roseateles terrae sp. nov., in the class Betaproteobacteria, and emended description of the genus Roseateles

¹ Área Microbiologia, Departament de Biologia, Universitat de les Illes Balears, and Institut Mediterrani d'Estudis Avançats (CSIC-UIB), 07122 Palma de Mallorca, Illes Balears, Spain
² Abt. Molekularphysiologie, Institut für Mikrobiologie und Genetik, Georg-August-Universität Göttingen, 37077 Göttingen, Germany
³ CCUG, Culture Collection, Department of Clinical Bacteriology, University of Göteborg, 41346 Göteborg, Sweden

Correspondence
Jorge Lalucat
jlalucat{at}uib.es

	ABSTRACT

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Three strains of aerobic Gram-negative bacilli, two isolated from industrial water and freshwater (strains CCUG 48205^T and CCUG 52220) and the third from soil (strain CCUG 52222^T), were analysed phenotypically and genotypically to clarify their taxonomic classification. 16S rRNA gene sequence analysis revealed that the three strains were located on the same phylogenetic branch, closely related to Roseateles depolymerans, the only recognized species in the genus. DNA–DNA hybridization studies, analyses of fatty acid contents, and physiological and biochemical tests supported the proposal of two novel species, Roseateles aquatilis sp. nov. (type strain, CCUG 48205^T=CECT 7248^T) and Roseateles terrae sp. nov. (type strain, CCUG 52222^T=CECT 7247^T).

The GenBank/EMBL/DDBJ accession numbers for the 16S rRNA, ITS1, nifH and puf gene sequences determined in this study are AM501443–AM501446, AM501462, AM501479 and AM501480, and AM773545–AM773547, respectively.

Carbon source utilization data (Biolog), DNA–DNA hybridization values and a 16S rRNA gene sequence matrix are available as supplementary tables with the online version of this paper.

	MAIN TEXT

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The genera Aquabacterium (Kalmbach et al., 1999), Ideonella (Malmqvist et al., 1994), Rubrivivax (Willems et al., 1991), Roseateles (Suyama et al., 1999), Azohydromonas (Xie & Yokota, 2005), Mitsuaria (Amakata et al., 2005) and Pelomonas (Xie & Yokota, 2005; Gomila et al., 2007) are phylogenetically closely related to the Sphaerotilus–Leptothrix group. These genera form the Rubrivivax line of descent, which is associated with the family Comamonadaceae (Wen et al., 1999). Willems & Gillis (2001) consider these genera to be of incertae sedis within the family Comamonadaceae. The relative branching order of most species within the Rubrivivax group is difficult to determine, mainly because of the limited number of variable positions available for estimating phylogenetic distance values (Spring, 2001).

Roseateles depolymerans 61A^T (=CCUG 52219^T=DSM 11813^T), which is closely related to species of the genera Mitsuaria and Pelomonas, was isolated in 1998 from river water and described in 1999 as the first bacteriochlorophyll a-containing, obligate aerobe belonging to the Betaproteobacteria. The strain was isolated originally as a degrader of poly(hexamethylene carbonate) (PHC) and is considered to be an aerobic phototroph (Suyama et al., 1999). Since 2005, three novel strains (CCUG 48205^T, CCUG 52220 and CCUG 52222^T) have been isolated from different sources, including industrial water, freshwater and soil, and were identified provisionally as ‘Roseateles depolymerans-like’ organisms. The present study was undertaken to characterize and determine the taxonomic positions of these organisms. The data demonstrated that strains CCUG 48205^T and CCUG 52222^T should be classified as representing two novel species, with the names Roseateles aquatilis sp. nov. and Roseateles terrae sp. nov., respectively.

The reference strains used in this study included Pelomonas saccharophila CCUG 32988^T, Pelomonas aquatica CCUG 52575^T, Pelomonas puraquae CCUG 52769^T, Mitsuaria chitosanitabida IAM 14711^T and Roseateles depolymerans CCUG 52219^T, as well as Roseateles depolymerans strain CCUG 52220, Roseateles sp. strain CCUG 52222^T and Roseateles depolymerans-like strain CCUG 48205^T. All of the strains used in this study were cultivated in R2A medium (Reasoner & Geldreich, 1985), containing (l^–1): 0.5 g yeast extract, 0.5 g acid hydrolysate of casein, 0.5 g glucose, 0.5 g starch, 0.3 g K₂HPO₄, 0.3 g sodium pyruvate, 0.25 g pancreatic digest of casein, 0.25 g peptic digest of animal tissue, 0.0492 g MgSO₄ . 7H₂O, supplemented with 1.5 % (w/v) agar (Scharlab) for solid medium. The bacteria were incubated for 3–4 days at 30 °C, if not stated otherwise.

Cell size, morphology and flagella insertion were determined using transmission electron microscopy of cells from the exponential growth phase in R2A broth. A Hitachi model H600 electron microscope was used at 75 kV. The samples were negatively stained with phosphotungstic acid (1 % w/v, pH 7.0), as described by Lalucat (1988).

The following phenotypic tests were carried out: API 20NE (identification system for Gram-negative, non-enterobacterial rods) and API 50 CH, according to the instructions of the manufacturer. Biolog tests were also carried out according to the instructions of the manufacturer. Briefly, the procedure was as follows: a homogeneous suspension of cells grown on plates of trypticase soy agar supplemented with sheep blood was made in the GN/GP inoculating fluid and 150 µl of the suspension was dispensed into each well of a GN microplate, which was then incubated for up to 96 h at 30 °C. The absorbance values were recorded periodically over a 4-day period, at 0, 4, 8, 24, 48, 72 and 96 h incubation time, using an automated Microplate reader. Absorbance was measured in dual wavelength mode, at 590 nm (as respiratory reduction will cause the tetrazolium dye to turn purple and absorb light at 590 nm) and at 750 nm as a second reference wavelength.

Conventional phenotypic tests were done according to the methods of Cowan (1974). Growth rates were determined at different temperatures (4, 10, 20, 30, 37 and 45 °C) in R2A medium, and aerobic autotrophic growth with hydrogen was tested in mineral medium, as described by Aragno & Schlegel (1992), at different O₂ partial pressures. For the detection of photosynthetic pigments, cells were grown in R2A medium, PHC medium (or PHC medium supplemented with Tween 80) or in medium lacking organic carbon as described by Suyama et al. (1999, 2002). Lipophilic pigments were extracted from fresh wet cells cultured in the four media, under light or in the dark, using acetone [90 % (v/v) with 1 % MgCO₃ at 4 °C for 24 h). Absorption spectra were recorded spectrophotometrically (Ultrospec III; Pharmacia LKB) between wavelengths of 360 and 900 nm.

Colonies of strains CCUG 52219^T and CCUG 52220 grown on R2A medium for 5 days were 4–5 mm in diameter, transparent, darker in the centre, circular and flat, with an undulate margin, and smooth and translucent. Strain CCUG 52222^T could be differentiated by means of a more mucous appearance of the colonies, which were 4–6 mm in diameter, less transparent, circular and convex, with an undulate transparent margin. Colonies of strain CCUG 48205^T were 4–6 mm in diameter, clear white, circular and umbonate, with an undulate margin, and translucent. Old colonies showed concentric circles.

Cells were rod-shaped (2 µm in length), Gram-negative and motile, by means of a single polar flagellum. All strains grew at 20 and 30 °C. None of the strains were able to grow at 4 or 45 °C. The range of growth temperatures is indicated in Table 1. Differential phenotypic characteristics and substrates assimilated or utilized as sole carbon and energy sources are listed in Table 1. Carbon sources utilized in Biolog plates are given in Supplementary Table S1, available in IJSEM Online. Differential phenotypic characteristics obtained in the Biolog test are summarized in Table 2. None of the novel isolates were able to produce pigments when incubated for 1 week in the dark or under light in R2A medium or PHC medium, or in PHC medium supplemented with Tween 80, as well as in mineral medium.

The 16S rRNA, internally transcribed spacer 1 (ITS1; between the 16S and the 23S genes), nifH (nitrogenase) and Rubisco genes were amplified from genomic DNA by PCR, and sequenced as described previously (Gomila et al., 2007). Gene sequences were aligned with the homologous sequences of the closest relatives retrieved using the BLAST analysis tool and the NCBI nucleotide sequence database. The alignments were done using a hierarchical method for multiple alignments implemented in the program CLUSTAL_X (Thompson et al., 1997). Automatically aligned sequences were checked manually. Sequence similarities and evolutionary distances were calculated with programs implemented in PHYLIP (Phylogeny Inference Package, version 3.5c) (Felsenstein, 1989). The 16S rRNA gene sequence of strain CCUG 52220 was 99.7 % similar to that of Roseateles depolymerans CCUG 52219^T (Fig. 1). Strain CCUG 52222^T clustered in the same phylogenetic branch of the 16S rRNA gene sequence tree, with a sequence similarity of 99.6 % with that of the type strain, and was similar to the sequences of the species in the genus Pelomonas (between 97.2 and 97.9 %) and to the type strain of M. chitosanitabida (98.1 %). Strain CCUG 48205^T also grouped in the Roseateles branch, with a similarity of 98.6 % to the 16S rRNA gene sequence of the type strain of Roseateles depolymerans (see Supplementary Table S3 in IJSEM Online). The type strain of Roseateles depolymerans, as well as strains CCUG 52220 and CCUG 52222^T, showed two ITS1 amplicons of different sizes and were not sequenced. Rubisco genes cbbL of green or red form I enzymes and cbbM of the form II enzyme did not amplify in any of the strains. The nifH genes in strains CCUG 52219^T, CCUG 52220 and CCUG 52222^T were PCR-amplified and sequenced, and showed the same nucleotide sequence.

View larger version (29K): [in this window] [in a new window]   Fig. 1. Phylogenetic tree, based on 16S rRNA gene sequence comparisons over 1380 aligned bases, showing the relationship between the genera Mitsuaria, Pelomonas and Roseateles in the Betaproteobacteria. The tree was constructed using the neighbour-joining method, following distance analysis calculated by using the Jukes and Cantor method (Jukes & Cantor, 1969). The topology of the tree was visualized by means of the program TreeView (Page, 1996). Bootstrap values greater than 500 based on 1000 replications are indicated at nodes. Sequences indicated in bold were determined in this study. GenBank accession numbers are given in parentheses. Bar, 0.01 nucleotide substitutions per site.

In addition to the phylogenetic, genomic and chemotaxonomic differences, strain CCUG 48205^T could be differentiated from other Roseateles strains by its narrow range of temperatures for growth, by the assimilation of different carbon sources, catalase, β-glucosidase and β-galactosidase reactions and by the absence of nif and puf genes. Strain CCUG 52222^T could be differentiated from Roseateles depolymerans by its profile of carbon sources assimilated and by the urease reaction.

Based on these results, we conclude that strain CCUG 52220 belongs to the species Roseateles depolymerans and that strains CCUG 48205^T and CCUG 52222^T represent two novel species, with the names Roseateles aquatilis sp. nov. and Roseateles terrae sp. nov., respectively.

Emended description of the genus Roseateles Suyama et al. 1999
Roseateles (Ro.se.a.te'les. L. adj. roseus rose-coloured, pink; Gr. adj. ateles defective, incomplete; N.L. masc. n. roseateles the rose-coloured incomplete photosynthetic bacterium).

Cells are motile, Gram-negative straight rods. Cells of some strains are pink in colour under conditions suitable for photosynthetic pigment production. Cis-9-hexadecanoic and hexadecanoic acids are the major cellular fatty acids. Low levels of dodecanoic acid and high levels of cis-11-octadecanoic acid differentiate the genus from other genera in the same phylogenetic branch. Other characteristics of the genus are given by Suyama et al. (1999).

Description of Roseateles aquatilis sp. nov.
Roseateles aquatilis (a.qua.ti'lis. L. masc. adj. aquatilis aquatic, growing in water).

Colonies are 4–6 mm in diameter, clear white, circular and umbonate, with an undulate margin and translucent. Four-day-old colonies show concentric circles. Non-pigmented. Oxidase-positive and catalase-negative. Growth occurs in R2A medium at 20–30 °C, but not at 10 or 45 °C. Cells are rod-shaped (2 µm in length and 0.5 µm in width) with single polar flagella. Nitrate reduction, indole formation, glucose fermentation, arginine dihydrolase, urease, β-galactosidase (PNPG) and aesculin tests are negative. Gelatin hydrolysis is positive. D-Glucose, maltose, gluconate and malic acid are assimilated. L-Arabinose, D-mannose, D-mannitol, N-acetyl-D-glucosamine, capric acid, adipic acid, citrate and phenylacetic acid are not assimilated. Photosynthetic genes (puf) are not detected.

The type strain, CCUG 48205^T (=CECT 7248^T), was isolated from industrial water in Sweden.

Description of Roseateles terrae sp. nov.
Roseateles terrae (ter'rae. L. gen. n. terrae of the soil).

Colonies are circular, 4–6 mm in diameter and convex, with an undulate transparent margin. Non-pigmented. Oxidase- and catalase-positive. Growth occurs in R2A medium at 10–37 °C, but not at 4 or 45 °C. Cells are rod-shaped (2 µm in length and 0.5 µm in width) with single polar flagella. Nitrate reduction, indole formation, glucose fermentation, arginine dihydrolase and urease tests are negative. β-Galactosidase (PNPG), aesculin and gelatin hydrolysis are positive. D-Glucose, L-arabinose, D-mannose, D-mannitol, maltose, gluconate and capric acid are assimilated. Assimilation of malic acid is extremely weak. N-Acetyl-D-glucosamine, adipic acid, citrate and phenylacetic acid are not assimilated. Photosynthetic genes (puf) are detected, but are not expressed under the experimental conditions used.

The type strain, CCUG 52222^T (=CECT 7247^T), was isolated from soil in Japan.

	ACKNOWLEDGEMENTS

 
This work was supported in part by the CICYT (Spain) grant REN2002-04035-CO3-01 and by the ‘I Plà Balear de Recerca I Desenvolupament Tecnològic de les Illes Balears’. M. G. was the recipient of a predoctoral fellowship from the Spanish Ministerio de Educación y Ciencia. We gratefully acknowledge the excellent technical assistance of Gertrud Stahlhut. Also thanks to Kent Molin for his excellent cellular fatty acid analysis and to Tetsushi Suyama for strain deposits. We thank J. Gascó for helpful discussions.

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