Dietmar Vybiral

Classification of three airborne bacteria and proposal of Hymenobacter aerophilus sp. nov.

Three aerobic, gram-negative, rod-shaped, non-spore-forming, red-pigmented, airborne bacteria (I/26-Cor1T, I/32A-Cor1 and I/74-Cor2) collected in the Museo Correr (Venice, Italy) were investigated to determine their taxonomic status by analysing their biochemical, physiological and chemotaxonomic features and the G+C content of genomic DNA and by comparing their genomic fingerprints. Additionally, the almost complete 16S rRNA gene sequence of strain I/26-Cor1T was analysed. The three strains were nearly identical in their morphological, physiological, biochemical and chemotaxonomic properties. The strains contained a menaquinone system with the predominant menaquinone MK-7 and a fatty acid profile with C15:0 anteiso, C15:0 iso and C16:1 predominant. Phosphatidylethanolamine and several unidentified lipids were detected in the polar lipid profiles. The polyamine pattern consisted of sym-homospermidine as the major compound. meso-Diaminopimelic acid was found as the characteristic cell-wall diamino acid. The DNA base composition of the three strains ranged from 60 to 63 mol% G+C. Phylogenetically, strain I/26-Cor1T was most closely related to Hymenobacter actinosclerus (95.8% 16S rRNA gene sequence similarity). Physiological and genomic characteristics indicated that the two strains I/26-Cor1T and I/32A-Cor1 are representatives of the same species. The phylogenetic distance to any validly described taxon as indicated by 16S rRNA gene sequence similarities demonstrates that I/26-Cor1T and I/32A-Cor1 represent a novel species, for which the name Hymenobacter aerophilus sp. nov. is proposed, with the type strain I/26-Cor1T (= DSM 13606T = LMG 19657T). I/32A-Cor1 (= DSM 13607 = LMG 19658) is another strain of the species Hymenobacter aerophilus. Since the taxonomic status of strain I/74-Cor2 within the genus Hymenobacter was not determined unambiguously, it is designated Hymenobacter sp. I/74-Cor2 (= DSM 13611 = LMG 19659).

Erythrobacter citreus sp. nov., a yellow-pigmented bacterium that lacks bacteriochlorophyll a, isolated from the western Mediterranean Sea.

Two facultatively oligotrophic, intensely yellow-pigmented bacterial strains, RE35F/1T and RE10F/45, have been previously isolated from the western Mediterranean Sea (Bay of Calvi, Corsica, France) by 0.2 microm membrane filtration. The organisms were gram-negative, catalase- and oxidase-positive, strictly aerobic, rod-shaped and non-motile. Their respiratory lipoquinone profiles consisted exclusively of ubiquinone-10 (Q-10) and the G+C contents of their DNAs were 62.0 and 62.4 mol%, respectively. Among the cellular fatty acids, octadecenoic acid (18:1omega7c) was the major component. Both isolates also contained hydroxy fatty acids (14:0 2-OH, 18:1 2-OH and 16:0 iso 3-OH) and branched fatty acids (15:0 anteiso, 16:0 anteiso and 17:0 anteiso). Polar lipid fingerprints were characterized by the presence of a sphingoglycolipid. Comparative analyses of their 16S rRNA gene sequences indicated that both isolates were phylogenetically closely related (sequence similarity of 99.9%) and formed a coherent cluster with aerobic bacteriochlorophyll a-containing species of the Erythrobacter/Porphyrobacter/Erythromicrobium cluster within the family Sphingomonadaceae. The closest relative was Erythrobacter litoralis DSM 8509T (97.4 and 97.5% 16S rRNA gene sequence similarity between this strain and RE35F/1T and RE10F/45, respectively). DNA-DNA reassociation studies confirmed that strains RE35F/1T and RE10F/45 represent a single species (79.6% DNA homology), but also demonstrated that they do not belong to the species Erythrobacter litoralis (25.2 and 34.2% DNA homology, respectively). Notably, both RE35F/1T and RE10F/45 lacked bacteriochlorophyll a. Based upon phenotypic and molecular evidence, a novel species of the genus Erythrobacter, Erythrobacter citreus sp. nov., is proposed. Strain RE35F/1T (= CIP 107092T = DSM 14432T) is the type strain.

Emended descriptions of the genus micrococcus, Micrococcus luteus (Cohn 1872) and Micrococcus lylae (Kloos et al. 1974)

Nine yellow-pigmented, spherical bacterial strains isolated from a medieval wall painting (strain D7), from indoor air (strains 3, 6, 7, 13C2, 38, 83 and 118) and from an activated-sludge plant (strain Ballarat) were classified by a polyphasic approach. Analyses of the 16S rRNA gene sequences of three representatives (strains D7, 118 and Ballarat) indicated that they all belong to the genus Micrococcus. The three isolates shared the highest sequence similarities with Micrococcus luteus DSM 20030T (97.9-98%), Micrococcus antarcticus AS 1.2372T (97.9-98.3%) and Micrococcus lylae DSM 20315T (97.5-97.9%). DNA-DNA reassociation studies clearly demonstrated that all nine isolates belong to the species M. luteus. However, neither their chemotaxonomic features nor their physiological and biochemical properties were consistent with those of M. luteus DSM 20030T. In contrast to M. luteus DSM 20030T, all isolates investigated possessed MK-8(H2) as the major respiratory quinone, and strain Ballarat had an A4alpha peptidoglycan type. On the basis of analyses of their Fourier transform-infrared spectroscopy spectra, isolates D7, 3, 6, 7, 13C2, 38, 83 and 118 could be grouped into a single cluster separate from M. luteus DSM 20030T, strain Ballarat and M. lylae DSM 20315T. In addition, all these isolates could be distinguished from M. luteus DSM 20030T by their ability to assimilate D-maltose, D-trehalose, DL-3-hydroxybutyrate, DL-lactate, pyruvate and L-histidine and to hydrolyse casein. Strains D7, 3, 6, 7, 13C2, 38, 83 and 118 differed from both M. luteus DSM 20030T and strain Ballarat by their ability to assimilate acetate, L-phenylalanine, L-serine and phenylacetate. Furthermore, REP-PCR fingerprinting yielded one common band for these strains, whereas this band was not observed for M. luteus DSM 20030T, strain Ballarat or M. lylae DSM 20315T. On the basis of these data, the species M. luteus can be divided into three biovars that are distinguished by several chemotaxonomic and biochemical traits: biovar I, represented by M. luteus DSM 20030T; biovar II, represented by strains D7 (= DSM 14234 = CCM 4959), 3, 6, 7, 13C2, 38, 83 and 118; and biovar III, represented by strain Ballarat (= DSM 14235 = CCM 4960). On the basis of the results generated in this study, emended descriptions of the genus Micrococcus and the species M. luteus and M. lylae are given.

Rubrobacter-related bacteria associated with rosy discolouration of masonry and lime wall paintings

Abstract. A molecular approach was chosen to analyse the correlation between bacterial colonisation and rosy discolouration of masonry and lime wall paintings of two historically important buildings in Austria and Germany. The applied molecular method included PCR amplification of genes encoding the small subunit rRNA of bacteria (16S rDNA), genetic fingerprinting by denaturing gradient gel electrophoresis (DGGE), construction of 16S rDNA clone libraries, and comparative phylogenetic sequence analyses. The bacterial community of one red-pigmented biofilm sampled in Herberstein (Austria) contained bacteria phylogenetically related to the genera Saccharopolyspora, Nocardioides, Pseudonocardia, Rubrobacter, and to a Kineococcus-like bacterium. The bacterial community of the second red-pigmented biofilm sampled in Herberstein contained bacteria related to Arthrobacter, Comamonas, and to Rubrobacter. Rubrobacter-related 16S rDNA sequences were the most abundant. In the red-pigmented biofilm sampled in Burggen (Germany), only Rubrobacter-related bacteria were identified. No Rubrobacter-related bacteria were detected in non-rosy biofilms. The majority of sequences (70%) obtained from the bacterial communities of the three investigated rosy biofilms were related to sequences of the genus Rubrobacter (red-pigmented bacteria), demonstrating a correlation between Rubrobacter-related bacteria and the phenomenon of rosy discolouration of masonry and lime wall paintings.

Detection of Indigenous Halobacillus Populations in Damaged Ancient Wall Paintings and Building Materials: Molecular Monitoring and Cultivation

ABSTRACT Several moderately halophilic gram-positive, spore-forming bacteria have been isolated by conventional enrichment cultures from damaged medieval wall paintings and building materials. Enrichment and isolation were monitored by denaturing gradient gel electrophoresis and fluorescent in situ hybridization. 16S ribosomal DNA analysis showed that the bacteria are most closely related to Halobacillus litoralis. DNA-DNA reassociation experiments identified the isolates as a population of hitherto unknownHalobacillus species.

Georgenia muralis gen. nov., sp. nov., a novel actinobacterium isolated from a medieval wall painting

Two bacterial strains, designated 1A-C(T) and 3A-1, were studied and, using these results and previously published data, taxonomically classified. Cells of the strains exhibited a rod-coccus cycle. The peptidoglycan determined for 1A-C(T) was of type A4alpha with lysine as the diagnostic cell-wall diamino acid and an interpeptide bridge of L-Lys <-- L-Glu. The menaquinone systems of the two strains contained MK-8(H4) (82-94%) and MK-7(H4) (3-11%). The polar lipid profiles consisted of diphosphatidylglycerol, phosphatidylglycerol, phosphatidylinositol mannoside, two unidentified phospholipids and an unidentified glycolipid. The fatty acid profiles contained predominantly ai-C15:0 and significant amounts of i-C14:0 and i-C15:1 fatty acids. Genomic fingerprints clearly distinguished strains 1A-C(T) and 3A-1 from each other. DNA-DNA relatedness between the two strains (92%) demonstrated that they are members of a single species. Analyses of the 16S rDNA sequences of strains IA-C(T) and 3A-1, which were almost identical (99.6% sequence similarity), and comparison with corresponding sequences demonstrated that they represent a novel lineage within the suborder Micrococcineae, most closely related to species of the genera Beutenbergia, Bogoriella and Cellulomonas (94.7-95.7% sequence similarity). The results demonstrate that the two strains are members of a single new genus and a single novel species. Thus, the name Georgenia muralis gen. nov., sp. nov. is proposed. The type strain is strain 1A-C(T) (= DSM 14418T = CCM 4963T). Another strain of the species is strain 3A-1 (= DSM 14419 = CCM 4964).

Vibrio calviensis sp. nov., a halophilic, facultatively oligotrophic 0.2 microm-fiIterabIe marine bacterium.

A gram-negative, facultatively anaerobic, straight to slightly curved rod-shaped bacterium (RE35F/12T) sensitive to vibriostatic agent O/129 was previously isolated from sea water (Western Mediterranean Sea, Bay of Calvi, Corsica, France) by 0.2 microm-membrane filtration. Strain RE35/F12T (= CIP 107077T = DSM 14347T) was facultatively oligotrophic, halophilic, required Na+ for growth and produced acid but no gas from D-glucose under anaerobic conditions. Comparative 165 rRNA gene-sequence analyses demonstrated that the bacterium is most closely related (94.3%) to Vibrio scophthalmi. Similarities to the sequences of all other established Vibrio species ranged from 93.6% (with Vibrio aestuarianus) to 90.7% (with Vibrio rumoiensis). Strain RE35/F12T occupies a distinct phylogenetic position; this is similar to the case of Vibrio hollisae, because RE35F/12T represents a relatively long subline of descent sharing a branching point with the outskirts species V. hollisae. The G+C content of the DNA was 49.5 mol%. Ubiquinone Q-8 was the main respiratory lipoquinone, and 16:1omega9cis, 16:0 and 18:1trans9, cis11 were the major cellular fatty acids, 16:1omega9cis being predominant. The polyamine pattern was characterized by the presence of the triamine sym-norspermidine. On the basis of the polyphasic information summarized above, a new Vibrio species is described for which the name Vibrio calviensis sp. nov. is proposed.

Polyphasic Classification of 0.2 μm Filterable Bacteria from the Western Mediterranean Sea

The 0.2 microm filtration of sea water samples from the Mediterranean Sea (Bay of Calvi, Corsica), collected from 10 m and 35 m depth led to the isolation of several gram-negative bacterial strains able to grow on full-strength media as well as on diluted media. The analysis of the 16S rRNA gene sequences and estimation of the phylogenetic relationships of these facultative oligotrophic bacteria indicated that they grouped into two phylogenetic branches. The strains RE10F/2, RE10F/5 (10 m depth samples) and RE35/F12 (35 m depth samples) were assigned to the gamma-subclass, while RE35F/1 (35m depth sample) was assigned to the alpha-4-subclass of the Proteobacteria. The strains RE10/F2 and RE10/F5 were most closely related to species and strains of the Pseudoalteromonas group, whereas the strain RE35F/12 placed adjacent to the family Vibrionaceae. The phylogenetic analysis of strain RE35F/1 revealed that this bacterium clusters with marine strains and species of the aerobic anoxygenic phototrophic bacteria Erythrobacter as well as Erythromicrobium and more distantly to Sphingomonas spp. Supplementary to those genotypic classifications the chemotaxonomic signatures including the major respiratory lipoquinone systems, the cellular fatty acid compositions as well as the polyamine contents of the bacteria were investigated. The isolated organisms displayed differences in their physiological and biochemical properties to already described strains belonging to the same genera or families, as revealed by the comparative 16S rRNA analysis. Despite the fact that these bacteria were isolated from a 0.2 microm filtrate, the cultured organisms which were all rod-shaped, displayed width dimensions ranging from 0.4 up to 0.7 microm, indicating that these bacteria were starvation forms at the time of isolation and not ultramicrobacteria as defined by Torella and Morita (1981) or by Schut et al. (1993). Because our isolated strains represent potentially new taxa, this first investigation on 0.2 pm filterable bacteria from the Western Mediterranean Sea supports the hypothesis that this bacterial fraction contributes to the diversity of marine bacteria.