Orsola Päuker

Phylogenetic Analysis of the Genus Desulfotomaculum: Evidence for the Misclassification of Desulfotomaculum guttoideum and Description of Desulfotomaculum orientis as Desulfosporosinus orientis gen. nov., comb. nov.

Almost complete 16S ribosomal DNA (rDNA) sequences were determined for the type strains of nine species belonging to the genus Desulfotomaculum and for seven strains described as strains of this genus. The sequences were compared with previously published 16S rDNA and rRNA sequences of the type strains of the other species of the genus. The majority of the species form a phylogenetically coherent cluster within the Clostridium-Bacillus subphylum of gram-positive bacteria. The cluster consists of phylogenetically well-separated lineages containing (i) Desulfotomaculum nigrificans, Desulfotomaculum aeronauticum, and Desulfotomaculum ruminis, (ii) Desulfotomaculum geothermicum, Desulfotomaculum thermosapovorans, and Desulfotomaculum sapomandens, (iii) Desulfotomaculum kuznetsovii, Desulfotomaculum australicum, and Desulfotomaculum thermocisternum, (iv) Desulfotomaculum thermobenzoicum and Desulfotomaculum thermoacetoxidans, and (v) Desulfotomaculum acetoxidans. Some as-yet-undescribed Desulfotomaculum strains are phylogenetically well-separated from strains of the described species. Desulfotomaculum guttoideum shares extremely high 16S rDNA similarity with certain Clostridium species (e.g., Clostridium sphenoides and Clostridium celerecrescens) and is most likely a misidentified species. Desulfotomaculum orientis represents a new genus which branches most closely to the genus Desulfitobacterium. The name Desulfosporosinus orientis gen. nov., comb. nov., is proposed for this taxon.

Genome Organization and Localization of the pufLM Genes of the Photosynthesis Reaction Center in Phylogenetically Diverse Marine Alphaproteobacteria

ABSTRACT Genome organization, plasmid content and localization of the pufLM genes of the photosynthesis reaction center were studied by pulsed-field gel electrophoresis (PFGE) in marine phototrophic Alphaproteobacteria. Both anaerobic phototrophs (Rhodobacter veldkampii and Rhodobacter sphaeroides) and strictly aerobic anoxygenic phototrophs from the Roseobacter-Sulfitobacter-Silicibacter clade (Roseivivax halodurans, Roseobacter litoralis, Staleya guttiformis, Roseovarius tolerans, and five new strains isolated from dinoflagellate cultures) were investigated. The complete genome size was estimated for R. litoralis DSM6996T to be 4,704 kb, including three linear plasmids. All strains contained extrachromosomal elements of various conformations (linear or circular) and lengths (between 4.35 and 368 kb). In strain DFL-12, a member of a putative new genus isolated from a culture of the toxic dinoflagellate Prorocentrum lima, seven linear plasmids were found, together comprising 860 kb of genetic information. Hybridization with probes against the pufLM genes of the photosynthesis gene cluster after Southern transfer of the genomic DNAs showed these genes to be located on a linear plasmid of 91 kb in R. litoralis and on a linear plasmid of 120 kb in S. guttiformis, theoretically allowing their horizontal transfer. In all other strains, the pufLM genes were detected on the bacterial chromosome. The large number and significant size of the linear plasmids found especially in isolates from dinoflagellates might account for the metabolic versatility and presumed symbiotic association with eukaryotic hosts in these bacteria.

Molecular and phenotypic analyses reveal the non-identity of the Phaeobacter gallaeciensis type strain deposits CIP 105210T and DSM 17395

The marine genus Phaeobacter currently comprises six species, some of which were intensively studied mainly due to their ability to produce secondary metabolites. The type strain of the type species, Phaeobacter gallaeciensis BS107(T), has been deposited at several public culture collections worldwide. Based on differences in plasmid profiles, we detected that the alleged P. gallaeciensis type strains deposited at the Collection Institute Pasteur (CIP; Paris, France) as CIP 105210 and at the German Collection of Microorganisms and Cell Cultures (DSMZ; Braunschweig, Germany) as DSM 17395 are not identical. To determine the identity of these strains, we conducted DNA-DNA hybridization, matrix-assisted laser desorption/ionization time-of-flight mass spectrometry (MALDI-TOF), 16S rRNA gene and internal transcribed spacer (ITS) sequence analyses, as well as physiological experiments. Based on the detailed 16S rRNA gene reanalysis we showed that strain CIP 105210 most likely corresponds to the original P. gallaeciensis type strain BS107(T). In contrast, the Phaeobacter strain DSM 17395 exhibits a much closer affiliation to Phaeobacter inhibens DSM 16374(T) ( = T5(T)) and should thus be allocated to this species. The detection of the dissimilarity of strains CIP 105210(T) and DSM 17395 will influence future comparative studies within the genus Phaeobacter.

Grouping Myxococci (Corallococcus) Strains by Matrix-Assisted Laser Desorption Ionization Time-of-Flight (MALDI TOF) Mass Spectrometry: Comparison with Gene Sequence Phylogenies

Nine Corallococcus isolates and three type strains of Corallococcus species were characterized by Intact Cell Mass Spectrometry using Matrix Assisted Laser Desorption Ionization Time-of-Flight (MALDI-TOF) mass spectrometry. The resulting phenetic clustering was compared to the phylogenetic grouping based upon sequences of two housekeeping genes. The three dendrograms of relatedness resembled each other in that the isolates were highly similar to the type strains of Corallococcus exiguus and Corallococcus coralloides, while Corallococcus macrosporus and Myxococcus xanthus were more distantly related. While certain pairs of organisms were recovered by spectrometry and genes sequence analysis, others were detected by two of the three approaches. The degree of similarity determined by sequence analysis of the two genes was not higher than that revealed by MALDI-TOF analysis. The results show that the spectral profile, consisting of about 25 to 45 masses ranging between 2 and 20 kDa, have indeed taxonomic significance, confirming literature data that ribosomal proteins and certain housekeeping proteins are responsible for the masses obtained. Provided the availability of a database of type strains, MALDI-TOF analysis of unknown strains appears to be a rapid and inexpensive method to taxonomically cluster environmental isolates, expanding the spectrum to strains other than those of medical importance predominantly investigated so far.

Genome of the R-body producing marine alphaproteobacterium Labrenzia alexandrii type strain (DFL-11(T)).

Labrenzia alexandrii Biebl et al. 2007 is a marine member of the family Rhodobacteraceae in the order Rhodobacterales, which has thus far only partially been characterized at the genome level. The bacterium is of interest because it lives in close association with the toxic dinoflagellate Alexandrium lusitanicum. Ultrastructural analysis reveals R-bodies within the bacterial cells, which are primarily known from obligate endosymbionts that trigger “killing traits” in ciliates (Paramecium spp.). Genomic traits of L. alexandrii DFL-11T are in accordance with these findings, as they include the reb genes putatively involved in R-body synthesis. Analysis of the two extrachromosomal elements suggests a role in heavy-metal resistance and exopolysaccharide formation, respectively. The 5,461,856 bp long genome with its 5,071 protein-coding and 73 RNA genes consists of one chromosome and two plasmids, and has been sequenced in the context of the Marine Microbial Initiative.

Genome of the marine alphaproteobacterium Hoeflea phototrophica type strain (DFL-43 T )

Hoeflea phototrophica Biebl et al. 2006 is a member of the family Phyllobacteriaceae in the order Rhizobiales, which is thus far only partially characterized at the genome level. This marine bacterium contains the photosynthesis reaction-center genes pufL and pufM and is of interest because it lives in close association with toxic dinoflagellates such as Prorocentrum lima. The 4,467,792 bp genome (permanent draft sequence) with its 4,296 protein-coding and 69 RNA genes is a part of the Marine Microbial Initiative.

Gene Flow Across Genus Barriers – Conjugation of Dinoroseobacter shibae’s 191-kb Killer Plasmid into Phaeobacter inhibens and AHL-mediated Expression of Type IV Secretion Systems

Rhodobacteraceae harbor a conspicuous wealth of extrachromosomal replicons (ECRs) and therefore the exchange of genetic material via horizontal transfer has been supposed to be a major evolutionary driving force. Many plasmids in this group encode type IV secretion systems (T4SS) that are expected to mediate transfer of proteins and/or DNA into host cells, but no experimental evidence of either has yet been provided. Dinoroseobacter shibae, a species of the Roseobacter group within the Rhodobacteraceae family, contains five ECRs that are crucial for anaerobic growth, survival under starvation and the pathogenicity of this model organism. Here we tagged two syntenous but compatible RepABC-type plasmids of 191 and 126-kb size, each encoding a T4SS, with antibiotic resistance genes and demonstrated their conjugational transfer into a distantly related Roseobacter species, namely Phaeobacter inhibens. Pulsed field gel electrophoresis showed transfer of those replicons into the recipient both individually but also together documenting the efficiency of conjugation. We then studied the influence of externally added quorum sensing (QS) signals on the expression of the T4SS located on the sister plasmids. A QS deficient D. shibae null mutant (ΔluxI1) lacking synthesis of N-acyl-homoserine lactones (AHLs) was cultivated with a wide spectrum of chemically diverse long-chain AHLs. All AHLs with lengths of the acid side-chain ≥14 reverted the ΔluxI1 phenotype to wild-type. Expression of the T4SS was induced up to log2 ∼3fold above wild-type level. We hypothesize that conjugation in roseobacters is QS-controlled and that the QS system may detect a wide array of long-chain AHLs at the cell surface.