Andreas Pommerening-Röser
University of Hamburg
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Applied and Environmental Microbiology | 2000
Ulrike Purkhold; Andreas Pommerening-Röser; Stefan Juretschko; Markus Schmid; Hans-Peter Koops; Michael Wagner
ABSTRACT The current perception of evolutionary relationships and the natural diversity of ammonia-oxidizing bacteria (AOB) is mainly based on comparative sequence analyses of their genes encoding the 16S rRNA and the active site polypeptide of the ammonia monooxygenase (AmoA). However, only partial 16S rRNA sequences are available for many AOB species and most AOB have not yet been analyzed on the amoAlevel. In this study, the 16S rDNA sequence data of 10Nitrosomonas species and Nitrosococcus mobiliswere completed. Furthermore, previously unavailable 16S rRNA sequences were determined for three Nitrosomonas sp. isolates and for the gamma-subclass proteobacterium Nitrosococcus halophilus. These data were used to revaluate the specificities of published oligonucleotide primers and probes for AOB. In addition, partial amoA sequences of 17 AOB, including the above-mentioned 15 AOB, were obtained. Comparative phylogenetic analyses suggested similar but not identical evolutionary relationships of AOB by using 16S rRNA and AmoA as marker molecules, respectively. The presented 16S rRNA and amoA and AmoA sequence data from all recognized AOB species significantly extend the currently used molecular classification schemes for AOB and now provide a more robust phylogenetic framework for molecular diversity inventories of AOB. For 16S rRNA-independent evaluation of AOB species-level diversity in environmental samples, amoA and AmoA sequence similarity threshold values were determined which can be used to tentatively identify novel species based on cloned amoA sequences. Subsequently, 122 amoA sequences were obtained from 11 nitrifying wastewater treatment plants. Phylogenetic analyses of the molecular isolates showed that in all but two plants only nitrosomonads could be detected. Although several of the obtained amoAsequences were only relatively distantly related to known AOB, none of these sequences unequivocally suggested the existence of previously unrecognized species in the wastewater treatment environments examined.
Systematic and Applied Microbiology | 1996
Andreas Pommerening-Röser; Gabriele Rath; Hans-Peter Koops
Summary The phylogenetic relationships within the genus Nitrosomonas were examined in order to obtain a basis for the development of a taxonomically, as well as ecophysiologically related gene probe system suitable for in situ analysis of natural populations of ammonia-oxidizing bacteria. In addition to the 10 validly described species and three undefined species of the genus Nitrosomonas, Nitrosococcus mobilis was included in this study. On the basis of 16S rRNA gene sequence results and DNA-DNA hybridization data, six distinct lines of descent, containing closely related or single species, can be distinguished. One of these lineages allied N. europaea and N. eutropha , which are both common in eutrophic freshwater habitats and which are both halotolerant, together with the obligately halophilic N. halophila . All these three species are urease negative. A second lineage was defined by the three marine species N. marina, N. aestuarii and Nitrosomonas sp. Nm 51, which are all obligately halophilic and urease positive. Two other distinct groups comprised oligotrophic Nitrosomonas species originating from terrestrial or freshwater environments. Members of one group were N. ureae and N. oligotropha , both being urease positive, and the other group contained the urease positive N. nitrosa together with the urease negative N. communis and Nitrosomonas spp. Nm 33 and Nm 41. The remaining two lineages were represented by single marine species, N. cryotolerans and Nitrosococcus mobilis , respectively. Based on currently available 16S rDNA sequences primer pairs useful for specific PCR assisted detection of ecophysiologically defined groups of ammonia oxidizers were selected.
Applied and Environmental Microbiology | 2009
Christel Schmeisser; Heiko Liesegang; Dagmar Krysciak; Nadia Bakkou; Antoine Le Quéré; Antje Wollherr; Isabelle Heinemeyer; Burkhard Morgenstern; Andreas Pommerening-Röser; Margarita Flores; Rafael Palacios; Sydney Brenner; Gerhard Gottschalk; Ruth A. Schmitz; William J. Broughton; Xavier Perret; Axel Strittmatter; Wolfgang R. Streit
ABSTRACT Rhizobium sp. strain NGR234 is a unique alphaproteobacterium (order Rhizobiales) that forms nitrogen-fixing nodules with more legumes than any other microsymbiont. We report here that the 3.93-Mbp chromosome (cNGR234) encodes most functions required for cellular growth. Few essential functions are encoded on the 2.43-Mbp megaplasmid (pNGR234b), and none are present on the second 0.54-Mbp symbiotic plasmid (pNGR234a). Among many striking features, the 6.9-Mbp genome encodes more different secretion systems than any other known rhizobia and probably most known bacteria. Altogether, 132 genes and proteins are linked to secretory processes. Secretion systems identified include general and export pathways, a twin arginine translocase secretion system, six type I transporter genes, one functional and one putative type III system, three type IV attachment systems, and two putative type IV conjugation pili. Type V and VI transporters were not identified, however. NGR234 also carries genes and regulatory networks linked to the metabolism of a wide range of aromatic and nonaromatic compounds. In this way, NGR234 can quickly adapt to changing environmental stimuli in soils, rhizospheres, and plants. Finally, NGR234 carries at least six loci linked to the quenching of quorum-sensing signals, as well as one gene (ngrI) that possibly encodes a novel type of autoinducer I molecule.
Science | 2013
Robert Oswald; Thomas Behrendt; M. Ermel; Dianming Wu; Hang Su; Yafang Cheng; Claudia Breuninger; Alexander Moravek; E. Mougin; C. Delon; Benjamin Loubet; Andreas Pommerening-Röser; Matthias Sörgel; Ulrich Pöschl; Thorsten Hoffmann; Meinrat O. Andreae; F. X. Meixner; Ivonne Trebs
From Soil to Sky Trace gases emitted either through the activity of microbial communities or from abiotic reactions in the soil influence atmospheric chemistry. In laboratory column experiments using several soil types, Oswald et al. (p. 1233) showed that soils from arid regions and farmlands can produce substantial quantities of nitric oxide (NO) and nitrous acid (HONO). Ammonia-oxidizing bacteria are the primary source of HONO at comparable levels to NO, thus serving as an important source of reactive nitrogen to the atmosphere. HONO emissions from soil are comparable to those of NO in arid and arable regions. Abiotic release of nitrous acid (HONO) in equilibrium with soil nitrite (NO2–) was suggested as an important contributor to the missing source of atmospheric HONO and hydroxyl radicals (OH). The role of total soil-derived HONO in the biogeochemical and atmospheric nitrogen cycles, however, has remained unknown. In laboratory experiments, we found that for nonacidic soils from arid and arable areas, reactive nitrogen emitted as HONO is comparable with emissions of nitric oxide (NO). We show that ammonia-oxidizing bacteria can directly release HONO in quantities larger than expected from the acid-base and Henry’s law equilibria of the aqueous phase in soil. This component of the nitrogen cycle constitutes an additional loss term for fixed nitrogen in soils and a source for reactive nitrogen in the atmosphere.
Archives of Microbiology | 1990
Hans-Peter Koops; B. Böttcher; U. C. Möller; Andreas Pommerening-Röser; G. Stehr
A new species of Nitrosococcus is described. It resembles Nitrosococcus oceanus in shape, size, and ultrastructure of the cells. However, the new species has a more pronounced salt requirement, corresponding to its natural habitats. Two strains were isolated from a salt lake in Saudi Arabia and a salt lagoon in the Mediterranean Sea, respectively. In contrast to N. oceanus, both isolates of the new species were unable to utilize urea as ammonia source. Both species also differed in gelelectrophoretic cell protein patterns. The name N. halophilus is proposed.
Applied and Environmental Microbiology | 2013
Ines Krohn-Molt; Bernd Wemheuer; Malik Alawi; Anja Poehlein; Simon Güllert; Christel Schmeisser; Andreas Pommerening-Röser; Adam Grundhoff; Rolf Daniel; Dieter Hanelt; Wolfgang R. Streit
ABSTRACT Photobioreactors (PBRs) are very attractive for sunlight-driven production of biofuels and capturing of anthropogenic CO2. One major problem associated with PBRs however, is that the bacteria usually associated with microalgae in nonaxenic cultures can lead to biofouling and thereby affect algal productivity. Here, we report on a phylogenetic, metagenome, and functional analysis of a mixed-species bacterial biofilm associated with the microalgae Chlorella vulgaris and Scenedesmus obliquus in a PBR. The biofilm diversity and population dynamics were examined through 16S rRNA phylogeny. Overall, the diversity was rather limited, with approximately 30 bacterial species associated with the algae. The majority of the observed microorganisms were affiliated with Alphaproteobacteria, Betaproteobacteria, and Bacteroidetes. A combined approach of sequencing via GS FLX Titanium from Roche and HiSeq 2000 from Illumina resulted in the overall production of 350 Mbp of sequenced DNA, 165 Mbp of which was assembled in larger contigs with a maximum size of 0.2 Mbp. A KEGG pathway analysis suggested high metabolic diversity with respect to the use of polymers and aromatic and nonaromatic compounds. Genes associated with the biosynthesis of essential B vitamins were highly redundant and functional. Moreover, a relatively high number of predicted and functional lipase and esterase genes indicated that the alga-associated bacteria are possibly a major sink for lipids and fatty acids produced by the microalgae. This is the first metagenome study of microalga- and PBR-associated biofilm bacteria, and it gives new clues for improved biofuel production in PBRs.
PLOS ONE | 2013
Claudia Hornung; Anja Poehlein; Frederike S. Haack; Martina Schmidt; Katja Dierking; Andrea Pohlen; Hinrich Schulenburg; Melanie Blokesch; Laure Plener; Kirsten Jung; Andreas Bonge; Ines Krohn-Molt; Christian Utpatel; Gabriele Timmermann; Eva Spieck; Andreas Pommerening-Röser; Edna Bode; Helge B. Bode; Rolf Daniel; Christel Schmeisser; Wolfgang R. Streit
Janthinobacteria commonly form biofilms on eukaryotic hosts and are known to synthesize antibacterial and antifungal compounds. Janthinobacterium sp. HH01 was recently isolated from an aquatic environment and its genome sequence was established. The genome consists of a single chromosome and reveals a size of 7.10 Mb, being the largest janthinobacterial genome so far known. Approximately 80% of the 5,980 coding sequences (CDSs) present in the HH01 genome could be assigned putative functions. The genome encodes a wealth of secretory functions and several large clusters for polyketide biosynthesis. HH01 also encodes a remarkable number of proteins involved in resistance to drugs or heavy metals. Interestingly, the genome of HH01 apparently lacks the N-acylhomoserine lactone (AHL)-dependent signaling system and the AI-2-dependent quorum sensing regulatory circuit. Instead it encodes a homologue of the Legionella- and Vibrio-like autoinducer (lqsA/cqsA) synthase gene which we designated jqsA. The jqsA gene is linked to a cognate sensor kinase (jqsS) which is flanked by the response regulator jqsR. Here we show that a jqsA deletion has strong impact on the violacein biosynthesis in Janthinobacterium sp. HH01 and that a jqsA deletion mutant can be functionally complemented with the V. cholerae cqsA and the L. pneumophila lqsA genes.
International Journal of Systematic and Evolutionary Microbiology | 2015
Hidetoshi Urakawa; Juan C. Garcia; Jeppe Lund Nielsen; Vang Quy Le; Jessica A. Kozlowski; Lisa Y. Stein; Chee Kent Lim; Andreas Pommerening-Röser; Willm Martens-Habbena; David A. Stahl; Martin G. Klotz
A Gram-negative, spiral-shaped, chemolithotrophic, ammonia-oxidizing bacterium, designated APG3(T), was isolated into pure culture from sandy lake sediment collected from Green Lake, Seattle, WA, USA. Phylogenetic analyses based on the 16S rRNA gene sequence showed that strain APG3(T) belongs to cluster 0 of the genus Nitrosospira, which is presently not represented by described species, with Nitrosospira multiformis (cluster 3) as the closest species with a validly published name (identity of 98.6 % to the type strain). Strain APG3(T) grew at 4 °C but could not grow at 35 °C, indicating that this bacterium is psychrotolerant. Remarkably, the strain was able to grow over a wide range of pH (pH 5-9), which was greater than the pH range of any studied ammonia-oxidizing bacteria in pure culture. The DNA G+C content of the APG3(T) genome is 53.5 %, which is similar to that of Nitrosospira multiformis ATCC 25196(T) (53.9 %) but higher than that of Nitrosomonas europaea ATCC 19718 (50.7 %) and Nitrosomonas eutropha C71 (48.5 %). The average nucleotide identity (ANI) calculated for the genomes of strain APG3(T) and Nitrosospira multiformis ATCC 25196(T) was 75.45 %, significantly lower than the value of 95 % ANI that corresponds to the 70 % species-level cut-off based on DNA-DNA hybridization. Overall polyphasic taxonomy study indicated that strain APG3(T) represents a novel species in the genus Nitrosospira, for which the name Nitrosospira lacus sp. nov. is proposed (type strain APG3(T) = NCIMB 14869(T) = LMG 27536(T) = ATCC BAA-2542(T)).
Scientific Reports | 2018
M. Ermel; Thomas Behrendt; Robert Oswald; Bettina Derstroff; Dianming Wu; S. Hohlmann; Christof Stönner; Andreas Pommerening-Röser; M. Könneke; J. Williams; F. X. Meixner; Meinrat O. Andreae; Ivonne Trebs; Matthias Sörgel
Nitrous acid (HONO) is an important precursor of the hydroxyl radical (OH), the atmosphere´s primary oxidant. An unknown strong daytime source of HONO is required to explain measurements in ambient air. Emissions from soils are one of the potential sources. Ammonia-oxidizing bacteria (AOB) have been identified as possible producers of these HONO soil emissions. However, the mechanisms for production and release of HONO in soils are not fully understood. In this study, we used a dynamic soil-chamber system to provide direct evidence that gaseous emissions from nitrifying pure cultures contain hydroxylamine (NH2OH), which is subsequently converted to HONO in a heterogeneous reaction with water vapor on glass bead surfaces. In addition to different AOB species, we found release of HONO also in ammonia-oxidizing archaea (AOA), suggesting that these globally abundant microbes may also contribute to the formation of atmospheric HONO and consequently OH. Since biogenic NH2OH is formed by diverse organisms, such as AOB, AOA, methane-oxidizing bacteria, heterotrophic nitrifiers, and fungi, we argue that HONO emission from soil is not restricted to the nitrifying bacteria, but is also promoted by nitrifying members of the domains Archaea and Eukarya.
Applied and Environmental Microbiology | 1998
Stefan Juretschko; Gabriele Timmermann; Markus Schmid; Karl-Heinz Schleifer; Andreas Pommerening-Röser; Hans-Peter Koops; Michael Wagner