The Development of Media Suitable for the Microorganisms Morphologically Resembling Planctomyces spp., Pirellula spp., and other Planctomycetales from Various Aquatic Habitats Using Dilute Media

Isolation of Gemmata-like and Isosphaera-like planctomycete bacteria from soil and freshwater

New cultured strains of the planctomycete division (order Planctomycetales) of the domain Bacteria related to species in the genera Gemmata and Isosphaera were isolated from soil, freshwater, and a laboratory ampicillin solution. Phylogenetic analysis of the 16S rRNA gene from eight representative isolates showed that all the isolates were members of the planctomycete division. Six isolates clustered with Gemmata obscuriglobus and related strains, while two isolates clustered with Isosphaera pallida. A double-membrane-bounded nucleoid was observed in Gemmata-related isolates but not in Isosphaera-related isolates, consistent with the ultrastructures of existing species of each genus. Two isolates from this study represent the first planctomycetes successfully cultivated from soil.

16S-23S rDNA intergenic spacer and 23S rDNA of anaerobic ammonium-oxidizing bacteria: implications for phylogeny and in situ detection

Recently, anaerobic ammonium-oxidizing bacteria (AAOB) were identified by comparative 16S rDNA sequence analysis as a novel, deep-branching lineage within the Planctomycetales. This lineage consists currently of only two, not yet culturable bacteria which have been provisionally described as Candidatus 'Brocadia anammoxidans' and Candidatus 'Kuenenia stuttgartiensis'. In this study, a large fragment of the rDNA operon, including the 16S rDNA, the intergenic spacer region (ISR) and approximately 2 000 bases of the 23S rDNA, was polymerase chain reaction (PCR) amplified, cloned and sequenced from both AAOB. The retrieved 16S rDNA sequences of both species contain an insertion at helix 9 with a previously overlooked pronounced secondary structure (new subhelices 9a and 9b). This insertion, which is absent in all other known prokaryotes, is detectable by fluorescence in situ hybridization (FISH) and thus present in the mature 16S rRNA. In contrast with the genera Pirellula, Planctomyces and Gemmata that possess unlinked 16S and 23S rRNA genes, both AAOB have the respective genes linked together by an ISR of approximately 450 bp in length. Phylogenetic analysis of the obtained 23S rRNA-genes confirmed the deep branching of the AAOB within the Planctomycetales and allowed the design of additional specific FISH probes. Remarkably, the ISR of the AAOB also could be successfully detected by FISH via simultaneous application of four monolabelled oligonucleotide probes. Quantitative FISH experiments with cells of Candidatus 'Brocadia anammoxidans' that were inhibited by exposure to oxygen for different time periods demonstrated that the concentration of transcribed ISR reflected the activity of the cells more accurately than the 16S or 23S rRNA concentration. Thus the developed ISR probes might become useful tools for in situ monitoring of the activity of AAOB in their natural environment.

Novel bacterial lineages at the (sub)division level as detected by signature nucleotide-targeted recovery of 16S rRNA genes from bulk soil and rice roots of flooded rice microcosms

Using a newly developed 16S rRNA gene (rDNA)-targeted PCR assay with proposed group specificity for planctomycetes, we examined anoxic bulk soil of flooded rice microcosms for the presence of novel planctomycete-like diversity. For comparison, oxic rice roots were included as an additional sample in this investigation. The bacterial diversity detectable by this PCR assay was assessed by using a combined approach that included terminal restriction fragment length polymorphism (T-RFLP) analysis and comparative sequence analysis of cloned 16S rDNA. T-RFLP fingerprint patterns generated from rice roots contained 12 distinct terminal restriction fragments (T-RFs). In contrast, the T-RFLP fingerprint patterns obtained from the anoxic bulk soil contained 33 distinct T-RFs, a clearly higher level of complexity. A survey of 176 bulk soil 16S rDNA clone sequences permitted correlation of 20 T-RFs with phylogenetic information. The other 13 T-RFs remained unidentified. The predominant T-RFs obtained from rice roots could be assigned to members of the genus Pirellula within the Planctomycetales, while most of the T-RFs obtained from the bulk soil corresponded to novel lines of bacterial descent. Using a level of 16S rDNA sequence dissimilarity to cultured microorganisms of approximately 20% as a threshold value, we detected 11 distinct bacterial lineages for which pure-culture representatives are not known. Four of these lineages could be assigned to the order Planctomycetales, while one lineage was affiliated with the division Verrucomicrobia and one lineage was affiliated with the spirochetes. The other five lineages either could not be assigned to any of the main lines of bacterial descent or clearly expanded the known diversity of division level lineages WS3 and OP3. Our results indicate the presence of bacterial diversity at a subdivision and/or division level that has not been detected previously by the so-called universal 16S rDNA PCR assays.

Characterization of the microbial community of lotic organic aggregates ('river snow') in the Elbe River of Germany by cultivation and molecular methods

Aerobic and anaerobic cultivation techniques, 16S rDNA-based phylogeny, and fluorescent in situ hybridization were used to describe the phylogenetic diversity and physiological versatility of lotic microbial aggregates ('river snow') obtained from the river Elbe. In the course of the year the 'river snow' community changed. It was characterized by a great bacterial diversity in spring, the predominant occurrence of algae in summer and reduction of the total bacterial cell count in autumn and winter. In all 'river snow' samples, more than 70% of the bacteria counted with the general DNA stain DAPI also hybridized with the Bacteria-specific probe EUB338. In situ analysis of the bacterial 'river snow' community with a comprehensive suite of specific rRNA-targeted probes revealed population dynamics to be governed by seasonal factors. During all seasons, beta-Proteobacteria constituted the numerically most important bacterial group forming up to 54% of the total cell counts. In contrast to this, the relative abundance of other major bacterial lineages ranged from 2% for the order Planctomycetales to 36% for Cytophaga-Flavobacteria. Cultivation of 'river snow' under aerobic and anaerobic conditions with a variety of different media resulted in the isolation of 40 new bacterial strains. Phenotypic and phylogenetic analyses revealed these new strains to be mostly unknown organisms affiliated to different bacterial phyla. Application of newly developed specific oligonucleotide probes proved the cultivated bacteria, including clostridia and the numerically abundant beta-Proteobacteria, as relevant in situ members of the 'river snow' community.

Bacterioplankton compositions of lakes and oceans: a first comparison based on fluorescence in situ hybridization

Fluorescence in situ hybridization (FISH) with rRNA-targeted oligonucleotide probes was used to investigate the phylogenetic composition of bacterioplankton communities in several freshwater and marine samples. An average of about 50% of the cells were detected by probes for the domains Bacteria and Archaea, and of these, about half could be identified at the subdomain level with a set of group-specific probes. Beta subclass proteobacteria constituted a dominant fraction in freshwater systems, accounting for 16% (range, 3 to 32%) of the cells, although they were essentially absent in the marine samples examined. Members of the Cytophaga-Flavobacterium cluster were the most abundant group detected in the marine systems, accounting for 18% (range, 2 to 72%) of the 4',6-diamidino-2-phenylindole (DAPI) counts, and they were also important in freshwater systems (7%, range 0 to 18%). Furthermore, members of the alpha and gamma subclasses of Proteobacteria as well as members of the Planctomycetales were detected in both freshwater and marine water in abundances <7%.

Monitoring a widespread bacterial group: in situ detection of planctomycetes with 16S rRNA-targeted probes

The group of planctomycetes represents a separate line of descent within the domain Bacteria. Two phylum-specific 16S rRNA-targeted oligonucleotide probes for planctomycetes have been designed, optimized for in situ hybridization and used in different habitats to detect members of the group in situ. The probes, named PLA46 and PLA886, are targeting all or nearly all members of the planctomycete line of descent. Planctomycetes could be detected in almost all samples examined, e.g. a brackish water lagoon, activated sludge, and other wastewater habitats. In situ probing revealed quite uniform morphology and spatial arrangement of the detected cells but profound differences in abundance ranging from less than 0.1% to several percentage of the total cells. Single coccoid cells with diameters between 1 and 2.5 microm were dominating in most samples with the exception of the lagoon, in which rosettes of pear-shaped cells were abundant. The planctomycetes showed generally no hybridization signals with the bacterial probe EUB338, which is in accordance with base changes in their 165 rRNA sequences. A discrete ultrastructure of planctomycete cells was suggested by double staining with rRNA-targeted probes and the DNA-binding dye 4',6-diamidino-2-phenylindole (DAPI). The probe-conferred fluorescence was distributed in a ring-shaped manner around a central DAPI spot. The two probes developed extend the existing set of group-specific rRNA-targeted probes and help to elucidate the basic composition of bacterial communities in a first step of differential analysis. In situ hybridization of environmental samples indicated widespread presence of planctomycetes in different ecosystems.

MICROBIAL DIVERSITY: Domains and Kingdoms

▪ Abstract  With the discovery of the eukaryote nucleus, all living organisms were neatly divided into prokaryotes, which lacked a nucleus, and eukaryotes, which possessed it. As data derived directly from the genome became available, it was clear that prokaryotes were comprised of two groups, Eubacteria and Archaebacteria. These were subsequently renamed at the new taxonomic level of Domain as Bacteria and Archaea, with the eukaryotes named as the Eucarya Domain. The interrelationships of the three Domains are still subject to discussion and evaluation, as is their monophyly. Further data, drawn from various protein sequences, suggest conflicting schemes, and resolution may not be straightforward. Additionally, Bacteria and Archaea as well as Eucarya are largely based on organisms already in culture. Investigation of the potentially enormous quantity of uncultured organisms in nature is likely to have as broad-ranging implications as the exploration of new protein sequences.

Physical map of the genome of Planctomyces limnophilus, a representative of the phylogenetically distinct planctomycete lineage

A physical map of the chromosome of Planctomyces limnophilus DSM 3776T was constructed by pulsed-field gel electrophoresis techniques. A total of 32 cleavage sites for the rare-cutting restriction endonucleases PacI, PmeI, and SwaI were located on the chromosome, which was shown to be circular and approximately 5.2 Mbp in size. An extrachromosomal element was detected but was found not to be cleaved by any of the enzymes used in the analysis of the chromosome. The order of the fragments on the chromosome was determined by hybridization of excised, labelled restriction fragments to Southern blots of pulsed-field gel electrophoresis-separated restriction digests. Seven genetic markers, rrs, rrl, atpD, tuf, gyrB, rpoD, and dnaK, on the chromosome were located by hybridization. Probes for all genetic markers were obtained by PCR. For five of these markers, probes were constructed by PCR with degenerate primers targeting conserved sequences. The arrangement of the genetic markers was compared with that found in other bacteria.