Diversity and seasonal changes of uncultured Planctomycetales in river biofilms.

Cell counts of planctomycetes showed that there were high levels of these organisms in the summer and low levels in the winter in biofilms grown in situ in two polluted rivers, the Elbe River and the Spittelwasser River. In this study 16S rRNA-based methods were used to investigate if these changes were correlated with changes in the species composition. Planctomycete-specific clone libraries of the 16S rRNA genes found in both rivers showed that there were seven clusters, which were distantly related to the genera Pirellula, Planctomyces, and Gemmata. The majority of the sequences from the Spittelwasser River were affiliated with a cluster related to Pirellula, while the majority of the clones from the Elbe River fell into three clusters related to Planctomyces and one deeply branching cluster related to Pirellula. Some clusters also contained sequences derived from freshwater environments worldwide, and the similarities to our biofilm clones were as high as 99.8%, indicating the presence of globally distributed freshwater clusters of planctomycetes that have not been cultivated yet. Community fingerprints of planctomycete 16S rRNA genes were generated by temperature gradient gel electrophoresis from Elbe River biofilm samples collected monthly for 1 year. Sixteen bands were identified, and for the most part these bands represented organisms related to the genus Planctomyces. The fingerprints showed that there was strong seasonality of most bands and that there were clear differences in the summer and the winter. Thus, seasonal changes in the abundance of Planctomycetales in river biofilms were coupled to shifts in the community composition.

Isolation and biodiversity of hitherto undescribed soil bacteria related to Bacillus niacini.

The hitherto largely not described phylogenetic neighborhood of Bacillus niacini has been explored by a comprehensive cultivation experiment and genomic variety studies. Previous culture-independent studies demonstrated that approximately 15% of all Bacillus 16S rDNA directly extracted from soils worldwide was affiliated to B. niacini. Seven different media were inoculated with soil suspensions in serial dilutions and incubated at different temperatures. Then, bacterial colonies were picked and analyzed by sequencing. A mineral medium with acetate as carbon source yielded a B. niacini rate of >3% of all picked colonies. Other media were less efficient but also successful. Applying this culturing approach, we succeeded in obtaining 64 isolates from different Dutch soils. The isolates turned out to be diverse, although closely related to B. niacini as revealed by 16S rDNA sequencing. Close matches with environmental clones were also found, thus demonstrating much more diversity beyond previously known 16S rDNA sequences. The rep-PCR fingerprinting method revealed a high genomic variety, redundancy could not be observed among our isolates. Hence, the hitherto neglected B. niacini lineage, apparently among the most abundant soil Bacillus, was accessible to our cultivation approach.

Diversity and seasonal variability of beta-Proteobacteria in biofilms of polluted rivers: analysis by temperature gradient gel electrophoresis and cloning.

The beta-subgroup of the Proteobacteria has been shown to be important in aquatic habitats and was investigated in depth here by molecular 16S rRNA techniques in biofilms of the Elbe River and its polluted tributary, the Spittelwasser River. The bacterial 16S rRNA genes were cloned from each site, screened for beta-proteobacterial clones and sequenced. River biofilm clones from both rivers grouped into 9 clusters (RBFs). RBFs 1, 2, and 3 fell into the recently described betaI cluster of cosmopolitan freshwater bacteria, where they represented new species related to Rhodoferax, Aquaspirillum, and Hydrogenophaga: RBFs 4 to 7 affiliated with Aquabacterium commune, Ideonella dechloratans, and Sphaerotilus natans, respectively. The two remaining RBFs were uncultivated clusters, one of them being distantly related to Gallionella ferruginea. Seasonal changes in the relative intensity of the beta-proteobacterial 16S rRNA genes of biofilms harvested monthly for 1 year were determined by specific amplification and separation by temperature gradient gel electrophoresis (TGGE). Bands were identified by comparison of clones to community fingerprints by TGGE. Eight of 13 identified bands were shared by both habitats but showed different relative abundance and seasonal variability in the two rivers, probably caused by differences in temperature and pollutants. The data indicate new not-yet-cultivated clusters of river biofilm organisms, some of them probably distributed globally. They confirm the importance of certain known freshwater genera in river biofilms. The high phylogenetic resolution obtained by clone library analysis combined with the high temporal resolution obtained by TGGE suggest that the observed microdiversity in the river biofilm clone libraries might be caused by phylogenetically closely related microbial populations which are adapted to ecological parameters.

Molecular quantification of genes encoding for green-fluorescent proteins.

A quantitative PCR approach is presented to analyze the amount of recombinant green fluorescent protein (gfp) genes in environmental DNA samples. The quantification assay is a combination of specific PCR amplification and temperature gradient gel electrophoresis (TGGE). Gene quantification is provided by a competitively coamplified DNA standard constructed by point mutation PCR. A single base difference was introduced to achieve a suitable migration difference in TGGE between the original target DNA and the modified standard without altering the PCR amplification efficiency. This competitive PCR strategy is a highly specific and sensitive way to monitor recombinant DNA in environments like the efflux of a biotechnological plant.

A Methylobacterium-like organism from algal crusts covering silicone rubber electric insulators in Africa.

AIMS: The primary goals of this study were to isolate, identify and characterize culturable bacteria living in a close association with microalgae within green crusts covering silicone rubber electric insulators in Tanzania. METHODS AND RESULTS: Twenty-four bacterial colonies were isolated from an Apatococcus crust. Characterization by statistical analyses of total cellular protein profiles demonstrated that they were highly similar to one another. Final identification was achieved using 16S rDNA sequencing and fatty acid methyl ester profiling. These analyses revealed the presence of microbes with high similarity to Methylobacterium radiotolerans. The selected isolate, A1, displayed strong inhibitory activity against Rhizoctonia solani and was found to be resistant to relatively high concentrations of zinc in the growth medium. CONCLUSIONS: This study revealed the presence of M. radiotolerans bacteria in a novel environment--within algal crusts formed on electrical insulators in Africa. Moreover, this bacterium was found to be a predominant culturable species within those complex algal-microbial associations. The isolate also shared some traits of biotechnological importance with other members of the Methylobacterium genus. SIGNIFICANCE AND IMPACT OF THE STUDY: The data presented provide a valuable contribution concerning the formation and function of associations between green microalgae and bacteria. This study also provides some information about the utility of bacteria from the genus Methylobacterium in biotechnological applications, such as biocontrol of rhizoctoniosis and bioremediation of heavy metal-contaminated soils.

The microbial diversity in picoplankton enrichment cultures: a molecular screening of marine isolates.

Picoplankton bacteria from a North Sea water sample were cultured under a variety of different conditions (nutrients, temperature, light, agitation, adhesion). Fluorescent in situ hybridization (FISH) analysis of the enrichments showed complex communities which were dominated by gamma-Proteobacteria or beta-Proteobacteria, followed by alpha-Proteobacteria and bacteria from the Cytophaga/Flavobacterium/Bacteroides (CFB) cluster. Among 410 isolates, a high degree of diversity was found, both with respect to colony color and morphology and with respect to genetic diversity. Isolated bacteria were classified into the main taxa by a special PCR approach, termed signature PCR (SIG-PCR). It was based on an oligo primer mixture targeting 16S rDNA which yielded PCR products of taxon-specific lengths. Again, gamma-Proteobacteria dominated (48%), followed by alpha-Proteobacteria (20%). beta-Proteobacteria were rarely isolated (eight strains of 410). The CFB cluster comprised the second largest phylum (14%), and 7.5% of all isolates belonged to the high-GC Gram-positives. Thus, isolated bacteria were representative of enrichment communities with the exception of the beta-Proteobacteria, which were detected in high abundance in certain enrichments by FISH but not isolated, and the high-GC Gram-positives, which were cultivated but not detected by FISH. A genomic fingerprinting technique, randomly amplified polymorphic DNA, showed that among 58 CFB isolates only 18 identical genotypes were found, and among the 84 alpha-Proteobacteria only eight identical genotypes were present. The data show the enormous diversity of cultivated bacteria from picoplankton enrichment cultures of one North Sea water sample, which is only a small fraction of the total picoplankton community.

Detection of small sequence differences using competitive PCR: molecular monitoring of genetically improved, mercury-reducing bacteria.

A quantitative PCR approach is presented to detect small genomic sequence differences for molecular quantification of recombinant DNA. The only unique genetic feature of the mercury-reducing, genetically improved Pseudomonas putida KT2442::mer73 available to distinguish it from its native mercury-resistant relatives is the DNA sequence crossing the border of the insertion site of the introduced DNA fragment. The quantification assay is a combination of specific PCR amplification and temperature gradient gel electrophoresis (TGGE). Gene quantification is provided by a competitively co-amplified DNA standard constructed by point mutation PCR. After computing the denaturation behavior of the target DNA stretch, a single base difference was introduced to achieve maximum migration difference in TGGE between the original target DNA and the modified standard without altering the PCR amplification efficiency. This competitive PCR strategy is a highly specific and sensitive way to detect small sequence differences and to monitor recombinant DNA in effluxes of biotechnological plants.

Long-Term Stability of Mercury-Reducing Microbial Biofilm Communities Analyzed by 16S-23S rDNA Interspacer Region Polymorphism.

The composition of mercury-reducing communities in two bioreactors retaining Hg(II) from chloralkali electrolysis wastewater for 485 days was analyzed based on effluent community DNA. Packed bed bioreactors with lava chips as carrier of the biofilm were inoculated with nine Hg(II)-resistant isolates that belonged to the alpha and gamma subdivisions of the proteobacteria. A rapid DNA-fingerprinting method was applied, using the intergenic spacer region (ISR) of the 16S-23S rDNA for analysis of the community composition. This allowed discrimination of the inoculum strains down to subspecies level. A merA specific PCR permitted the discrimination of the community's merA genes. During the 485 days of operation, the bioreactors were exposed to various physical stresses (mixing, gas bubbles, temperature increase up to 41 degrees C, increased flow velocity) and repeated high mercury inflow concentrations, resulting in reduced bioreactor performance and decreased culturable cell numbers in the reactor effluent. Nevertheless, the composition of the microbial community remained rather stable throughout the investigated time period. Of the inoculum strains, two could be detected throughout, whereas three were sometimes present with varying periods of nondetection. Two inoculum strains were only detected within the first month. Two strains of gamma-proteobacteria that were able to reduce ionic mercury invaded the bioreactor community. They did not outcompete established strains and had no negative effect on the Hg(II)-retention activity of the bioreactors. The community comprised diverse merA genes. The abundance of merA genes matched the abundance of their respective strains as confirmed by ISR community analysis. The continuously high selection pressure for mercury resistance maintained a stable and highly active mercury-reducing microbial community within the bioreactors.

Microbiology of the stalactites from Grotta dei Cervi, Porto Badisco, Italy.

The active stalactites from Grotta dei Cervi, Porto Badisco, southeastern Italy, were sampled to investigate the microbial communities present in these speleothems. Sampling was carried out in a transect about 150 m long in the central gallery, where numerous Gram-positive bacteria were isolated. Actinomycetes of the genus Streptomyces were the most abundant, followed by members of the genus Bacillus. Further isolates were assigned to the genera Amycolatopsis, Arthrobacter; Agromyces. Micrococcus, Nocardiopsis and Rhodococcus of the order Actinomycetales. The ability of actinomycetes to colonize subterranean environments is discussed.

Spatial distribution of 16S rRNA levels from uncultured acidobacteria in soil.

The activity of uncultured acidobacteria was monitored in Dutch grassland soils by quantifying their ribosomes. These bacteria were detectable by five different 16S rRNA RT-PCR products in temperature gradient gel electrophoresis fingerprints. The ribosomes in surface soil samples were quantified with multiple competitive RT-PCR along a 1.5-km transect through the grassland. In total, the five members of the acidobacteria were estimated to contribute 4 x 1010 to 1 x 1011 ribosomes g soil-1, representing 7-14% of all bacterial ribosomes. These results indicate that ribosomes from acidobacteria are continuously present and abundant in soil and might contribute significantly to microbial activity in soil.

Response of a soil bacterial community to grassland succession as monitored by 16S rRNA levels of the predominant ribotypes.

The composition of predominant soil bacteria during grassland succession was investigated in the Dutch Drentse A area. Five meadows, taken out of agricultural production at different time points, and one currently fertilized plot represented different stages of grassland succession. Since fertilization and agricultural production were stopped, the six plots showed a constant decline in the levels of nutrients and vegetation changes. The activity of the predominant bacteria was monitored by direct ribosome isolation from soil and temperature gradient gel electrophoresis of reverse transcription (RT)-PCR products generated from bacterial 16S rRNA. The amounts of 16S rRNA of 20 predominant ribosome types per gram of soil were monitored via multiple competitive RT-PCR in six plots at different succession stages. These ribosome types mainly represented Bacillus and members of the Acidobacterium cluster and the alpha subclass of the class Proteobacteria. The 20 16S rRNA molecules monitored represented approximately half of all bacterial soil rRNA which was estimated by dot blot hybridizations of soil rRNA with the Bacteria probe EUB338. The grasslands showed highly reproducible and specific shifts of bacterial ribosome type composition. The total bacterial ribosome level increased during the first years after agricultural production and fertilization stopped. This correlated with the collapse of the dominant Lolium perenne population and an increased rate of mineralization of organic matter. The results indicate that there is a true correlation between the total activity of the bacterial community in soil and the amount of bacterial ribosomes.

Searching for predominant soil bacteria: 16S rDNA cloning versus strain cultivation.

The predominant bacteria in Dutch grassland soils, as identified by direct DNA extraction, PCR amplification of 16S rDNA and subsequent cloning and sequencing, were compared to the most abundant culturable bacteria. The 16S rDNAs of the strains from a comprehensive cultivation campaign were compared to some of the predominant cloned sequences by temperature gradient gel electrophoresis (TGGE). Four ribotypes were selected that were found to be abundant in the clone library: two closely related Bacillus-like sequences, a representative from the Verrucomicrobiales cluster and an uncultured member of the Actinobacteria. Using a variety of cultivation approaches a total of 659 pure cultures were isolated. Initially, approximately 8% of all isolates matched any of these ribotypes by same migration speed of their 16S rDNA amplicons on TGGE. However, sequencing analysis of matching isolates indicated that their 16S rDNA sequences were clearly different from the cloned sequences representing the fingerprint bands. Comparing the cultivation approach and the molecular 16S rDNA analysis from the same soil sample, there was no correlation between the collection of cultured strains and the 16S rDNA clone library.

Molecular monitoring of an uncultured group of the class Actinobacteria in two terrestrial environments.

Previous investigations of 16S rRNA clone libraries from a wide spectrum of mainly terrestrial origin have shown the worldwide distribution of several as yet uncultivated phylogenetically deeply rooting groups of Actinobacteria. From the percentage of the occurrence of these clones it was concluded that these organisms constitute a significant part of the bacterial microflora in these habitats. Two of the clone groups, previously designated group II and group III, were shown to be phylogenetically moderately related among each other. In order to more exactly determine the abundance of a representative of group II, clone DA079, the fraction of the organism's rRNA in total extracted rRNA was determined in several neighboring samples from Drentse A grassland soil (The Netherlands). The fraction ranged from 2.6 to 9.1%, averaging 5.5%. Based upon comparison of total rRNA and strain DA079-specific rRNA it was concluded that on the average 2 x 10(6) cells/g of this organism are present in the investigated soil. Attempts to isolate members of one of the 16S rDNA clone groups of Actinobacteria were made with samples from a German peat bog, in which the organisms had been detected previously. Molecular detection of group III organisms by a nested PCR approach was possible in different cultivation media. Despite the wide spectrum of growth media employed the isolation of group III strains failed.

Reviewing the DA001-files: a 16S rRNA chase on suspect #X99967, a Bacillus and Dutch underground activist.

A variant of 'the rRNA approach' on uncultured soil bacteria is discussed, which is mainly based on 16S rRNA rather than on genomic 16S rDNA. While the rDNA only reflects the presence of bacteria, the rRNA indicates much more the activity of bacteria. Hence, the presented strategy can indicate the involvement of uncultured bacteria to the metabolic activity of the total microbial community. The potentials and limitations of the applied techniques will be discussed: isolation of ribosomes from soil, temperature gradient gel electrophoresis, cloning and sequencing, and the verification of these data by V6 Southern blot hybridization, dot blot hybridization and in situ hybridization. By this and another novel rRNA quantification approach, the multiple competitive RT-PCR, it could be found that an uncultured Bacillus, recognized as ribotype DA001, contributes approximately 5-10% to all bacterial ribosomes in Dutch Drentse A grassland soils. These bacteria should be major operators of biogeochemical processes in soil.

Reductive dechlorination of tetrachloroethene to cis-1, 2-dichloroethene by a thermophilic anaerobic enrichment culture.

Thermophilic anaerobic biodegradation of tetrachloroethene (PCE) was investigated with various inocula from geothermal and nongeothermal areas. Only polluted harbor sediment resulted in a stable enrichment culture that converted PCE via trichloroethene to cis-1, 2-dichloroethene at the optimum temperature of 60 to 65 degrees C. After several transfers, methanogens were eliminated from the culture. Dechlorination was supported by lactate, pyruvate, fructose, fumarate, and malate as electron donor but not by H2, formate, or acetate. Fumarate and L-malate led to the highest dechlorination rate. In the absence of PCE, fumarate was fermented to acetate, H2, CO2, and succinate. With PCE, less H2 was formed, suggesting that PCE competed for the reducing equivalents leading to H2. PCE dechlorination, apparently, was not outcompeted by fumarate as electron acceptor. At the optimum dissolved PCE concentration of approximately 60 microM, a high dechlorination rate of 1.1 micromol h-1 mg-1 (dry weight) was found, which indicates that the dechlorination is not a cometabolic activity. Microscopic analysis of the fumarate-grown culture showed the dominance of a long thin rod. Molecular analysis, however, indicated the presence of two dominant species, both belonging to the low-G+C gram positives. The highest similarity was found with the genus Dehalobacter (90%), represented by the halorespiring organism Dehalobacter restrictus, and with the genus Desulfotomaculum (86%).

Application of temperature-gradient gel electrophoresis in taxonomy of coryneform bacteria.

Strains belonging to the Gram-positive coryneform soil bacteria were screened genotypically by temperature-gradient gel electrophoresis (TGGE). This method allows the sequence-specific separation of amplified fragments of 16S rRNA genes. A total of 115 reference strains representing the majority of the species of the genera Aeromicrobium, Agromyces, Arthrobacter, Aureobacterium, Cellulomonas, Curtobacterium, Nocardioides and Terrabacter were characterized. Depending on the genus investigated, the resolution limit of the technique appeared to be at the species or genus level or intermediate between the two. Aberrant TGGE profiles of strains within particular taxa revealed genomic heterogeneity and generic misclassification of nine strains studied. Beyond that, indications of 16S rRNA gene heterogeneity were found within the genomes of three Curtobacterium strains. The misclassifications revealed by TGGE were confirmed using whole-cell fatty acid methyl ester analysis and subsequent comparison with a database. TGGE has been demonstrated to be a useful tool in bacterial taxonomy.

Molecular analysis of ammonia-oxidizing bacteria of the beta subdivision of the class Proteobacteria in compost and composted materials.

Although the practice of composting animal wastes for use as biofertilizers has increased in recent years, little is known about the microorganisms responsible for the nitrogen transformations which occur in compost and during the composting process. Ammonia is the principle available nitrogenous compound in composting material, and the conversion of this compound to nitrite in the environment by chemolithotrophic ammonia-oxidizing bacteria is an essential step in nitrogen cycling. Therefore, the distribution of ammonia-oxidizing members of the beta subdivision of the class Proteobacteria in a variety of composting materials was assessed by amplifying 16S ribosomal DNA (rDNA) and 16S rRNA by PCR and reverse transcriptase PCR (RT-PCR), respectively. The PCR and RT-PCR products were separated by denaturing gradient gel electrophoresis (DGGE) and were identified by hybridization with a hierarchical set of oligonucleotide probes designed to detect ammonia oxidizer-like sequence clusters in the genera Nitrosospira and Nitrosomonas. Ammonia oxidizer-like 16S rDNA was detected in almost all of the materials tested, including industrial and experimental composts, manure, and commercial biofertilizers. A comparison of the DGGE and hybridization results after specific PCR and RT-PCR suggested that not all of the different ammonia oxidizer groups detected in compost are equally active. amoA, the gene encoding the active-site-containing subunit of ammonia monooxygenase, was also targeted by PCR, and template concentrations were estimated by competitive PCR. Detection of ammonia-oxidizing bacteria in the composts tested suggested that such materials may not be biologically inert with respect to nitrification and that the fate of nitrogen during composting and compost storage may be affected by the presence of these organisms.

In situ detection of an uncultured predominant bacillus in Dutch grassland soils.

Uncultured predominant Bacillus ribotype DA001 in Dutch Drentse A grassland soils, as revealed by its 16S rRNA sequence, was detected in soil by fluorescent whole-cell in situ hybridization. A prominent rod-shaped cell type was identified in bacterial suspensions prepared from soil by a multiple 16S rRNA probing approach.

Quantification of 16S rRNAs in complex bacterial communities by multiple competitive reverse transcription-PCR in temperature gradient gel electrophoresis fingerprints.

A novel approach was developed to quantify rRNA sequences in complex bacterial communities. The main bacterial 16S rRNAs in Drentse A grassland soils (The Netherlands) were amplified by reverse transcription (RT)-PCR with bacterium-specific primers and were separated by temperature gradient gel electrophoresis (TGGE). The primer pair used (primers U968-GC and L1401) was found to amplify with the same efficiency 16S rRNAs from bacterial cultures containing different taxa and cloned 16S ribosomal DNA amplicons from uncultured soil bacteria. The sequence-specific efficiency of amplification was determined by monitoring the amplification kinetics by kinetic PCR. The primer-specific amplification efficiency was assessed by competitive PCR and RT-PCR, and identical input amounts of different 16S rRNAs resulted in identical amplicon yields. The sequence-specific detection system used for competitive amplifications was TGGE, which also has been found to be suitable for simultaneous quantification of more than one sequence. We demonstrate that this approach can be applied to TGGE fingerprints of soil bacteria to estimate the ratios of the bacterial 16S rRNAs.