Community Composition of Marine Bacterioplankton Determined by 16S rRNA Gene Clone Libraries and Fluorescence In Situ Hybridization

We determined the compositions of bacterioplankton communities in surface waters of coastal California using clone libraries of 16S rRNA genes and fluorescence in situ hybridization (FISH) in order to compare the community structures inferred from these two culture-independent approaches. The compositions of two clone libraries were quite similar to those of clone libraries of marine bacterioplankton examined by previous studies. Clones from γ-proteobacteria comprised ca. 28% of the libraries, while approximately 55% of the clones came from α-proteobacteria, which dominated the clone libraries. The Cytophaga-Flavobacter group and three others each comprised 10% or fewer of the clone libraries. The community composition determined by FISH differed substantially from the composition implied by the clone libraries. The Cytophaga-Flavobacter group dominated 8 of the 11 communities assayed by FISH, including the two communities assayed using clone libraries. On average only 10% of DAPI (4′,6′-diamidino-2-phenylindole)-stained bacteria were detected by FISH with a probe for α-proteobacteria, but 30% of DAPI-stained bacteria appeared to be in the Cytophaga-Flavobacter group as determined by FISH. α-Proteobacteria were greatly overrepresented in clone libraries compared to their relative abundance determined by FISH, while the Cytophaga-Flavobacter group was underrepresented in clone libraries. Our data show that the Cytophaga-Flavobacter group can be a numerically dominant component of coastal marine bacterioplankton communities.     

Simultaneous Fluorescence In Situ Hybridization of mRNA and rRNA in Environmental Bacteria

We developed for Bacteria in environmental samples a sensitive and reliable mRNA fluorescence in situ hybridization (FISH) protocol that allows for simultaneous cell identification by rRNA FISH. Samples were carbethoxylated with diethylpyrocarbonate to inactivate intracellular RNases and pretreated with lysozyme and/or proteinase K at different concentrations. Optimizing the permeabilization of each type of sample proved to be a critical step in avoiding false-negative or false-positive results. The quality of probes as well as a stringent hybridization temperature were determined with expression clones. To increase the sensitivity of mRNA FISH, long ribonucleotide probes were labeled at a high density with cis-platinum-linked digoxigenin (DIG). The hybrid was immunocytochemically detected with an anti-DIG antibody labeled with horseradish peroxidase (HRP). Subsequently, the hybridization signal was amplified by catalyzed reporter deposition with fluorochrome-labeled tyramides. p-Iodophenylboronic acid and high concentrations of NaCl substantially enhanced the deposition of tyramides and thus increased the sensitivity of our approach. After inactivation of the antibody-delivered HRP, rRNA FISH was performed by following routine protocols. To show the broad applicability of our approach, mRNA of a key enzyme of aerobic methane oxidation, particulate methane monooxygenase (subunit A), was hybridized with different types of samples: pure cultures, symbionts of a hydrothermal vent bivalve, and even sediment, one of the most difficult sample types with which to perform successful FISH. By simultaneous mRNA FISH and rRNA FISH, single cells are identified and shown to express a particular gene. Our protocol is transferable to many different types of samples with the need for only minor modifications of fixation and permeabilization procedures.     

Specific Detection of Dehalococcoides Species by Fluorescence In Situ Hybridization with 16S rRNA-Targeted Oligonucleotide Probes

Dehalococcoides ethenogenes is the only known cultivated organism capable of complete dehalogenation of tetrachloroethene (PCE) to ethene. The prevalence of Dehalococcoides species in the environment and their association with complete dehalogenation of chloroethenes suggest that they play an important role in natural attenuation of chloroethenes and are promising candidates for engineered bioremediation of these contaminants. Both natural attenuation and bioremediation require reliable and sensitive methods to monitor the presence, distribution, and fate of the organisms of interest. Here we report the development of 16S rRNA-targeted oligonucleotide probes for Dehalococcoides species. The two designed probes together encompass 28 sequences of 16S rRNA genes retrieved from the public database. Except D. ethenogenes and CBDB1, all the others are environmental clones obtained from sites contaminated with chlorinated ethenes. They are all closely related and form a unique cluster of Dehalococcoides species. In situ hybridization of probe Dhe1259t with D. ethenogenes strain 195 and two enrichment cultures demonstrated the applicability of the probe to monitoring the abundance of active Dehalococcoides species in these enrichment samples.     

Double Labeling of Oligonucleotide Probes for Fluorescence In Situ Hybridization (DOPE-FISH) Improves Signal Intensity and Increases rRNA Accessibility

Fluorescence in situ hybridization (FISH) with singly labeled rRNA-targeted oligonucleotide probes is widely applied for direct identification of microbes in the environment or in clinical specimens. Here we show that a replacement of singly labeled oligonucleotide probes with 5′-, 3′-doubly labeled probes at least doubles FISH signal intensity without causing specificity problems. Furthermore, Cy3-doubly labeled probes strongly increase in situ accessibility of rRNA target sites and thus provide more flexibility for probe design.Since its introduction almost 20 years ago (2, 7), the identification of microorganisms by fluorescence in situ hybridization (FISH) with singly labeled rRNA-targeted probes has found widespread application in environmental and medical microbiology (1, 16). Despite being a methodologically robust technique, standard FISH suffers from several limitations (26) that may prevent successful detection of target microorganisms. One of the most frequently reported FISH problems is a low signal intensity of the detected microbes.Dim signals can be caused by a low cellular concentration of the target molecules (16S rRNA or 23S rRNA), a feature typically found in microorganisms thriving in oligotrophic environments (19). In order to increase the sensitivity of FISH and make it suitable for the detection of microbes with a low ribosome content, several strategies have been developed (6, 13, 18, 19, 21, 25), of which catalyzed reporter deposition (CARD)-FISH has found the most widespread application. The CARD-FISH technique (18, 21) uses horseradish peroxidase (HRP)-labeled oligonucleotide probes and tyramide signal amplification and achieves a 26- to 41-fold-higher sensitivity than standard FISH (11). However, CARD-FISH is rather expensive, requires enzymatic pretreatment to allow the large horseradish peroxidase-labeled probes to penetrate the target cells (17), and causes a dramatically altered melting behavior of the probes (11).Another frequently encountered FISH problem is the low in situ accessibility of many regions of the 16S and 23S rRNA for singly labeled probes (9, 10). Probes targeting such regions, which comprise about one-third of the Escherichia coli 16S rRNA (10), confer signals which are very dim or even below the detection limit. In order to avoid the selection of poorly accessible target sites for FISH probe design, a consensus 16S rRNA accessibility map for prokaryotes has been established based on detailed accessibility maps of two bacterial model organisms and one archaeal model organism (3). Considering this consensus map during probe design is recommended, but it excludes many probes with useful specificities from FISH applications. Furthermore, accessibility of many 16S and 23S rRNA target sites varies between different microorganisms and thus cannot yet be reliably predicted in silico. Accessibility of target sites to probes can be improved by the following: (i) use of unlabeled helper probes (8), (ii) elongation of the hybridization time up to 96 h (30), (iii) elongation of the probes, resulting in an altered ΔG°_overall (30), or (iv) use of peptide nucleic acid probes (reference 26 and references therein). However, all these strategies have specific limitations. For example, the design of helper probes is often impossible for probes with broader specificities, the extension of the hybridization time might lead to unspecific probe or dye binding in complex samples, probe elongation is often not possible without narrowing its specificity, and previously published oligonucleotide probes cannot simply be converted into the expensive peptide nucleic acid probes without a dramatically changed specificity (26).In principle, using oligonucleotide probes labeled with multiple fluorescent dyes should provide a simple means to increase the FISH signal intensity. The first experiments with multilabeled oligonucleotides were performed briefly after the introduction of the technique in microbiology but resulted in a pronounced increase in unspecific staining of nontarget organisms and/or an unexpected decrease in the signal intensity of the target organism which was attributed to quenching effects (28). Inconsistent with these data, Spear et al. (23) reported a successful increase in the signal-to-noise ratio of FISH-detected fungal cells by application of a multilabeled 18S rRNA-targeted oligonucleotide probe. In this work, we systematically evaluated the effect of 5′- and 3′-doubly labeled oligonucleotide probes (which were not included in the previously published study of multilabeled probes [28]) on the FISH signal intensity of Gram-negative and Gram-positive cells and studied the influence of double labeling on the in situ accessibility of rRNA target sites.The double-labeling-of-oligonucleotide-probes (DOPE)-FISH approach was initially tested with four bacterial pure cultures. These included the gamma- and betaproteobacterial Gram-negative species Escherichia coli (DSM 498) and Burkholderia cepacia (DSM 7288), respectively. In addition, the two Gram-positive bacteria Bacillus subtilis (DSM 10) and Listeria monocytogenes (strain LO28) were used. E. coli, B. cepacia, and B. subtilis were grown according to the DSMZ instructions until they reached their stationary growth phase and were fixed with paraformaldehyde (E. coli and B. cepacia) or ethanol (B. subtilis) as described elsewhere (5). L. monocytogenes strain LO28 was grown on brain heart infusion for 5 h and fixed with ethanol as outlined previously (27). The oligonucleotide probes EUB338 (targeting the 16S rRNA of most but not all bacteria), NonEUB338 (a nonsense probe), GAM42a (targeting the 23S rRNA of many members of the Gammaproteobacteria), and five E. coli-targeted probes with a low 16S rRNA accessibility (10) were obtained as singly and doubly labeled derivatives from Thermo Hybaid (Interactiva Division, Ulm, Germany). More information about the applied probes can be found at probeBase (14) and in the publication by Fuchs et al. (10). FISH was performed by following the standard protocol (5) under the conditions recommended for each probe (14). If not stated otherwise, all hybridizations were carried out with identical hybridization (4 h) and washing times (10 min), respectively. Probe-conferred signal intensities were quantified using a confocal laser scanning microscope (CLSM) (LSM 510 Meta; Zeiss, Oberkochen, Germany) and the software program daime (4) by analyzing at least 1,000 single cells per experiment. For these measurements, individual cells were detected by image segmentation via edge detection.Regardless of the dye used (Cy3, Cy5, or FLUOS) and the respective target organism analyzed, hybridization with the doubly labeled probe EUB338 resulted in an increase in the FISH signal compared to the use of the singly labeled probe EUB338. For three of the four reference organisms, this increase was about 2-fold, while an even stronger signal amplification was observed for B. cepacia (Fig. ​(Fig.1A).1A). Consequently, the distance between the two dye molecules in 18-nucleotide probes labeled at both ends is sufficient to avoid quenching. This is in contrast to oligonucleotides which are multiply labeled at one end or within the probe (28). Hybridization of the four reference organisms with the singly and doubly labeled derivatives of probe GAM42a confirmed these results and demonstrated that double labeling does not increase the background fluorescence of nontarget microorganisms (Fig. ​(Fig.1B).1B). Consistent with these findings, hybridization of all reference organisms with a doubly labeled nonsense probe (with FLUOS, Cy3, and Cy5) resulted in signals below the detection limit of the CLSM if standard FISH settings were applied (data not shown). We also evaluated the influence of the hybridization time on the signal intensity achievable by DOPE-FISH by varying the hybridization time between 1 and 6 h. In these experiments, no significant difference in DOPE-FISH signal intensities of the Gram-positive and Gram-negative reference organisms were observed, indicating that the additional label of the DOPE-FISH probes does not dramatically influence the hybridization kinetics (data not shown).Open in a separate windowFIG. 1.(A) Effect of double labeling of the EUB338 probe on the FISH signal intensity of four reference organisms. For each organism, the signal intensity conferred by a doubly labeled EUB338 probe was normalized to the signal intensity obtained with the same probe as a singly labeled derivative. Hatched, light-gray, and dark-gray bars depict results with the Cy3-, Cy5- and FLUOS-labeled probe EUB338, respectively. (B) Effect of double labeling of the probe Gam42a (in the presence of the unlabeled competitor probe Bet42a, specific for most members of the Betaproteobacteria [14]) on the FISH signal intensities of four reference organisms. For each organism, the signal intensity conferred by the doubly labeled probe Gam42a was normalized to the signal intensity obtained for E. coli with the same probe as a singly labeled derivative. Hatched, light-gray, and dark-gray bars depict results with the Cy3-, Cy5-, and FLUOS-labeled probe, respectively. The weak unspecific signals observed with some DOPE-FISH probes for B. subtilis are also detectable at comparable intensities with singly labeled probes (data not shown). (C) Cy3-doubly labeled but not FLUOS-doubly labeled probes improve in situ accessibility of E. coli 16S rRNA target sites. E. coli was hybridized with five probes representing brightness classes V and VI (3). FISH signals were recorded for Cy3-singly and -doubly labeled probes and normalized to the FISH signal obtained for E. coli with the singly labeled probe EUB338. Light-gray and dark-gray bars depict results with Cy3-singly and doubly labeled probes, respectively. FLUOS-singly and -doubly labeled probes showed no signal. For all panels, all experiments were performed in triplicate. Error bars indicate the standard deviation. ND, not detectable.Although DOPE-FISH worked well with all tested reference organisms, it should be noted that the Gram-positive species L. monocytogenes showed a signal amplification only if it was treated with lysozyme (according to Wagner et al. [27]) prior to the application of the doubly labeled probe. Without this enzymatic pretreatment, application of the singly labeled probe EUB338 resulted in a stronger signal than was seen with the doubly labeled probe EUB338, indicating that for some Gram-positive microorganisms with dense cell walls, double labeling impairs probe penetration. The observation that lysozyme treatment of L. monocytogenes also enhanced the probe-conferred signal of the singly labeled EUB338 probe confirmed that the cell wall of this organism after ethanol fixation is also not freely permeable to singly labeled probes (27; also data not shown). Enzymatic pretreatment of fixed microbial cells is also routinely applied for successful application of CARD-FISH, but since this method uses peroxidase-labeled probes which are much larger than DOPE-FISH probes, such treatments are also used for Gram-negative bacteria (11). Although many microorganisms are detectable by CARD-FISH with enhanced signal intensities, appropriate pretreatment protocols are not yet available for all microbes. For example, the sheathed filamentous methane oxidizer Crenothrix polyspora can easily be detected by standard FISH (24), but only very few cells within the filaments show a signal after CARD-FISH even if harsh permeabilization pretreatments are applied (see Fig. S1A in the supplemental material), a phenomenon known for sheathed microorganisms (12). In contrast, detection of all Crenothrix cells with more than 2-fold-increased signal intensity is readily possible by DOPE-FISH (see Fig. S1B).Prior research has demonstrated that probe labeling with horseradish peroxidase for CARD-FISH dramatically alters the melting behavior of oligonucleotide probes (11). Therefore, we recorded melting curves for Cy3-, Cy5-, and FLUOS-singly and -doubly labeled probes EUB338 and Gam42a by applying increasingly stringent conditions in the hybridization and wash steps (5). Interestingly, these experiments showed that the FLUOS singly labeled probes formed less-stable duplexes with their target sequences than the respective Cy3- and Cy5-labeled probes (Fig. ​(Fig.2).2). This effect, which is consistent with recent data on the stabilizing effect of various fluorophores on model probe-target duplexes (15), indicates that FLUOS-labeled FISH probes are generally applied under more-stringent conditions than Cy3- or Cy5-labeled probes. Cy3- and Cy5-doubly labeled probes displayed with their target organisms probe dissociation profiles similar to those of the respective FLUOS singly labeled probes, demonstrating that Cy3 or Cy5 double labeling does not further stabilize but rather moderately weakens the probe-target hybrid. Consistent with these findings, doubly FLUOS-labeled probes showed the lowest T_m (Fig. ​(Fig.2).2). Importantly, double labeling of probe GAM42a did not adversely affect mismatch discrimination, as shown by its dissociation profiles if in situ hybridizations were performed at various stringencies with B. cepacia containing a single mismatch in the probe target site of its 23S rRNA. (Fig. ​(Fig.2B).2B). These results indicate that the specificities of DOPE-FISH probes can be regarded as identical to those of standard singly labeled FISH probes.Open in a separate windowFIG. 2.Comparison of probe dissociation profiles of singly and doubly labeled probes. For each profile, the microscopic settings were adjusted for the lowest formamide concentration and subsequently kept constant. Dashed and solid lines represent sigmoid fittings for singly and doubly labeled probes, respectively. (A) Dissociation profiles of the singly and doubly labeled probe Gam42a with E. coli as the target organism. Empty circles, squares, and triangles represent data obtained with the Cy3-, Cy5-, and FLUOS-singly labeled probe GAM42a, respectively. Filled circles, squares, and triangles depict the data measured for the Cy3-, Cy5-, and FLUOS-doubly labeled probe GAM42a, respectively. (B) Dissociation profiles of the singly and doubly labeled probe Gam42a with B. cepacia as a nontarget organism having a single mismatch to probe GAM42a. Empty circles, squares, and triangles represent data obtained with the Cy3-, Cy5-, and FLUOS-singly labeled probe GAM42a, respectively. Filled circles, squares, and triangles depict the data measured for the Cy3-, Cy5-, and FLUOS-doubly labeled probe GAM42a, respectively. The melting curves for FLUOS-singly labeled and Cy5-doubly labeled probes are almost identical and thus overlap. In the presence of the unlabeled probe Bet42a as a competitor, no probe-conferred signal was recordable for both singly and doubly labeled GAM42a probes. (C) Dissociation profiles of the singly and doubly labeled probe EUB338 with E. coli as the target organism. Empty circles, squares, and triangles represent data obtained with the Cy3-, Cy5-, and FLUOS-singly labeled probe EUB338, respectively. Filled circles, squares, and triangles depict the data measured for the Cy3-, Cy5-, and FLUOS-doubly labeled probe EUB338, respectively. For all panels, error bars are not shown since they were always smaller than the symbols.In order to analyze whether the in situ accessibility of rRNA target sites to doubly labeled probes differs from that to those labeled with only one dye, we tested five probes targeting E. coli 16S rRNA. These probes were described as yielding only very dim signals with standard FISH as a consequence of limited target site accessibility and were thus assigned to the lowest brightness classes, V or VI (3, 10). Consistently, standard FISH with these five singly labeled probes (Cy3 and FLUOS) gave no or very weak signals (Fig. ​(Fig.1C).1C). Unexpectedly, however, Cy3-doubly labeled derivatives of these probes produced much brighter signals (Fig. ​(Fig.1C),1C), and for some of the probes (Eco468 and Eco1310), the DOPE-FISH signal intensity was higher than that measured for the Cy3-singly labeled probe EUB338 (Fig. ​(Fig.1C).1C). One could speculate that a Cy3 label at the 3′ end and not the double labeling might be responsible for the improved accessibility of rRNA target sites for Cy3 DOPE-FISH probes. However, since selected probes (Eco262, Eco468, and Eco1310) labeled with a single Cy3 molecule at the 3′ end did not result in increased fluorescence, this hypothesis can be rejected (data not shown). Interestingly, FLUOS-labeled DOPE-FISH probes did not show increased fluorescence, strongly indicating that the improved accessibility of Cy3 DOPE-FISH probes depends on the chemical structure of the fluorophore. This is consistent with the observation that Cy5 double labeling of the five E. coli probes also resulted in improved probe accessibilities (data not shown). While Cy3 and Cy5 double labeling decreases the probe-target duplex stability (Fig. ​(Fig.2),2), it apparently helps to resolve secondary or tertiary structures responsible for poor in situ accessibility of rRNA target sites. It is tempting to speculate that binding of Cy3 or Cy5 to double-stranded rRNA regions, analogous to the previously reported intercalation of certain cyanine class dyes in DNA (29) or other modes of nucleic acid binding by cyanine dyes (15), contributes to this phenomenon.The improved accessibility of rRNA target sites for Cy3 DOPE-FISH probes offers more flexibility for probe design because it enables the use of probes with excellent specificity but low standard FISH signal intensity for the successful in situ detection of microbes. This advantage of DOPE-FISH is nicely demonstrated by the probe Ntspa175 (5′-GAC CAG GAG CCG TAT GCG-3′), which targets the 16S rRNA (GenBank accession no. {"type":"entrez-nucleotide","attrs":{"text":"GU229885","term_id":"281398158","term_text":"GU229885"}}GU229885) of an uncultured nitrite oxidizer of the genus Nitrospira thriving in activated sludge. At 25% formamide in the standard FISH hybridization buffer (5), this probe is highly specific as demonstrated by Clone-FISH (22) using another activated sludge-derived 16S rRNA Nitrospira-like sequence with a single mismatch to probe Ntspa175 as a nontarget control (data not shown). Standard FISH of activated sludge with the Cy3-labeled probe Ntsp175, which targets the 175-to-193 region in the 16S rRNA, resulted in the detection of Nitrospira microcolonies with very variable FISH signal intensities. A considerable number of stained microcolonies had extremely dim FISH signals, indicating that these cells had a ribosome content too low to be reliably detectable by a standard FISH probe of a low brightness class. DOPE-FISH of the same sample with the Cy3-doubly labeled probe Ntspa175 led to a pronounced increase in signal intensity of the target cells (see Fig. S2 in the supplemental material) without causing increased background fluorescence if standard confocal-microscope settings were applied. In accordance with this observation, the relative biovolume-abundance of the detectable Ntspa175-stained population compared to the biovolume of those cells labeled by the Nitrospira genus-specific probe Ntspa662 (14) in the activated sludge increased by a factor of 1.81 ± 0.1 if a doubly labeled Ntspa175 probe was used (measurements made by the software package daime using confocal-microscope images as described previously [4]).In summary, DOPE-FISH with commercially available doubly labeled oligonucleotide probes is a straightforward modification of the standard FISH procedure which increases the signal intensity of standard FISH probes by at least a factor of 2 without causing specificity problems. Importantly, the influence of DOPE-FISH on the dissociation profile of probes is not larger than that caused by a dye switch from Cy3 to FLUOS if singly labeled probes are used for FISH. Thus, previously optimized hybridization and washing conditions for published probes can be applied for DOPE-FISH. Since DOPE-FISH unlocks previously inaccessible target sites on the rRNA, this new FISH approach offers more options for the design of specific probes, a task which becomes increasingly difficult with the rapid growth of rRNA databases (20).      

Unlabeled Helper Oligonucleotides Increase the In Situ Accessibility to 16S rRNA of Fluorescently Labeled Oligonucleotide Probes

Target site inaccessibility represents a significant problem for fluorescence in situ hybridization (FISH) of 16S rRNA with oligonucleotide probes. Here, unlabeled oligonucleotides (helpers) that bind adjacent to the probe target site were evaluated for their potential to increase weak probe hybridization signals in Escherichia coli DSM 30083^T. The use of helpers enhanced the fluorescence signal of all six probes examined at least fourfold. In one case, the signal of probe Eco474 was increased 25-fold with the use of a single helper probe, H440-2. In another case, four unlabeled helpers raised the FISH signal of a formerly weak probe, Eco585, to the level of the brightest monolabeled oligonucleotide probes available for E. coli. The temperature of dissociation and the mismatch discrimination of probes were not significantly influenced by the addition of helpers. Therefore, using helpers should not cause labeling of additional nontarget organisms at a defined stringency of hybridization. However, the helper action is based on sequence-specific binding, and there is thus a potential for narrowing the target group which must be considered when designing helpers. We conclude that helpers can open inaccessible rRNA regions for FISH with oligonucleotide probes and will thereby further improve the applicability of this technique for in situ identification of microorganisms.     

Fluorescence In Situ Hybridization in Studying the Human Genome

Physical chromosome mapping by fluorescence in situ hybridization (FISH) is among the major lines of research on the human genome (as well as genomes of numerous other organisms). To localize particular genes or anonymous DNA sequences on individual chromosomes or chromosome regions, FISH was developed in the late 1980s and early 1990s, when the International Human Genome Project and the Russian program Human Genome were launched. Now FISH continues to play a prominent part in studies of the human genome. The review considers the major steps of FISH development in Russia, with special emphasis on the key roles of the Institute of Cytology and Genetics (Novosibirsk) and Engelhardt Institute of Molecular Biology (Moscow). Physical mapping of human chromosomes 3 and 13 by FISH is described in detail. The acquisition of FISH in Russia contributed to the progress in the related fields such as comparative animal genomics (ZOOFISH) and studies of plant chromosomes.     

Cultivation-Independent, Semiautomatic Determination of Absolute Bacterial Cell Numbers in Environmental Samples by Fluorescence In Situ Hybridization

Fluorescence in situ hybridization (FISH) with rRNA-targeted oligonucleotide probes has found widespread application for analyzing the composition of microbial communities in complex environmental samples. Although bacteria can quickly be detected by FISH, a reliable method to determine absolute numbers of FISH-stained cells in aggregates or biofilms has, to our knowledge, never been published. In this study we developed a semiautomated protocol to measure the concentration of bacteria (in cells per volume) in environmental samples by a combination of FISH, confocal laser scanning microscopy, and digital image analysis. The quantification is based on an internal standard, which is introduced by spiking the samples with known amounts of Escherichia coli cells. This method was initially tested with artificial mixtures of bacterial cultures and subsequently used to determine the concentration of ammonia-oxidizing bacteria in a municipal nitrifying activated sludge. The total number of ammonia oxidizers was found to be 9.8 × 10⁷ ± 1.9 × 10⁷ cells ml⁻¹. Based on this value, the average in situ activity was calculated to be 2.3 fmol of ammonia converted to nitrite per ammonia oxidizer cell per h. This activity is within the previously determined range of activities measured with ammonia oxidizer pure cultures, demonstrating the utility of this quantification method for enumerating bacteria in samples in which cells are not homogeneously distributed.     

Detection and Enumeration of Methanotrophs in Acidic Sphagnum Peat by 16S rRNA Fluorescence In Situ Hybridization, Including the Use of Newly Developed Oligonucleotide Probes for Methylocella palustris

Two 16S rRNA-targeted oligonucleotide probes, Mcell-1026 and Mcell-181, were developed for specific detection of the acidophilic methanotroph Methylocella palustris using fluorescence in situ hybridization (FISH). The fluorescence signal of probe Mcell-181 was enhanced by its combined application with the oligonucleotide helper probe H158. Mcell-1026 and Mcell-181, as well as 16S rRNA oligonucleotide probes with reported group specificity for either type I methanotrophs (probes M-84 and M-705) or the Methylosinus/Methylocystis group of type II methanotrophs (probes MA-221 and M-450), were used in FISH to determine the abundance of distinct methanotroph groups in a Sphagnum peat sample of pH 4.2. M. palustris was enumerated at greater than 10⁶ cells per g of peat (wet weight), while the detectable population size of type I methanotrophs was three orders of magnitude below the population level of M. palustris. The cell counts with probe MA-221 suggested that only 10⁴ type II methanotrophs per g of peat (wet weight) were present, while the use of probe M-450 revealed more than 10⁶ type II methanotroph cells per g of the same samples. This discrepancy was due to the fact that probe M-450 targets almost all currently known strains of Methylosinus and Methylocystis, whereas probe MA-221, originally described as group specific, does not detect a large proportion of Methylocystis strains. The total number of methanotrophic bacteria detected by FISH was 3.0 (±0.2) × 10⁶ cells per g (wet weight) of peat. This was about 0.8% of the total bacterial cell number. Thus, our study clearly suggests that M. palustris and a defined population of Methylocystis spp. were the predominant methanotrophs detectable by FISH in an acidic Sphagnum peat bog.     

Detection and Differentiation of Chlamydiae by Fluorescence In Situ Hybridization

Chlamydiae are important pathogens of humans and animals but diagnosis of chlamydial infections is still hampered by inadequate detection methods. Fluorescence in situ hybridization (FISH) using rRNA-targeted oligonucleotide probes is widely used for the investigation of uncultured bacteria in complex microbial communities and has recently also been shown to be a valuable tool for the rapid detection of various bacterial pathogens in clinical specimens. Here we report on the development and evaluation of a hierarchic probe set for the specific detection and differentiation of chlamydiae, particularly C. pneumoniae, C. trachomatis, C. psittaci, and the recently described chlamydia-like bacteria comprising the novel genera Neochlamydia and Parachlamydia. The specificity of the nine newly developed probes was successfully demonstrated by in situ hybridization of experimentally infected amoebae and HeLa 229 cells, including HeLa 229 cells coinfected with C. pneumoniae and C. trachomatis. FISH reliably stained chlamydial inclusions as early as 12 h postinfection. The sensitivity of FISH was further confirmed by combination with direct fluorescence antibody staining. In contrast to previously established detection methods for chlamydiae, FISH was not susceptible to false-positive results and allows the detection of all recognized chlamydiae in one single step.     

Flow Sorting of Marine Bacterioplankton after Fluorescence In Situ Hybridization

We describe an approach to sort cells from coastal North Sea bacterioplankton by flow cytometry after in situ hybridization with rRNA-targeted horseradish peroxidase-labeled oligonucleotide probes and catalyzed fluorescent reporter deposition (CARD-FISH). In a sample from spring 2003 >90% of the cells were detected by CARD-FISH with a bacterial probe (EUB338). Approximately 30% of the microbial assemblage was affiliated with the Cytophaga-Flavobacterium lineage of the Bacteroidetes (CFB group) (probe CF319a), and almost 10% was targeted by a probe for the β-proteobacteria (probe BET42a). A protocol was optimized to detach cells hybridized with EUB338, BET42a, and CF319a from membrane filters (recovery rate, 70%) and to sort the cells by flow cytometry. The purity of sorted cells was >95%. 16S rRNA gene clone libraries were constructed from hybridized and sorted cells (S-EUB, S-BET, and S-CF libraries) and from unhybridized and unsorted cells (UNHYB library). Sequences related to the CFB group were significantly more frequent in the S-CF library (66%) than in the UNHYB library (13%). No enrichment of β-proteobacterial sequence types was found in the S-BET library, but novel sequences related to Nitrosospira were found exclusively in this library. These bacteria, together with members of marine clade OM43, represented >90% of the β-proteobacteria in the water sample, as determined by CARD-FISH with specific probes. This illustrates that a combination of CARD-FISH and flow sorting might be a powerful approach to study the diversity and potentially the activity and the genomes of different bacterial populations in aquatic habitats.     

Quantification of Uncultured Ruminococcus obeum-Like Bacteria in Human Fecal Samples by Fluorescent In Situ Hybridization and Flow Cytometry Using 16S rRNA-Targeted Probes

A 16S rRNA-targeted probe was designed and validated in order to quantify the number of uncultured Ruminococcus obeum-like bacteria by fluorescent in situ hybridization (FISH). These bacteria have frequently been found in 16S ribosomal DNA clone libraries prepared from bacterial communities in the human intestine. Thirty-two reference strains from the human intestine, including a phylogenetically related strain and strains of some other Ruminococcus species, were used as negative controls and did not hybridize with the new probe. Microscopic and flow cytometric analyses revealed that a group of morphologically similar bacteria in feces did hybridize with this probe. Moreover, it was found that all hybridizing cells also hybridized with a probe specific for the Clostridium coccoides-Eubacterium rectale group, a group that includes the uncultured R. obeum-like bacteria. Quantification of the uncultured R. obeum-like bacteria and the C. coccoides-E. rectale group by flow cytometry and microscopy revealed that these groups comprised approximately 2.5 and 16% of the total community in fecal samples, respectively. The uncultured R. obeum-like bacteria comprise about 16% of the C. coccoides-E. rectale group. These results indicate that the uncultured R. obeum-like bacteria are numerically important in human feces. Statistical analysis revealed no significant difference between the microscopic and flow cytometric counts and the different feces sampling times, while a significant host-specific effect on the counts was observed. Our data demonstrate that the combination of FISH and flow cytometry is a useful approach for studying the ecology of uncultured bacteria in the human gastrointestinal tract.     

Fluorescence In Situ Hybridization and Spectral Imaging of Coral-Associated Bacterial Communities

Microbial communities play important roles in the functioning of coral reef communities. However, extensive autofluorescence of coral tissues and endosymbionts limits the application of standard fluorescence in situ hybridization (FISH) techniques for the identification of the coral-associated bacterial communities. This study overcomes these limitations by combining FISH and spectral imaging.     

荧光原位杂交技术在医学微生物学中的应用

以16S rRNA 为靶序列的寡核苷酸探针荧光原位杂交技术已广泛应用于分析复杂环境中的微生物群落构成,包括监测和鉴定病原微生物以及未被培养微生物．通过对临床样品中微生物细胞的检测能提供微生物在人体中的种类、数量和空间分布等信息．其结果快速准确,较之传统的病原微生物诊断方法具有明显的优越性,在临床应用中有广泛的前景．     

In Situ Detection of Freshwater Fungi in an Alpine Stream by New Taxon-Specific Fluorescence In Situ Hybridization Probes

New rRNA-targeting oligonucleotide probes permitted the fluorescence in situ hybridization (FISH) identification of freshwater fungi in an Austrian second-order alpine stream. Based on computer-assisted comparative sequence analysis, nine taxon-specific probes were designed and evaluated by whole-fungus hybridizations. Oligonucleotide probe MY1574, specific for a wide range of Eumycota, and the genus (Tetracladium)-specific probe TCLAD1395, as well as the species-specific probes ALacumi1698 (Alatospora acuminata), TRIang322 (Tricladium angulatum), and Alongi340 (Anguillospora longissima), are targeted against 18S rRNA, whereas probes TmarchB10, TmarchC1_1, TmarchC1_2, and AlongiB16 are targeted against the 28S rRNA of Tetracladium marchalianum and Anguillospora longissima, respectively. After 2 weeks and 3 months of exposure of polyethylene slides in the stream, attached germinating conidia and growing hyphae of freshwater fungi were accessible for FISH. Growing hyphae and germinating conidia on leaves and in membrane cages were also visualized by the new FISH probes.     

Design and Performance of a 16S rRNA-Targeted Oligonucleotide Probe for Detection of Members of the Genus Bdellovibrio by Fluorescence In Situ Hybridization

A 16S rRNA-targeted, Cy3-labeled oligonucleotide probe was designed to detect members of the genus Bdellovibrio by fluorescence in situ hybridization. Specific hybridization conditions were established; however, the detection of bdellovibrios in environmental samples required enrichment, confirming that Bdellovibrio spp. are not present in large numbers in the environment.     

Simple Method for Fluorescence DNA In Situ Hybridization to Squashed Chromosomes

DNA in situ hybridization (DNA ISH) is a commonly used method for mapping sequences to specific chromosome regions. This approach is particularly effective at mapping highly repetitive sequences to heterochromatic regions, where computational approaches face prohibitive challenges. Here we describe a streamlined protocol for DNA ISH that circumvents formamide washes that are standard steps in other DNA ISH protocols. Our protocol is optimized for hybridization with short single strand DNA probes that carry fluorescent dyes, which effectively mark repetitive DNA sequences within heterochromatic chromosomal regions across a number of different insect tissue types. However, applications may be extended to use with larger probes and visualization of single copy (non-repetitive) DNA sequences. We demonstrate this method by mapping several different repetitive sequences to squashed chromosomes from Drosophila melanogaster neural cells and Nasonia vitripennis spermatocytes. We show hybridization patterns for both small, commercially synthesized probes and for a larger probe for comparison. This procedure uses simple laboratory supplies and reagents, and is ideal for investigators who have little experience with performing DNA ISH.     

Protocol for Rapid Fluorescence In Situ Hybridization of Bacteria in Cryosections of Microarthropods

A protocol was developed to detect bacteria inhabiting microarthropods by means of small-subunit rRNA-targeted fluorescence in situ hybridization and microscopy. The protocol is based on cryosections of whole specimens. In contrast to more commonly applied paraffin-embedding techniques, the protocol is quicker and reduces the number of manipulations which might damage the microscopic material. The method allowed the study of the bacterial colonization of Folsomia candida (Collembola) and the detection of bacteria in both the gut and tissue.     

Automated Enumeration of Groups of Marine Picoplankton after Fluorescence In Situ Hybridization

We describe here an automated system for the counting of multiple samples of double-stained microbial cells on sections of membrane filters. The application integrates an epifluorescence microscope equipped with motorized z-axis drive, shutters, and filter wheels with a scanning stage, a digital camera, and image analysis software. The relative abundances of specific microbial taxa are quantified in samples of marine picoplankton, as detected by fluorescence in situ hybridization (FISH) and catalyzed reporter deposition. Pairs of microscopic images are automatically acquired from numerous positions at two wavelengths, and microbial cells with both general DNA and FISH staining are counted after object edge detection and signal-to-background ratio thresholding. Microscopic fields that are inappropriate for cell counting are automatically excluded prior to measurements. Two nested walk paths guide the device across a series of triangular preparations until a user-defined number of total cells has been analyzed per sample. A backup autofocusing routine at incident light allows automated refocusing between individual samples and can reestablish the focal plane after fatal focusing errors at epifluorescence illumination. The system was calibrated to produce relative abundances of FISH-stained cells in North Sea samples that were comparable to results obtained by manual evaluation. Up to 28 preparations could be analyzed within 4 h without operator interference. The device was subsequently applied for the counting of different microbial populations in incubation series of North Sea waters. Automated digital microscopy greatly facilitates the processing of numerous FISH-stained samples and might thus open new perspectives for bacterioplankton population ecology.     

Processing Deep-Sea Particle-Rich Water Samples for Fluorescence In Situ Hybridization: Consideration of Storage Effects, Preservation, and Sonication

Particles are often regarded as microniches of enhanced microbial production and activities in the pelagic ocean and are vehicles of vertical material transport from the euphotic zone to the deep sea. Fluorescence in situ hybridization (FISH) can be a useful tool to study the microbial community structures associated with these particles, and thus their ecological significance, yet an appropriate protocol for processing deep-sea particle-rich water samples is lacking. Some sample processing considerations are discussed in the present study, and different combinations of existing procedures for preservation, size fractionation sequential filtration, and sonication were tested in conjunction with FISH. Results from this study show that water samples should be filtered and processed within no more than 10 to 12 h after collection, or else preservation is necessary. The commonly used prefiltration formaldehyde fixation was shown to be inadequate for the rRNA targeted by FISH. However, prefiltration formaldehyde fixation followed by immediate freezing and postfiltration paraformaldehyde fixation yielded highly consistent cell abundance estimates even after 96 days or potentially longer storage. Size fractionation sequential filtration and sonication together enhanced cell abundance estimates by severalfold. Size fractionation sequential filtration effectively separated particle-associated microbial communities from their free-living counterparts, while sonication detached cells from particles or aggregates for more-accurate cell counting using epifluorescence microscopy. Optimization in sonication time is recommended for different specific types of samples. These tested and optimized procedures can be incorporated into a FISH protocol for sampling in deep-sea particle-rich waters.