Application of rRNA-targeted oligonucleotide probes in biotechnology

Synergetic action between the rumen microbiota and bovine health

Host-rumen-microbe interactions are essential components of many physiological processes, and therefore can affect ruminant health. Classical knowledge of rumen microbiology is based on culture-dependent methodologies, which only account for 10-20% of the rumen bacterial communities. While, the advancement in DNA sequencing and bioinformatics platforms provide novel approaches to investigate the composition and dynamics of the rumen microbiota. Recent studies demonstrated that the ruminal ecosystem is highly diverse and harbors numerous microbial communities. The composition of these microbial communities are affected by various environmental factors such as nutrition and different management strategies. Disturbance in the microbial ecology of the rumen is associated with the development of various diseases. Despite the flow of recent rumen-based studies, rumen microbiota is still not fully characterized. This review provides an overview of recent efforts to characterize rumen microbiota and its potential role in rumen health and disease. Moreover, the recent effects of dietary interventions and probiotics on rumen microbiota are discussed.

In situ hybridization for rRNA sequences in anatomic pathology specimens, applications for fungal pathogen detection: a review

Fungal infections are a frequent occurrence in medical practice due to increasing numbers of immunosuppressed patients. New antifungal medications have been developed and it has become evident that different fungi require different treatments as some are intrinsically resistant to these drugs. Thus, it is imperative that pathologists recognize the limitations of histopathologic diagnosis regarding speciation of fungal infections and advocate for the use of different techniques that can help define the genus and species of the fungus present in the specimen they are studying. In this review we present the use of in situ hybridization as an important adjunct for the diagnosis of fungal diseases, the different techniques that have been used for fungal identification, and the limitations that these techniques have.

In situ hybridization for specific fungal organisms in acute invasive fungal rhinosinusitis

Acute invasive fungal rhinosinusitis (AIFRS) most commonly occurs in immunosuppressed patients. The identification of fungal subtypes is important for management, and cultures can be negative. We studied 55 specimens from 23 patients with AIFRS (Rhizopus sp, 6; Aspergillus sp, 8; Fusarium sp, 1; Alternaria sp, 1; and culture negative, 7) using in situ hybridization (ISH) with biotin-labeled oligonucleotide probes targeting Aspergillus sp, Fusarium sp, Rhizopus sp, and a sequence identified in dematiaceous fungi. Ribosomal RNA preservation was established by using a pan-fungal probe. Nucleic acid preservation was seen in 18 patients (33 specimens [60%]). ISH using the specific fungal probes highlighted the respective fungal organisms in all culture-positive cases with adequate negative controls. Of the 7 culture-negative AIFRS cases, 4 had preserved fungal sequences. Of these cases, 2 additional cases of Aspergillus and 1 additional case of dematiaceous species were identified. In our study, 60% of AIFRS cases had fungal nucleic acid preservation. ISH can effectively identify fungi in AIFRS. ISH for specific fungal pathogens may aid in species identification in specimens with negative cultures.

In situ hybridization for Coccidioides immitis 5.8S ribosomal RNA sequences in formalin-fixed, paraffin-embedded pulmonary specimens using a locked nucleic acid probe: a rapid means for identification in tissue sections

Coccidioides immitis/Coccidioides posadasii are common causes of pulmonary infection in certain geographic areas, and are highly infectious when working with culture isolates in the laboratory. Rapid techniques to accurately identify this pathogen in tissues may be of benefit for diagnosis and in limiting the exposure of laboratory personnel to this agent. Locked nucleic acids (LNA) are modified nucleotides in which a ribonucleoside is linked between the 2'-oxygen and the 4'-carbon atoms with a methylene unit. LNA oligonucleotides exhibit increased thermal stability and make excellent probes for in situ hybridization (ISH). In this study, ISH utilizing a biotin-labeled LNA probe targeting Coccidioides sp. ribosomal RNA sequences in 6 formalin-fixed, paraffin-embedded pulmonary tissue specimens from 6 patients with culture positive or histologic findings suggestive of Coccidioides sp. infection is described. The cultures of the pulmonary specimens confirmed C. immitis in 3 of 6 patients. The ISH procedure with the LNA probe was positive in all 6 cases, although the number of organisms that were highlighted varied from rare to numerous. ISH with a biotin-labeled DNA probe of the same sequence was positive in 4 of the 6 cases and the signal intensity and number of organisms was much less than that observed with the LNA probe. Negative control tissues containing a variety of different fungal pathogens including Aspergillus sp., Fusarium sp., Blastomyces dermatitidis, Candida sp, Histoplasma capsulatum, and Zygomyces did not hybridize with the LNA and DNA probes. ISH with an LNA oligonucleotide probe targeting Coccidioides sp. ribosomal RNA is useful for rapid ISH. ISH could be rapidly performed when fungal pathogens are observed in tissue but cultures are negative or have not been performed.

Differentiation of Fusarium from Aspergillus species by colorimetric in situ hybridization in formalin-fixed, paraffin-embedded tissue sections using dual fluorogenic-labeled LNA probes

Fusarium and Aspergillus are 2 genera of fungal pathogens that can result in devastating disease particularly in immunosuppressed hosts. In tissue sections, these organisms can be extremely difficult to distinguish from one another. To differentiate between these 2 pathogens, a rapid (<3 hours) ribosomal RNA (rRNA) in situ hybridization (ISH) protocol using dual fluorogenic-labeled oligonucleotide probes composed of a mixture of DNA and locked nucleic acids (LNAs) was developed. This assay was able to differentiate between Aspergillus and Fusarium in formalin-fixed, paraffin-embedded tissue sections. ISH targeting rRNA can be used to identify the species of fungal pathogens in surgical pathology material and may be useful when pathogens are histologically observed but cultures are negative or have not been performed. ISH with dual-labeled LNA probes may be useful for detecting a variety of fungal pathogens in formalin-fixed, paraffin-embedded tissue specimens.

Quantitative analysis of a high-rate hydrogen-producing microbial community in anaerobic agitated granular sludge bed bioreactors using glucose as substrate

Fermentative H(2) production microbial structure in an agitated granular sludge bed bioreactor was analyzed using fluorescence in situ hybridization (FISH) and polymerase chain reaction-denatured gradient gel electrophoresis (PCR-DGGE). This hydrogen-producing system was operated at four different hydraulic retention times (HRTs) of 4, 2, 1, and 0.5 h and with an influent glucose concentration of 20 g chemical oxygen demand/l. According to the PCR-DGGE analysis, bacterial community structures were mainly composed of Clostridium sp. (possibly Clostridium pasteurianum), Klebsiella oxytoca, and Streptococcus sp. Significant increase of Clostridium/total cell ratio (68%) was observed when the reactor was operated under higher influent flow rate. The existence of Streptococcus sp. in the reactor became more important when operated under a short HRT as indicated by the ratio of Streptococcus probe-positive cells to Clostridium probe-positive cells changing from 21% (HRT 4 h) to 38% (HRT 0.5 h). FISH images suggested that Streptococcus cells probably acted as seeds for self-flocculated granule formation. Furthermore, combining the inspections with hydrogen production under different HRTs and their corresponding FISH analysis indicated that K. oxytoca did not directly contribute to H(2) production but possibly played a role in consuming O(2) to create an anaerobic environment for the hydrogen-producing Clostridium.

Potential of a 16S rRNA-based taxonomic microarray for analyzing the rhizosphere effects of maize on Agrobacterium spp. and bacterial communities

Bacterial diversity is central to ecosystem sustainability and soil biological function, for which the role of roots is important. The high-throughput analysis potential of taxonomic microarray should match the breadth of bacterial diversity. Here, the power of this technology was evidenced through methodological verifications and analysis of maize rhizosphere effect based on a 16S rRNA-based microarray developed from the prototype of H. Sanguin et al. (Environ. Microbiol. 8:289-307, 2006). The current probe set was composed of 170 probes (41 new probes in this work) that targeted essentially the Proteobacteria. Cloning and sequencing of 16S rRNA amplicons were carried out on maize rhizosphere and bulk soil DNA. All tested clones that had a perfect match with corresponding probes were positive in the hybridization experiment. The hierarchically nested probes were reliable, but the level of taxonomic identification was variable, depending on the probe set specificity. The comparison of experimental and theoretical hybridizations revealed 0.91% false positives and 0.81% false negatives. The microarray detection threshold was estimated at 0.03% of a given DNA type based on DNA spiking experiments. A comparison of the maize rhizosphere and bulk soil hybridization results showed a significant rhizosphere effect, with a higher predominance of Agrobacterium spp. in the rhizosphere, as well as a lower prevalence of Acidobacteria, Bacteroidetes, Verrucomicrobia, and Planctomycetes, a new taxon of interest in soil. In addition, well-known taxonomic groups such as Sphingomonas spp., Rhizobiaceae, and Actinobacteria were identified in both microbial habitats with strong hybridization signals. The taxonomic microarray developed in the present study was able to discriminate and characterize bacterial community composition in related biological samples, offering extensive possibilities for systematic exploration of bacterial diversity in ecosystems.

Development and validation of a prototype 16S rRNA-based taxonomic microarray for Alphaproteobacteria

The microarray approach has been proposed for high throughput analysis of the microbial community by providing snapshots of the microbial diversity under different environmental conditions. For this purpose, a prototype of a 16S rRNA-based taxonomic microarray was developed and evaluated for assessing bacterial community diversity. The prototype microarray is composed of 122 probes that target bacteria at various taxonomic levels from phyla to species (mostly Alphaproteobacteria). The prototype microarray was first validated using bacteria in pure culture. Differences in the sequences of probes and potential target DNAs were quantified as weighted mismatches (WMM) in order to evaluate hybridization reliability. As a general feature, probes having a WMM > 2 with target DNA displayed only 2.8% false positives. The prototype microarray was subsequently tested with an environmental sample, which consisted of an Agrobacterium-related polymerase chain reaction amplicon from a maize rhizosphere bacterial community. Microarray results were compared to results obtained by cloning-sequencing with the same DNA. Microarray analysis enabled the detection of all 16S rRNA gene sequences found by cloning-sequencing. Sequences representing only 1.7% of the clone library were detected. In conclusion, this prototype 16S rRNA-based taxonomic microarray appears to be a promising tool for the analysis of Alphaproteobacteria in complex ecosystems.

Efficient procedure for purification of obligate intracellular Wolbachia pipientis and representative amplification of its genome by multiple-displacement amplification

Bacteria belonging to the genus Wolbachia are obligatory microendocytobionts that infect a variety of arthropods and a majority of filarial nematode species, where they induce reproductive alterations or establish a mutualistic symbiosis. Although two whole genome sequences of Wolbachia pipientis, for strain wMel from Drosophila melanogaster and strain wBm from Brugia malayi, have been fully completed and six other genome sequencing projects are ongoing (http://www.genomesonline.org/index.cgi?want=Prokaryotic+Ongoin), genetic analyses of these bacteria are still scarce, mainly due to the inability to cultivate them outside of eukaryotic cells. Usually, a large amount of host tissue (a thousand individuals, or about 10 g) is required in order to purify Wolbachia and extract its DNA, which is often recovered in small amounts and contaminated by host cell DNA, thus hindering genomic studies. In this report, we describe an efficient and reliable procedure to representatively amplify the Wolbachia genome by multiple-displacement amplification from limited infected host tissue (0.2 g or 2 x 10(7) cells). We obtained sufficient amounts (8 to 10 microg) of DNA of suitable quality for genomic studies, and we demonstrated that the amplified DNA contained all of the Wolbachia loci targeted. In addition, our data indicated that the genome of strain wRi, an obligatory endosymbiont of Drosophila simulans, shares a similar overall architecture with its relative strain wMel.

Quenched autoligation probes allow discrimination of live bacterial species by single nucleotide differences in rRNA

Quenched autoligation (QUAL) probes are a class of self-reacting nucleic acid probes that give strong fluorescence signal in the presence of fully complementary RNAs and selectivity against single nucleotide differences in solution. Here, we describe experiments designed to test whether QUAL probes can discriminate between bacterial species by the detection of small differences in their 16S rRNA sequences. Probes were introduced into live cells using small amounts of detergent, thus eliminating the need for fixation, and fluorescence signal was monitored both by microscopy and by flow cytometry without any washing steps. The effects of probe length, modified backbone, probe concentration and growth state of the bacteria were investigated. The data demonstrate specific fluorescence discrimination between three closely related bacteria, Escherichia coli, Salmonella enterica and Pseudomonas putida, based on single nucleotide differences in their 16S rRNA. Discrimination was possible with cells in mid-log phase or in lag phase. These results suggest that QUAL probes may be useful for rapid identification of microorganisms in laboratory and clinical settings.

Quenched probes for highly specific detection of cellular RNAs

Nucleic acid-based RNA detection is a promising field in molecular biotechnology that is leading to the rapid and accurate identification of microorganisms, diagnosis of infections and imaging of gene expression. The specificity of short synthetic DNA probes raises the hope of distinguishing small differences in sequence, ultimately achieving single nucleotide resolution. Recent work using quenched fluorescently labeled oligonucleotide probes as sensors for RNA in bacterial and human cells has overcome several difficult hurdles on the way to these goals, including delivery of probes to live cells, accessing RNA sites containing a high degree of secondary structure, and eliminating many sources of background. Two new classes of quenched oligonucleotide probes, molecular beacons and quenched auto-ligation probes, have shown the most promise for in situ RNA detection. High-specificity detection, at the single-nucleotide resolution level, is now possible in solution with these classes of probes. However, for applications in intact cells, signal and background issues still need to be addressed before the full potential of these methods is achieved.

Locked TASC probes for homogeneous sensing of nucleic acids and imaging of fixed E. coli cells

We have designed a second-generation TASC (target-assisted self-cleavage) probe. It is based on the switching-on of incorporated cis-acting DNAzyme activity upon the target-induced conformational change of the otherwise inactive off-target probes locked in an intrastrand base-paired hairpin geometry. With E. coli 16S ribosomal RNA-relevant oligonucleotides as targets, the locked TASC probe exhibits an allosteric factor of k(on)/k(off) = 65 and the sequence selectivity is high, in terms of single nucleotide difference, when particular sequence and length of targets are chosen. Preliminary experiments with fixed E. coli cells show that the locked TASC probe with a FRET pair can be used to image fixed E. coli cells.

Culture-independent microbial community analysis with terminal restriction fragment length polymorphism

Terminal restriction fragment length polymorphism is a polymerase chain reaction (PCR)-based technique that has been used to effectively interrogate microbial communities to determine the diversity of both phylogenetic and functional markers. It requires the isolation of community DNA and knowledge of the target sequence. PCR amplification, performed with fluorescently labeled primers, is followed with restriction digestion and size selection on automated sequencing systems. The fluorescent tag identifies the terminal fragment, and the length polymorphism of the terminal fragments reveals a fraction of the phylogenetic diversity within the target sequence. Because the technique has high-throughput capabilities, it performs well in surveys where a large number of samples must be interrogated to ascertain spatial or temporal changes in community structure.

Recent advances in removing phosphorus from wastewater and its future use as fertilizer (1997-2003)

Large quantities of phosphate present in wastewater is one of the main causes of eutrophication that negatively affects many natural water bodies, both fresh water and marine. It is desirable that water treatment facilities remove phosphorus from the wastewater before they are returned to the environment. Total removal or at least a significant reduction of phosphorus is obligatory, if not always fulfilled, in most countries. This comprehensive review summarizes the current status in phosphorus-removal technologies from the most common approaches, like metal precipitation, constructed wetland systems, adsorption by various microorganisms either in a free state or immobilized in polysaccharide gels, to enhanced biological phosphorus removal using activated sludge systems, and several innovative engineering solutions. As chemical precipitation renders the precipitates difficult, if not impossible, to recycle in an economical industrial manner, biological removal opens opportunities for recovering most of the phosphorus and beneficial applications of the product. This review includes the options of struvite (ammonium-magnesium-phosphate) and hydroxyapatite formation and other feasible options using, the now largely regarded contaminant, phosphorus in wastewater, as a raw material for the fertilizer industry. Besides updating our knowledge, this review critically evaluates the advantage and difficulties behind each treatment and indicates some of the most relevant open questions for future research.

Quenched auto-ligating DNAs: multicolor identification of nucleic acids at single nucleotide resolution

We describe the synthesis and study of multicolor quenched autoligating (QUAL) probes for identification and discrimination of closely related RNA and DNA sequences in solution and in bacteria. In these probes, a dabsyl quencher doubles as an activator in the oligonucleotide-joining reaction. The oligonucleotides remain dark until they bind at adjacent sites, and "light up" on nucleophilic displacement of the dabsyl probe by the phosphorothioate probe. Four fluorescent dye conjugates were prepared and tested with probes and targets that differ by one nucleotide. Experiments on polymer beads show clear color-based discrimination of DNAs added in solution. Two-color quenched probe pairs were then tested in the discrimination of 16S rRNA sequences in Escherichia coli. Single nucleotide resolution was achieved in the cells with green/red QUAL probes, allowing identification of a one-base sequencing error in the 16S rRNA database. Finally, QUAL probes were successfully applied in live bacterial cells. The method requires only incubation followed by fluorescence imaging, and requires no enzymes, added reagents, cross-linking, fixing, or washes. Because probes must bind side-by-side to generate signal, there is little or no interference from unintended protein binding, which can occur with other probe types. The results suggest that QUAL probes may be of general use in the detection and identification of sequences in solution, on microarrays, and in microorganisms.

Use of fluorochrome-labeled rRNA targeted oligonucleotide probe and tyramide signal amplification to improve sensitivity of fluorescence in situ hybridization

A tyramide signal amplification (TSA) system was used in combination with a conventional fluorochrome-labeled 16S rRNA oligonucleotide probe to increase the sensitivity of fluorescence in situ hybridization. TSA was performed after hybridization resulted in a low fluorescence signal intensity. In contrast to the horseradish peroxidase-tyramide signal amplification (HRP-TSA) system and biotin-tyramide signal amplification (biotin-TSA) system, no additional expensive probe labeling was required. A whole cell hybridization technique was used to compare the fluorescence signal obtained using a monolabeled probe with that obtained using the TSA system. The fluorescence signal of the probe obtained using the TSA system was much higher than that obtained using the monolabeled probe. The technique was successfully applied to the in situ detection of microbial communities in anaerobic sludge. It was demonstrated that TSA resulted in an increased in sensitivity, as the fluorescence signal intensity was much higher than that obtained using a conventional probe.

Fluorescent in situ hybridization analysis of open lactic acid fermentation of kitchen refuse using rRNA-targeted oligonucleotide probes

Reproducible amounts of lactic acid accumulate in minced kitchen refuse under open conditions with intermittent pH neutralization [Sakai et al., Food Sci. Technol. Res., 6, 140 (2000)]. Here, we showed that such pH-controlled open fermentation of kitchen refuse reproducibly resulted a selective proliferation of a major lactic acid bacterial (LAB) species. In one experiment, the predominant microorganisms isolated during the early phase (6 h) were Gammaproteobacteria. In contrast, those that predominated during the late phase (48 h) were always Lactobacillus plantarum in three independent experiments. To further quantify the microbial community within open lactic acid fermentation, we performed fluorescent in situ hybridization (FISH) analysis targeting 16S (23S) rRNA. We designed two new group-specific DNA probes: LAC722(L) was active for most LAB including the genera Lactobacillus, Pediococcus, Leuconostoc and Weisella, whereas Lplan477 was specific for L. plantarum and its related species. We then optimized sample preparation using lysozyme and hybridization conditions including temperature, as well as the formamide concentration and the salt concentration in the washing buffer. We succeeded in quantification of microorganisms in semi-solid, complex biological materials such as minced kitchen refuse by taking color microphotographs in modified RGB balance on pre-coated slides. FISH analysis of the fermentation of kitchen refuse indicated that control of the pH swing leads to domination by the LAB population in minced kitchen refuse under open conditions. We also confirmed that L. plantarum, which generates lactic acid in high quantities but with low optical activity, became the dominant microorganism in kitchen refuse during the late phase of open fermentation.

The microbiology of biological phosphorus removal in activated sludge systems

Activated sludge systems are designed and operated globally to remove phosphorus microbiologically, a process called enhanced biological phosphorus removal (EBPR). Yet little is still known about the ecology of EBPR processes, the microbes involved, their functions there and the possible reasons why they often perform unreliably. The application of rRNA-based methods to analyze EBPR community structure has changed dramatically our understanding of the microbial populations responsible for EBPR, but many substantial gaps in our knowledge of the population dynamics of EBPR and its underlying mechanisms remain. This review critically examines what we once thought we knew about the microbial ecology of EBPR, what we think we now know, and what still needs to be elucidated before these processes can be operated and controlled more reliably than is currently possible. It looks at the history of EBPR, the currently available biochemical models, the structure of the microbial communities found in EBPR systems, possible identities of the bacteria responsible, and the evidence why these systems might operate suboptimally. The review stresses the need to extend what have been predominantly laboratory-based studies to full-scale operating plants. It aims to encourage microbiologists and process engineers to collaborate more closely and to bring an interdisciplinary approach to bear on this complex ecosystem.

Imaging of RNA in bacteria with self-ligating quenched probes

We report on the application of a new class of oligonucleotide reporter probes, QUAL probes, that "light up" when a nucleophilic phosphorothioate probe binds adjacent to a dabsyl-quenched probe. These self-ligating DNA probes were used for sequence-specific detection of 16S rRNA in Escherichia coli cells. Strong fluorescence was observed only when the phosphorothioate and quenched dabsyl probes bind side-by-side on a 16S rRNA target. The results demonstrate the use of QUAL probes to detect specific RNA sequences in bacterial cells without enzymes and without washing steps.