Development and field application of a quantitative method for examining natural assemblages of protists with oligonucleotide probes.

A fluorescent in situ hybridization method that uses rRNA-targeted oligonucleotide probes for counting protists in cultures and environmental water samples is described. Filtration, hybridization, and enumeration of fixed cells with biotinylated eukaryote-specific probes and fluorescein isothiocyanate-conjugated avidin were performed directly on 0.4-microns-pore-size polycarbonate filters of Transwell cell culture inserts (Costar Corp., Cambridge, Mass.). Counts of various species of cultured protists by this probe hybridization method were not significantly different from counts obtained by the 4',6-diamidino-2-phenylindole (DAPI) and acridine orange (AO) staining methods. However, counts of total nanoplankton (TNAN) based on probe hybridizations in several field samples and in samples collected from a mesocosm experiment were frequently higher than TNAN counts obtained by staining with DAPI or AO. On the basis of these results, 25 to 70% of the TNAN determined with probes were not detectable by DAPI or AO staining. The underestimation of TNAN abundances in samples stained with DAPI or AO was attributed to the existence of small nanoplanktonic cells which could be detected with probes but not DAPI or AO and the difficulty associated with distinguishing DAPI- or AO-stained protists attached to or embedded in aggregates. We conclude from samples examined in this study that enumeration of TNAN with oligonucleotide probes provides estimates of natural TNAN abundances that are at least as high as (and in some cases higher than) counts obtained with commonly employed fluorochrome stains. The quantitative in situ hybridization method we have described here enables the direct enumeration of free-living protists in water samples with oligonucleotide probes. When combined with species-specific probes, this method will enable quantitative studies of the abundance and distribution of specific protistan taxa.     

PCR amplification of chromosome-specific DNA isolated from flow cytometry-sorted chromosomes.

We have established a method for amplifying and obtaining large quantities of chromosome-specific DNA by linker/adaptor ligation and polymerase chain reaction (PCR). Small quantities of DNA isolated from flow cytometry-sorted chromosomes 17 and 21 were digested with MboI, ligated to a linker/adaptor, and then subjected to 35 cycles of PCR. Using this procedure, 20 micrograms of chromosome-specific DNA can be obtained. Southern blot analysis using several DNA probes previously localized to chromosomes 17 and 21 indicated that these gene sequences were present in the amplified chromosome-specific DNA. A small quantity of the chromosome-specific DNA obtained from the first round of PCR amplification was used to amplify DNA for a second, third, and fourth round of PCR (30 cycles), and specific DNA sequences were still detectable. Fluorescence in situ hybridization using these chromosome-specific DNA probes clearly indicated the hybridization signals to the designated chromosomes. We showed that PCR-amplified chromosome 17-specific DNA can be used to detect nonrandom chromosomal translocation of t(15;17) in acute promyelocytic leukemia by fluorescence in situ hybridization.     

Nonradioactive labeling with chemically modified cytosine tails by the polymerase chain reaction.

We developed a modified nonradioactive method for the detection of DNA. This method makes use of the polymerase chain reaction for preparation of probes; that is, a DNA fragment inserted in the polylinker region of an M13 or pUC vector is amplified with primers that have a modified cytosine tail at the 5' terminus (C-tailed primers). By this method, large amounts of labeled probes can be obtained easily. After hybridization, modified cytosine tails can be detected immunologically. DNA labeled by this method could be used in plaque hybridization. We could detect 0.05 pg of dot-blotted labeled DNA in 30 min with an enzyme-catalyzed chemiluminescence reaction.     

Use of random amplified polymorphic DNA (RAPD) for generating specific DNA probes for microorganisms

We report the rapid generation of DNA probes for several Azospirillum strains. This method does not require any knowledge of the genetics and/or the molecular biology of the organism (genome) to be investigated. The procedure is based on the generation of random amplified polymorphic DNA (RAPD) fingerprints using primers with an embedded restriction site. The amplification product(s) peculiar to one strain or common to two or more strains can be purified, cloned, sequenced and used as molecular probes in hybridization experiments for the detection and identification of microorganisms. We have tested this methodology in the nitrogen-fixing bacterium Azospirillum by amplyfing the total DNA extracted from several Azospirillum strains. We have used amplification bands with different specificity as molecular probes in hybridization experiments performed on amplified DNA. Results obtained have demonstrated the usefulness of this methodology for Azospirillum. Its use in microbial ecology studies as a general strategy to generate specific DNA probes is also discussed.     

A method for cross-species gene expression analysis with high-density oligonucleotide arrays

DNA microarrays have been widely used in gene expression analysis of biological processes. Due to a lack of sequence information, the applications have been largely restricted to humans and a few model organisms. Presented within this study are results of the cross-species hybridization with Affymetrix human high-density oligonucleotide arrays or GeneChip® using distantly related mammalian species; cattle, pig and dog. Based on the unique feature of the Affymetrix GeneChip® where every gene is represented by multiple probes, we hypothesized that sequence conservation within mammals is high enough to generate sufficient signals from some of the probes for expression analysis. We demonstrated that while overall hybridization signals are low for cross-species hybridization, a few probes of most genes still generated signals equivalent to the same-species hybridization. By masking the poorly hybridized probes electronically, the remaining probes provided reliable data for gene expression analysis. We developed an algorithm to select the reliable probes for analysis utilizing the match/mismatch feature of GeneChip®. When comparing gene expression between two tissues using the selected probes, we found a linear correlation between the cross-species and same-species hybridization. In addition, we validated cross-species hybridization results by quantitative PCR using randomly selected genes. The method shown herein could be applied to both plant and animal research.     

LNA-modified oligonucleotides are highly efficient as FISH probes

Fluorescence in situ hybridization (FISH) is a highly useful technique with a wide range of applications including the delineation of complex karyotypes, prenatal diagnosis of aneuploidies, screening for diagnostic or prognostic markers in cancer cells, gene mapping and gene expression studies. However, it is still a fairly time-consuming method with limitations in both sensitivity and resolution. Locked Nucleic Acids (LNAs) constitute a novel class of RNA analogs that have an exceptionally high affinity towards complementary DNA and RNA. Substitution of DNA oligonucleotide probes with LNA has shown to significantly increase their thermal duplex stability as well as to improve the discrimination between perfectly matched and mismatched target nucleic acids. To exploit the improved hybridization properties of LNA oligonucleotides in FISH, we have designed several LNA substituted oligonucleotide probes specific to different human-specific repetitive elements, such as the classical satellite-2, telomere and alpha-satellite repeats. In the present study we show that LNA modified oligonucleotides are excellent probes in FISH, combining high binding affinity with short hybridization time.     

Cooperativity of paired oligonucleotide probes for microarray hybridization assays

Synthetic DNA probes attached to microarrays usually range in length from 25 to 70 nucleotides. There is a compromise between short probes with lower sensitivity, which can be accurately synthesized in higher yields, and long probes with greater sensitivity but lower synthesis yields. Described here are microarrays printed with spots containing a mixture of two short probes, each designed to hybridize at noncontiguous sites in the same targeted sequence. We have shown that, for a printed microarray, mixed probe spots containing a pair of 30mers show significantly greater hybridization than spots containing a single 30mer and can approach the amount of hybridization to spots containing a 60mer or a 70mer. These spots with mixed oligonucleotide probes display cooperative hybridization signals greater than those that can be achieved by either probe alone. Both the higher synthesis yields of short probes and the greater sensitivity of long oligonucleotides can be utilized. This strategy provides new design options for microarray hybridization assays to detect RNA abundance, RNA splice variants, or sequence polymorphisms.     

A reliable method for the use of oligonucleotides as probes in blot-hybridization experiments

We have developed a ligation and specificprimer radiolabeling method that allows the use of oligonucleotides as probes in blot-hybridization experiments. The major advantage of the protocol is that standard hybridization and washing conditions may be used and yield high signals and low background. The observed increase in the stability and intensity of the hybridization signals appears to result from both increased length and specific radioactivity of the hybridization probe.     

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.     

Towards quality control for DNA microarrays.

We present a framework for detecting probes in oligonucleotide microarrays that may add significant error to measurements in hybridization experiments. Four types of so-called degenerate probe behavior are considered: secondary structure formation, self-dimerization, cross-hybridization, and dimerization. The framework uses a well-established model for computing the free energy of nucleic acid sequence hybridization and a novel method for the detection of patterns in hybridization experiment data. Our primary result is the identification of unique patterns in hybridization experiment data that are shown to correlate with each type of degenerate probe behavior. A support function for identifying degenerate probes from a large set of hybridization experiments is given and some preliminary experimental results are given for the Affymetrix HuGeneFL GeneChip. Finally, we show a strong relationship between the Affymetrix discrimination measure for a probe and the free-energy estimate from theoretical models of hybridization. In particular, probes on the HuGeneFL GeneChip with high free-energy estimates (weak hybridization) have almost always approximately zero discrimination. The framework can be applied to any Affymetrix oligonucleotide array, and the software is made freely available to the community.     

Whole-cell hybridization of Methanosarcina cells with two new oligonucleotide probes.

Two new oligonucleotide probes targeting the 16S rRNA of the methanogenic genus Methanosarcina were developed. The probes have the following sequences (Escherichia coli numbering): probe SARCI551, 5'-GAC CCAATAATCACGATCAC-3', and probe SARCI645, 5'-TCCCGGTTCCAAGTCTGGC-3'. In situ hybridization with the fluorescently labelled probes required several modifications of standard procedures. Cells of Methanosarcina mazeii S-6 were found to lyse during the hybridization step if fixed in 3% formaldehyde and stored in 50% ethanol. Lysis was, however, not observed with cells fixed and stored in 1.6% formaldehyde-0.85% NaCl. Extensive autofluorescence of the cells was found upon hybridization in the presence of 5 mM EDTA, but successful hybridization could be obtained without addition of this compound. The mounting agent Citifluor AF1, often used in conjugation with the fluorochrome fluorescein, was found to wash the labelled probes out of the cells. Stable labelling could be obtained with rhodamine-labelled probes when the specimen was mounted in immersion oil, and high hybridization intensities of the Methanosarcina cells were found even in the presence of biomass from an anaerobic reactor. The inherent high autofluorescence of the biomass could be lowered by use of a highly specific narrow-band filter. The probes were found to be specific for Methanosarcina and useful for detection of this genus in samples from anaerobic reactors.     

Sensitive and specific detection of microRNAs by northern blot analysis using LNA-modified oligonucleotide probes

We describe here a new method for highly efficient detection of microRNAs by northern blot analysis using LNA (locked nucleic acid)-modified oligonucleotides. In order to exploit the improved hybridization properties of LNA with their target RNA molecules, we designed several LNA-modified oligonucleotide probes for detection of different microRNAs in animals and plants. By modifying DNA oligonucleotides with LNAs using a design, in which every third nucleotide position was substituted by LNA, we could use the probes in northern blot analysis employing standard end-labelling techniques and hybridization conditions. The sensitivity in detecting mature microRNAs by northern blots was increased by at least 10-fold compared to DNA probes, while simultaneously being highly specific, as demonstrated by the use of different single and double mismatched LNA probes. Besides being highly efficient as northern probes, the same LNA-modified oligonucleotide probes would also be useful for miRNA in situ hybridization and miRNA expression profiling by LNA oligonucleotide microarrays.     

A methacrylate embedding procedure developed for immunolocalization on plant tissues is also compatible with in situ hybridization.

A recently described method that uses methacrylate embedding of aldehyde fixed plant tissues allows the immunolabelling of a range of antigens (Baskin et al. 1992). We have tested whether the same embedding procedure is also compatible with in situ hybridization. For this purpose we have used 2- 5 μm sections of methacrylate embedded plantlets of Arabidopsis thaliana. After removal of the resin the sections were prepared for in situ hybridization following standard procedures. Three different digoxygenin (dig)-labelled probes were used, recognizing RNAs coding for the chlorophyll a/b binding protein cab-140, the β-tubulin tub5 and meri a member of the meri-5 family. Each of the probes shows the labelling pattern expected from the literature. Moreover, the method allows a good structural preservation of very fragile tissues, in contrast to paraffin embedding. We conclude that methacrylate embedding, allowing both immunolabelling and in situ hybridization with high resolution and structural preservation, offers a high potential for the functional analysis of genes and proteins in plant development. This is especially true for Arabidopsis thaliana, a widely used model species where it seems to be the method of choice.     

Multiplex polymerase chain reaction/membrane hybridization assay for detection of genetically modified organisms

To improve detection efficiency and result accuracy, four screening primer pairs, four identifying primer pairs, one common primer pair and corresponding probes were designed for the development of multiplex polymerase chain reaction/membrane hybridization assay (MPCR-MHA) for detection of the foreign genes insert in genetically modified organisms (GMOs). After detecting condition and parameter were optimized and determined, MPCR reactions were developed for amplifying several target genes simultaneously in one tube. Primers were labeled with biotin at the 5'-end; biotinylated MPCR products were detected by hybridization to the oligonucleotide probes immobilized on a membrane with subsequent colorimetric detection to confirm hybridization. The testing of screening primers can judge whether the sample contains GMOs, and that of identifying primers can further judge what kinds of trait genes are contained in the sample. We detected nine soybean samples, six maize samples, seven potato samples and two rice samples by the MPCR-MHA method; at the same time we also detected them with single PCR-MHA method. The results between two methods have good consistency.     

Synthetic oligodeoxyribonucleotide probes for detection of Listeria monocytogenes.

A 500-base-pair DNA fragment of a presumptive beta-hemolysin gene of Listeria monocytogenes has been used to identify this organism by a modified colony hybridization technique. We have cloned this DNA fragment into M13 bacteriophage vectors and sequenced it by a dideoxynucleotide sequencing technique. From this sequencing information, several oligodeoxyribonucleotides were synthesized and used as synthetic probes to identify L. monocytogenes. The probes were specific for L. monocytogenes and did not react with any other Listeria strains in a colony hybridization assay. In particular, one of these probes (AD07) was used to detect L. monocytogenes in artificially contaminated raw-milk and soft-cheese samples.     

Synthetic oligodeoxyribonucleotide probes for detection of Listeria monocytogenes

A 500-base-pair DNA fragment of a presumptive beta-hemolysin gene of Listeria monocytogenes has been used to identify this organism by a modified colony hybridization technique. We have cloned this DNA fragment into M13 bacteriophage vectors and sequenced it by a dideoxynucleotide sequencing technique. From this sequencing information, several oligodeoxyribonucleotides were synthesized and used as synthetic probes to identify L. monocytogenes. The probes were specific for L. monocytogenes and did not react with any other Listeria strains in a colony hybridization assay. In particular, one of these probes (AD07) was used to detect L. monocytogenes in artificially contaminated raw-milk and soft-cheese samples.     

Reliable hybridization of oligonucleotides as short as six nucleotides

Although there are many new applications for hybridizing short, synthetic oligonucleotide probes to DNA, such applications have not included determining unknown sequences of DNA. The lack of clear discrimination in hybridization of oligo probes shorter than 11 nucleotides and the lack of a theoretical understanding of factors influencing hybridization of short oligos have hampered the development of their use. We have found conditions for reliable hybridization of oligonucleotides as short as seven nucleotides to cloned DNA or to oligonucleotides attached to filters. Low-temperature hybridization and washing conditions, in contrast to the high stringency conditions currently used in hybridization experiments, have the potential for allowing the simple use of all oligos of six nucleotides or longer in meaningful hybridizations. We also present the hybridization discrimination theory that provides the conceptual framework for understanding these results.