Fluorescence in situ hybridization with high-complexity repeat-free oligonucleotide probes generated by massively parallel synthesis.

The ability to visualize specific DNA sequences, on chromosomes and in nuclei, by fluorescence in situ hybridization (FISH) is fundamental to many aspects of genetics, genomics and cell biology. Probe selection is currently limited by the availability of DNA clones or the appropriate pool of DNA sequences for PCR amplification. Here, we show that liquid-phase probe pools from sequence capture technology can be adapted to generate fluorescently labelled pools of oligonucleotides that are very effective as repeat-free FISH probes in mammalian cells. As well as detection of small (15 kb) and larger (100 kb) specific loci in both cultured cells and tissue sections, we show that complex oligonucleotide pools can be used as probes to visualize features of nuclear organization. Using this approach, we dramatically reveal the disposition of exons around the outside of a chromosome territory core and away from the nuclear periphery.

HiSpOD: probe design for functional DNA microarrays.

MOTIVATION: The use of DNA microarrays allows the monitoring of the extreme microbial diversity encountered in complex samples like environmental ones as well as that of their functional capacities. However, no probe design software currently available is adapted to easily design efficient and explorative probes for functional gene arrays. RESULTS: We present a new efficient functional microarray probe design algorithm called HiSpOD (High Specific Oligo Design). This uses individual nucleic sequences or consensus sequences produced by multiple alignments to design highly specific probes. Indeed, to bypass crucial problem of cross-hybridizations, probe specificity is assessed by similarity search against a large formatted database dedicated to microbial communities containing about 10 million coding sequences (CDS). For experimental validation, a microarray targeting genes encoding enzymes involved in chlorinated solvent biodegradation was built. The results obtained from a contaminated environmental sample proved the specificity and the sensitivity of probes designed with the HiSpOD program. AVAILABILITY: http://fc.isima.fr/~g2im/hispod/.

[Development in ligase-mediated techniques for bio-molecular analysis].

Two oligonucleotide probes are permitted to anneal to the nucleic acid target of interest so that the ends of two probes immediately become adjacent to each other. The ligase can then efficiently join the two juxtaposed oligonucleotide probes by the formation of a phosphodiester bond if and only if perfectly matched base-pairs at the nick are present. During past 20 years, many ligase-mediated techniques have been developed for analyzing various bio-molecules, such as known/unknown point mutations, small-scale insertions and deletions, CpG islands methylation, large sets of single nucleotide polymorphisms (SNPs), specific proteins and DNA regions with which some other proteins can interact. Since the ligation reaction can be easily integrated into other techniques, certain advances have been already achieved. These novel approaches retain high accuracy through multiple hybridization and enzymatic processing events, and provide inherent quality control checking. In this article, we provide a comprehensive review of the ligase-mediated techniques for bio-molecular analysis.

Synthesis of unimolecularly circular G-quadruplexes as prospective molecular probes.

Synthesis of unimolecularly circular G-quadruplex has been accomplished for the first time during our investigation on the template basis of G-quadruplex through chemical ligations of guanine-rich linear sequences of oligodeoxyribonucleotides. The uniqueness of this newly designed circularization course is its self-recognition and self-templating on the scale of individual strand of oligodeoxyribonucleotide in which the same linear sequence serves both as a template and as a substrate simultaneously. The results from our exonuclease and DNAse hydrolysis studies confirm that there is indeed absence of open termini within the structure of the identified circular product. Our subsequent investigation on the loop-size effect indicates that the unimolecularly circular G-quadruplex possessing two or more thymine nucleotides within their connecting loops is readily attainable, while the linear sequence with a single thymine nucleotide between guanine tracts is not a proper precursor for our ligation reaction. In addition, conformation dependency of the circularization course as well as the effects of alkali ions, pH values and concentration of potassium ions on the circularization reaction are examined during our investigation. The implication of our current studies and possible application of the obtained unimolecularly circular G-quadruplex in certain biological processes are also discussed in this report.

A scalable high-throughput chemical synthesizer.

A machine that employs a novel reagent delivery technique for biomolecular synthesis has been developed. This machine separates the addressing of individual synthesis sites from the actual process of reagent delivery by using masks placed over the sites. Because of this separation, this machine is both cost-effective and scalable, and thus the time required to synthesize 384 or 1536 unique biomolecules is very nearly the same. Importantly, the mask design allows scaling of the number of synthesis sites without the addition of new valving. Physical and biological comparisons between DNA made on a commercially available synthesizer and this unit show that it produces DNA of similar quality.

Single-nucleotide sequence discrimination in situ using padlock probes.

DNA ligases are very sensitive to mismatches at the DNA ends to be joined through ligation. This mechanism has been exploited to distinguish DNA sequence variants in situ using so-called padlock probes. Padlock probes are linear oligonucleotides with target-complementary sequences at both ends, and an on-target-complementary segment in between. The end sequences are brought next to each other upon hybridization to the target DNA sequence, and if the ends are perfectly matched to the target sequence, they can be joined by a DNA ligase. Padlock probes detect target sequences with very high specificity, because both probe segments must hybridize to the target for circularization to occur. This unit presents a protocol for discrimination between closely similar DNA sequences in situ using padlock probes. A discussion of methods for greatly amplifying the signal from circularized probes is also included.DNA ligases are very sensitive to mismatches at the DNA ends to be joined through ligation.

Enzymatic labeling of nucleic acids.

Extensive knowledge of the enzymology involved in biosynthesis and degradation of nucleic acids has permitted the development of simple methods for labeling RNA and DNA with radioisotopes or biotin. These labeled probes are used primarily for hybridization to nucleic acid fragments of interest in a variety of applications. A complete description of the methods available for such labeling is beyond the scope of this manual, but contained within this unit are protocols for oligonucleotide-primed synthesis of radiolabeled and biotinylated DNA probes, in vitro synthesis of radiolabeled RNA, and end labeling of synthetic oligonucleotide probes.

PCR-generated padlock probes detect single nucleotide variation in genomic DNA.

Circularizing oligonucleotide probes, so-called padlock probes, have properties that should prove valuable in a wide range of genetic investigations, including in situ analyses, genotyping and measurement of gene expression. However, padlock probes can be difficult to obtain by standard oligonucleotide synthesis because they are relatively long and require intact 5'- and 3'-end sequences to function. We describe a PCR-based protocol for flexible small-scale enzymatic synthesis of such probes. The protocol also offers the advantage over chemical synthesis that longer probes can be made that are densely labeled with detectable functions, resulting in an increased detection signal. The utility of probes synthesized according to this protocol is demonstrated for the analysis of single nucleotide variations in human genomic DNA both in situ and in solution.

Specific oligonucleotide probes for in situ detection of a major group of gram-positive bacteria with low DNA G + C content.

Almost one thousand 16S rRNA sequences of Gram-positive bacteria with a low DNA G + C content from public databases were analyzed using the ARB software package. A signature region was identified between positions 354 and 371 (E. coli numbering) for the Bacillus sub-branch of the Gram-positive bacteria with a low DNA G + C content, the former orders Bacillales and Lactobacillales. Three oligonucleotide probes, namely LGC354A, LGC354B, and LGC354C, were designed to target this diagnostic site. Their fluorescent derivatives were suitable for whole cell detection by fluorescence in situ hybridization (FISH). Hybridization conditions were adjusted for differentiation of target and related non-target reference species. When applying FISH to whole bacterial cells in a sample of activated sludge from a communal wastewater treatment plant, members of the Bacillus sub-branch were detected at levels from 0.01% of cells in samples fixed with paraformaldehyde to over 8 percent in the same samples fixed with ethanol and treated with lysozyme. The problems of quantitative in situ analysis of Gram-positive bacteria with a low DNA G + C content in biofilm flocs are discussed and recommendations made. Members of the Bacillus sub-branch were detected in different abundances in activated sludge samples from different wastewater plants.

Identification of toxigenic Clostridium difficile strains using a toxin B gene-specific oligonucleotide probe.

We describe the use of a new specific synthetic oligonucleotide probe, deduced from the sequence of the gene for Clostridium difficile toxin B, to identify toxigenic strains of C. difficile. This probe does not hybridize to the DNA of non-toxigenic strains of C. difficile nor to DNA isolated from different Clostridium species, including C. sordellii. None of the enteric pathogenic bacteria tested were seen to hybridize with the probe. A preliminary study of direct probing of faecal specimens indicates a potential for the use of this DNA probe in the clinical laboratory for the rapid identification of toxigenic strains of C. difficile.

The complete amino acid sequence of the Clostridium botulinum type A neurotoxin, deduced by nucleotide sequence analysis of the encoding gene.

A 26-mer oligonucleotide probe was synthesized (based on the determined amino acid sequence of the N-terminus of the Clostridium botulinum type A neurotoxin, BoNT/A) and used in Southern blot analysis to construct a restriction map of the region of the clostridial genome encompassing BoNT/A. The detailed information obtained enabled the cloning of the structural gene as three distinct fragments, none of which were capable of directing the expression of a toxic molecule. The central portion was cloned as a 2-kb PvuII-TaqI fragment and the remaining regions of the light chain and heavy chain as a 2.4-kb ScaI-TaqI fragment and a 3.4-kb HpaI-PvuII fragment, respectively. The nucleotide sequence of all three fragments was determined and an open reading frame identified, composed of 1296 codons corresponding to a polypeptide of 149 502 Da. The deduced amino acid sequence exhibited 33% similarity to tetanus toxin, with the most highly conserved regions occurring between the N-termini of the respective heavy chains. Conservation of Cys residues flanking the position at which the toxins are cleaved to yield the heavy chain and light chain allowed the tentative identification of those residues which probably form the disulphide bridges linking the two toxin subfragments.

Structural characterization of a follicle-stimulating hormone action inhibitor in porcine ovarian follicular fluid. Its identification as the insulin-like growth factor-binding protein.

Recently, an inhibitory polypeptide that could block the follicle-stimulating hormone-induced estradiol and progesterone production in rat ovary granulosa cells has been isolated from porcine ovarian follicular fluid. Amino-terminal sequence analysis of the purified inhibitor suggests that it could be the porcine congener of the 53-kDa subunit of the growth hormone-dependent insulin-like growth factor binding protein (IGF-BP3). Using amino acid sequence information derived from the purified inhibitor to construct oligonucleotide probes, we have now identified the complementary deoxyribonucleic acids (cDNAs) encoding the inhibitory polypeptide from a porcine liver and a porcine ovary library. The nucleotide and predicted amino acid sequences revealed that the cDNAs indeed encode the porcine homolog of the recently characterized human IGF-BP3. The mature polypeptide consists of 266 amino acids, which is 2 amino acids longer than the human sequence. Between the two species, there are 42 amino acid substitutions, but the 18 cysteines and the three Asn-linked glycosylation sites are totally conserved. A single mRNA species of 2.6 kilobases encoding the IGF-BP3 was detected in porcine gonadal, brain, and liver tissues by Northern analysis.

Solution-phase detection of polynucleotides using interacting fluorescent labels and competitive hybridization.

DNA was assayed in a homogeneous format using DNA probes containing hybridization-sensitive labels. The DNA probes were prepared from complementary DNA strands in which one strand was covalently labeled on the 5'-terminus with fluorescein and the complementary strand was covalently labeled on the 3'-terminus with a quencher of fluorescein emission, either pyrenebutyrate or sulforhodamine 101. Probes prepared in this manner were able to detect unlabeled target DNA by competitive hybridization producing fluorescence signals which increased with increasing target DNA concentration. A single pair of complementary probes detected target DNA at a concentration of approximately 0.1 nM in 10 min or about 10 pM in 20-30 min. Detection of a 4 pM concentration of target DNA was demonstrated in 6 h using multiple probe pairs. The major limiting factors were background fluorescence and hybridization rates. Continuous monitoring of fluorescence during competitive hybridization allowed correction for variable sample backgrounds at probe concentrations down to 20 pM; however, the time required for complete hybridization increased to greater than 1 h at probe concentrations below 0.1 nM. A promising application for this technology is the rapid detection of amplified polynucleotides. Detection of 96,000 target DNA molecules in a 50-microliters sample was demonstrated following in vitro amplification using the polymerase chain reaction technique.