The influence of the non-nucleotide insert on the hybridization properties of oligonucleotides

The effect of different non-nucleotide inserts incorporated into oligonucleotide chains on their hybridization properties was studied by the method of thermal denaturation. Various types of alkyldiols and oligoethylene glycols were used as inserts modifying oligonucleotide backbone. Such modification of oligonucleotides caused the destabilization of their complementary complexes. It was shown that the hybridization properties of the modified oligonucleotides depend on several features of inserts: the type, number, length of insertions, and positions of interrupted dinucleotide steps in oligonucleotide chain.     

The use of the resonant mirror biosensor to detect point mutations,as demonstrated with synthetic oligonucleotides

The possibility of using the resonant mirror biosensor to detect point substitutions in oligonucleotides was demonstrated with a fragment of the Helicobacter pylori 23S rRNA gene, point mutations in which are responsible for clarythromycin resistance. Conditions were optimized for the interaction of a probe immobilized on the sensing surface with targets containing various nucleotide substitutions. A probe allowing reliable discrimination of mutant targets was selected. The mismatch position in the probe was shown to affect the kinetic parameters (response) of hybridization with mutant targets, reporting not only the position, but also the character (G or C) of a substitution.     

DNA biosensors based on self-assembled carbon nanotubes

DNA biosensors based on self-assembled multi-walled carbon nanotubes (MWNTs) were described in this paper, in which the probe DNA oligonucleotides were immobilized by forming covalent amide bonds between carboxyl groups at the nanotubes and amino groups at the ends of the DNA oligonucleotides. Hybridization between the probe and target DNA oligonucleotides was confirmed by the changes in the voltammetric peak of the indicator of methylene blue. Our results demonstrate that the DNA biosensors based on self-assembled MWNTs had a higher hybridization efficiency compared to those based on random MWNTs. In addition, the developed DNA biosensors also had a high selectivity of hybridization detection.     

Strategies for optimizing DNA hybridization on surfaces

Specific and predictable hybridization of the polynucleotide sequences to their complementary counterparts plays a fundamental role in the rational design of new nucleic acid nanodevices. Generally, nucleic acid hybridization can be performed using two major strategies, namely hybridization of DNA or RNA targets to surface-tethered oligonucleotide probes (solid-phase hybridization) and hybridization of the target nucleic acids to randomly distributed probes in solution (solution-phase hybridization). Investigations into thermodynamic and kinetic parameters of these two strategies showed that hybridization on surfaces is less favorable than that of the same sequence in solution. Indeed, the efficiency of DNA hybridization on surfaces suffers from three constraints: (1) electrostatic repulsion between DNA strands on the surface, (2) steric hindrance between tethered DNA probes, and (3) nonspecific adsorption of the attached oligonucleotides to the solid surface. During recent years, several strategies have been developed to overcome the problems associated with DNA hybridization on surfaces. Optimizing the probe surface density, application of a linker between the solid surface and the DNA-recognizing sequence, optimizing the pH of DNA hybridization solutions, application of thiol reagents, and incorporation of a polyadenine block into the terminal end of the recognizing sequence are among the most important strategies for enhancing DNA hybridization on surfaces.     

Rational selection and quantitative evaluation of antisense oligonucleotides

Antisense oligonucleotides are an attractive therapeutic option to modulate specific gene expression. However, not all antisense oligonucleotides are effective in inhibiting gene expression, and currently very few methods exist for selecting the few effective ones from all candidate oligonucleotides. The lack of quantitative methods to rapidly assess the efficacy of antisense oligonucleotides also contributes to the difficulty of discovering potent and specific antisense oligonucleotides. We have previously reported the development of a prediction algorithm for identifying high affinity antisense oligonucleotides based on mRNA-oligonucleotide hybridization. In this study, we report the antisense activity of these rationally selected oligonucleotides against three model target mRNAs (human lactate dehydrogenase A and B and rat gp130) in cell culture. The effectiveness of oligonucleotides was evaluated by a kinetic PCR technique, which allows quantitative evaluation of mRNA levels and thus provides a measure of antisense-mediated decreases in target mRNA, as occurs through RNase H recruitment. Antisense oligonucleotides that were predicted to have high affinity for their target proved effective in almost all cases, including tests against three different targets in two cell types with phosphodiester and phosphorothioate oligonucleotide chemistries. This approach may aid the development of antisense oligonucleotides for a variety of applications.     

Cu@Au alloy nanoparticle as oligonucleotides labels for electrochemical stripping detection of DNA hybridization

Synthesis of the novel Cu@Au alloy nanoparticle and its application in an electrochemical DNA hybridization detection assay is described in this article. We report a low-temperature method for generating core-shell particles consisting of a core of Cu and a thin layer of Au shell that can be readily functionalized with oligonucleotides. Core-shell Cu@Au particles were successfully labeled to a 5'-alkanethiol capped oligonucleotides probe that is related to the colitoxin gene. The DNA genetic sensing assay relies on the electrostatic adsorption of target oligonucleotides onto conducting polypyrrole (PPy) surface at the glassy carbon electrode (GCE), and its hybridization to the alloy particle-oligonucleotides DNA probe. Hybridization events between probe and target were monitored by the release of the copper metal atoms anchored on the hybrids by oxidative metal dissolution and the indirectly determination of the solubilized Cu2+ ions by sensitive anodic stripping voltammetry (ASV). The detection limit is 5.0 pmol l(-1) of target oligonucleotides. The Cu@Au core-shell nanoparticles combining the surface modification properties of Au with the good electrochemical activity of Cu core shows their perspective application in the electrochemical DNA hybridization analysis assay.     

Synthesis and hybridization properties of oligonucleotides containing 6-membered azasugar nucleotides

A modified nucleoside was synthesized with adenine and a 6-membered azasugar, and it was converted to the phosphoramidite which was used for the incorporation into oligonucleotides. The hybridization properties of the modified oligonucleotides with DNA and RNA were studied.     

Conformational and chiral selection of oligonucleotides

In view of a better understanding of chiral selection of oligonucleotides, we have studied the hybridization of D- and L-CNA (cyclohexane nucleic acids) and D- and L-DNA, with chiral D-beta-homo-DNA and achiral PNA (peptide nucleic acids). PNA hybridizes as well with D-DNA, L-DNA as with D-beta-homo-DNA. The structure of the PNA x D-beta-homo-DNA complex is different from the PNA x DNA duplexes. D-CNA prefers D-DNA as hybridization partner, while L-CNA prefers D-beta-homo-DNA as hybridization partner. The conformation of the enantiomeric oligonucleotides D-CNA and L-CNA in the supramolecular complex with D-DNA and D-beta-homo-DNA, respectively, is different. These data may contribute to the confirmation of a hypothesis of the existence of achiral informative polymers as RNA predecessor, and to the understanding of homochirality of nucleic acids.     

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.     

Hybridization of DNA with oligonucleotides immobilized in a gel: a convenient method for recording single base replacements

In an attempt to develop a reliable system for DNA sequence analysis with multiple hybridization probes, oligonucleotides down to 8 bases long were covalently immobilized in a thin layer of polyacrylamide gel fixed on a glass plate. It was shown possible to detect single base changes in DNA by hybridization of the immobilized oligonucleotides with radioactively and fluorescently labeled DNA fragments. Moreover, it was found that dissociation temperatures of differently GC-rich duplexes could be equalized by appropriate choice of immobilized oligonucleotides concentrations. A model accounting for this phenomenon is presented. In order to make the system more compact, a rectangular matrix of 200 mm dots of immobilized oligonucleotides ("hybridization chip") was designed which offered the sensitivity of 20 attomoles per dot for fluorescent DNA fragment. The applications and perspectives of the approach are discussed.     

Study of DNA hybridization on polypyrrole grafted with oligonucleotides by photocurrent spectroscopy

Recognition of DNA sequences by biochemical sensor is generally performed by analysis after completion of hybridization. Using a technique able to directly translate the biological event into an electrical signal allows the in situ monitoring of the hybridization kinetics. In this aim, the photoelectrochemical behavior of one electroactive polymeric sensor based on a copolymer of polypyrrole and polypyrrole-oligonucleotide has been investigated in aqueous solution. This sensor has been studied as such (i) and in two other situations: (ii) when the copolymer is in presence of non-complementary oligonucleotides; and (iii) when the copolymer is in presence of complementary oligonucleotides. From the photocurrent spectra obtained at -0.6 V/SCE versus incident energy the allowed direct and indirect transitions for each polymer have been evidenced. The photocurrent evolution during hybridization and adsorption processes has been recorded in real time and the hybridization kinetics has revealed to be comparable with mass variations obtained by quartz crystal microbalance under the same experimental conditions.     

Identification of apolipoprotein E polymorphism by using synthetic oligonucleotides

A procedure based on selective hybridization with allele-specific oligonucleotides was developed for typing apolipoprotein E variants from human genomic DNAs. Two sets of oligonucleotides were synthesized and used to discriminate either between epsilon 3 and epsilon 4 alleles or between epsilon 3 and epsilon 2 alleles. Combination of the allele-specific oligonucleotide hybridization with the method for in vitro DNA amplification (Polymerase Chain Reaction) Saiki, R. K. et al. 1985. Science, 230: 1350-1354) (1) dramatically improved the sensitivity and the reliability of the procedure. Adaptation of a simple strategy involving direct cloning and DNA sequencing of in vitro amplified DNA enables rapid identification of any mutation within the apoE gene area encoding the receptor binding domain.     

Genome-wide selection of unique and valid oligonucleotides

Functional genomics methods are used to investigate the huge amount of information contained in genomes. Numerous experimental methods rely on the use of oligo- or polynucleotides. Nucleotide strand hybridization forms the underlying principle for these methods. For all these techniques, the probes should be unique for analyzed genes. In addition to being unique for the studied genes, the probes should fulfill a large number of criteria to be usable and valid. The criteria include for example, avoidance of self-annealing, suitable melting temperature and nucleotide composition. We developed a method for searching unique and valid oligonucleotides or probes for genes so that there is not even a similar (approximate) occurrence in any other location of the whole genome. By using probe size 25, we analyzed 17 complete genomes representing a wide range of both prokaryotic and eukaryotic organisms. More than 92% of all the genes in the investigated genomes contained valid oligonucleotides. Extensive statistical tests were performed to characterize the properties of unique and valid oligonucleotides. Unique and valid oligonucleotides were relatively evenly distributed in genes except for the beginning and end, which were somewhat overrepresented. The flanking regions in eukaryotes were clearly underrepresented among suitable oligonucleotides. In addition to distributions within genes, the effects on codon and amino acid usage were also studied.     

Biotinylated oligonucleotides as probes in the method of molecular hybridization

The chemical approaches to the preparation of non-radioactive and biotinylated probes based on synthetic oligonucleotides and their applicability to the molecular hybridization method are discussed.     

LNA-modified oligonucleotides effectively drive intramolecular-stable hairpin to intermolecular-duplex state

Sequence-specific hybridization of antisense and antigene agent to the target nucleic acid is an important therapeutic strategy to modulate gene expression. However, efficiency of such agents falls due to inherent intramolecular-secondary-structures present in the target that pose competition to intermolecular hybridization by complementary antisense/antigene agent. Performance of these agents can be improved by employing structurally modified complementary oligonucleotides that efficiently hybridize to the target and force it to transit from an intramolecular-structured-state to an intermolecular-duplex state. In this study, the potential of variably substituted locked nucleic acid-modified oligonucleotides (8mer) to hybridize and disrupt highly stable, secondary structure of nucleic acid has been biophysically characterized and compared with the conventionally used unmodified DNA oligonucleotides. The target here is a stem-loop hairpin oligonucleotide-a structure commonly present in most structured-nucleic acids and known to exhibit an array of biological functions. Using fluorescence-based studies and EMSA we prove that LNA-modified oligonucleotides hybridize to the target hairpin with higher binding affinity even at lower concentration and subsequently, force it to assume a duplex conformation. LNA-modified oligonucleotides may thus, prove as potential therapeutic candidates to manipulate gene expression by disruption of biologically relevant nucleic acid secondary structure.     

Incorporation of hexose nucleoside analogues into oligonucleotides: synthesis, base-pairing properties and enzymatic stability.

Oligonucleotides containing 1-(2,4-dideoxy-beta-D-erythro-hexopyranosyl)thymine (2) and 1-(3,4-dideoxy-beta-D-erythro-hexopyranosyl)thymine (3) were synthesized on a solid support using the phosphoramidite approach. The properties of these oligonucleotides were compared with the earlier reported characteristics of oligonucleotides containing 1-(2,3-dideoxy-beta-D-erythro-hexopyranosyl) thymine (1). The order in enzymatic stability of end-substituted oligonucleotides is 3 greater than 1 much greater than 2. The hybridization properties of the modified oligonucleotides are in reverse order: 2 much greater than 1 greater than 3.     

Cartridge-based high-throughput purification of oligonucleotides for reliable oligonucleotide arrays

A novel, cartridge-based procedure for the efficient and irreversible detritylation of oligonucleotides is reported. This method, combined with a process for the elimination of depurinated fragments produces, in a highly parallel fashion, oligonucleotides with better purity than those traditionally obtained using reversed-phase high-performance liquid chromotography purification. Our combined detritylation and purification methodology compares favorably with commercial cartridge-based purification systems. The benefits of working with pure oligonucleotides, with regard to higher signal and better signal linearity, are shown in array-based hybridization experiments.     

Accuracy of genotyping for single nucleotide polymorphisms by a microarray-based single nucleotide polymorphism typing method involving hybridization of short allele-specific oligonucleotides.

Advances in technologies for identifying genetic polymorphisms rapidly and accurately will dramatically accelerate the discovery of disease-related genes. Among a variety of newly described methods for rapid typing of single-nucleotide polymorphisms (SNPs), gene detection using DNA microarrays is gradually achieving widespread use. This method involves the use of short (11- to 13-mer) allele-specific oligonucleotides. This method allows simultaneous analysis of many SNPs in DNAs from a large number of individuals, in a single experiment. In this work, we evaluated the accuracy of a new microarray-based short allele-specific oligonucleotide (ASO) hybridization method. There is a 96-well formatted array on a single plate, in which up to 256 spots are included in each well. Fluorescent probes for our experiments were produced by multiplex PCR amplification often target SNP-containing regions. We genotyped 192 individuals across a panel of ten single base variations, which included an insertion/deletion polymorphism. For comparison, we genotyped the same individuals for the same SNPs by the method of single-base extension with fluorescence detection. The typing accuracies of the microarray-based PCR-ASO and single-base extension methods were calculated as 99.9% and 99.1%, respectively, on the basis of genotyping results determined by direct sequencing. We conclude that the microarray-based hybridization method using short ASO probes represents a potential breakthrough technology for typing large numbers of SNPs rapidly and efficiently.     

Single-base mutational analysis of cancer and genetic diseases using membrane bound modified oligonucleotides.

A convenient format for the detection of PCR amplified sequences is the hybridization of the PCR products to oligonucleotide probes which are immobilized on a solid phase. We describe a new method for site-specific attachment of such probe oligonucleotides to nylon membranes. The method is based on the formation of an amide bond between carboxyl groups present on the membranes and amino-linkers situated on the 5' end of the oligonucleotides. The covalent attachment is via a carbodiimide mediated condensation. The single, 5' end attachment of the oligonucleotides to the membrane surface leaves the probe free to interact with complementary sequences, thus increasing the hybridization efficiency relative to methods where heat or ultraviolet light is used for non-specific fixation. Using biotinylated PCR products in hybridization reactions along with a non-radioactive chemiluminescent detection system, high efficiency hybridization is obtained as well as a very good signal to noise ratio. The method has been applied successfully to the detection of RAS point mutations, cystic fibrosis deletion and point mutations and others. The sensitivity, simplicity and reproducibility of this method make it an ideal tool for the diagnosis of infectious and genetic diseases, as well as analysis of mutations in neoplasias, HLA typing and other areas.     

Optimal conditions for hybridization with oligonucleotides: a study with myc-oncogene DNA probes

We present a study on the refinement of filter-hybridization conditions for a series of synthetic oligonucleotides in the range from 17 to 50 base residues in length. Experimental conditions for hybridization and the subsequent washing steps of the filter were optimized for different lengths of the synthetic oligonucleotides by varying the formamide concentration and washing conditions (temperature and monovalent cation concentration). Target DNA was immobilized to the nitrocellulose filter with the slot blot technique. The sequences of the synthetic oligonucleotides are derived from the third exon of the human oncogene c-myc and the corresponding viral gene v-myc and the G + C content was between 43 and 47%. Optimal conditions for hybridization with a 82% homologous 30-mer and 100% homologous 17-, 20-, 25-, 30-, and 50-mers were found to be a concentration of formamide of 15, 15, 30, 30, 40, and 50%, respectively. Optimal conditions for washing were 0.5X standard sodium citrate (SSC) at 42 degrees C for 2 X 15 min. The melting temperature for these optimal hybridization and washing conditions was calculated to be up to 11 degrees C below the hybridization temperature actually used. This confirms that the duplexes are more stable than expected. The melting points for 17-, 20-, and 30-mers were measured in the presence of 5X SSC and found to be 43, 58, and 60 degrees C, respectively. Competition between double- and single-stranded DNA probes to the target DNA was investigated. The single-stranded DNA probes were about 30- to 40-fold more sensitive than the double-stranded DNA probes.