Gene suppression via U1 small nuclear RNA interference (U1i) machinery using oligonucleotides containing 2′-modified-4′-thionucleosides

Gene suppression via U1 small nuclear RNA interference (U1i) is considered to be one of the most attractive approaches, and takes the place of general antisense, RNA interference (RNAi), and anti-micro RNA machineries. Since the U1i can be induced by short oligonucleotides (ONs), namely U1 adaptors consisting of a ‘target domain’ and a ‘U1 domain’, we prepared adaptor ONs using 2′-modified-4′-thionucleosides developed by our group, and evaluated their U1i activity. As a result, the desired gene suppression via U1i was observed in ONs prepared as a combination of 2′-fluoro-4′-thionucleoside and 2′-fluoronucleoside units as well as only 2′-fluoronucleoside units, while those prepared as combination of 2′-OMe nucleoside/2′-OMe-4′-thionucleoside and 2′-fluoronucleoside units did not show significant activity. Measurement of T_m values indicated that a higher hybridization ability of adaptor ONs with complementary RNA is one of the important factors to show potent U1i activity.     

Novel insights into the use of Glowing LNA as nucleic acid detection probes--influence of labeling density and nucleobases

Appropriately designed 2'-N-(pyren-1-yl)carbonyl-2'-amino-LNA (locked nucleic acid) display large increases in fluorescence intensity and remarkably high quantum yields upon hybridization with nucleic acid targets. Thermal denaturation and fluorescence spectroscopy studies on ONs modified with known thymine monomer X and novel 5-methylcytosine monomer Y provide new insights into the design principles and mechanism of these Glowing LNA nucleic acid detection probes.     

Matching base-pair number dependence of the kinetics of DNA-DNA hybridization studied by surface plasmon fluorescence spectroscopy

Two single-stranded DNA oligonucleotides consisting of complementary base-pairs can form double strands. This phenomenon is well studied in solutions, however, in order to clarify the physical mechanism of the hybridization occurring at a solid/solution interface, we studied the kinetics by surface plasmon fluorescence spectroscopy (SPFS): one single-stranded oligo-DNA (probe-DNA) was immobilized on the substrate, the other one (target-DNA) labelled with a fluorescent probe was added to the flow cell. After hybridization, the chromophores could be excited by the surface plasmon mode and their fluorescence detected with high sensitivity. The dependence of the k(on) and k(off) rate constants on the length of the hybridizing oligonucleotides was investigated by using a MM0 series (no mismatch) and the kinetics was found to be well described by a Langmuir adsorption model. From these measurements we found that also in the case of surface hybridization the affinity of the duplexes decreases as the number of matching base-pairs decreases from 15 to 10. In order to show that SPFS is the powerful technique with high sensitivity, the hybridization process for mixed target-oligos was measured by SPFS and analyzed by an expanded Langmuir model in which two components of target-oligo can bind to probe-DNA at the sensor surface competitively. Two sets of the k(on) and k(off) obtained from the experiment are successfully consistent with the k(on) and k(off) obtained from experiments for single (pure) target-DNA.     

A novel versatile phosphoramidite building block for the synthesis of 5'- and 3'-hydrazide modified oligonucleotides

We introduce a novel versatile phosphoramidite building block for the modification of oligonucleotides (ONs) with acyl hydrazides on the 5'- or 3'-terminus, or both. The reaction of these hydrazide functionalized ONs with 4-methoxyphenylaldehyde is demonstrated for solution derivatization. Hydrazides are considered nowadays as promising reactants, which show enhanced reactivity at neutral and slightly acidic conditions and higher stability of yielding products as compared to the aliphatic amines, which are broadly used for ONs derivatization. Our method to introduce hydrazides into ONs employs a phosphoramidite modifier designed to split, during ammonia or lithium hydroxide treatment, into two hydrazides via beta-elimination of a central bis-2-carbonylethoxysulfone unit. It allows the creation of ONs derivatized with a hydrazide moiety at the 5'-, 3'- and both 5'- and 3'-termini, as well as two different hydrazide containing ONs at the same time, viz. in one sequence on the same solid support In latter case one can, for example, synthesize two hydrazide containing ONs, where one is 5'-modified and second one is 3'-modified.     

Synthesis of a N-acylsulfamide linked dinucleoside and its incorporation into an oligonucleotide.

A N-acylsulfamide linked thymidine dinucleoside was synthesized and incorporated into an oligonucleotide (ON). The interest is in a linkage analog that has a higher pKa relative to a phosphodiester and when incorporated into ONs is capable of helix formation with complementary RNA. The hybridization property of the resultant ON with RNA was shown to result in significant destabilization.     

Stable transmission of targeted gene modification using single-stranded oligonucleotides with flanking LNAs

Targeted mutagenesis directed by oligonucleotides (ONs) is a promising method for manipulating the genome in higher eukaryotes. In this study, we have compared gene editing by different ONs on two new target sequences, the eBFP and the rd1 mutant photoreceptor βPDE cDNAs, which were integrated as single copy transgenes at the same genomic site in 293T cells. Interestingly, antisense ONs were superior to sense ONs for one target only, showing that target sequence can by itself impart strand-bias in gene editing. The most efficient ONs were short 25 nt ONs with flanking locked nucleic acids (LNAs), a chemistry that had only been tested for targeted nucleotide mutagenesis in yeast, and 25 nt ONs with phosphorothioate linkages. We showed that LNA-modified ONs mediate dose-dependent target modification and analyzed the importance of LNA position and content. Importantly, when using ONs with flanking LNAs, targeted gene modification was stably transmitted during cell division, which allowed reliable cloning of modified cells, a feature essential for further applications in functional genomics and gene therapy. Finally, we showed that ONs with flanking LNAs aimed at correcting the rd1 stop mutation could promote survival of photoreceptors in retinas of rd1 mutant mice, suggesting that they are also active in vivo.     

New monolith technology for automated anion-exchange purification of nucleic acids

Synthetic nucleic acid analysis often employs pellicular anion-exchange (AE) chromatography because it supports very high efficiency separations while offering means to control secondary structure, retention and resolution by readily modifiable chromatographic conditions. However, these pellicular anion-exchange (pAE) phases do not offer capacity sufficient for lab-scale oligonucleotide (ON) purification. In contrast, monolithic phases produce fast separations at capacities exceeding their pellicular counterparts, but do not exhibit capacities typical of fully porous, bead-based, anion-exchangers. In order to further increase monolith capacity and obtain the selectivity and mass transfer characteristics of pellicular phases, a surface-functionalized monolith was coated with pAE nanobeads (latexes) usually employed on the pellicular DNAPac phase. The nanobead-coated monolith exhibited chromatographic behaviors typical of polymer AE phases. Based on this observation the monolithic substrate surface porosity and latex diameters were co-optimized to produce a hybrid monolith harboring capacity similar to that of fully porous bead-based phases and peak shape approaching that of the pAE phases. We tested the hybrid monolith on a variety of previously developed pAE capabilities including control of ON selectivity, resolution of derivatized ONs, the ability to resolve RNA ONs harboring aberrant linkages at different positions in a single sequence and separation of phosphorothioate diastereoisomers. We compared the yield and purity of an 8 mg ON sample purified on both the new hybrid monolith and a benchmark AE column based on fully porous monodisperse beads. This comparison included an assessment of the relative selectivities of both columns. Finally, we demonstrated the ability to couple AE ON separations with ESI-MS using an automated desalting protocol. This protocol is also useful for preparing ONs for other assays, such as enzyme treatments, that may be sensitive to high salt levels.     

A Novel Versatile Phosphoramidite Building Block for the Synthesis of 5′- and 3′-Hydrazide Modified Oligonucleotides

We introduce a novel versatile phosphoramidite building block for the modification of oligonucleotides (ONs) with acyl hydrazides on the 5′- or 3′-terminus, or both. The reaction of these hydrazide functionalized ONs with 4-methoxyphenylaldehyde is demonstrated for solution derivatization. Hydrazides are considered nowadays as promising reactants, which show enhanced reactivity at neutral and slightly acidic conditions and higher stability of yielding products as compared to the aliphatic amines, which are broadly used for ONs derivatization.

Our method to introduce hydrazides into ONs employs a phosphoramidite modifier designed to split, during ammonia or lithium hydroxide treatment, into two hydrazides via β-elimination of a central bis-2-carbonylethoxysulfone unit. It allows the creation of ONs derivatized with a hydrazide moiety at the 5′-, 3′- and both 5′- and 3′-termini, as well as two different hydrazide containing ONs at the same time, viz. in one sequence on the same solid support. In latter case one can, for example, synthesize two hydrazide containing ONs, where one is 5′-modified and second one is 3′-modified.     

Label-free electrochemical DNA sensor based on functionalised conducting copolymer

A simple and label-free electrochemical sensor for recognition of the DNA hybridization event was prepared based on a new functionalised conducting copolymer, poly[pyrrole-co-4-(3-pyrrolyl) butanoic acid]. This precursor copolymer can be easily electrodeposited on the electrode surface and shows high electroactivity in an aqueous medium. An amino-substituted oligonucleotide (ODN) probe was covalently grafted onto the surface of the copolymer in a one step procedure and tested on hybridization with complementary ODN segments. The cyclic voltammogram of ODN probe-modified copolymer showed very little change when incubated in presence of non-complementary ODN, while a significant, and reproducible, modification of the voltammogram was observed after addition of complementary ODN. The AC impedance spectrum showed an increased charge transfer resistance (Rct) and double layer capacitance of the sensor film after hybridisation. Sensors with thinner films showed higher sensitivity than thicker films, suggesting that hybridisation at or near the surface of the film produces a larger change in electrical properties than that within the body of the film.     

Optic nerve histopathology in a case of Wolfram Syndrome: A mitochondrial pattern of axonal loss

Mitochondrial dysfunction in Wolfram Syndrome (WS) is controversial and optic neuropathy, a cardinal clinical manifestation, is poorly characterized. We here describe the histopathological features in postmortem retinas and optic nerves (ONs) from one patient with WS, testing the hypothesis that mitochondrial dysfunction underlies the pathology. Eyes and retrobulbar ONs were obtained at autopsy from a WS patient, and compared with those of a Leber hereditary optic neuropathy (LHON) patient and one healthy control. Retinas were stained with hematoxylin & eosin for general morphology and ONs were immunostained for myelin basic protein (MBP). Immunostained ONs were examined in four “quadrants”: superior, inferior, nasal, and temporal. The WS retinas displayed a severe loss of retinal ganglion cells in the macular region similar to the LHON retina, but not in the control. The WS ONs, immunostained for MBP, revealed a zone of degeneration in the temporal and inferior quadrants. This pattern was similar to that seen in the LHON ONs but not in the control. Thus, the WS patient displayed a distinct pattern of optic atrophy observed bilaterally in the temporal and inferior quadrants of the ONs. This arrangement of axonal degeneration, involving primarily the papillomacular bundle, closely resembled LHON and other mitochondrial optic neuropathies, supporting that mitochondrial dysfunction underlies its pathogenesis.     

Sequence-dependent cytotoxicity of second-generation oligonucleotides

In this study, we have examined the potential of second-generation antisense chimeric 2′-O-(2-methoxy)ethyl/DNA phosphorothioate oligonucleotides (ONs) to affect cell growth through non-antisense mechanisms. Evaluation of a series of ONs demonstrated that only a small number were cytotoxic at concentrations close to those required for antisense activity. Toxicity of the ONs appeared to be sequence dependent and could be affected by base and backbone modifications. Caspase-3 activation occurs with some ONs and it is most likely secondary to necrosis rather than apoptosis, since cells treated with toxic ONs did not show chromatin condensation, but did exhibit high-extracellular lactate dehydrogenase activity. Caspase-3 activation does not correlate with and appears not to be required for the inhibition of cell proliferation. Toxicity was only observed when ONs were delivered intracellularly. The mechanism by which one of the most cytotoxic ON produces cytotoxicity was investigated in more detail. Treatment with the cytotoxic ON caused disruption of lysosomes and Pepstatin A, a specific inhibitor of aspartic proteases, reduced the cytotoxicity of the ON. Reduction of lysosomal aspartic protease cathepsin D by prior treatment with cathepsin D-specific antisense ON did not attenuate the cytotoxicity, suggesting that other aspartic proteases play a crucial role in the cellular proliferation inhibition by ONs.     

Binding of phosphorothioate oligonucleotides to zwitterionic liposomes

Although double-stranded DNA (dsDNA) has been shown to bind to zwitterionic lipids, it has been reported that this association is stronger for disordered (L(alpha)) phase lipids than for well-ordered (L(beta)) lipids. In this work, the interaction of single-strand phosphorothioate oligonucleotides (ONs) with unilamellar liposomes of saturated and unsaturated zwitterionic phosphocholines (PCs) and phosphoroethylamine (PE) was investigated. It is shown that the association of phosphorothioate ONs to diacyl glycerophosphocholines is strong, but only for L(beta) phase or otherwise ordered bilayers. There is no measurable affinity for PE lipids. The apparent affinity of three different phosphorothioate ONs for L(beta) phase 1,2-dipalmitoyl-sn-glycero-3-phosphocholine (DPPC) has been measured and the dissociation constants were on the order of 10(-7) M. Purine-rich ON sequences had stronger binding to DPPC liposomes than did pyrimidine-rich sequences, but there were other sequence-dependent factors. This exceptionally high affinity could be an important consideration in ON uptake, delivery, and biodistribution.     

DNA hybridization sensor based on pentacene thin film transistor

A DNA hybridization sensor using pentacene thin film transistors (TFTs) is an excellent candidate for disposable sensor applications due to their low-cost fabrication process and fast detection. We fabricated pentacene TFTs on glass substrate for the sensing of DNA hybridization. The ss-DNA (polyA/polyT) or ds-DNA (polyA/polyT hybrid) were immobilized directly on the surface of the pentacene, producing a dramatic change in the electrical properties of the devices. The electrical characteristics of devices were studied as a function of DNA immobilization, single-stranded vs. double-stranded DNA, DNA length and concentration. The TFT device was further tested for detection of λ-phage genomic DNA using probe hybridization. Based on these results, we propose that a "label-free" detection technique for DNA hybridization is possible through direct measurement of electrical properties of DNA-immobilized pentacene TFTs.     

Oligothiophene molecular beacons

Oligomers of thiophene are widely studied compounds for their electronic and optoelectronic properties. Despite their strong fluorescence, their use as markers for biomolecules, especially for oligonucleotides (ONs), is still largely unexplored. Here, we describe the synthesis of a series of ON molecular beacons employing different oligothiophenes as fluorescent probes and discuss their fluorescence emissions in comparative experiments with and without dabcyl as a quencher, in their hairpin and linear conformations, and as duplexes after hybridization with a complementary target.     

Rapid Catch and Signal (RCS) Technology Platform: Multiplexed Three-Color, 30 s Microwave-Accelerated Metal-Enhanced Fluorescence DNA Assays

We present an innovative “Rapid Catch and Signal” (DNA-RCS) technology for the simultaneous highly selective detection of multiple specific DNA sequences in solution. The DNA-RCS technology combines advantages of microwave-accelerated DNA hybridization (Rapid Catch) with the metal-enhanced fluorescence (MEF) technology (Signal), to enable specific DNA’s to be detected at high sensitivity within seconds. Fluorescent DNA labels, which play the role of molecular sensor probes, show a strong response upon DNA hybridization, due to fluorophore coupling with nanoparticle plasmons at a short (10–30 nm) distance from the surface. We have also shown that the fluorophore sensor probes demonstrate high photostability due to close proximity to a SiF surface, which significantly increases the total stability and reliability of the assay. Applications of the DNA-RCS technology in the life sciences, its advantages and benefits as compared to other DNA detection schemes, such as PCR, are subsequently discussed.     

MicroRNA fate upon targeting with anti-miRNA oligonucleotides as revealed by an improved Northern-blot-based method for miRNA detection

MicroRNAs (miRNAs) are small non-coding RNAs involved in fine-tuning of gene regulation. Antisense oligonucleotides (ONs) are promising tools as anti-miRNA (anti-miR) agents toward therapeutic applications and to uncover miRNA function. Such anti-miR ONs include 2'-O-methyl (OMe), cationic peptide nucleic acids like K-PNA-K3, and locked nucleic acid (LNA)-based anti-miRs such as LNA/DNA or LNA/OMe. Northern blotting is a widely used and robust technique to detect miRNAs. However, miRNA quantification in the presence of anti-miR ONs has proved to be challenging, due to detection artifacts, which has led to poor understanding of miRNA fate upon anti-miR binding. Here we show that anti-miR ON bound to miR-122 can prevent the miRNA from being properly precipitated into the purified RNA fraction using the standard RNA extraction protocol (TRI-Reagent), yielding an RNA extract that does not reflect the real cellular levels of the miRNA. An increase in the numbers of equivalents of isopropanol during the precipitation step leads to full recovery of the targeted miRNA back into the purified RNA extract. Following our improved protocol, we demonstrate by Northern blotting, in conjunction with a PNA decoy strategy and use of high denaturing PAGE, that high-affinity anti-miRs (K-PNA-K3, LNA/DNA, and LNA/OMe) sequester miR-122 without causing miRNA degradation, while miR-122 targeting with a lower-affinity anti-miR (OMe) seems to promote degradation of the miRNA. The technical issues explored in this work will have relevance for other hybridization-based techniques for miRNA quantification in the presence of anti-miR ONs.     

Nanocrystalline silicon-based oligonucleotide chips

A novel oligonucleotide array sensor has been developed with nanocrystalline Si (ncSi) substrates. The ncSi was prepared by electrochemical etching technique. Our study indicated that both the binding capacity and the hybridization efficiency are dependent upon the particle size of ncSi. In contrary, the chips developed with Si substrates exhibit the lower binding capacity and hybridization efficiency. The improved performances of the sensor chips are attributed to the large specific surface area of ncSi compared to the existing conventional techniques. The sensor chips with the ncSi substrate of 13 nm-sized particle can be regenerated and reused for at least 12 times. The oligonucleotide array sensor also shows high stability, which can bear relatively the stringent conditions (e.g. 80 degrees C, 75% of relative humidity and 3.6 klx of irradiation).     

Short,single-stranded oligonucleotides mediate targeted nucleotide conversion using extracts from isolated liver mitochondria

Site-specific single-nucleotide changes in chromosomal DNA of eukaryotic cells have been achieved using chimeric RNA/DNA oligonucleotides (ONs) and short single-stranded (SS) ONs. However, a variety of human diseases originate from single-point mutations in the genome of mitochondrial DNA. We previously demonstrated that extracts from highly purified rat liver mitochondria possess the essential enzymatic activity to mediate targeted single-nucleotide changes using chimeric ONs in vitro. However, different factor(s) and/or mechanism(s) appear to be involved in SS and RNA/DNA ON mediated DNA repair. Because mitochondria are deficient in certain factors involved in nuclear DNA repair pathways, we investigated whether mitochondria possess the enzymatic machinery for SS ON mediated DNA alterations. Using in vitro DNA repair assays based on mutagenized plasmids and a bacterial read-out system, SS ONs were designed to correct the point mutations in the genes encoded by the different plasmids. In this system, protein extracts from purified rat liver mitochondria and nuclei catalyzed similar levels of site-specific nucleotide modifications using SS ONs. Interestingly, extracts isolated from quiescent liver mediated significantly higher conversion rates than those isolated from regenerating liver. The results suggest that mitochondria contain the factors necessary for correction of single-point mutations by SS ONs. In addition, at least some are different than those required for DNA repair by RNA/DNA ONs. Moreover, correction with SS ONs appears to occur one strand at a time suggesting that repair of the DNA substrate involves strand transfer. The ability of unmodified SS ONs to mediate targeted alteration of the mitochondrial genome may provide a new tactic for treatment of certain mitochondrial-based diseases.     

Mismatching base-pair dependence of the kinetics of DNA-DNA hybridization studied by surface plasmon fluorescence spectroscopy

Two single-stranded DNAs consisting of complementary base pairs except for one mismatching base pair (MM1) can form double-stranded DNA by molecular recognition. This type of duplex is not as stable as that formed by MM0. In order to add to a better understanding of the physical mechanism of the hybridization and dissociation processes at sensor (chip) surfaces, we studied the kinetics of the MM1 hybridization by surface plasmon fluorescence spectroscopy. Target DNA strands labelled with a fluorescent molecule Cy5 at the 5′ end and hybridizing with the surface-attached probe DNA can be excited by the strong optical field of a surface plasmon resonance mode. The emitted fluorescence can be detected with high sensitivity. The affinity of a duplex was found to depend on the chemical nature, i.e. G–G, G–T etc., and on the position of the mismatching base pair along the 15mer duplex.     

Effects of oligonucleotide length, mismatches and mRNA levels on C-5 propyne-modified antisense potency.

To understand the parameters required for designing potent and specific antisense C-5 propynyl-pyrimidine-2'-deoxyphosphorothioate-modified oligonucleotides (C-5 propyne ONs), we have utilized a HeLa line that stably expresses luciferase under tight control of a tetracycline-responsive promoter. Using this sensitive and regulatable cell-based system we have identified five distinct antisense ONs targeting luciferase and have investigated the role that ON length, target mismatches, compound stability and intracellular RNA levels play in affecting antisense potency. We demonstrate that C-5 propyne ONs as short as 11 bases retained 66% of the potency demonstrated by the parent 15 base compound, that a one base internal mismatch between the antisense ON and the luciferase target reduced the potency of the antisense ON by 43% and two or more mismatches completely inactivated the antisense ON and that C-5 propyne ONs have a biologically active half-life in tissue culture of 35 h. In addition, by regulating the intracellular levels of the luciferase mRNA over 20-fold, we show that the potency of C-5 propyne ONs is unaffected by changes in the expression level of the target RNA. These data suggest that low and high copy messages can be targeted with equivalent potency using C-5 propyne ONs.