Unusual chromatographic behavior of oligonucleotide sequence isomers on two different anion exchange HPLC columns

The retention behavior of the unmodified phosphodiester oligonucleotide sequence isomers was investigated on two different anion exchange columns: Biospher GMB 1000Q (based on DEAE-modified glycidyl methacrylate) and PolyWAX LP (based on silica with a crosslinked coating of linear polyethyleneimine). There was a notable difference in retention of oligonucleotides of the same composition but differing in the position of a single base. The most pronounced difference was observed between the oligonucleotides with the variable base in the end and in the center of the sequence. The use of either acetonitrile or 2-propanol as a mobile phase organic modifier did not markedly affect the retention time patterns. Prediction of the retention times of oligonucleotides must take into account the base position as well as identity. This is the first report of such a "same composition different sequence" effect, described for the short peptides, for synthetic oligonucleotides.     

Conjugation of chemical handles and functional moieties to DNA during solid phase synthesis with sulfonyl azides

Labelling of oligonucleotides with dyes, targeting ligands, and other moieties has become ever more essential in life-sciences. Conventionally, modifications are introduced to oligonucleotides during solid phase synthesis by special phosphoramidites functionalised with a chemical handle or the desired functional group. In this work, we present a facile and inexpensive method to introduce modifications to oligonucleotides without the need for special phosphoramidites. Sulfonyl azides are applied to react with one or more selected phosphite intermediates during solid phase synthesis. We have prepared 11 sulfonyl azides with different chemical handles such as amine, azide, alkyne, and thiol, and we have further introduced functionalities such as pyrene, other dyes, photo-switchable azobenzenes, and a steroid. The method is compatible with current phosphoramidite-based automated oligonucleotide synthesis and serves as a simple alternative to the unstable and expensive special phosphoramidites currently used for conjugation to oligonucleotides.     

Facile and Rapid Deprotection Conditions for the Cleavage of Synthetic Oligonucleotides from 1,4-Anhydroerythritol-Based Universal Polymer Support

In our previous report [Kumar, P.; Dhawan, G.; Chandra, R.; Gupta, K.C. Polyamine-assisted rapid and clean cleavage of oligonucleotides from cis-diol bearing universal support. Nucl. Acids Res. 2002, 30, e130 (1-8)], we demonstrated polyamine-mediated deprotection of oligonucleotides from cis-diol group bearing universal polymer support (I). However, vulnerability of the conventional dC^bz to modifications under these conditions compelled us to employ dC^ac during synthesis of oligonucleotide using conventional synthons. Here, a new set of simple and rapid deprotection conditions has been developed for the complete cleavage of oligonucleotides from the 1,4-anhydroerythritol-based universal polymer support employing conventional dC^bz synthon. Using manganese-imidazole complex in aqueous ammonium hydroxide (～30%), fully deprotected oligonucleotide sequences were obtained in 40 min, which were analyzed on reverse phase-HPLC and compared with the standard oligomers in terms of their retention time. Finally, their biological compatibility was established by analyzing PCR amplified products of npsA gene of N. meningitidis.     

Comparative evaluation of 99mTc-labeled aminothiols as possible brain perfusion imaging agents

Several new ^99mTc aminodithiols were prepared and evaluated comparatively in experimental animals. The ligands were diamine, triamine or tetramine dithiols. Substituents were either attached on one of the nitrogens or introduced in between the two nitrogens of diamino dithiol (DADT) backbone. ^99mTc-derivatives prepared by coupling DADT to secondary amines via ethylene group showed in mice high initial brain uptake and significant retention in brain tissue. These preparations were mixtures of more than one ^99mTc-complex differing in brain uptake and clearance from the brain. The highest brain retention (brain to blood ratio 2.53, 15 min p.i.) was achieved with the ^99mTc-complex prepared by coupling DADT with ethylene pyrrolidine. Lengthening the chain between the nitrogens of DADT moiety by introducing methyl or amino alkyl groups resulted in ^99mTc-complexes with poor brain accumulation.     

Identification of RNA linkage isomers by anion exchange purification with electrospray ionization mass spectrometry of automatically desalted phosphodiesterase-II digests

Among the possible contaminants unique to RNA are linkage isomers that are difficult to identify by standard oligonucleotide analysis techniques. In a prior study, we used nonporous and monolithic polymer anion exchangers for purification and demonstrated a method to identify the presence of the linkage isomers. We also suggested a confirming technique employing phosphodiesterase-II (PDase-II), an enzyme incapable of cleaving 2′-5′ linkages. We now present a method identifying the location of the linkage in the RNA isomer by anion exchange purification and electrospray ionization mass spectrometry (ESI-MS) of the digestion products. Because the ion-pair reversed-phase liquid chromatography (IP-RPLC) desalting methods we previously employed do not effectively separate oligonucleotides less than 6 bases from salt, we employed a direct reversed-phase method to automatically desalt the digestion products and then assessed the desalted digests by ESI-MS. The length and base composition of the fragments identified indicate that PDase-II cleaves up to and skips over the aberrant linkage and then resumes cleavage 1 or 2 bases to the 3′ side of the 2′-5′ linkage.     

Antisense technologies. Improvement through novel chemical modifications.

Antisense agents are valuable tools to inhibit the expression of a target gene in a sequence-specific manner, and may be used for functional genomics, target validation and therapeutic purposes. Three types of anti-mRNA strategies can be distinguished. Firstly, the use of single stranded antisense-oligonucleotides; secondly, the triggering of RNA cleavage through catalytically active oligonucleotides referred to as ribozymes; and thirdly, RNA interference induced by small interfering RNA molecules. Despite the seemingly simple idea to reduce translation by oligonucleotides complementary to an mRNA, several problems have to be overcome for successful application. Accessible sites of the target RNA for oligonucleotide binding have to be identified, antisense agents have to be protected against nucleolytic attack, and their cellular uptake and correct intracellular localization have to be achieved. Major disadvantages of commonly used phosphorothioate DNA oligonucleotides are their low affinity towards target RNA molecules and their toxic side-effects. Some of these problems have been solved in 'second generation' nucleotides with alkyl modifications at the 2' position of the ribose. In recent years valuable progress has been achieved through the development of novel chemically modified nucleotides with improved properties such as enhanced serum stability, higher target affinity and low toxicity. In addition, RNA-cleaving ribozymes and deoxyribozymes, and the use of 21-mer double-stranded RNA molecules for RNA interference applications in mammalian cells offer highly efficient strategies to suppress the expression of a specific gene.     

Modifications of guanine bases during oligonucleotide synthesis.

Guanine bases are sensitive to modification during automated DNA synthesis and processing reactions. Methods for the detection of two types of guanine modifications are described. The first method uses the higher reactivity of the modified G base to KMn04 oxidation than T bases, and thus allows detection by chemical DNA sequencing. The second method makes use of the Escherichia coli nucleotide excision repair enzyme UvrABC endonuclease which can detect "bulky" base modifications at each nucleotide in the synthetic DNA. Though the chemical structures of the two modifications are not known, they may be related. Both types of G modifications are often found in oligonucleotides synthesized by the methoxy-diisopropyl-phosphoramidite (MEDP) chemistry but non-detectable in the products of the beta-cyanoethyl-diisopropyl-phosphoramidite (CEDP) chemistry. The Rubin and Schmid pyrimidine-specific chemical DNA sequencing procedure (Rubin, C.M., and Schmid, C.W. (1980) Nucleic Acids Res. 8, 4613-4619) was found to be applicable to oligonucleotides synthesized by the CEDP chemistry, and to oligonucleotides synthesized by the MEDP chemistry if precautionary measures are taken to destroy the signals produced by the highly KMnO4 sensitive modified guanine bases. We also show how chemical DNA sequencing might be useful for diagnosing other chemical modifications in synthetic oligonucleotides.     

Solid Phase Synthesis and Chromatographic Characteristics of Nucleophilic Agents Conjugated with Oligonucleotides Containing 5'-Terminal Carboxyl Group

Conjugates of amines or short peptides with oligonucleotides containing 5'-terminal carboxyl group were prepared by solid phase chemical synthesis. A correlation between the physicochemical parameters and retention times of the synthesized conjugates was established by ion-pair reversed-phase HPLC.     

Synthesis and properties of oligodeoxyribonucleotides containing an ethylated internucleotide phosphate

Internucleotide phosphotriesters comprise an important class of DNA lesions produced by carcinogenic alkylating agents. To avoid confusion resulting from the presence of other DNA lesions, synthetically prepared oligonucleotides containing ethylated internucleotide phosphates as the sole form of damage were employed to investigate several chemical and biochemical properties of DNA alkyl phosphotriesters. A total of four oligonucleotides were synthesised for this study, the dimers Tp(Et)T and pTp(Et)T and the decamer d-TpTpTp(Et)TpCpTpApTpTpT together with its unmodified analogue. The dimers were characterized by UV and phosphorus NMR spectroscopy and the decamers by two-dimensional homochromatography, alkali hydrolysis, and variable-temperature circular dichroism (CD). Alkali hydrolysis of the ethylated decamer produced strand breaks in approximately 75% of the molecules. This is in close agreement with data previously obtained for dinucleoside ethyl phosphotriesters and triesters in alkylated cellular DNA. Results from the CD study suggest that the ethyl substituent does not disrupt base stacking within the oligomer. The interactions of two enzymes with the alkylated oligonucleotides were examined. First, it was found that ethylation of the internucleotide phosphate renders TpT inactive as a substrate for T4 polynucleotide kinase, implying that a negative charge is required on the 3'-phosphate group of the nucleotide to be phosphorylated. Hence, postlabeling assays of DNA damage that depend upon enzymatic phosphorylation of modified 3'-nucleotides cannot be applied to dinucleoside alkyl phosphotriesters. Second, both decamers, when annealed to a single-stranded plasmid template, were able to prime DNA synthesis, catalyzed by Escherichia coli DNA polymerase I, with equal effectiveness. The use of this reaction as a means of site-specifically incorporating phosphotriesters into viral vectors is recognized.     

Solid phase synthesis and chromatographic characteristics of nucleophilic agents conjugated with oligonucleotides containing 5'-terminal carboxyl group

Conjugates of amines or short peptides with oligonucleotides containing 5'-terminal carboxyl group were prepared by solid phase chemical synthesis. A correlation between the physicochemical parameters and retention times of the synthesized conjugates was established by ion-pair reversed-phase HPLC.     

Molecular recognition of oligonucleotides and plasmid DNA by l‐methionine

The present study explores the effect of oligonucleotide composition on the mechanism of retention to l ‐methionine agarose support by chromatography and saturation transfer difference (STD)‐nuclear magnetic resonance (NMR) techniques. All chromatographic experiments were performed using 1.5 M (NH₄)₂SO₄. The binding profiles obtained by chromatography show that oligonucleotides with thymine had the highest retention time. In general, the larger homo‐oligonucleotides are more retained to the l ‐methionine agarose support. Moreover, the study with hetero‐oligonucleotides confirms that the presence of guanine reduces the retention on the l ‐methionine chromatographic support. These results are in accord with STD‐NMR experiments, which show that the strongest signals were observed for the methyl group of thymine, and no STD signals were observed for the guanosine protons. Finally, the retention behaviour of linear plasmid DNA (pDNA) with different sizes and base composition (2.7‐kbp pUC19, 6.05‐kbp pVAX1‐LacZ, 7.4‐kbp pVAX1‐LacZgag and 14‐kbp pcDNA‐based plasmid) was also evaluated by chromatography. The results indicate that the underlying mechanism of retention involves not only hydrophobic interactions but also other elementary interactions responsible for the biorecognition of pDNA molecules by l ‐methionine ligands. Copyright © 2014 John Wiley & Sons, Ltd.     

Heterocyclic modifications of oligonucleotides and antisense technology

Modification of the heterocyclic moiety of oligonucleotides has led to the discovery of potent antisense compounds. This review describes the physicochemical factors that are responsible for duplex stabilization through base modification. A summary is given of the different heterocyclic modifications that can be used to beneficially influence this duplex stability. The biologic activity of base-modified oligonucleotides is described, and the different factors that are important for obtaining in vivo antisense activity with heterocyclic-modified oligonucleotides are summarized.     

2′-Fluoro-modified phosphorothioate oligonucleotide can cause rapid degradation of P54nrb and PSF

Synthetic oligonucleotides are used to regulate gene expression through different mechanisms. Chemical modifications of the backbone of the nucleic acid and/or of the 2′ moiety of the ribose can increase nuclease stability and/or binding affinity of oligonucleotides to target molecules. Here we report that transfection of 2′-F-modified phosphorothioate oligonucleotides into cells can reduce the levels of P54nrb and PSF proteins through proteasome-mediated degradation. Such deleterious effects of 2′-F-modified oligonucleotides were observed in different cell types from different species, and were independent of oligonucleotide sequence, positions of the 2′-F-modified nucleotides in the oligonucleotides, method of delivery or mechanism of action of the oligonucleotides. Four 2′-F-modified nucleotides were sufficient to cause the protein reduction. P54nrb and PSF belong to Drosophila behavior/human splicing (DBHS) family. The third member of the family, PSPC1, was also reduced by the 2′-F-modified oligonucleotides. Preferential association of 2′-F-modified oligonucleotides with P54nrb was observed, which is partially responsible for the protein reduction. Consistent with the role of DBHS proteins in double-strand DNA break (DSB) repair, elevated DSBs were observed in cells treated with 2′-F-modified oligonucleotides, which contributed to severe impairment in cell proliferation. These results suggest that oligonucleotides with 2′-F modifications can cause non-specific loss of cellular protein(s).     

Mass spectrometry of oligonucleotides

Expanding research in the field of modified oligonucleotides demands suitable analytical tools for size and purity verification of known compounds and accurate structure elucidation of unknowns. There is a need for characterization of the types and sites of modifications in oligonucleotides and to identify and sequence selected candidates originating from synthesis. The potential of electrospray tandem mass spectrometry (ESI-MS/MS) for structural characterization and sequencing of oligonucleotides is demonstrated. The fundamental behavior of DNA, RNA, and selected modified oligonucleotides in gas-phase is shown. Since gas-phase dissociation does not demand specific structural prerequisites, the method bears a great potential for rapid and most accurate characterization of modified oligonucleotides, e.g. from combinatorial libraries.     

Effects of base modifications on antisense properties of 2'-O-methoxyethyl and PNA oligonucleotides

A recently developed antisense splicing assay was used to determine the relative activities of 2'-O-methoxyethoxy (2'-MOE) phosphorothioate oligonucleotides containing base modifications. In the assay, RNase H-inactive oligonucleotides are used to block aberrant splicing and restore correct splicing of an Enhanced Green Fluorescence Protein (EGFP) reporter pre-mRNA stably expressed in HeLa cells. Thus, the extent of EGFP upregulation is proportional to the antisense activity of the tested molecule. The base modifications included C-5 propynyl analogs of uridine and cytidine and phenoxazine and G-clamp analogs of cytosine. Base-modified 2'-MOE oligonucleotides were delivered to the HeLa EGFP-654 test cells by cationic lipid transfection or scrape-loading or without any delivery method (free uptake). When delivered with a cationic lipid, the G-clamp and phenoxazine oligomers showed increases in activity over the unmodified 2'-MOE parent compound. However, when delivered by scrape-loading or without a delivery method, the unmodified oligomer performed best. The results suggest that base modifications do not enhance the free uptake activity of RNase H inactive 2'-MOE oligomers.     

Synthesis and thermodynamics of oligonucleotides containing chirally pure R(P) methylphosphonate linkages.

Methylphosphonate (MP) oligodeoxynucleotides (MPOs) are metabolically stable analogs of conventional DNA containing a methyl group in place of one of the non-bonding phosphoryl oxygens. All 16 possible chiral R(P) MP dinucleotides were synthesized and derivatized for automated oligonucleotide synthesis. These dimer synthons can be used to prepare (i) all-MP linked oligonucleotides having defined R(P) chirality at every other position (R(P) chirally enriched MPOs) or (ii) alternating R(P) MP/phosphodiester backbone oligonucleotides, depending on the composition of the 3'-coupling group. Chirally pure dimer synthons were also prepared with 2'-O-methyl sugar modifications. Oligonucleotides prepared with these R(P) chiral methylphosphonate linkage synthons bind RNA with significantly higher affinity than racemic MPOs.     

An improved CPG support for the synthesis of 3'-amine-tailed oligonucleotides.

A new controlled-pore glass (CPG) support is described that allows for the direct synthesis of oligonucleotides bearing a 3'-aminohexyl tail. This solid support (AH-CPG) exhibits superior performance as compared to a commercially available 3'-amine CPG. The AH-CPG is prepared from 6-aminohexan-1-ol with a unique protecting group for the amine that also functions as the site of attachment to the CPG. A 3'-amine-tailed oligodeoxynucleotide (ODN) was prepared from this support using standard phosphoramidite coupling and deprotection conditions. The 3'-amine-tailed ODN was subsequently modified with an acridinylpropionic acid tetrafluorophenyl ester. Facile synthesis of the AH-CPG and the stability of the deprotected product makes this functionalized solid support especially useful for preparation of oligonucleotides bearing 3'-amine tails and other modifications.     

Polyamine-assisted rapid and clean cleavage of oligonucleotides from cis-diol bearing universal support

Polyamine-assisted deprotection conditions have been developed for the rapid and clean cleavage of oligonucleotide chains from a cis-diol group bearing universal polymer support, making it compatible with modern oligonucleotide synthesis via all types of phosphoramidite synthons, including base labile protecting group bearing synthons as well. The synthesized oligonucleotides were found to be comparable with the corresponding standard oligomers with respect to their retention time on HPLC, mass on MALDI-TOF and biological activity in PCR amplification.     

Specific inhibition of hepatitis C viral gene expression by non-polar (phenylalkyl)phosphonates

Different phenylalkyl backbone modified antisense oligonucleotides complementary to the Hepatitis C virus (HCV) RNA nucleotides 326-342 were synthesized. The lipohilic character of modified oligonucleotides was determined from RP-HPLC retention times. The inhibitory effect of these antisense oligonucleotides on HCV gene expression was analyzed in an in vitro test system.