PHOSPHOROTHIOATE OLIGONUCLEOTIDE METABOLISM: CHARACTERIZATION OF THE “N+”-MER BY CE AND HPLC-ES/MS

Analytical techniques for characterizing diastereomers of phosphorothioated oligonucleotides

Oligonucleotides have emerged as powerful therapeutics for treating diverse diseases. To fully unlock the therapeutic potential of oligonucleotides, there is still a great need to further improve their drug-like properties. Numerous chemical modifications have been explored to achieve this goal, with phosphorothioation being one of the most widely used strategies. However, phosphorothioate modification produces diastereomers that are reported to have different properties and performances, demanding detailed characterization of these diastereomers. Here we provide an overview of phosphorothioated oligonucleotide diastereomers, covering their origin and configurations, physicochemical and pharmacological properties, and stereo-selective chemical synthesis, followed by a summary of currently available analytical techniques for characterizing these diastereomers, with a focus on liquid chromatography-based approaches, including ion-pair reversed-phase liquid chromatography, anion exchange chromatography, mixed-mode chromatography, and hybrid approaches. Non-chromatographic techniques, such as capillary electrophoresis, spectroscopy and other methods, are also being reviewed.

Chromatographic approaches for the characterization and quality control of therapeutic oligonucleotide impurities

Phosphorothioate (PS) oligonucleotides are a rapidly rising class of drugs with significant therapeutic applications. However, owing to their complex structure and multistep synthesis and purification processes, generation of low-level impurities and degradation products are common. Therefore, they require significant investment in quality control and impurity identification. This requires the development of advanced methods for analysis, characterization and quantitation. In addition, the presence of the PS linkage leads to the formation of chiral centers which can affect their biological properties and therapeutic efficiency. In this review, the different types of oligonucleotide impurities and degradation products, with an emphasis on their origin, mechanism of formation and methods to reduce, prevent or even eliminate their production, will be extensively discussed. This review will focus mainly on the application of chromatographic techniques to determine these impurities but will also discuss other approaches such as mass spectrometry, capillary electrophoresis and nuclear magnetic resonance spectroscopy. Finally, the chirality and formation of diastereomer mixtures of PS oligonucleotides will be covered as well as approaches used for their characterization and the application for the development of stereochemically-controlled PS oligonucleotides.

Advantages of ion-exchange chromatography for oligonucleotide analysis

The rapid development of therapeutic oligonucleotides (ONs) has created a need for in-depth characterization of ONs, beyond previous requirements. The natural migration to LC-MS requires the use of chromatography with MS-compatible eluents to introduce the large, highly charged biopolymers into the mass spectrometer. Most frequently this employs ion-pair reversed-phase liquid chromatography, which may leave gaps in the characterization, but these can be filled with the use of high-resolution ion-exchange chromatography. Several classes of isobaric isomers are among the impurities that will require further separation prior to MS analysis. This review shows how the use of ion exchange as an additional orthogonal analytical method can be used as standalone or interfaced with MS to achieve the highest possible analytical coverage in the characterization and quantification of impurities present in single- and double-stranded ON formulations. Some of these techniques have been in use for some time and the importance of others is just being recognized.

Separation of oligonucleotide phosphorothioate diastereoisomers by pellicular anion-exchange chromatography

Synthetic oligonucleotides (ONs) are often prepared for development of therapeutic candidates. Among the modifications most often incorporated into therapeutic ONs are phosphorothioate (PT) linkages. The PT linkage introduces an additional chiral center at phosphorus to the chiral centers in D-ribose (and 2-deoxy-D-ribose) of the nucleic acid. Therefore, modified linkages can produce a diastereoisomer pair ([Rp] and [Sp]) at each PT linkage. These isomers are of identical length, sequence, charge and mass, and are not reliably separated by most chromatographic approaches (e.g., reversed phase chromatography) unless the ON is very short. Further these isomers are not distinguishable by single-stage mass spectrometry. During chromatography of a purified anti-NGF (nerve growth factor) aptamer containing 37 bases with 2 PT linkages by monolithic pellicular anion-exchange (pAE) column, we observed four components. The four components were postulated to be: (i) distinct folding conformations; (ii) fully and partially athioated aptamers; or (iii) PT diastereoisomers. Fractionation of the components, followed by de- and re-naturation failed to produce the original forms by refolding, eliminating option (i). Mass spectrometry of the fractionated, desalted samples revealed no significant mass differences, eliminating option (ii). Oxidative conversion of the PT to phosphodiester (PO) linkages in each of the purified components produced a single chromatographic peak, co-eluting with authentic PO aptamer, and having the PO aptamer mass. We conclude that the components resolved by pAE chromatography are diastereoisomers arising from the two PT linkages. Hence, pAE chromatography further enhances characterization of ON therapeutics harboring limited PT linkages and having up to 37 bases.

A combined solid phase extraction/capillary gel electrophoresis method for the determination of phosphorothioate oligodeoxynucleotides in biological fluids, tissues and feces

A novel biological sample clean-up procedure has been developed for the determination of phosphorothioate oligodeoxynucleotides (PS-ODNs) and derived metabolites in biological fluids (plasma, urine and bile) and in tissues and feces from mice and rats. This method uses a one-step C18 solid-phase extraction (SPE) for biological matrix removal, and it uses capillary gel electrophoresis (CGE) for analyte detection. The assay is specific, and its linearity is superb (r>0.99) for IV-AS (a 13-mer PS-ODN) and PS19 (a 19-mer PS-ODN) in a variety of biological matrices. For both IV-AS and PS19, the precision, accuracy and absolute recovery values were found to be <20%, +/-20% and 80-120%, respectively. The LODs of IV-AS and PS19 were 0.6 mg/l for plasma, 0.8 mg/l for rat urine and bile, 6 microg/g for rat tissues, and 10 microg/g for rat feces, with a signal-to-noise ratio of 3 (S/N=3). This method has been successfully applied to the analysis and quantitation of PS-ODNs in various biological samples arising from preclinical pharmacokinetic studies.

Application of LC-MS for quantitative analysis and metabolite identification of therapeutic oligonucleotides

Therapeutic oligonucleotides (OGNs) have been studied extensively in the recent years as novel agents designed to selectively and specifically inhibit target gene expression in cell culture, in animal disease models and in human. This review summarizes applications of liquid chromatography coupled with mass spectrometry or tandem mass spectrometry (LC-MS or LC-MS/MS) for quantitative analysis of therapeutic OGNs and characterization of their metabolism in vitro and in vivo described in the literature over the past 10 years. Although the applications of LC-MS or LC-MS/MS to the molecular mass measurement, sequence determination, DNA adducts identification, detection of mutations and characterization of covalent and/or noncovalent DNA/RNA complexes have been comprehensively reviewed in a few excellent review papers. The quantitative bioanalysis and metabolite identification of therapeutic OGNs using LC-MS or LC-MS/MS have not been covered. This review covers technical issues, current approaches and applications of LC-MS or LC-MS/MS for quantitative analysis of OGNs in biological matrices and characterization of their in vitro and in vivo metabolism. Finally, some conclusions are drawn and prospects of LC-MS in quantitative analysis and metabolism characterization of therapeutic OGNs are discussed.

Purification of antisense oligonucleotides

Chromatography is an effective tool for obtaining high-purity synthetic oligonucleotides for a variety of end uses, including antisense drug therapy. Reversed-phase and anion-exchange chromatographies are widely used techniques for this application. While selectivity of these techniques can be modified by methods such as ion-pair RP-HPLC or affinity chromatography, these are presently used only at small scales. RP chromatography makes use of terminal hydrophobic-protecting groups to increase retention and selectivity. The main advantages of the RP method are its utility for the purification of a wide variety of modified oligonucleotide structures, its applicability across a range of terminal hydrophobic groups, such as fluorescein, and its ready use from small scale to very large scale with a minimal requirement for process development. AX-HPLC can also give high-purity products at generally higher media capacities. A more extensive method development effort is typically required for the AX-HPLC purification of AO. The AX yield per unit operation can be lower, but the isolated yield of DMT-off desalted oligonucleotide can be equal to or higher than that from RP-HPLC. As additional AO drugs enter and mature in the market, there will be a potential need for ton-scale purification processes. AX provides a way to scale up production on somewhat less expensive equipment with reduced organic solvent requirements.

A nonradioisotope biomedical assay for intact oligonucleotide and its chain-shortened metabolites used for determination of exposure and elimination half-life of antisense drugs in tissue

Rigorous extraction methods coupled with capillary gel electrophoresis (CGE) provide a basis for a nonradiolabel assay for quantitation of intact antisense drug and its numerous chain-shortened metabolites. As part of the validation of the CGE method, we compared the quantitation of unlabeled ISIS 3521 (ISI 641A) and its chain-shortened metabolites with total radioactivity of [(35)S]-ISIS 3521. ISIS 3521 was labeled on the fifth nucleotide linkage from the 5'-end with (35)S by well-established methods. Multiple tissues collected from rats after administration of [(35)S]-ISIS 3521 were assayed by both radiolabel (liquid scintillation spectroscopy) and CGE methods. The CGE method provided accurate quantitation of the drug and its metabolites in kidney cortex and liver tissues. The correlation between methods for multiple tissues over time was excellent with 88.5% of the measurements being statistically equivalent. These data suggest that CGE is an accurate means of quantitating oligonucleotide in tissue and that it compares favorably with traditional radiochemical techniques. Clearance half-lives for total measurable oligonucleotides were equivalent to clearance of total radioactivity in both liver and kidney with the longest clearance half-life associated with the kidney.

Antisense therapeutics

The field of antisense therapeutics has attracted great interest during the past decade. A large body of literature has recently appeared in which the antisense mechanism is claimed to be involved and a number of human clinical trials are underway. Questions regarding the specificity of action and side effects of antisense phosphorothioate oligonucleotides have arisen simultaneously.

Pharmacokinetics and metabolism of an oligodeoxynucleotide phosphorothioate (GEM91) in cynomolgus monkeys following intravenous infusion

The pharmacokinetics and metabolism of an antisense oligonucleotide phosphorothioate (GEM91) were studied in cynomolgus monkeys following intravenous infusion. [35S]-Labeled GEM91 was administered to 12 monkeys by means of a 2-hour intravenous infusion at a dose of 4 mg/kg. Plasma pharmacokinetic analysis revealed that the maximum plasma concentration was 41.7 microg equivalents/ml, which was achieved in 2.13 hours. The plasma elimination half-life was 55.8 hours based on radioactivity levels. Urinary excretion represented the major pathway of elimination, with 70% of the administered dose excreted in urine over 240 hours. The oligonucleotide was widely distributed to tissues. The highest concentrations were observed in the liver and kidney. Analysis of the extracted oligonucleotide following post-labeling with [32p] on polyacrylamide gel electrophoresis showed the presence of both intact and degraded oligonucleotide in plasma, kidney, liver, spleen, and lymph nodes. Based on the methods used for post-labeling (either 3'-end or 5'-end), different patterns of bands were observed on polyacrylamide gel electrophoresis, suggesting metabolic modification of the administered oligonucleotide.