Improvements to Hybridization-Ligation ELISA Methods to Overcome Bioanalytical Challenges Posed by Novel Oligonucleotide Therapeutics.

Abstract

As oligonucleotides (ONs) and similar nucleic acid therapeutic modalities enter development pipelines, there is continual need to develop bioanalytical methodologies addressing unique challenges they pose. Novel ONs back bone chemistries, especially those enabling stereochemical control, and base modifications are being exploited to improve pharmacological properties, potency, and increase half-lives. These changes have strained established methods, oftentimes precluding development of assays sensitive and specific enough to meet the needs of preclinical programs. For stereopure ONs representing a single molecular species, nontrivial presence of chain-shortened metabolites in biological samples necessitate assays with high specificity. To meet these needs, this report presents a toolbox of novel techniques, easy to implement for existing hybridization-ligation enzyme-linked immunosorbent assay formats, which address this challenge and yield significant sensitivity and specificity enhancements. Ligation efficiency was improved up to 61-fold through addition of polyethylene glycol, betaine, or dimethylsulfoxide, mitigating major differences among sequence-matched ONs of varying stereopurity, enabling sensitivities below 0.100 ng/mL for quantitation. These improvements enabled further refinement of capture probe designs engendering sufficient specificity to discriminate N-1 chain-shortened metabolites at both the 5′ and 3′ end of the ONs. These generalizable methods advance the performance of mainstay bioanalytical assays, facilitating research and development of innovative ONs therapeutics.