A Single Amide Linkage in the Passenger Strand Suppresses Its Activity and Enhances Guide Strand Targeting of siRNAs.

Potential in vivo applications of RNA interference (RNAi) require suppression of various off-target activities. Herein, we report that replacement of a single phosphate linkage between the first and second nucleosides of the passenger strand with an amide linkage almost completely abolished its undesired activity and restored the desired activity of guide strands that had been compromised by unfavorable amide modifications. Molecular modeling suggested that the observed effect was most likely due to suppressed loading of the amide-modified strand into Ago2 caused by inability of amide to adopt the conformation required for the backbone twist that docks the first nucleotide of the guide strand in the MID domain of Ago2.

Amide linkages mimic phosphates in RNA interactions with proteins and are well tolerated in the guide strand of short interfering RNAs.

While the use of RNA interference (RNAi) in molecular biology and functional genomics is a well-established technology, in vivo applications of synthetic short interfering RNAs (siRNAs) require chemical modifications. We recently found that amides as non-ionic replacements for phosphodiesters may be useful modifications for optimization of siRNAs. Herein, we report a comprehensive study of systematic replacement of a single phosphate with an amide linkage throughout the guide strand of siRNAs.

Fluorescent 2-Aminopyridine Nucleobases for Triplex-Forming Peptide Nucleic Acids.

Development of new fluorescent peptide nucleic acids (PNAs) is important for fundamental research and practical applications. The goal of this study was the design of fluorogenic nucleobases for incorporation in triplex-forming PNAs. The underlying design principle was the use of a protonation event that accompanied binding of a 2-aminopyridine (M) nucleobase to a G-C base pair as an on switch for a fluorescence signal.

Using triple-helix-forming Peptide nucleic acids for sequence-selective recognition of double-stranded RNA.

Non-coding RNAs play important roles in regulation of gene expression. Specific recognition and inhibition of these biologically important RNAs that form complex double-helical structures will be highly useful for fundamental studies in biology and practical applications in medicine. This protocol describes a strategy developed in our laboratory for sequence-selective recognition of double-stranded RNA (dsRNA) using triple-helix-forming peptide nucleic acids (PNAs) that bind in the major grove of the RNA helix.