Simultaneous Targeting of Two Master Regulators of Apoptosis with Dual-Action PNA-and DNA-Peptide Conjugates

Abstract

Conjugation of peptides with oligonucleotides offers opportunities for combining the strengths of both biopolymer classes. Herein, we show that the combination of a peptide-based module with an antisense oligonucleotide module provides for enhancements of potency and a widened scope of cell delivery options. The peptide unit comprises a Smac mimetic compound (SMCs) which antagonizes the action of inhibitor of apoptosis proteins (IAPs) frequently overexpressed in cancer cells. To counteract SMC resistance, the antisense module downregulates the cellular FLICE-like protein (c-FLIP), a master regulator of the extrinsic apoptosis pathway. We compared c-FLIP antisense units based on oligophosphorothioate (PSO) and peptide nucleic acid (PNA) architectures. Owing to the ease of synthesis, PNA conjugates combined with a cell penetrating peptide (CPP) offer a seemingly ideal solution for cell delivery of dual activity agents. However, our investigations revealed that such congeners have to be handled with care to avoid off-Target effects. By contrast, PSO conjugates provided a more robust and specific activity for inducing death of SMC-resistant A549 cells due to a simultaneous activation of caspases and c-FLIP knockdown. We show that lipofection is a convenient approach for delivery of peptide-PSO conjugates into cells. The results highlight that the combination of the peptide and the DNA world confers properties inaccessible by the unconjugated components.