The polyanionic nature of oligonucleotides and their enzymatic degradation present challenges for the use of siRNA in research and therapy; among the most notable of these is clinically relevant delivery into cells. To address this problem, we designed and synthesized the first members of a new class of guanidinium-rich amphipathic oligocarbonates that noncovalently complex, deliver, and release siRNA in cells, resulting in robust knockdown of target protein synthesis in vitro as determined using a dual-reporter system. The organocatalytic oligomerization used to synthesize these co-oligomers is step-economical and broadly tunable, affording an exceptionally quick strategy to explore chemical space for optimal siRNA delivery in varied applications. The speed and versatility of this approach and the biodegradability of the designed agents make this an attractive strategy for biological tool development, imaging, diagnostics, and therapeutic applications.amphipathic co-oligomers | nanoparticles | oligonucleotide delivery | biodegradable oligomers | organocatalysis R NA interference (RNAi) is an emerging technology that is revolutionizing many strategic approaches to biochemical pathway analysis, drug discovery, and therapy (1-6). As part of the RNAi pathway, small interfering RNAs (siRNAs) induce post-transcriptional, sequence-specific gene silencing utilizing endogenous intracellular machinery to selectively suppress gene expression and, thereby, reduce target protein synthesis (7). The net effect is equivalent to protein inhibition without the use of small molecule inhibitors. The specificity of RNAi also allows one to make inhibitors against previously undruggable targets. Both the ubiquity of the RNAi pathway within the body and the ease with which siRNA can be used to suppress a specific target of interest have made siRNAs a promising class of molecules for the treatment of cancer, viral infections, ocular disorders, and genetic diseases (5). In 2004, the first siRNA-based therapy entered Phase 1 clinical trials (4). Since then, several other RNAi-based therapies have reached clinical evaluation for a number of indications including cancer, viral infections, and genetic skin disorders (5,8,9). Notwithstanding this progress, formidable challenges remain for the application of RNAi technology in basic research and therapy, the most fundamental of which is delivery of siRNA across biological barriers.The siRNAs are double-stranded RNA molecules typically consisting of a 19-23 base-paired region with two 3′ overhanging nucleotides. It is polyanionic, polar, and large (ca. 13 kDa), compared to small molecule therapeutics. These physical properties suppress or prevent its unassisted passage through nonpolar membranes and, thus, its access to the intracellular RNA-induced silencing complex (RISC) components required for target protein knockdown (6). This problem is further exacerbated by siRNA's susceptibility to enzymatic degradation (i.e., RNases) (3). To address these problems, two strategies have been pursued: d...
