Effects of side chain configuration and backbone spacing on the gene delivery properties of lysine-derived cationic polymers.

A series of lysine-based oligomers (18 residues) that differ in side chain configuration or side chain spacing along the backbone was tested for DNA transfection activity. Although materials constructed from lysine are not the most effective polymeric transfection agents, we have chosen L-lysine-based molecules as a starting point because this system allows us to examine the functional effects of incremental changes in polycation structure. The oligomer constructed from beta(3)-homolysine (beta(3)-hLys) and that from alpha-D-lysine were superior to an alpha-L-lysine 18-mer in gene delivery assays. This improved activity is attributed to the fact that the alpha-L-peptide is a protease substrate while the other 18-mers are not. This conclusion is supported by the effects of chloroquine on transfection activity, based on the protease inhibition activity of chloroquine. To our knowledge, these results represent the first direct comparison of a D-lysine oligomer with an L-lysine oligomer in the context of gene delivery. Poly(beta(3)-hLys) was synthesized from the ring opening polymerization of the corresponding lactam. The DNA transfection ability of this polymer was compared with that of commercially available poly(L-lysine) (PLL). In each case the polymer was more active than the corresponding oligomer.

Catalytic transamidation under moderate conditions.

The carboxamide group is generally inert, except under harsh conditions or in the presence of highly evolved enzymes. We have identified several metal complexes that efficiently catalyze transamidation reactions of amide/amine mixtures under moderate conditions. This unprecedented reactivity represents an important step toward our long-term goal of using dynamic combinatorial chemistry to generate new amide-based molecules with interesting structures and functions.