Hydrophobic
Organic Linkers in the Self-Assembly of
Small Molecule-DNA Hybrid Dimers: A Computational–Experimental
Study of the Role of Linkage Direction in Product Distributions and
Stabilities
posted on 2015-12-17, 00:55authored byIlyas Yildirim, Ibrahim Eryazici, SonBinh T. Nguyen, George C. Schatz
Detailed
computational and experimental studies reveal the crucial
role that hydrophobic interactions play in the self-assembly of small
molecule-DNA hybrids (SMDHs) into cyclic nanostructures. In aqueous
environments, the distribution of the cyclic structures (dimers or
higher-order structures) greatly depends on how well the hydrophobic
surfaces of the organic cores in these nanostructures are minimized.
Specifically, when the cores are attached to the 3′-ends of
the DNA component strands, they can insert into the minor groove of
the duplex that forms upon self-assembly, favoring the formation of
cyclic dimers. However, when the cores are attached to the 5′-ends
of the DNA component strands, such insertion is hindered, leading
to the formation of higher-order cyclic structures. These computational
insights are supported by experimental results that show clear differences
in product distributions and stabilities for a broad range of organic
core-linked DNA hybrids with different linkage directions and flexibilities.