A variety of non-covalent interactions (including hydrogen bonding, ionic interactions, metal coordination and desolvation/solvation) have been utilized to organize oligomers into well-defined structures. Herein is described a survey of aromatic foldamers that capitalize on electrostatic complementarity of substituted aromatic units to drive folding and assembly in aqueous environments. A brief description of recent advances in the understanding of aromatic interactions is provided, followed by examples of foldamers that exploit interactions between aromatic units to drive their assembly in predictable fashion. The history of our aromatic foldamers is traced from the first structure designed to fold into a pleated structure in an aqueous environment to a heteroduplex system more related to nucleic acids. Taken together, the results demonstrate that electrostatic complementarity of aromatic units provides a versatile framework for driving predictable folding and assembly in aqueous environments.
Two novel DNA base
surrogate phosphoramidites 1 and 2, based
upon relatively electron-rich 1,5-dialkoxynaphthalene
(DAN) and relatively electron-deficient 1,4,5,8-naphthalenetetracarboxylic
diimide (NDI), respectively, were designed, synthesized, and incorporated
into DNA oligonucleotide strands. The DAN and NDI artificial DNA bases
were inserted within a three-base-pair region within the interior
of a 12-mer oligonucleotide duplex in various sequential arrangements
and investigated with CD spectroscopy and UV melting curve analysis.
The CD spectra of the modified duplexes indicated B-form DNA topology.
Melting curve analyses revealed trends in DNA duplex stability that
correlate with the known association of DAN and NDI moieties in aqueous
solution as well as the known favorable interactions between NDI and
natural DNA base pairs. This demonstrates that DNA duplex stability
and specificity can be driven by the electrostatic complementarity
between DAN and NDI. In the most favorable case, an NDI–DAN–NDI
arrangement in the middle of the DNA duplex was found to be approximately
as stabilizing as three A–T base pairs.
Small molecules that bind DNA in a sequence-specific
manner could
act as antibiotic, antiviral, or anticancer agents because of their
potential ability to manipulate gene expression. Our laboratory has
developed threading polyintercalators based on 1,4,5,8-naphthalene
diimide (NDI) units connected in a head-to-tail fashion by flexible
peptide linkers. Previously, a threading tetraintercalator composed
of alternating minor–major–minor groove-binding modules
was shown to bind specifically to a 14 bp DNA sequence with a dissociation
half-life of 16 days [Holman, G. G., et al. (2011) Nat. Chem.
3, 875–881]. Herein are described new NDI-based tetraintercalators
with a different major groove-binding module and a reversed N to C
directionality of one of the minor groove-binding modules. DNase I
footprinting and kinetic analyses revealed that these new tetraintercalators
are able to discriminate, by as much as 30-fold, 14 bp DNA binding
sites that differ by 1 or 2 bp. Relative affinities were found to
correlate strongly with dissociation rates, while overall C2 symmetry in the DNA-binding molecule appeared
to contribute to enhanced association rates.
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