posted on 2014-09-08, 00:00authored byDawid Kedracki, Mahshid Chekini, Plinio Maroni, Helmut Schlaad, Corinne Nardin
We report herein on the polymer-crystallization-assisted
thiol-ene
photosynthesis of an amphiphilic comb/graft DNA copolymer, or molecular
brush, composed of a hydrophobic poly(2-oxazoline) backbone and hydrophilic
short single-stranded nucleic acid grafts. Coupling efficiencies are
above 60% and thus higher as compared with the straight solid-phase-supported
synthesis of amphiphilic DNA block copolymers. The DNA molecular brushes
self-assemble into sub-micron-sized spherical structures in water
as evidenced by light scattering as well as atomic force and electron
microscopy imaging. The nucleotide sequences remain functional, as
assessed by UV and fluorescence spectroscopy subsequent to isoindol
synthesis at the surface of the structures. The determination of a
vesicular morphology is supported by encapsulation and subsequent
spectroscopy monitoring of the release of a water-soluble dye and
spectroscopic quantification of the hybridization efficiency (30%
in average) of the functional nucleic acid strands engaged in structure
formation: about one-half of the nucleotide sequences are available
for hybridization, whereas the other half are hindered within the
self-assembled structure. Because speciation between complementary
and non complementary sequences in the medium could be ascertained
by confocal laser scanning microscopy, the stable self-assembled molecular
brushes demonstrate the potential for sensing applications.