posted on 2015-09-09, 00:00authored byJuan Li, Cheng-Yi Hong, Shu-Xian Wu, Hong Liang, Li-Ping Wang, Guoming Huang, Xian Chen, Huang-Hao Yang, Dihua Shangguan, Weihong Tan
Hydrophobic nanoparticles have shown
substantial potential for
bioanalysis and biomedical applications. However, their use is hindered
by complex phase transfer and inefficient surface modification. This
paper reports a facile and universal strategy for phase transfer and
surface biofunctionalization of hydrophobic nanomaterials using aptamer-pendant
DNA tetrahedron nanostructures (Apt-tet). The Janus DNA tetrahedron
nanostructures are constructed by three carboxyl group modified DNA
strands and one aptamer sequence. The pendant linear sequence is an
aptamer, in this case AS1411, known to specifically bind nucleolin,
typically overexpressed on the plasma membranes of tumor cells. The
incorporation of the aptamers adds targeting ability and also enhances
intracellular uptake. Phase-transfer efficiency using Apt-tet is much
higher than that achieved using single-stranded DNA. In addition,
the DNA tetrahedron nanostructures can be programmed to permit the
incorporation of other functional nucleic acids, such as DNAzymes,
siRNA, or antisense DNA, allowing, in turn, the construction of promising
theranostic nanoagents for bioanalysis and biomedical applications.
Given these unique features, we believe that our strategy of surface
modification and functionalization may become a new paradigm in phase-transfer-agent
design and further expand biomedical applications of hydrophobic nanomaterials.