Nanoscale vectors comprised of cationic polymers that condense DNA to form nanocomplexes are promising options for gene transfer. The rational design of more efficient nonviral gene carriers will be possible only with better mechanistic understanding of the critical rate-limiting steps, such as nanocomplex unpacking to release DNA and degradation by nucleases. We present a two-step quantum dot fluorescence resonance energy transfer (two-step QD-FRET) approach to simultaneously and non-invasively analyze DNA condensation and stability. Plasmid DNA, double-labeled with QD (525 nm emission) and nucleic acid dyes, were complexed with Cy5-labeled cationic gene carriers. The QD donor drives energy transfer stepwise through the intermediate nucleic acid dye to the final acceptor Cy5. At least three distinct states of DNA condensation and integrity were distinguished in single particle manner and within cells by quantitative ratiometric analysis of energy transfer efficiencies. This novel two-step QD-FRET method allows for more detailed assessment of the onset of DNA release and degradation simultaneously.
n class="Chemical">Nanpan>oscale vectors comprised of cationpan>ic pan> class="Chemical">polymers that condense DNA to form nanocomplexes are promising options for gene transfer. The rational design of more efficient nonviral gene carriers will be possible only with better mechanistic understanding of the critical rate-limiting steps, such as nanocomplex unpacking to release DNA and degradation by nucleases. We present a two-step quantum dot fluorescence resonance energy transfer (two-step QD-FRET) approach to simultaneously and non-invasively analyze DNA condensation and stability. Plasmid DNA, double-labeled with QD (525 nm emission) and nucleic acid dyes, were complexed with Cy5-labeled cationic gene carriers. The QD donor drives energy transfer stepwise through the intermediate nucleic acid dye to the final acceptor Cy5. At least three distinct states of DNA condensation and integrity were distinguished in single particle manner and within cells by quantitative ratiometric analysis of energy transfer efficiencies. This novel two-step QD-FRET method allows for more detailed assessment of the onset of DNA release and degradation simultaneously.
Authors: Igor L Medintz; Aaron R Clapp; Hedi Mattoussi; Ellen R Goldman; Brent Fisher; J Matthew Mauro Journal: Nat Mater Date: 2003-08-24 Impact factor: 43.841
Authors: Xuan Jiang; Hui Dai; Chyan-Ying Ke; Xiao Mo; Michael S Torbenson; Zhiping Li; Hai-Quan Mao Journal: J Control Release Date: 2007-06-22 Impact factor: 9.776
Authors: Vasudev J Bailey; Brian P Keeley; Yi Zhang; Yi-Ping Ho; Hariharan Easwaran; Malcolm V Brock; Kristen L Pelosky; Hetty E Carraway; Stephen B Baylin; James G Herman; Tza-Huei Wang Journal: Chembiochem Date: 2010-01-04 Impact factor: 3.164