Journal
JOURNAL OF PHYSICAL CHEMISTRY C
Volume 113, Issue 40, Pages 17326-17331Publisher
AMER CHEMICAL SOC
DOI: 10.1021/jp905408q
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Funding
- Natural Science Foundation of China [20645002]
- SIZE
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A novel method was developed to control the dynamic of triplex formation between oligonucleotide-modified gold nanoparticles in the presence of complementary strand. The solution containing the oligonucleotide 5'-SH-ACA CAC ACA CAC CTT TCT TTC CTT TCT TTC-3'(oligo-1)-modified gold nanoparticles was red in color. Due to triplex formation, there was a tiny change in color on addition of the complementary oligonucleotide 5'-GAA AGA AAG GAA AGA AAG-3'(oligo-3). The addition of oligonucleotide 5'-GTG TGT GTG TGT-3'(oligo-2) induced the spacer portion of oligo-1 to change from single strand to rigid duplex structure and protrude from the surface of the gold colloid, removing the physisorption between oligo-1 and the gold nanoparticles successfully. Therefore, when the oligo-2 was added accompanied by oligo-3 at pH 5.6 and 6.0 mu M spermine, larger aggregates were formed and the color of the solution changed from red to blue within 20 min. The oligo-2 hybridized with the spacer portion of oligo-1 and had no effect oil the stability of triplex DNA: thereby, the melting temperatures of the triplex DNA were 51 and 53 degrees C in the absence and presence of oligo-2, respectively. Oligo-3 played a crucial role in the triplex formation between nanoparticles. When oligo-3 was replaced with 5'-GAA AGA AAG TAA AGA AAG-3' (oligo-4, single-base mismatched) and 5'-GAA AGT AAG GAA TGA AAG-3'(oligo-5, double-base mismatched), respectively, the melting temperature decreased from 53 to 41 degrees C and eventually to 33 degrees C.
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