DNA Aptamer Folding on Gold Nanoparticles:  From Colloid Chemistry to Biosensors

适体 化学 胶体金 DNA 纳米颗粒 纳米技术 生物传感器 生物物理学 折叠(DSP实现) 生物化学 材料科学 生物 电气工程 工程类 遗传学
作者
Weian Zhao,William Chiuman,Jeffrey C. F. Lam,Simon A. McManus,Wei Chen,Yuguo Cui,Robert Pelton,Michael A. Brook,Yingfu Li
出处
期刊:Journal of the American Chemical Society [American Chemical Society]
卷期号:130 (11): 3610-3618 被引量:372
标识
DOI:10.1021/ja710241b
摘要

We have investigated the effect of the folding of DNA aptamers on the colloidal stability of gold nanoparticles (AuNPs) to which an aptamer is tethered. On the basis of the studies of two different aptamers (adenosine aptamer and K+ aptamer), we discovered a unique colloidal stabilization effect associated with aptamer folding: AuNPs to which folded aptamer structures are attached are more stable toward salt-induced aggregation than those tethered to unfolded aptamers. This colloidal stabilization effect is more significant when a DNA spacer was incorporated between AuNP and the aptamer or when lower aptamer surface graft densities were used. The conformation that aptamers adopt on the surface appears to be a key factor that determines the relative stability of different AuNPs. Dynamic light scattering experiments revealed that the sizes of AuNPs modified with folded aptamers were larger than those of AuNPs modified with unfolded (but largely collapsed) aptamers in salt solution. From both the electrostatic and steric stabilization points of view, the folded aptamers that are more extended from the surface have a higher stabilization effect on AuNP than the unfolded aptamers. On the basis of this unique phenomenon, colorimetric biosensors have been developed for the detection of adenosine, K+, adenosine deaminase, and its inhibitors. Moreover, distinct AuNP aggregation and redispersion stages can be readily operated by controlling aptamer folding and unfolding states with the addition of adenosine and adenosine deaminase.
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