Studying Protein–DNA Complexes Using Gold Nanoparticles by Exploiting Particle Aggregation, Refractive Index Change, and Fluorescence Quenching and Enhancement Principles

Studying Protein–DNA Complexes Using Gold Nanoparticles by Exploiting Particle Aggregation, Refractive Index Change, and Fluorescence Quenching and Enhancement Principles

Gold nanoparticles (AuNPs) have a unique optical phenomena termed localized surface plasmon resonance that is determined by particle shape, size, interparticle distance (or aggregation status), and local refractive index. AuNPs can also modulate fluorescence emission of proximal fluorophores under t...

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Main Authors: Sutarlie, Laura, Aung, Khin Moh Moh, Lim, Michelle Gek Liang, Lukman, Steven, Cheung, Edwin, Su, Xiaodi
Other Authors: School of Biological Sciences
Format: Article
Language:English
Published: 2016
Subjects:
Protein–DNA complexes
Gold nanoparticles
Online Access:https://hdl.handle.net/10356/81780
http://hdl.handle.net/10220/40976
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Institution: Nanyang Technological University
Language: English
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spelling sg-ntu-dr.10356-817802020-03-07T12:18:10Z Studying Protein–DNA Complexes Using Gold Nanoparticles by Exploiting Particle Aggregation, Refractive Index Change, and Fluorescence Quenching and Enhancement Principles Sutarlie, Laura Aung, Khin Moh Moh Lim, Michelle Gek Liang Lukman, Steven Cheung, Edwin Su, Xiaodi School of Biological Sciences Protein–DNA complexes Gold nanoparticles Gold nanoparticles (AuNPs) have a unique optical phenomena termed localized surface plasmon resonance that is determined by particle shape, size, interparticle distance (or aggregation status), and local refractive index. AuNPs can also modulate fluorescence emission of proximal fluorophores under the Förster resonance energy transfer and/or nanoparticle surface energy transfer mechanisms. In this study, we use AuNPs (13 and 100 nm in diameter) as sensing elements to study sequence-dependent protein–DNA interactions by exploring all possible principles, namely (1) particle aggregation based colorimetric sensing, (2) refractive index sensing, and (3) fluorescence quenching/enhancement based fluorimetric sensing, exemplified by transcription factors, i.e., FoxA1 and AP2γ, and their respective DNAs. We conclude that the first principle, i.e., particle aggregation-based colorimetric assay that measures preformed complex by exploring complex protection of AuNPs from salt-induced aggregation, is simple to use. However, its performance is protein specific. For second and third principles that measure on-particle complex formation, we prove that the fluorescence quenching/enhancement assays supported by AuNPs are more sensitive than assays exploiting analyte-binding induced refractive index principle. This study provides a comprehensive assessment of the versatility of AuNPs as sensing probes for studying bioaffinity interactions especially protein–DNA complexes. The discovery of the DNA binding properties of FoxA1 and AP-2γ is important in revealing their roles in gene regulation. ASTAR (Agency for Sci., Tech. and Research, S’pore) 2016-07-20T04:44:09Z 2019-12-06T14:40:27Z 2016-07-20T04:44:09Z 2019-12-06T14:40:27Z 2014 Journal Article Sutarlie, L., Aung, K. M. M., Lim, M. G. L., Lukman, S., Cheung, E., & Su, X. (2014). Studying Protein–DNA Complexes Using Gold Nanoparticles by Exploiting Particle Aggregation, Refractive Index Change, and Fluorescence Quenching and Enhancement Principles. Plasmonics, 9(4), 753-763. 1557-1955 https://hdl.handle.net/10356/81780 http://hdl.handle.net/10220/40976 10.1007/s11468-013-9655-2 en Plasmonics © 2014 Springer Science+Business Media New York.
institution Nanyang Technological University
building NTU Library
country Singapore
collection DR-NTU
language English
topic Protein–DNA complexes
Gold nanoparticles
spellingShingle Protein–DNA complexes
Gold nanoparticles
Sutarlie, Laura
Aung, Khin Moh Moh
Lim, Michelle Gek Liang
Lukman, Steven
Cheung, Edwin
Su, Xiaodi
Studying Protein–DNA Complexes Using Gold Nanoparticles by Exploiting Particle Aggregation, Refractive Index Change, and Fluorescence Quenching and Enhancement Principles
description Gold nanoparticles (AuNPs) have a unique optical phenomena termed localized surface plasmon resonance that is determined by particle shape, size, interparticle distance (or aggregation status), and local refractive index. AuNPs can also modulate fluorescence emission of proximal fluorophores under the Förster resonance energy transfer and/or nanoparticle surface energy transfer mechanisms. In this study, we use AuNPs (13 and 100 nm in diameter) as sensing elements to study sequence-dependent protein–DNA interactions by exploring all possible principles, namely (1) particle aggregation based colorimetric sensing, (2) refractive index sensing, and (3) fluorescence quenching/enhancement based fluorimetric sensing, exemplified by transcription factors, i.e., FoxA1 and AP2γ, and their respective DNAs. We conclude that the first principle, i.e., particle aggregation-based colorimetric assay that measures preformed complex by exploring complex protection of AuNPs from salt-induced aggregation, is simple to use. However, its performance is protein specific. For second and third principles that measure on-particle complex formation, we prove that the fluorescence quenching/enhancement assays supported by AuNPs are more sensitive than assays exploiting analyte-binding induced refractive index principle. This study provides a comprehensive assessment of the versatility of AuNPs as sensing probes for studying bioaffinity interactions especially protein–DNA complexes. The discovery of the DNA binding properties of FoxA1 and AP-2γ is important in revealing their roles in gene regulation.
author2 School of Biological Sciences
author_facet School of Biological Sciences
Sutarlie, Laura
Aung, Khin Moh Moh
Lim, Michelle Gek Liang
Lukman, Steven
Cheung, Edwin
Su, Xiaodi
format Article
author Sutarlie, Laura
Aung, Khin Moh Moh
Lim, Michelle Gek Liang
Lukman, Steven
Cheung, Edwin
Su, Xiaodi
author_sort Sutarlie, Laura
title Studying Protein–DNA Complexes Using Gold Nanoparticles by Exploiting Particle Aggregation, Refractive Index Change, and Fluorescence Quenching and Enhancement Principles
title_short Studying Protein–DNA Complexes Using Gold Nanoparticles by Exploiting Particle Aggregation, Refractive Index Change, and Fluorescence Quenching and Enhancement Principles
title_full Studying Protein–DNA Complexes Using Gold Nanoparticles by Exploiting Particle Aggregation, Refractive Index Change, and Fluorescence Quenching and Enhancement Principles
title_fullStr Studying Protein–DNA Complexes Using Gold Nanoparticles by Exploiting Particle Aggregation, Refractive Index Change, and Fluorescence Quenching and Enhancement Principles
title_full_unstemmed Studying Protein–DNA Complexes Using Gold Nanoparticles by Exploiting Particle Aggregation, Refractive Index Change, and Fluorescence Quenching and Enhancement Principles
title_sort studying protein–dna complexes using gold nanoparticles by exploiting particle aggregation, refractive index change, and fluorescence quenching and enhancement principles
publishDate 2016
url https://hdl.handle.net/10356/81780
http://hdl.handle.net/10220/40976
_version_ 1681044081633918976

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