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Literature DB >> 28238126

Quantification of siRNA Duplexes Bound to Gold Nanoparticle Surfaces.

Jilian R Melamed¹, Rachel S Riley¹, Danielle M Valcourt¹, Margaret M Billingsley¹, Nicole L Kreuzberger¹, Emily S Day^2,3,4.

Abstract

RNA interference (RNAi)-based gene regulation has recently emerged as a promising strategy to silence genes that drive disease progression. RNAi is typically mediated by small interfering ribonucleic acids (siRNAs), which, upon delivery into the cell cytoplasm, trigger degradation of complementary messenger RNA molecules to halt production of their encoded proteins. While RNAi has enormous clinical potential, its in vivo utility has been hindered because siRNAs are rapidly degraded by nucleases, cannot passively enter cells, and are quickly cleared from the bloodstream. To overcome these delivery barriers, siRNAs can be conjugated to nanoparticles (NPs), which increase their stability and circulation time to enable in vivo gene regulation. Here, we present methods to conjugate siRNA duplexes to NPs with gold surfaces. Further, we describe how to quantify the resultant amount of siRNA sense and antisense strands loaded onto the NPs using a fluorescence-based assay. This method focuses on the attachment of siRNAs to 13 nm gold NPs, but it is adaptable to other types of nucleic acids and nanoparticles as discussed throughout the protocol.

Entities: Chemical Disease Gene Species

Keywords: Conjugation; Gene regulation; Loading; Nanoparticles; Nucleic acids; siRNA

Mesh：

Substances：

Year: 2017 PMID： 28238126 PMCID： PMC5555579 DOI： 10.1007/978-1-4939-6840-4_1

Source DB: PubMed Journal: Methods Mol Biol ISSN： 1064-3745

26 in total

Review 1. Overcoming Gene-Delivery Hurdles: Physiological Considerations for Nonviral Vectors.

Authors: Andrew B Hill; Mingfu Chen; Chih-Kuang Chen; Blaine A Pfeifer; Charles H Jones
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2. Layer-by-layer assembled gold nanoparticles for siRNA delivery.

Authors: Asmaa Elbakry; Alaa Zaky; Renate Liebl; Reinhard Rachel; Achim Goepferich; Miriam Breunig
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3. siRNA-based spherical nucleic acids reverse impaired wound healing in diabetic mice by ganglioside GM3 synthase knockdown.

Authors: Pratik S Randeria; Mark A Seeger; Xiao-Qi Wang; Heather Wilson; Desmond Shipp; Chad A Mirkin; Amy S Paller
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Review 4. Therapeutic potentials of gene silencing by RNA interference: principles, challenges, and new strategies.

Authors: Yan Deng; Chi Chiu Wang; Kwong Wai Choy; Quan Du; Jiao Chen; Qin Wang; Lu Li; Tony Kwok Hung Chung; Tao Tang
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5. A fluorescence-based method for determining the surface coverage and hybridization efficiency of thiol-capped oligonucleotides bound to gold thin films and nanoparticles.

Authors: L M Demers; C A Mirkin; R C Mucic; R A Reynolds; R L Letsinger; R Elghanian; G Viswanadham
Journal: Anal Chem Date: 2000-11-15 Impact factor: 6.986

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Authors: Pratik S Randeria; Matthew R Jones; Kevin L Kohlstedt; Resham J Banga; Monica Olvera de la Cruz; George C Schatz; Chad A Mirkin
Journal: J Am Chem Soc Date: 2015-03-04 Impact factor: 15.419

7. Oligonucleotide loading determines cellular uptake of DNA-modified gold nanoparticles.

Authors: David A Giljohann; Dwight S Seferos; Pinal C Patel; Jill E Millstone; Nathaniel L Rosi; Chad A Mirkin
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9. Gold, poly(beta-amino ester) nanoparticles for small interfering RNA delivery.

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10. miR-182 integrates apoptosis, growth, and differentiation programs in glioblastoma.

Authors: Fotini M Kouri; Lisa A Hurley; Weston L Daniel; Emily S Day; Youjia Hua; Liangliang Hao; Chian-Yu Peng; Timothy J Merkel; Markus A Queisser; Carissa Ritner; Hailei Zhang; C David James; Jacob I Sznajder; Lynda Chin; David A Giljohann; John A Kessler; Marcus E Peter; Chad A Mirkin; Alexander H Stegh
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6 in total

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2. Layer-by-layer assembled PLGA nanoparticles carrying miR-34a cargo inhibit the proliferation and cell cycle progression of triple-negative breast cancer cells.

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Journal: J Biomed Mater Res A Date: 2019-11-26 Impact factor: 4.396