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Nanoparticle–Cell Interactions: Molecular Structure of the Protein Corona and Cellular Outcomes

[Image: see text] The use of nanoparticles (NPs) in biology and medicine requires a molecular-level understanding of how NPs interact with cells in a physiological environment. A critical difference between well-controlled in vitro experiments and in vivo applications is the presence of a complex mi...

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Autores principales: Fleischer, Candace C., Payne, Christine K.
Formato: Online Artículo Texto
Lenguaje:English
Publicado: American Chemical Society 2014
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC4139184/
https://www.ncbi.nlm.nih.gov/pubmed/25014679
http://dx.doi.org/10.1021/ar500190q
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author Fleischer, Candace C.
Payne, Christine K.
author_facet Fleischer, Candace C.
Payne, Christine K.
author_sort Fleischer, Candace C.
collection PubMed
description [Image: see text] The use of nanoparticles (NPs) in biology and medicine requires a molecular-level understanding of how NPs interact with cells in a physiological environment. A critical difference between well-controlled in vitro experiments and in vivo applications is the presence of a complex mixture of extracellular proteins. It has been established that extracellular serum proteins present in blood will adsorb onto the surface of NPs, forming a “protein corona”. Our goal was to understand how this protein layer affected cellular-level events, including NP binding, internalization, and transport. A combination of microscopy, which provides spatial resolution, and spectroscopy, which provides molecular information, is necessary to probe protein–NP–cell interactions. Initial experiments used a model system composed of polystyrene NPs functionalized with either amine or carboxylate groups to provide a cationic or anionic surface, respectively. Serum proteins adsorb onto the surface of both cationic and anionic NPs, forming a net anionic protein–NP complex. Although these protein–NP complexes have similar diameters and effective surface charges, they show the exact opposite behavior in terms of cellular binding. In the presence of bovine serum albumin (BSA), the cellular binding of BSA–NP complexes formed from cationic NPs is enhanced, whereas the cellular binding of BSA–NP complexes formed from anionic NPs is inhibited. These trends are independent of NP diameter or cell type. Similar results were obtained for anionic quantum dots and colloidal gold nanospheres. Using competition assays, we determined that BSA–NP complexes formed from anionic NPs bind to albumin receptors on the cell surface. BSA–NP complexes formed from cationic NPs are redirected to scavenger receptors. The observation that similar NPs with identical protein corona compositions bind to different cellular receptors suggested that a difference in the structure of the adsorbed protein may be responsible for the differences in cellular binding of the protein–NP complexes. Circular dichroism spectroscopy, isothermal titration calorimetry, and fluorescence spectroscopy show that the structure of BSA is altered following incubation with cationic NPs, but not anionic NPs. Single-particle-tracking fluorescence microscopy was used to follow the cellular internalization and transport of protein–NP complexes. The single particle-tracking experiments show that the protein corona remains bound to the NP throughout endocytic uptake and transport. The interaction of protein–NP complexes with cells is a challenging question, as the adsorbed protein corona controls the interaction of the NP with the cell; however, the NP itself alters the structure of the adsorbed protein. A combination of microscopy and spectroscopy is necessary to understand this complex interaction, enabling the rational design of NPs for biological and medical applications.
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spelling pubmed-41391842015-07-11 Nanoparticle–Cell Interactions: Molecular Structure of the Protein Corona and Cellular Outcomes Fleischer, Candace C. Payne, Christine K. Acc Chem Res [Image: see text] The use of nanoparticles (NPs) in biology and medicine requires a molecular-level understanding of how NPs interact with cells in a physiological environment. A critical difference between well-controlled in vitro experiments and in vivo applications is the presence of a complex mixture of extracellular proteins. It has been established that extracellular serum proteins present in blood will adsorb onto the surface of NPs, forming a “protein corona”. Our goal was to understand how this protein layer affected cellular-level events, including NP binding, internalization, and transport. A combination of microscopy, which provides spatial resolution, and spectroscopy, which provides molecular information, is necessary to probe protein–NP–cell interactions. Initial experiments used a model system composed of polystyrene NPs functionalized with either amine or carboxylate groups to provide a cationic or anionic surface, respectively. Serum proteins adsorb onto the surface of both cationic and anionic NPs, forming a net anionic protein–NP complex. Although these protein–NP complexes have similar diameters and effective surface charges, they show the exact opposite behavior in terms of cellular binding. In the presence of bovine serum albumin (BSA), the cellular binding of BSA–NP complexes formed from cationic NPs is enhanced, whereas the cellular binding of BSA–NP complexes formed from anionic NPs is inhibited. These trends are independent of NP diameter or cell type. Similar results were obtained for anionic quantum dots and colloidal gold nanospheres. Using competition assays, we determined that BSA–NP complexes formed from anionic NPs bind to albumin receptors on the cell surface. BSA–NP complexes formed from cationic NPs are redirected to scavenger receptors. The observation that similar NPs with identical protein corona compositions bind to different cellular receptors suggested that a difference in the structure of the adsorbed protein may be responsible for the differences in cellular binding of the protein–NP complexes. Circular dichroism spectroscopy, isothermal titration calorimetry, and fluorescence spectroscopy show that the structure of BSA is altered following incubation with cationic NPs, but not anionic NPs. Single-particle-tracking fluorescence microscopy was used to follow the cellular internalization and transport of protein–NP complexes. The single particle-tracking experiments show that the protein corona remains bound to the NP throughout endocytic uptake and transport. The interaction of protein–NP complexes with cells is a challenging question, as the adsorbed protein corona controls the interaction of the NP with the cell; however, the NP itself alters the structure of the adsorbed protein. A combination of microscopy and spectroscopy is necessary to understand this complex interaction, enabling the rational design of NPs for biological and medical applications. American Chemical Society 2014-07-11 2014-08-19 /pmc/articles/PMC4139184/ /pubmed/25014679 http://dx.doi.org/10.1021/ar500190q Text en Copyright © 2014 American Chemical Society Terms of Use (http://pubs.acs.org/page/policy/authorchoice_termsofuse.html)
spellingShingle Fleischer, Candace C.
Payne, Christine K.
Nanoparticle–Cell Interactions: Molecular Structure of the Protein Corona and Cellular Outcomes
title Nanoparticle–Cell Interactions: Molecular Structure of the Protein Corona and Cellular Outcomes
title_full Nanoparticle–Cell Interactions: Molecular Structure of the Protein Corona and Cellular Outcomes
title_fullStr Nanoparticle–Cell Interactions: Molecular Structure of the Protein Corona and Cellular Outcomes
title_full_unstemmed Nanoparticle–Cell Interactions: Molecular Structure of the Protein Corona and Cellular Outcomes
title_short Nanoparticle–Cell Interactions: Molecular Structure of the Protein Corona and Cellular Outcomes
title_sort nanoparticle–cell interactions: molecular structure of the protein corona and cellular outcomes
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC4139184/
https://www.ncbi.nlm.nih.gov/pubmed/25014679
http://dx.doi.org/10.1021/ar500190q
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