Radioiodination of extravesicular surface constituents to study the biocorona, cell trafficking and storage stability of extracellular vesicles

Extracellular vesicles (EVs) are produced by all cell types and serve as biological packets delivering a wide variety of molecules for cell-to-cell communication. However, the biology of the EV extravesicular surface domain that we have termed EV ‘biocorona’ remains underexplored. Upon cell secretio...

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Published inBiochimica et biophysica acta. General subjects Vol. 1866; no. 2; p. 130069
Main Authors Yerneni, Saigopalakrishna S., Solomon, Talia, Smith, Jason, Campbell, Phil G.
Format Journal Article
LanguageEnglish
Published Netherlands Elsevier B.V 01.02.2022
Subjects
biocompatible materials
Biocorona
biomimetics
cell communication
Cell trafficking
Corona
DNA
drugs
Extracellular vesicles
Extracellular Vesicles - chemistry
Extracellular Vesicles - metabolism
Humans
Iodine Radioisotopes - chemistry
proteolysis
Radiolabeling
RNA
secretion
Storage artifacts
storage quality
temperature
therapeutics
Extracellular vesicles
Radiolabeling
Biocorona
Corona
Storage artifacts
Cell trafficking
Online AccessGet full text
ISSN0304-4165
1872-8006
1872-8006
DOI10.1016/j.bbagen.2021.130069

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Abstract Extracellular vesicles (EVs) are produced by all cell types and serve as biological packets delivering a wide variety of molecules for cell-to-cell communication. However, the biology of the EV extravesicular surface domain that we have termed EV ‘biocorona’ remains underexplored. Upon cell secretion, EVs possess an innate biocorona containing membrane integral and peripheral constituents that is modified by acquired constituents post secretion. This distinguishes EVs from synthetic nanoparticulate biomaterials that are limited to an adsorption-based, acquired biocorona. The EV biocorona molecular constituents were radiolabeled with 125I to study biocorona constituents and its surface dynamics. As example toolset applications, 125I-EVs were utilized to study EV cell trafficking and the stability of the EV biocorona during storage. The biocorona of EVs consisted of proteins, lipids, DNA and RNA. The cellular uptake of 125I-EVs was temperature dependent and internalized 125I-EVs were rapidly recycled by cells. When 125I-EVs were stored in a purified state, they exhibited time and temperature dependent biocorona shedding and proteolytic degradation that was partially inhibited in the presence of serum. The EV biocorona is complex and dynamic. Radiolabeling of the EV biocorona enables a unique platform methodology to study the biocorona and will facilitate unlocking EV's full clinical translation potential. The EV biocorona affects EV mediated biological processes in health and disease. Acquiring knowledge of the EV biocorona composition, dynamics, stability and structure not only informs the diagnostic and therapeutic translation of EVs but also aids in designing biomimetic nanomaterials for drug delivery. [Display omitted] •The extracellular vesicle (EV) has a complex ‘biocorona’ that consists of proteins, lipids, DNA and RNA.•Nucleic acids in the EV biocorona are both membrane protein bound and non-protein bound.•The biocorona exhibits time and temperature dependent proteolytic shedding and degradation.•Cell trafficking of EVs includes rapid recycling of internalized EVs.
AbstractList Extracellular vesicles (EVs) are produced by all cell types and serve as biological packets delivering a wide variety of molecules for cell-to-cell communication. However, the biology of the EV extravesicular surface domain that we have termed EV 'biocorona' remains underexplored. Upon cell secretion, EVs possess an innate biocorona containing membrane integral and peripheral constituents that is modified by acquired constituents post secretion. This distinguishes EVs from synthetic nanoparticulate biomaterials that are limited to an adsorption-based, acquired biocorona.BACKGROUNDExtracellular vesicles (EVs) are produced by all cell types and serve as biological packets delivering a wide variety of molecules for cell-to-cell communication. However, the biology of the EV extravesicular surface domain that we have termed EV 'biocorona' remains underexplored. Upon cell secretion, EVs possess an innate biocorona containing membrane integral and peripheral constituents that is modified by acquired constituents post secretion. This distinguishes EVs from synthetic nanoparticulate biomaterials that are limited to an adsorption-based, acquired biocorona.The EV biocorona molecular constituents were radiolabeled with 125I to study biocorona constituents and its surface dynamics. As example toolset applications, 125I-EVs were utilized to study EV cell trafficking and the stability of the EV biocorona during storage.METHODSThe EV biocorona molecular constituents were radiolabeled with 125I to study biocorona constituents and its surface dynamics. As example toolset applications, 125I-EVs were utilized to study EV cell trafficking and the stability of the EV biocorona during storage.The biocorona of EVs consisted of proteins, lipids, DNA and RNA. The cellular uptake of 125I-EVs was temperature dependent and internalized 125I-EVs were rapidly recycled by cells. When 125I-EVs were stored in a purified state, they exhibited time and temperature dependent biocorona shedding and proteolytic degradation that was partially inhibited in the presence of serum.RESULTSThe biocorona of EVs consisted of proteins, lipids, DNA and RNA. The cellular uptake of 125I-EVs was temperature dependent and internalized 125I-EVs were rapidly recycled by cells. When 125I-EVs were stored in a purified state, they exhibited time and temperature dependent biocorona shedding and proteolytic degradation that was partially inhibited in the presence of serum.The EV biocorona is complex and dynamic. Radiolabeling of the EV biocorona enables a unique platform methodology to study the biocorona and will facilitate unlocking EV's full clinical translation potential.CONCLUSIONThe EV biocorona is complex and dynamic. Radiolabeling of the EV biocorona enables a unique platform methodology to study the biocorona and will facilitate unlocking EV's full clinical translation potential.The EV biocorona affects EV mediated biological processes in health and disease. Acquiring knowledge of the EV biocorona composition, dynamics, stability and structure not only informs the diagnostic and therapeutic translation of EVs but also aids in designing biomimetic nanomaterials for drug delivery.GENERAL SIGNIFICANCEThe EV biocorona affects EV mediated biological processes in health and disease. Acquiring knowledge of the EV biocorona composition, dynamics, stability and structure not only informs the diagnostic and therapeutic translation of EVs but also aids in designing biomimetic nanomaterials for drug delivery.
Extracellular vesicles (EVs) are produced by all cell types and serve as biological packets delivering a wide variety of molecules for cell-to-cell communication. However, the biology of the EV extravesicular surface domain that we have termed EV ‘biocorona’ remains underexplored. Upon cell secretion, EVs possess an innate biocorona containing membrane integral and peripheral constituents that is modified by acquired constituents post secretion. This distinguishes EVs from synthetic nanoparticulate biomaterials that are limited to an adsorption-based, acquired biocorona.The EV biocorona molecular constituents were radiolabeled with ¹²⁵I to study biocorona constituents and its surface dynamics. As example toolset applications, ¹²⁵I-EVs were utilized to study EV cell trafficking and the stability of the EV biocorona during storage.The biocorona of EVs consisted of proteins, lipids, DNA and RNA. The cellular uptake of ¹²⁵I-EVs was temperature dependent and internalized ¹²⁵I-EVs were rapidly recycled by cells. When ¹²⁵I-EVs were stored in a purified state, they exhibited time and temperature dependent biocorona shedding and proteolytic degradation that was partially inhibited in the presence of serum.The EV biocorona is complex and dynamic. Radiolabeling of the EV biocorona enables a unique platform methodology to study the biocorona and will facilitate unlocking EV's full clinical translation potential.The EV biocorona affects EV mediated biological processes in health and disease. Acquiring knowledge of the EV biocorona composition, dynamics, stability and structure not only informs the diagnostic and therapeutic translation of EVs but also aids in designing biomimetic nanomaterials for drug delivery.
Extracellular vesicles (EVs) are produced by all cell types and serve as biological packets delivering a wide variety of molecules for cell-to-cell communication. However, the biology of the EV extravesicular surface domain that we have termed EV 'biocorona' remains underexplored. Upon cell secretion, EVs possess an innate biocorona containing membrane integral and peripheral constituents that is modified by acquired constituents post secretion. This distinguishes EVs from synthetic nanoparticulate biomaterials that are limited to an adsorption-based, acquired biocorona. The EV biocorona molecular constituents were radiolabeled with I to study biocorona constituents and its surface dynamics. As example toolset applications, I-EVs were utilized to study EV cell trafficking and the stability of the EV biocorona during storage. The biocorona of EVs consisted of proteins, lipids, DNA and RNA. The cellular uptake of I-EVs was temperature dependent and internalized I-EVs were rapidly recycled by cells. When I-EVs were stored in a purified state, they exhibited time and temperature dependent biocorona shedding and proteolytic degradation that was partially inhibited in the presence of serum. The EV biocorona is complex and dynamic. Radiolabeling of the EV biocorona enables a unique platform methodology to study the biocorona and will facilitate unlocking EV's full clinical translation potential. The EV biocorona affects EV mediated biological processes in health and disease. Acquiring knowledge of the EV biocorona composition, dynamics, stability and structure not only informs the diagnostic and therapeutic translation of EVs but also aids in designing biomimetic nanomaterials for drug delivery.
Extracellular vesicles (EVs) are produced by all cell types and serve as biological packets delivering a wide variety of molecules for cell-to-cell communication. However, the biology of the EV extravesicular surface domain that we have termed EV ‘biocorona’ remains underexplored. Upon cell secretion, EVs possess an innate biocorona containing membrane integral and peripheral constituents that is modified by acquired constituents post secretion. This distinguishes EVs from synthetic nanoparticulate biomaterials that are limited to an adsorption-based, acquired biocorona. The EV biocorona molecular constituents were radiolabeled with 125I to study biocorona constituents and its surface dynamics. As example toolset applications, 125I-EVs were utilized to study EV cell trafficking and the stability of the EV biocorona during storage. The biocorona of EVs consisted of proteins, lipids, DNA and RNA. The cellular uptake of 125I-EVs was temperature dependent and internalized 125I-EVs were rapidly recycled by cells. When 125I-EVs were stored in a purified state, they exhibited time and temperature dependent biocorona shedding and proteolytic degradation that was partially inhibited in the presence of serum. The EV biocorona is complex and dynamic. Radiolabeling of the EV biocorona enables a unique platform methodology to study the biocorona and will facilitate unlocking EV's full clinical translation potential. The EV biocorona affects EV mediated biological processes in health and disease. Acquiring knowledge of the EV biocorona composition, dynamics, stability and structure not only informs the diagnostic and therapeutic translation of EVs but also aids in designing biomimetic nanomaterials for drug delivery. [Display omitted] •The extracellular vesicle (EV) has a complex ‘biocorona’ that consists of proteins, lipids, DNA and RNA.•Nucleic acids in the EV biocorona are both membrane protein bound and non-protein bound.•The biocorona exhibits time and temperature dependent proteolytic shedding and degradation.•Cell trafficking of EVs includes rapid recycling of internalized EVs.
ArticleNumber 130069
Author Yerneni, Saigopalakrishna S.
Campbell, Phil G.
Solomon, Talia
Smith, Jason
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  surname: Yerneni
  fullname: Yerneni, Saigopalakrishna S.
  organization: Department of Biomedical Engineering, Carnegie Mellon University, Pittsburgh, PA, United States of America
– sequence: 2
  givenname: Talia
  surname: Solomon
  fullname: Solomon, Talia
  organization: Department of Biomedical Engineering, Carnegie Mellon University, Pittsburgh, PA, United States of America
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  givenname: Jason
  surname: Smith
  fullname: Smith, Jason
  organization: Engineering Research Accelerator, Carnegie Mellon University, Pittsburgh, PA, United States of America
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  givenname: Phil G.
  surname: Campbell
  fullname: Campbell, Phil G.
  email: pcampbel@cs.cmu.edu
  organization: Department of Biomedical Engineering, Carnegie Mellon University, Pittsburgh, PA, United States of America
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Issue 2
Keywords Extracellular vesicles
Radiolabeling
Biocorona
Corona
Storage artifacts
Cell trafficking
Language English
License This is an open access article under the CC BY-NC-ND license.
Copyright © 2021 The Authors. Published by Elsevier B.V. All rights reserved.
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Snippet Extracellular vesicles (EVs) are produced by all cell types and serve as biological packets delivering a wide variety of molecules for cell-to-cell...
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StartPage 130069
SubjectTerms biocompatible materials
Biocorona
biomimetics
cell communication
Cell trafficking
Corona
DNA
drugs
Extracellular vesicles
Extracellular Vesicles - chemistry
Extracellular Vesicles - metabolism
Humans
Iodine Radioisotopes - chemistry
proteolysis
Radiolabeling
RNA
secretion
Storage artifacts
storage quality
temperature
therapeutics
Title Radioiodination of extravesicular surface constituents to study the biocorona, cell trafficking and storage stability of extracellular vesicles
URI https://dx.doi.org/10.1016/j.bbagen.2021.130069
https://www.ncbi.nlm.nih.gov/pubmed/34906563
https://www.proquest.com/docview/2610410647
https://www.proquest.com/docview/2636629618
Volume 1866
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