Assessment of extracellular vesicle isolation methods from human stool supernatant

Emmalee J. Northrop-Albrecht; William R. Taylor; Bing Q. Huang; John B. Kisiel; Fabrice Lucien

doi:10.1002/jev2.12208

Assessment of extracellular vesicle isolation methods from human stool supernatant

Emmalee J. Northrop-Albrecht, William R. Taylor, Bing Q. Huang, John B. Kisiel, Fabrice Lucien

Research output: Contribution to journal › Article › peer-review

Abstract

Extracellular vesicles (EVs) are of growing interest due to their potential diagnostic, disease surveillance, and therapeutic applications. While several studies have evaluated EV isolation methods in various biofluids, there are few if any data on these techniques when applied to stool. The latter is an ideal biospecimen for studying EVs and colorectal cancer (CRC) because the release of tumour markers by luminal exfoliation into stool occurs earlier than vascular invasion. Since EV release is a conserved mechanism, bacteria in stool contribute to the overall EV population. In this study, we assessed five EV separation methods (ultracentrifugation [UC], precipitation [EQ-O, EQ-TC], size exclusion chromatography [SEC], and ultrafiltration [UF]) for total recovery, reproducibility, purity, RNA composition, and protein expression in stool supernatant. CD63, TSG101, and ompA proteins were present in EV fractions from all methods except UC. Human (18s) and bacterial (16s) rRNA was detected in stool EV preparations. Enzymatic treatment prior to extraction is necessary to avoid non-vesicular RNA contamination. Ultrafiltration had the highest recovery, RNA, and protein yield. After assessing purity further, SEC was the isolation method of choice. These findings serve as the groundwork for future studies that use high throughput omics technologies to investigate the potential of stool-derived EVs as a source for novel biomarkers for early CRC detection.

Original language	English (US)
Article number	e12208
Journal	Journal of Extracellular Vesicles
Volume	11
Issue number	4
DOIs	https://doi.org/10.1002/jev2.12208
State	Published - Apr 2022

Keywords

biomarkers
cell-derived microparticles
colonic neoplasms/diagnosis
extracellular vesicles/chemistry
gastrointestinal microbiome
tumour

ASJC Scopus subject areas

Histology
Cell Biology

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10.1002/jev2.12208

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title = "Assessment of extracellular vesicle isolation methods from human stool supernatant",

abstract = "Extracellular vesicles (EVs) are of growing interest due to their potential diagnostic, disease surveillance, and therapeutic applications. While several studies have evaluated EV isolation methods in various biofluids, there are few if any data on these techniques when applied to stool. The latter is an ideal biospecimen for studying EVs and colorectal cancer (CRC) because the release of tumour markers by luminal exfoliation into stool occurs earlier than vascular invasion. Since EV release is a conserved mechanism, bacteria in stool contribute to the overall EV population. In this study, we assessed five EV separation methods (ultracentrifugation [UC], precipitation [EQ-O, EQ-TC], size exclusion chromatography [SEC], and ultrafiltration [UF]) for total recovery, reproducibility, purity, RNA composition, and protein expression in stool supernatant. CD63, TSG101, and ompA proteins were present in EV fractions from all methods except UC. Human (18s) and bacterial (16s) rRNA was detected in stool EV preparations. Enzymatic treatment prior to extraction is necessary to avoid non-vesicular RNA contamination. Ultrafiltration had the highest recovery, RNA, and protein yield. After assessing purity further, SEC was the isolation method of choice. These findings serve as the groundwork for future studies that use high throughput omics technologies to investigate the potential of stool-derived EVs as a source for novel biomarkers for early CRC detection.",

keywords = "biomarkers, cell-derived microparticles, colonic neoplasms/diagnosis, extracellular vesicles/chemistry, gastrointestinal microbiome, tumour",

author = "Northrop-Albrecht, {Emmalee J.} and Taylor, {William R.} and Huang, {Bing Q.} and Kisiel, {John B.} and Fabrice Lucien",

note = "Funding Information: William R. Taylor and John B. Kisiel are inventors of Mayo Clinic intellectual property, licensed by Exact Sciences (Madison, WI, USA), from which royalties may be paid to Mayo Clinic. In addition to grants NCI CA214679 and CA 241164, John B. Kisiel receives funding from a sponsored research agreement between Mayo Clinic and Exact Sciences. Funding Information: This work was supported by the National Cancer Institute under CA214679 to JBK. Publisher Copyright: {\textcopyright} 2022 The Authors. Journal of Extracellular Vesicles published by Wiley Periodicals, LLC on behalf of the International Society for Extracellular Vesicles.",

year = "2022",

month = apr,

doi = "10.1002/jev2.12208",

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AU - Northrop-Albrecht, Emmalee J.

AU - Taylor, William R.

AU - Huang, Bing Q.

AU - Kisiel, John B.

AU - Lucien, Fabrice

N1 - Funding Information: William R. Taylor and John B. Kisiel are inventors of Mayo Clinic intellectual property, licensed by Exact Sciences (Madison, WI, USA), from which royalties may be paid to Mayo Clinic. In addition to grants NCI CA214679 and CA 241164, John B. Kisiel receives funding from a sponsored research agreement between Mayo Clinic and Exact Sciences. Funding Information: This work was supported by the National Cancer Institute under CA214679 to JBK. Publisher Copyright: © 2022 The Authors. Journal of Extracellular Vesicles published by Wiley Periodicals, LLC on behalf of the International Society for Extracellular Vesicles.

PY - 2022/4

Y1 - 2022/4

N2 - Extracellular vesicles (EVs) are of growing interest due to their potential diagnostic, disease surveillance, and therapeutic applications. While several studies have evaluated EV isolation methods in various biofluids, there are few if any data on these techniques when applied to stool. The latter is an ideal biospecimen for studying EVs and colorectal cancer (CRC) because the release of tumour markers by luminal exfoliation into stool occurs earlier than vascular invasion. Since EV release is a conserved mechanism, bacteria in stool contribute to the overall EV population. In this study, we assessed five EV separation methods (ultracentrifugation [UC], precipitation [EQ-O, EQ-TC], size exclusion chromatography [SEC], and ultrafiltration [UF]) for total recovery, reproducibility, purity, RNA composition, and protein expression in stool supernatant. CD63, TSG101, and ompA proteins were present in EV fractions from all methods except UC. Human (18s) and bacterial (16s) rRNA was detected in stool EV preparations. Enzymatic treatment prior to extraction is necessary to avoid non-vesicular RNA contamination. Ultrafiltration had the highest recovery, RNA, and protein yield. After assessing purity further, SEC was the isolation method of choice. These findings serve as the groundwork for future studies that use high throughput omics technologies to investigate the potential of stool-derived EVs as a source for novel biomarkers for early CRC detection.

AB - Extracellular vesicles (EVs) are of growing interest due to their potential diagnostic, disease surveillance, and therapeutic applications. While several studies have evaluated EV isolation methods in various biofluids, there are few if any data on these techniques when applied to stool. The latter is an ideal biospecimen for studying EVs and colorectal cancer (CRC) because the release of tumour markers by luminal exfoliation into stool occurs earlier than vascular invasion. Since EV release is a conserved mechanism, bacteria in stool contribute to the overall EV population. In this study, we assessed five EV separation methods (ultracentrifugation [UC], precipitation [EQ-O, EQ-TC], size exclusion chromatography [SEC], and ultrafiltration [UF]) for total recovery, reproducibility, purity, RNA composition, and protein expression in stool supernatant. CD63, TSG101, and ompA proteins were present in EV fractions from all methods except UC. Human (18s) and bacterial (16s) rRNA was detected in stool EV preparations. Enzymatic treatment prior to extraction is necessary to avoid non-vesicular RNA contamination. Ultrafiltration had the highest recovery, RNA, and protein yield. After assessing purity further, SEC was the isolation method of choice. These findings serve as the groundwork for future studies that use high throughput omics technologies to investigate the potential of stool-derived EVs as a source for novel biomarkers for early CRC detection.

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KW - cell-derived microparticles

KW - colonic neoplasms/diagnosis

KW - extracellular vesicles/chemistry

KW - gastrointestinal microbiome

KW - tumour

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Assessment of extracellular vesicle isolation methods from human stool supernatant

Abstract

Keywords

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