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In This Article

  • Summary
  • Abstract
  • Introduction
  • Protocol
  • Results
  • Discussion
  • Disclosures
  • Acknowledgements
  • Materials
  • References
  • Reprints and Permissions

Summary

This study describes a method to isolate and purify bacterial extracellular vesicles (BEVs) enriched from human feces via density gradient centrifugation (DGC), identifies the physical characteristics of BEVs from morphology, particle size, and concentration, and discusses the potential applications of the DGC approach in clinical and scientific research.

Abstract

Bacterial extracellular vesicles (BEVs) are nanovesicles derived from bacteria that play an active role in bacteria-bacteria and bacteria-host communication, transferring bioactive molecules such as proteins, lipids, and nucleic acids inherited from the parent bacteria. BEVs derived from the gut microbiota have effects within the gastrointestinal tract and can reach distant organs, resulting in significant implications for physiology and pathology. Theoretical investigations that explore the types, quantities, and roles of BEVs derived from human feces are crucial for understanding the secretion and function of BEVs from the gut microbiota. These investigations also necessitate an improvement in the current strategy for isolating and purifying BEVs.

This study optimized the isolation and purification process of BEVs by establishing two density gradient centrifugation (DGC) modes: Top-down and Bottom-up. The enriched distribution of BEVs was determined in fractions 6 to 8 (F6-F8). The effectiveness of the approach was evaluated based on particle morphology, size, concentration, and protein content. The particle and protein recovery rates were calculated, and the presence of specific markers was analyzed to compare the recovery and purity of the two DGC modes. The results indicated that the Top-down centrifugation mode had lower contamination levels and achieved a recovery rate and purity similar to that of the Bottom-up mode. A centrifugation time of 7 h was sufficient to achieve a fecal BEV concentration of 108/mg.

Apart from feces, this method could be applied to other body fluid types with proper modification according to the differences in components and viscosity. In conclusion, this detailed and reliable protocol would facilitate the standardized isolation and purification of BEVs and thus, lay a foundation for subsequent multi-omics analysis and functional experiments.

Introduction

The gut is widely recognized as the organ harboring the most abundant microbial communities in the human body, with over 90% of bacteria involved in colonization and multiplication1,2. Extensive evidence has demonstrated that the gut microbiota modulates the gut microenvironment and simultaneously interacts with dysfunction in distant organs, primarily through an impaired intestinal barrier3,4. Mounting evidence indicates a correlation between the imbalance of gut microbiota and the progression of inflammatory bowel disease (IBD)5,6, as well as cognitive disorders through the gut-brain axis5,6,7,8. Bacterial extracellular vesicles (BEVs) produced by bacteria play significant roles in these pathological processes.

BEVs are nanoscale particles encapsulating bacterial derivatives, with diameters ranging from 20 to 400 nm. They have been demonstrated to facilitate interactions between bacteria and their host organisms9,10. Despite their invisibility, these particles have garnered increasing attention from researchers due to their prospective broad applications as diagnostic biomarkers, therapeutic targets, and drug delivery vehicles11. Human feces, often used as biospecimens for studying BEVs, predominantly sourced from gut bacteria, contain a complex mixture of water, bacteria, lipids, proteins, undigested food residue, and exfoliated epithelial cells among others. The intricate fecal composition poses challenges to the isolation and purity of BEVs, thereby impeding a comprehensive, objective, and realistic analysis of BEVs. Hence, effective strategies to minimize interference from contaminating components and enhance the yield of BEVs have emerged as critical issues warranting immediate attention.

Existing isolation strategies largely rely on techniques such as ultra-high-speed centrifugation (UC), density gradient centrifugation (DGC), and size exclusion chromatography (SEC)12,13,14,15,16,17. Currently, DGC is one of the most widely applied methods in the field of BEV separation, encompassing two sedimentation-floating modes, "Top-down" and "Bottom-up", which are determined by the initial loading position of the sample. These methodologies differentiate extracellular vesicles (EVs) from other components based on size and density disparities, yielding variable purity and recovery rates. Prior research has indicated that single-approach strategies are insufficient for adequately separating EVs from soluble proteins in body fluid samples, such as lipoprotein in blood18 and Tamm-Horsfall protein in urine19. Additionally, the size distribution of eukaryotic extracellular vesicles (EEVs) often overlaps with that of BEVs, thereby necessitating further methodological enhancements to optimize BEV yield. Consequently, advancing the study of BEVs hinges on the development of effective separation and purification methodologies. Notably, Tulkens et al15 employed an orthogonal biophysical strategy to separate fecal BEVs from EEVs, in which the centrifugation time of a Bottom-up DGC mode was up to 18 h. In contrast, this study reduced it to 7 h, greatly saving the gradient-ultracentrifugation time and simplifying the process.

In the present study, we isolated and purified fecal BEVs employing two DGC modes under optimized buffer conditions, after enriching BEVs with a range of differential centrifugation speeds, from low to extremely high velocity. Evaluations based on morphology, particle size, and concentration indicated a commendable performance by this enhanced method. This study could serve as the foundation for future research, extending its applications to a broader domain, and offering insights into the heterogeneity of BEVs within the human body. It also contributes to the standardization of BEV separation and analysis techniques.

Protocol

The Ethics Committee of Nanfang Hospital, Southern Medical University, sanctioned this study, which was conducted with the informed consent of the participants. All methods employed herein adhered to the standard operating guidelines furnished by the International Human Microbiome Standards (IHMS:Β http://www.microbiome-standards.org/). All subsequent liquid handling procedures were mandated to be carried out within a biosafety cabinet or an ultra-clean bench.

1. Collection and aliquoting of fecal samples

  1. Distribute a stool sampler, a sealed bag, and an iced box, and provide comprehensive instructions to the participants on how to procure and preserve the samples.
  2. Instruct each participant to collect their fecal sample using the provided sampler, and to transport it to the lab at a temperature of 4 Β°C within a 24-h window.
  3. Upon receipt at the lab, use a sterile spoon to aliquot less than 3.5 g of feces into a pre-weighed 50 mL centrifuge tube. Notate the fecal sample's weight on the tube for subsequent pre-treatment procedures.
    PAUSE POINT: If immediate processing of the samples is not feasible, allocate the sample for long-term storage at -80 Β°C after appropriate notation.

2. Feces sample preparation

  1. Chill 500 mL of phosphate-buffered saline (PBS) at 4 Β°C. Filter the pre-chilled PBS through a 0.22 Β΅m Polyethersulfone (PES) filter using a 50 mL syringe into ten 50 mL centrifugation tubes.
  2. Position two 50 mL tubes on ice, each containing 3.5 g of fecal samples. Add 35 mL of PBS to each tube.
    NOTE: Calculate the required amount of PBS for feces dissolution, ensuring a maximum sample concentration of 10% (w/v). If processing additional samples, employ more tubes as needed.
  3. Shake the samples at 300 rpm for 2 h at 4 Β°C, or place them for 8 h at least at 4 Β°C until the feces are completely suspended visibly.

3. Differential speed centrifugation

  1. Chill the high-speed refrigerated centrifuge to 4 Β°C.
  2. Adjust the weight of the two tubes containing the samples prepared in Step 2.3 with PBS to reach a total weight of 0.1 g.
  3. Centrifuge the samples at 3, 000 Γ— g for 20 min at 4 Β°C.
  4. Carefully pipette the supernatant into two clean 50 mL centrifuge tubes, leaving approximately 1 mL above the pellet. Use a disposable plastic Pasteur pipette for this process.
  5. Adjust the weight of the two tubes with PBS to reach a total weight within Β± 0.1 g.
  6. Centrifuge the transferred supernatant at 12, 000 Γ— g for 30 min at 4 Β°C.
  7. Aspirate the supernatant using a 20 mL syringe, remove the syringe needle, and filter it through 0.22 Β΅m filters into 50 mL tubes. At this point, the supernatant volume should be approximately 30 mL.
    ​NOTE: If a significant amount of impurity is still visible after the 12,000 Γ— g centrifugation, it is necessary to repeat the centrifugation step at 12,000 Γ— g for 30 min at 4 Β°C. Failure to do so may result in a significant loss of BEVs due to pore blockage during filtration.

4. Ultra-high-speed centrifugation

  1. Clean the rotor and bucket by wiping them with 75% (v/v) alcohol to eliminate any residual contamination.
  2. Position a 38.5 mL ultracentrifuge tube in the tube holder.
    NOTE: Select the appropriate ultracentrifuge tube based on the sample volume. Avoid ultraviolet radiation and unsuitable chemical reagents for sterilizing centrifugal tubes as indicated in the product manual.
  3. Transfer approximately 30 mL of the filtered fecal supernatant from Step 3.7 into the ultracentrifuge tube.
  4. Fill the ultracentrifuge tube with approximately 8 mL of PBS, leaving a 3 mm gap from the tube's opening.
  5. Place the two ultracentrifuge tubes with the samples in opposing ultracentrifugation buckets, for example, bucket 1 corresponds to 4 (1-4), 2-5, 3-6.
  6. Adjust the weight of the two buckets with PBS to achieve a total weight within Β± 0.005 g.
  7. Install all buckets onto the rotor, regardless of whether the tubes are loaded.
  8. Initiate the vacuum and centrifuge the samples at 160,000 Γ— g for 70 min at 4 Β°C.
  9. Release the chamber vacuum, and open the door onceΒ ReadyΒ is displayed on theΒ HomeΒ page of the instrument.Β 
  10. Remove the rotor from the ultracentrifuge.
  11. Move the buckets from the rotor to the rack, and retrieve the tubes using a nipper.
  12. Discard the supernatant, which will contain visible brown pellets at the bottom.
  13. Resuspend the pellets by repeatedly pipetting them up and down using a 1,000 Β΅L pipette with 1 mL of prechilled (4 Β°C) PBS until completely suspended. Fill the tube with approximately 37 mL of PBS, leaving a 3 mm gap from the opening.
  14. Perform another ultracentrifugation following Steps 4.5-4.11 at 160,000 Γ— g for 70 min at 4 Β°C to remove partially attached contaminating components from the tube walls.
  15. Discard the supernatant, invert the two ultracentrifuge tubes for 5 min, and clear any remaining solution on the inner wall with wipers.
    NOTE: Cleaning the inner wall minimizes interference from residual contamination adhering to the ultracentrifuge tube wall. Choose wipers that will not influence the BEV analysis, particularly regarding particle size.
  16. Resuspend the pellets in each tube by pipetting them up and down with 1.2 mL of pre-chilled (4 Β°C) PBS using a 1,000 Β΅L pipette.
  17. Transfer 1.2 mL of the PBS/BEV solution from one ultracentrifuge tube to a clean 1.5 mL microtube.
    PAUSE POINT: The PBS/BEV solution collected from one ultracentrifuge tube can proceed to Step 6. Store the solution from the other tube at -80 Β°C.

5. Solution preparation for density gradient centrifugation

  1. Preparation of 0.02 M HEPES buffer
    1. Combine 0.477 g of HEPES powder and 0.8 g of NaCl with 90 mL of autoclaved deionized water.
    2. Adjust the pH to 7.2 by adding 1 M sodium hydroxide (NaOH). Bring the volume to 100 mL with deionized water and filter the solution through 0.22 Β΅m PES membranes.
      CAUTION: Sodium hydroxide is a strong caustic alkali. Operators must handle and prepare it carefully in a fume cupboard.
  2. Preparation of density gradient buffer
    1. Calculate the required volume of each density gradient buffer based on the number of ultracentrifuge tubes for density gradient centrifugation (Step 6) (In this protocol, the volumes for 60%, 50%, 40%, 20%, and 10% gradient solutions were 2.5 mL, 3 mL, 6 mL, 6 mL, and 6 mL, respectively).
    2. For the preparation of a 50% (w/v) iodixanol working solution, mix the 0.02 M HEPES buffer and 60% (w/v) iodixanol stock solution in a volume ratio of 1:5 (0.5 mL:2.5 mL).
      NOTE: Use a disposable 20 mL syringe to withdraw the iodixanol stock solution and avoid introducing air.
    3. To prepare iodixanol buffers with different concentrations, combine the 50% iodixanol working solution from Step 5.2.2 with the HEPES buffer obtained in Step 5.1 using a 1,000 Β΅L pipette according to the proportions shown in Table 1.
      ​NOTE: Perform Step 5 on an ultra-clean bench with the lights off. Store the opened iodixanol stock solution in the refrigerator at 4 Β°C to prevent bacterial growth. Keep the iodixanol solution and HEPES buffer protected from light.

6. Establishment of a density gradient centrifugation system

  1. Top-down DGC mode
    1. Combine 500 Β΅L of PBS/BEV solution isolated from Step 4 with 3 mL of PBS. Gently mix the solutions using a 1,000 Β΅L pipette to obtain 3.5 mL of PBS/BEV solution.
    2. Place a 31 mL ultracentrifuge tube on a foam plate with holes and label it as "↓".
    3. Vertically add 3 mL of the 50% iodixanol solution to the bottom of the tube using a 1,000 Β΅L pipette.
    4. Tilt the tube to a 70Β° angle and position a tube holder or other support slightly above the level of the foam plate, below the opening of the tube.
    5. Add 3 mL of 40% iodixanol solution on top of the 50% iodixanol solution using a 1,000 Β΅L pipette.
    6. Add 3 mL of 20% iodixanol solution on top of the 40% iodixanol solution using a 1,000 Β΅L pipette.
    7. Add 3 mL of 10% iodixanol solution on top of the 20% iodixanol solution using a 1,000 Β΅L pipette.
    8. Add 3.5 mL of PBS/BEV solution from Step 6.1.1 on top of the 10% iodixanol solution using a 1,000 Β΅L pipette.
    9. Gently return the tubes to an upright position.
      NOTE: After pipetting, the stratification should be visible.
  2. Bottom-up DGC mode
    1. Place a 31 mL ultracentrifuge tube on a foam plate with holes and label it as "↑".
    2. Vertically add 2.5 mL of the 60% iodixanol stock solution to the bottom of the tube. Mix it gently with 500 Β΅L of PBS/BEV solution isolated from Step 4 using a 1,000 Β΅L pipette to obtain 3 mL of 50% iodixanol/BEV solution.
    3. Tilt the tube to a 70Β° angle and position a tube holder or other support slightly above the level of the foam plate, below the opening of the tube.
    4. Add 3 mL of the 40% iodixanol solution on top of the 50% iodixanol/BEV solution using a 1,000 Β΅L pipette.
    5. Add 3 mL of the 20% iodixanol solution on top of the 40% iodixanol solution using a 1000 Β΅L pipette.
    6. Add 3 mL of the 10% iodixanol solution on top of the 20% iodixanol solution using a 1000 Β΅L pipette.
    7. Add 3.5 mL of PBS on top of the 10% iodixanol solution using a 1,000 Β΅L pipette.
    8. Gently return the tubes to an upright position.
    9. At this point, 200 Β΅L of the suspension obtained in Step 4.17 remained, which can be analyzed subsequently as a group named "UC".
      ​NOTE: When transferring solutions in Step 6, always keep the pipette tip against the ultracentrifuge tube wall perpendicular to the axis of the tube.

7. Density gradient centrifugation and fraction collection

  1. Adjust the weight of the two tubes with PBS to achieve a total weight within Β± 0.005 g.
  2. Place the tubes in the buckets according to Step 4.5 and subject them to centrifugation at 160,000 Γ— g for 7 h at 4 Β°C.
  3. Collect the fractions using a pipettor (1000 Β΅L) from top to bottom against the side wall in the following order: 3 mL, 2 mL, 1 mL, 1 mL, 1 mL, 1 mL, 1 mL, 1 mL, 1.5 mL, and 3 mL into a 38.5 mL ultracentrifuge tube.
    ​NOTE: Maintain the line of sight at the same level as the liquid surface.
  4. Conduct ultracentrifugation for each fraction obtained in Step 7.3 according to Step 4 at 160,000 Γ— g for 70 min at 4 Β°C.
  5. Remove the supernatant and invert the ultracentrifuge tubes for 5 min.
  6. Resuspend the pellets in 200 Β΅L of pre-chilled (4 Β°C) PBS using a 200 Β΅L pipette.
  7. Transfer the PBS/BEV solution into a clean 1.5 mL microtube.
  8. Label the fractions from F1 to F10 and analyze them based on Step 8.
    PAUSE POINT: If the samples obtained in Step 7.8 cannot be processed immediately, store them at -80 Β°C.

8. Characterization and quantitative analysis of the collected fractions

  1. Determine the absorbance values (OD 340 nm) of each fraction using a microplate detector with a blank control to calculate their corresponding density.
    NOTE: Replace PBS/BEV solution (Step 6.1.1 and Step 6.2.2) with PBS to establish a blank control.
    1. Prepare 100 Β΅L each of 0%, 5%, 10%, 12.5%, and 20% iodixanol solution diluted by 0.02 M HEPES based on 50% stock solution (Step 5.2.2) as the standards, corresponding to densities of 1.0058 g/mL, 1.0318 g/mL, 1.058 g/mL, 1.0708 g/mL, and 1.111 g/mL, respectively.
    2. Add 50 Β΅L of each fraction from the blank control (prepared in Step 7.3) and 50 Β΅L of each standard solution (prepared in Step 8.1.1) to duplicate wells of a 96-well plate.
    3. Set the wavelength to 340 nm, measure the endpoint optical density, and calculate the density of each fraction.
    4. Identify F4-F9 as the range of BEV fractions based on their density.
  2. Determine the protein concentration of the BEV fractions using the bicinchoninic acid assay (BCA).
    1. Dilute the substance tenfold in PBS provided by the manufacturer to prepare a 0.5 Β΅g/Β΅L standard protein solution.
    2. Add the standard protein solution (prepared in Step 8.2.1) with varying volumes according to the reagent instructions, and supplement each well of a 96-well plate with PBS to a total volume of 20 Β΅L.
    3. Add 20 Β΅L of the samples prepared in Step 7.8 and the samples left after UC defined in Step 6.2.9 to each well.
    4. Mix reagents A and B in a ratio of 50:1, and transfer 200 Β΅L to each well.
    5. Incubate the plate in a 37 Β°C water bath for 30 min.
    6. Measure the absorbance value using a microplate reader, calculate the protein concentration (Β΅g/Β΅L), and determine the protein content (Β΅g) of the samples based on the standard curve (x: optical density; y: protein concentration) generated from the values of the standard solutions diluted in Step 8.2.2.
  3. Characterize the BEV fractions defined in Step 8.1.4 using transmission electron microscopy (TEM) to verify the presence of BEVs. All procedures below should be performed on ice.
    1. Apply 10 Β΅L of each isolated F4-F9 fraction from Step 7.8 and the samples left after UC defined in Step 6.2.9 onto Formvar/Carbon supported copper grids for 20 min, and blot with filter paper.
    2. Rinse the samples with 100 Β΅L of PBS three times for 1 min each, and blot with filter paper.
    3. Fix the samples with 100 Β΅L of 1% (w/v) glutaraldehyde for 5 min and blot with filter paper.
    4. Wash the grids with 100 Β΅L of PBS ten times for 2 min each, and blot with filter paper.
    5. Stain the grids with 50 Β΅L of 1.5% (w/v) uranyl acetate for 10 min, and blot with filter paper.
      CAUTION: Uranyl acetate is radioactive and extremely toxic when in contact with the skin or inhaled. Handle solutions with uranyl acetate in a fume cupboard and follow appropriate safety measures.
    6. Transfer the grids onto a 1% (w/v) methylcellulose drop for 5 min and blot with filter paper.
    7. Store the air-dried grids in a dark, dust-free environment until observation.
    8. Capture images and analyze them using a TEM.
  4. Characterize the BEV fractions defined in Step 8.1.4 using nanoparticle tracking analysis (NTA) to count the number of particles.
    1. Calibrate the system using 110 nm polystyrene particles.
    2. Wash the sample pool using PBS.
    3. Dilute the samples from different fractions acquired in Step 7.8 and the samples left after UC defined in Step 6.2.9 to a concentration in the range of 105-109 particles/mL, with an optimized concentration of 107 particles/mL.
    4. Record and analyze at 11 positions with three replications, maintaining the temperature around 23-30 Β°C.
  5. Analyze the protein contents of the samples by coomassie brilliant blue staining (CBBS) and western blotting (WB).
    1. Dilute the BEVs samples from different fractions obtained in Step 7.8 and the samples left after UC defined in Step 6.2.9 using PBS and 5 Γ— loading buffer to a final concentration of 0.5 or 1 Β΅g/Β΅L, if quantitation is needed, ensuring sufficient sample loading of 20 Β΅L (10 Β΅g or 20 Β΅g) of each well in Step 8.5.2. Boil the samples at 95 Β°C for 10 min.
    2. Assemble the prefabricated polyacrylamide gel into the electrophoresis tank, and transfer the samples to the wells.
    3. Conduct vertical electrophoresis with the following parameters: 160 V for 50 min.
    4. Stain the gel in Coomassie brilliant blue solution for 1 h, rinse in deionized water until the blue background lightens, and capture images with a camera.
    5. Perform protein blotting procedures for other gels with the following parameters: 400 mA for 20 min.
    6. Block the blotting membranes with a 5% (w/v) BSA solution for 1 h at room temperature.
    7. Wash the membranes in TBST buffer three times for 5 min each.
    8. Incubate the membranes with primary antibodies (BEV markers: LPS, OmpA, LTA; EEV markers: CD63, CD9, TSG-101, Syntenin, Integrin Ξ²1; Other contamination markers: Flagellin, Calnexin) for 8-12 h at 4 Β°C.
    9. Wash the membranes in TBST buffer three times for 10 min each.
    10. Incubate the membranes with secondary antibodies for 1 h at room temperature.
    11. Perform Step 8.5.9.
    12. Develop the blotting using a chemiluminescence apparatus.
    13. Replace PBS/BEV solution (Step 6.1.1 and Step 6.2.2) with BEVs from Escherichia coli to establish a positive control (see Table of Materials for the procedure of isolating crude E. coli-BEVs), and conduct all the above experiments for characterizing BEVs.
      PAUSE POINT: Determine F6-F8 as the distribution of BEV-enriched fractions based on the results of the characterization described above for fecal BEVs, and utilize this narrowed range for subsequent analysis.
  6. Calculate the recovery rates in terms of particles and proteins to assess the efficiency of the two DGC modes. The results below are presented as percentages.
    1. Calculate the recovery rates of particles in the Top-down mode: total particles in F6-F8/particles after UC defined in Step 6.2.9.
    2. Calculate the recovery rates of particles in the Bottom-up mode: total particles in F6-F8/particles after UC defined in Step 6.2.9.
    3. Calculate the recovery rates of proteins in the Top-down mode: total protein contents in F6-F8 (Β΅g)/protein content after UC defined in Step 6.2.9 (Β΅g).
    4. Calculate the recovery rates of proteins in the Bottom-up mode: total protein contents in F6-F8 (Β΅g)/protein content after UC defined in Step 6.2.9 (Β΅g).
  7. Calculate the particle/protein ratio to assess the purity traditionally defined of UC and the two DGC modes, and the results below were all presented as percentages.
    1. Particle/protein ratio after UC defined in Step 6.2.9: particles after UC/protein content after UC (Β΅g).
    2. Particle/protein ratio in the Top-down mode: total particles in F6-F8/protein content in F6-F8 (Β΅g).
    3. Particle/protein ratio in the Bottom-up mode: total particles in F6-F8/protein content in F6-F8 (Β΅g).
  8. Select the most suitable centrifugation mode (Top-down mode was selected in the protocol) for fecal BEV purification and future analysis.

Results

Determine the distribution of BEV-enriched fractions
To determine the distribution of bacterial extracellular vesicles (BEVs)-enriched fractions, a blank control was established to measure the absorbance values at OD 340 nm, and the density of each fraction was calculated based on the measurements and iodixanol guidelines (Step 8.1). Table 2 presents the density results, demonstrating that fractions F4 to F9 exhibited densities within the range typically associated with extracellul...

Discussion

Bacterial extracellular vesicles (BEVs) are lipid-bilayer nanoparticles secreted by bacteria, carrying a wealth of proteins, lipids, nucleic acids, and other bioactive molecules, contributing to mediating the functional effects of bacteria20. BEVs derived from the gut have been verified to be involved in the development of diseases, such as inflammatory bowel disease, Crohn's disease, and colorectal cancer, and also affect general metabolism and mediate impaired cognitive function

Disclosures

The authors declare no conflicting interests.

Acknowledgements

This work was supported by the National Science Fund for Distinguished Young Scholars (82025024);Β the Key project of the National Natural Science Foundation of China (82230080);Β the National Key R&D Program of China (2021YFA1300604); the National Natural Science Foundation of China (81871735, 82272438, and 82002245);Β GuangdongΒ Natural Science FundΒ forΒ Distinguished Young Scholars (2023B1515020058);Β the Natural Science Foundation of Guangdong Province (2021A1515011639);Β the Major State Basic Research Development Program of Natural Science Foundation of Shandong Province in China (ZR2020ZD11);Β the Post-doctoral Science Foundation (2022M720059); the Outstanding Youths Development Scheme of Nanfang Hospital, Southern Medical University (2022J001).

Materials

NameCompanyCatalog NumberComments
1 % (w/v) glutaraldehyde (prepared from 2.5 % stock solution in deionized water)ACMECAP1126Morphological observation for BEVs using TEM at Step 8.3.3
1 % (w/v) methylcellulose (prepared from original powder in deionized water)Sigma-AldrichM7027Morphological observation for BEVs using TEM at Step 8.3.6
1.5 % (w/v) uranyl acetate (prepared from original powder in deionized water)Polysciences21447-25Morphological observation for BEVs using TEM at Step 8.3.5
1000 ΞΌL, 200 ΞΌL, 10 ΞΌL PipetteKIRGENKG1313, KG1212, KG1011Transfer the solution
5 % (w/v) bovine serum albumin solution (prepared from the original powder in TBST buffer)Fdbio scienceFD0030Used in western blotting for blocking at Step 8.5.6
5 Γ— loading bufferFdbio scienceFD006Used in western blotting and Coomassie brilliant blue stain at Step 8.5.1
75 % (v/v) alcoholLIRCONLIRCON-500 mLSurface disinfection
96-well plateRarA8096Measure the absorbance valuesΒ 
Anti-Calnexin antibodyAbcamab92573Western blotting (Primary Antibody)
Anti-CD63 antibodyAbcamab134045Western blotting (Primary Antibody)
Anti-CD9 antibodyAbcamab236630Western blotting (Primary Antibody)
Anti-Flagellin antibodySino Biological40067-MM06Western blotting (Primary Antibody)
Anti-Integrin beta 1 antibodyAbcamab30394Western blotting (Primary Antibody)
Anti-LPS antibodyThermo FisherMA1-83152Western blotting (Primary Antibody)
Anti-LTA antibodyThermo FisherΒ MA1-7402Western blotting (Primary Antibody)
Anti-OmpA antibodyCUSABIOCSB-PA359226ZA01EOD, https://www.cusabio.com/Western blotting (Primary Antibody)
Anti-Syntenin antibodyAbcamab133267Western blotting (Primary Antibody)
Anti-TSG101 antibodyAbcamab125011Western blotting (Primary Antibody)
AutoclaveZEALWAYGR110DPSterilization for supplies and mediums used in the experiment
BalanceMettler ToledoAL104Balance the tube sample-loaded with PBS
Bicinchoninic acid assayΒ Fdbio scienceFD2001Measure protein content of BEVs at Step 8.2
BioRenderBioRenderhttps://app.biorender.comMake the schematic workflow of BEVs isolation and purification showed in Figure 1
Biosafety cabinetHaierHR1200- II B2Peform the procedures about feces sample handling
Centrifuge 5810 R; Rotor F-34-6-38Eppendorf5805000092; 5804727002, adapter: 5804774000Preprocess for BEVs (Step 3)
Chemiluminescence ApparatusBIO-OIOI600SE-MFUsed in western blotting for signal detection at Step 8.5.12
Cytation 5BioTekF01Microplate detector for measuring the absorbance (Step 8.1) and fluorescence (Figure 6) valuesΒ 
Dil-labled low density lipoproteinACMECAC12038Definition of distribution of interfering componentsΒ 
Electrophoresis equipmentBio-rad1658033Used in western blotting for protein separation and transfer at Step 8.5.2, 8.5.3, 8.5.5
Enhanced Chemiluminescence kit HRPΒ Fdbio scienceFD8020Used in western blotting for signal detection at Step 8.5.12
Escherichia coliΒ American Type Culture CollectionATCC8739Isolate BEVs as a positive control. Protocol: Dissolve 25 g of the LB powder in 1 L deionized water, and autoclave. Transfer the 800 ΞΌL of preserved Escherichia coli into the medium. Cultivate at 37 Β°C in the incubator shaker. Then centrifuge at 3, 000 Γ— g for 20 min at 4 Β°C, 12, 000 Γ— g for 30 min at 4 Β°C, filter the supernatant through 0.22 ΞΌm membrane, and perform ultra-speed centrifugation at 160, 000 Γ— g for 70 min at 4 Β°C. Pellet defined as crude BEVs from Escherichia coli was suspended in 1.2 mL PBS (Step 3, 4).Β Β Β Β 
Falcon tubes 50 mLKIRGENKG2811Preprocess for BEVs (Step 3)
Feto Protein Staining BufferAbsciab.001.50Coomassie brilliant blue staining at Step 8.5.4
Filter paperBiosharpBS-TFP-070BMorphological observation for BEVs using TEM at Step 8.3 (Blotting the solution)
Formvar/Carbon supported copper gridsΒ Sigma-AldrichTEM-FCF200CU50Morphological observation for BEVs using TEM at Step 8.3
HEPES powderMeilunbioMB6078Prepare iodixanol buffers with different concentrations for density gradient centrifugation
HRP AffiniPure Goat Anti-Mouse IgG (H+L)Fdbio scienceFDM007Western blotting (Secondary Antibody)
HRP AffiniPure Goat Anti-Rabbit IgG (H+L)Fdbio scienceFDR007Western blotting (Secondary Antibody)
Incubator shakerQiangwenDHZ-LCultivate Escherichia coliΒ 
Kimwipesβ„’ Delicate Task WipesKimtech Science34155Wipe the inner wall of the ultracentrifuge tube at Step 4.15
LB brothHopebioHB0128Cultivate Escherichia coliΒ 
Low temperature freezer (-80 Β°C)HaierDW-86L338JStore the samples
MethanolAlalddinM116118Used in western blotting for activating PVDF membrane at Step 8.5.5
Micro tubes 1.5 mLKIRGENKG2211Recover fractions after density gradient centrifugation
Micro tubes 2 mLKIRGENKG2911Recover fractions after density gradient centrifugation
Micro tubes 5 mLBBIF610888-0001Recover fractions after density gradient centrifugation
Microplate readerΒ Thermo FisherΒ Multiskan MK3Measure protein content of BEVs at Step 8.2
Millipore filter 0.22 ΞΌmMerck milliporeSLGP033RBFiltration sterilization; Material: polyethersulfone, PES
NaClGHTECH1.01307.040Density gradient centrifugation solution
NaOHGHTECH1.01394.068Density gradient centrifugation solution (pH adjustment)
Optimaβ„’ XPN-100Beckman CoulterA94469Ultracentrifugation for BEVs isolation at Step 4, 7
OptiPrepβ„’Serumwerk Bernburg AG1893Density gradient centrifugation stock solution
Orbital ShakerYouningCS-100Dissolve feces at Step 2
Phosphate buffered salineProcellPB180327Dissolve feces at Step 2
PipettorEppendorf3120000267, 3120000259Transfer the solution
Plastic pasteur pipetteABCbioABC217003-4Remove supernatant in preprocessing at Step 3.4
Polyvinylidene difluoride (PVDF) membranesMilliporeISEQ00010, IPVH00010Used in western blotting for protein transfer at Step 8.5.5
Prefabricated polyacrylamide gel, 4–20% 15 WellsACEF15420GelUsed in western blotting for protein separation at Step 8.5.2, 8.5.3
Primary antibody diluentFdbio scienceFD0040Used in western blotting at Step 8.5.8
Protein ladderFdbio scienceFD0672Used in western blotting and Coomassie brilliant blue stain at Step 8.5
Rapid protein blotting solutionUBIOUW0500Used in western blotting for protein transfer at Step 8.5.5
Rotor SW 32 Ti Swinging-Bucket RotorBeckman Coulter369650Ultracentrifugation for BEVs isolation at Step 4, 7
Syringe 20 mL, 50 mLΒ JetwayZSQ-20ML, YCXWJZSQ-50 mLTransfer buffers amd remove supernatant in preprocessing
TBS powderFdbio scienceFD1021Used in western blotting at Step 8.5
Transmission electron microscope (TEM)HitachiΒ H-7650Morphological observation for BEVs at Step 8.3
Tween-20Fdbio scienceFD0020Used in western blotting at Step 8.5
Ultracentrifuge tubeBeckman326823, 355642Ultracentrifugation for BEVs isolation at Step 4, 7
Ultra-clean benchAIRTECHSW-CJ-2FDPeform the procedures about liquid handling
Water bathBluepardCU600Used for measuring protein content of BEVs at Step 8.2.5
ZetaViewParticle MetrixS/N 21-734, Software ZetaView (version 8.05.14 SP7)Nanoparticle tracking analysis (NTA) for measuring the particle size and concentrarion of BEVs at Step 8.4

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