An exosome is a new generation of drug delivery carriers. We established an exosome isolation protocol with high yield and purity for siRNA delivery. We also encapsulated fluorescently labelled non-specific siRNA into exosomes and investigated the cellular uptake of siRNA-loaded exosomes in cancer cells.
Extracellular vesicles, in particular exosomes, have recently gained interest as novel drug delivery vectors due to their biological origin, abundance, and intrinsic capability in intercellular delivery of various biomolecules. This work establishes an isolation protocol to achieve high yield and high purity of exosomes for siRNA delivery. Human Embryonic Kidney cells (HEK-293 cells) are cultured in bioreactor flasks and the culture supernatant (hereon referred to as conditioned medium) is harvested on a weekly basis to allow for enrichment of HEK-293 exosomes. The conditioned medium (CM) is pre-cleared of dead cells and cellular debris by differential centrifugation and is subjected to ultracentrifugation onto a sucrose cushion followed by a washing step, to collect the exosomes. Isolated HEK-293 exosomes are characterized for yield, morphology and exosomal marker expression by nanoparticle tracking analysis, protein quantification, electron microscopy and flow cytometry, respectively. Small interfering RNA (siRNA), fluorescently labeled with Atto655, is loaded into exosomes by electroporation and excess siRNA is removed by gel filtration. Cell uptake in PANC-1 cancer cells, after 24 h incubation at 37 °C, is confirmed by flow cytometry. HEK-293 exosomes are 107.0 ± 8.2 nm in diameter. The exosome yield and particle-to-protein ratio (P:P) ratio are 6.99 ± 0.22 × 1012 particle/mL and 8.3 ± 1.7 × 1010 particle/µg, respectively. The encapsulation efficiency of siRNA in exosomes is ~ 10-20%. Forty percent of the cells show positive signals for Atto655 at 24 h post-incubation. In conclusion, exosome isolation by ultracentrifugation onto sucrose cushion offers a combination of good yield and purity. siRNA could be successfully loaded into exosomes by electroporation and subsequently delivered into cancer cells in vitro. This protocol offers a standard procedure for developing siRNA-loaded exosomes for efficient delivery to cancer cells.
Exosomes are a subtype of extracellular vesicles (EV) ranging from 50-200 nm in diameter, secreted by various cell types such as immune cells1,2, cancer cells3,4,5,6 and stem cells7. Exosomes have also been shown to be present in various physiological fluids8,9,10,11. The combination of the inherent ability of exosomes to carry various biomolecules (e.g., RNA and proteins)12,13,14 and the effective delivery of these biomolecules into recipient cells15,16,17 attracted interest for their potential as nano-scale drug delivery vectors. Various small molecules that serve as anti-cancer and anti-inflammatory drugs have been demonstrated to be successfully loaded into exosomes and delivered to target cells18,19,20,21,22,23,24,25,26,27. Interestingly, nucleic acids such as siRNA28,29 and microRNA30 have also been successfully loaded into exosomes via electroporation and delivered to target cells.
Recently, RNA interference (RNAi) via small interfering RNA (siRNA) has gained more interest as the preferred mechanism in gene silencing due to its high specificity, potent effect, minimal side effects and ease of siRNA synthesis28,29. siRNAs are double-stranded RNA molecules ranging from 19 to 25 nucleotides in length that triggers sequence-specific catalytic mRNA knockdown. Due to its large molecular weight and polyanionic nature, passive uptake of naked siRNA into cells is hindered28,29. It is also not possible for naked siRNA to be injected into the systemic circulation due to rapid degradation by plasma nucleases31. Thus, encapsulation of siRNA in a nanocarrier would aid the effective delivery and uptake of siRNA into the target cells.
Exosomes are an ideal system for siRNA encapsulation as its structure is comprised of a hollow, aqueous core enveloped by a phospholipid bilayer. Exosomes not only have good stability in the blood but also have natural targeting properties to deliver functional RNA into cells32. The study conducted by Alvarez-Erviti et al. successfully demonstrated effective delivery of siRNA to the brains of mice using engineered exosomes with virtually no complications31. It is hypothesized that exosome-based therapy is relatively safer than other therapies as exosomes do not replicate endogenously as cells would and therefore do not exhibit metastatic properties15.
Various methods have been reported to successfully isolate exosomes from either cell culture or physiological fluids. The most popular method uses ultracentrifugation to pellet exosomes from the starting material31,32,33. This method can be quite harsh on exosomes and usually co-precipitates proteins from the sample. Combining ultracentrifugation with a density-based separation such as sucrose gradients is becoming more common, to reduce protein and non-exosomal contamination in the isolated exosomes19,34. Size-exclusion chromatography (SEC) allows separation of exosomes from other types of extracellular vesicles (EV) by size and can also result in minimal protein contamination but is limited by small amount of starting material it can process35,36. Immunoaffinity capture uses beads coated with antibodies that bind to exosomal surface proteins such as tetraspanins or other cell-specific marker that allows specific capture of exosomes rather than EVs or other proteins, as well as isolating sub-population of exosomes from whole samples, but again is limited by the amount of starting material and is costly36,37. Polymer-based precipitation of exosomes used to be popular too, but since it is a rather crude precipitation, it leads to a higher non-exosomal vesicle and protein contamination38,39.
Electroporation has been reported for its inefficiency as a method to load exosomes with siRNA due to protein aggregation15,28,31. Transfection-based approaches were demonstrated to have better loading efficiency and protein stability, but is undesirable due to its toxicity and side effects of transfection agents in altering cellular gene expression28. Thus, electroporation has been more widely used in siRNA loading into exosomes as it is a safer method. However, an optimized encapsulation method needs to be established in order to deliver adequate amounts of siRNA to the target site for a potent gene knockdown.
Here, we propose an exosome isolation protocol using density-based ultracentrifugation onto just a single 25% (w/w) sucrose cushion prepared in deuterium oxide, rather than a sucrose density gradient. This is a cost-effective method that circumvents the laborious density gradient preparation and allows processing of large volumes of starting material, yet results in intact exosomes of high yield and purity suitable for subsequent loading with siRNA. Fluorescent Atto655-conjugated non-specific siRNA was loaded into Human Embryonic Kidney cells (HEK-293 cells) derived exosomes via electroporation and delivered to human pancreatic adenocarcinoma (PANC-1) cancer cells in vitro.
1. Cell Culture in a Bioreactor Flask
Figure 1: Culture of cells in bioreactor flask for exosome production. (A) Simplified anatomy of the bioreactor flask. (B) Starting culture in the bioreactor flask. See Table of Materials for the composition of normal and exosome-depleted medium (C) Harvesting conditioned medium (CM) and maintenance of culture in the bioreactor flask. Please click here to view a larger version of this figure.
2. Conditioned Medium (CM) Harvesting from the Bioreactor Flask
3. Exosome Isolation onto a Sucrose Cushion
Figure 2: Isolation and characterization of exosomes. (A) Pre-clearing harvested conditioned medium (CM) from dead cells and cell debris. (B) Isolating exosomes from CM onto sucrose cushion. (C) Washing step to remove sucrose and contaminating proteins. (D) Isolated exosomes were then subjected to physicochemical, biochemical and morphological characterization. Please click here to view a larger version of this figure.
4. Characterization of Exosome Size and Yield by Nanoparticle Tracking Analysis (NTA)
5. Characterization of Exosome Purity by Particle:Protein Ratio Determination
6. Characterization of Exosomal Marker Expression by Flow Cytometry
7. Characterization of Exosome Morphology by Transmission Electron Microscopy (TEM)
8. siRNA Encapsulation into Exosomes by Electroporation
9. Removal of Free siRNA Using Size Exclusion Chromatography (SEC)
10. In Vitro Uptake of siRNA-Loaded Exosomes into PANC-1 Cells
The physicochemical characterization of exosomes isolated from HEK-293 cells (HEK-293 Exo) are summarized in Table 1. The size measured using nanoparticle tracking analysis (NTA) instrument was 107.0 ± 8.2 nm. Exosome yield from the HEK-293 cells, also analyzed using the NTA instrument, was 6.99 ± 0.22 x 1012 p/mL from ~24 mL of CM (obtained from 2 rounds of harvest). Purity of the HEK-293 Exo assessed by calculating the particle-to-protein ratio (P:P) was 8.3 ± 1.7 × 1010 p/µg.
The size distribution of isolated HEK-293 Exo is shown in Figure 3A. Morphological analysis using transmission electron microscopy (TEM) showed the HEK-293 Exo were spherical structures slightly above 100 nm in size (Figure 3B). This result agrees with that from NTA measurement (Figure 3A). The isolated HEK-293 Exo were positive for CD81, CD9 and CD63, which are canonical markers used to identify vesicles as exosomes (Figure 3C).
For purification of exosomes using size exclusion chromatography (Figure 4), the percentage recovery of exosomes was calculated by dividing the total exosome particle number recovered in the 10 fractions collected (F0-F9) with the initial exosome particle number used, while the percentage recovery of siRNA was calculated by dividing the total fluorescence intensity obtained from F3, F4 and F5 with the total fluorescence intensity obtained from all 10 fractions collected. The recovery of exosome and siRNA post-purification was calculated as 75.0% and 80.4%, respectively. The encapsulation efficiency of siRNA in exosomes was ~10-20%, calculated using the siRNA standard curve established (Figure 4C).
Qualitative analysis of in vitro uptake of exosomes loaded with the fluorescent Atto655-siRNA by flow cytometry showed that PANC-1 cells treated with siRNA-encapsulated exosomes recorded the largest shift in fluorescence signal (Figure 5A). PANC-1 cells treated with siRNA-encapsulated exosomes recorded a higher percentage of population positive for the Atto655 signal (39.4%) compared to that treated with unloaded exosomes and siRNA mixture (0.56%), which corroborated the observation above (Figure 5B). The degree of cellular uptake of siRNA (expressed as the fold difference in mean fluorescence intensity (MFI) values from that of untreated cells) was also observed to be significantly higher in PANC-1 cells treated with siRNA-encapsulated exosomes (MFI fold difference = 5.1) compared to that treated with the exosome-siRNA mixture (MFI fold difference = 1.1) (Figure 5C). These observations demonstrated that the siRNA-encapsulated exosomes were internalized by the PANC-1 cells and that they effectively delivered the siRNA intracellularly.
Figure 3: Biochemical and morphology analysis of HEK-293 exosomes. (A) Size distribution of HEK-293 exosomes using Nanoparticle Tracking Analysis (NTA). The curve shows a superimposed histogram from 3 different captures at 30 s interval with red areas denoting standard deviation between measurements (n = 3). (B) Transmission Electron Microscopy (TEM) images of the naïve HEK-293 exosomes. Scale bar: 100 nm. (C) Detection of exosomal markers CD81, CD9 and CD63 using flow cytometry on HEK-293 exosomes. Exosomes were coupled to aldehyde/sulphate latex beads prior to detection. Exosome-beads complex were subsequently stained with fluorophore-conjugated anti-CD81, anti-CD9 and anti-CD63 antibodies. Degree of expression of the markers are expressed as the fold difference in median fluorescence intensity (MFI) values from that of the control (exosome-beads complex stained with the corresponding isotype). Values are expressed as mean ± SD, where n = 3. Please click here to view a larger version of this figure.
Figure 4: Exosome purification post-electroporation. (A) Elution profiles (F0-F9) of Atto655-siRNA and electroporated exosomes using size exclusion chormatography. (B) NTA analysis of both Atto655-siRNA and exosome from F0 to F9 using size exclusion chormatography. (C) The calibration curve of Atto655 labelled siRNA. Fluorescence intensities were obtained by plate reader at Ex/Em: 640-10/680 nm; Gain 2800. Values are expressed as mean ± SD (n = 3). Please click here to view a larger version of this figure.
Figure 5: Cellular uptake of siRNA-encapsulated exosomes into PANC-1 cells at 4 h. (A) Histograms comparing cellular uptake of unloaded exosomes + siRNA mixture and siRNA-encapsulated exosomes. (B) Comparison of the uptake of unloaded exosomes + siRNA mixture at 4h by pseudocolor plot. (C) The fold difference in mean fluorescence intensity (MFI) values of the samples tested compared to that of untreated cells. Values are expressed as mean ± SD, where n = 3. *** P < 0.001. NS: not significant. One-way ANOVA was used for statistical analysis. Please click here to view a larger version of this figure.
Exosome | Size1,2 (nm) |
Yield1,2,3 (p/mL) |
[Protein]2,4 (µg/mL) |
Particle-to-protein (P:P) ratio5 (p/µg) |
HEK-293 | 107.0 ± 8.2 | 6.99 ± 0.22 x 1012 | 84.3 ± 9.8 | 8.3 ± 1.7 x 1010 |
1 Measured using nanoparticle tracking analysis (NTA instrument) 2 Values are expressed as mean ± SD, where n=3 3 Yield was obtained by cell-conditioned medium pooled from 2 rounds of harvesting from bioreactor flasks (~24 mL) 4 Measured using a protein assay kit 5 Value obtained by using formula: P:P ratio = Yield / [Protein] |
Table 1: Physicochemical characterization of exosomes.
Obtaining a decent exosome yield from cultured cells, which are enough for several rounds of in vitro or in vivo studies, is still a challenge. According to the manufacturer, the bioreactor flasks were intended for production of antibodies and proteins with high yield from culture of various immortalized cell lines. This allows the cells to continuously enrich the culture medium with the desired product, resulting in a concentrated conditioned medium (CM) in the cell-compartment. Theoretically, the same concept would be beneficial in exosome production from various cell lines, and indeed culturing these cells in the bioreactor flasks was demonstrated to significantly increase the exosome yield40. The large medium reservoir continuously supplies nutrients to and removes wastes from the cell compartment through a 10 kDa semi-permeable membrane, allowing prolonged culture without requiring a large volume of medium to be in contact with the cells, or regular flasks changing, which can ultimately save the overall cost and labor of high-scale exosome production40. It was also demonstrated that the morphology, phenotype as well as the immunomodulatory functions of exosomes isolated cells long-term bioreactor flasks cultures are similar to that sourced from cells cultured in regular 75 cm2 flasks40. Culture of other immortalized cell lines as exosome sources in the bioreactor flask would therefore help increase their exosome yield while maintaining their integrity and function. This form of culture is however not applicable to primary cells with limited division cycles, and those that cannot be cultured in high density.
Since harvest of the CM is done weekly, and the cells in culture were never passaged, it can be assumed that the cells in the bioreactor flask are not growing in a monolayer like the regular cell culture. They are most likely to form clusters with necrotic centers, or simply detach from the surface and die when the cells are too confluent for a monolayer. Visual inspection of the cell compartment of the bioreactor flask is not possible to confirm this assumption, but is reflected by the large number of dead cells obtained during the CM harvesting. Regular removal of poorly adherent and non-viable cells from the bioreactor flask can prevent the build-up of materials on the semi-permeable membrane that can adversely affect the exchange of gas, nutrients and waste between the cell compartment and the medium reservoir, thus allowing prolonged culture in the bioreactor flasks for >6 months40. In this context, this non-regularity of cell growth in the bioreactor flasks is ideal as we speculate that it mimics the actual condition of tumor growth in vivo more closely than the conventional monolayer cell culture, and it is hoped that the exosomes produced by the cancer cells in the bioreactor flask would be more similar to that secreted by tumors in vivo. This would be particularly beneficial in studies looking into the role of tumor-derived exosomes in the progression of the tumor pathology. Tumor-derived exosomes have been reported to intrinsically and preferentially home to their tissue of origin32, therefore having exosomes produced in a system mimicking their in vivo production would also be desirable in studies looking at exploring the passive targeting ability of exosomes as drug nanocarriers.
The P:P ratio was reported as a parameter to assess the purity of isolated exosomes from contaminating proteins from the culture medium of physiological fluids from which exosomes were sourced from41. The P:P ratio of 8.3 ± 1.7 × 1010 p/µg obtained in this study falls within the high purity range proposed in the study. This ratio highlights the danger of using protein concentration to express the yield or dose of exosomes isolated or used in downstream studies respectively, as this does not reflect the true amount of exosomes available in the sample given the problem of protein contamination during isolation. NTA via instruments such as NanoSight, which measures the concentration of exosomes in terms of particle number, is a more sensible and accurate way of quantifying exosomes.
Highly accurate weighing during the preparation of the 25% sucrose solution in deuterium oxide is crucial as this method is a density-based isolation. Exosomes have a rather narrow range of flotation density in sucrose solution so accurate preparation of the sucrose cushion will reduce contamination of non-exosomal vesicles such as apoptotic bodies or Golgi-derived vesicles during isolation42. It is advised not to keep leftover sucrose solution and using it even after one day so as to avoid risk of factors that can alter its density such as loss or addition of water in the solution by either evaporation or condensation of air in the tube. Use of a swing-out rotor is also essential during centrifugation onto the sucrose cushion to allow even migration of exosomes from the CM to the sucrose solution.
Withdrawing the sucrose solution post-centrifugation is also a delicate step, and it involves finding a compromise between maximizing the amount of exosomes recovered, and not too much that protein from culture medium is introduced to the exosome sample withdrawn. The interface between the sucrose solution and the condition medium is where proteins from the culture medium would collect post-centrifugation, and can usually be seen as a dark brown ring that sits on the interface. In our hands, withdrawing 2 mL of the sucrose cushion from the initial 3 mL added is the optimum volume that agrees with the compromise mentioned above. The volumes described in this protocol are for the specific rotors used; therefore, it is advised to optimize the volume of sucrose to be withdrawn when scaling up or down the volumes for the types of rotors available in different facilities. It is also important to avoid the area right at the center of the bottom of the tube when withdrawing the sucrose, as this is where particles of higher density than sucrose will sediment and can usually be seen as an off-white pellet.
The washing step with a relatively large amount of PBS helps to further reduce the degree of protein contamination during exosome isolation41. This step is also essential in removing excess sucrose from the exosomes so as to avoid osmotic damage to the exosomes themselves or the biomolecules within the exosomal lumen, as well as reducing the risk of bacterial and/or fungal growth in the exosome stock. Preparing the sucrose solution in deuterium oxide rather than water helps to reduce the amount of sucrose needed to achieve the exosome flotation density for isolation, hence reducing the risk of both osmotic damage and microbial contamination. After the first centrifugation onto the sucrose cushion, the exosome-containing sucrose layer withdrawn and added to the PBS can be stored at 4 °C and processed the following day if faced with time constraints.
To the best of our knowledge, the exosome/siRNA molar ratio is an important factor in determining the efficiency of electroporation. In this protocol, we used 1:60 as the exosome to siRNA molar ratio. As the encapsulation ability of different types of exosomes are different, we strongly suggest this to be optimized on a case-by-case basis. However, the encapsulation efficiency proposed herein can always be a parameter for selecting the optimal electroporation conditions.
In addition, aggregation of siRNA is believed to be one of the most common problem in electroporation. It is proven that electroporation can induce strong aggregation of siRNA, making it even harder to enter exosomes. siRNA aggregations are often mistakenly interpreted as encapsulation of siRNA into exosome therefore proper controls were used in this study as the formation of siRNA aggregates is unavoidable during electroporation28. The percentage encapsulation efficiency of our purification method was calculated by using normalized values to minimize the influence from other sources such as background noise, exosome and siRNA aggregations that would affect the data reliability. Based on our findings, there was negligible siRNA aggregations observed in the control sample i.e., using electroporated and un-electroporated siRNA.
This protocol has successfully demonstrated the encapsulation of siRNA into exosomes and their subsequent intracellular delivery of the siRNA to cancer cells in vitro. Therefore, various types of exosomes from different cell lines can be isolated and characterized using the proposed protocol, and subsequently loaded with various therapeutic siRNA for different types of oncogenic targets over-expressed in different cancers. An interesting application would be to explore the siRNA delivery and uptake efficiency using various permutations of exosome source-target cell pair in vitro. This can then be translated to animal models to assess the efficiency of both the delivery and therapeutic efficiency of siRNA-encapsulated exosomes in vivo.
The authors have nothing to disclose.
F. N. Faruqu is funded by the Malaysian government agency Majlis Amanah Rakyat (MARA). L. Xu is a recipient of the Marie Sklodowska-Curie Individual Fellowships (Horizon 2020) (H2020-MSCA-IF-2016). K. T. Al-Jamal acknowledges funding from BBSRC (BB/J008656/1) and Wellcome Trust (WT103913). The authors would also like to thank Dr Paul Lavender and Dr David Fear (Department of Respiratory Medicine and Allergy, King’s College London) for the providing the electroporator.
Material | |||
Sterile Newborn Calf Serum Heat Inactivated | First Link | 08-05-850 | 500 ml |
EMEM medium | Thermo Fisher Scientific | 11090081 | 500 ml |
Penicillin/Streptomycin | Thermo Fisher Scientific | 15140-122 | 100 ml |
GlutaMax | Thermo Fisher Scientific | 35050-038 | 100 ml |
Sucrose | Fisher Scientific | S/8600/60 | 1 kg |
Deuterium oxide (D2O) | Sigma-Aldrich | 151882 | 250 g |
1X Phosphate Buffered Saline | Thermo Fisher Scientific | 10010015 | 500 ml |
Glycine | VWR Chemicals | 101196X | 1 kg |
Sepharose CL-2B | GE Healthcare Life Sciences | 17-0140-01 | 1 L; Particle Size 60 μm-200 μm |
Trypsin-EDTA 0.05% | Thermo Fisher Scientific | 25300096 | 100 ml |
Aldehyde/sulfate latex beads | Thermo Fisher Scientific | A37304 | 4% w/v, 4 µm, 15 ml |
MicroBCA kit | Thermo Fisher Scientific | 23235 | |
CD81 antibody (APC) | Thermo Fisher Scientific | 17-0819-42 | Lot: E15950-104. RRID: AB_11150235. 1:10 dilution in 50 µl sample |
CD81 isotype (APC) | Thermo Fisher Scientific | 17-4714-81 | Lot: 4291563. RRID: AB_763650. 1:10 dilution in 50 µl sample |
CD9 antibody (FITC) | Thermo Fisher Scientific | 11-0098-41 | Lot: 4345870. RRID: AB_10698007. 1:10 dilution in 50 µl sample |
CD9 isotype (FITC) | Thermo Fisher Scientific | 11-4714-41 | Lot: 4299784. RRID: AB_10598647. 1:10 dilution in 50 µl sample |
CD63 antibody (PE) | Thermo Fisher Scientific | 12-0639-41 | Lot: 1930435. RRID: AB_2572564. 1:10 dilution in 50 µl sample |
CD63 isotype (PE) | Thermo Fisher Scientific | 12-4714-81 | Lot: 1937696. RRID: AB_470059. 1:10 dilution in 50 µl sample |
Atto655-siRNA | Eurogentec | SQ-SIRNA | (Labelled-S) UGC-GCU-ACG-AUC-GAC-GAU-G55; (Unlabelled-AS) CAU-CGU-CGA-UCG-UAG-CGC-A55. |
Name | Company | Catalog Number | コメント |
Equipment | |||
Millex-GP Syringe Filter Unit 0.22 µm | Millipore | SLGP033RS | |
CELLine AD1000 bioreactor flasks | Wheaton | WCL1000ad | |
Ultracentrifuge | Beckman Coulter | Optima XPN-80 | |
Swing-out rotor | Beckman Coulter | SW45 Ti | |
Fixed-angle rotor | Beckman Coulter | Type 70 Ti | |
Ultracentrifuge tubes | Beckman Coulter | 355631 | Polycarbonate. Max. fill 32 ml |
Ultracentrifuge bottles | Beckman Coulter | 355618 | Polycarbonate. Min. fill 16 ml, max. fill 25 ml |
NanoSight | Malvern | LM10 | Software: NanoSight NTA v3.2 |
Flow Cytometer | BD Biosciences | FACSCalibur | |
Centrifuge | Eppendorf | 5810R | |
Plate reader | BMG Labtech | FLUOstar Omega | |
Flow cytometry tubes | BD Biosciences, Falcon | 352052 | |
Microfuge tubes | Starlab | S1615-5500 | 1.5 ml |
Cell culture flasks | Fisher Scientific | 156499 | 75 cm2 |
Transmission electron microscope | FEI Electron Optics | Philips CM 12 | with Tungsten filament and a Veleta – 2k × 2k side-mounted TEM CCD Camera (Olympus, Japan) |
Amaxa Nucleofector I | Lonza | Nucleofector I | with Amaxa’s Nucleofector Kits |
24-well flat-bottom plates | Corning | Costar | |
Blunt fill needle | BD Biosciences | 305180 | 18G x 1 1/2" (1.2 mm x 40 mm) |
Glass pipettes | Fisher Scientific | 1156-6963 | |
Name | Company | Catalog Number | コメント |
Reagents | Composition | ||
Normal medium | Eagle's Minimum Essential Medium supplemented with 10% foetal bovine serum (FBS), 1% penicillin/streptomycin and 1% GlutaMax. | ||
Exosome-depleted medium | Eagle's Minimum Essential Medium supplemented with 10% exosome-depleted FBS (see below), 1% penicillin/streptomycin and 1% GlutaMax. | ||
Exosome-depleted FBS | Subject FBS to ultracentrifugation at 100,000 g for 18 h at 4°C. The FBS supernatant post-centrifugation was collected and sterile-filtered using 0.22 µm filters. | ||
25% w/w sucrose cushion | Add 1.9 g (± 0.001 g) of sucrose in a universal tube, and top up with D2O until the weight reaches 7.6 g (± 0.001 g). This makes ~6ml of the 25% w/w sucrose cushion. | ||
3% FBS/PBS | Add 1.5 ml exosome-depleted FBS to 48.5 ml 1X PBS to prepare 50 ml of 3% FBS/PBS. | ||
100 µM BSA solution | Prepare 1mM BSA solution by adding 0.3325 g to 50 ml PBS. Make 1:10 dilution of this stock to obtain 100 µM BSA solution. Make 5-10 µl aliqouts of this 100 µM BSA solution (for single use) and store them at -20°C. All BSA solution should be stored at -20°C, and discard solutions that have undergone ≥2 freeze-thaw cycles. | ||
100 mM glycine solution | Add 0.375 g of glycine to 50 ml PBS to obtain 100 mM glycine solution, store at 4°C. | ||
Citric acid buffer with EDTA | Mix 0.1954 g citric acid and 0.2087 g disodium phosphate in 50 mL of deionised water. Add EDTA to 0.1 mM. Adjust pH to 4.4. | ||
Fixing solution | Prepare formaldehyde/glutaraldehyde, 2.5% (w/v) each in 0.1 M sodium cacodylate buffer, and adjust pH to 7.4. | ||
Aqueous uranyl acetate | Prepare 25% (v/v) uranyl acetate in methanol. | ||
50% methanol/H2O | Mix methanol and H2O 1:1 (v/v). | ||
SEC Column packed with Sepharose CL-2B | Dilute 37.5 ml Sepharose CL-2B resin with 12.5 ml PBS to obtain 75% Sepharose CL-2B solution. Pour the Sepharose CL-2B solution into a column of dimension 2.9 cm [H] x 1.3 cm [W]. Pour the Sepharose CL-2B to 3-4 mm above the stated height, and then press it down to the stated height with the filter for optimal packing. |