...via ultracentrifugation and size exclusion chromatography...
Functional repertoire of EV-associated miRNA profiles after lipoprotein depletion via ultracentrifugation and size exclusion chromatography from autologous blood products | Scientific Reports Functional repertoire of EV-associated miRNA profiles after lipoprotein depletion via ultracentrifugation and size exclusion chromatography from autologous blood products AbstractCartilage breakdown, inflammation and pain are hallmark symptoms of osteoarthritis, and autologous blood products such as citrate-anticoagulated platelet-rich plasma (CPRP) or hyperacute serum (hypACT) have been developed as a regenerative approach to rebuild cartilage, inhibit inflammation and reduce pain. However, mechanisms of action of these blood derivatives are still not fully understood, in part due to the large number of components present in these medical products. In addition, the discovery of extracellular vesicles (EVs) and聽their involvement in intercellular communication mediated by聽cargo molecules like microRNAs (miRNAs) opened up a whole new level of complexity in understanding blood products. In this study we focused on the development of an isolation protocol for EVs from CPRP and hypACT that can also deplete lipoproteins, which are often co-isolated in EV research due to shared physical properties. Several isolation methods were compared in terms of particle yield from CPRP and hypACT. To gain insights into the functional repertoire conveyed via EV-associated miRNAs, we performed functional enrichment analysis and identified NF魏B signaling strongly targeted by CPRP EV miRNAs, whereas hypACT EV miRNAs affect IL6- and TGF尾/SMAD signaling. IntroductionAutologous blood derived products have already been used for more than a decade and increasingly gain popularity in regenerative medicine. A main application is the intra-articular injection into affected joints of osteoarthritis (OA) patients1, besides other treatments of muskuloskeletal conditions such as epicondylitis or rotator cuff injuries2,3. Platelet-rich plasma (PRP) is the most commonly used blood product for these conditions. The term refers to a fraction of whole blood, which is obtained after centrifuging a small amount of whole blood drawn from a peripheral vein in presence of an anti-coagulant such as citrate to obtain citrate-anticoagulated PRP (CPRP). A plethora of commercially devices are available to standardise PRP production4. Upon intra-articular injection, it is hypothesised that platelets are activated via contact with tissue factor and release a variety of growth factors and cytokines that contribute to tissue homeostasis and regeneration5. In contrast, serum-derived blood products have been developed聽including聽autologous conditioned serum (ACS) or hyperacute serum (hypACT). These fractions are obtained after extracorporeal coagulation of a small volume of fresh whole blood and squeezing out the soluble fraction of the fibrin clot. As for PRP, a variety of preparation devices exist that assist and standardise the production procedure. The rationale behind serum-derived blood products is to increase the concentration of natural anti-inflammatory molecules such as IL-1 receptor antagonist (IL1ra) released into whole blood after activation of blood coagulation6,7,8. Traditionally, research on the mechanisms of action of blood products has focused on growth factor and cytokine contents9,10,11.Nevertheless, the discovery of extracellular vesicles (EVs) as novel components present in blood products and their recognition as relevant signaling players in tissue homeostasis12 have increased the level of complexity in understanding the effects of blood product therapies. EVs are a heterogeneous group of cell-derived membrane particles with a size of around 50 up to 2000聽nm. They are classified by their biosynthetic origin whether they are intralumenal exosomes shed from multivesicular bodies, plasma membrane buds termed microvesicles released from the cell surface or apoptotic bodies derived from dying cells12. The approximate sizes of these particle types vary and size ranges overlap, thereby usually reducing the reasonableness of particle size as a specific analytic parameter. Once an EV has been generated it is almost impossible to determine its type as there are no molecular markers that uniquely identify a given EV subtype13. However, plasma membrane derived particles expose phosphatidylserine14 whereas higher amounts of tetraspanins such as Alix, CD9, or CD63 tend to be found in EVs originating from the cell interior15.There is mounting evidence that EVs are the basis of regeneration in terms of cartilage recovery as shown for mesenchymal stem/stromal cell (MSC) based therapies of OA in vitro and in vivo16,17,18. 聽In these studies it was observed that beneficial effects were mediated by the secretome of MSCs, in particular EVs, rather than by cell-based mechanisms. EVs bring along a variety of signaling molecules such as miRNAs that might have a disease modifying effect in OA. However, as current research focuses mainly聽on MSC-derived EVs little is known about EV populations in blood products regarding chondroregenerative potentials. Although blood products pose a more direct approach of obtaining and applying autologous EVs while circumventing practical hurdles associated with cell-based therapeutics such as uncontrolled cell growth or graft rejection, besides regulatory hurdles19.So far, a range of EV isolation techniques have been developed which employ either size- or density-based separation principles. Currently, the gold standard method is differential ultracentrifugation (UC)20,21, which enriches particles according to density. Limitations are the reported co-enrichment of lipoproteins and aggregates of soluble proteins that overlap in density with EVs22,23. To avoid aggregate formation and to enable gentle isolation of EVs, size exclusion chromatography (SEC) has been used to enrich EVs24,25,26,27,28, but it was observed that specific classes of lipoproteins with similar size as EVs were still present in the SEC fractions29. SEC dilutes particles, therefore concentrating steps have to be performed afterwards. This might employ UC or ultrafiltration (UF), a density- or again size-based method, respectively. However, performing two consecutive size-based methods in tandem like SEC for EV enrichment and UF for concentrating would prevent the depletion of lipoproteins co-isolated via SEC. UC depletes large lipoproteins with low buoyant density, but might co-pellet small dense lipoproteins. On the other hand, SEC could remove these small dense lipoproteins together with remaining soluble proteins, after large lipoproteins have been removed in a first step via UC (Fig.聽1A). Therefore, we hypothesised that a combination of UC and SEC in tandem might provide a procedure to obtain highly pure EVs from plasma and serum without lipoprotein or soluble protein contamination. Furthermore, we aimed to outline the EV-associated miRNA species and their functional repertoire enriched in EV preparations from CPRP and hypACT to characterise expected functional associations, which might qualify isolated EVs suitable for cartilage regeneration and might explain disease modifying effects mediated by blood products in OA.Figure 1(A) Rationale behind using density- and size-based EV isolation techniques in tandem to deplete non-EV particles from plasma or serum (modified after21). (B) Overview of isolation procedures investigated in this study. Black dots indicate that the preparative step (grey row labels) or analytic step (white row labels) was a task in the procedure.Full size imageMethodsPreparation of blood products CPRP and hypACTBlood products were prepared from human voluntary whole blood donations freshly drawn in house by approved personnel. We obtained informed consent from the donors and approval from the Ethics Committee of the Danube University Krems (ESC1020/2020). All experiments were performed in accordance with relevant guidelines and regulations.聽Eligibility criteria were age between 25 and 45聽years, healthy at the time of donation according to a self-evaluation form asking for conditions such as diabetes, underweight or pregnancy as exclusion criteria. Donors were randomly selected from a pool of 4 female and 3 male donors. Blood was collected into citrate coated collection tubes (VACUETTE 9NC trisodiumcitrate 3.2%, Greiner BioOne, #455322) for preparing citrate-anticoagulated platelet-rich plasma (CPRP) or was drawn via the hypACT inject device developed by OrthoSera (Krems, Austria) to produce hyperacute serum (hypACT). Blood products were prepared as previously described30. In brief, CPRP was obtained聽from whole blood via a first round of centrifugation at 440鈥壝椻€?i>g at room temperature (rt) for 10聽min to pellet blood cells, transfer of the top fraction containing platelets and聽spinning this again at 1710鈥壝椻€?i>g for 10聽min at rt. Two-thirds of the supernatant were then discarded and the platelet pellet was resuspended in the remaining plasma. Preparation of hypACT involved a single round of centrifugation at 1710鈥壝椻€?i>g for 10聽min at rt. Afterwards, serum was squeezed from the fibrin clot that聽was formed in the device in the meantime. Blood products were processed immediately. CPRP and hypACT were prepared from the same聽donor in parallel for each isolation procedure. Due to limited sample volume per donation, blood products could not be used to perform different isolation procedures from the same blood product preparation.EV enrichment proceduresFreshly prepared blood products were pre-cleared from residual cells and cell debris via centrifugation at 2500鈥壝椻€?i>g for 15聽min at rt in 15聽ml polypropylene tubes. The supernatant (S2 fraction) was used for subsequent enrichment procedures as outlined in Fig.聽1B. Ultracentrifugation steps were conducted at 100,000鈥壝椻€?i>g for 120聽min at 4聽掳C in a MLA-80 fixed angle rotor (k-factor 29; 45,000聽rpm). SEC-based separation was performed via pre-packed sepharose columns (iZON, qEVoriginal). PBS was sterile filtered prior to use (Sartorius, #16534) and was devoid of Ca2+ and Mg2+.EV enrichment via ultracentrifugation (UC)S2 fraction (2.5聽ml) was transfered into polycarbonate ultracentrifugation tubes (Beckman-Coulter, #355647) and PBS was added to a final volume of 5聽ml. Following balancing with PBS and ultracentrifugation, the EV pellet was resuspended in 200聽碌l PBS by gentle pipetting (P100 fraction). For western blotting, aliquots were taken directly after ultracentrifugation of the floating fat layer (fat fraction) and the cleared supernatant (S100 fraction). Samples were stored at 鈭掆€?0聽掳C until further analysis.EV enrichment via size-exclusion chromatography and pooling via UC (SEC鈥?鈥塙C)After equilibrating the column with 10聽ml PBS, aliquots of 500聽碌l of S2 fraction were loaded onto a SEC column. Columns were eluted with PBS. Collection of 1聽ml fractions was started immediately after adding 14聽ml elution buffer. After collecting 20 fractions, the column was washed with 1 bed volume (10聽ml) PBS and stored at 4聽掳C. Fractions were stored at 4聽掳C for further analysis on the same day or frozen at 鈭掆€?0聽掳C and quickly thawed at 37聽掳C in a water bath. After performing nanoparticle tracking analysis (NTA) as described below to determine particle-rich fractions, corresponding fractions were pooled into polycarbonate ultracentrifugation tubes (Beckman-Coulter, #355647) and PBS was added to a final volume of 5聽ml. After ultracentrifugation of pooled fractions 3鈥?, the EV pellet was resuspended in 200聽碌l PBS. Isolates were stored at 鈭掆€?0聽掳C until further analysis.EV enrichment via UC and SEC in tandem and pooling via UC (UC鈥?鈥塖EC鈥?鈥塙C)EVs were enriched from 2.5聽ml S2 fraction as described above. The pellets were resuspended in 500聽碌l PBS before loading onto a SEC column and separating EVs from residual soluble proteins as outlined before. Afterwards, particle concentration was assessed in SEC fractions. Following pooling of fractions 3鈥?, particles were pelleted via ultracentrifugation and resuspended in 200聽碌l PBS by gentle pipetting.EV enrichment via SEC and pooling via ultrafiltration (SEC鈥?鈥塙F)S2 fraction (500聽碌l) was separated via SEC as described above. The SEC fractions 3 to 5 (1聽ml each) were pooled and ultrafiltrated at 10,000鈥壝椻€?i>g and rt via a Vivaspin PES 100 kD cutoff filter (Sartorius, #VS0141). Particles were resuspended in 200聽碌l PBS by gentle pipetting and stored at 鈭掆€?0聽掳C.Nanoparticle tracking analysis (NTA)Sizes and concentrations of particles in EV isolates or SEC fractions were determined via NTA using the particle analyzer ZetaView from Particlemetrix in scatter mode. The measurement procedure was done as previously described31,32. In brief, samples were diluted as required 1:20鈥?:1000 with PBS. Pre-acquisition camera settings were kept constant at sensitivity 80 and shutter 100. Videos were aquired at 11 positions each with 30 frames per second in one aquisition cycle. Video analysis was done with ZetaView 8.04.02 software using a minimum and maximum particle area of 5 and 1000, respectively. Mode size of particle size distributions was determined after smoothing of measured size profiles using a custom PHP-based implementation of the Savitzky-Golay algorithm as given in Supplementary Data 133.Assessment of protein concentrationTotal protein was determined via BioRad DC assay in a microplate format. 10聽碌l of undiluted or diluted sample as required were used. Samples were lysed with 10聽碌l RIPA buffer without protease inhibitors (Thermo Scientific, #89900) for 10聽min at 4聽掳C to release EV protein content prior to performing the assay. A linear standard curve was generated from a serial dilution of bovine serum albumin (BSA) (Sigma-Aldrich, #A8022) ranging from 0 to聽2聽mg/ml.Western blotEV suspensions (10聽碌g total protein) were mixed with 4鈥壝椻€塋DS loading buffer (ThermoFisher, #NP0007) in presence (for Alix and ApoB100/48) or absence (for CD9, CD63 and ApoA1) of 100聽mM dithiothreitol (DTT) and boiled at 95聽掳C for 10聽min before loading onto pre-cast 10% or 4鈥?2% gradient SDS-PAGE Tris-Bis gels (Invitrogen, # NP0301 and #NP0322). Proteins were blotted onto PVDF membranes (Invitrogen, #IB401002) under semi-dry conditions using an iBlot gel transfer device (Invitrogen, USA) for 26聽min at 20聽V. Successful transfer was checked by Ponceau S staining before destaining the membrane with deionised water and blocking in 5% non-fat dry milk in PBST (PBS鈥?鈥?.1% Tween-20) for 1聽h or overnight shaking at rt on an orbital shaker (15聽rpm). After washing 3 times with PBST for 5聽min at rt, membranes were incubated with primary antibodies diluted 1:1000 in 1% BSA/PBST against ApoA1 (Santa Cruz, #sc-376818), ApoB100/48 (Santa Cruz, #sc-393636), Alix (Cell Signaling, #2171), CD63 (BioLegend, #353005, clone H5C9) and CD9 (SystemBiosciences, #EXOAB-CD9A-1) for 1聽h, followed by incubation with HRP-conjugated secondary antibodies (BioRad, #L9704446 and # L9704447) for 1聽h. Proteins were detected via enhanced chemiluminscence (ECL) using WesternBright ECL substrate (Advansta, #K-12045-D20) and a ChemiDoc Reader (BioRad) equipped with PDQuest 7.4 software. Blot images were automatically uniformly white-corrected using the GIMP 2.8.22.RNA isolation and RT-qPCRCPRP and hypACT were prepared as described above. Anonymised blood donor characteristics and isolated particle counts from 3 donors are given in Table 1. RT-qPCR based microRNA screening was performed by TAmiRNA GmbH (Vienna, Austria). Total RNA was extracted from blood products (CPRP or hypACT) as well as from EVs isolated via UC鈥?鈥塖EC鈥?鈥塙C, respectively, using the miRNeasy Mini Kit (Qiagen, #217004). Blood products and suspended EVs were transported frozen , thawed on ice and centrifuged at 12,000鈥壝椻€?i>g for 5聽min to remove cellular debris from blood products before RNA isolation. Each sample (200聽碌l) was mixed with 1000聽碌l Qiazol and 1聽碌l of a mix of 3 synthetic 22 nt long spike-in controls UniSp2, UniSp4 and UniSp5 (Qiagen, #339390) to monitor variability of RNA yield. After a 10聽min incubation at rt, 200聽碌l chloroform were added to the lysates followed by centrifugation at 12,000鈥壝椻€?i>g for 15聽min at 4聽掳C. Precisely 650聽碌l of the aqueous phase were mixed with 7 碌L glycogen (50聽mg/ml) to enhance precipitation. Samples were transferred to a miRNeasy mini column, and RNA was precipitated with 750聽碌l ethanol followed by automated washing with RPE and RWT buffer in a QiaCube liquid handling robot. Finally, total RNA was eluted in 30 碌L nuclease free water and stored at 鈭掆€?0聽掳C until further analysis. cDNA was synthesized using the miRCURY RT kit (Qiagen, #339340). Reaction conditions were set according to recommendations by the manufacturer suggesting 42聽掳C reverse transcription for 60聽min, followed by 5聽min at 95聽掳C for inactivation. In total, 18聽碌l of total RNA were used per 90聽碌l reverse transcription (RT) reaction. To monitor RT efficiency and presence of impurities with inhibitory activity, 4.5聽碌l of a synthetic 22 nt long RNA spike-in (cel-miR-39-3p, 0.002 fmol/碌l) was included in the RT reaction. PCR amplification was performed in a 384-well plate format using a Roche LC480 II instrument and miRCURY SYBR Green mastermix (Qiagen, #339347). The Human miRNome Panel I was employed for screening miRNA expression (Qiagen, #339322). Each well contained a dried-down primer set specific for the individual reation. 4 spike-in control assays (UniSp2, UniSp4, UniSp5, cel-miR-39-3p), 3 interplate calibrators (IPC), 3 reference assays (U6snRNA, SNORD38B, SNORD49A) and blanks. In total, 12 plates were measured (isolated EVs and native blood product from CPRP and hypACT from 3 donors). cDNA was diluted 1:100 in 10聽碌l PCR reaction volume. Plates were incubated at 4聽掳C for 1聽h prior to PCR amplification, using the following settings: 95聽掳C for 2聽min, 45 cycles of 95聽掳C for 10聽s and 60聽掳C for 60聽s, followed by melting curve analysis. To calculate the cycle of quantification values (Cq-values), the second derivative method was used.Table 1 Donor characteristics and sample details used for miRNA profile characterisation.Full size tableProfiling of miRNA expressionAnalysis of PCR data was started by applying a Cq cutoff of 35 to select relevant hits. A miRNA was regarded as detected if it occurred in at least 2 out of 3 biological replicates per sample group. Next, the most stably expressed miRNA across sample groups was determined via NormFinder34 to use it as endogenous internal reference to normalise miRNA expression levels. The use of spike-in controls and/or the particle number for normalisation was dismissed as these parameters do not account for differences in RNA content between samples inherent to the biological materials. Cq values were then normalised to the Cq value of endogenous let-7a-5p in a given sample to obtain 螖Cq values, which were ranked to perform rank analysis via Spearman rank correlation test. For quantitative assessment of miRNA enrichment or depletion in purified EVs, the fold change from 螖螖Cq between EVs and blood product was calculated for each blood product. A 螖螖Cq threshold of 1 or 鈭掆€? had to be exceeded to be considered a relevant change in expression. The significance of calculated fold changes was determined via multiple t-test while allowing a false discovery rate (FDR)鈥?lt;鈥?.05. Contamination due to hemolysis was assessed in all samples using the ratio of miR-23a-3p versus miR-451a35. Cq values of individual miRNAs were backcalculated to copy numbers relative to the average Cq (24,929) of cel-miR-39-3p of approximately 6.02鈥?鈥?06 spiked-in molecules corresponding to 0.001 amol/碌l in 10聽碌l PCR reaction volume via the formula 6.02鈥?鈥?06鈥?鈥?鈭?Cq-24.929) multiplied by a combined dilution factor of 166.6 (1.666-fold dilution of total RNA in RT mix and 100-fold dilution of cDNA in PCR reaction).Pathway analysisStrong evidence gene targets for all miRNAs in EVs from CPRP or hypACT were obtained from mirTarbase 7.0 by selecting only targets verified by Western Blot, quantitative PCR or reporter assay from a database snapshot via the given SELECT statement: SELECT miRTarBase.[Target Gene] FROM miRTarBase WHERE (LOWER(miRTarBase.Experiments) LIKE 鈥?reporter assay*鈥? Or LOWER(miRTarBase. Experiments) LIKE 鈥?western Blot*鈥?Or LOWER(miRTarBase.Experiments) LIKE 鈥?qpcr*鈥? AND miRNA IN ( miRNA list ) GROUP BY miRTarBase.[Target Gene], where miRNA list is a placeholder for the respective miRNA query set. Targets were selected for all miRNAs identified in EVs from CPRP or hypACT, and enriched miRNAs in EVs, respectively. Next, STRING software v11 (https://string-db.org/) was used to identify enriched Gene Ontology (GO) Biological Processes terms and Reactome pathways among the proteins targeted by the miRNA sets36,37,38. Only GO and Reactome terms with highest confidence (鈮モ€?.9) were further investigated. To focus on highly relevant pathways, even more stringent selection criteria were applied by including only pathways having a confidence of at least 90% of the maximum confidence indicator found per group.Statistical analysisUnless otherwise stated, data were tested with paired t-test using GraphPad version 8 to determine statistical significance which was accepted for p鈥?lt;鈥?.05. Two-way ANOVA and Sidak鈥檚 post hoc test were applied on NTA data, while RT-qPCR data were tested with multiple unpaired t-test accepting a false discovery rate (FDR) of 5% (q鈥?lt;鈥?.05). Discoveries were determined using the two-stage linear step-up procedure of Benjamini et al.39.ResultsCapacity of EV isolation methods for lipoprotein depletionAs EVs overlap in size and/or density with other particles such as lipoproteins present in blood and blood products, developing an isolation procedure that combines size- and density-based separation techniques could enable obtaining highly pure EV preparations (Fig.聽1A). This is necessary to study effects mediated by EVs and mechanisms of action of EVs in blood products without confounding influences from other factors including lipoproteins and soluble proteins in plasma and serum. Several combinations of SEC and UC as given in Fig.聽1B were evaluated in terms of particle yield and mode size via NTA.Initial experiments comparing size profiles of CPRP or hypACT pre-cleared blood product (S2 fraction) revealed a dramatic difference in the total particle concentrations present in the input material before UC and the UC pellet (Fig.聽2A). Next, particle concentrations of the same input material were determined after SEC and UC鈥?鈥塖EC (Fig.聽2A diagram 2). The huge particle concentrations in SEC fractions compared to UC鈥?鈥塖EC fractions might indicate a tremendous amount of contaminating particles in SEC fractions, which could be lipoproteins based on the hypothesis that a prior UC step depletes these particles in the buoyant fat layer (Fig.聽2C). The eluent (PBS) was essentially particle-free (Fig.聽2A, diagram 3). The fourth diagram in Fig.聽2A presents a representative result of data smoothing (red line) as described in the Methods section. The smoothing was used to denoise size distributions and to obtain a read out of mode size rather than average or median sizes, which tend to be higher than mode due to skewness of the particle size distribution. Figure聽2B summarises particle concentrations found via different isolation methods, normalised to ml of input material. While input, SEC and SEC鈥?鈥塙F (still) contained substantial amounts of lipoproteins, method combinations involving UC depleted more than 90% of particles each, compared to input. Determined particle concentrations were significantly different between isolation methods as assessed via one-way ANOVA and Dunett鈥檚 post-hoc test for CPRP (F(6, 29)鈥?鈥?6.29; p鈥?lt;鈥?.0001) and hypACT (F (6, 30)鈥?鈥?42.8; p鈥?lt;鈥?.0001). However, concentration differences between blood products for a given method were not significant, except for UC鈥?鈥塖EC鈥?鈥塙C (p鈥?lt;鈥?.001). Interestingly, mode sizes of smoothed particle size distributions revealed significant increases in mode size of particles obtained after methods involving UC compared to input as determined via one-way ANOVA and Dunnett鈥檚 post hoc test for CPRP (F (6, 29)鈥?鈥?.725; p鈥?鈥?.0002) and hypACT (F (6, 30)鈥?鈥?.345; p鈥?鈥?.0121) (Fig.聽2A). In CPRP, UC (p鈥?鈥?.019), SEC鈥?鈥塙C (p鈥?鈥?.007) and UC鈥?鈥塖EC (p鈥?lt;鈥?.0001) were significantly different, respectively. This pattern was essentially recapitulated in hypACT for UC (p鈥?鈥?.048), SEC鈥?鈥塙C (p鈥?鈥?.057), UC鈥?鈥塖EC (p鈥?鈥?.031) and UC鈥?鈥塖EC鈥?鈥塙C (p鈥?鈥?.019), although with lower statistical significances. A buoyant layer, termed fat layer, contained the majority of particles after UC (Fig.聽2C). Only 1鈥?% of all particles in blood products were found in UC pellets (P100). As UC was considered to deplete lipoproteins from input, which can be smaller than EVs (Fig.聽1A), and a UC pellet contains enriched EVs, the mode size increased in EV preparations when the majority of non-EV particles was depleted which would cover up the true mode size of an EV size distribution as in input, SEC and SEC鈥?鈥塙F. For any isolation method, mode sizes of particles were not significantly different between blood products (Fig.聽2B). The protein concentration of EV preparation decreased with increasing number of isolation methods performed in tandem. The UC pellets contained 0.71鈥壜扁€?.06(SD) mg/ml or 0.69鈥壜扁€?.03(SD) mg/ml protein normalised to the respective input materials CPRP S2 (79.72鈥壜扁€?.88(SD) mg/ml) and hypACT S2 (86.56鈥壜扁€?.46(SD) mg/ml), respectively. After pooling SEC fractions via UC (SEC鈥?鈥塙C), pellets contained 0.19鈥壜扁€?.07 (SD) mg/ml or 0.04鈥壜扁€?.01(SD) mg/ml protein, while UC鈥?鈥塖EC鈥?鈥塙C pellets yielded 0.07鈥壜扁€?.02(SD) mg/ml or 0.03鈥壜扁€?.01(SD) mg/ml protein for CPRP or hypACT, respectively. Each protein concentration represents the amount of protein that was isolated via the respective method per ml of input material (Fig.聽2D).Figure 2Particle concentration, mode sizes and protein concentrations of isolated EVs from CPRP and hypACT. (A) (1), representative size profiles of S2 and P100 fractions; (2), particle concentrations in SEC fractions with or without prior UC; (3), size profile of PBS control and (4), representative result of smoothing the raw size distribution via the Savitzky-Golay approach as described and comparison of mode, median and average particle size of a particle population as determined via NTA. (B) Particle concentrations and mode sizes in input and after indicated EV preparation procedures. Data from at least three biological replicates are given鈥壜扁€塖D. (C) Evaluation of particle content after UC of S2 fraction in fat layer, S100 and P100 fractions, adapted from21. Data from three biological replicates are given as mean percentages of sum of particles in all fractions. (D) Protein concentration in input material and EV preparations obtained via the indicated procedures, normalised to input volume. Data from at least three biological replicates are given鈥壜扁€塖D.*p鈥?lt;鈥?.05, **p鈥?lt;鈥?.01, ***p鈥?lt;鈥?.001, ****p鈥?lt;鈥?.0001.Full size imageProtein marker profilingAs NTA in scatter mode is limited to detect particles without further characterisation, Western Blot analysis of EV preparations via different isolation methods was performed to monitor the recovery of EV markers Alix, CD9 and CD63, as well as the depletion of lipoproteins Apolipoprotein A1 (ApoA1) and Apolipoprotein B100 and its truncated variant B48 (ApoB100/48) found in high density lipoproteins (HDL) and (very) low density lipoproteins ((V)LDL) particles, respectively. As shown in Fig.聽3A, ApoA1 was depleted below detection limit from CPRP and hypACT EVs via UC鈥?鈥塖EC鈥?鈥塙C, while the first UC pellet (P100) as well as SEC鈥?鈥塙C co-pelleted ApoA1. Similarly, ApoB100/48 was depleted via combined density- and size-based isolation. As expected, SEC鈥?鈥塙F yielded preparations with concentrated ApoB100/48, which is co-isolated via SEC. Nevertheless, also ApoA1 was enriched via SEC鈥?鈥塙F. Unexpectedly, while UC pellets (P100) contained substantial amounts of Alix and dimeric CD9 (around 50聽kDa), SEC鈥?鈥塙C and UC鈥?鈥塖EC鈥?鈥塙C caused a dramatic or complete loss of signal, although same protein concentrations were loaded into each lane. When loading eightfold protein amount, monomeric CD9 (predicted molecular weight 25.42聽kDa, Uniprot-ID P21926) was detected in UC鈥?鈥塖EC鈥?鈥塙C EVs for CPRP, but still absent for hypACT EVs. In addition, the membrane was probed for another EV marker, CD63, and a weak signal was detectable for hypACT EVs (Fig.聽3B). Reduced samples were probed for Alix as well, however, Alix was neither detected in CPRP or hypACT EVs (data not shown). Nevertheless, this shows that there is no complete loss of EV marker proteins via UC鈥?鈥塖EC鈥?鈥塙C. Ponceau S stained membranes showed very faint, but visible, protein bands for UC鈥?鈥塖EC鈥?鈥塙C EVs, however, the majority of bands might be below the detection limit of Ponceau S stain, especially for hypACT (Fig.聽3A).Figure 3Western Blot of lipoprotein (ApoA1, ApoB100/48) and EV markers (Alix, CD9, CD63). (A) 10聽碌g protein was loaded per lane (except for PL, 20聽碌g) and membrane Ponceau S stained after transfer is shown. (B) Detection of CD63 and CD9 (80聽碌g per lane, except for 20聽碌g for PL) in UC鈥?鈥塖EC鈥?鈥塙C pellets. (C) UC鈥?鈥塖EC鈥?鈥塙C pellets obtained after removing supernatant. PL: platelet lysate, S2: plasma or serum supernatant after 2500鈥壝椻€?i>g centrifugation, S100: supernatant after 100,000鈥壝椻€?i>g centrifugation, P100:.pellet after 100,000鈥壝椻€?i>
g centrifugation, fat: buoyant layer after ultracentrifugation, a: marker (Invitrogen, #LC5800), b: marker (Invitrogen, #LC5699). Full-length blots/gels are presented in Supplementary Data 2.Full size imageBlood product-derived purified EVs have disctinct miRNA profilesTo determine EV miRNA cargo profiles in CPRP and hypACT, full blood product and purified EV preparations from 3 donors each were screened for a panel of 372 miRNAs via a reverse transcriptase quantitative PCR (RT-qPCR)-based assay in 384-well microplate format. Sample details are given in Table 1, the full miRNA panel is given in Table S1. The data analysis flow chart is shown in Fig.聽4A. The efficiency of RNA isolation, reverse transcription and PCR showed low variability across samples (Fig. S1). Relevant data on EV isolation for miRNA assessment was deposited in the EVTRACK database, accession number EV190086. In total, 274 or 252 distinct miRNAs were detected in CPRP or hypACT blood products, respectively, whereas 156 or 49 miRNAs were found in purified EVs from CPRP or hypACT. The Venn diagrams (Fig.聽4B) show an overview of the numbers of miRNAs found in blood products and EVs from CPRP and hypACT, while outlining the number of shared miRNAs between sample groups. The qualitative assessment revealed 26 miRNAs specific to CPRP and 4 miRNAs specific to hypACT when comparing blood products. The 26 CPRP blood product miRNAs were not found in CPRP EVs, neither 3 out of 4 miRNAs from hypACT blood product in EVs, except for miR-373-3p (Fig.聽4B). CPRP and hypACT blood products shared 248 out of 272 miRNAs (91.2%), whereas the EV preparations had 48 out of 157 miRNAs in common (30.6%). The detection rates of miRNAs per sample were determined as the number of detected miRNAs (Cp鈥?lt;鈥?5) in proportion to the whole 372 miRNA test panel (Fig. S1C). According to one-way ANOVA and Tukey鈥檚 post hoc test (F(3,8)鈥?鈥?48.7; p鈥?lt;鈥?.0001) they were significantly lower in EVs purified from hypACT or CPRP compared to the respective native blood product (q鈥?鈥?3.39 or 13.95, respectively). In addition, there were significantly more miRNAs detected in CPRP than in聽hypACT EVs (q鈥?鈥?3.39). Interestingly, similar amounts of miRNA species were found in both blood products (q鈥?鈥?.952). Screening the raw Cq values for miRNA expression levels via NormFinder34 identified miRNA let-7a-5p as most stably expressed miRNA with stability value of 0.194. In the following, the Cq values were normalised to let-7a-5p in each sample to obtain 螖Cq values. Average 螖Cq values were assigned ranks to perform rank analysis of relative abundance changes between blood product and purified EVs in CPRP or hypACT (Fig.聽4C). A higher rank indicates a higher relative abundance. Generally, the rank correlation observed for relative miRNA abundances in CPRP and hypACT resulted in Spearman correlation coefficients of 0.9589 (0.9435鈥?.9702 95% CI) and 0.3879 (0.1113鈥?.6087 95% CI), respectively (Fig.聽4C). Linear regression analysis quantified the goodness of fit with R2鈥?鈥?.9201 in contrast to R2鈥?鈥?.1495 for CPRP and hypACT, respectively (Fig.聽4C).Figure 4miRNA profiling. (A) RT-qPCR data analysis workflow. (B) Qualitative assessment of number of miRNA species identified in blood products and purified EVs. (C) Rank analysis of relative abundance of identified miRNAs in blood products and EVs for CPRP and hypACT, 156 and 49 miRNA species, respectively. Higher rank represents higher relative abundance. Spearman rank correlation resulted in r鈥?鈥?.9592 (0.9439鈥?.9704 95% CI) for CPRP and r鈥?鈥?.3879 (0.1113鈥?.6087 95% CI) for hypACT with p鈥?lt;鈥?.001 and p鈥?鈥?.006, respectively. (D) Quantitative assessment of miRNA fold changes normalised to let-7a. Dotted black lines indicate relevance thresholds (twofold enrichment or 0.5-fold depletion). (E) Volcano plot of significantly enriched miRNAs. Black dotted line indicates significance threshold, orange dashed lines are relevance thresholds. Statistical significance (D,E) was assessed via multiple t-test accepting a false discovery rate of 5% (q鈥?lt;鈥?.05). Black dotted line indicates significance threshold, orange dashed lines are relevance thresholds. **p鈥?lt;鈥?.01, ***p鈥?lt;鈥?.001, ****p鈥?lt;鈥?.00001.Full size imageQuantitative enrichment analysis via calculating the fold change of miRNA abundances in purified EVs compared to blood products identified miR-214-3p as most enriched in CPRP EVs followed by miR-10b-5p, miR-874-3p and miR-484, whereas the amount of miR-373-3p increased strongest in hypACT EVs followed by miR-23b-3p, miR-199a-3p, miR-23a-3p, miR-221-3p, miR-223-3p, miR-342-3p, miR-27a-3p, miR-24-3p, miR-423-3p, miR-30c-5p, miR-126-3p, miR-142-3p, miR-21-5p and miR-142-5p (Fig.聽4D). The significances of enriched miRNAs are highlighted in a volcano plot (Fig.聽4E).To visualise clusters of enriched or depleted miRNAs in all samples of all 3 donors, a heat map of miRNAs present in EVs from CPRP or hypACT or blood product was constructed (Fig S2). Clusters of miRNAs appear which were overrepresented in EVs from CPRP (cluster 1 and 2, miR-122-5p, miR-125b-5p, miR-214-3p, miR-10b-5p, miR-652-3p and miR-874, miR-840, miR-99a) and hypACT (cluster 3 and 4, miR-30b-5p, miR-150-5p, miR-342-3p, miR-30c-5p, miR-373-3p and miR-126-3p, miR-27a-3p, miR-24-3p, miR-223-3p, miR-23a-3p, miR23-b-3p). Interestingly, a large cluster (cluster 5) was evident in hypACT blood product including miRNAs miR-451a, miR-16 and miR-92 indicating contamination with erythrocytes40. Therefore, all samples were tested for hemolysis by calculating a 螖Cp of miR-23a-3p and miR-451a as hemolysis indicator as reported elsewhere35. Values are given in Table 1. A 螖Cp of 5 or more is indicative of erythrocyte miRNA contamination. An average 螖Cp of 10.13鈥壜扁€?.17 (SD) was determined in hypACT blood product indicating strong hemolysis in these samples. In contrast, the hemolysis indicator stayed below 5 and took values of 2.13鈥壜扁€?.31 (SD), -0.01鈥壜扁€?.91 (SD) and 0.35鈥壜扁€?.37 (SD) for hypACT EVs, CPRP blood product and CPRP EVs, respectively. This underlines the absence of erythrocyte miRNAs in EV samples, which is an indicator of the absence of miRNAs potentially released from the cytoplasm of residual blood cells present in blood products upon freezing samples for transport. This is also presented on the heat map (Fig S2, cluster 5).To determine how many miRNA sequences were found per particle, the copy numbers of individual miRNAs were estimated relative to spiked-in cel-miR-39-3p as described above. Then, copy numbers of all identified miRNAs in a given EV preparation were summed up and divided by the number of particles detected in the sample. Data are given in Table 1. For CPRP EVs, 5.69%鈥壜扁€?.74% (SD) of all particles contained on average 1 miRNA molecule. This result implicates that probably a part of this proportion might contain zero miRNAs while others carry 2 or more miRNA molecules of any identified miRNA species or combination of miRNA species. On the other hand, the miRNA-bearing EV proportion in hypACT EVs amounted to 0.26%鈥壜扁€?.01% (SD). That means that 1 out of 24 CPRP EVs鈥壜扁€?6 (SD) carried any one miRNA, while any one miRNA was present in 1 out of 379 hypACT EVs鈥壜扁€? (SD).Functional repertoire of miRNA populations in UC鈥?鈥塖EC鈥?鈥塙C purified EVsQuerying miRTarBase v7 with all miRNAs identified in EVs from CPRP or hypACT for experimentally validated target genes resulted in 2033 or 1042 verified targets, respectively. The 4 and 14 miRNAs significantly enriched in CPRP or hypACT EVs (Fig.聽4C,D) were found to target 88 and 548 verified targets.Pathway analysis via STRING found 640 reactome pathways and 3731 GO biological processes with FDR鈥?lt;鈥?.05 targeted by all CPRP EV miRNAs. Among those, 13 GO biological processes and 10 Reactome pathways were of highest confidence ( 鈥?.9) and with an FDR鈥?lt;鈥?.001. Pathway analysis for all hypACT EV miRNAs resulted in 597 reactome pathways and 3722 GO biological processes with FDR鈥?lt;鈥?.05. Interestingly, 262 GO biological processes and 107 Reactome pathways remained after applying highest confidence and FDR鈥?lt;鈥?.001 filter constraints on the data set. Although hypACT EVs contained only around 30% of miRNA species compared to CPRP EVs, more than tenfold as much significant pathways and processes are targeted by hypACT EV miRNAs. Full list of highest confidence GO terms and Reactome pathways are given in Table S2. Targets returned by miRTarBase, but not considered for STRING analysis, are PDK1, PDK2, CACNA1C, ZNF763, PLAC8, SLC11A2, TAC1, XIST, WDR4, TFAM, UCP2, TSPYL2, TTN, TBR1, ARTN, BASP1. These were manually excluded from the query list, based on their associated functions not directly related with or not being specific to cartilage, to meet the input limit for STRING of 2000 protein identifiers.Visualising 60 and 336 unique targets from the identified significant pathways in CPRP and hypACT EV miRNAs in gene clusters via STRING to outline shared nodes was hampered by their large number for hypACT in particular. Therefore, more stringent selection criteria were applied. A Reactome term had to reach a confidence of at least 90% of the maximum strength indicator of all terms with FDR鈥?lt;鈥?.001, resulting in a minimum strength of 0.891 or 1.161 for CPRP and hypACT, respectively. This yielded 9 Reactome terms and 13 GO biological processes for CPRP, while 14 Reactome terms and 11 GO biological processes were obtained for hypACT as given in Table S3. The GO enrichment resulted in biological processes related with regulation of apoptosis for CPRP EVs, while mainly cell-fate and differentiation related processes were found among targets of hypACT EV miRNAs. For the genes involved in Reactome pathways, STRING networks were generated from 55 and 47 Reactome gene targets for CPRP and hypACT EV miRNAs, respectively (Fig.聽5A,B). Clusters involving HRAS/NRAS/KRAS were common to EV miRNAs from CPRP and hypACT as well as a cluster including insulin- and JAK/STAT-driven signaling (Fig.聽5A,B, clusters 1 and 2). Clusters specific to CPRP EV miRNAs regulate NF魏B and Notch/Delta signaling, while hypACT EV miRNAs target TGF尾/SMAD and IL6 signaling as well as cell cycle regulation.Figure 5Physical STRING networks of miRNA targets in high confidence Reactome pathways for CPRP and hypACT EVs. Clusters 1 and 2 are found among miRNA targets for EVs from either blood product. (A) NF魏B and Notch signaling are specifically targeted by CPRP EVs, while (B) TGF尾/SMAD signaling, IL6 signaling and cell cycle regulation are high confidence targets of hypACT EVs. Line thickness represents鈥?gt;鈥?.9 confidence of interaction.Full size imageTo determine which paythways are increasingly targeted by the identified enriched miRNAs in CPRP and hypACT EVs (Fig.聽4E), strong evidence miRNA targets were selected from mirTarBase and subjected to Reactome pathway enrichment analysis as before. While no pathways met the significance criteria of FDR鈥?lt;鈥?.001 and 90% maximum confidence for CPRP EV miRNAs, 6 Reactome terms were identified for enriched miRNAs in hypACT EVs totaling up to 15 gene targets as shown in Fig.聽6. These targets formed two distinct clusters affecting proliferation and TGF尾/SMAD signaling.Figure 6Maximum confidence gene targets of enriched miRNA in hypACT EVs. Reactome pathways presented as physical STRING clusters, line thickness indicates confidence of interaction.Full size imageDiscussionBiofluids like plasma or serum are very complex mixtures, therefore studying mechanisms of action of single or a group of components like EVs and their cargo imposes challenges in terms of isolation and purification. It is known that CPRP and hypACT also contain pro-inflammatory cytokines like IL1尾8 that would counterbalance regenerative effects mediated by EV-associated miRNAs. Since each EV isolation method has limitations and co-purifies particles and molecules that contaminate EV isolates such as lipoproteins, which overlap in size or density with EVs (Fig.聽1), new protocols need to be developed in order to obtain pure EVs from blood products to study their immediate therapeutic effects.For this reason, this work investigated combined density- and size-based isolation (UC and SEC) in tandem to obtain highly pure EV preparations devoid of soluble proteins and non-EV particles including lipoproteins. Earlier reports worked on the feasibility of this EV enrichment combination41, but did not investigate residual lipoprotein contaminations. Oxidised low density lipoprotein (ox-LDL) is found in blood and therefore in blood derived products42. This lipoprotein derivative can act pro-inflammatory43,44 via induction of IL1尾 release45 and could interfere with diseased cartilage upon blood product therapy. Chondrocytes express Toll-like receptors (TLRs)2 and TLR4 especially in OA which was associated with increased cartilage degradation and elevated inflammation46,47,48. TLR4, which is a receptor for ox-LDL, promotes pro-inflammatory macrophage differentiation and is involved in the onset of inflammatory conditions49,50,51. Similarly, TLR4 mediates IL1尾 expression in chondrocytes in presence of ox-LDL52. In addition, OA聽chondrocytes express lectin-like oxidised low-density lipoprotein receptor (LOX-1), another receptor for ox-LDL, and loss of LOX-1 protects against age-related knee OA via preventing VEGF-mediated metalloproteinase expression53,54. These findings highlight the relevance of ox-LDL in OA disease progression and the potential for improvement during production of autologous blood products and derivatives such as EV preparations. Beside adverse effects of LDL, HDL can bind pro-inflammatory miRNAs55, that might be taken up by OA chondrocytes and aggravate disease. There has also been a report on synovial inflammation driven by elevated levels of the HDL receptor scavenger receptor B1 (SR-BI or CD36), which was also found to be stronger expressed in OA cartilage driving chondrocyte hypertrophy, which might promote OA progression when taking up elevated amounts of HDL56,57. Therefore, also removal of HDL from EV preparations might be of interest especially when tracking down the regenerative potential of EVs.A striking observation was that only 1鈥?% of all detected particles in plasma or serum can be found in a UC pellet (Fig.聽2A,C) and that non-pelletable particles floating in a fat layer by far outnumbered EVs. In addition, the proportion of lipoproteins co-isolated via SEC was tremendous. Similar to an earlier report58, we observed an increase in particle size pre- and post-UC samples (Fig.聽2B). Depletion of lipoproteins might provide an explanation for this shift in mode size of the whole particle populations, because lipoprotein-containg samples showed a size distribution with lower mode size that covered up size distributions of lipoprotein-depleted EV preparations (Fig.聽2A).Although, UC was reported to promote aggregate formation and to impose damage to EVs59, it is a gold standard method for EV enrichment20. However, to decrease viscosity of plasma and serum which is inversely proportional to sedimentation efficiency58, S2 fractions were diluted 1:1聽with PBS in this study to reduce internal friction and to lower potential EV damage when EVs travel along the sedimentation path during centrifugation.While we were able to show substantial depletion of lipoprotein content with UC鈥?鈥塖EC鈥?鈥塙C, this combination method resulted in considerable losses of EV marker signals on Western Blot (Fig.聽3). This effect was obviously caused by concentrating SEC fractions via UC, because concentrating via UF recovered clearly detectable amounts of聽Alix and CD9. This might indicate that the concentration step was too short to pellet all the material from the pooled SEC fractions, although the final UC run lasted for 2聽h. On the other hand, UC protocols often include washing steps for plasma and serum EVs without reporting similar effects in terms of particle damage or loss20,60,61, therefore EV damage due to UC is also less likely an explanation. More preparative steps might come at a cost in terms of EV yield, so the concentration of Alix or CD9 might have been simply too low for detection via Western Blot. To overcome this, we loaded eight-fold protein amount and probed for CD9 and CD63 and showed that these two EV markers are strongly present in CPRP EVs, in contrast to hypACT EVs. This might be explained by CD63+ and/or CD9+ platelet derived EVs contributing to and being partially consumed in blood coagulation in the hypACT device. As no protease inhibitors were used during the procedure with respect to a future clinical application of the EVs, residual protease activity can not be ruled out in hypACT62 that might have decreased epitopes below detection limit. Nevertheless, these samples were used for miRNA analysis.When determining EV-associated miRNA cargo profiles, a potential contribution of other sources for extracellular RNA has to be considered63. By using SEC, it was expected that free-floating or Ago2-associated miRNAs in plasma or serum were separated from EVs based on the small size of Ago264. The depletion of miR-16-5p and enrichment of miR-21 in hypACT EVs which were reported to be preferentially associated with Ago2 or EVs65,66, respectively, confirms our expectation (Fig.聽4D). However, RNAse treatment of samples prior to EV purification to get rid of extralumenal miRNA was dismissed as a previous report highlighted that Ago2 protects miRNAs against RNAses67. This additional step would also complicate clinical application of EVs as medical product.The miRNA let-7a was used as internal reference to compare Cq values across samples in this study. Although let-7a was identified most suitable for normalisation via NormFinder in our samples, others report that this miRNA performs poorly for other EVs like adipose-derived MSC EVs68. In contrast, let-7a was found to be highly abundant in milk across species as well as in plasma or serum of healthy individuals and traveled with EVs rather than soluble factors like Ago269,70,71, which supports the idea that the optimal reference miRNA might be sample type specific. Nevertheless, we identified characteristic sets of miRNAs enriched or depleted in EVs purified from the blood products CPRP and hypACT (Fig.聽4D,E). Interestingly, miRNAs were differentially enriched or depleted in blood product EVs. miR-101 was significantly depleted in both CPRP and hypACT EVs, whereas miR-27a was depleted in CPRP EVs, but strongly enriched in hypACT EVs (Fig.聽4D). This indicates that clotting might promote changes in the EV-associated miRNA repertoire, for example via EVs supporting coagulation72 or release during or after clotting. Lower levels of particular miRNAs might in fact be favourable, as miR-101 targets Sox9, therefore miR-101 might decrease the regenerative potential of blood products compared to isolated EVs73. Nevertheless, the identified miRNA profiles might be influenced by the EV purification approach, therefore applying different procedures to obtain pure EVs for miRNA profiling will substantiate our findings.Potential miRNA-mRNA target interactions of miRNAs found in CPRP and hypACT EVs were analysed via STRING including functional enrichment analysis and physical relations between protein products of target mRNAs. While these targets included shared clusters, some clusters were specific for either CPRP EVs or hypACT EVs (Fig.聽5). A prominent target of miRNAs CPRP EVs is NF魏B signaling, whereas IL6 signaling is targeted by hypACT EV miRNAs. Indeed, treating patient-derived chondrocytes with EVs enriched via UC produced a decrease of NF魏B levels in response to CPRP EVs and IL6 release was decreased from cells exposed to hypACT EVs enriched via UC only instead UC鈥?鈥塖EC鈥?鈥塙C as shown in a previous work from our group30. The latter might be a concerted result from inhibitory effects on IL6 mRNA mediated by miR-223, miR-142-3p, let-7a and miR-26a which are all found in hypACT EVs and target IL6 with strong experimental evidence according to miRTarBase. In addition, Notch/Delta signaling, which is specifically targeted by CPRP EVs (Fig.聽5), was identified as inhibitor of chondrogenic differentiation74,75.Focusing on miRNAs that are enriched in EVs compared to blood products (Fig.聽4D,E) revealed two clusters of genes strongly targeted by hypACT EVs (Fig.聽6). Among those is SMAD3, which has been identified as risk factor for OA76. The stringent selection criteria that were used in this analysis might leave less strongly enriched terms unnoticed, though being potentially relevant.Recently, a study determined how many miRNA molecules are found per EV77. It turned out that only 1 miRNA copy was present in 300 to 1.6鈥壝椻€?04 EVs for an individual viral miRNA, which resulted in the statement that miRNAs are minor or almost irrelevant constituents of EVs. Similarly, we found that an individual miRNA species of our screening panel was present in around 2鈥壝椻€?04 EVs on average. However, blood EVs bear a plethora of different miRNA species. Any EV which does not carry a given miRNA species might carry one or more different ones, totaling up to 1 in 24 or 1 in 379 EVs on average which carries any miRNA in CPRP or hypACT, respectively (Table 1). This stands against the claim that miRNAs would be negligible components of EV cargo. In addition, one might argue that not the absolute amount of a given miRNA is important. Although, the copy number might not be sufficient to substantially modulate a given mRNA with relevant stoichometry, a group of miRNAs targeting the same mRNA or mRNAs of related factors in a given pathway like TGF尾/SMAD signaling could still result in relevant, even disease modifying, effects. Therefore, as miRNAs can target a pathway on multiple levels, effects mediated by miRNAs might be more than the sum of their parts.Intra-articular injection of isolated (autologous) EVs for cartilage repair might provide more stable outcomes in cartilage repair than blood products. EVs as fraction of blood products are probably less prone to donor variability, which integrates differences in all other blood product constituents as well. Therefore, focusing on EVs and EV-asociated miRNAs might allow a more detailed prediction of therapeutic outcomes.Although the identified functions encoded in the miRNA repertoire of blood product EVs suggest that they might facilitate cartilage repair, basic questions remain that need to be addressed in animal studies before clinical translation. First of all, the bioavailability and biodistribution within the joint after injection has to be evaluated as EVs need to come in contact with chondrocytes to exert their predicted effects. In the following, therapeutic efficacy and outcomes such as cartilage tissue regeneration and homeostasis, alongside with effects on inflammation in the joint need to be investigated to estimate the clinical potential of EVs in cartilage repair.In conclusion, EVs from CPRP and hypACT carry diverse miRNA cargos with distinct functional repertoires, which might be sufficient to induce regenerative processes in cartilage and might supersede application of full blood products in OA therapy. References1.Filardo, G. et al. Platelet-rich plasma: Why intra-articular? A systematic review of preclinical studies and clinical evidence on PRP for joint degeneration. Knee Surg. Sports Traumatol. Arthrosc. 23, 2459鈥?474. https://doi.org/10.1007/s00167-013-2743-1 (2015).CAS聽 Article聽 PubMed聽Google Scholar聽 2.Gosens, T., Peerbooms, J. C., van Laar, W. den Oudsten, B. L. Ongoing positive effect of platelet-rich plasma versus corticosteroid injection in lateral epicondylitis: A double-blind randomized controlled trial with 2-year follow-up. Am. J. Sports Med. 39, 1200鈥?208. https://doi.org/10.1177/0363546510397173 (2011).Article聽 PubMed聽Google Scholar聽 3.Randelli, P., Arrigoni, P., Ragone, V., Aliprandi, A. Cabitza, P. Platelet rich plasma in arthroscopic rotator cuff repair: A prospective RCT study, 2-year follow-up. J. Shoulder Elbow Surg. 20, 518鈥?28. https://doi.org/10.1016/j.jse.2011.02.008 (2011).Article聽 PubMed聽Google Scholar聽 4.Yung, Y.-L. et al. Optimisation of platelet concentrates therapy: Composition, localisation, and duration of action. Asia-Pac. J. Sports Med. Arthrosc. Rehabil. Technol. 7, 27鈥?6. https://doi.org/10.1016/j.asmart.2016.11.003 (2017).Article聽 PubMed聽 PubMed Central聽Google Scholar聽 5.Cavallo, C. et al. Platelet-rich plasma: The choice of activation method affects the release of bioactive molecules. Biomed. Res. Int. 2016, 6591717. https://doi.org/10.1155/2016/6591717 (2016).CAS聽 Article聽 PubMed聽 PubMed Central聽Google Scholar聽 6.Barreto, A. Braun, T. R. A method to induce Interleukin-1 Receptor Antagonist Protein from autologous whole blood. Cytokine 81, 137鈥?41. https://doi.org/10.1016/j.cyto.2016.03.008 (2016).CAS聽 Article聽 PubMed聽Google Scholar聽 7.Meijer, H., Reinecke, J., Becker, C., Tholen, G. Wehling, P. The production of anti-inflammatory cytokines in whole blood by physico-chemical induction. Inflamm. Res. 52, 404鈥?07. https://doi.org/10.1007/s00011-003-1197-1 (2003).CAS聽 Article聽 PubMed聽Google Scholar聽 8.Kardos, D. et al. The composition of hyperacute serum and platelet-rich plasma is markedly different despite the similar production method. Int. J. Mol. Sci. https://doi.org/10.3390/ijms20030721 (2019).Article聽 PubMed聽 PubMed Central聽Google Scholar聽 9.Rutgers, M., Saris, D. B. F., Dhert, W. J. A. Creemers, L. B. Cytokine profile of autologous conditioned serum for treatment of osteoarthritis, in vitroeffects on cartilage metabolism and intra-articular levels after injection. Arthritis Res. Ther. 12, R114. https://doi.org/10.1186/ar3050 (2010).CAS聽 Article聽 PubMed聽 PubMed Central聽Google Scholar聽 10.Oh, J. H., Kim, W., Park, K. U. Roh, Y. H. Comparison of the cellular composition and cytokine-release kinetics of various platelet-rich plasma preparations. Am. J. Sports Med. 43, 3062鈥?070. https://doi.org/10.1177/0363546515608481 (2015).Article聽 PubMed聽Google Scholar聽 11.Shirokova, K., Noskov, S. Shirokova, L. Comparison of clinical efficacy of platelet-rich plasma and autologous conditioned serum treatment in patients with osteoarthritis of the knee. Osteoarthr. Cartil. 25, S438. https://doi.org/10.1016/j.joca.2017.02.756 (2017).Article聽Google Scholar聽 12.Y谩帽ez-M贸, M. et al. Biological properties of extracellular vesicles and their physiological functions. J. Extracell. Vesicles 4, 27066鈥?7066. https://doi.org/10.3402/jev.v4.27066 (2015).Article聽 PubMed聽Google Scholar聽 13.Thery, C. et al. Minimal information for studies of extracellular vesicles 2018 (MISEV2018): A position statement of the International Society for Extracellular Vesicles and update of the MISEV2014 guidelines. J. Extracell. Vesicles 7, 1535750. https://doi.org/10.1080/20013078.2018.1535750 (2018).Article聽 PubMed聽 PubMed Central聽Google Scholar聽 14.Morel, O., Jesel, L., Freyssinet, J. M. Toti, F. Cellular mechanisms underlying the formation of circulating microparticles. Arterioscler. Thromb. Vasc. Biol. 31, 15鈥?6. https://doi.org/10.1161/atvbaha.109.200956 (2011).CAS聽 Article聽 PubMed聽Google Scholar聽 15.Andreu, Z. Y谩帽ez-M贸, M. Tetraspanins in extracellular vesicle formation and function. Front. Immunol. 5, 442鈥?42. https://doi.org/10.3389/fimmu.2014.00442 (2014).CAS聽 Article聽 PubMed聽 PubMed Central聽Google Scholar聽 16.Cosenza, S., Ruiz, M., Toupet, K., Jorgensen, C. Noel, D. Mesenchymal stem cells derived exosomes and microparticles protect cartilage and bone from degradation in osteoarthritis. Sci. Rep. 7, 16214. https://doi.org/10.1038/s41598-017-15376-8 (2017).ADS聽 CAS聽 Article聽 PubMed聽 PubMed Central聽Google Scholar聽 17.Vonk, L. A. et al. Mesenchymal stromal/stem cell-derived extracellular vesicles promote human cartilage regeneration in vitro. Theranostics 8, 906鈥?20. https://doi.org/10.7150/thno.20746 (2018).CAS聽 Article聽 PubMed聽 PubMed Central聽Google Scholar聽 18.Kim, M., Steinberg, D. R., Burdick, J. A. Mauck, R. L. Extracellular vesicles mediate improved functional outcomes in engineered cartilage produced from MSC/chondrocyte cocultures. Proc. Natl. Acad. Sci.. USA 116, 1569鈥?578. https://doi.org/10.1073/pnas.1815447116 (2019).CAS聽 Article聽 PubMed聽Google Scholar聽 19.Toh, W. S., Lai, R. C., Hui, J. H. P. Lim, S. K. MSC exosome as a cell-free MSC therapy for cartilage regeneration: Implications for osteoarthritis treatment. Semin. Cell Dev. Biol. 67, 56鈥?4. https://doi.org/10.1016/j.semcdb.2016.11.008 (2017).CAS聽 Article聽 PubMed聽Google Scholar聽 20.Thery, C., Amigorena, S., Raposo, G. Clayton, A. Isolation and characterization of exosomes from cell culture supernatants and biological fluids. Curr. Protoc. Cell Biol. 3, 322. https://doi.org/10.1002/0471143030.cb0322s30 (2006).Article聽Google Scholar聽 21.Witwer, K. W. et al. Standardization of sample collection, isolation and analysis methods in extracellular vesicle research. J. Extracell. Vesicles https://doi.org/10.3402/jev.v2i0.20360 (2013).Article聽 PubMed聽 PubMed Central聽Google Scholar聽 22.S贸dar, B. W. et al. Low-density lipoprotein mimics blood plasma-derived exosomes and microvesicles during isolation and detection. Sci. Rep. 6, 24316. https://doi.org/10.1038/srep24316 (2016).ADS聽 CAS聽 Article聽 PubMed聽 PubMed Central聽Google Scholar聽 23.Karimi, N. et al. Detailed analysis of the plasma extracellular vesicle proteome after separation from lipoproteins. Cell. Mol. Life Sci. https://doi.org/10.1007/s00018-018-2773-4 (2018).Article聽 PubMed聽 PubMed Central聽Google Scholar聽 24.Lozano-Ramos, I. et al. Size-exclusion chromatography-based enrichment of extracellular vesicles from urine samples. J. Extracell. Vesicles 4, 27369. https://doi.org/10.3402/jev.v4.27369 (2015).Article聽 PubMed聽Google Scholar聽 25.B枚ing, A. N. et al. Single-step isolation of extracellular vesicles by size-exclusion chromatography. J. Extracell. Vesicles https://doi.org/10.3402/jev.v3.23430 (2014).Article聽 PubMed聽 PubMed Central聽Google Scholar聽 26.de Menezes-Neto, A. et al. Size-exclusion chromatography as a stand-alone methodology identifies novel markers in mass spectrometry analyses of plasma-derived vesicles from healthy individuals. J. Extracell. Vesicles 4, 27378. https://doi.org/10.3402/jev.v4.27378 (2015).Article聽 PubMed聽Google Scholar聽 27.G谩mez-Valero, A. et al. Size-exclusion chromatography-based isolation minimally alters extracellular vesicles鈥?characteristics compared to precipitating agents. Sci. Rep. 6, 33641. https://doi.org/10.1038/srep33641 (2016).ADS聽 CAS聽 Article聽 PubMed聽 PubMed Central聽Google Scholar聽 28.Mol, E. A., Goumans, M. J., Doevendans, P. A., Sluijter, J. P. G. Vader, P. Higher functionality of extracellular vesicles isolated using size-exclusion chromatography compared to ultracentrifugation. Nanomed. Nanotechnol. Biol. Med. 13, 2061鈥?065. https://doi.org/10.1016/j.nano.2017.03.011 (2017).CAS聽 Article聽Google Scholar聽 29.Takov, K., Yellon, D. M. Davidson, S. M. Comparison of small extracellular vesicles isolated from plasma by ultracentrifugation or size-exclusion chromatography: Yield, purity and functional potential. J. Extracell. Vesicles 8, 1560809. https://doi.org/10.1080/20013078.2018.1560809 (2019).CAS聽 Article聽 PubMed聽Google Scholar聽 30.Alexander, O. et al. Characterization and chondroprotective effects of extracellular vesicles from plasma- and serum-based autologous blood-derived products for osteoarthritis therapy. Front. Bioeng. Biotechnol. https://doi.org/10.3389/fbioe.2020.584050 (2020).Article聽Google Scholar聽 31.Gardiner, C., Ferreira, Y. J., Dragovic, R. A., Redman, C. W. Sargent, I. L. Extracellular vesicle sizing and enumeration by nanoparticle tracking analysis. J. Extracell. Vesicles https://doi.org/10.3402/jev.v2i0.19671 (2013).Article聽 PubMed聽 PubMed Central聽Google Scholar聽 32.Mehdiani, A. et al. An innovative method for exosome quantification and size measurement. J. Vis. Exp. https://doi.org/10.3791/50974 (2015).Article聽 PubMed聽 PubMed Central聽Google Scholar聽 33.Savitzky, A. Golay, M. J. E. Smoothing and differentiation of data by simplified least squares procedures. Anal. Chem. 36, 1627鈥?639. https://doi.org/10.1021/ac60214a047 (1964).ADS聽 CAS聽 Article聽Google Scholar聽 34.Andersen, C. L., Jensen, J. L. Orntoft, T. F. Normalization of real-time quantitative reverse transcription-PCR data: A model-based variance estimation approach to identify genes suited for normalization, applied to bladder and colon cancer data sets. Can. Res. 64, 5245鈥?250. https://doi.org/10.1158/0008-5472.can-04-0496 (2004).CAS聽 Article聽Google Scholar聽 35.Blondal, T. et al. Assessing sample and miRNA profile quality in serum and plasma or other biofluids. Methods (San Diego, Calif) 59, S1-6. https://doi.org/10.1016/j.ymeth.2012.09.015 (2013).CAS聽 Article聽Google Scholar聽 36.Szklarczyk, D. et al. STRING v11: Protein鈥損rotein association networks with increased coverage, supporting functional discovery in genome-wide experimental datasets. Nucleic Acids Res. 47, D607鈥揇613. https://doi.org/10.1093/nar/gky1131 (2019).CAS聽 Article聽 PubMed聽Google Scholar聽 37.Ashburner, M. et al. Gene ontology: Tool for the unification of biology. The Gene Ontology Consortium. Nat. Genet. 25, 25鈥?9. https://doi.org/10.1038/75556 (2000).CAS聽 Article聽 PubMed聽 PubMed Central聽Google Scholar聽 38.Carbon, S. et al. The Gene Ontology resource: Enriching a GOld mine. Nucleic Acids Res. 49, D325-d334. https://doi.org/10.1093/nar/gkaa1113 (2021).Article聽Google Scholar聽 39.Benjamini, Y., Krieger, A. M. Yekutieli, D. Adaptive linear step-up procedures that control the false discovery rate. Biometrika 93, 491鈥?07. https://doi.org/10.1093/biomet/93.3.491 (2006).MathSciNet聽 Article聽 MATH聽Google Scholar聽 40.Pizzamiglio, S. et al. A methodological procedure for evaluating the impact of hemolysis on circulating microRNAs. Oncol. Lett. 13, 315鈥?20. https://doi.org/10.3892/ol.2016.5452 (2017).CAS聽 Article聽 PubMed聽Google Scholar聽 41.Koh, Y. Q., Almughlliq, F. B., Vaswani, K., Peiris, H. N. Mitchell, M. D. Exosome enrichment by ultracentrifugation and size exclusion chromatography. Front. Biosci. (Landmark Ed.) 23, 865鈥?74 (2018).CAS聽 Article聽Google Scholar聽 42.Itabe, H. Oxidized low-density lipoprotein as a biomarker of in vivo oxidative stress: From atherosclerosis to periodontitis. J. Clin. Biochem. Nutr. 51, 1鈥?. https://doi.org/10.3164/jcbn.11-00020R1 (2012).CAS聽 Article聽 PubMed聽 PubMed Central聽Google Scholar聽 43.Masuda, D. Yamashita, S. Postprandial hyperlipidemia and remnant lipoproteins. J. Atherosc. Thromb. 24, 95鈥?09. https://doi.org/10.5551/jat.RV16003 (2017).CAS聽 Article聽Google Scholar聽 44.Fujioka, Y. Ishikawa, Y. Remnant lipoproteins as strong key particles to atherogenesis. J. Atherosc. Thromb. 16, 145鈥?54. https://doi.org/10.5551/jat.e598 (2009).CAS聽 Article聽Google Scholar聽 45.Okumura, T. et al. Chylomicron remnants stimulate release of interleukin-1beta by THP-1 cells. J. Atherosc. Thromb. 13, 38鈥?5. https://doi.org/10.5551/jat.13.38 (2006).CAS聽 Article聽Google Scholar聽 46.Sillat, T. et al. Toll-like receptors in human chondrocytes and osteoarthritic cartilage. Acta Orthop. 84, 585鈥?92. https://doi.org/10.3109/17453674.2013.854666 (2013).Article聽 PubMed聽 PubMed Central聽Google Scholar聽 47.Wang, Y., Zhao, X. Liu-Bryan, R. Role of TLR2 and TLR4 in regulation of articular chondrocyte homeostasis. Osteoarthr. Cartil. 28, 669鈥?74. https://doi.org/10.1016/j.joca.2020.01.011 (2020).CAS聽 Article聽Google Scholar聽 48.Bobacz, K. et al. Toll-like receptors and chondrocytes: The lipopolysaccharide-induced decrease in cartilage matrix synthesis is dependent on the presence of toll-like receptor 4 and antagonized by bone morphogenetic protein 7. Arthritis Rheum. 56, 1880鈥?893. https://doi.org/10.1002/art.22637 (2007).CAS聽 Article聽 PubMed聽Google Scholar聽 49.Howell, K. W. et al. Toll-like receptor 4 mediates oxidized LDL-induced macrophage differentiation to foam cells. J. Surg. Res. 171, e27-31. https://doi.org/10.1016/j.jss.2011.06.033 (2011).CAS聽 Article聽 PubMed聽Google Scholar聽 50.Wang, X. et al. Oxidized low-density lipoprotein promotes macrophage lipid accumulation via the toll-like receptor 4-Src Pathway. Circ. J. 79, 2509鈥?516. https://doi.org/10.1253/circj.CJ-15-0345 (2015).Article聽 PubMed聽Google Scholar聽 51.Miller, Y. I. Toll-like receptors and atherosclerosis: Oxidized LDL as an endogenous Toll-like receptor ligand. Future Cardiol. 1, 785鈥?92. https://doi.org/10.2217/14796678.1.6.785 (2005).CAS聽 Article聽 PubMed聽Google Scholar聽 52.Ding, Y., Wang, L., Zhao, Q., Wu, Z. Kong, L. MicroRNA-93 inhibits chondrocyte apoptosis and inflammation in osteoarthritis by targeting the TLR4/NF-魏B signaling pathway. Int. J. Mol. Med. 43, 779鈥?90. https://doi.org/10.3892/ijmm.2018.4033 (2019).CAS聽 Article聽 PubMed聽Google Scholar聽 53.Hashimoto, K., Oda, Y., Nakamura, F., Kakinoki, R. Akagi, M. Lectin-like, oxidized low-density lipoprotein receptor-1-deficient mice show resistance to age-related knee osteoarthritis. Eur. J. Histochem. 61, 2762鈥?762. https://doi.org/10.4081/ejh.2017.2762 (2017).CAS聽 Article聽 PubMed聽 PubMed Central聽Google Scholar聽 54.Kanata, S. et al. Oxidized LDL binding to LOX-1 upregulates VEGF expression in cultured bovine chondrocytes through activation of PPAR-gamma. Biochem. Biophys. Res. Commun. 348, 1003鈥?010. https://doi.org/10.1016/j.bbrc.2006.07.133 (2006).CAS聽 Article聽 PubMed聽Google Scholar聽 55.Vickers, K. C., Palmisano, B. T., Shoucri, B. M., Shamburek, R. D. Remaley, A. T. MicroRNAs are transported in plasma and delivered to recipient cells by high-density lipoproteins. Nat. Cell Biol. 13, 423鈥?33. https://doi.org/10.1038/ncb2210 (2011).CAS聽 Article聽 PubMed聽 PubMed Central聽Google Scholar聽 56.Pfander, D., Cramer, T., Deuerling, D., Weseloh, G. Swoboda, B. Expression of thrombospondin-1 and its receptor CD36 in human osteoarthritic cartilage. Ann. Rheum. Dis. 59, 448鈥?54. https://doi.org/10.1136/ard.59.6.448 (2000).CAS聽 Article聽 PubMed聽 PubMed Central聽Google Scholar聽 57.Kamekura, S. et al. Contribution of runt-related transcription factor 2 to the pathogenesis of osteoarthritis in mice after induction of knee joint instability. Arthritis Rheum. 54, 2462鈥?470. https://doi.org/10.1002/art.22041 (2006).CAS聽 Article聽 PubMed聽Google Scholar聽 58.Momen-Heravi, F. et al. Impact of biofluid viscosity on size and sedimentation efficiency of the isolated microvesicles. Front. Physiol. 3, 162. https://doi.org/10.3389/fphys.2012.00162 (2012).CAS聽 Article聽 PubMed聽 PubMed Central聽Google Scholar聽 59.Linares, R., Tan, S., Gounou, C., Arraud, N. Brisson, A. R. High-speed centrifugation induces aggregation of extracellular vesicles. J. Extracell. Vesicles 4, 29509. https://doi.org/10.3402/jev.v4.29509 (2015).CAS聽 Article聽 PubMed聽Google Scholar聽 60.Serrano-Pertierra, E. et al. Characterization of plasma-derived extracellular vesicles isolated by different methods: A comparison study. Bioengineering (Basel) 6, 8. https://doi.org/10.3390/bioengineering6010008 (2019).CAS聽 Article聽Google Scholar聽 61.Brennan, K. et al. A comparison of methods for the isolation and separation of extracellular vesicles from protein and lipid particles in human serum. Sci. Rep. 10, 1039. https://doi.org/10.1038/s41598-020-57497-7 (2020).ADS聽 CAS聽 Article聽 PubMed聽 PubMed Central聽Google Scholar聽 62.Kardos, D. et al. Biological and mechanical properties of platelet-rich fibrin membranes after thermal manipulation and preparation in a single-syringe closed system. Int. J. Mol. Sci. 19, 3433. https://doi.org/10.3390/ijms19113433 (2018).CAS聽 Article聽 PubMed Central聽Google Scholar聽 63.Turchinovich, A., Tonevitsky, A. G. Burwinkel, B. Extracellular miRNA: A collision of two paradigms. Trends Biochem. Sci. 41, 883鈥?92. https://doi.org/10.1016/j.tibs.2016.08.004 (2016).CAS聽 Article聽 PubMed聽Google Scholar聽 64.Arroyo, J. D. et al. Argonaute2 complexes carry a population of circulating microRNAs independent of vesicles in human plasma. Proc. Natl. Acad. Sci. USA 108, 5003鈥?008. https://doi.org/10.1073/pnas.1019055108 (2011).ADS聽 Article聽 PubMed聽Google Scholar聽 65.Hulsmans, M. Holvoet, P. MicroRNA-containing microvesicles regulating inflammation in association with atherosclerotic disease. Cardiovasc. Res. 100, 7鈥?8. https://doi.org/10.1093/cvr/cvt161 (2013).CAS聽 Article聽 PubMed聽Google Scholar聽 66.Alegre, E. et al. Study of circulating microRNA-125b levels in serum exosomes in advanced melanoma. Arch. Pathol. Lab. Med. 138, 828鈥?32. https://doi.org/10.5858/arpa.2013-0134-OA (2014).CAS聽 Article聽 PubMed聽Google Scholar聽 67.Winter, J. Diederichs, S. Argonaute proteins regulate microRNA stability: Increased microRNA abundance by Argonaute proteins is due to microRNA stabilization. RNA Biol. 8, 1149鈥?157. https://doi.org/10.4161/rna.8.6.17665 (2011).CAS聽 Article聽 PubMed聽Google Scholar聽 68.Ragni, E. et al. Identification of miRNA reference genes in extracellular vesicles from adipose derived mesenchymal stem cells for studying osteoarthritis. Int. J. Mol. Sci. 20, 1108. https://doi.org/10.3390/ijms20051108 (2019).CAS聽 Article聽 PubMed Central聽Google Scholar聽 69.Tay, J. W., James, I., Hughes, Q. W., Tiao, J. Y. Baker, R. I. Identification of reference miRNAs in plasma useful for the study of oestrogen-responsive miRNAs associated with acquired Protein S deficiency in pregnancy. BMC Res. Notes 10, 312鈥?12. https://doi.org/10.1186/s13104-017-2636-3 (2017).CAS聽 Article聽 PubMed聽 PubMed Central聽Google Scholar聽 70.van Herwijnen, M. J. C. et al. Abundantly present miRNAs in milk-derived extracellular vesicles are conserved between mammals. Front. Nutr. 5, 81鈥?1. https://doi.org/10.3389/fnut.2018.00081 (2018).CAS聽 Article聽 PubMed聽 PubMed Central聽Google Scholar聽 71.Wang, Z. et al. Serum microRNA is a promising biomarker for osteogenesis imperfecta. Intractable Rare Dis. Res. 1, 81鈥?5. https://doi.org/10.5582/irdr.2012.v1.2.81 (2012).CAS聽 Article聽 PubMed聽 PubMed Central聽Google Scholar聽 72.Tripisciano, C. et al. Different potential of extracellular vesicles to support thrombin generation: Contributions of phosphatidylserine, tissue factor, and cellular origin. Sci. Rep. 7, 6522. https://doi.org/10.1038/s41598-017-03262-2 (2017).ADS聽 CAS聽 Article聽 PubMed聽 PubMed Central聽Google Scholar聽 73.Dai, L., Zhang, X., Hu, X., Zhou, C. Ao, Y. Silencing of microRNA-101 prevents IL-1尾-induced extracellular matrix degradation in chondrocytes. Arthritis Res. Ther. 14, R268. https://doi.org/10.1186/ar4114 (2012).CAS聽 Article聽 PubMed聽 PubMed Central聽Google Scholar聽 74.Dong, Y. et al. RBPj魏-dependent Notch signaling regulates mesenchymal progenitor cell proliferation and differentiation during skeletal development. Development 137, 1461. https://doi.org/10.1242/dev.042911 (2010).CAS聽 Article聽 PubMed聽 PubMed Central聽Google Scholar聽 75.Fujimaki, R., Toyama, Y., Hozumi, N. Tezuka, K.-I. Involvement of Notch signaling in initiation of prechondrogenic condensation and nodule formation in limb bud micromass cultures. J. Bone Miner. Metab. 24, 191鈥?98. https://doi.org/10.1007/s00774-005-0671-y (2006).CAS聽 Article聽 PubMed聽Google Scholar聽 76.Shen, J., Li, S. Chen, D. TGF-尾 signaling and the development of osteoarthritis. Bone Res. 2, 14002. https://doi.org/10.1038/boneres.2014.2 (2014).CAS聽 Article聽 PubMed聽 PubMed Central聽Google Scholar聽 77.Albanese, M. et al. Micro RNAs are minor constituents of extracellular vesicles and are hardly delivered to target cells. bioRxiv. https://doi.org/10.1101/2020.05.20.106393 (2020).Article聽Google Scholar聽 Download referencesAcknowledgementsThe work was jointly supported by the European Fund for Regional Development (EFRE) and the Fund for Economy and Tourism of Lower Austria, Grant Number WST3-F-5030664/003-2017. TamiRNA GmbH (Vienna, Austria) performed miRNA quantification as service company and provided Cp raw data.Author informationAffiliationsCenter for Regenerative Medicine, Department for Health Sciences, Medicine and Research, Danube University Krems, Krems an der Donau, AustriaAlexander Otahal,聽Karina Kramer,聽Markus Neubauer,聽Stefan Nehrer聽 聽Andrea De LunaOrthoSera GmbH, Krems an der Donau, AustriaOlga Kuten-PellaDepartment of Sports Physiology, University of Physical Education, Budapest, HungaryZsombor LaczaAuthorsAlexander OtahalView author publicationsYou can also search for this author in PubMed聽Google ScholarOlga Kuten-PellaView author publicationsYou can also search for this author in PubMed聽Google ScholarKarina KramerView author publicationsYou can also search for this author in PubMed聽Google ScholarMarkus NeubauerView author publicationsYou can also search for this author in PubMed聽Google ScholarZsombor LaczaView author publicationsYou can also search for this author in PubMed聽Google ScholarStefan NehrerView author publicationsYou can also search for this author in PubMed聽Google ScholarAndrea De LunaView author publicationsYou can also search for this author in PubMed聽Google ScholarContributionsThe EV isolation protocol was developed and EV isolations were performed by A.O. NTA. assessments and Western Blot were done by A.O., blood was drawn by M.N. and blood products were prepared by O.K.-P. and K.K. The manuscript was prepared by A.O. and A.D.L., while M.N., Z.L. and S.N. provided valuable ideas, carefully read and approved the manuscript draft.Corresponding authorCorrespondence to Andrea De Luna.Ethics declarations Competing interests Z.L. is CEO and O.K.-P. is employee of Orthosera GmbH developing the hypACT inject device. The other authors declare no competing interest. Additional informationPublisher\'s noteSpringer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.Supplementary Information CommentsBy submitting a comment you agree to abide by our Terms and Community Guidelines. If you find something abusive or that does not comply with our terms or guidelines please flag it as inappropriate. Sign up for the Nature Briefing newsletter 鈥?what matters in science, free to your inbox daily.