11 research outputs found
Mesenchymal stem cell-derived exosomes have altered microRNA profiles and induce osteogenic differentiation depending on the stage of differentiation
<div><p>Human mesenchymal stem cell (hMSC)-derived exosomes have shown regenerative effects, but their role in osteogenesis and the underlying mechanism are yet to be determined. In this study, we examined the time-course secretion of exosomes by hMSCs during the entire process of osteogenic differentiation. Exosomes derived from hMSCs in various stages of osteogenic differentiation committed homotypic cells to differentiate towards osteogenic lineage, but only exosomes from late stages of osteogenic differentiation induced extracellular matrix mineralisation. Exosomes from expansion and early and late stages of osteogenic differentiation were internalised by a subpopulation of hMSCs. MicroRNA profiling revealed a set of differentially expressed exosomal microRNAs from the late stage of osteogenic differentiation, which were osteogenesis related. Target prediction demonstrated that these microRNAs enriched pathways involved in regulation of osteogenic differentiation and general mechanisms how exosomes exert their functions, such as “Wnt signalling pathway” and “endocytosis”. Taken together, the results show that MSCs secrete exosomes with different biological properties depending on differentiation stage of their parent cells. The exosomal cargo transferred from MSCs in the late stage of differentiation induces osteogenic differentiation and mineralisation. Moreover, it is suggested that the regulatory effect on osteogenesis by exosomes is at least partly exerted by exosomal microRNA.</p></div
Differentially expressed microRNAs in exosomes derived from hMSCs during expansion and osteogenic differentiation.
<p>Differentially expressed microRNAs in exosomes derived from hMSCs during expansion and osteogenic differentiation.</p
Characterisation of exosomes by transmission electron microscopy (A) and nanoparticle tracking analysis (B).
<p>(A) A1, A4 and A7: Survey transmission electron micrographs of exosomes from the Exo_P6, Exo_D3 and Exo_D21 groups. Exosomes are approximately 30–150 nm and mainly display a rounded shape. A4-A9: Details of selected exosomes without (A2, A5 and A8) or with (A3, A5 and A9) labelling of 10 nm gold-labelled anti-CD63 antibodies. Scale bar: top panel (A1, A4 and A7), 100 nm; bottom panel (A2-A3, A5-A6 and A8-A9), 50 nm. (B) B1-B3: Distribution of particles from all nine captures of three biological replicates in each group of exosomes. B4-B6: Average concentration/size distribution of all nine captures in each group of exosomes. B7-B8: Mean and mode of particle size of each group of exosomes. B9: Mean concentration of particles in each group of exosomes. Error bars in B7-B9 denote standard error mean, SEM; n = 3 biological replicates.</p
Internalisation of exosomes in hMSCs.
<p>Confocal micrographs of hMSCs incubated for 24h with A) PBS (negative control); B) Exo_P6; C) Exo_D3 and D) Exo_D21. PKH67-stained exosomes are detected mainly in the cytoplasm of some of the cells. The intensity varied between individual cells. No PKH67-stained material was found in the negative control. A1-D1, blue channel; A2-D2, green channel; A3-D3, transmission (TD) channel; A4-D4, merged channels. Blue, DAPI-stained nucleus; Green, PKH67-stained exosomes. Scale bar: 20 ÎĽm.</p
Summary of biological pathways enriched by differentially expressed microRNAs.
<p>Summary of biological pathways enriched by differentially expressed microRNAs.</p
Evaluation of osteogenic differentiation of hMSCs after exosome treatment.
<p>(A) ALP activity 14 d after treatment with exosomes or the appropriate controls; (B) Quantification of calcium in ECM after 21 d; (C) Quantification of phosphate in ECM after 21 d. In (A-C), bars indicate mean values whereas error bars denote standard errors of the mean (SEM). Small letters a, b and c represent statistical significance when compared with NCtrl_D0, NCtrl_D14/D21 and Sexo_Ctrl respectively, based on Bonferroni-corrected p value < 0.05. n = 3 independent experiments; (D) Alizarin red staining after 21 d.</p
MicroRNA profiles of exosomes and hMSCs during expansion and osteogenic differentiation.
<p>(A) Altered microRNA profiles of exosomes and hMSCs during expansion (P6) and osteogenic differentiation (D3 and D21) of hMSCs and (B) Altered microRNA profiles of exosomes derived from the expansion (P6) and osteogenic differentiation (D3 and D21) of hMSCs. The heat map diagram shows the result of the two-way hierarchical clustering of microRNAs and samples. The clustering is performed on all samples and on the top 50 microRNAs with the highest standard deviation. The normalised (dCq) values have been used for the analysis. Each row represents one microRNA and each column represents one sample. The microRNA clustering tree is shown on the left. The colour scale shown at the bottom illustrates the relative expression level of a microRNA across all samples: red colour represents an expression level above the mean, green colour represents expression lower than the mean.</p
Enriched KEGG biological pathways related to osteogenic differentiation and general regulation mechanism.
<p>Enriched KEGG biological pathways related to osteogenic differentiation and general regulation mechanism.</p
Schematic illustration of the experimental set-up.
<p>Schematic illustration of the experimental set-up.</p
Osteogenic gene expression in MSCs.
<p>Gene expression for RUNX2 (a), BMP-2 (b) and OC (c) in MSCs, cultured in unconditioned control medium, in monocyte-conditioned medium (CM) or in medium supplemented with exosomes isolated from the CM for 72 h (n = 4). Each bar represents the mean ± SEM, n = 4. *p<0.05 compared with the medium control.</p