Project description:Unprogrammed macrophage polarization, is associated with diabetic wound ulcers. Nevertheless, development of corresponding drugs is still a challenge. Here, exosomes are isolated from naive bone marrow-derived macrophages (BMDMs) (M0-Exos), inflammatory BMDMs (M1-Exos), and anti-inflammatory BMDMs (M2-Exos), with the aim of pinpointing the exosomes functionality and identify global miRNAs expression profiles.

Project description:Tumor immunotherapy has been convincingly demonstrated as a feasible approach for treating cancers. Although promising, however, the immunosuppressive tumor microenvironment (TME) has been recognized as a major obstacle in tumor immunotherapy. It is highly desirable to release an immunosuppressive “brake” for improving cancer immunotherapy. Among tumor-infiltrated immune cells, tumor-associated macrophages (TAMs) play an important role in the growth, invasion and metastasis of tumors. The polarization of TAMs (M2) into the M1 type can alleviate the immunosuppression of the TME and enhance the effect of immunotherapy. Inspired by this, we constructed a therapeutic exosomal vaccine from antigen-stimulated M1-type macrophages (M1OVA-Exos). M1OVA-Exos are capable of polarizing TAMs into M1 type through downregulation of the Wnt signaling pathway. Mediating the TME further activates the immune response and inhibits tumor growth and metastasis via the exosomal vaccine. Our study provides a new strategy for the polarization of TAMs, which augments cancer vaccine therapy efficacy.

Project description:Limbal stem cells including epithelial and stromal/Mesenchymal stem cells that contribute to sustained corneal homeostasis, maintain their ability to act as self-renewal progenitor cells by virtue of their limbal niche and intercellular communication. Extracellular vehicles (EVs), including exosomes (Exos), are important paracrine mediators through their cargo transfer for intercellular communication in various stem cell niches. Previously we have shown the differential cargos and regulatory roles of limbal stromal cell (LSC)-derived Exos, in limbal epithelial cells (LEC) in normal (N) and diabetic (DM) limbal niche. In the present study, to have a comprehensive knowledge of reciprocal LEC-LSC crosstalk, we investigated the proteomics and miRNA profile of exosomes derived from LEC and their regulatory roles in LSC in N and DM limbus. Our study showed wound healing and proliferation rates in primary N-LSC were significantly enhanced upon treatment by normal LEC-derived Exos (N-Exos), but not by diabetic Exos (DM-Exos). Further, N-Exos treated LSC showed downregulation of keratocyte markers, ALDH3A1 and lumican, but not keratocan, and upregulation of MSC markers, CD105, CD90, and CD73 compared to the DM-Exos treated LSC. Using next generation sequencing (NGS) and proteomics analysis, we revealed some miRNAs and proteins in the Exos that affect the cellular crosstalk and the function of the cornea. We also documented differences in DM vs. normal LEC-derived Exo’s cargos. Overall, DM-Exos have less effect on LSC proliferation, wound healing, and stem cell maintenance than N-Exos, likely by transferring their cargo proteins and/or regulatory miRNAs targeting cell cycle, ERK/MAPK, TGF-β, EMT, PI3K-Akt-mTOR signaling molecules. This suggests that the small RNA and protein cargo differences in DM vs. N LEC-derived Exos could contribute to the disease state. Our study revealed a complex contribution of Exos to health and diabetic state of corneal homeostasis and suggests the potential of EV therapeutics for diabetic cornea regenerative medicine

Project description:Alveolar macrophages (AMs) are crucial for pulmonary defense and immune regulation. Exosomes from adipose-derived mesenchymal stem cells (ADSC-Exos) have emerged as a promising therapy for inflammatory lung diseases by modulating immune responses. This study investigates the ability of ADSC-Exos to alleviate inflammation in acute lunag injury (ALI), a condition often triggered by sepsis and characterized by lung permeability and respiratory failure.

Project description:Background: Following spinal cord injury (SCI), the inflammatory storm initiated by microglia/macrophages poses a significant impediment to the recovery process. Exosomes play a crucial role in the transport of miRNAs, facilitating essential cellular communication through the transfer of genetic material. However, the miRNAs from iPSC-NSCs-Exos and their potential mechanisms leading to repair after SCI remain unclear. This study aims to explore the role of iPSC-NSCs-Exos in microglia/macrophage pyroptosis and reveal their potential mechanisms. Methods: iPSC-NSCs-Exos were characterized and identified using transmission electron microscopy (TEM), nanoparticle tracking analysis (NTA), and Western blot. A mouse SCI model and a series of in vivo and in vitro experiments were conducted to investigate the therapeutic effects of iPSC-NSCs-Exos. Subsequently, miRNA microarray analysis and rescue experiments were performed to confirm the role of miRNAs in iPSC-NSCs-Exos in SCI. Mechanistic studies were carried out using Western blot, luciferase activity assays, and RNA-ChIP. Results: Our findings revealed that iPSC-NSCs-derived exosomes inhibited microglia/macrophage pyroptosis at 7 days post-SCI, maintaining myelin integrity and promoting axonal growth, ultimately improving mice motor function. The miRNA microarray showed let-7b-5p to be highly enriched in iPSC-NSCs-Exos, and LRIG3 was identified as the target gene of let-7b-5p. Through a series of rescue experiments, we uncovered the connection between iPSC-NSCs and microglia/macrophages, revealing a novel target for treating SCI. Conclusion: In conclusion, we discovered that iPSC-NSCs-derived exosomes can package and deliver let-7b-5p, regulating the expression of LRIG3 to ameliorate microglia/macrophage pyroptosis and enhance motor function in mice after SCI. This highlights the potential of combined therapy with iPSC-NSCs-Exos and let-7b-5p in promoting functional recovery and limiting inflammation following SCI.

Project description:Exosomes are nanosized extracellular vesicles with lipid bilayer membranes and contain various contents, including lipids, miRNAs and proteins, all of which are widely involved in signaling pathways and genetic information processes. Exosomes derived from adipose tissues (AT-Exos) have been identified as a crucialmedium in the transmission of information from adipose tissue to itself and to other organs, including exosomes derived from inguinal white adipose tissue (iWAT-Exos), visceral white adipose tissue (vWAT-Exos) and brown adipose tissue (BAT-Exos). Here we reported that dietary conditions and tissue origins of exosome can affect the composition and function of miRNAs in AT-Exos, mainly including lipid metabolism and inflammatory signaling pathways associated with metabolic imbalance.

Project description:In order to examine the proteomics of exosomes derived from DPSCs under hypoxia (Hypo-Exos) and the mechanism underlying the angiogenic effect of DPSC-Exos, iTRAQ-based proteomics analysis and bioinformatic analysis were performed to investigate proteome profile differences between exosomes derived from DPSCs under normoxia (Nor-Exos) and Hypo-Exos.7114 peptides and 1792 proteins were identified from the Hypo-Exos samples with a 1% FDR. Compared with the control group, 39 proteins were upregulated and 40 proteins were downregulated in Hypo-Exos.

Project description:To explore the potential exosomal miRNAs regulating macrophage M1 polarization, we isolated and characterized inf-Exos or un-Exos, ad the miRNA profiling between inf-Exos and un-Exos was then compared by using miRNA-seq. We then performed miRNAs expression profiling analysis using data obtained from RNA-seq of inf-Exos (n = 5) and un-Exos (n = 5)

Project description:Vitiligo is a skin disease characterized by the destruction of epidermal melanocytes due to oxidative stress and autoimmune response. As the main responder to oxidative stress, keratinocytes facilitate melanocyte loss under oxidative stress by inducing melanocyte death and recruiting antigen-specific CD8+ T cell to skin to destroy melanocytes. It has been proved that keratinocytes secrete abundant functional exosomes, but the role of exosomes secreted from keratinocytes under oxidative stress in vitiligo pathogenesis is unknown. We found that oxidative stress enhanced the secretion of exosomes from keratinocytes. These exosomes (OS-Exos) administration aggravated melanocyte loss and CD8+ T cell infiltration in the epidermis of tail in the vitiligo mouse model, thereby driving vitiligo progression. OS-Exos suppressed the survival of melanocytes while promoting the proliferation and activation of CD8+ T cells in vitro. As miRNAs contained in OS-Exos might be responsible for the functions of OS-Exos on melanocytes and CD8+ T cells, we employed small RNAs-seq analysis to screen miRNAs enriched in OS-Exos as compared to those in Exos (from untreated HaCaT cells). The hierarchical clustering analysis and the volcano plot showed the distinct signatures of known miRNAs as well as novel miRNAs between OS-Exos and Exos. In total, 276 differentially expressed miRNAs were discovered, with 134 and 142 miRNAs displaying significant up- or down-regulation, respectively, in OS-Exos compared with Exos (P<0.05; fold change≥2. The above data suggest that miRNAs enriched in OS-Exos might contribute to the facilitatory role of OS-Exos in vitiligo progression.

Project description:Exosomes derived from adipose tissues (AT-Exos) have been identified as a crucialmedium in the transmission of information from adipose tissue to itself and to other organs, including exosomes derived from inguinal white adipose tissue (iWAT-Exos), visceral white adipose tissue (vWAT-Exos) and brown adipose tissue (BAT-Exos). However, the functional differences in depot-specific AT-Exos under obese conditions remain elusive. Here we reported that AT-Exos participated in regulating adipocyte inflammation and metabolic homeostasis. Notably, vWAT-Exos play a critical role in promoting lipid accumulation and inflammation in the development of obesity. Although both are derived from “energy storage” WAT, the biological effects exhibited by iWAT-Exos are far different from those vWAT-Exos. Especially under diet-induced obesity conditions, iWAT-Exos appeared to be BAT-Exo-like, exhibiting an “energy expending” type. Altogether, our data indicated that AT-Exos from different depots have distinct functions and effects on adipocytes metabolism.