Project description:Administration of mesenchymal stem cells (MSCs) has the potential to ameliorate degenerative disorders and to repair damaged tissues. The homing of transplanted MSCs to injured sites is a critical property of engraftment. Our aim was to identify microRNAs involved in controlling MSC proliferation and migration. MSCs can be isolated from bone marrow and umbilical cord Wharton's jelly (BM-MSCs and WJ-MSCs, respectively), and WJ-MSCs show poorer motility yet have a better amplification rate compared to BM-MSCs. One human BM-MSC (pooled sample of 4 independent donors), one human WJ-MSC (pooled sample of 3 independent donors), and differentiated osteocytes and adipocytes derived from BM-MSCs after 2 weeks induction.

Project description:Conventional treatments for inflammatory bowel disease (IBD) have multiple potential side effects. Therefore, alternative treatments are desperately needed. In the present study, we proposed a new therapeutic tool for the treatment of IBD in murine pre-clinical models by using MSC-Exos. We demonstrated that the infused MSC-Exos are immunotolerated by the host, which is convenient for a future clinical application of MSC-Exos in IBD. To understand the molecular basis mediating the anticolitic benefit of MSC-Exos, we performed proteomic analysis using iTRAQ technology to detect the protein expression profiles in MSC-Exos and the corresponding supernatants from their parent cell MSCs. Proteomic analysis revealed that MSC-Exos were enriched in proteins involved in regulating multiple biological processes associated with the anti-colitic benefit of MSC-Exos. Particularly, metallothionein-2 in MSC-Exos was required for the suppression of inflammatory responses in macrophages. Taken together, MSC-Exos are critical regulators of inflammatory responses and may be promising candidates for IBD treatment.

Project description:MSCs are inherently tumor-homing and immunosuppressive and can be isolated, cultured, expanded, and transduced, making them viable candidates for cell therapy. MSCs can also be useful in allogeneic transplantation because of their immunocompatibility. MSCs have the capacity to home specifically to tumors including gliomas and breast, colon, ovarian, and lung carcinomas, among many other primary and metastatic tumors. Some discrepancies are however present regarding the mechanism and the involvement of molecules/receptors in MSC homing to tumours. We have used in this study a combination of genome expression profiling and cytokine arrays to screen for candidates mediating MSC homing to two different cancer cell lines: A549 and MDAMB231. We found a variety of interleukines and cytokines already described as players in the process, such as IL6, IL8, CCL2. Additionally, from in vitro migration and invasion assays, we show that CXCR4 is a major player in this mechanism being the essential MSC receptor for the process to occur. For the first time, we have identified in this study a novel axis: MIF-CXCR4, showing a physical interaction between them and validating their essential role in vitro and in vivo. A better understanding of MSC homing players towards tumours will help the development of novel strategies in their use as vehicles in cancer cell therapy.

Project description:Mesenchymal stem cells (MSCs) exhibit immunosuppressive properties. However the homing mechanisms underlying MSC trafficking to target tissues remain elusive. Here we report that skin-derived MSCs (S-MSCs) secrete high levels of interleukin-6 (IL-6), inhibit T helper (Th)1- and Th17-cell differentiation, and possess IL-6-dependent immunomodulatory capacity in inflammatory microenvironment. Disruption of the il6 locus or its signaling transducer gp130 blocks voltage-operated calcium (Ca2+) channels (VOCC) critically required for cell contraction involved in the sequential adhesion and de-adhesion events during S-MSC migration. IL-6 directly regulates CaV2.3 encoded by cacna1e of R-type Ca2+ channels through the JAK3/STAT3 signaling pathway. Deletion of il6 or silencing CaV2.3 gene expression leads to a severe defect in S-MSC’s homing and immunosuppressive function in vivo. Thus, this unexpected requirement of autocrine IL-6 for activating CaV2.3 Ca2+ channels uncovers a previously unrecognized link between IL-6 signaling and the VOCC, and provides novel mechanistic insights for the immunomodulatory activities of S-MSCs. A two chip study using total RNA recovered from three mixed S-MSCs derived from WT mice and three mixed S-MSCs derived from IL6KO mice.

Project description:Exosomes transport biologically active cargo (e.g., proteins and microRNA) between cells, including many of the paracrine factors that mediate the beneficial effects associated with stem-cell therapy. Stem cell derived exosomes, in particular mesenchymal stem cells (MSCs), have been shown previously to largely replicate the therapeutic activity associated with the cells themselves, which suggests that exosomes may be a useful cell-free alternative for the treatment of cardiovascular disorders. However, the mechanisms that govern how exosomes home to damaged cells and tissues or the uptake and distribution of exosomal cargo are poorly characterized, because techniques for distinguishing between exosomal proteins and proteins in the targeted tissues are lacking. Here, we report the development of an in-vivo model that enabled the visualization, tracking, and quantification of proteins from systemically administered MSC exosomes. The model uses bioorthogonal chemistry and cell-selective metabolic labeling to incorporate the noncanonical amino acid azidonorleucine (ANL) into the MSC proteome. ANL incorporation is facilitated via expression of a mutant (L274G) methionyl-tRNA-synthetase (MetRS*) and subsequent incubation with ANL-supplemented media; after which ANL can be covalently linked to alkyne-conjugated reagents (e.g., dyes, resins) via click chemistry. Our results demonstrate that when the exosomes produced by ANL-treated, MetRS*-expressing MSCs were systemically administered to mice, the ANL-labeled exosomal proteins could be accurately and reliably identified, isolated, and quantified from a variety of mouse organs, and that myocardial infarction (MI) both increased the abundance of exosomal proteins and redistributed a number of them from the membrane fraction of intact hearts to the cytosol of cells in infarcted hearts. Additionally, we found that Desmoglein-1c is enriched in MSC exosomes and taken up by ischemic myocardium. Collectively, our results indicate that this newly developed bioorthogonal system can provide crucial insights into exosome homing, as well as the uptake and biodistribution of exosomal proteins.

Project description:Exosomes transport biologically active cargo (e.g., proteins and microRNA) between cells, including many of the paracrine factors that mediate the beneficial effects associated with stem-cell therapy. Stem cell derived exosomes, in particular mesenchymal stem cells (MSCs), have been shown previously to largely replicate the therapeutic activity associated with the cells themselves, which suggests that exosomes may be a useful cell-free alternative for the treatment of cardiovascular disorders. However, the mechanisms that govern how exosomes home to damaged cells and tissues or the uptake and distribution of exosomal cargo are poorly characterized, because techniques for distinguishing between exosomal proteins and proteins in the targeted tissues are lacking. Here, we report the development of an in-vivo model that enabled the visualization, tracking, and quantification of proteins from systemically administered MSC exosomes. The model uses bioorthogonal chemistry and cell-selective metabolic labeling to incorporate the noncanonical amino acid azidonorleucine (ANL) into the MSC proteome. ANL incorporation is facilitated via expression of a mutant (L274G) methionyl-tRNA-synthetase (MetRS*) and subsequent incubation with ANL-supplemented media; after which ANL can be covalently linked to alkyne-conjugated reagents (e.g., dyes, resins) via click chemistry. Our results demonstrate that when the exosomes produced by ANL-treated, MetRS*-expressing MSCs were systemically administered to mice, the ANL-labeled exosomal proteins could be accurately and reliably identified, isolated, and quantified from a variety of mouse organs, and that myocardial infarction (MI) both increased the abundance of exosomal proteins and redistributed a number of them from the membrane fraction of intact hearts to the cytosol of cells in infarcted hearts. Additionally, we found that Desmoglein-1c is enriched in MSC exosomes and taken up by ischemic myocardium. Collectively, our results indicate that this newly developed bioorthogonal system can provide crucial insights into exosome homing, as well as the uptake and biodistribution of exosomal proteins.

Project description:Exosomes transport biologically active cargo (e.g., proteins and microRNA) between cells, including many of the paracrine factors that mediate the beneficial effects associated with stem-cell therapy. Stem cell derived exosomes, in particular mesenchymal stem cells (MSCs), have been shown previously to largely replicate the therapeutic activity associated with the cells themselves, which suggests that exosomes may be a useful cell-free alternative for the treatment of cardiovascular disorders. However, the mechanisms that govern how exosomes home to damaged cells and tissues or the uptake and distribution of exosomal cargo are poorly characterized, because techniques for distinguishing between exosomal proteins and proteins in the targeted tissues are lacking. Here, we report the development of an in-vivo model that enabled the visualization, tracking, and quantification of proteins from systemically administered MSC exosomes. The model uses bioorthogonal chemistry and cell-selective metabolic labeling to incorporate the noncanonical amino acid azidonorleucine (ANL) into the MSC proteome. ANL incorporation is facilitated via expression of a mutant (L274G) methionyl-tRNA-synthetase (MetRS*) and subsequent incubation with ANL-supplemented media; after which ANL can be covalently linked to alkyne-conjugated reagents (e.g., dyes, resins) via click chemistry. Our results demonstrate that when the exosomes produced by ANL-treated, MetRS*-expressing MSCs were systemically administered to mice, the ANL-labeled exosomal proteins could be accurately and reliably identified, isolated, and quantified from a variety of mouse organs, and that myocardial infarction (MI) both increased the abundance of exosomal proteins and redistributed a number of them from the membrane fraction of intact hearts to the cytosol of cells in infarcted hearts. Additionally, we found that Desmoglein-1c is enriched in MSC exosomes and taken up by ischemic myocardium. Collectively, our results indicate that this newly developed bioorthogonal system can provide crucial insights into exosome homing, as well as the uptake and biodistribution of exosomal proteins.

Project description:Exosomes transport biologically active cargo (e.g., proteins and microRNA) between cells, including many of the paracrine factors that mediate the beneficial effects associated with stem-cell therapy. Stem cell derived exosomes, in particular mesenchymal stem cells (MSCs), have been shown previously to largely replicate the therapeutic activity associated with the cells themselves, which suggests that exosomes may be a useful cell-free alternative for the treatment of cardiovascular disorders. However, the mechanisms that govern how exosomes home to damaged cells and tissues or the uptake and distribution of exosomal cargo are poorly characterized, because techniques for distinguishing between exosomal proteins and proteins in the targeted tissues are lacking. Here, we report the development of an in-vivo model that enabled the visualization, tracking, and quantification of proteins from systemically administered MSC exosomes. The model uses bioorthogonal chemistry and cell-selective metabolic labeling to incorporate the noncanonical amino acid azidonorleucine (ANL) into the MSC proteome. ANL incorporation is facilitated via expression of a mutant (L274G) methionyl-tRNA-synthetase (MetRS*) and subsequent incubation with ANL-supplemented media; after which ANL can be covalently linked to alkyne-conjugated reagents (e.g., dyes, resins) via click chemistry. Our results demonstrate that when the exosomes produced by ANL-treated, MetRS*-expressing MSCs were systemically administered to mice, the ANL-labeled exosomal proteins could be accurately and reliably identified, isolated, and quantified from a variety of mouse organs, and that myocardial infarction (MI) both increased the abundance of exosomal proteins and redistributed a number of them from the membrane fraction of intact hearts to the cytosol of cells in infarcted hearts. Additionally, we found that Desmoglein-1c is enriched in MSC exosomes and taken up by ischemic myocardium. Collectively, our results indicate that this newly developed bioorthogonal system can provide crucial insights into exosome homing, as well as the uptake and biodistribution of exosomal proteins.

Project description:Administration of mesenchymal stem cells (MSCs) has the potential to ameliorate degenerative disorders and to repair damaged tissues. The homing of transplanted MSCs to injured sites is a critical property of engraftment. Our aim was to identify microRNAs involved in controlling MSC proliferation and migration. MSCs can be isolated from bone marrow and umbilical cord Wharton's jelly (BM-MSCs and WJ-MSCs, respectively), and WJ-MSCs show poorer motility yet have a better amplification rate compared to BM-MSCs.

Project description:Mesenchymal stem cells (MSCs) exhibit immunosuppressive properties. However the homing mechanisms underlying MSC trafficking to target tissues remain elusive. Here we report that skin-derived MSCs (S-MSCs) secrete high levels of interleukin-6 (IL-6), inhibit T helper (Th)1- and Th17-cell differentiation, and possess IL-6-dependent immunomodulatory capacity in inflammatory microenvironment. Disruption of the il6 locus or its signaling transducer gp130 blocks voltage-operated calcium (Ca2+) channels (VOCC) critically required for cell contraction involved in the sequential adhesion and de-adhesion events during S-MSC migration. IL-6 directly regulates CaV2.3 encoded by cacna1e of R-type Ca2+ channels through the JAK3/STAT3 signaling pathway. Deletion of il6 or silencing CaV2.3 gene expression leads to a severe defect in S-MSC’s homing and immunosuppressive function in vivo. Thus, this unexpected requirement of autocrine IL-6 for activating CaV2.3 Ca2+ channels uncovers a previously unrecognized link between IL-6 signaling and the VOCC, and provides novel mechanistic insights for the immunomodulatory activities of S-MSCs.