Ewing tumors (ET) are highly malignant, localized in bone or soft tissue, and are molecularly defined by ews/ets translocations. DNA microarray analysis revealed a relationship of ET to both endothelium and fetal neural crest. We identified expression of histone methyltransferase enhancer of Zeste, Drosophila, Homolog 2 (EZH2) to be increased in ET. Suppressive activity of EZH2 maintains stemness in normal and malignant cells. Here, we found EWS/FLI1 bound to the EZH2 promoter in vivo, and induced EZH2 expression in ET and mesenchymal stem cells. Down-regulation of EZH2 by RNA interference in ET suppressed oncogenic transformation by inhibiting clonogenicity in vitro. Similarly, tumor development and metastasis was suppressed in immunodeficient Rag2 ؊/؊ ␥C ؊/؊ mice. EZH2-mediated gene silencing was shown to be dependent on histone deacetylase (HDAC) activity. Subsequent microarray analysis of EZH2 knock down, HDAC-inhibitor treatment and confirmation in independent assays revealed an undifferentiated phenotype maintained by EZH2 in ET. EZH2 regulated stemness genes such as nerve growth factor receptor (NGFR), as well as genes involved in neuroectodermal and endothelial differentiation (EMP1, EPHB2, GFAP, and GAP43). These data suggest that EZH2 might have a central role in ET pathology by shaping the oncogenicity and stem cell phenotype of this tumor.epigenetic regulation ͉ Ewing tumor ͉ stemness E wing tumors (ET) are highly malignant tumors with an approximate incidence of 3.3/10 6 in children under the age of 15. ET are characterized by early metastases, and metastatic spread is commonly hematogeneous. ET were originally described by Ewing in 1921 as endothelioma of the bone (1), and we confirmed this endothelial signature by microarray analysis (2). ET are molecularly defined by ews/ets translocations. Translocation-derived chimeric transcription factors yield transactivation, transformation, and the highly malignant phenotype. In mice, EWS/FLI1 transforms bone marrow derived or mesenchymal progenitor cells, and generates tumors (3, 4), which have features of ET. Also, inhibition of EWS/FLI1 expression may allow ET cells to recover the phenotype of their presumed mesenchymal stem cell (MSC) progenitor (5). Multipotent MSCs represent a leading candidate for primary transformation in ET. We revealed a relationship of ET to both endothelial and fetal neural crest-derived cells (2), after having demonstrated neuroectodermal histogenesis of ET in 1985 (6). Based on our recent study, we postulated in 2004 that the ET stem cell is arrested at early mesenchyme development from the neuroectodermal germ layer, and, thus, the ET stem cell is a neuronal crest-derived stem cell at transition to mesenchymal endothelial development, residing in the bone marrow. However, ectopic EWS/FLI1 expression resulted in a neural phenotype, raising the possibility that transdifferentiation or lineage promiscuity may be an alternative to the MSC histogenetic origin hypothesis of ET (7).We used high density DNA microarrays for the ident...
Background-The importance and therapeutic value of stem cells in lymphangiogenesis are poorly understood. We evaluated the potential of human and murine mesenchymal stem cells (MSCs) to acquire a lymphatic phenotype in vitro and to enhance lymphatic regeneration in vivo. Methods and Results-We assessed the lymphendothelial differentiation of human and murine MSCs after induction with supernatant derived from human dermal microvascular endothelial cells, isolated lymphatic endothelial cells, and purified vascular endothelial growth factor (VEGF)-C in vitro. We used human or murine progenitor MSC lines and then characterized the lymphatic phenotype by morphology, migratory capacity, and the expression of lymphatic markers such as Prox-1, podoplanin, Lyve-1, VEGF receptor-2, and VEGF receptor-3. Using a murine lymphatic edema model, we assessed the potential of these cells to form a functional lymphatic vasculature in vivo after injection of syngeneic MSCs. Incubation with supernatant from lymphatic endothelial cells induced an endothelium-like morphology and the expression of lymphendothelial markers in both human and murine MSCs in vitro. MSCs showed migratory activity along a VEGF-C gradient, which was enhanced by VEGF-C conditioning. In vivo, the local application of MSCs resulted in a significant decrease in edema formation (Ϫ20.1%; PϽ0.01 versus untreated tails) after 3 weekly cell injections and restored the drainage of intradermally injected methylene blue after 7 weekly injections. Conclusions-MSCs
© Ferrata Storti Foundation IntroductionSince the first clinical trial of mesenchymal stromal cells (MSC) 9,10 Another important issue regarding the clinical application of MSCs is their culture under serum-free conditions. The majority of clinical studies have used MSCs that were expanded in media supplemented with fetal bovine serum (FBS). 1,[11][12][13][14][15] To avoid the risks associated with the use of FBS, 16 platelet lysate (PL) was proposed as a supplement to tissue culture media for MSCs. 17 Recently, several studies showed that MSCs that were expanded in PL exhibited the same efficacy as MSCs cultured in serum-containing media for the treatment of GvHD. 18-22To date, clinical studies have used MSCs that have been generated from several individual donors. Considering the aforementioned inter-donor heterogeneity and the need for a large number of "off-the-shelf" MSCs, the establishment of MSC banks appears to be an indispensable strategy for providing a continuous supply of MSCs with predictable potency. To our knowledge, there are few established MSC banks worldwide, and these MSC banks were generated by separately isolating, expanding, and freezing MSCs from up to 10 donors in FBS-containing media. [23][24][25][26] In the current study, we report for the first time the establishment of a serum-free and GMP-compliant MSC bank generated from pooled bone marrow mononuclear cells (BM-MNCs) of multiple donors as a novel strategy to circumvent donor-to-donor variability. Clinical-grade MSC endproducts (MEPs) derived from the MSC bank were thoroughly assessed for their proliferation, differentiation, and, in particular, for the allosuppressive potential in vitro. Importantly, 81 MEPs were administered as a rescue therapy to 26 pediatric patients with severe steroid-refractory aGvHD in seven transplantation centers. Safety and efficacy of MEPs was compared to MSCs generated from a single or several individual donors that have been used in the GvHDclinical studies reported thus far. Methods Generation of MSC bank and clinical-grade MEPsBone marrow was collected from 8 healthy volunteers (age 21-45 years old) after written informed consent and after the approval of the local Ethics Committee (n. 275/09). BM-MNCs were enriched from the bone marrow aspirate by using the Sepax II NeatCell process (Biosafe, Eysins, Switzerland) and frozen individually. After thawing and washing these BM-MNCs were pooled. This pool of BM-MNCs from 8 donors was used to generate MSCs over 14 days in culture. After their detachment, passage 1 mesenchymal stromal cells (MSC-P1) were washed and aliquoted into 209 cryovials (each containing 1.5x10 6 MSC-P1). Cryopreserved vials with MSC-P1 were referred to as the MSC bank.To generate clinical-grade MEPs, MSC-P1 aliquots from the MSC bank were thawed and after washing they were expanded in medium containing 10% PL till the end of passage 2. These MSCs were re-suspended in cryomedium (0.9% NaCl containing 5% HSA and 10% DMSO), distributed in cryobags (each containing 1-3x10 6 MS...
In summary, our results imply that ES-derived exosomes could eventually serve as biomarkers for minimal residual disease diagnostics in peripheral blood and prompt further investigation of their potential biological role in modification of the ES-associated microenvironment
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