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BACKGROUND: Mesenchymal stromal cells (MSC) have been proven to have potent immunosuppressive action and hence have been proposed for the treatment of severe Graft Versus Host Disease. However,in most models,MSC were added at the same time of lymphocyte stimulation,which is quite different from what occurs in vivo. AIMS: To investigate how the timing of lymphocyte activation and the exposure to activation-related cytokines (licensing) can influence the immunosuppressive action of Wharton's jelly stromal cells (WJSC). METHODS: WJSC,licensed or not with activation-related cytokines,were added lymphocytes the same time or 24 hours after their stimulation with phytohaemoagglutinin. Proliferation of lymphocytes and cytokines production was measured after three days co-culture. RESULTS: Lymphocytes stimulated in the presence of WJSC displayed a dramatic decrease in proliferation and production of cytokines,in spite of normal expression of activation markers. The suppression was weakened when targeted lymphocytes were seperated by a membrane and partially rescued by the addition of exogenous l-tryptophan,suggesting a major role for indoleamine 2,3-dioxigenase with a probable paracrine effect. Licensing of WJSC increased the immunosuppressive effect,in both contact and non-contact settings. The timing of WJSC licensing was crucial for the immunosuppressive action. Lymphocytes pre-stimulated alone for 24 h,and added afterwards to non-licensed WJSC,showed normal or even increased proliferation. On the other hand,their proliferation was strongly inhibited by licensed WJSC. CONCLUSIONS: WJSC have a potent immunosuppressive function best realized with direct contact,and increased by licensing signals before and during lymphocyte stimulation. Our results could contribute to the set up of new WJSC-based therapies for severe autoimmuno disorders. View Publication

Bone marrow-derived mesenchymal stem cells (BM-MSCs) can be induced to differentiate into myogenic cells. Despite their potential,previous studies have not been successful in producing a high percentage of cardiac-like cells with a muscle phenotype. We hypothesized that cardiac lineage development in BM-MSC is related to cell passage,culture milieu,and enrichment for specific cell subtypes before and during differentiation. Our study demonstrated that Lin(-) BM-MSC at an intermediate passage (IP; P8-P12) expressed cardiac troponin T (cTnT) after 21 days in culture. Cardiac TnT expression was similar whether IP cells were differentiated in media containing 5-azacytidine+2% FBS (AZA; 14%) or 2% FBS alone (LS; 12%) and both were significantly higher than AZA+5% FBS. This expression was potentiated by first enriching for CD117/Sca-1 cells followed by differentiation (AZA,39% and LS,28%). A second sequential enrichment for the dihydropyridine receptor subunit alpha2delta1 (DHPR-alpha2) resulted in cardiac TnT expressed in 54% of cultured cells compared to 28% of cells after CD117/Sca-1(+) enrichment. Cells enriched for CD117/Sca-1 and subjected to differentiation displayed spontaneous intracellular Ca(2+) transients with an increase in transient frequency and a 60% decrease in the transient duration amplitude between days 14 and 29. In conclusion,IP CD117/Sca-1(+) murine BM-MSCs display robust cardiac muscle lineage development that can be induced independent of AZA but is diminished under higher serum concentrations. Furthermore,temporal changes in calcium kinetics commensurate with increased cTnT expression suggest progressive maturation of a cardiac muscle lineage. Enrichment with CD117/Sca-1 to establish lineage commitment followed by DHPR-alpha2 in lineage developing cells may enhance the therapeutic potential of these cells for transplantation. View Publication

There has been a great deal of scientific interest recently generated by the potential therapeutic applications of adult stem cells in human care but there are several challenges regarding quality and safety in clinical applications and a number of these challenges relate to the processing and banking of these cells ex-vivo. As the number of clinical trials and the variety of adult cells used in regenerative therapy increases,safety remains a primary concern. This has inspired many nations to formulate guidelines and standards for the quality of stem cell collection,processing,testing,banking,packaging and distribution. Clinically applicable cryopreservation and banking of adult stem cells offers unique opportunities to advance the potential uses and widespread implementation of these cells in clinical applications. Most current cryopreservation protocols include animal serum proteins and potentially toxic cryoprotectant additives (CPAs) that prevent direct use of these cells in human therapeutic applications. Long term cryopreservation of adult stem cells under good manufacturing conditions using animal product free solutions is critical to the widespread clinical implementation of ex-vivo adult stem cell therapies. Furthermore,to avoid any potential cryoprotectant related complications,reduced CPA concentrations and efficient post-thaw washing to remove CPA are also desirable. The present review focuses on the current strategies and important aspects of adult stem cell banking for clinical applications. These include current good manufacturing practices (cGMPs),animal protein free freezing solutions,cryoprotectants,freezing & thawing protocols,viability assays,packaging and distribution. The importance and benefits of banking clinical grade adult stem cells are also discussed. View Publication

We report an injectable hydrogel scaffold system with tunable stiffness for controlling the proliferation rate and differentiation of human mesenchymal stem cells (hMSCs) in a three-dimensional (3D) context in normal growth media. The hydrogels composed of gelatin-hydroxyphenylpropionic acid (Gtn-HPA) conjugate were formed using the oxidative coupling of HPA moieties catalyzed by hydrogen peroxide (H(2)O(2)) and horseradish peroxidase (HRP). The stiffness of the hydrogels was readily tuned by varying the H(2)O(2) concentration without changing the concentration of polymer precursor. We found that the hydrogel stiffness strongly affected the cell proliferation rates. The rate of hMSC proliferation increased with the decrease in the stiffness of the hydrogel. Also,the neurogenesis of hMSCs was controlled by the hydrogel stiffness in a 3D context without the use of any additional biochemical signal. These cells which were cultured in hydrogels with lower stiffness for 3 weeks expressed much more neuronal protein markers compared to those cultured within stiffer hydrogels for the same period of time. View Publication

Chondrogenesis of mesenchymal stem cells (MSCs) is typically induced when they are condensed into a single aggregate and exposed to transforming growth factor-beta (TGF-beta). Hypoxia,like aggregation and TGF-beta delivery,may be crucial for complete chondrogenesis. However,the pellet dimensions and associated self-induced oxygen gradients of current chondrogenic methods may limit the effectiveness of in vitro differentiation and subsequent therapeutic uses. Here we describe the use of embryoid body-forming technology to produce microscopic aggregates of human bone marrow MSCs (BM-MSCs) for chondrogenesis. The use of micropellets reduces the formation of gradients within the aggregates,resulting in a more homogeneous and controlled microenvironment. These micropellet cultures (approximately 170 cells/micropellet) as well as conventional pellet cultures (approximately 2 x 10(5) cells/pellet) were chondrogenically induced under 20% and 2% oxygen environments for 14 days. Compared to conventional pellets under both environments,micropellets differentiated under 2% O(2) showed significantly increased sulfated glycosaminoglycan (sGAG) production and more homogeneous distribution of proteoglycans and collagen II. Aggrecan and collagen II gene expressions were increased in pellet cultures differentiated under 2% O(2) relative to 20% O(2) pellets but 2% O(2) micropellets showed even greater increases in these genes,as well as increased SOX9. These results suggest a more advanced stage of chondrogenesis in the micropellets accompanied by more homogeneous differentiation. Thus,we present a new method for enhancing MSC chondrogenesis that reveals a unique relationship between oxygen tension and aggregate size. The inherent advantages of chondrogenic micropellets over a single macroscopic aggregate should allow for easy integration with a variety of cartilage engineering strategies. View Publication

RATIONALE: Studies have demonstrated that bone marrow-derived cells can be recruited to injured lungs through an unknown mechanism. We hypothesize that marrow progenitors are mobilized into the circulation of patients with cardiac and/or respiratory failure,and may then traffic to and incorporate into the sites of tissue injury. OBJECTIVES: To determine whether progenitor populations are increased in the blood of patients with severe acute cardiorespiratory failure placed on extracorporeal membrane oxygenation (ECMO). METHODS: Mononuclear cells from ECMO,umbilical cord,and control blood samples were evaluated in colony-forming assays for hematopoietic,mesenchymal,and epithelial cells. Progenitors were identified by proliferative and differentiative capacities,and confirmed by the expression of lineage-specific markers. MEASUREMENTS AND MAIN RESULTS: Significantly higher levels of hematopoietic progenitors were observed in ECMO (n = 41) samples than neonatal intensive care unit (n = 16) or pediatric intensive care unit controls (n = 14). Hematopoietic progenitor mobilization increased with time on ECMO support. Mesenchymal progenitors (MSC) were recovered from 18/58 ECMO samples with rapid sample processing (textless 4 h) critical to their recovery. MSC were not recovered from normal controls. ECMO-derived MSC had osteogenic,chondrogenic,and adipogenic differentiation potential. The recovery of MSC did not influence survival outcome (61%). Epithelial progenitors were observed in eight ECMO samples but not in control samples. Their presence was associated with a lower survival trend (38%). CONCLUSIONS: Hematopoietic,mesenchymal,and epithelial progenitors were mobilized into the circulation of patients on ECMO. This may reflect a response to severe cardiopulmonary injury,blood-foreign surface interactions with the ECMO circuit,and/or hemodilution. View Publication

We observed that BMSCs (bone marrow stromal cells) from myeloma patients (myeloma BMSCs) were significantly stiffer than control BMSCs using a cytocompression device. The stiffness of myeloma BMSCs and control BMSCs was further increased upon priming by myeloma cells. Additionally,myeloma cells became stiffer when primed by myeloma BMSCs. The focal adhesion kinase activity of myeloma cells was increased when cells were on stiffer collagen gels and on myeloma BMSCs. This change in myeloma stiffness is associated with increased colony formation of myeloma cells and FAK activation when co-cultured with stiffer myeloma BMSCs or stiffer collagen. Additionally,stem cells of RPMI8226 cells became stiffer after priming by myeloma BMSCs,with concomitant increases of stem cell colony formation. These results suggest the presence of a mechanotransduction loop between myeloma cells and myeloma BMSCs to increase the stiffness of both types of cells via FAK activation. The increase of stiffness may in turn support the growth of myeloma cells and myeloma stem cells. View Publication

OBJECTIVE: Bone marrow-derived mononuclear cells (BMCs) improve the functional recovery after ischemia. However,BMCs comprise a heterogeneous mixture of cells,and it is not known which cell types are responsible for the induction of neovascularization after cell therapy. Because cell recruitment is critically dependent on the expression of the SDF-1-receptor CXCR4,we examined whether the expression of CXCR4 may identify a therapeutically active population of BMCs. METHODS AND RESULTS: Human CXCR4(+) and CXCR4(-) BMCs were sorted by magnetic beads. CXCR4(+) BMCs showed a significantly higher invasion capacity under basal conditions and after SDF-1 stimulation. Hematopoietic or mesenchymal colony-forming capacity did not differ between CXCR4(+) and CXCR4(-) BMCs. Injection of CXCR4(+) BMCs in mice after induction of hindlimb ischemia significantly improved the recovery of perfusion compared to injection of CXCR4(-) BMCs. Likewise,capillary density was significantly increased in CXCR4(+) BMC-treated mice. Because part of the beneficial effects of cell therapy were attributed to the release of paracrine effectors,we analyzed BMC supernatants for secreted factors. Importantly,supernatants of CXCR4(+) BMCs were enriched in the proangiogenic cytokines HGF and PDGF-BB. CONCLUSIONS: CXCR4(+) BMCs exhibit an increased therapeutic potential for blood flow recovery after acute ischemia. Mechanistically,their higher migratory capacity and their increased release of paracrine factors may contribute to enhanced tissue repair. View Publication

Mammalian cells generally require both mitogens and anchorage signals in order to proliferate. An important characteristic of many tumour cells is that they have lost this anchorage-dependent cell-cycle checkpoint,allowing them to proliferate without signals provided by their normal microenvironment. In the absence of anchorage signals from the extracellular matrix,many cell types arrest cell-cycle progression in G1 phase as a result of Rb-dependent checkpoints. However,despite inactivation of p53 and Rb proteins,SV40LT-expressing cells retain anchorage dependency,suggesting the presence of an uncharacterised cell-cycle checkpoint,which can be overridden by coexpression of oncogenic Ras. We report here that,although cyclin-CDK complexes persisted in suspension,proliferation was inhibited in LT-expressing cells by the CDK inhibitor p27(Kip1) (p27). Interestingly,this did not induce a stable arrest,but aberrant cell-cycle progression associated with stalled DNA replication,rereplication and chromosomal instability,which was sufficient to increase the frequency of oncogenic transformation. These results firstly indicate loss of anchorage in Rb- and p53-deficient cells as a novel mechanism for promotion of genomic instability; secondly suggest that anchorage checkpoints that protect normal cells from inappropriate proliferation act deleteriously in Rb- and p53-deficient cells to promote tumourigenesis; and thirdly indicate caution in the use of CDK inhibitors for cancer treatment. View Publication

Mesenchymal stem cells (MSC) have been extensively studied and gained wide popularity due to their therapeutic potential. Spontaneous transformation of MSC,from both human and murine origin,has been reported in many studies. MSC transformation depends on the culture conditions,the origin of the cells and the time on culture; however,the precise biological characteristics involved in this process have not been fully defined yet. In this study,we investigated the role of p53 in the biology and transformation of murine bone marrow (BM)-derived MSC. We demonstrate that the MSC derived from p53KO mice showed an augmented proliferation rate,a shorter doubling time and also morphologic and phenotypic changes,as compared to MSC derived from wild-type animals. Furthermore,the MSC devoid of p53 had an increased number of cells able to generate colonies. In addition,not only proliferation but also MSC differentiation is controlled by p53 since its absence modifies the speed of the process. Moreover,genomic instability,changes in the expression of c-myc and anchorage independent growth were also observed in p53KO MSC. In addition,the absence of p53 implicates the spontaneous transformation of MSC in long-term cultures. Our results reveal that p53 plays a central role in the biology of MSC. View Publication

Cell-matrix interactions are paramount for the successful repair and regeneration of damaged and diseased tissue. Since many tissues have an anisotropic architecture,it has been proposed that aligned extracellular matrix (ECM) structures in particular could guide and support the differentiation of resident mesenchymal stem and progenitor cells (MSCs). We therefore created aligned collagen type I structures using a microfluidic set-up with the aim to assess their impact on MSC growth and differentiation. In addition,we refined our aligned collagen matrices by incorporating the glycosaminoglycan (GAG) heparin to demonstrate the versatility of the applied methodology to study multiple ECM components in a single system. Our reconstituted,aligned ECM structures maintained and allowed multilineage (osteogenic/adipogenic/chondrogenic) differentiation of MSCs. Most noticeable was the observation that during osteogenesis,aligned collagen substrates choreographed ordered matrix mineralization. Likewise,myotube assembly of C2C12 cells was profoundly influenced by aligned topographic features resulting in enhanced myotube organization and length. Our results shed light on the regulation of MSCs through directional ECM structures and demonstrate the versatility of these cell culture platforms for guiding the morphogenesis of tissue types with anisotropic structures. View Publication

Implantation of tissue engineering constructs is a promising technique to reconstruct injured tissue. However,after implantation the nutrition of the constructs is predominantly restricted to vascularization. Since cells possess distinct angiogenic potency,we herein assessed whether scaffold vitalization with different cell types improves scaffold vascularization. 32 male balb/c mice received a dorsal skinfold chamber. Angiogenesis,microhemodynamics,leukocyte-endothelial cell interaction and microvascular permeability induced in the host tissue after implantation of either collagen coated poly (L-lactide-co-glycolide) (PLGA) scaffolds (group 4),additionally seeded with osteoblast-like cells (OLCs,group 1),bone marrow mesenchymal stem cells (bmMSCs,group 2) or a combination of OLCs and bmMSCs (group 3) were analyzed repetitively over 14 days using intravital fluorescence microscopy. Apart from a weak inflammatory response in all groups,vascularization was found distinctly accelerated in vitalized scaffolds,indicated by a significantly increased microvascular density (day 6,group 1: 202+/-15 cm/cm(2),group 2: 202+/-12 cm/cm(2),group 3: 194+/-8 cm/cm(2)),when compared with controls (group 4: 72+/-5 cm/cm(2)). This acceleration was independent from the seeded cell type. Immunohistochemistry revealed in vivo VEGF expression in close vicinity to the seeded OLCs and bmMSCs. Therefore,the observed lack of cell type confined differences in the vascularization process suggests that the accelerated vascularization of vitalized scaffolds is VEGF-related rather than dependent on the potential of bmMSCs to differentiate into specific vascular cells. View Publication