Paula Hansen

Dissimilar Differentiation of Mesenchymal Stem Cells from Bone Marrow, Umbilical Cord Blood, and Adipose Tissue:

Mesenchymal stem cells (MSCs) have been investigated as promising candidates for use in new cell-based therapeutic strategies such as mesenchyme-derived tissue repair. MSCs are easily isolated from adult tissues and are not ethically restricted. MSC-related literature, however, is conflicting in relation to MSC differentiation potential and molecular markers. Here we compared MSCs isolated from bone marrow (BM), umbilical cord blood (UCB), and adipose tissue (AT). The isolation efficiency for both BM and AT was 100%, but that from UCB was only 30%. MSCs from these tissues are morphologically and immunophenotypically similar although their differentiation diverges. Differentiation to osteoblasts and chondroblasts was similar among MSCs from all sources, as analyzed by cytochemistry. Adipogenic differentiation showed that UCB-derived MSCs produced few and small lipid vacuoles in contrast to those of BM-derived MSCs and AT-derived stem cells (ADSCs) (arbitrary differentiation values of 245.57 ± 943 and 243.89 ± 145.52 μm2 per nucleus, respectively). The mean area occupied by individual lipid droplets was 7.37 μm2 for BM-derived MSCs and 2.36 μm2 for ADSCs, a finding indicating more mature adipocytes in BM-derived MSCs than in treated cultures of ADSCs. We analyzed FAPB4, ALP, and type II collagen gene expression by quantitative polymerase chain reaction to confirm adipogenic, osteogenic, and chondrogenic differentiation, respectively. Results showed that all three sources presented a similar capacity for chondrogenic and osteogenic differentiation and they differed in their adipogenic potential. Therefore, it may be crucial to predetermine the most appropriate MSC source for future clinical applications.

Are purified or expanded cord blood-derived CD133+ cells better at improving cardiac function?

Endothelial progenitor cells (EPCs), which express the CD133 marker, can differentiate into mature endothelial cells (ECs) and create new blood vessels. Normal angiogenesis is unable to repair the injured tissues that result from myocardial infarction (MI). Patients who have high cardiovascular risks have fewer EPCs and their EPCs exhibit greater in vitro senescence. Human umbilical cord blood (HUCB)-derived EPCs could be an alternative to rescue impaired stem cell function in the sick and elderly. The aim of this study was to purify HUCB-derived CD133+ cells, expand them in vitro and evaluate the efficacy of the purified and expanded cells in treating MI in rats. CD133+ cells were selected for using CD133-coupled magnetic microbeads. Purified cells stained positive for EPC markers. The cells were expanded and differentiated in media supplemented with fetal calf serum and basic fibroblast growth factor, insulin-like growth factor-I and vascular endothelial growth factor (VEGF). Differentiation was confirmed by lack of staining for EPC markers. These expanded cells exhibited increased expression of mature EC markers and formed tubule-like structures in vitro. Only the expanded cells expressed VEGF mRNA. Cells were expanded up to 70-fold during 60 days of culture, and they retained their functional activity. Finally, we evaluated the therapeutic potential of purified and expanded CD133+ cells in treating MI by intramyocardially injecting them into a rat model of MI. Rats were divided into three groups: A (purified CD133+ cells-injected); B (expanded CD133+ cells-injected) and C (saline buffer-injected). We observed a significant improvement in left ventricular ejection fraction for groups A and B. In summary, CD133+ cells can be purified from HUCB, expanded in vitro without loosing their biological activity, and both purified and expanded cells show promising results for use in cellular cardiomyoplasty. However, further pre-clinical testing should be performed to determine whether expanded CD133+ cells have any clinical advantages over purified CD133+ cells.

Comparison of mononuclear and mesenchymal stem cell transplantation in myocardium infarction

Background: Bone marrow stem cell (SC) transplantation into failing myocardium has emerged as a novel therapeutic option for the treatment of ventricular dysfunction. Both mononuclear (MoSC) and mesenchymal (MeSC) stem cells have been proposed as ideal cell types to this goal. The objective of this study is to compare the efficacy of these cells in improving ventricular function in a rat model of postinfarct ventricular dysfunction. Method: Myocardial infarction was induced in Wistar rats by left coronary occlusion. After 1 week, 42 animals with resulting ejection fractions (EF) lower than 30% were included in the study. MoSC and MeSC were obtained from bone marrow aspirates and separated by the Ficoll-Hypaque method. MeSC were cultured for 14 days before injection. Nine days after infarction, rats received intramyocardial injections of MoSC (n=8), MeSC (n=13) or culture medium as a control (n=21). Echocardiographic evaluation was performed at baseline and after one month. Results: There were no significant differences in the baseline ejection fractions or the left ventricular end diastolic volumes (LVEDV) between all groups. After 1 month, ejection fraction decreased in the Control Group and remained unchanged in MoSC and MeSC Groups. In all three groups ventricular dilation was observed. Histopathology of the infarcted area where injections were performed identified new smooth muscle cells and endothelial cells in the MeSC Group and only new endothelial cells in MoSC Group Conclusions: Both MoSC and MeSC provided stabilization in the ejection fraction in this post-infarction ventricular dysfunction model however, no therapy prevented ventricular dilation.

Expression of cardiac function genes in adult stem cells is increased by treatment with nitric oxide agents.

Mesenchymal stem cells (MSCs) have received special attention for cardiomyoplasty because several studies have shown that they differentiate into cardiomyocytes both in vitro and in vivo. Nitric oxide (NO) is a free radical signaling molecule that regulates several differentiation processes including cardiomyogenesis. Here, we report an investigation of the effects of two NO agents (SNAP and DEA/NO), able to activate both cGMP-dependent and -independent pathways, on the cardiomyogenic potential of bone marrow-derived mesenchymal stem cells (BM-MSCs) and adipose tissue-derived stem cells (ADSCs). The cells were isolated, cultured and treated with NO agents. Cardiac- and muscle-specific gene expression was analyzed by indirect immunofluorescence, flow cytometry, RT-PCR and real-time PCR. We found that untreated (control) ADSCs and BM-MSCs expressed some muscle markers and NO-derived intermediates induce an increased expression of some cardiac function genes in BM-MSCs and ADSCs. Moreover, NO agents considerably increased the pro-angiogenic potential mostly of BM-MSCs as determined by VEGF mRNA levels.

Human cardiac explant-conditioned medium: soluble factors and cardiomyogenic effect on mesenchymal stem cells.

The use of conditioned medium (CM) from human cardiac explants (HCEs) as a potential source of paracrine factors for adult stem cell signaling has never been evaluated. We hypothesized that HCEs might provide a source of soluble factors triggering the differentiation of mesenchymal stem cells (MSCs) into cardiomyocyte-like cells. By using two-dimensional electrophoresis (2-DE) gels/mass spectrometry and antibody macroarray assays, we found that HCEs release macromolecules, including cytokines, growth factors and myocardial and metabolism-related proteins into the culture medium. We identified a total of 20 proteins in the HCE-CM. However, as shown by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and 2-DE, these 20 proteins account for only a fraction of the total number of proteins present in the HCE-CM. We also found that CM increased the proliferation of bone marrow-derived-MSCs (BM-MSCs) in vitro. Unlike the other effects, this effect was most evident after 48 h of culture. Moreover, we examined the effect of HCE-CM on levels of mRNA and protein for specific cardiac markers. We showed that a surprisingly big fraction of BM-MSCs (3.4–5.0%) treated in vitro with HCE-CM became elongated and began to express cardiac markers, consistent with their possible differentiation into cardiomyocyte-like cells. Our in vitro model may be useful not only per se, but also for studies of the mechanisms of action of soluble factors involved in cell differentiation, paving the way for possible new protein-based treatments in the future.

O transplante em conjunto de células mioblásticas esqueléticas e mesenquimais (cocultivadas) na disfunção ventricular pós-infarto do miocárdio

OBJECTIVE: Cell therapy in the myocardium has been mainly performed with satisfactory results using 2 cell types: skeletal myoblasts (myogenic) and mesenchymal cells (angiogenic). This study assessed the combined transplantation of those 2 cell types (SMM) into infarcted rats. METHODS: Myocardial infarction was induced by ligature of the left coronary artery in 26 Wistar rats. After one week, the animals underwent echocardiography for assessing ejection fraction (EF%) and left ventricular end-diastolic and systolic volumes (EDV, ESV, mL). After 2 days, the animals were reoperated on and divided into 2 groups: 1) control (n=10), which received 0.15 mL of culture medium; and 2) SMM (n=16), which received 7.5x106 heterologous skeletal myoblasts and mesenchymal cells in the infarcted region. The cells were obtained from puncture of the iliac crest and biopsy of skeletal muscle, and were cultured in vitro. After one month, the animals underwent a new echocardiography. RESULTS: No significant difference in EF, EDV, and ESV was observed between the 2 groups on baseline echocardiographic values. One month after transplantation, the following was observed: a reduction in EF in the control group (29.31 ± 5.6% to 23.54 ± 6.51%; P=0.048); and an increase in EF in the SMM group (24.03 ± 8.68% to 31.77 ± 9.06%; P=0.011). The presence of neovascularization and muscle fibers was identified in the regions of myocardial fibrosis in the SMM group. CONCLUSION: Cocultivation of skeletal myoblasts and mesenchymal cells is functionally effective.

In vitro formation of capillary tubules from human umbilical cord blood cells with perspectives for therapeutic application

OBJECTIVE Endothelial progenitor cells (EPC) characterized by the CD133+ marker, contribute to the neovascularization. Increasing EPC number in vitro could be a promising therapeutic tool. Human umbilical cord blood maintains a significant number of EPC, suggesting the possibility to use these cells to induce the revascularization of ischemic tissues. The aim of this study was to analyze the in vitro function of differentiated CD133+ cells. METHODS Cells were characterized by flow cytometry, VEGF mRNA expression was evaluated by the RT-PCR analysis and the functionally by essays of capillary tubes formation. RESULTS Differentiated cells lost EPC markers, maintained low levels of markers for hematopoietic and monocytic cell lines and increased the expression of adult endothelial cell markers. Differentiated cells expressed VEGF mRNA and were capable to induce in vitro capillary tubules formation. CONCLUSION CD133+ cells differentiated into endothelial cells in vitro are functionally active initiating the possibility of their use in future therapeutic applications.

Cellular transplant: functional, immunocytochemical and histopathologic analysis in an experimental model of ischemic heat disease using different cells

OBJECTIVE: To present the functional, immunocytochemical and histopathologic results (in vitro or in heart specimens) after isolation, culture and co-culture of mesenchymal stem cells and skeletal myoblast cells transplanted and co-transplanted in experimental animals with ischemic heart disease and left ventricular ejection fractions lower than 40%. METHOD: We utilized 72 Wistar rats, divided into four groups according to the culture media or injected cells: control group into which only culture media was injected (22 rats); mesenchymal stem cell group (17 rats); myoblast skeletal cell group (16 rats) and co-culture group (17 rats). In the immunohistochemical studies, the cells were stained with anti-vimentin, anti-desmin and anti-myosin. In the histopathologic analysis, slides were stained with Gomori Trichrome, and neo-vessels and muscle tissues were identified. In the functional analysis the left ventricle ejection fraction was analyzed one week after myocardial infarction and one month after the injection. RESULTS: The initial left ventricle ejection fraction (control echo) was not statistically significant between the four groups (P=0.276), but was significantly different in the follow-up examination (P=0.001). This difference was seen between the control and the myoblast skeletal cells groups (P=0.037), between the control and the co-culture groups (P<0.001), and between the mesenchymal stem cell and co-culture groups (P=0.025). When the initial and final echocardiograms in each group were compared, the control group deteriorated (P=0.005) and the co-culture group improved (P=0.006). With the immunocytochemical in vitro analysis, mesenchymal stem cells were identified when stained with anti-vimentin and muscle cells when stained with anti-desmin. In the heart specimens, muscle tissue, stained with anti-desmin and skeletal myoblasts cells, stained with fast anti-miosin were identified. In the histopathologic analysis, new vessels were observed in the mesenchymal stem cell and skeletal myoblast groups, and muscular tissue, angiogenesis and myogenesis in the co-culture group. CONCLUSION: The left ventricle ejection fraction improved in the group in which muscle cells were injected and more strikingly in the co-culture group. The immunohistochemical findings in the culture and co-culture groups evidenced the corresponding cells. In the heart specimens, muscle and skeletal myoblast cells were found. In the histopathologic examination, new vessels and muscle tissue were found in the mesenchymal stem cell, skeletal myoblast cell and co-culture groups.