Human dental mesenchymal stem cells and neural regeneration

Nerve tissue presents inherent difficulties for its effective regeneration. Stem cell transplantation is considered an auspicious treatment for neuronal injuries. Recently, human dental mesenchymal stem cells (DMSCs) have received extensive attention in the field of regenerative medicine due to their accessibility and multipotency. Since their origin is within the neural crest, they can be differentiated into neural crest-derived cells including neuron and glia cells both in vitro and in vivo. DMSCs are also able to secrete a wide variety of neurotrophins and chemokines, which promote neuronal cells to survival and differentiation. Experimental evidence has shown that human DMSCs engraftment recovered neuronal tissue damage in animal models of central nervous system injuries. Human DMSCs can be a new hope for treatment of nervous system diseases and deficits such as spinal cord injury, stroke and Parkinson’s disease.     

Human gingiva-derived mesenchymal stem cells are superior to bone marrow-derived mesenchymal stem cells for cell therapy in regenerative medicine

Mesenchymal stem cells (MSCs) are capable of self-renewal and differentiation into multiple cell lineages. Presently, bone marrow is considered as a prime source of MSCs; however, there are some drawbacks and limitations in use of these MSCs for cell therapy. In this study, we demonstrate that human gingival tissue-derived MSCs have several advantages over bone marrow-derived MSCs. Gingival MSCs are easy to isolate, homogenous and proliferate faster than bone marrow MSCs without any growth factor. Importantly, gingival MSCs display stable morphology and do not loose MSC characteristic at higher passages. In addition, gingival MSCs maintain normal karyotype and telomerase activity in long-term cultures, and are not tumorigenic. Thus, we reveal that human gingiva is a better source of MSCs than bone marrow, and large number of functionally competent clinical grade MSCs can be generated in short duration for cell therapy in regenerative medicine and tissue engineering.     

Human bone marrow-derived mesenchymal stem cells differentiate into epidermal-like cells in vitro

Human bone marrow-derived mesenchymal stem cells (hMSCs) are a population of pluripotent cells. They can differentiate into different embryonic layer cells as osteoblasts, adipocytes, chondrocytes, myoblasts, neurocytes, etc. However, there are only few reports with regard to differentiate hMSCs into epidermal cells in vitro. In this study, we want to investigate the feasibility of inducing hMSCs into epidermal-like cells under specific medium in vitro. hMSCs in specific inducing medium expressed the early markers of epidermal cell lineage, P63, cytokeratin19 (CK19), the late differentiated marker, the pan-cytokeratin, and another early marker, the beta1-integrin, which up-regulated remarkably in inducing medium. Their morphologies were changed from spindle-like fibroblastic appearances to oblate or irregular shapes under phase contrast microscopy. The hemidesmosome structure was found using the transmission electron microscope. All these data suggested that, under certain conditions, hMSCs have the potential to differentiate into epidermal-like cells. It will be of great accordance in the study of the multipotential property of hMSCs.     

Human bone marrow-derived stem cells acquire epithelial characteristics through fusion with gastrointestinal epithelial cells

Bone marrow-derived mesenchymal stem cells (MSC) have the ability to differentiate into a variety of cell types and are a potential source for epithelial tissue repair. Several studies have demonstrated their ability to repopulate the gastrointestinal tract (GIT) in bone marrow transplanted patients or in animal models of gastrointestinal carcinogenesis where they were the source of epithelial cancers. However, mechanism of MSC epithelial differentiation still remains unclear and controversial with trans-differentiation or fusion events being evoked. This study aimed to investigate the ability of MSC to acquire epithelial characteristics in the particular context of the gastrointestinal epithelium and to evaluate the role of cell fusion in this process. In vitro coculture experiments were performed with three gastrointestinal epithelial cell lines and MSC originating from two patients. After an 8 day coculture, MSC expressed epithelial markers. Use of a semi-permeable insert did not reproduce this effect, suggesting importance of cell contacts. Tagged cells coculture or FISH on gender-mismatched cells revealed clearly that epithelial differentiation resulted from cellular fusion events, while expression of mesenchymal markers on fused cells decreased over time. In vivo cell xenograft in immunodeficient mice confirmed fusion of MSC with gastrointestinal epithelial cells and self-renewal abilities of these fused cells. In conclusion, our results indicate that fusion could be the predominant mechanism by which human MSC may acquire epithelial characteristics when in close contact with epithelial cells from gastrointestinal origin . These results could contribute to a better understanding of the cellular and molecular mechanisms allowing MSC engraftment into the GIT epithelium.     

Expansion of human bone marrow-derived mesenchymal stromal cells: serum-reduced medium is better than conventional medium

Background aimsHuman mesenchymal stromal cells (hMSC) are of enormous interest for various clinical applications. For the expansion of isolated hMSC to relevant numbers for clinical applications, 10% fetal bovine serum (FBS)-supplemented medium is commonly used. The main critical disadvantage of FBS is the possibility of transmission of infectious agents as well as the possibility of immune rejection of the transplanted cells in response to the bovine serum. Therefore, we tested a commercially available medium, Panserin 401, that was specifically developed for serum-free cell cultivation.MethodshMSC were isolated from bone marrow (BM) and expanded in either Dulbecco's modified Eagle medium (DMEM) or Panserin 401 alone, or combined with FBS (2% or 10%), with or without supplementary growth factors. Cell proliferation and cytotoxicity were monitored twice a week for 3 weeks.Results and ConclusionsNo proliferation was observed in any of the serum-free media. However, DMEM/10% FBS (the conventional culture medium for hMSC) and DMEM/2% FBS with growth factors revealed moderate proliferation. Interestingly, the best proliferation was obtained using Panserin 401 supplemented with 2% FBS and growth factors (as well as with 10% FBS). Analysis of cell growth in Panserin 401 supplemented with 2% FBS only or with growth factors only revealed no proliferation, demonstrating the necessity of the combination of 2% FBS and growth factors. Efficient isolation and expansion of hMSC from cancellous bone could also be performed using Panserin 401 with 2% FBS and growth factors. Furthermore, these isolated cultures maintained multipotency, as demonstrated by adipogenic and osteogenic differentiation.     

Injured cardiomyocytes promote dental pulp mesenchymal stem cell homing

Background

The heart is unable to regenerate its tissues after severe injuries. Stem cell therapy appears to be one of the most promising approaches, though preclinical results are hitherto contradictory and clinical trials scanty and/or limited to phase-I. The limited knowledge about stem cell early homing in infarcted cardiac tissues can concur to this scenario.

Methods

The stem cell migration was assessed in in-vitro and ex-vivo models of heart ischemia, employing a rat dental pulp stem cell line (MUR-1) that shares the same ontogenic progenitors with portions of the heart, expresses markers typical of cardiac/vascular-like progenitors and is able to differentiate into cardiomyocytes in-vitro.

Results

Here, we demonstrated that the MUR-1 can reach the injured cells/tissue and make contacts with the damaged cardiomyocytes, likely through Connexin 43, N-cadherin and von Willebrand Factor mediated cell–cell interactions, both in in-vitro and ex-vivo models. Furthermore, we found that SDF-1, FGF-2 and HGF, but not VEGF are involved as chemotactic factors in MUR-1 migration, notifying a similarity with neural crest cell behavior during the organogenesis of both the splanchnocranium and the heart.

Conclusions

Herein we found a similarity between what happens during the heart organogenesis and the early migration and homing of MUR-1 cells in ischemic models.

General significance

The comprehension of molecular aspects underlying the early phases of stem cell migration and interaction with damaged organ contributes to the future achievement of the coveted stem cell-mediated organ regeneration and function preservation in-vivo.     

Mitophagy promotes the stemness of bone marrow-derived mesenchymal stem cells

Previous studies demonstrated that mitochondrial fission arguments the stemness of bone marrow-derived mesenchymal stem cells (BMSCs). Because mitophagy is critical in removing damaged or surplus mitochondrial fragments and maintaining mitochondrial integrity, the present study was undertaken to test the hypothesis that mitophagy is involved in mitochondrial fission-enhanced stemness of BMSCs. Primary cultures of rat BMSCs were treated with tyrphostin A9 (TA9, a potent inducer of mitochondrial fission) to increase mitochondrial fission, which was accompanied by enhanced mitophagy as defined by increased co-staining of MitoTracker Green for mitochondria and LysoTracker Deep Red for lysosomes, as well as the increased co-localization of autophagy markers (LC3B, P62) and mitochondrial marker (Tom20). A mitochondrial uncoupler, carbonyl cyanide 4-(trifluoromethoxy) phenylhydrazone (FCCP) was used to promote mitophagy, which was confirmed by an increased co-localization of mitochondrial and lysosome biomarkers. The argumentation of mitophagy was associated with enhanced stemness of BMSCs as defined by increased expression of stemness markers Oct4 and Sox2, and enhanced induction of BMSCs to adipocytes or osteocytes. Conversely, transfection of BMSCs with siRNA targeting mitophagy-essential genes Pink1/Prkn led to diminished stemness of the stem cells, as defined by depressed stemness markers. Importantly, concomitant promotion of mitochondrial fission and inhibition of mitophagy suppressed the stemness of BMSCs. These results thus demonstrate that mitophagy is critically involved in mitochondrial fission promotion of the stemness of BMSCs.     

Differentiation into neurons of rat bone marrow-derived mesenchymal stem cells

Purpose

It has been reported that mesenchymal stem cells (MSCs) can differentiate into neurons as an effect of adding extraneous factors, such as β-mercaptoethanol, dimethyl sulfoxide and butylated hydroxyanisole. However, many of these compounds could harm MSCs and the human body, which restricts their application. We examined whether MSCs could differentiate into neuron-like cells under the influence of natural growth factors, such as epidermal growth factor (EGF), basic fibroblast growth factor (bFGF), insulin-like growth factor 1 (IGF-1, and neurotrophin 3 (NT-3).

Methods

MSCs were collected from rat bone marrow using the plastic adherent selection method, and induced in culture media to which was added different combinations of EGF, bFGF, IGF-1 and NT-3. The shape of the induced cells was observed daily and the differentiated cells were characterized by immunocytochemistry with neural-specific markers.

Result

With bFGF and NT-3 in the medium, the induced cells became slim, gradually developing protruding processes, with parts of them forming net- or ring-like structures. Cells with processes showed expression of microtubule-associated protein 2 (MAP2) and nestin (NES), which was enhanced when bFGF and NT-3 were added in combination. However, with IGF-1 added to the medium, there was no evidence of neurite-like processes or any net- or ring-like structures; the MSCs retained their round or slim shape.

Conclusion

Using natural cytokines in vitro, MSCs successfully differentiated into neuron-like cells. Our study confirms that bFGF and NT-3 exerts a neural-induction effect on the differentiation of MSCs, but that IGF has a rather negative effect on this process.

     

Integration potential of mouse and human bone marrow-derived mesenchymal stem cells

Mesenchymal stem cells (MSCs) are a multipotent cell population which has been described to exert renoprotective and regenerative effects in experimental models of kidney injury. Several lines of evidence indicate that MSCs also have the ability to contribute to nephrogenesis, suggesting that the cells can be employed in stem cell-based applications aimed at de novo renal tissue generation. In this study we re-evaluate the capacity of mouse and human bone marrow-derived MSCs to contribute to the development of renal tissue using a novel method of embryonic kidney culture. Although MSCs show expression of some genes involved in renal development, their contribution to nephrogenesis is very limited in comparison to other stem cell types tested. Furthermore, we found that both mouse and human MSCs have a detrimental effect on the ex vivo development of mouse embryonic kidney, this effect being mediated through a paracrine action. Stimulation with conditioned medium from a mouse renal progenitor population increases the ability of mouse MSCs to integrate into developing renal tissue and prevents the negative effects on kidney development, but does not appear to enhance their ability to undergo nephrogenesis.     

Human marrow-derived mesenchymal progenitor cells

A number of adult mesenchymal tissues contain subpopulations of undifferentiated cells, which retain the capacity to differentiate along multiple lineages. These mesenchymal progenitor cells may be cultured in an undifferentiated state and, when given the appropriate signals, differentiate into an expanding list of several mesenchymal and a few ectodermal derived tissues. The maintenance and propagation of the multipotential nature of these progenitor cell populations are crucially dependent on the isolation protocol, the culture expansion conditions, particularly the properties of the fetal bovine serum supplement in the culture medium. This article describes a method for selection of the appropriate serum lot, and introduces a simplified isolation technique to optimize the yield of progenitor cells that maintain the capability of undergoing multilineage differentiation in response to appropriate cues. Cell populations isolated and culture expanded in this manner, by virtue of their multiple differentiation potential, should serve as ideal candidate cells for tissue engineering applications for the repair and regeneration of tissue damaged by disease and or trauma.     

Hypoxia inhibits the spontaneous calcification of bone marrow-derived mesenchymal stem cells

Bone marrow-derived mesenchymal stem cells (BM-MSCs) are the popular seed cells for regenerative medicine, and there has been a rapid increase in the number of BM-MSC-based clinical trials. However, the safety of these cells should also be closely studied. In this study, spontaneous calcification of BM-MSCs from rats was evaluated in normoxia (20% O(2)) without osteogenic medium after continuous culture for 21 days; obvious mineralized nodules were observed, which were positive for Alizarin Red, collagen-I (Col-I), osteocalcin (OC) and alkaline phosphatase (ALP), and mainly consisted of C, O and Ca elements. Interestingly, hypoxia (2% O(2)) significantly inhibited this spontaneous calcification. In addition, the ALP and calcium content of rBM-MSCs were sharply reduced. Based on RT-PCR results, the expression of osteogenic genes (Cbfa1/Runx2, Col-I, ALP, and OC) was reduced compared to that in normoxia. These results demonstrate a natural and unique characterization of rat BM-MSCs in normoxia after continuous culture and highlight the inhibiting effects of hypoxia. Finally, this study contributes to the information regarding the application of BM-MSCs in the regeneration of various tissues.     

Labeling of cynomolgus monkey bone marrow-derived mesenchymal stem cells for cell tracking by multimodality imaging

Recently, transplantation of allogeneic and autologous cells has been used for regenerative medicine. A critical issue is monitoring migration and homing of transplanted cells, as well as engraftment efficiency and functional capability in vivo. Monitoring of superparamagnetic iron oxide (SPIO) particles by magnetic resonance imaging (MRI) has been used in animal models and clinical settings to track labeled cells. A major limitation of MRI is that the signals do not show biological characteristics of transplanted cells in vivo. Bone marrow mesenchymal stem cells (MSCs) have been extensively investigated for their various therapeutic properties, and exhibit the potential to differentiate into cells of diverse lineages. In this study, cynomolgus monkey MSCs (cMSCs) were labeled with Molday ION Rhodamine-B™ (MIRB), a new SPIO agent, to investigate and characterize the biophysical and MRI properties of labeled cMSCs in vitro and in vivo. The results indicate that MIRB is biocompatible and useful for cMSCs labeling and cell tracking by multimodality imaging. Our method is helpful for detection of transplanted stem cells in vivo, which is required for understanding mechanisms of cell therapy.     

Odontogenic capability: bone marrow stromal stem cells versus dental pulp stem cells

Background information. Although adult bone‐marrow‐derived cell populations have been used to make teeth when recombined with embryonic oral epithelium, the differences between dental and non‐dental stem‐cell‐mediated odontogenesis remain an open question. Results. STRO‐1⁺ (stromal precursor cell marker) DPSCs (dental pulp stem cells) and BMSSCs (bone marrow stromal stem cells) were isolated from rat dental pulp and bone marrow respectively by magnetic‐activated cell‐sorting techniques. Their odontogenic capacity was compared under the same inductive microenvironment produced by ABCs (apical bud cells) from 2‐day‐old rat incisors. Co‐cultured DPSCs/ABCs in vitro showed more active odontogenic differentiation ability than mixed BMSSCs/ABCs, as indicated by the accelerated matrix mineralization, up‐regulated alkaline phosphatase activity, cell‐cycle modification, and the expression of tooth‐specific proteins and genes. After cultured for 14 days in the renal capsules of rat hosts, recombined DPSC/ABC pellets formed typical tooth‐shaped tissues with balanced amelogenesis and dentinogenesis, whereas BMSSC/ABC recombinants developed into atypical dentin—pulp complexes without enamel formation. DPSC and BMSSC pellets in vivo produced osteodentin‐like structures and fibrous connective tissues respectively. Conclusions. DPSCs presented more striking odontogenic capability than BMSSCs under the induction of postnatal ABCs. This report provides critical insights into the selection of candidate cells for tooth regeneration between dental and non‐dental stem cell populations.     

Ceramide kinase regulates the migration of bone marrow-derived mesenchymal stem cells

Endogenous bone marrow-derived mesenchymal stem cells (BM-MSCs) are mobilized into peripheral blood and injured tissues by various growth factors and cytokines that are expressed in the injured tissues, such as substance P (SP), stromal cell derived factor-1 (SDF-1), and transforming growth factor-beta (TGF-β). Extracellular bioactive lipid metabolites such as ceramide-1-phosphate and sphingosine-1-phosphate also modulate BM-MSC migration as SP, SDF-1, and TGF-β. However, the roles of intrinsic lipid kinases of BM-MSCs in the stem cell migration are unclear. Here, we demonstrated that ceramide kinase mediates the chemotactic migration of BM-MSCs in response to SP, SDF-1, or TGF-β. Furthermore, a specific inhibitor of ceramide kinase inhibited TGF-β-induced migration of BM-MSCs and N-cadherin that is necessary for BM-MSCs migration in response to TGF-β. Therefore, these results suggest that the intracellular ceramide kinase is required for the BM-MSCs migration and the roles of the intrinsic ceramide kinase in the migration are associated with N-cadherin regulation.     

杆状病毒转导不同哺乳动物骨髓来源间充质干细胞

杆状病毒作为一种新型基因载体,若能有效转导不同哺乳动物骨髓来源间充质干细胞(bone marrow-derived mesenchymal stem cells, BMSCs),将会成为干细胞基因修饰研究领域中更理想的一种基因载体.本文探讨了重组杆状病毒(BacV-CMV-EGFP)对不同哺乳动物BMSCs的转导效率.体外原代培养小鼠、大鼠、猪、恒河猴及人的BMSCs.用培养3代以上的哺乳动物BMSCs进行病毒转导实验,转导2d后用倒置荧光显微镜观察绿色荧光蛋白在不同哺乳动物BMSCs中的表达,并用流式细胞仪检测重组杆状病毒对不同哺乳动物BMSCs的转导效率.结果显示:原代培养的小鼠、大鼠、猪、恒河猴及人的BMSCs于体外传代3次以上后,细胞呈现较均一的梭形,漩涡状生长;倒置荧光显微镜观察显示,与小鼠、大鼠、猪的BMSCs相比,恒河猴及人有更多BMSCs表达绿色荧光蛋白,且荧光强度较强;杆状病毒对小鼠、大鼠、猪、恒河猴及人的BMSCs的转导效率分别为(21.21±3.02)%、(22.51±4.48)%、(39.13±5.79)%、(71.16±5.36)%及(70.67±3.74)%.上述结果表明,重组杆状病毒对不同哺乳动物BMSCs的转导效率不同,对恒河猴及人的BMSCs转导效率较高,说明重组杆状病毒可作为人或灵长类动物BMSCs基因修饰研究领域中更理想的基因载体.     

Cell-autonomous heparanase modulates self-renewal and migration in bone marrow-derived mesenchymal stem cells

Background

Stem cell-fate is highly regulated by stem cell niche, which is composed of a distinct microenvironment, including neighboring cells, signals and extracellular matrix. Bone marrow-derived mesenchymal stem cells (BM-MSCs) are multipotent stem cells and are potentially applicable in wide variety of pathological conditions. However, the niche microenvironment for BM-MSCs maintenance has not been clearly characterized. Accumulating evidence indicated that heparan sulfate glycosaminoglycans (HS-GAGs) modulate the self-renewal and differentiation of BM-MSCs, while overexpression of heparanase (HPSE1) resulted in the change of histological profile of bone marrow. Here, we inhibited the enzymatic activity of cell-autonomous HPSE1 in BM-MSCs to clarify the physiological role of HPSE1 in BM-MSCs.

Results

Isolated mouse BM-MSCs express HPSE1 as indicated by the existence of its mRNA and protein, which includes latent form and enzymatically active HPSE1. During in vitro osteo-differentiations, although the expression levels of Hpse1 fluctuated, enzymatic inhibition did not affect osteogenic differentiation, which might due to increased expression level of matrix metalloproteinase 9 (Mmp9). However, cell proliferation and colony formation efficiency were decreased when HPSE1 was enzymatically inhibited. HPSE1 inhibition potentiated SDF-1/CXCR4 signaling axis and in turn augmented the migratory/anchoring behavior of BM-MSCs. We further demonstrated that inhibition of HPSE1 decreased the accumulation of acetylation marks on histone H4 lysine residues suggesting that HPSE1 also modulates the chromatin remodeling.

Conclusions

Our findings indicated cell-autonomous HPSE1 modulates clonogenicity, proliferative potential and migration of BM-MSCs and suggested the HS-GAGs may contribute to the niche microenvironment of BM-MSCs.