Dopaminergic neuronal differentiation protocol for human mesenchymal stem cells.

The generation of dopamine (DA) neurons from stem cells holds great promise for future biomedical research and in the clinical treatment of neurodegenerative diseases, such as Parkinson's disease. Mesenchymal stem cells (MSCs) derived from the adult human bone marrow (BM) can be easily isolated and expanded in culture while maintaining their immense plasticity. Here, we describe a protocol to generate DA-producing cells from adult human MSCs using a cocktail that includes sonic hedgehog (SHH), fibroblast growth factor 8 (FGF8), and basic fibroblast growth factor (bFGF). Electrophysiological functional DA neurons could be achieved by further treatment with brain-derived neurotrophic factor (BDNF). In summary, a protocol is described for the induction of primary BM-derived human MSCs to specific transdifferentiation; in this case, functional DA neurons. The MSC-derived DA cells express DA-specific markers, synthesize, and secrete dopamine. The described method could be used to generate DA cells for various model systems in which DA-producing cells are implicated in pathophysiological conditions.

Brain-derived neurotrophic factor facilitates maturation of mesenchymal stem cell-derived dopamine progenitors to functional neurons.

The generation of dopamine (DA) neurons from stem cells holds great promise in the treatment of Parkinson's disease and other neural disease associated with dysfunction of DA neurons. Mesenchymal stem cells (MSCs) derived from the adult bone marrow show plasticity with regards to generating cells of other germ layers. In addition to reduced ethical concerns, MSCs could be transplanted across allogeneic barriers, making them desirable stem cells for clinical applications. We have reported on the generation of DA cells from human MSCs using sonic hedgehog (SHH), fibroblast growth factor 8 and basic fibroblast growth factor. Despite the secretion of DA, the cells did not show evidence of functional neurons, and were therefore designated DA progenitors. Here, we report on the role of brain-derived neurotrophic factor (BDNF) in the maturation of the MSC-derived DA progenitors. 9-day induced MSCs show significant tropomyosin-receptor-kinase B expression, which correlate with its ligand, BDNF, being able to induce functional maturation. The latter was based on Ca2+ imaging analyses and electrophysiology. BDNF-treated cells showed the following: increases in intracellular Ca2+ upon depolarization and after stimulation with the neurotransmitters acetylcholine and GABA and, post-synaptic currents by electrophysiological analyses. In addition, BDNF induced increased DA release upon depolarization. Taken together, these results demonstrate the crucial role for BDNF in the functional maturation of MSC-derived DA progenitors.

RE-1-silencing transcription factor shows tumor-suppressor functions and negatively regulates the oncogenic TAC1 in breast cancer cells.

Breast cancer remains the most prevalent cancer among women in the United States. Substance P, a peptide derived from the TAC1 gene, mediates oncogenic properties in breast and other cancers. TAC1 expression facilitates the entry of breast cancer cells into bone marrow. The transcriptional repressor element 1-silencing transcription factor (REST) has been implicated in both oncogenic and tumor-suppressor functions. REST binds to the 5' untranslated region of the TAC1 promoter and suppresses its expression. This study investigated a role for REST in TAC1 induction in breast cancer. Western blots and real-time PCR indicated that REST expression in breast cancer cells was inversely proportional to the cells' aggressiveness, for both cell lines and primary breast cancer cells. REST knockdown in low-metastatic T47D cells and nontumorigenic MCF12A cells resulted in increases in TAC1 induction, proliferation, and migration. These parameters were negatively affected by ectopic expression of REST in highly aggressive MDA-MB-231 cells. Together, these findings show a central role for REST in the oncogenic function of TAC1 and suggest a tumor-suppressor role for REST in breast cancer.

Neurokinin-A inhibits cell cycle activators in K562 cells and activates Smad 4 through a non-canonical pathway: a novel method in neural-hematopoietic axis.

Hematopoiesis is a complexprocess in which blood and immune cells are developed. Among the regulators of hematopoiesis are two members of the G-protein coupled receptor family, neurokinin-1 (NK1) and NK2, which partly encompass the communication between the neural and hematopoietic systems. This communication also involves a complex network of cytokines, and crosstalk between NK1 and NK2. Excessive activation of NK1 has been linked to leukemia. NK2 exerts negative effects on NK1. Previous studies with the hematopoietic progenitor cell line, K562 have identified activated p53 as a mediator of NK2 transcription, which correlated with cell proliferation. This study investigated the mechanism of NK-A mediated inhibition of cell proliferation. K562 was stimulated with 10 nM of NK-A, and the nuclear extracts were analyzed by Westernblots for cell cycle regulators. The studies showed decreases in the cell cycling activators, Cdk2 and Cyclin A, which correlated with increases in p21 and p53. The differentiation protein p19 was unchanged, suggesting that NK-A maintains K562 at cell cycle checkpoints, but does not have roles in differentiation. NK-A appears to regulate TGF-beta 1 production at the level of translation. Despite the production of TGF-beta 1, the activation of Smad 4 occurs by NK-A, via a non-canonical pathway, as indicated by an inhibitor of TGF-beta receptor activators, SB431542. TGF-beta 1 was needed to prevent exacerbated decrease in Cyclin A, but not Cdk2, indicating that it was its role might be limited to balancing the negative regulation of TGF-beta 1. In summary, NK-A enhances translation of TGF-beta 1 in K562 cells. NK-A suppressed cell cycle activators, and activated Smad 4 via a non-canonical pathway, independent of TGF-beta receptor. These findings are significant in the negative regulation of progenitor proliferation, with implications for hematopoiesis and its associated dysfunctions.

Loss of RE-1 silencing factor in mesenchymal stem cell-derived dopamine progenitors induces functional maturity.

Stem cell-derived dopamine (DA) neurons hold great promise for Parkinson's disease (PD). Mesenchymal stem cells (MSCs) have great potential for clinical applications. The generation of DA cells from MSCs using sonic hedgehog (SHH) and fibroblast growth factors (FGF8 and bFGF) has been reported. However, the DA cells showed weak electrical properties, representing DA neuron progenitors. Since RE-1 Silencing Factor (REST), suppresses mature neuronal genes in neuronal progenitors, we studied its role in the maturation of MSC-derived DA cells. REST expression did not change during the induction process, thus we knocked down REST and subjected MSCs to the same neural induction cocktail. We observed increases in the protein level of the Na(+) voltage-gated channel and tyrosine hydroxylase (TH). Electrophysiological analyses showed spontaneous firings and spontaneous postsynaptic currents, similar to native DA neurons. Taken together, these results show REST as the limiting gene in the generation of functional mature neurons from MSCs.

Mesenchymal stem cells in early entry of breast cancer into bone marrow.

BACKGROUND: An understanding of BC cell (BCC) entry into bone marrow (BM) at low tumor burden is limited when compared to highly metastatic events during heavy tumor burden. BCCs can achieve quiescence, without interfering with hematopoiesis. This occurs partly through the generation of gap junctions with BM stroma, located close to the endosteum. These events are partly mediated by the evolutionary conserved gene, Tac1. METHODOLOGY/PRINCIPAL FINDINGS: This study focuses on the role of mesenchymal stem cells (MSCs), Tac1, SDF-1 and CXCR4 in BCC entry into BM. The model is established in studies with low numbers of tumor cells, and focuses on cancer cells with low metastatic and invasion potential. This allowed us to recapitulate early event, and to study cancer cells with low invasive potential, even when they are part of larger numbers of highly metastatic cells. A novel migration assay showed a facilitating role of MSCs in BCC migration across BM endothelial cells. siRNA and ectopic expression studies showed a central role for Tac1 and secondary roles for SDF-1alpha and CXCR4. We also observed differences in the mechanisms between low invasive and highly metastatic cells. The in vitro studies were verified in xenogeneic mouse models that showed a preference for low invasive BCCs to BM, but comparable movement to lung and BM by highly metastatic BCCs. The expressions of Tac1 and production of SDF-1alpha were verified in primary BCCs from paired samples of BM aspirates and peripheral blood. CONCLUSIONS/SIGNIFICANCE: MSC facilitate BCC entry into BM, partly through Tac1-mediated regulation of SDF-1alpha and CXCR4. We propose a particular population of BCC with preference for BM could be isolated for characterization. This population might be the subset that enter BM at an early time period, and could be responsible for cancer resurgence and resistance to current therapies.

Neurokinin receptors as potential targets in breast cancer treatment.

Despite recent advances in the diagnoses and treatment of breast cancer, this disease continues to be a major cause of death. One of the biggest challenges in breast cancer treatment is bone metastasis. Breast cancer cells (BCCs) are capable of migrating to the bone marrow and utilizing the marrow microenvironment to remain quiescent. While exhibiting quiescence in the marrow, BCCs can evade the effects of conventional cancer treatments such as chemotherapy. Therefore, scientists must find a new paradigm to target these quiescent BCCs. The development of potential targets may require a more comprehensive understanding of the marrow microenvironment and its regulators. The preprotachykinin-1 (PPT-I) gene encodes for the tachykinin peptides, which interact with neurokinin (NK) receptors. Studies have correlated this interaction with BCC integration into the bone marrow and breast cancer progression. In this review, we discuss the roles that different factors of the marrow microenvironment play in breast cancer and targets of NK receptors as potential treatment options.

Down-regulation of MHC II in mesenchymal stem cells at high IFN-gamma can be partly explained by cytoplasmic retention of CIITA.

Mesenchymal stem cells (MSCs) are located in postnatal bone marrow, show plasticity, are linked to various bone marrow disorders, exhibit phagocytosis, exert Ag-presenting properties (APC), and are immune suppressive. Unlike professional APCs, MSCs respond bimodally to IFN-gamma in MHC-II expression, with expression at 10 U/ml and baseline, and down-regulation at 100 U/ml. The effects at high IFN-gamma could not be explained by down-regulation of its receptor, IFN-gammaRI. In this study, we report on the mechanisms by which IFN-gamma regulates MHC-II expression in MSCs. Gel shift assay and Western blot analyses showed dose-dependent increases in activated STAT-1, indicating responsiveness by IFN-gammaRI. Western blots showed decreased intracellular MHC-II, which could not be explained by decreased transcription of the master regulator CIITA, based on RT-PCR and in situ immunofluorescence. Reporter gene assays with PIII and PIV CIITA promoters indicate constitutive expression of PIII in MSCs and a switch to PIV by IFN-gamma, indicating the presence of factors for effect promoter responses. We explained decreased MHC-II at the level of transcription because CIITA protein was observed in the cytosol and not in nuclei at high IFN-gamma level. The proline/serine/threonine region of CIITA showed significant decrease in phosphorylation at high IFN-gamma levels. An understanding of the bimodal effects could provide insights on bone marrow homeostasis, which could be extrapolated to MSC dysfunction in hematological disorders.

Immunostimulatory effects of mesenchymal stem cell-derived neurons: implications for stem cell therapy in allogeneic transplantations.

Mesenchymal stem cells (MSCs) differentiate along various lineages to specialized mesodermal cells and also transdifferentiate into cells such as ectodermal neurons. MSCs are among the leading adult stem cells for application in regenerative medicine. Advantages include their immune-suppressive properties and reduced ethical concerns. MSCs also show immune-enhancing functions. Major histocompatibility complex II (MHC-II) is expected to be downregulated in MSCs during neurogenesis. Ideally, "off the shelf" MSCs would be suited for rapid delivery into patients. The question is whether these MSC-derived neurons can reexpress MHC-II in a milieu of inflammation. Western analyses demonstrated gradual decrease in MHC-II during neurogenesis, which correlated with the expression of nuclear CIITA, the master regulator of MHC-II expression. MHC-II expression was reversed by exogenous IFNY. One-way mixed lymphocyte reaction with partly differentiated neurons showed a stimulatory effect, which was partly explained by the release of the proinflammatory neurotransmitter substance P (SP), cytokines, and decreases in miR-130a and miR-206. The anti-inflammatory neurotransmitters VIP and CGRP were decreased at the peak time of immune stimulation. In summary, MSC-derived neurons show decreased MHC-II expression, which could be reexpressed by IFNY. The release of neurotransmitters could be involved in initiating inflammation, underscoring the relevance of immune responses as consideration for stem cell therapies.

Adult mesenchymal stem cells in neural regeneration and repair: Current advances and future prospects (Review).

Mesenchymal stem cells (MSCs) are an attractive cell source for regenerative medicine as they can be easily isolated from bone marrow (BM) aspirates and expanded in culture while maintaining their 'stemness'. In addition to differentiating into mesodermal cells, MSCs have shown considerable plasticity and generate ectodermal neurons and glia, which can be used to replace cells damaged by neurological diseases and injuries. These unique stem cells also exhibit immunomodulatory functions and secrete a variety of trophic factors which support regeneration and repair. This review focuses on the therapeutic usage of MSCs for neurodegenerative diseases and traumatic injuries to the nervous system. Animal studies demonstrate great promise for MSC transplantation in neurological disorders. In fact, a few clinical trials have already been initiated and show that MSCs are a safe cellular therapy and have great potential to become a viable treatment for neural disorders in the years to come.

Specification of a dopaminergic phenotype from adult human mesenchymal stem cells.

Dopamine (DA) neurons derived from stem cells are a valuable source for cell replacement therapy in Parkinson disease, to study the molecular mechanisms of DA neuron development, and for screening pharmaceutical compounds that target DA disorders. Compared with other stem cells, MSCs derived from the adult human bone marrow (BM) have significant advantages and greater potential for immediate clinical application. We report the identification of in vitro conditions for inducing adult human MSCs into DA cells. Using a cocktail that includes sonic hedgehog and fibroblast growth factors, human BM-derived MSCs were induced in vitro to become DA cells in 12 days. Based on tyrosine hydroxylase (TH) expression, the efficiency of induction was determined to be approximately 67%. The cells develop a neuronal morphology expressing the neuronal markers NeuN and beta III tubulin, but not glial markers, glial fibrillary acidic protein and Olig2. As the cells acquire a postmitotic neuronal fate, they downregulate cell cycle activator proteins cyclin B, cyclin-dependent kinase 2, and proliferating cell nuclear antigen. Molecular characterization revealed the expression of DA-specific genes such as TH, Pitx3, Nurr1, DA transporter, and vesicular monoamine transporter 2. The induced MSCs also synthesize and secrete DA in a depolarization-independent manner. The latter observation is consistent with the low expression of voltage gated Na(+) and Ca(2+) channels in the induced MSCs and suggests that the cells are at an immature stage of development likely representing DA neuronal progenitors. Taken together, the results demonstrate the ability of adult human BM-derived MSCs to form DA cells in vitro.

Current advances in the treatment of Parkinson's disease with stem cells.

Stem cell replacement has emerged as the novel therapeutic strategy for Parkinson's disease (PD). Control of motor behavior is lost in PD due to the selective degeneration of mesencephalic dopamine neurons (DA) in the substantia nigra. This progressive loss of DA neurons results in devastating symptoms for which there is no cure. Debilitating side effects often result from chronic pharmacological treatment, hence current investigations into cell transplantation therapy as a substitute and/or adjuvant to other therapeutics. Clinical trials with fetal DA tissue have provided evidence that cell transplantation could be a viable alternative. Limited availability of fetal tissue, combined with variable outcome led to emphasis on other sources of cells, such as stem cells. This review focuses on three stem cell sources (embryonic, neural, and adult mesenchymal). Also discussed is the molecular differentiation into mature DA neurons, the various protocols that have been developed to generate DA neurons from various stem cells, and the current state of stem cell therapy for PD.

Neurons derived from human mesenchymal stem cells show synaptic transmission and can be induced to produce the neurotransmitter substance P by interleukin-1 alpha.

Mesenchymal stem cells (MSCs) exhibit immune-suppressive properties, follow a pattern of multilineage differentiation, and exhibit transdifferentiation potential. Ease in expansion from adult bone marrow, as well as its separation from ethical issues, makes MSCs appealing for clinical application. MSCs treated with retinoic acid resulted in synaptic transmission, based on immunostaining of synaptophysin and electrophysiological studies. In situ hybridization indicated that the neurotransmitter gene preprotachykinin-I was expressed in these cells. However, translation of this gene only occurred after stimulation with interleukin (IL)-1 alpha. This effect was blunted by costimulation with IL-1 receptor antagonist. This study reports on the ability of MSCs to be transdifferentiated into neurons with functional synapses with the potential to become polarized towards producing specific neurotransmitters.

Neurokinin receptors: relevance to the emerging immune system.

The adult bone marrow (BM )is the major site of the emerging immune system. Hematopoiesis is the process whereby immune cells are generated from a finite number of hematopoietic stem cells. Hematopoiesis is regulated by soluble mediators and inter cellular interactions. A major regulatory mechanism of hematopoiesis involves bidirectional crosstalk with the neural system. This communication mainly occurs by the release of neurotransmitters from innervated fibers. The neurotransmitters interact with specific receptors on BM resident cells and release other hematopoietic regulators such as cytokines. Together, the neurotransmitters and cytokines form a complex network to regulate hematopoiesis. Among BM resident cells, the stromal cells are particularly relevant for two reasons:1) they represent non-neural sources of neurotransmitters, and 2) stromal cells express specific receptors for neurotransmitters. This review focuses on the hematopoietic effects of neurotransmitters belonging to the tachykinins. The two major tachykinins focused in this review are substance P and neurokinin (NK)-A,11 and 10 amino acid peptides. In BM, the tachykinins interact with two major NK receptors:NK-1 and NK-2. These two receptors appear to limit tachykinin-mediated effects on hematopoiesis. The central roles of NK receptors within a network comprising of cytokines and tachykinins are reviewed.