Ischemic brain injury: a consortium analysis of key factors involved in mesenchymal stem cell-mediated inflammatory reduction.

Increasing global birth rate, coupled with the aging population surviving into their eighth decade has lead to increased incidence diseases, hitherto designated as rare. Brain related ischemia, at birth, or later in life, during, for example stroke, is increasing in global prevalence. Reactive microglia can contribute to neuronal damage as well as compromising transplantion. One potential treatment strategy is cellular therapy, using mesenchymal stem cells (hMSCs), which possess immunomodulatory and cell repair properties. For effective clinical therapy, mechanisms of action must be understood better. Here multicentre international laboratories assessed this question together investigating application of hMSCs neural involvement, with interest in the role of reactive microglia. Modulation by hMSCs in our in vivo and in vitro study shows they decrease markers of microglial activation (lower ED1 and Iba) and astrogliosis (lower GFAP) following transplantation in an ouabain-induced brain ischemia rat model and in organotypic hippocampal cultures. The anti-inflammatory effect in vitro was demonstrated to be CD200 ligand dependent with ligand expression shown to be increased by IL-4 stimulation. hMSC transplant reduced rat microglial STAT3 gene expression and reduced activation of Y705 phosphorylated STAT3, but STAT3 in the hMSCs themselves was elevated upon grafting. Surprisingly, activity was dependent on heterodimerisation with STAT1 activated by IL-4 and Oncostatin M. Our study paves the way to preclinical stages of a clinical trial with hMSC, and suggests a non-canonical JAK-STAT signaling of unphosphorylated STAT3 in immunomodulatory effects of hMSCs.

In vitro modelling of cortical neurogenesis by sequential induction of human umbilical cord blood stem cells.

Neurogenesis of excitatory neurons in the developing human cerebral neocortex is a complex and dynamic set of processes and the exact mechanisms controlling the specification of human neocortical neuron subtypes are poorly understood due to lack of relevant cell models available. It has been shown that the transcription factors Pax6, Tbr2 and Tbr1, which are sequentially expressed in the rodent neocortex, regulate and define corticogenesis of glutamatergic neocortical neurons. In humans the homologues of these genes are generally expressed in a similar pattern, but with some differences. In this study, we used purified human umbilical cord blood stem cells, expressing pluripotency marker genes (OCT4, SOX2 and NANOG), to model human neocortical neurogenesis in vitro. We analyzed the expression patterns of PAX6, TBR2 and TBR1, at both protein and mRNA levels, throughout the 24 days of a sequential neuronal induction protocol. Their expression patterns correlated with those found in the developing human neocortex where they define different developmental stages of neocortical neurons. The derived cord blood neuron-like cells expressed a number of neuronal markers. They also expressed components of glutamatergic neurotransmission including glutamate receptor subunits and transporters, and generated calcium influxes upon stimulation with glutamate. Thus we have demonstrated that it is possible to model neocortical neurogenesis using cord blood stem cells in vitro. This may allow detailed analysis of the molecular mechanisms regulating neocortical neuronal specification, thus aiding the development of potential therapeutic tools for diseases and injuries of the cerebral cortex.

Neurogenic properties and a clinical relevance of multipotent stem cells derived from cord blood samples stored in the biobanks.

Several innovative therapies with human umbilical cord blood stem cells (SCs) are currently developing to treat central nervous system (CNS) diseases. It has been shown that cord blood contains multipotent lineage-negative (LinNEG) SCs capable of neuronal differentiation. Clinically useful cord blood samples are stored in different biobanks worldwide, but the content and neurogenic properties of LinNEG cells are unknown. Here we have compared 5 major methods of blood processing: Sepax, Hetastarch, plasma depletion, Prepacyte-SC, and density gradient. We showed that Sepax-processed blood units contained 10-fold higher number of LinNEG cells after cryopreservation in comparison to all other methods. We showed in this study that multipotent SCs derived from fresh and frozen cord blood samples could be efficiently induced in defined serum-free medium toward neuronal progenitors (NF200+, Ki67+). During neuronal differentiation, the multipotent SCs underwent precise sequential changes at the molecular and cellular levels: Oct4 and Sox2 downregulation and Ngn1, NeuN, and PSD95 upregulation, similar to neurogenesis process in vivo. We expect that data presented here will be valuable for clinicians, researchers, biobanks, and patients and will contribute for better efficacy of future clinical trials in regeneration of CNS.

miRNAs stem cell reprogramming for neuronal induction and differentiation.

Mimicking the natural brain environment during neurogenesis represents the main challenge for efficient in vitro neuronal differentiation of stem cells. The discovery of miRNAs opens new possibilities in terms of modulation of stem cells lineage commitment and differentiation. Many studies demonstrated that in vitro transient overexpression or inhibition of brain-specific miRNAs in stem cells significantly directed differentiation along neuronal cell lineages. Modulating miRNA expression offers new pathways for post-transcriptional gene regulation and stem cell commitment. Neurotrophins and neuropoietins signaling pathways are the main field of investigation for neuronal commitment, differentiation, and maturation. This review will highlight examples of crosstalk between stem-cell-specific and brain-specific signaling pathways and key miRNA candidates for neuronal commitment. Recent progress on understanding miRNAs genetic networks offers promising prospects for their increasing application in the development of new cellular therapies in humans.

The performance of laminin-containing cryogel scaffolds in neural tissue regeneration.

Currently, there are no effective therapies to restore lost brain neurons, although rapid progress in stem cell biology and biomaterials development provides new tools for regeneration of central nervous system. Here we describe neurogenic properties of bioactive scaffolds generated by cryogelation of dextran or gelatin linked to laminin - the main component of brain extracellular matrix. We showed that such scaffolds promoted differentiation of human cord blood-derived stem cells into artificial neural tissue in vitro. Our experiments revealed that optimal range of scaffolds' pore size for neural tissue engineering was 80-100 microns. We found that scaffold seeded with undifferentiated, but not neutrally committed stem cells, gave optimal cell adhesion and proliferation in "niche"-like structures. Subsequent differentiation resulted in generation of mature 3D networks of neurons (MAP2+) and glia (S100beta+) cells. We showed that cryogel scaffolds could be transplanted into the brain tissue or organotypic hippocampal slices in a rat models. The scaffolds did not induced inflammation mediated by microglial cells (ED1-, Ox43-, Iba1-) and prevented formation of glial scar (GFAP-). Contrary, laminin-rich scaffolds attracted infiltration of host's neuroblasts (NF200+, Nestin+) indicating high neuroregeneration properties.

Artificial human tissues from cord and cord blood stem cells for multi-organ regenerative medicine: viable alternatives to animal in vitro toxicology.

New medicinal products and procedures must meet very strict safety criteria before being applied for use in humans. The laboratory procedures involved require the use of large numbers of animals each year. Furthermore, such investigations do not always give an accurate translation to the human setting. Here, we propose a viable alternative to animal testing, which uses novel technology featuring human cord and cord blood stem cells. With over 130 million children born each year, cord and cord blood remains the most widely available alternative to the use of animals or cadaveric human tissues for in vitro toxicology.

Umbilical cord blood stem cells--an ethical source for regenerative medicine.

Never before in the history of human kind have we tried to keep a tissue preserved for the entire life of a human. This, however, is what is proposed with umbilical cord blood banking. The media often report on the latest 'Stem Cell' breakthrough in 'Regenerative Medicine'. Between human embryonic stem cells, adult stem cells and umbilical cord blood stem cells, it is hard to decipher what all these have done and will do for patients. Cord blood is collected after birth with no harm to mother or baby and contains stem cells with an incredible potential to form tissues including neural, liver and pancreatic tissues in a laboratory. In less than 20 years, cord blood has become the biggest real success story in stem cells, with nearly 10,000 patients treated, from blood and immune transplants, through to more controversial interventions, such as Type 1 diabetes. With ongoing clinical trials and research predicting new avenues, the future seems assured for this stem cell source. What does this predict, however, for cord blood banking? More importantly, what does it justify?

Endolyn (CD164) modulates the CXCL12-mediated migration of umbilical cord blood CD133+ cells.

Hematopoietic stem cell/hematopoietic progenitor cell (HSC/HPC) homing to specific microenvironmental niches involves interactions between multiple receptor ligand pairs. Although CXCL12/CXCR4 plays a central role in these events, CXCR4 regulators that provide the specificity for such cells to lodge and be retained in particular niches are poorly defined. Here, we provide evidence that the sialomucin endolyn (CD164), an adhesion receptor that regulates the adhesion of CD34+ cells to bone marrow stroma and the recruitment of CD34+CD38(lo/-) cells into cycle, associates with CXCR4. The class II 103B2 monoclonal antibody, which binds the CD164 N-linked glycan-dependent epitope or CD164 knockdown by RNA interference, significantly inhibits the migration of CD133+ HPCs toward CXCL12 in vitro. On presentation of CXCL12 on fibronectin, CD164 associates with CXCR4, an interaction that temporally follows the association of CXCR4 with the integrins VLA-4 and VLA-5. This coincides with PKC-zeta and Akt signaling through the CXCR4 receptor, which was disrupted on the loss of CD164 though MAPK signaling was unaffected. We therefore demonstrate a novel association among 3 distinct families of cell-surface receptors that regulate cell migratory responses and identify a new role for CD164. We propose that this lends specificity to the homing and lodgment of these cells within the bone marrow niche.

Umbilical cord blood stem cells can expand hematopoietic and neuroglial progenitors in vitro.

The ability of hematopoietic tissue-derived adult stem cells to transdifferentiate into neural progenitor cells offers an interesting alternative to central nervous system (CNS)- or embryonic-derived stem cells as a viable source for cellular therapies applied to brain regeneration. Umbilical cord blood (CB) due to its primitive nature and it unproblematic collection appears as a promising candidate for multipotent stem cell harvest. We developed a negative immunomagnetic selection method that depletes CB from hematopoietic lineage marker-expressing cells, hence isolating a discrete lineage negative (LinNeg) stem cell population (0.1% of CB mononucleated cell [MCN] population). In liquid culture supplemented with thrombopoietin, flt-3 ligand, and c-kit ligand (TPOFLK), CB LinNeg stem cells could expand primitive nonadherent hematopoietic progenitors (up to 47-fold) and simultaneously produce slow-dividing adherent cells with neuroglial progenitor cell morphology over 8 weeks. Laser scanning confocal microscopy analysis identified these adherent cells to express glial fibrillary acidic protein (GFAP). Gene expression analysis showed upregulation of primitive neuroglial progenitor cell markers including, GFAP, nestin, musashi-1, and necdin. ELISA quantification of liquid culture supernatant revealed the in vitro release of transforming growth factor beta-1 (TGFbeta1), glial cell line-derived neurotrophic factor (GDNF) suggesting their contribution to CB LinNeg stem cell transdifferentiation into neuroglial progenitors. Our study supports that a single CB specimen can be pre-expanded in TPOFLK to produce both primitive hematopoietic and neuropoietic progenitors, hence widening CB clinical potential for cellular therapies.

Characterization of a lineage-negative stem-progenitor cell population optimized for ex vivo expansion and enriched for LTC-IC.

Current hematopoietic stem cell transplantation protocols rely heavily upon CD34+ cells to estimate hematopoietic stem and progenitor cell (HSPC) yield. We and others previously reported CD133+ cells to represent a more primitive cell population than their CD34+ counterparts. However, both CD34+ and CD133+ cells still encompass cells at various stages of maturation, possibly impairing long-term marrow engraftment. Recent studies demonstrated that cells lacking CD34 and hematopoietic lineage markers have the potential of reconstituting long-term in vivo hematopoiesis. We report here an optimized, rapid negative-isolation method that depletes umbilical cord blood (UCB) mononucleated cells (MNC) from cells expressing hematopoietic markers (CD45, glycophorin-A, CD38, CD7, CD33, CD56, CD16, CD3, and CD2) and isolates a discrete lineage-negative (Lin-) cell population (0.10% +/- 0.02% MNC, n=12). This primitive Lin- cell population encompassed CD34+/- and CD133+/- HSPC and was also enriched for surface markers involved in HSPC migration, adhesion, and homing to the bone marrow (CD164, CD162, and CXCR4). Moreover, our depletion method resulted in Lin- cells being highly enriched for long-term culture-initiating cells when compared with both CD133+ cells and MNC. Furthermore, over 8 weeks in liquid culture stimulated by a cytokine cocktail optimized for HSPC expansion, TPOFLK (thrombopoietin 10 ng/ml, Flt3 ligand 50 ng/ml, c-Kit ligand 20 ng/ml) Lin- cells underwent slow proliferation but maintained/expanded more primitive HSPC than CD133+ cells. Therefore, our Lin- stem cell offers a promising alternative to current HSPC selection methods. Additionally, this work provides an optimized and well-characterized cell population for expansion of UCB for a wider therapeutic potential, including adult stem cell transplantation.

Multiparametric analysis of immature cell populations in umbilical cord blood and bone marrow.

Adult stem cells are finding increased therapeutic potential not least in tissue regeneration protocols. The cell sources being proposed for such protocols include embryonic, umbilical cord blood (CB) and adult bone marrow (BM). Although embryonic sources are controversial, CB and marrow are available immediately. The appropriate cells of use in these sources are considered to be extremely rare and a characterisation of the starting cell source is important for the development of adult stem cell protocols and ex vivo expansion. Umbilical CB and BM mononuclear cells were labelled for the antigens CD34, CD133, CD117, CD164, Thy-1 or CD38, and additional intracellular CD34 antigen. Three dimensional flow-cytometric analyses were carried out together with dual laser confocal microscope analysis for antigen profile expression. Variable levels of immaturity were detected on CB and BM populations using internal and external CD34 antigen. For CB and BM cells, internal CD34 (intCD34+) could be detected on co-expressing CD133+ cells before expression of external CD34 antigen (extCD34+). CD38 co-expression analysis also showed that a small but distinct group of cells expressing low CD38 and no external CD34 antigen could be detected. Additional phenotyping of these cells using CD117, Thy-1, CD164 and CD133 demonstrated variable primitive status detectable within the external CD34- population. Newly harvested primary CB and BM populations were shown to contain not only cellular populations of known standard sequential maturity but also populations of more extreme rarity. The presence of cells which lacked extracellular CD34 antigen, in both CB and BM, but which possessed CD133, has important implications for purification of human stem cells in clinical applications.

Three-dimensional analysis of CD34 sialomucin distribution on cord blood and bone marrow.

Determining the cellular distribution of key adhesion molecules may aid in understanding haematopoietic progenitor/stem cell (HPSC) homing to bone marrow (BM). CD34, a well-characterized marker for blast-like HPSC, is widely used for the isolation and enumeration of HPSC. Functional studies have yet to identify a ligand for CD34. However, growing evidence suggests that CD34 may aid the regulation of HPSC differentiation and modulate the expression of other HPSC adhesion molecules necessary for homing. This study aimed to determine CD34 distribution on umbilical cord blood (CB) and BM. CD34-selected cells were adhered to positively charged gold slides at room temperature, before indirect fluorescent antibody labelling with fluorescein isothiocyanate. Fluorescent distribution was determined by 1-microm interval, confocal laser scanning microscope Z-sections. Initial analysis showed CD34 distributed within peripheral halos and dense pocket regions. The development of three-dimensional imaging software enabled spatial visualization of CD34 distribution on CB and BM in association with differential interference contrast cell image. This showed that CD34 was distributed within peripheral halos, with magnupodia-associated 'meridian-shaped crescents', extending from points of cell-slide adhesion towards the top of the cell. True CD34 distribution, not previously discernible by confocal laser scanning microscopy alone, suggests a possible role in cell adhesion/homing revealed by three-dimensional imaging.

Colocalization analysis of sialomucins CD34 and CD164.

Flow cytometric protocols are employed to identify and characterize hemopoietic stem/progenitor populations before transplantation. Cell surface antigens, including CD34, are employed in this process and widely used in harvest protocols, which largely ignores the potential functional role of such antigens. Transmembrane glycoprotein sialomucins, including CD34 and CD164, have been implicated in cell-to-cell interactions and activation. CD164, also expressed on early hemopoietic populations, was reported to have a possible function facilitating CD34(+) cells to adhere to bone marrow stroma. In this study, we employed high-definition laser-scanning confocal microscopy to investigate CD34 and CD164 surface co-localization patterns on bone marrow and cord blood cells and to compare the expression patterns using a three-dimensional computer-generated method developed in house. Differential interference microscopy analysis revealed bone marrow membrane activity was higher than the corresponding cord blood counterpart, perhaps indicating the marrow microenvironmental nature. Fluorescence analysis of CD34 and CD164 antigens showed both were expressed first in a halo-like pattern and second in antigen-dense pockets. Three-dimensional computer analyses further revealed that this pocketing corresponded to dense crest-like surface structures appearing to rise from the point of adherence on the slide. Further, it was found that CD34 and CD164 display strong colocalization patterns on cells expressing both antigens. The dual nature of the CD34 and CD164 antigens discovered here lends further evidence to the previous literature implicating a strong functional link between these two sialomucins, which should be considered in the transplantation arena and in the function of such sialomucins as negative regulators of cell proliferation.

Diaminofluorene stain detects erythroid differentiation in immature haemopoietic cells treated with EPO, IL-3, SCF, TGFbeta1, MIP-1alpha and IFNgamma.

We have combined in vitro clonogenic culture and a highly sensitive stain for haemoglobin to compare the influence of EPO, IL-3, SCF, TGFbeta1, MIP-1alpha and IFNgamma, to directly stimulate cells in the progenitor compartment to develop towards the erythroid lineage. Three cell lines were chosen, as they exist developmentally arrested in the progenitor compartment, yet in a pliant state of maturation. HEL (erythroleukaemia) and K562 (CML-derived) cell lines, may, under appropriate stimuli, develop erythroid characters, whilst the third, U937 (as control cell line), may be stimulated by DMSO to differentiate to myeloid cells. After in vitro semi-solid methylcellulose culture with these cytokines, resulting colonies were stained with 2,7-diaminofluorene (DAF), which sensitively stains haemoglobin blue. Haemoglobin production was low in HEL and K562 cells and absent in U937. Cytokine analysis showed varying levels of influence depending on the starting level of cell line maturation. EPO and TGFbeta1 maximally stimulated haemoglobin production in the HEL and K562 cell lines. This differential cytokine stimulation analysis combined with sensitive DAF haemoglobin detection could be applied in the study of many erythropoiesis-deficient patients or primitive erythropoiesis.

AC133+ umbilical cord blood progenitors demonstrate rapid self-renewal and low apoptosis.

Umbilical cord blood (UCB) provides immediate access to haemopoietic stem/progenitor cells (HSPC) but low cell number restricts use in full adult bone marrow reconstitution. This study investigated early ex vivo expansion kinetics of UCB AC133+ cells (2-4 x 10(4)/ml), mononuclear cells (MNC, 1-2 x 10(6)/ml) and AC133negative cells (AC133(neg), 2-4 x 10(4)/ml) in stroma-free 8 d liquid culture (fetal bovine serum-supplemented Iscove's-modified Dulbecco's medium (IMDM) with either 'K36EG'[c-Kit ligand, interleukin 3 (IL-3), IL-6, erythropoietin, granulocyte colony-stimulating factor] or 'TPOFL' (thrombopoietin, Flt-3 ligand). Cell enumeration, apoptosis assay and AC133/CD34/CD38 antigen immunophenotyping were performed at d 0, 3, 5 and 8. All three cell populations went through a proliferation lag phase between d 3 and d 5. AC133+ cells recovered better from lag phase with significantly higher fold increase (FI) when compared with MNC and AC133(neg) populations (K36EG FI: 15.04 +/- 5.46; TPOFL FI: 8.59 +/- 2.92, P < 0.05). After 8 d, populations lacking AC133+ cells were significantly more inclined to undergo apoptosis under proliferative conditions (P < 0.01). Also, when compared with K36EG, 8 d TPOFL-expanded AC133+ cells encompassed a significantly higher percentage of AC133+ and CD34+ early HSPC (K36EG: 20.50 +/- 2.36; TPOFL: 47.00 +/- 7.69; P < 0.05). In conclusion, TPOFL synergism demonstrated the potential for AC133+ HSPC ex vivo expansion inducing self-renewal, early HSPC maintenance and promoting cell survival status.