Mesenchymal stem cells protect CNS neurons against glutamate excitotoxicity by inhibiting glutamate receptor expression and function.

Mesenchymal stem cells (MSC) promote functional recovery in experimental models of central nervous system (CNS) pathology and are currently being tested in clinical trials for stroke, multiple sclerosis and CNS injury. Their beneficial effects are attributed to the activation of endogenous CNS protection and repair processes as well as immune regulation but their mechanisms of action are poorly understood. Here we investigated the neuroprotective effects of mouse MSC in rodent MSC-neuron co-cultures and mice using models of glutamate excitotoxicity. A 24h pre-culture of mouse primary cortical neurons with MSC protected them against glutamate (NMDA) receptor-induced death and conditioned medium from MSC (MSC CM) was sufficient for this effect. Protection by MSC CM was associated with reduced mRNA levels of genes encoding NMDA receptor subunits, and increased levels for genes associated with non-neuronal and stem cell types, as shown by RT-PCR and cDNA microarray analyses. Changes in gene expression were not associated with alterations in cell lineage representation within the cultures. Further, MSC CM-mediated neuroprotection in rat retinal ganglion cells was associated with reduced glutamate-induced calcium influx. The adoptive transfer of EGFP(+)MSC in a mouse kainic acid epilepsy model also provided neuroprotection against glutamate excitotoxicity in vivo, as shown by reduced neuron damage and glial cell activation in the hippocampus. These results show that MSC mediate direct neuroprotection by reducing neuronal sensitivity to glutamate receptor ligands and altering gene expression, and suggest a link between the therapeutic effects of MSC and the activation of cell plasticity in the damaged CNS.

Properties and potential of bone marrow mesenchymal stromal cells from children with hematologic diseases.

BACKGROUND: Mesenchymal stromal cells (MSC) have become the focus of cellular therapeutics but little is known regarding bone marrow (BM) MSC derived from children. As MSC constitute part of BM stroma, we examined their properties in children with hematologic diseases. METHODS: BM MSC from children with non-malignant hematologic disorders and acute lymphoblastic leukemia (ALL) were isolated and expanded. MSC were immunophenotypically characterized and their functional characteristics were assessed by CFU-F assay and cell doubling time calculation. Their ability for trilineage differentiation was verified by molecular and histochemical methods. Apoptosis was evaluated and clonal analysis was performed. RESULTS: MSC were isolated from BM of all groups. They acquired the mesenchymal-related markers from the first passage, with a simultaneous decrease of hematopoietic markers. A very low percentage of apoptotic cells was detected in all passages. The proliferative and clonogenic capacity did not differ among groups, with the exception of ALL at diagnosis, in which they were defective. Histochemical and molecular analysis of differentiated MSC yielded characteristics for adipocytes, osteoblasts and chondrocytes. Clonal analysis in a number of BM samples revealed a highly heterogeneous population of cells within each clone. DISCUSSION: MSC from BM of children with hematologic disorders, with the exception of ALL at diagnosis, can be isolated in sufficient number and quality to serve as a potential source for clinical applications.

Functional, molecular and proteomic characterisation of bone marrow mesenchymal stem cells in rheumatoid arthritis.

OBJECTIVE: Bone marrow (BM) mesenchymal stem cells (MSCs) are being considered as potential therapeutic agents in various inflammatory autoimmune diseases for their tissue-repair and anti-inflammatory tissue-protective properties. This study investigates the reserves and function, the molecular and proteomic profile and the differentiation potential of BM MSCs in patients with active rheumatoid arthritis (RA). METHODS: We evaluated the frequency of MSCs in the BM mononuclear cell fraction using a limiting dilution assay, the proliferative/clonogenic potential and the capacity of cells to differentiate towards the osteogenic/chondrogenic/adipogenic lineages using appropriate culture conditions. We also assessed the molecular and proteomic characteristics in terms of inflammatory cytokine gene and protein expression, the relative telomere length and the survival characteristics of BM MSCs. RESULTS: MSCs from patients with RA (n = 26) and age- and sex-matched healthy individuals (n = 21) were similar in frequency, differentiation potential, survival, immunophenotypic characteristics, and protein profile. Patient MSCs, however, had impaired clonogenic and proliferative potential in association with premature telomere length loss. Transcriptome analysis revealed differential expression of genes related to cell adhesion processes and cell cycle progression beyond the G1 phase. Previous treatment with methotrexate, corticosteroids, anti-cytokine and biological agents or other disease-modifying anti-inflammatory drugs did not correlate with the clonogenic and proliferative impairment of BM MSCs. CONCLUSION: In spite of some restrictions related to the impaired clonogenic and proliferative potential, our findings support the use of autologous BM MSCs in RA and may have important implications for the ongoing efforts to repair tissue injury commonly seen in the course of the disease.

A sub-population of high proliferative potential-quiescent human mesenchymal stem cells is under the reversible control of interferon alpha/beta.

Type I interferon (IFN) is shown to control the reversible quiescence of a primitive human bone marrow mesenchymal stem cell (MSC) subpopulation. A 24 h pre-treatment of Stro1+/GlycoA- or CD45-/GlycoA- subpopulations with a monoclonal antibody (mAb) against the IFNAR1 chain of the human type I IFN receptor (64G12), or with a polyclonal anti-IFNalpha antibody, resulted in a marked increase in the number of very large colonies (CFU-F >3000 cells) obtained in the presence of low, but necessary, concentrations of bFGF. Over a 2-month culture period, this short activation promoted a faster and greater amplification of mesenchymal progenitors for adipocytes and osteoblasts. Activation correlated with inhibition of STAT1 and STAT2 phosphorylation and of STAT1 nuclear translocation. A non-neutralizing anti-IFNAR1 mAb was ineffective. We demonstrate that control and activated MSCs express ST3GAL3, a sialyltransferase necessary to produce the embryonic antigens SSEA-3 and -4. Interestingly, activated MSC progeny expressed SSEA-3 and -4 at a higher level than control cultures, but this was not correlated with a significant expression of other embryonic markers. As MSCs represent an essential tool in tissue regeneration, the use of 64G12, which rapidly recruits a higher number of primitive cells, might increase amplification safety for cell therapy.

Human cytomegalovirus infection of bone marrow myofibroblasts enhances myeloid progenitor adhesion and elicits viral transmission.

Human cytomegalovirus (CMV) infection of bone marrow transplant recipients can cause pancytopenia, as well as life-threatening interstitial pneumonia. CMV replicates actively in bone marrow stromal cells, whereas it remains latent in hematopoietic progenitors. Our aim was to study the influence of CMV infection on adherence of CD34(+) cells to the myofibroblastic component of human bone marrow and examine transmission of virus from myofibroblasts to CD34(+) cells. We show that smooth actin, but not fibronectin, organization is markedly modified by CMV infection of bone marrow stromal myofibroblasts. Nonetheless, CMV infection led to increased adherence of the CD34(+) progenitor cell line, KG1a, relative to adherence to uninfected myofibroblasts from the same donors. Adherence of CD34(+) cells to infected bone marrow myofibroblasts resulted in transfer of virions and viral proteins through close cell-to-cell contacts. This phenomenon may play a role in the pathophysiology of CMV bone marrow infection and in eventual virus dissemination.

[The hematopoietic stem cell and the stromal microenvironment]. / Les cellules souches hématopoïétiques (CSH) et microenvironnement stromal.

The hematopoietic system is the adult cellular model in which the biology of the stem cells is the best known and may be a model for numerous other tissues. This model is theoretically based on a hierarchy of cells, which begin on a stem cell that differentiates into mature cells through a large number of cellular stages including hematopoietic progenitors. Hematopoietic stem cells have three ain properties: (1) Self-renewal capacities. However, in transplantation experiments this property is limited and may be regulated by the stem cell niche. (2) Multipotentiality. Hematopoietic stem cells are capable of differentiation towards all myeloid and lymphoid lineages. However, recent experiments suggest that, like other somatic stem cells, hematopoietic stem cells are capable

Adhesion of CD34+ marrow precursors to human stroma is related to alphaSM actin expression by human marrow myofibroblasts.

We have studied the adhesion of human marrow CD34(+) precursors to stromal layer of nontransformed human marrow myofibroblasts (normal stroma) and to different stromal cell lines immortalized by T (PU-34) or t and T (L88/5, L87/4, L2Ori-, KM-102) oncogenes from simian virus 40 and E6, E7 oncogenes from human papilloma virus 16 (HS-27A, HS-23). Flow cytometry and Western blotting studies showed that cells from all lines were stromal myofibroblasts similar to normal stroma. Using an original method of adhesion measurement, we found that adhesion of CD34(+) cells was significantly increased on PU-34 cell layer as compared to normal stroma (43% vs. 27%) whereas adhesion on HS-27A and HS-23 was significantly decreased (11% and 8.5%, respectively), and adhesion on L88/5, L87/4, KM-102 and L2Ori- was negligible to nil (<6%). Adhesion of CD34(+) cells to stromal layers paralleled the expression of alpha smooth muscle (alphaSM) actin within the microfilaments of the cells from the different lines and was inversely correlated to their anchorage-independent growth in semisolid agar. These data show that adhesion to the stromal layer of CD34(+) cells is related to the alphaSM actin microfilamentous network in marrow myofibroblasts and that transformation can negatively affect this microfilamentous network and therefore adhesion of hematopoietic precursors.

Human marrow stromal precursors are alpha 1 integrin subunit-positive.

In this work we studied the expression of adhesion molecules on primate human and non-human marrow stromal cells (primary cultures and lines) and on human CD34(+) hematopoietic normal and leukemic precursors. Differential expression of alpha1 integrin subunit was observed, since this molecule was intensely expressed by marrow stroma but not detected on CD34(+) cells. We used this difference to select, in fresh bone marrow samples, alpha 1-positive cells. We found that all stromal precursors giving rise to colony-forming units-fibroblasts (CFU-F) were present in the alpha 1-positive fraction. No colonies were detected in the alpha 1-negative fraction even after 2 weeks of culture. Phenotypic studies of stromal cells derived from alpha1-positive cells and grown in long-term marrow culture indicated that these cells were similar to stromal cells from primary cultures. We also observed early upregulation of alpha 4 and alpha 2 integrin subunits in cultures derived from alpha1-positive cells with maximal expression by day 10 (26 and 51%, respectively) preceding a gradual decline to low to nil values at day 30 (4.5 and 12%). These data indicate that alpha 1 integrin subunit is a marker for both mature stromal cells and stromal precursors, while alpha 2 and alpha 4 integrin subunits are expressed primarily by immature cells.

CD40-ligand stimulates myelopoiesis by regulating flt3-ligand and thrombopoietin production in bone marrow stromal cells.

CD40 ligand (CD40L)/CD40 interactions play a central role in T-cell-dependent B-cell activation as previously shown by in vitro studies, the phenotype of CD40L knockout mice and the defective expression of CD40L in patients who have X-linked immunodeficiency with hyper-IgM. The distribution of CD40 in cells other than of myeloid and lymphoid lineages has suggested additional functions for this receptor/ligand couple. Here we show that CD40L stimulates myelopoiesis with a noticeable effect on megakaryocytopoiesis in cocultures of hematopoietic progenitor cells and bone marrow stromal cells. These results suggest a mechanism by which T-cell or platelet-associated or soluble CD40L may regulate myelopoiesis. (Blood. 2000;95:3758-3764)

Transplantation of gene-modified human bone marrow stromal cells into mouse-human bone chimeras.

Transplantation of BM stromal cells engineered to secrete therapeutic factors could represent a treatment for a large array of hematologic disorders. The aim of this study was to evaluate the susceptibility of human BM stromal cell precursors to retroviral gene transfer, then the ability of those to be transplanted in vivo. We have transduced a recombinant retrovirus encoding the mouse CD2 antigen into STRO-1+ cells selected from adult and fetal BM. Gene-modified stromal cells were injected intravenously into NOD-SCID mice engrafted previously with pieces of human fetal hematopoietic bone. Using nested PCR, transgenic human cells were detected both in the marrow of human bone grafts and in the BM, liver, and spleen of host mice 7 weeks after grafting. These data indicate that BM stromal progenitor cells are targets for retrovirus-mediated gene transfer and can home to hematopoietic tissues on engraftment through the bloodstream of nonconditioned hosts.

An in vitro model for the study of human bone marrow angiogenesis: role of hematopoietic cytokines.

This study describes a human bone marrow endothelial cell culture in which endothelial cells are organized into capillary tubes. These endothelial cells were positive for von Willebrand Factor, expressed CD34, CD31, and L-fucose residues, took up acetylated low-density lipoproteins, contained Weibel-Palade bodies, and were ensheathed in a basal lamina (which included laminin beta1, EDa+ and EDb+ fibronectin, and collagen type iv). Pericytes expressing alpha-smooth muscle (alpha-SM) actin were spatially associated with the capillary tubes and there was a highly significant correlation between the number of capillary tubes and pericytes. In this model, basal angiogenesis was found to be vascular endothelial growth factor (VEGF)-dependent, because neutralization of endogenous VEGF induced a dramatic regression in the number of tubes. However, the presence of alpha-SM actin-expressing pericytes in the linings of endothelial tubes partially prevented the VEGF-neutralized tube regression. We also observed that nitric oxide production contributed to basal angiogenesis and that upregulation of nitric oxide increased the number of tubes. Tube numbers also decreased when antibodies neutralizing the integrin alphavbeta5 were applied to the cultures. Moreover, addition of any of the hematopoietic cytokines, erythropoietin, stem cell factor, granulocytic colony stimulating factor, or granulomonocytic colony stimulating factor induced a highly significant increase in tube formation. When erythropoietin and granulocytic colony stimulating factor were added, this increase was larger than the maximum increase observed with VEGF. Thus, we have described an in vitro model for human bone marrow angiogenesis in which pericytes and basal lamina matrix were associated with endothelial cells and formed fully organized capillary tubes. In this model, cytokines known to regulate hematopoiesis also seemed to be mediators of angiogenesis. This culture system may therefore prove to be a valuable tool for the study of hematopoietic cytokines on angiogenesis.

Analysis of the microenvironment necessary for engraftment: role of the vascular smooth muscle-like stromal cells.

This is a review of recent data concerning the phenotype of human and murine stroma, as grown in long-term cultures. Using data on cytoskeletal and extracellular matrix protein expression, a sequential model of differentiation from mesenchymal (stem) cells to vascular-smooth muscle-like stromal cells is proposed. This model would apply, at least in the mouse, to stromal cells generated from different sites of hematopoiesis (bone marrow, fetal liver, spleen, and yolk sac). The in vivo counterparts of vascular-smooth muscle-like stromal cells in the different sites of definitive hematopoiesis are discussed.

Early progenitor cells from human mobilized peripheral blood express low levels of the flt3 receptor, but exhibit various biological responses to flt3-L.

The biological effects of flt3-L, and the expression of its tyrosine kinase receptor (flt3, CD135) were investigated on the immature subsets of human circulating peripheral blood progenitors obtained from cancer patients or normal volunteer donors, after mobilization with rhG-CSF or chemotherapy. flt3 was expressed at low levels, and its expression increased concomitantly with expression of CD38 within the CD34+ cell population. Despite this low-level expression, flt3-L exerted synergistic effects with a combination of c-kit ligand, IL-3, IL-6, GM-CSF and G-CSF, mainly to induce proliferation of CD34+/CD38- cells. In addition, flt3-L increased the detection of HPP-CFC, both immediately after cell selection, and after 7 and 14 d of cultures. We conclude that flt3-L is active on circulating early mobilized haemopoietic progenitors, despite the low- level expression of its receptor.

HCA, an immunoglobulin-like adhesion molecule present on the earliest human hematopoietic precursor cells, is also expressed by stromal cells in blood-forming tissues.

We have previously shown that the HCA/ALCAM (CD166) glycoprotein, a member of the immunoglobulin family that mediates both homophilic and heterophilic cell-cell adhesion, via the CD6 ligand, is expressed at the surface of all of the most primitive CD38(-/lo), Thy-1(+), rho123(lo), CD34(+) hematopoietic cells in human fetal liver and fetal and adult bone marrow. In the present report we show that HCA is also expressed by subsets of stromal cells in the primary hematopoietic sites that sequentially develop in the human embryo and fetus, ie, the paraaortic mesoderm, liver, thymus, and bone marrow. Adult bone marrow stromal cells established in vitro, including those derived from Stro-1(+) progenitors and cells from immortalized cell lines, express HCA. In contrast, no HCA expression could be detected in peripheral lymphoid tissues, fetal spleen, and lymph nodes. HCA membrane molecules purified from marrow stromal cells interact with intact marrow stromal cells, CD34(+) CD38(-) hematopoietic precursors, and CD3(+) CD6(+) peripheral blood lymphocytes. Finally, low but significant levels of CD6 are here for the first time detected at the surface of CD34(+) rho123(med/lo) progenitors in the bone marrow and in mobilized blood from healthy individuals. Altogether, these results indicate that the HCA/ALCAM surface molecule is involved in homophilic or heterophilic (with CD6) adhesive interactions between early hematopoietic progenitors and associated stromal cells in primary blood-forming organs.

Vascular smooth muscle differentiation of murine stroma: a sequential model.

Previous studies by our group showed that stromal cells from human long-term marrow cultures were mesenchymal cells following a vascular smooth muscle pathway. The present study using 58 immortalized stromal lines from different hematopoietic sites was conducted to verify whether this hypothesis also held true for murine stroma. Principal components analysis performed using cytoskeletal and extracellular matrix proteins allowed the segregation of five factors explaining more than 70% of the variance. Factor I, including osteopontin and vimentin, and factor II, laminins and fibronectins, were representative of the mesenchyme. The remaining three factors were representative of vascular smooth muscle: factor III, including alphaSM actin, SM alpha actinin, SM22alpha, EDa+ fibronectin, and thrombospondin-1; factor IV, metavinculin and h-caldesmon; and factor V, smooth muscle myosin SM1 and desmin. All lines expressed factors I and II; 53 lines expressed factor III, 35 lines expressed factor IV; and 11 lines expressed factor V. A second principal components analysis including membrane antigens indicated the cosegregration of vascular cell adhesion molecule-1 with osteopontin and that of Ly6A/E with vimentin, whereas CD34 and Thy-1 appeared to be independent factors. The heterogeneity of vascular smooth muscle markers expression suggests that harmonious maintenance of hematopoiesis depends on the cooperation between different stromal cell clones.

Retroviral-mediated marker gene transfer in hematopoiesis-supportive marrow stromal cells.

A Moloney-derived retrovirus containing both LacZ and NeoR genes (G1BgSVNa from Genetic Therapy, Inc.), was used to transduce human and murine bone marrow stromal cells. Different kinds of stromal cells that were able to support hematopoiesis were transduced by incubation for 24 h in the presence of virus-containing supernatant. Semiconfluent layers of MRC-5 (human, myofibroblastic, fetal, pulmonary) and MS-5 (murine, myofibroblastic, medullary) cells were successfully transduced after one 24-h incubation, as demonstrated by G418 resistance and Escherichia coli beta-galactosidase staining. In contrast, human stromal cells, purified from primary confluent layers grown for 3-4 weeks, could not be transduced. However, stromal cells generated after 10-12 days in culture from Stro-1+ and 1B10+ stromal precursors were successfully transduced in the presence of basic fibroblast growth factor. Transduced stromal cells maintained a myofibroblastic phenotype, although with a decreased number of alpha-SM actin-positive microfilaments in MS-5 cells. The ability to support the generation of stroma-adherent colony-forming cells from cocultured cord blood CD34+ cells after 4 weeks in culture was similar before and after transduction and G418 selection. In conclusion, human primary stromal precursors can be efficiently transduced, and the stromal cell phenotype and function are not significantly altered after retroviral-mediated transfer of marker genes.

Adhesion of Hematopoietic Precursors to Human Stroma: Studies Using Normal Marrow Stromal Myofibroblasts and a Stromal Cell Line Transformed by SV40.

Adhesion of hematopoietic precursors to the marrow microenvironment appears to be a prerequisite for proliferation and differentiation of hematopoietic cells. In this report, we have studied the adhesion of CFU-GM from marrow CD34+ precursors to human marrow myofibroblasts and to an human stromal cell line, L2Ori-, transformed by a vector comprising the whole of the SV40 viral sequence except for the origin of replication. This Stro-l(+) cell line presents characteristics similar to those of vascular smooth muscle cells, since (i) few cells were α-SM actin(+)while all cells were vimentin(+) but desmine(-) and a metavinculin band was consistently detected, (ii) all cells contained lysosomes filled with glycoproteins recognized by the monoclonal antibody 1B10, (iii) we detected EDa(+) EDb(-) pericellular fibronectin and intracellular ß1 and ß laminins and (iv) the cytokine expression pattern was similar to that of cells from colony-derived cell lines. Transformation was confirmed by abnormal and irregular growth (hallmarked by crises with rather slow growth between crises), and the presence of some very large cells with several nuclei. Although presenting an usual stromal phenotype, this cell line could not sustain hematopoiesis from marrow CD34+ cells in coculture due to a complete inability of adhesion of CD34+ cells (0% of adherent CFU-GM vs. 20% on normal stromal myofibroblasts). The lack of adhesion was explained by abnormal expression of adhesion molecules and molecules involved in the organization of extracellular matrix: (1) at the membrane level: the lack of VCAM-1 and significant differences in the distribution of CD44 and integrins α1, α3, α4 and ß as compared to normal stroma; (2) at the level of focal adhesions: the predominance of the 200 kD fragment of talin (as opposed to that of 230 kD in normal stroma), and a significantly decreased expression of vinculin and α-actinin; (3) at the level of microfilaments: the decrease in polymerized actin and a large decrease of α-SM actin synthesis; and (4) at the level of extracellular matrix: very few fibronectin fibres. These data show that transformation can strongly and negatively affect the function of hematopoiesis maintenance by disrupting intercellular and extracellular matrix adhesion mechanisms of hematopoietic cells to the stroma, in particular by affecting the fibronexus. Our data suggest the need for extreme caution when using SV40 transformed cell lines and instead, make the case for the use of other means of immortalization (such as thermosensitive T, other transforming sequences, introduction of inducible promoters).

Cytokines active on granulomonopoiesis: release and consumption by human marrow myoid [corrected] stromal cells.

Haemopoiesis is sustained and preferentially committed to granulomonopoiesis by myoid [corrected] stromal cells generated by colony-derived cell lines (CDCL). Using ELISA and RIA, we studied, in the supernatant of cells from CDCL, the time course of interleukins 3 and 6 (IL-3, IL-6), stem cell factor (SCF), granulocyte-macrophage, granulocyte and macrophage colony stimulating factors (GM-CSF, G-CSF and M-CSF), macrophage-inflammatory protein-1alpha (MIP-1alpha) and transforming growth factor beta1 (TGF beta1). IL-6, GM-CSF, M-CSF and MIP-1alpha were released into the supernatant after medium renewal and, except for M-CSF, addition of IL-1beta. G-CSF was detected only after addition of IL-1beta. SCF, contained in medium, first declined and then increased 24 h after medium renewal. Release of TGF beta1 started 24 h after medium renewal and lasted until day 7. IL-3, provided by horse serum, declined throughout the 7d of observation. In conclusion, stromal cells from CDCL synthesized and released into the supernatant. IL-6, GM-CSF, G-CSF, M-CSF and MIP-1alpha after stimulation by seric factor(s) and/or IL-1beta. TGF beta1 was synthesized and released without any obvious extraneous stimuli. There is no definite argument for synthesis of soluble SCF and IL-3. These data support a model where growth factors increase shortly after medium renewal, and negative regulators take over at a later time.