Mesenchymal stem cells promote macrophage polarization toward M2b-like cells.

Mesenchymal stem or stromal cells (MSCs) act on different components of the immune response including macrophages (MΦs). Therefore this study has been committed to explore how MSCs may modify the effect of MΦ polarization upon an inductive environment using mouse bone marrow (BM)-derived "naïve", unpolarized MΦs. Phagocytosis of various MΦ subtypes was different since M1 and M2b showed poorer, while M2a higher rate of phagocytosis. MSCs significantly promoted yeast ingestion by M1 and M2b and diminished it by M2a cells. Under polarizing conditions, MSCs profoundly affected the TNFα production of MΦ subtypes since M1 and M2b MΦs produced less and M2a produced higher amount of TNFα while the amount of IL-10 was not affected. The most striking effect of MSCs was registered on M2b cells since the inflammatory TNFα dominance remarkably shifted to the immunosuppressive IL-10. Prepolarized M1 cells readily converted to M2a and M2b states when polarizing conditions changed from M1 to M2a or M2b induction, respectively. Repolarizing from M1 to M2a resulted in the decline of IL-10 and TNFα and defined elevation of Ym1 similar to levels characteristic to M2a primarily polarized from naïve BM-MΦs. Similarly, polarization of M1 to M2b MΦs was successful showing increase in IL-10 and reduction in TNFα levels characteristic to M2b cells. However, when co-culturing with MSCs, M1-M2a or M1-M2b transition was not affected. Crosstalk between MΦs and MSCs depended on PGE-2 since COX-2 inhibition reduced the effect of MSCs to establish an IL-10-dominant cytokine production by MΦs.

Activated T-cells and pro-inflammatory cytokines differentially regulate prostaglandin E2 secretion by mesenchymal stem cells.

In recent years it has become clear that mesenchymal stem or stromal cells (MSCs) are capable of modulating inflammatory and immune responses through interaction with a wide variety of cells. Whereas several studies indicated that PGE2 is one of the chief soluble mediators involved in these processes, here we investigated prostaglandin E2 (PGE2) production of murine bone marrow- (BM-) and adipose tissue- (Ad-) derived MSCs stimulated with pro-inflammatory cytokines TNF-α and IFN-γ, or co-cultured with ConA-induced T-cell blasts. We found that both MSC populations are able to produce high amounts of PGE2 in MSC/activated T-cell co-cultures. This effect was markedly attenuated when direct cell-cell contact was prevented in transwell system, indicating that the elicitation of the PGE2 secretion of MSCs is contact-dependent in this experimental setting. In contrast, when soluble recombinant pro-inflammatory cytokines were added to the MSC cultures, TNF-α and IFN-γ act synergistically to induce PGE2 production, whereas only high amount of TNF-α but not IFN-γ was able to do so alone. Although the PGE2 secretion by MSCs was completely abrogated by addition of indomethacin under all culture conditions tested, L-NMA, a NOS inhibitor could only partially inhibit it when the cells were elicited in the concomitant presence of TNF-α and IFN-γ. These results, combined with others, suggest that NO acts downstream of IFN-γ but upstream of COX2. Taken together, our findings demonstrate that the induction of PGE2 secretion by BM- and Ad-MSCs is not mediated by a single or unique, nonredundant molecular mechanism under different experimental conditions.

[Beyond genetics--the emerging role of epigenetics and its clinical aspects]. / A genetikán is túl - Az epigenetika eloretörése és orvosi vonatkozásai.

Analysis of genomic sequences has clearly shown that the genomic differences among species do not explain the diversity of life. The genetic code itself serves as only a part of the dynamic complexity that results in the temporal and spatial changes in cell phenotypes during development. It has been concluded that the phenotype of a cell and of the organism as a whole is more influenced by environmentally-induced changes in gene activity than had been previously thought. The emerging field of epigenetics focuses on molecular marks on chromatin; called the epigenome, which serve as transmitters between the genome and the environment. These changes not only persist through multiple cell division cycles, but may also endure for multiple generations. Irregular alterations of the epigenome; called epimutations, may have a decisive role in the etiology of human pathologies such as malignancies and other complex human diseases. Epigenetics can provide the missing link between genetics, disease and the environment. Therefore, this field may have an increasing impact on future drug design and serve as a basis for new therapeutic/preventative approaches.

Identical, similar or different? Learning about immunomodulatory function of mesenchymal stem cells isolated from various mouse tissues: bone marrow, spleen, thymus and aorta wall.

Mesenchymal stem or multipotent stromal cells (MSCs) have been implicated in tissue maintenance and repair and regulating immune effector cells through different mechanisms. These functions in mouse were primarily described for bone marrow (BM)-derived MSCs. To learn more about MSCs of different tissue origin, we compared the immunophenotype, differentiation ability to adipocyte and bone and immunomodulatory activity of MSCs isolated from BM, spleen, thymus and aorta wall of 14-day-old C57Bl/6 mice. The established cell lines fulfilled the requirements described for MSCs in terms of morphology, surface marker expression and differentiation potential although they were distinguishable regarding the expression pattern of the MSC markers and ability generating other cell types. Most importantly, a remarkable diversity was shown in the capacity of inhibition of mitogen- and alloantigen-induced T-cell proliferation, since BM- and spleen-derived MSCs were the most powerful aorta-derived MSCs were less effective, whereas thymus-derived mesenchymal cells were unable to block T-cell growth in vitro. Accordingly, BM, spleen and aorta, but not thymus-derived MSCs, in combination with BM hematopoietic cells were equally efficient to prevent streptozotocin-induced diabetes in vivo. These findings suggested that MSCs residing in different organs might stem from common ancestor; however, once populating into a given tissue microenvironment, they acquire specific properties mainly in the term of the immunoregulatory function.

Regulation of mouse microglia activation and effector functions by bone marrow-derived mesenchymal stem cells.

Mesenchymal stems or stromal cells (MSCs) are rare multipotent cells with potent regenerative and immunomodulatory properties. Microglial cells (MGs) are specialized tissue macrophages of the central nervous system (CNS) that continuously survey their environment with highly motile extensions. Recently, several studies have shown that MSCs are capable of reprogramming microglia into an "M2-like" phenotype characterized by increased phagocytic activity and upregulated expression of anti-inflammatory mediators in vitro. However, the precise polarization states of microglia in the presence of MSCs under physiological or under inflammatory conditions remain largely unknown. In this study, we found that MSCs induce a mixed microglia phenotype defined as Arg1-high, CD86-high, CD206-high, IL-10-high, PGE2-high, MCP-1/CCL2-high, IL-1ß-moderate, NALP-3-low, and TNF-α-low cells. These MSC-elicited MGs have high phagocytic activity and antigen-presenting ability. Lipopolysaccharide is able to shape this microglia phenotype quantitatively, but not qualitatively in the presence of MSCs. This unique polarization state resembles a novel regulatory microglia phenotype, which might contribute to the resolution of inflammation and to tissue repair in the CNS.

Positional identity of murine mesenchymal stem cells resident in different organs is determined in the postsegmentation mesoderm.

Although mesenchymal stem cells (MSCs) of distinct tissue origin have a large number of similarities and differences, it has not been determined so far whether tissue-resident MSCs are the progenies of one ancestor cell lineage or the results of parallel cell developmental events. Here we compared the expression levels of 177 genes in murine MSCs derived from adult and juvenile bone marrow and adult adipose tissue, as well as juvenile spleen, thymus, and aorta wall by quantitative real-time polymerase chain reaction and the results were partially validated at protein level. All MSC lines uniformly expressed a large set of genes including well-known mesenchymal markers, such as α-smooth muscle actin, collagen type I α-chain, GATA6, Mohawk, and vimentin. In contrast, pluripotency genes and the early mesodermal marker T-gene were not expressed. On the other hand, different MSC lines consistently expressed distinct patterns of Hox genes determining the positional identity of a given cell population. Moreover, MSCs of different origin expressed a few other transcription factors also reflecting their topological identity and so the body segment or organ to which they normally contributed in vivo: (1) thymus-derived cells specifically expressed Tbx5 and Pitx2; (2) spleen-derived MSCs were characterized with Tlx1 and Nkx2.5; (3) Pitx1 designated femoral bone marrow cells and (4) En2 appeared in aorta wall-derived MSCs. Thus, MSCs exhibited topographic identity and memory even after long-term cultivation in vitro. On the basis of these results, we suggest that postnatal MSCs isolated from different anatomical sites descend from precursor cells developing in the postsegmentation mesoderm.

Identification of galectin-1 as a critical factor in function of mouse mesenchymal stromal cell-mediated tumor promotion.

Bone marrow derived mesenchymal stromal cells (MSCs) have recently been implicated as one source of the tumor-associated stroma, which plays essential role in regulating tumor progression. In spite of the intensive research, the individual factors in MSCs controlling tumor progression have not been adequately defined. In the present study we have examined the role of galectin-1 (Gal-1), a protein highly expressed in tumors with poor prognosis, in MSCs in the course of tumor development. Co-transplantation of wild type MSCs with 4T1 mouse breast carcinoma cells enhances the incidence of palpable tumors, growth, vascularization and metastasis. It also reduces survival compared to animals treated with tumor cells alone or in combination with Gal-1 knockout MSCs. In vitro studies show that the absence of Gal-1 in MSCs does not affect the number of migrating MSCs toward the tumor cells, which is supported by the in vivo migration of intravenously injected MSCs into the tumor. Moreover, differentiation of endothelial cells into blood vessel-like structures strongly depends on the expression of Gal-1 in MSCs. Vital role of Gal-1 in MSCs has been further verified in Gal-1 knockout mice. By administering B16F10 melanoma cells into Gal-1 deficient animals, tumor growth is highly reduced compared to wild type animals. Nevertheless, co-injection of wild type but not Gal-1 deficient MSCs results in dramatic tumor growth and development.These results confirm that galectin-1 is one of the critical factors in MSCs regulating tumor progression.