Circulating mesenchymal stem cells

Mesenchymal precursor cells (MPCs) are multipotent cells capable of differentiating into various mesenchymal tissues, such as bone, cartilage, fat, tendon and muscle. They are present within both mesenchymal tissues and the bone marrow (BM). If marrow-derived MPCs are to have a role in repair and fibrosis of mesenchymal tissues, transit of these cells through the peripheral blood is to be expected. Although there is evidence for the existence of MPCs within the peripheral blood, results are debated and are not always reproducible. Variations in the methods of cell purification, culture and characterisation may explain the inconsistent results obtained in different studies.     

Immunomodulation by mesenchymal stem cells:Interplay between mesenchymal stem cells and regulatory lymphocytes

Mesenchymal stem cells(MSCs) possess immunomodulatory properties, which confer enormous potential for clinical application. Considerable evidence revealed their efficacy on various animal models of autoimmune diseases, such as multiple sclerosis, systemic lupus erythematosus and uveitis. MSCs elicit their immunomodulatory effects by inhibiting lymphocyte activation and proliferation, forbidding the secretion of proinflammatory cytokines, limiting the function of antigen presenting cells, and inducing regulatory T(Treg) and B(Breg) cells. The induction of Treg and Breg cells is of particular interest since Treg and Breg cells have significant roles in maintaining immune tolerance. Several mechanisms have been proposed regarding to the MSCs-mediated induction of Treg and Breg cells. Accordingly, MSCs induce regulatory lymphocytes through secretion of multiple pleiotropic cytokines, cell-to-cell contact with target cells and modulation of antigen-presenting cells. Here, we summarized how MSCs induce Treg and Breg cells to provoke immunosuppression.     

Bone marrow mesenchymal stem cells

Following the identification of bone marrow multipotent cells that could adhere to plastic and differentiate along numerous mesenchymal lineages in vitro, a considerable effort has been invested in characterizing and expanding these cells, which are now called “mesenchymal stem cells” (MSCs), in vitro. Over the years, numerous lines of evidence have been provided in support of their plasticity, their extraordinary immunomodulatory properties, their potential use for tissue engineering purposes, as well as their ability to be recruited to sites of injury, where they might contribute a “natural in vivo system for tissue repair.” Moreover, some studies have attempted the characterization of their cell‐surface specific antigens and of their anatomical location in vivo. Lastly, it has been shown that similar cells could be also isolated from organs other than the bone marrow. Despite this impressive body of investigations, numerous questions related to the developmental origin of these cells, their proposed pluripotency, and their role in bone modeling and remodeling and tissue repair in vivo are still largely unanswered. In addition, both a systematic phenotypic in vivo characterization of the MSC population and the development of a reproducible and faithful in vivo assay that would test the ability of MSCs to self‐renew, proliferate, and differentiate in vivo are just beginning. This brief review summarizes the current knowledge in the field of study of MSCs and the outstanding questions. J. Cell. Biochem. 109: 277–282, 2010. © 2009 Wiley‐Liss, Inc.     

Human fetal mesenchymal stem cells

Stem cells have been isolated at all stages of development from the early developing embryo to the post-reproductive adult organism. However, the fetal environment is unique as it is the only time in ontogeny that there is migration of stem cells in large numbers into different organ compartments. While fetal neural and haemopoietic stem cells (HSC) have been well characterised, only recently have mesenchymal stem cells from the human fetus been isolated and evaluated. Our group have characterised in human fetal blood, liver and bone marrow a population of non-haemopoietic, non-endothelial cells with an immunophenotype similar to adult bone marrow-derived mesenchymal stem cells (MSC). These cells, human fetal mesenchymal stem cells (hfMSC), are true multipotent stem cells with greater self-renewal and differentiation capacity than their adult counterparts. They circulate in first trimester fetal blood and have been found to traffic into the maternal circulation, engrafting in bone marrow, where they remain microchimeric for decades after pregnancy. Though fetal microchimerism has been implicated in the pathogenesis of autoimmune disease, the biological role of hfMSC microchimerism is unknown. Potential downstream applications of hfMSC include their use as a target cell for non-invasive pre-natal diagnosis from maternal blood, and for fetal cellular and gene therapy. Using hfMSC in fetal therapy offers the theoretical advantages of avoidance of immune rejection, increased engraftment, and treatment before disease pathology sets in. Aside from allogeneic hfMSC in utero transplantation, the use of autologous hfMSC has been brought a step forward with the development of early blood sampling techniques, efficient viral transduction and clonal expansion. Work is ongoing to determine hfMSC fate post-transplantation in murine models of genetic disease. In this review we will examine what is known about hfMSC biology, as well as discussing areas for future research. The implications of hfMSC trafficking in pregnancy will be explored and the potential clinical applications of hfMSC in prenatal diagnosis and fetal therapy discussed.     

Immunobiology of mesenchymal stem cells

Mesenchymal stem cells (MSCs) can be isolated from almost all tissues and effectively expanded in vitro. Although their true in situ properties and biological functions remain to be elucidated, these in vitro expanded cells have been shown to possess potential to differentiate into specific cell lineages. It is speculated that MSCs in situ have important roles in tissue cellular homeostasis by replacing dead or dysfunctional cells. Recent studies have demonstrated that in vitro expanded MSCs of various origins have great capacity to modulate immune responses and change the progression of different inflammatory diseases. As tissue injuries are often accompanied by inflammation, inflammatory factors may provide cues to mobilize MSCs to tissue sites with damage. Before carrying out tissue repair functions, MSCs first prepare the microenvironment by modulating inflammatory processes and releasing various growth factors in response to the inflammation status. In this review, we focus on the crosstalk between MSCs and immune responses and their potential clinical applications, especially in inflammatory diseases.     

Immunogenicity of allogeneic mesenchymal stem cells

Mesenchymal stem cells (MSCs) inhibit proliferation of allogeneic T cells and express low levels of major histocompatibility complex class I (MHCI), MHCII and vascular adhesion molecule-1 (VCAM-1). We investigated whether their immunosuppressive properties and low immunophenotype protect allogeneic rat MSCs against cytotoxic lysis in vitro and result in a reduced immune response in vivo. Rat MSCs were partially protected against alloantigen-specific cytotoxic T cells in vitro. However, after treatment with IFN-γ and IL-1β, MSCs upregulated MHCI, MHCII and VCAM-1, and cytotoxic lysis was significantly increased. In vivo, allogeneic T cells but not allogeneic MSCs induced upregulation of the activation markers CD25 and CD71 as well as downregulation of CD62L on CD4(+) T cells from recipient rats. However, intravenous injection of allo-MSCs in rats led to the formation of alloantibodies with the capacity to facilitate complement-mediated lysis, although IgM levels were markedly decreased compared with animals that received T cells. The allo-MSC induced immune response was sufficient to lead to significantly reduced survival of subsequently injected allo-MSCs. Interestingly, no increased immunogenicity of IFN-γ stimulated allo-MSCs was observed in vivo. Both the loss of protection against cytotoxic lysis under inflammatory conditions and the induction of complement-activating antibodies will likely impact the utility of allogeneic MSCs for therapeutic applications.     

Immunomodulatory activity of mesenchymal stem cells

Mesenchymal stem cells (MSCs) were discovered as a rare population of non-hematopoietic stem cells that reside in the bone marrow and interact closely with hematopoietic stem cells to support their growth and differentiation. MSCs are multipotent cells that have the ability to differentiate into cells of the mesenchymal lineage including adipocytes, osteocytes and chondrocytes and they have been reported to home to areas of tissue injury and participate in tissue repair. More recently, MSCs have also been described to possess anti-inflammatory and immunomodulatory properties that can affect multiple arms of the immune system. MSCs have been shown to inhibit T and B cell proliferation, downregulate the lytic activity of cytotoxic T lymphocytes and NK cells, inhibit the maturation and antigen-presenting function of dendritic cells and modulate macrophage function through both contact-dependent and contact-independent mechanisms. The administration of MSCs in models of autoimmune disease such as collagen-induced arthritis, EAE and autoimmune diabetes has provided additional evidence for an immunoregulatory role of MSCs supporting their use in controlling autoimmunity. The administration of allogeneic MSCs as immunosuppressive agents represents a viable approach as they appear to be largely non-immunogenic and clinical trials with allogeneic MSCs are currently underway in graftversus- host disease, Crohn's disease and type I diabetes indications. The immunomodulatory properties, mechanism of action and potential clinical utility of MSCs are reviewed herein.     

Immune modulation by mesenchymal stem cells

Mesenchymal stem cells (MSCs) can be derived from various adult tissues with multipotent and self‐renewal abilities. The characteristics of presenting no major ethical concerns, having low immunogenicity and possessing immune modulation functions make MSCs promising candidates for stem cell therapies. MSCs could promote inflammation when the immune system is underactivated and restrain inflammation when the immune system is overactivated to avoid self‐overattack. These cells express many immune suppressors to switch them from a pro‐inflammatory phenotype to an anti‐inflammatory phenotype, resulting in immune effector cell suppression and immune suppressor cell activation. We would discuss the mechanisms governing the immune modulation function of these cells in this review, especially the immune‐suppressive effects of MSCs.     

Endothelial origin of mesenchymal stem cells

Mesenchymal stem/stromal cells (MSCs) are fibroblastoid cells capable of long-term expansion and skeletogenic differentiation. While MSCs are known to originate from neural crest and mesoderm, immediate mesodermal precursors that give rise to MSCs have not been characterized. Recently, using human embryonic stem cells (hESCs), we demonstrated that mesodermal MSCs arise from APLNR⁺ precursors with angiogenic potential, mesenchymoangioblasts, which can be identified by FGF2-dependent colony-forming assay in serum-free semisolid medium. In this overview we provide additional insights on cellular pathways leading to MSC establishment from mesoderm, with special emphasis on endothelial-mesenchymal transition as a critical step in MSC formation. In addition, we highlight an essential role of FGF2 in induction of angiogenic cells with potential to transform into MSCs (mesenchymoangioblasts) or hematopoietic cells (hemangioblasts) from mesoderm, and discuss correlations of our in vitro findings with the course of angioblast development during embryogenesis.Key words: mesenchymoangioblast, hemangioblast, human embryonic stem cells, endothelial-mesenchymal transition, epithelial-mesenchymal transition, mesenchymal stem cells, endothelial cells, apelin receptor, FGFMesenchymal stem/stromal cells (MSCs) are defined as multipotent fibroblastoid cells that give rise to cells of the skeletal connective tissue including osteoblasts, chondrocytes and adipocytes.^1–4 Although MSCs were described more than 40 years ago and are widely used for cellular therapies, very little knowledge exists regarding the developmental origins of MSCs in the embryo, the hierarchy of MSC progenitors or heterogeneity of MSCs within tissues. It has been demonstrated that during embryonic development, MSCs arise from a two major sources: neural crest and mesoderm.^5–7 Using Cre-recombinase lineage tracing experiments, Takashima et al. identified Sox1⁺ neuroepithelium as pre-cursors of MSCs of neural crest origin. However, direct precursors of mesoderm-derived MSCs were unknown. To identify these precursors, we employed human embryonic stem cells (hESCs) directed toward mesendodermal differentiation in coculture with mouse bone marrow stromal cells OP9,⁸ using the experimental approach depicted in Figure 1. As shown in this differentiation system, mesoderm reminiscent of lateral plate/extraembryonic mesoderm in the embryo can be identified by expression of apelin receptor (APLNR), otherwise known as angiotensin receptor like-1 receptor. Because we observed a positive selective effect of FGF2 on production of mesenchymal cells from hESCs in OP9 coculture, we decided to test whether FGF2 can induce the formation of colonies with mesenchymal potential from APLNR⁺ mesodermal cells. Indeed, when we isolated APLNR⁺ cells from hESCs differentiated on OP9 for 2 days and placed them in serum-free semisolid medium containing FGF2, we observed the formation of sharply-circumscribed spheroid colonies formed by tightly packed cells with a gene expression profile representative of embryonic mesenchyme originating from lateral plate/extraembryonic mesoderm and CD140a⁺CD146⁺C D90⁺CD56⁺CD166⁺CD31⁻CD43⁻CD45⁻ phenotype typical of mesenchymal cells. Based on cellular composition, we designated these colonies as mesenchymal (MS) colonies and cells forming these colonies as MS colony-forming cells (MS-CFCs). MS colony formation required serum-free medium and was solely dependent on FGF2 as a colony-forming factor. MS colonies were significantly enhanced by PDGF-BB, but suppressed by VEGF, TGFβ1 and Activin A. When transferred to the adherent cultures in serum-free medium with FGF2, individual MS colonies gave rise to multi-potential mesenchymal cell lines with typical phenotype (CD146⁺ CD105⁺ CD73⁺ CD31⁻ CD43/45⁻), differentiation (chondro-, osteo- and adipogenesis) and robust proliferation (>80 doublings) potentials. Using single cell deposition assay, chimeric hESC lines and time-lapse studies we demonstrated the clonality/single cell origin of MS colonies.Open in a separate windowFigure 1Schematic diagram of the experimental approach used to identify precursors and cellular events leading to formation of mesoderm-derived MSCs. hESCs were committed to mesendodermal differentiation through coculture with OP9 for 2 days. APLNR⁺ mesodermal cells were selected using magnetic sorting. In serum-free semisolid medium, APLNR⁺ cells grew into FGF2-dependent compact spheroid colonies composed of mesenchymal cells. MS colonies were formed through establishment of tightly-packed single cell-derived cores (day 3 of clonogenic culture), which expanded into spheroid colonies (days 6 and 12 of clonogenic culture). To evaluate differentiation potential, MS colonies were collected at different stages of clonogenic culture and placed on OP9. The presence of endothelial and mesenchymal cells after coculture of MS colonies with OP9 was evaluated by flow cytometry and immunofluorescence. In addition, colonies at core stage (day 3 of clonogenic culture) and mature colonies (day 12 of clonogenic cultures) were collected for molecular profiling studies. To generate clonal MSC lines, individual mature colonies were plated on the collagen/fibronectin-coated plastic and cultured in presence of FGF2.MS-CFCs could be detected only transiently, with a major peak on day 2 of hESC differentiation and disappeared after 4 days of differentiation. Notably, MS-CFC activity was developed prior to the expression of CD73 and CD105 MSC markers and upregulation of MSC-related genes, i.e., before onset of mesenchymogenesis. APLNR⁺ cells isolated from hESC cultures differentiated for 3 days also formed colonies in response to FGF2; however, the vast majority of these colonies were composed of blood cells and had a morphology similar to the previously described blast (BL) or hemangioblast colonies, which identify a common precursor for hematopoietic and endothelial cells.^9,10To fully evaluate the differentiation potential of MS colonies, we collected these colonies from semisolid cultures and placed them back on OP9 feeders, which are known to support development of a broad range of mesodermal lineage cells, including hematopoietic, vascular and cardiac.^11–13 Using this approach, we confirmed that individual BL colonies possess hemangioblastic potential, i.e., generate both hematopoietic and endothelial cells. When MS colonies were picked from clonogenic cultures and cultured on OP9, we found that the majority of cells differentiated into CD146⁺CD31⁻CD43/CD45⁻ mesenchymal cells as expected. However, we also discovered that MS colonies gave rise to CD31/VE-cadherin⁺CD43/45⁻ endothelial cells, indicating that MS colonies similar to BL colonies possess endothelial potential. The endothelial potential of MS colonies was also confirmed by demonstration of tube formation by MS colonies grown on Matrigel. In contrast, MSC lines derived from MS colonies did not produce any endothelial cells after coculture with OP9 indicating a progressive restriction of differentiation potential following MSC formation. Because single MS-CFC shows potential to form endothelium and MSCs, we designated the MSC precursor identified by this colony-forming assay as mesenchymoangioblast.To define more precisely the cellular events leading to establishing MSCs, we examined the formation of MS colonies using time-lapse cinematography and analyzed the kinetic of their angiogenic potential. As demonstrated by time-lapse studies, APLNR⁺ mesodermal cells placed in semisolid medium possessed a high motility, which was more pronounced before and during the first cell division. Following several divisions, single APLNR⁺ cells formed a core, an immotile structure composed of a small number of tightly packed cells. While APLNR⁺ mesodermal cells lacked endothelial gene expression, molecular profiling of MS colonies at the core stage revealed that these cells acquired angioblastic gene expression profile as indicated by upregulation of FLT1, TEK, CDH5 (VE-cadherin), PECAM1 (CD31), FLI1, SELE (ELAM-1) and ICAM2 endothelial genes. When we collected MS cores (day 3 of clonogenic culture) and placed them on OP9, they formed predominantly VE-cadherin⁺ endothelial clusters, strongly indicating the endothelial nature of the core-forming cells. Subsequently, cells at the periphery of the core underwent endothelial-mesenchymal transition (EndMT) and formed a shell of tightly packed spindle-like cells around the core. When we picked colonies at this stage (day 6 of colony-forming culture) and placed them on OP9, most of the colonies (>70%) grew cell clusters composed of endothelial and mesenchymal cells. In contrast, mature MS colonies collected on day 12 of clonogenic culture formed predominantly clusters of mesenchymal cells, indicating a progressive loss of endothelial potential following colony maturation. Although no CD31 expression was detected in the mesenchymal cells composing mature MS colonies, these cells retained several endothelial traits including surface expression of endothelial tyrosine kinase (TEK or TIE2), FLT1 (VEGFR1) and endomucin. The critical role of EndMT in MS colony formation and MSC development was also congruous with our observation of the suppressive effect of VEGF, a known inhibitor of EndMT,^14,15 on MS colonies. When VEGF was added to MS clonogenic cultures, hESC-derived mesodermal cells were capable of forming angiogenic cores; however, these cores did not transform into mesenchymal cells, indicating that VEGF abrogates MS colony development at the core stage through inhibition of EndoMT. The schematic diagram demonstrating development of mesodermal MSCs is presented in Figure 2.Open in a separate windowFigure 2A model of mesoderm-derived MSC development from hESCs. Coculture with OP9 stromal cells predominantly induces hESC differentiation toward APLNR⁺ mesoderm. APLNR⁺ population contains angiogenic mesodermal precursors with either mesenchymal (mesenchymoangioblast) or hematopoietic (hemangioblast) potentials. Mesenchymoangioblasts and hemangioblasts arise sequentially during differentiation and can be revealed by MS and BL colony formation in response to FGF2. Development of MS and BL colonies in semisolid media proceed through a core stage at which APLNR⁺ cells form clusters of tightly packed cells with angiogenic potential. Subsequently, core-forming cells undergo EndMT giving rise to mesenchymal cells, which form a shell around the core developing into a mature MS colony. VEGF, EndMT inhibitor, blocks MS colony-formation at core stage. The ability of MS-CFCs to generate mesenchymal and endothelial cells can be revealed by coculture of individual colonies with OP9. Similar to MS colonies, BL colonies are formed through establishment of angiogenic core. However, hemangioblast core-forming cells undergo endothelial-hematopoietic transition and grew hematopoietic cells around the core.The close relationship between endothelial and hematopoietic cell development was recognized more than 130 years ago (reviewed by ref. ¹⁶) and confirmed in multiple modern studies.^9,17–22 However, the association between endothelial pre-cursors and MSCs during development was not well established, although cells with endothelial and mural cell potential were identified²³ and the critical role of EndMT in the formation of endocardial cushion²⁴ and testicular cords²⁵ in the embryo was acknowledged. Our hESC-based in vitro studies indicated that formation of mesodermal MSCs proceed through the endothelial stage and likely included at least two successive cycles of cell transitions. Initially APLNR⁺ mesoderm, which consists of fibroblast-like migratory cells, give rise to core structures composed of tightly packed endothelial cells in response to FGF2. Subsequently, endothelial cells forming cores undergo epithelial-mesenchymal transition, i.e., EndMT and form MSCs. The question remains how well this in vitro model reflects in vivo development. Although only sparse data exist regarding MSC precursors in the embryo, development of angiogenic hematopoietic precursors, hemangioblasts was studied more extensively in mammals and birds, and therefore parallels between in vivo and in vitro studies can be drawn. As we demonstrated,⁸ APLNR⁺ mesodermal cells collected from hESCs differentiated on OP9 for 3 days formed disperse BL colonies that identify hemangioblasts in vivo and in vitro.^9,26 Similar to MS colonies, the development of BL colonies required FGF2 and proceeded through angiogenic core formation. However, in contrast to MS cores, BL cores transformed into blood cells, i.e., underwent endothelial-hematopoietic transformation (see Fig. 2). Importantly, in vivo studies identified FGF2 as the essential factor in hemangioblast induction²⁷ analogous to our in vitro observation. In chicken embryo, the activation of FGF signaling leads to aggregation of migrating mesodermal cells adjacent to the endoderm, upregulation of VEGFR2 (KDR) expression, and subsequent formation of angioblasts and hemangioblasts.^28–30 This sequence of events leading to hemangioblast development in vivo considerably resembles what we observed in vitro, and highly suggests accurate recapitulation of embryonic development by our hESC differentiation model. Therefore, searching for an in vivo equivalent of mesenchymonagioblast would be a reasonable next step.In addition to embryonic development, EndMT is also implicated in several pathologies including cancer progression and development of cardiac and renal fibrosis.^31–34 Recently, Olsen group revealed that endothelial cells could be transformed directly into MSCs through overexpression of ALK2 or its activation by TGFβ2 or BMP4,¹⁵ indicating that endothelial cells could be an important source of MSCs in postnatal life. Conversely, the transition from MSCs to endothelial cells, has been also described in reference ³⁵. Based on these observations, a cycle of cell-fate transition from endothelium to MSCs and back to endothelium was proposed as a circuit controlling stem cell state.³⁶ Since multiple parallels could be drawn between EndMT described in adult tissues and during hESC differentiation, one may wonder whether bipotential cells with endothelial and MSC potential similar to embryonic mesenchymoangioblasts are present and constitute an important element of EndMT circuit in adults.In conclusion, the identification of mesenchymoangioblast as a clonogenic precursor of mesoderm-derived MSCs is an important step toward defining pathways of MSC development and specification. In addition, the demonstration of MSC formation from mesoderm through EndMT provides new insights into the mechanisms involved in establishment of MSCs.     

Immune modulation by mesenchymal stem cells

Mesenchymal stem cells (MSCs) have been shown to suppress activation of T cells both in vivo and in vitro. In vivo, this may be a way for the body to maintain homeostasis and inhibit immune activation in distinct compartments, such as the bone marrow and the interface between mother and fetus. MSCs modulate the immune function of the major cell populations involved in alloantigen recognition and elimination, including antigen presenting cells, T cells, and natural killer cells. The molecular mechanism that mediates the immunosuppressive effect of MSCs is not completely understood.     

TRPC expression in mesenchymal stem cells

Transient receptor potential canonical (TRPC) channels are key players in calcium homeostasis and various regulatory processes in cell biology. Little is currently known about the TRPC subfamily members in mesenchymal stem cells (MSC), where they could play a role in cell proliferation. We report on the presence of TRPC1, 2, 4 and 6 mRNAs in MSC. Western blot and immunofluorescence staining indicate a membrane and intracellular distribution of TRPC1. Furthermore, the decrease in the level of TRPC1 protein caused by RNA interference is accompanied by the downregulation of cell proliferation. These results indicate that MSC express TRPC1, 2, 4 and 6 mRNA and that TRPC1 may play a role in stem cell proliferation.     

间充质干细胞的免疫调节作用研究进展

间充质干细胞(mesenchymal stem cell,MSCs)属于成体干细胞,其具有广阔的临床应用前景.近年来人们发现MSCs有较强的免疫调节能力,并成功的将其用于治疗移植物抗宿主病(graft versus host disease,GVHD).据此推测MSCs对于其它慢性炎症性或者免疫相关性疾病可能同样具有治疗作用.本文将从MSCs对各类免疫细胞的作用、可能的机制、相关的动物实验以及临床研究等方面对MSCs的免疫调节作用研究进展作一综述.     

Endothelial origin of mesenchymal stem cells

Mesenchymal stem/stromal cells (MSCs) are fibroblastoid cells capable of long-term expansion and skeletogenic differentiation. While MSCs are known to originate from neural crest and mesoderm, immediate mesodermal precursors that give rise to MSCs have not been characterized. Recently, using human embryonic stem cells (hESCs), we demonstrated that mesodermal MSCs arise from APLNR+ precursors with angiogenic potential, mesenchymoangioblasts, which can be identified by FGF2-dependent colony-forming assay in serum-free semisolid medium. In this overview we provide additional insights on cellular pathways leading to MSC establishment from mesoderm, with special emphasis on endothelial-mesenchymal transition as a critical step in MSC formation. In addition, we highlight an essential role of FGF2 in induction of angiogenic cells with potential to transform into MSCs (mesenchymoangioblasts) or hematopoietic cells (hemangioblasts) from mesoderm, and discuss correlations of our in vitro findings with the course of angioblast development during embryogenesis.     

骨髓间充质干细胞的免疫学研究进展

间充质干细胞（mesenchymal stem cells,MSCs）是骨髓中除造血干细胞以外的另一种成体干细胞,广泛分布于动物体内骨髓、肝脏、脂肪等多种组织中。MSCS具有强大的自我更新能力和多向分化潜能,是移植领域应用前景广阔的再生来源细胞;同时,MSCs是一种重要的免疫调节细胞,MSCs在炎症细胞因子刺激后对免疫系统表现出很强的抑制作用,所以MSCs有望应用于减少免疫排斥,延长移植物存活时间,治疗相关免疫失调症,如自身免疫疾病等方面。本文主要对间充质干细胞与免疫系统相互作用的研究做相关介绍。