Hypoxia changes chemotaxis behaviour of mesenchymal stem cells via HIF‐1α signalling

Mesenchymal stem cells (MSCs) have drawn great attention because of their therapeutic potential. It has been suggested that intra‐venous infused MSCs could migrate the site of injury to help repair the damaged tissue. However, the mechanism for MSC migration is still not clear so far. In this study, we reported that hypoxia increased chemotaxis migration of MSCs. At 4 and 6 hours after culturing in hypoxic (1% oxygen) conditions, the number of migrated MSCs was significantly increased. Meanwhile, hypoxia also increased the expression of HIF‐1α and SDF‐1. Using small interference RNA, we knocked down the expression of HIF‐1α in MSCs to study the role of HIF‐1α in hypoxia induced migration. Our data indicated that knocking down the expression of HIF‐1α not only abolished the migration of MSCs, but also reduced the expression of SDF‐1. Combining the results of migration assay and expression at RNA and protein level, we demonstrated a novel mechanism that controls the increase of MSCs migration. This mechanism involved HIF‐1α mediated SDF‐1 expression. These findings provide new insight into the role of HIF‐1α in the hypoxia induced MSC migration and can be a benefit for the development of MSC‐based therapeutics for wound healing.     

Hypoxia and stem cell‐based engineering of mesenchymal tissues

Stem cells have the ability for prolonged self‐renewal and differentiation into mature cells of various lineages, which makes them important cell sources for tissue engineering applications. Their remarkable ability to replenish and differentiate in vivo is regulated by both intrinsic and extrinsic cellular mechanisms. The anatomical location where the stem cells reside, known as the “stem cell niche or microenvironment,” provides signals conducive to the maintenance of definitive stem cell properties. Physiological condition including oxygen tension is an important component of the stem cell microenvironment and has been shown to play a role in regulating both embryonic and adult stem cells. This review focuses on oxygen as a signaling molecule and the way it regulates the stem cells' development into mesenchymal tissues in vitro. The physiological relevance of low oxygen tension as an environmental parameter that uniquely benefits stem cells' expansion and maintenance is described along with recent findings on the regulatory effects of oxygen on embryonic stem cells and adult mesenchymal stem cells. The relevance to tissue engineering is discussed in the context of the need to specifically regulate the oxygen content in the cellular microenvironment in order to optimize in vitro tissue development. © 2009 American Institute of Chemical Engineers Biotechnol. Prog., 2009     

Bone marrow mesenchymal stem cells increase motility of prostate cancer cells via production of stromal cell‐derived factor‐1α

Prostate cancer frequently metastasizes to the bone, and the interaction between cancer cells and bone microenvironment has proven to be crucial in the establishment of new metastases. Bone marrow mesenchymal stem cells (BM‐MSCs) secrete various cytokines that can regulate the behaviour of neighbouring cell. However, little is known about the role of BM‐MSCs in influencing the migration and the invasion of prostate cancer cells. We hypothesize that the stromal cell‐derived factor‐1α released by BM‐MSCs may play a pivotal role in these processes. To study the interaction between factors secreted by BM‐MSCs and prostate cancer cells we established an in vitro model of transwell co‐culture of BM‐MSCs and prostate cancer cells DU145. Using this model, we have shown that BM‐MSCs produce soluble factors which increase the motility of prostate cancer cells DU145. Neutralization of stromal cell‐derived factor‐1α (SDF1α) via a blocking antibody significantly limits the chemoattractive effect of bone marrow MSCs. Moreover, soluble factors produced by BM‐MSCs greatly activate prosurvival kinases, namely AKT and ERK 1/2. We provide further evidence that SDF1α is involved in the interaction between prostate cancer cells and BM‐MSCs. Such interaction may play an important role in the migration and the invasion of prostate cancer cells within bone.     

Age-related changes in mesenchymal stem cells derived from rhesus macaque bone marrow

The regeneration potential of mesenchymal stem cells (MSCs) diminishes with advanced age and this diminished potential is associated with changes in cellular functions. This study compared MSCs isolated from the bone marrow of rhesus monkeys (rBMSCs) in three age groups: young (< 5 years), middle (8-10 years), and old (> 12 years). The effects of aging on stem cell properties and indicators of stem cell fitness such as proliferation, differentiation, circadian rhythms, stress response proteins, miRNA expression, and global histone modifications in rBMSCs were analyzed. rBMSCs demonstrated decreased capacities for proliferation and differentiation as a function of age. The production of heat shock protein 70 (HSP70) and heat shock factor 1 (HSF1) were also reduced with increasing age. The level of a core circadian protein, Rev-erb α, was significantly increased in rBMSCs from old animals. Furthermore, analysis of miRNA expression profiles revealed an up-regulation of mir-766 and mir-558 and a down-regulation of mir-let-7f, mir-125b, mir-222, mir-199-3p, mir-23a, and mir-221 in old rBMSCs compare to young rBMSCs. However, there were no significant age-related changes in the global histone modification profiles of the four histone core proteins: H2A, H2B, H3, and H4 on rBMSCs. These changes represent novel insights into the aging process and could have implications regarding the potential for autologous stem cells therapy in older patients.     

Induction of hepatocyte‐like cells from human umbilical cord‐derived mesenchymal stem cells by defined microRNAs

Generating functional hepatocyte‐like cells (HLCs) from mesenchymal stem cells (MSCs) is of great urgency for bio‐artificial liver support system (BALSS). Previously, we obtained HLCs from human umbilical cord‐derived MSCs by overexpressing seven microRNAs (HLC‐7) and characterized their liver functions in vitro and in vivo. Here, we aimed to screen out the optimal miRNA candidates for hepatic differentiation. We sequentially removed individual miRNAs from the pool and examined the effect of transfection with remainder using RT‐PCR, periodic acid—Schiff (PAS) staining and low‐density lipoprotein (LDL) uptake assays and by assessing their function in liver injury models. Surprisingly, miR‐30a and miR‐1290 were dispensable for hepatic differentiation. The remaining five miRNAs (miR‐122, miR‐148a, miR‐424, miR‐542‐5p and miR‐1246) are essential for this process, because omitting any one from the five‐miRNA combination prevented hepatic trans‐differentiation. We found that HLCs trans‐differentiated from five microRNAs (HLC‐5) expressed high level of hepatic markers and functioned similar to hepatocytes. Intravenous transplantation of HLC‐5 into nude mice with CCl₄‐induced fulminant liver failure and acute liver injury not only improved serum parameters and their liver histology, but also improved survival rate of mice in severe hepatic failure. These data indicated that HLC‐5 functioned similar to HLC‐7 in vitro and in vivo, which have been shown to resemble hepatocytes. Instead of using seven‐miRNA combination, a simplified five‐miRNA combination can be used to obtain functional HLCs in only 7 days. Our study demonstrated an optimized and efficient method for generating functional MSC‐derived HLCs that may serve as an attractive cell alternative for BALSS.     

Bioassembly of three‐dimensional embryonic stem cell‐scaffold complexes using compressed gases

Tissues are composed of multiple cell types in a well‐organized three‐dimensional (3D) microenvironment. To faithfully mimic the tissue in vivo, tissue‐engineered constructs should have well‐defined 3D chemical and spatial control over cell behavior to recapitulate developmental processes in tissue‐ and organ‐specific differentiation and morphogenesis. It is a challenge to build a 3D complex from two‐dimensional (2D) patterned structures with the presence of cells. In this study, embryonic stem (ES) cells grown on polymeric scaffolds with well‐defined microstructure were constructed into a multilayer cell‐scaffold complex using low pressure carbon dioxide (CO₂) and nitrogen (N₂). The mouse ES cells in the assembled constructs were viable, retained the ES cell‐specific gene expression of Oct‐4, and maintained the formation of embryoid bodies (EBs). In particular, cell viability was increased from 80% to 90% when CO₂ was replaced with N₂. The compressed gas‐assisted bioassembly of stem cell‐polymer constructs opens up a new avenue for tissue engineering and cell therapy. © 2009 American Institute of Chemical Engineers Biotechnol. Prog., 2009     

Adipose‐derived mesenchymal stem cells and regenerative medicine

Adipose tissue‐derived mesenchymal stem cells (ADSCs) are multipotent and can differentiate into various cell types, including osteocytes, adipocytes, neural cells, vascular endothelial cells, cardiomyocytes, pancreatic β‐cells, and hepatocytes. Compared with the extraction of other stem cells such as bone marrow‐derived mesenchymal stem cells (BMSCs), that of ADSCs requires minimally invasive techniques. In the field of regenerative medicine, the use of autologous cells is preferable to embryonic stem cells or induced pluripotent stem cells. Therefore, ADSCs are a useful resource for drug screening and regenerative medicine. Here we present the methods and mechanisms underlying the induction of multilineage cells from ADSCs.     

利用微载体悬浮培养人脐带间充质干细胞

随着干细胞研究的不断深入,干细胞功能分化研究和临床应用转化的需求日益提升。人脐带间充质干细胞(human umbilical cord mesenchymal stem cells, hUCMSCs)来源广泛,不仅自我更新能力强、能够分化成多种类型的成体细胞,而且其自身具有免疫调节能力,不易引发免疫排斥反应,在干细胞功能分化研究和临床应用中具有巨大应用前景和应用潜力。目前,传统的细胞培养方式培养效率低、细胞活性较差,不能满足日益增长的研究和应用需求。本研究利用微载体结合旋转瓶的悬浮培养方法,通过优化细胞接种量及转速等影响因素,快速获得大量高质量的人脐带间充质干细胞。经悬浮培养总细胞量可高达到7×10 ⁸个细胞/L,而且细胞活性较高,MSC 特异性标记物表达良好,在恢复平面培养后仍能维持MSC的正常细胞形态和增殖能力。高效脐带间充质干细胞悬浮培养体系的初步建立,为未来的干细胞功能分化研究和临床应用奠定了基础。     

Difluoromethylornithine stimulates early cardiac commitment of mesenchymal stem cells in a model of mixed culture with cardiomyocytes

The efficiency of in vitro mesenchymal stem cell (MSC) differentiation into the myocardial lineage is generally poor. In order to improve cardiac commitment, bone marrow GFP+MSCs obtained from transgenic rats were cultured with adult wild type rat cardiomyocytes for 5 days in the presence of difluoromethylornithine (DFMO), an inhibitor of polyamine synthesis and cell proliferation. The percentage of GFP+MSCs showing cardiac myofibril proteins (cMLC2, cTnI) was about threefold higher after DFMO addition (3%) relative to the untreated control (1%). Another set of experiments was performed with cardiomyocytes incubated for 1 day in the absence of glucose and serum and under hypoxic conditions (pO2 < 1%), in order to simulate severe ischemia. The percentage of cardiac committed GFP+MSCs was about 5% when cultured with the hypoxic/starved cardiomyocytes and further increased to 7% after DFMO addition. The contemporary presence of putrescine in DFMO-treated cells markedly blunted differentiation, while the cytostatic mitomycin C was not able to induce cardiac commitment. The involvement of histone acetylation in DFMO-induced differentiation was evidenced by the strong attenuation of cardiac commitment exerted by anacardic acid, an inhibitor of histone acetylase. Moreover, the percentage of acetylated histone H3 significantly increased in bone marrow MSCs obtained from wild type rats and treated with DFMO. These results suggest that polyamine depletion can represent a useful strategy to improve MSC differentiation into the cardiac lineage, especially in the presence of cardiomyocytes damaged by an ischemic environment.     

Long‐term culture optimization of human omentum fat‐derived mesenchymal stem cells

Recent scientific explorations in search of novel sources for autologous transplantation transpired an alternative source of MSCs (mesenchymal stem cells) derived from omentum fat. The scarcity of experimental evidences probing into the biosafety concerns of omentum fat‐derived MSC under prolonged culture conditions limits its applicability as an efficient tool in regenerative medicine. This study, thus, aims to optimize human omentum fat‐derived MSC in four different media [DMEM (Dulbecco's modified Eagle's medium) LG (low glucose), DMEM KO (knock out), α‐MEM (α‐minimal essential media) and DMEM F12] in the facets of phenotypic characterization, growth kinetics, differentiation and karyotyping under prolonged culture. The cells exhibited a similarity in expression profile for the majority of markers with evidential variations in certain markers. The relevance of omentum fat‐derived MSCs became evident from its triumphant differentiation potential and karyotypic stability substantiated even at later passage. The results obtained from growth curve and PDT (population doubling time) lead to optimization of appropriate media for omentum fat‐derived stem cell research, thereby bringing omentum fat into the forefront of regenerative medicine.     

3D culture increases pluripotent gene expression in mesenchymal stem cells through relaxation of cytoskeleton tension

Three‐dimensional (3D) culture has been shown to improve pluripotent gene expression in mesenchymal stem cells (MSCs), but the underlining mechanisms were poorly understood. Here, we found that the relaxation of cytoskeleton tension of MSCs in 3D culture was critically associated with the expressional up‐regulation of Nanog. Cultured in spheroids, MSCs showed decreased integrin‐based cell–matrix adhesion but increased cadherin‐based cell–cell interaction. Different from that in 2D culture, where MSCs exhibited branched and multiple‐directed F‐actin stress bundles at the cell edge and strengthened stress fibres transversing the cell body, MSCs cultured in spheroids showed compact cell body, relaxed cytoskeleton tension with very thin cortical actin filament outlining the cell, and increased expression of Nanog along with reduced levels of Suv39h1 (H3K9 methyltransferase) and H3K9me3. Notably, pharmaceutical inhibition of actin polymerization with cytochalasin D or silencing Suv39h1 expression with siRNA in 2D‐cultured MSCs elevated the expression of Nanog via H3K9 demethylation. Thus, our data suggest that 3D culture increases the expression of Nanog through the relaxation of actin cytoskeleton, which mediates reduced Suv39h1 and H3K9me3 levels.     

Comparative evaluation of morphology and osteogenic behavior of human Wharton's jelly mesenchymal stem cells on 2D culture plate and 3D biomimetic scaffold

Expansion of seeded human Wharton's jelly mesenchymal stem cells (hWJ-MSCs) on 2D culture plates and 3D nano-hydroxyapatite/chitosan/gelatin scaffolds, from morphology and osteoactivity points of view, were investigated. Cell attachment and spreading, temporal expression profiles of selected osteogenic gene and protein markers, intracellular alkaline phosphatase enzyme activity (ALP activity), and matrix mineralization were assayed over the course of the experiments. Morphological results demonstrated hWJ-MSCs had greater affinity to adhere onto the 3D scaffold surface, as the number and thickness of the filopodia were higher in the 3D compared with 2D culture system. Functionally, the intracellular ALP activity and extracellular mineralization in 3D scaffolds were significantly greater, in parallel with elevation of osteogenic markers at the mRNA and protein levels at all-time point. It is concluded that 3D scaffolds, more so than 2D culture plate, promote morphology and osteogenic behavior of WJ-MSCs in vitro, a promising system for MSCs expansion without compromising their stemness before clinical transplantation.