Chemical and physical stimuli induce cardiomyocyte differentiation from stem cells

In this study we investigated cardiomyocyte differentiation of rat bone marrow-mesenchymal stem cells (BM-MSCs) by treating the stem cells with conditions mimicking that of myocardial infarction. The extract from infarcted rat myocardium contained the biochemical factors arising after infarction. The cardiac contraction and relaxation were simulated by applying 4% strain at 1 Hz to the stem cells. We found that the extract from infarcted myocardium or 4% strain each alone could induce cardiomyocyte differentiation of BM-MSCs, as shown by expression of cardiomyocyte-specific genes including α-actin, connexin 43, Nkx2.5, MEF2c, GATA4, α-MHC, and Troponin I. Furthermore, a combination of the extract and 4% strain had stronger effects on cardiomyocyte differentiation than what either treatment alone had. Our results suggest that this in vitro model system simulates the local cardiac environment cues after infarction and may be useful in identifying the biochemical and physical factors involved in cardiomyocyte differentiation.     

Cardiac potential of stem cells from whole human umbilical cord tissue

We investigated the role of stem cells from human umbilical cord tissue in cardiomyocyte regeneration. The umbilical cord stem cells were initially characterized and differentiated in a myocardial differentiation medium containing 5‐azacytidine for 24 h. Differentiation into cardiomyocytes was determined by expression of cardiac specific markers, like cardiac α‐actin, connexin43, myosin, Troponin T, and ultrastructural analysis. In vivo, the transplanted umbilical cord stem cells were sprouting from local injection and differentiated into cardiomyocyte‐like cells in a rat myocardial infarction model. Echocardiography revealed increasing left ventricular function after umbilical cord stem cell transplantation. These results demonstrate that umbilical cord stem cells can differentiate into cardiomyocyte‐like cells both in vitro and in vivo. Therefore, human umbilical cord might represent a source of stem cells useful for cellular therapy and myocardial tissue engineering. Future studies are required to determine the molecular signaling mechanisms responsible for this phenomenon. J. Cell. Biochem. 107: 926–932, 2009. © 2009 Wiley‐Liss, Inc.     

Promoting effect of 5-azacytidine on the myogenic differentiation of bone marrow stromal cells

Bone marrow stromal cells (BMSC) can differentiate into various cell types including myocytes, which may be valuable in cellular therapy of myocardial infarction. In an attempt to increase the myogenic commitment of BMSC, we investigated the extent of conversion induced by the demethylation agent 5-azacytidine. BMSC isolated from the adult rat tibia were exposed in culture to 5microM 5-azacytidine for 24h, 1 day after seeding. The treatment was repeated at weekly intervals and the expression of muscle-specific proteins and genes was assessed. The results revealed that cultured cells lost the native expression of osteocalcin and alkaline phosphatase as a function of time and began to express connexin 43. Exposure to 5-azacytidine of BMSC induced, at 14 days, a myocyte-resembling phenotype that included the expression of muscle-specific proteins (sarcomeric alpha-actin, troponin T, desmin, alpha-actinin, and GATA-4) and genes (GATA-4, myoD, desmin, and alpha-actinin), numerous mitochondria and myofilaments; however, the latter did not form sarcomeres. Although some of these myogenic markers also appeared in untreated cells, exposure to 5-azacytidine induced an enhanced response of calcium channels, as well as a threefold increase in desmin and myoD gene expression and a twofold increase in alpha-actinin gene and protein expression above the control values. In conclusion, the results demonstrate a promoting effect of 5-azacytidine on the expression of muscle-specific proteins and genes in BMSC in culture. Notably, the myogenic differentiation takes place over a short period of time. Priming of mesenchymal cells to cardiomyogenic differentiation may have significant applications in cellular approaches to ameliorate muscle loss after myocardial ischemia.     

Formation of functional gap junctions in amniotic fluid‐derived stem cells induced by transmembrane co‐culture with neonatal rat cardiomyocytes

Amniotic fluid‐derived stem cells (AFSC) have been reported to differentiate into cardiomyocyte‐like cells and form gap junctions when directly mixed and cultured with neonatal rat ventricular myocytes (NRVM). This study investigated whether or not culture of AFSC on the opposite side of a Transwell membrane from NRVM, allowing for contact and communication without confounding factors such as cell fusion, could direct cardiac differentiation and enhance gap junction formation. Results were compared to shared media (Transwell), conditioned media and monoculture media controls. After a 2‐week culture period, AFSC did not express cardiac myosin heavy chain or troponin T in any co‐culture group. Protein expression of cardiac calsequestrin 2 was up‐regulated in direct transmembrane co‐cultures and media control cultures compared to the other experimental groups, but all groups were up‐regulated compared with undifferentiated AFSC cultures. Gap junction communication, assessed with a scrape‐loading dye transfer assay, was significantly increased in direct transmembrane co‐cultures compared to all other conditions. Gap junction communication corresponded with increased connexin 43 gene expression and decreased phosphorylation of connexin 43. Our results suggest that direct transmembrane co‐culture does not induce cardiomyocyte differentiation of AFSC, though calsequestrin expression is increased. However, direct transmembrane co‐culture does enhance connexin‐43‐mediated gap junction communication between AFSC.     

Inhibition of gap junctional intercellular communication in rat liver epithelial cells with transforming RNA

Previous studies indicated that transforming RNA, derived from the 3' half of the U5 small nuclear RNA first stem structure, suppressed the secretory protein translation in vitro. Gap junctions facilitate homeostatic control of cell growth and differentiation and their dysfunction has been correlated with carcinogenesis. Here, we reported that transforming RNA directly suppressed the gap junction protein, connexin 43, translation and thereby inhibited functional gap junction function in rat epithelial cells. Together with previous data, this implies that altered expression of transforming RNA itself is a potential mechanism in inhibiting gap junction function during carcinogenesis.     

Differentiation of human adipose‐derived stem cells into beating cardiomyocytes

Human adipose‐derived stem cells (ASCs) may differentiate into cardiomyocytes and this provides a source of donor cells for tissue engineering. In this study, we evaluated cardiomyogenic differentiation protocols using a DNA demethylating agent 5‐azacytidine (5‐aza), a modified cardiomyogenic medium (MCM), a histone deacetylase inhibitor trichostatin A (TSA) and co‐culture with neonatal rat cardiomyocytes. 5‐aza treatment reduced both cardiac actin and TropT mRNA expression. Incubation in MCM only slightly increased gene expression (1.5‐ to 1.9‐fold) and the number of cells co‐expressing nkx2.5/sarcomeric α‐actin (27.2%versus 0.2% in control). TSA treatment increased cardiac actin mRNA expression 11‐fold after 1 week, which could be sustained for 2 weeks by culturing cells in cardiomyocyte culture medium. TSA‐treated cells also stained positively for cardiac myosin heavy chain, α‐actin, TropI and connexin43; however, none of these treatments produced beating cells. ASCs in non‐contact co‐culture showed no cardiac differentiation; however, ASCs co‐cultured in direct contact co‐culture exhibited a time‐dependent increase in cardiac actin mRNA expression (up to 33‐fold) between days 3 and 14. Immunocytochemistry revealed co‐expression of GATA4 and Nkx2.5, α‐actin, TropI and cardiac myosin heavy chain in CM‐DiI labelled ASCs. Most importantly, many of these cells showed spontaneous contractions accompanied by calcium transients in culture. Human ASC (hASC) showed synchronous Ca²⁺ transient and contraction synchronous with surrounding rat cardiomyocytes (106 beats/min.). Gap junctions also formed between them as observed by dye transfer. In conclusion, cell‐to‐cell interaction was identified as a key inducer for cardiomyogenic differentiation of hASCs. This method was optimized by co‐culture with contracting cardiomyocytes and provides a potential cardiac differentiation system to progress applications for cardiac cell therapy or tissue engineering.     

Human embryonic and fetal mesenchymal stem cells differentiate toward three different cardiac lineages in contrast to their adult counterparts

Mesenchymal stem cells (MSCs) show unexplained differences in differentiation potential. In this study, differentiation of human (h) MSCs derived from embryonic, fetal and adult sources toward cardiomyocytes, endothelial and smooth muscle cells was investigated. Labeled hMSCs derived from embryonic stem cells (hESC-MSCs), fetal umbilical cord, bone marrow, amniotic membrane and adult bone marrow and adipose tissue were co-cultured with neonatal rat cardiomyocytes (nrCMCs) or cardiac fibroblasts (nrCFBs) for 10 days, and also cultured under angiogenic conditions. Cardiomyogenesis was assessed by human-specific immunocytological analysis, whole-cell current-clamp recordings, human-specific qRT-PCR and optical mapping. After co-culture with nrCMCs, significantly more hESC-MSCs than fetal hMSCs stained positive for α-actinin, whereas adult hMSCs stained negative. Furthermore, functional cardiomyogenic differentiation, based on action potential recordings, was shown to occur, but not in adult hMSCs. Of all sources, hESC-MSCs expressed most cardiac-specific genes. hESC-MSCs and fetal hMSCs contained significantly higher basal levels of connexin43 than adult hMSCs and co-culture with nrCMCs increased expression. After co-culture with nrCFBs, hESC-MSCs and fetal hMSCs did not express α-actinin and connexin43 expression was decreased. Conduction velocity (CV) in co-cultures of nrCMCs and hESC-MSCs was significantly higher than in co-cultures with fetal or adult hMSCs. In angiogenesis bioassays, only hESC-MSCs and fetal hMSCs were able to form capillary-like structures, which stained for smooth muscle and endothelial cell markers.Human embryonic and fetal MSCs differentiate toward three different cardiac lineages, in contrast to adult MSCs. Cardiomyogenesis is determined by stimuli from the cellular microenvironment, where connexin43 may play an important role.     

Immunolocalization of connexin 43 in the tooth germ of the neonatal rat

Summary Rabbit polyclonal antibodies to amino acids 346–360 of connexin 43, the ‘heart’ gap junction protein, were employed to immunolocalize connexin 43 gap junctions in the neonatal rat molar tooth germ. Connexin 43 appears early in the differentiation of both ectodermally derived and ectomesenchymally derived cells of the developing tooth. Connexin 43 immunoreactivity is present in the epithelial components of the enamel organ, including the area of the proximal and distal junctional complexes of the ameloblast layer, and the stratum intermedium, stellate reticulum and outer enamel epithelium. Secretory odontoblasts and developing alveolar bone also display a pattern of connexin 43 immunostaining. Both the epithelial and ectomesenchymally-derived components of the developing tooth acquire connexin 43 channels in a manner that correlates with cell differentiation. In addition, three regions can be defined by connexin 43 immunostaining: the epithelia of the enamel organ that are derived from the oral epithelium, the odontoblast layer derived from the ectomesenchyme, and the alveolar bone. The results suggest that connexin 43 may provide the mechanism for functional compartmentalization of the tissues associated with tooth formation. Compartmentalization suggested by connexin 43 expression could play important roles in the development and functions of these tissues.     

脂肪间充质干细胞体外分化成心肌样细胞

探讨大鼠脂肪间充质干细胞（adipose-derived mesenchymal stem cells,AMSC）体外分化成心肌样细胞的潜能,为自体干细胞移植治疗心肌梗死提供理论基础.采用消化法分离大鼠AMSC,培养于RPMI1640生长培养基中,倒置相差显微镜观察细胞形态发现,随着培养时间的延长,细胞形态趋向于心肌细胞,SQ RT-PCR检测表达心肌特异性基因：β-肌球蛋白重链（β-MHC）、α-肌球蛋白重链（α-MHC）、心房利钠肽（ANP）、心肌肌钙蛋白（cTnT）、心肌肌动蛋白、肌肉增强因子和GATA-4;免疫细胞化学和免疫荧光染色检测表达心肌细胞特异性蛋白：结蛋白、横纹肌辅肌动蛋白、心肌肌动蛋白和间隙连接蛋白45(connexin 45);Western印迹检测表达心肌特异性蛋白Nkx2.5. 实验表明,大鼠AMSC在体外培养条件下能分化成心肌样细胞,在组织工程学及干细胞移植领域有着良好的应用前景.