Re-expression of alpha skeletal actin as a marker for dedifferentiation in cardiac pathologies

Differentiation of foetal cardiomyocytes is accompanied by sequential actin isoform expression, i.e. down-regulation of the 'embryonic' alpha smooth muscle actin, followed by an up-regulation of alpha skeletal actin (αSKA) and a final predominant expression of alpha cardiac actin (αCA). Our objective was to detect whether re-expression of αSKA occurred during cardiomyocyte dedifferentiation, a phenomenon that has been observed in different pathologies characterized by myocardial dysfunction. Immunohistochemistry of αCA, αSKA and cardiotin was performed on left ventricle biopsies from human patients after coronary bypass surgery. Furthermore, actin isoform expression was investigated in left ventricle samples of rabbit hearts suffering from pressure- and volume-overload and in adult rabbit ventricular cardiomyocytes during dedifferentiation in vitro . Atrial goat samples up to 16 weeks of sustained atrial fibrillation (AF) were studied ultrastructurally and were immunostained for αCA and αSKA. Up-regulation of αSKA was observed in human ventricular cardiomyocytes showing down-regulation of αCA and cardiotin. A patchy re-expression pattern of αSKA was observed in rabbit left ventricular tissue subjected to pressure- and volume-overload. Dedifferentiating cardiomyocytes in vitro revealed a degradation of the contractile apparatus and local re-expression of αSKA. Comparable αSKA staining patterns were found in several areas of atrial goat tissue during 16 weeks of AF together with a progressive glycogen accumulation at the same time intervals. The expression of αSKA in adult dedifferentiating cardiomyocytes, in combination with PAS-positive glycogen and decreased cardiotin expression, offers an additional tool in the evaluation of myocardial dysfunction and indicates major changes in the contractile properties of these cells.     

Immunocytochemical analysis of the regeneration of myofibrils in long-term cultures of adult cardiomyocytes of the rat

Dissociated adult rat ventricular cardiomyocytes obtained from hearts by retrograde perfusion with collagenase were investigated in long-term cultures. Myofibril regeneration, isoprotein transition of alpha- and beta-myosin heavy chain (MHC), and M-band localization of M-creatine kinase in the reconstituting heart cells were studied. Myofibril formation was demonstrated by the use of antibodies against either cardiac C-protein or myomesin as early differentiation markers. Four days after plating, small myofibrils could be identified in attached cells in a perinuclear fashion; later in culture the cells displayed various shapes and myofibril distribution. Frequently a patchy distribution of myofibrils within the extending peripheral processes could be observed. Colocalization of sarcomeres and phalloidin-stained F-actin filament bundles was demonstrated by double fluorescence staining and by the use of high intensifying video microscopy and computerized image processing. The immunofluorescence distribution of alpha- and beta-MHC isoproteins in newly isolated and cultured cardiomyocytes changed from 100% alpha-MHC and 70% beta-MHC in rod-shaped cells to about 100% beta-MHC and 70% alpha-MHC in spread out cultured cells. This shift was corroborated by a relative gradual decline in alpha-MHC at the expense of increasing amounts of beta-MHC with time in culture as assessed by sodium dodecyl sulfate gel electrophoresis of total cell homogenates. In addition, whereas rod-shaped newly isolated cardiomyocytes showed a clear M-band association of M-creatine kinase as found in adult heart tissue, adult cultivated spread out cells did not show a cross-striated pattern after incubation with antibody. Taken together, these observations suggest that adult cardiomyocytes not only undergo extensive morphological transitions in long-term cultures, but also generate new myofibrillar structures lacking M-creatine kinase and containing the beta-MHC, thus fitting the characteristics of fetal myofibrils. These results indicate a change from the adult terminally differentiated to a less differentiated state of the cardiac cells in culture.     

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.     

Angiotensin II stimulates α-skeletal actin expression in cadiomyocytes in vitro and in vivo in the absence of hypertension

Using a specific alpha-skeletal actin antibody, we have previously shown, that during hypertension-associated cardiac hypertrophy in the rat, the expression of alpha-skeletal actin in the myocardium is increased, but maintains focal distribution, compared to normotensive animals. In the present study, we have investigated whether alpha-skeletal actin expression can be induced in the absence of hypertension. For this purpose, we have examined transgenic mice overexpressing angiotensinogen exclusively in the heart. These animals are characterized by high cardiac angiotensin II levels and cardiac hypertrophy accompanied or not by high blood pressure depending on their genetic background, i.e. presence of one or two renin genes. Alpha-skeletal actin levels were highly increased in transgenic compared to wild-type myocardium independently of the number of renin genes, indicating that angiotensin II can stimulate alpha-skeletal actin expression in normotensive animals. Additional in vitro experiments using cultured mouse and rat cardiomyocytes showed that angiotension II not only increases alpha-skeletal actin expression but also induces an increase of its incorporation within II-bands compared to control cardiomyocytes. Angiotensin II increases also the expression of alpha-smooth muscle actin in sarcomeres of cardiomyocytes as well as in fibroblastic cells present within the culture.     

Expression of fetal antigens by normal human skin cells grown in tissue culture.

Normal human sera are capable of causing complement-mediated lysis of normal human skin cells grown in tissue culture. This lytic reactivity can be completely removed by absorption with first trimester fetal tissue. Absorption with a variety of normal adult human tissues including lymphocytes, decidua, skin, and muscle are incapable of absorbing reactivity. Absorption of reactivity by fetal tissue is specific and not due to the introduction of anti-complementary or other nonspecific factors, as evidenced by the inability of simultaneous fetal absorption to remove reactivity from antisera with specificity for HLA antigens. Similarly, absorption of lytic sera with fetal calf serum proteins was incapable of removing reactivity against normal cells in tissue culture. It thus appears that normal human cells in tissue culture express antigens shared by the first trimester human fetus, but not present on a variety of adult human tissues. This "neoantigen" present on normal human cells when grown in tissue culture is a potential source of confusion and must be accounted for in searching for human tumor-specific antigens utilizing tissue culture cells.     

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.     

全反式维甲酸体外诱导P19细胞向心肌方向分化

目的探讨不同浓度全反式维甲酸(all-trans retinoic acid,atRA)诱导P19细胞向心肌分化的效力。方法细胞分成P19细胞组,2nm/L atRA诱导组,5nm/L atRA诱导组,8nm/L atRA诱导组。各组细胞经过诱导、聚集培养、聚集体贴壁培养10天后,RT-PCR检测GATA-4,α-肌球蛋白重链(α-myosin heavychain,α-MHC)的mRNA表达,免疫荧光双标检测α-sarcomeric actin和cTnT蛋白共表达,Western blot检测cTnT的蛋白表达。结果 atRA可诱导聚集P19细胞表达GA-TA-4、a-MHC mRNA;α-sarcomeric actin和cTnT的表达和共表达增加;5nm/L atRA组,8nm/L atRA组GATA-4、a-MHCmRNA的表达量显著高于P19细胞组;5nm/L atRA组,8nm/L atRA组两种蛋白的表达和共表达量显著高于P19细胞组,以5nm/L atRA组最高,显著高于其它组。结论 atRA可诱导聚集P19细胞向心肌分化,其中5nm/L atRA组效果最好。     

Functional 3‐D cardiac co‐culture model using bioactive chitosan nanofiber scaffolds

The in vitro generation of a three‐dimensional (3‐D) myocardial tissue‐like construct employing cells, biomaterials, and biomolecules is a promising strategy in cardiac tissue regeneration, drug testing, and tissue engineering applications. Despite significant progress in this field, current cardiac tissue models are not yet able to stably maintain functional characteristics of cardiomyocytes for long‐term culture and therapeutic purposes. The objective of this study was to fabricate bioactive 3‐D chitosan nanofiber scaffolds using an electrospinning technique and exploring its potential for long‐term cardiac function in the 3‐D co‐culture model. Chitosan is a natural polysaccharide biomaterial that is biocompatible, biodegradable, non‐toxic, and cost effective. Electrospun chitosan was utilized to provide structural scaffolding characterized by scale and architectural resemblance to the extracellular matrix (ECM) in vivo. The chitosan fibers were coated with fibronectin via adsorption in order to enhance cellular adhesion to the fibers and migration into the interfibrous milieu. Ventricular cardiomyocytes were harvested from neonatal rats and studied in various culture conditions (i.e., mono‐ and co‐cultures) for their viability and function. Cellular morphology and functionality were examined using immunofluorescent staining for alpha‐sarcomeric actin (SM‐actin) and gap junction protein, Connexin‐43 (Cx43). Scanning electron microscopy (SEM) and light microscopy were used to investigate cellular morphology, spatial organization, and contractions. Calcium indicator was used to monitor calcium ion flux of beating cardiomyocytes. The results demonstrate that the chitosan nanofibers retained their cylindrical morphology in long‐term cell cultures and exhibited good cellular attachment and spreading in the presence of adhesion molecule, fibronectin. Cardiomyocyte mono‐cultures resulted in loss of cardiomyocyte polarity and islands of non‐coherent contractions. However, the cardiomyocyte‐fibroblast co‐cultures resulted in polarized cardiomyocyte morphology and retained their morphology and function for long‐term culture. The Cx43 expression in the fibroblast co‐culture was higher than the cardiomyocytes mono‐culture and endothelial cells co‐culture. In addition, fibroblast co‐cultures demonstrated synchronized contractions involving large tissue‐like cellular networks. To our knowledge, this is the first attempt to test chitosan nanofiber scaffolds as a 3‐D cardiac co‐culture model. Our results demonstrate that chitosan nanofibers can serve as a potential scaffold that can retain cardiac structure and function. These studies will provide useful information to develop a strategy that allows us to generate engineered 3‐D cardiac tissue constructs using biocompatible and biodegradable chitosan nanofiber scaffolds for many tissue engineering applications. Biotechnol. Bioeng. 2013; 110: 637–647. © 2012 Wiley Periodicals, Inc.     

Early markers of regeneration following ductal ligation in rat submandibular gland

Rat submandibular glands can recover their function and secretory protein content following ductal ligation-induced atrophy. Morphological studies have established that following ligation, deligation of the gland allows the regeneration of new salivary gland tissue. However, little is known about changes happening during early regeneration following intra-oral duct ligation, which does not damage the parasympathetic nerves. Glands that had been 2 weeks ligated or 2 weeks ligated + 3 days deligated were compared. Tissue was prepared for histological, immunohistochemical (SMG-B and Ki-67) and immunocytochemical analyses (smooth muscle actin, aquaporin 5). Haematoxylin and eosin staining of deligated glands showed that some acini regained their cytoplasmic volume; moreover, the loss of Alcian blue/periodic acid-Schiff’s staining from the lumen of ducts suggested successful deligation. The deligated gland was characterized by atypical acinar-ductal branched structures, which were less frequent in the ligated gland and rarely seen in normal unoperated tissue. Myoepithelial cells were also investigated since changes in their morphology reflected changes in the acini morphology not readily detected by conventional staining. Actin staining revealed the presence of some shrunken acini in the atrophic tissue, whereas they had regained their normal morphology in the deligated gland suggesting that the acini were recovering. Some acini during deligation regained aquaporin 5 expression, which had decreased during atrophy. SMG-B protein, located in the pro-acinar cell during gland development and usually found in the intercalated duct cells in the adult, was detected in the newly formed acini of the deligated gland. This study suggests that morphological markers of regeneration appear as early as 3 days following ligation removal. The authors thank the Wellcome Trust for funding.     

Nuclear cardiac troponin and tropomyosin are expressed early in cardiac differentiation of rat mesenchymal stem cells

Nuclear actin - which is immunologically distinct from cytoplasmic actin - has been documented in a number of differentiated cell types, and cardiac isoforms of troponin I (cTnI) and troponin T (cTnT) have been detected in association with nuclei of adult human cardiac myocytes. It is not known whether these and related proteins are present in undifferentiated stem cells, or when they appear in cardiomyogenic cells following differentiation. We first tested the hypothesis that nuclear actin and cardiac isoforms of troponin C (cTnC) and tropomyosin (cTm) are present along with cTnI and cTnT in nuclei of isolated, neonatal rat cardiomyocytes in culture. We also tested the hypothesis that of these five proteins, only actin is present in nuclei of multipotent, bone marrow-derived mesenchymal stem cells (BM-MSCs) from adult rats in culture, but that cTnC, cTnI, cTnT and cTm appear early and uniquely following cardiomyogenic differentiation. Here we show that nuclear actin is present within nuclei of both ventricular cardiomyocytes and undifferentiated, multipotent BM-MSCs. We furthermore show that cTnC, cTnI, cTnT and cTm are not only present in myofilaments of ventricular cardiomyocytes in culture but are also within their nuclei; significantly, these four proteins appear between days 3 and 5 in both myofilaments and nuclei of BM-MSCs treated to differentiate into cardiomyogenic cells. These observations indicate that cardiac troponin and tropomyosin could have important cellular function(s) beyond Ca(2+)-regulation of contraction. While the roles of nuclear-associated actin, troponin subunits and tropomyosin in cardiomyocytes are not known, we anticipate that the BM-MSC culture system described here will be useful for elucidating their function(s), which likely involve cardiac-specific, Ca(2+)-dependent signaling in the nucleus.     

Interleukin-6-Mediated Autocrine Growth Promotion in Human Glioblastoma Multiforme Cell Line U87MG

Abstract: Human glioblastoma multiforme cell lines, brain tumor biopsy tissue, and normal human fetal brain synthesize interleukin (IL)-6 and IL-6 receptor (IL-6R). Neither of these is expressed in human neurons or neuroblastoma cell lines in culture. Astrocytes from fetal brain grown in culture retain the ability to synthesize IL-6 but do not express IL-6R as inferred from RT-PCR and Southern blot studies. Coexpression of IL-6 and IL-6R in the glioblastoma cell line U87MG is confirmed by immunofluorescence staining. Both specific monoclonal antibodies against IL-6 and IL-6R and antisense oligonucleotide to IL-6 mRNA inhibit the growth of U87MG cells in culture, suggesting the existence of a functional autocrine growth loop. Anti-IL-6 antibodies also inhibit the growth of glioblastoma cell lines U373 and U118. The expression of IL-6 by human fetal astrocytes in culture is highly suggestive of its role as an oncofetal protein responsible for rapid proliferation of fetal and tumor cells but not cells of adult brain.     

Immunostaining of vascular, perivascular cells and stromal components in human placental villi.

Fetal placental vessels develop and adapt in order to supply the fetus with nutrients. Immunostaining by antibodies against blood clotting factors, cell-cell and cell-matrix adhesion molecules, intermediate and contractile filaments, matrix components and enzymes give an overall view useful in assessing cell differentiation in placental villi. Endothelial cells stained positively for thrombomodulin, von Willebrand factor, CD34, CD31, cadherin-5, phalloidin and alpha 3-integrin. Trophoblastic cells were positive for cytokeratin, alpha 5 and alpha V integrins, L-prolyl hydroxylase and phalloidin. Myocytes from the media of stem villi exhibited positive vimentin, desmin, alpha-sm-actin and sm-myosin reactions but were CD26 negative. Myofibroblasts were vimentin, desmin, CD26, alpha-sm-actin and sm-myosin positive. Perivascular cells of intermediate and terminal villi were alpha-sm-actin, sm-myosin and anti-high molecular weight melanoma associated antigen (HMWMAA) positive. Trophoblastic and endothelial basement membranes were collagen IV positive. The most specific endothelial markers were cadherin-5, observed only at paracellular clefts, and von Willebrand factor. For perivascular cells, alpha-sm-actin, sm-myosin and HMWMAA provided a specific labeling. Differences in labeling intensity were noted along the cross section of the villous tree (vimentin, desmin, actin, myosin inward gradient). A continuity in the contractile function along the vessel length was indicated by alpha-sm-actin and sm-myosin positive cells, contrasting with the decreased von Willebrand reaction intensity. These data are discussed in relation to cell function and compared to cell culture results.     

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.     

Fetal and adult human skin fibroblasts display intrinsic differences in contractile capacity.

One of the differences between fetal and adult skin healing is the unique ability of fetal wounds to heal without contracture and scar formation. Studies have shown that the ratio between the three isoforms of TGFbeta is different in adult and fetal wounds. Thus, we analyzed the capacity of adult and fetal human skin fibroblasts to contract collagen gels after stimulation with TGFbeta isoforms. In control medium, fetal fibroblasts had a contractile capacity similar to that of adult fibroblasts. However, the growth capacity of fetal fibroblasts was completely inhibited, in contrast to adult fibroblasts. When cells were treated with TGFbeta, fetal fibroblasts showed an inhibition of their contractile capacity whereas adult fibroblasts further contracted gels. The contractile response was similar for all isoforms of TGFbeta although TGFbeta3 always had the strongest effect. We considered that the regulation of cell contractile capacity by TGFbeta may be dependent on receptor expression for this cytokine, on myofibroblast differentiation of the cells, or in cell links with matrix. Since TGFbeta receptor analysis did not show differences in receptor affinity, we studied the expression of alpha-smooth muscle (SM) actin, a fibroblast contractile marker and of three integrins, the cell surface receptors specific of the attachment of the fibroblasts with collagen matrix. We observed that the expression of alpha-SM actin and alpha3 and beta1 integrin subunits was increased when TGFbeta was added to the medium of adult fibroblasts whereas the levels of the alpha1 and alpha2 subunits were unchanged. In contrast, fetal fibroblasts treated with TGFbeta showed a decrease of alpha1, alpha2, and beta1 integrin expression but no change in alpha3 integrin and in alpha-SM actin expression. These results indicate that intrinsic differences between fetal and adult fibroblasts might explain their opposite responses to TGFbeta stimuli. The variations in their alpha-SM actin and integrin expression patterns represent potentially important mechanisms used by fetal fibroblasts to regulate their response to cytokines, and likely contribute to the resultant differences in the quality of wound repair.     

Smooth muscle actin expression during rat gut development and induction in fetal skin fibroblastic cells associated with intestinal embryonic epithelium

Abstract. Cytodifferentiation of smooth muscle cells has been analyzed immunocytochemically during rat intestinal development and in chimaeric intestines by using monoclonal antibodies reacting specifically with smooth muscle actin species ( CGA7 [10] and anti-α SM-1 [40]). As development proceeds, the various intestinal muscle layers differentiate in the following order: (1) cells expressing smooth muscle actin appear within the mesenchyme of the 15-day fetal rat intestine, in the circular muscle-forming area, the differentiation of cells in the presumptive longitudinal muscle layer starting with a 48-h delay; (2) smooth muscle fibers appear within the connective tissue core of the villi shortly after birth, in parallel with a progressive formation of the muscularis mucosae, which becomes clear-cut only in the course of the 2nd week after birth; (3) a distinct cell layer in the innermost part of the circular muscle layer arises during the perinatal period. Thereafter, the fluorescence pattern remains unchanged until the adult stage. Chimaeric intestines were constructed by the association of 14-day fetal intestinal epithelium and cultured fetal rat or human skin fibroblasts. These fibroblastic cells did not express actin at the time at which they were associated. The immunocytochemical analysis of smooth muscle actin in the hybrid intestines, which had developed as intracoelomic grafts for 12 days, revealed that the skin fibroblastic cells had been induced by the intestinal epithelial cells to differentiate into smooth muscle cells. Such a result was also obtained with allantoic endoderm. It was not obvious in cocultures of intestinal epithelium with skin fibroblastic cells. However, when intestinal epithelial cells were cocultured with intestinal mesenchymal cells, actin expression was stimulated in the latter cell population.     

Blood-derived small Dot cells reduce scar in wound healing

Wounds in fetal skin heal without scar, however the mechanism is unknown. We identified a novel group of E-cadherin positive cells in the blood of fetal and adult mice and named them "Dot cells". The percentage of Dot cells in E16.5 fetal mice blood is more than twenty times higher compared to adult blood. Dot cells also express integrin beta1, CD184, CD34, CD13low and Sca1low, but not CD45, CD44, and CD117. Dot cells have a tiny dot shape between 1 and 7 microm diameters with fast proliferation in vitro. Most of the Dot cells remain positive for E-cadherin and integrin beta1 after one month in culture. Transplantation of Dot cells to adult mice heals skin wounds with less scar due to reduced smooth muscle actin and collagen expression in the repair tissue. Tracking GFP-positive Dot cells demonstrates that Dot cells migrate to wounds and differentiate into dermal cells, which also express strongly to FGF-2, and later lose their GFP expression. Our results indicate that Dot cells are a group of previously unidentified cells that have strong wound healing effect. The mechanism of scarless wound healing in fetal skin is due to the presence of a large number of Dot cells.     

Human oral epithelial cell culture II. Keratin expression in fetal and adult gingival cells

Summary Epithelial cells from human fetal and adult gingiva were cultured in keratinocyte growth medium (KGM), a serum-free medium. The expression of keratin proteins in these cells was evaluated using immunohistochemistry and SDS-PAGE-immunoblot analysis and compared with expression in the tissue. Keratins 5, 6, 14, 16, and 19 were identified in cells cultured from both fetal and adult tissues. K19 was localized in basal cells of fetal oral tissue but was not seen in adult gingiva (except for scattered Merkel cells). K1 and K10 were expressed in tissue, but not in cultured cells. The keratin profiles of cultured epithelial cells from several adult donors were similar and were identical in cultures from primary through Passage 5. K13, a differentiation-specific keratin, was expressed in all suprabasal cells of fetal oral epithelium, but shows only spotty expression in adult gingival tissue. K13 was expressed in cultures of fetal cells, but very weakly or not at all in cultures of adult cells. K13 expression was greater in cultures grown with physiologic calcium concentrations (1.2 mM) than in those grown at 0.15 mM or less. Our findings are consistent with basal-like characters of these cells in 0.15 mM calcium growth conditions. Differentiation of fetal oral cells in culture to the suprabasal basal cell stage in 1.2 mM Ca²⁺ is shown by the expressionof K13. This work was supported by Biomedical Research grant RR05346, National Institutes of Health grant DE04660, University of Washington Graduate Fund and Hack Foundation Fund, Department of Periodontology, University of Washington.     

Synergistic effect of bioactive lipid and condition medium on cardiac differentiation of human mesenchymal stem cells from different tissues

Human umbilical cord mesenchymal stem cells (hUCMSCs) and human adipose tissue mesenchymal stem cells (hATMSCs) have the potential to differentiate into cardiomyocytes, making them promising therapeutic candidates for treating damaged cardiac tissues. Currently, however, the differentiated cells induced from hUCMSCs or hATMSCs can hardly display functional characteristics similar to cardiomyocytes. In this study, we have investigated the effects of bioactive lipid sphingosine‐1‐phosphate (S1P) on cardiac differentiations of hUCMSCs and hATMSCs in condition medium composed of cardiac myocytes culture medium or 5‐azacytidine. Cardiac differentiations were identified through immunofluorescence staining, and the results were observed with fluorescence microscopy and confocal microscopy. Synergistic effects of S1P and condition medium on cell viability were evaluated by MTT assays. Functional characteristics similar to cardiomyocytes were evaluated through detecting calcium transient. The differentiated hUCMSCs or hATMSCs in each group into cardiomyocytes showed positive expressions of cardiac specific proteins, including α‐actin, connexin‐43 and myosin heavy chain‐6 (MYH‐6). MTT assays showed that suitable differentiation time was 14 days and that the optimal concentration of S1P was 0.5 μM. Moreover, incorporation of S1P and cardiac myocytes culture medium gave rise to calcium transients, an important marker for displaying in vivo electrophysiological properties. This feature was not observed in the S1P‐5‐azacytidine group, indicating the possible lack of cellular stimuli such as transforming growth factor‐beta, TGF‐β. © 2016 The Authors. Cell Biochemistry and Function published by John Wiley & Sons, Ltd.     

Cocultures of fetal and adult cardiomyocytes yield rhythmically beating rod shaped heart cells from adult rats

Summary Different models of isolated cardiomyocytes are generally used for biochemical, biophysical, and pharmacological studies. Fetal cardiomyocytes can be easily cultured for several weeks regaining their ability for rhythmical and synchronous contractions. For investigations, differentiated myocytes derived from adult hearts are closer to the in situ situation. Unfortunately, these cells at best exhibit irregular and asynchronous contractions at very low frequencies. Already 1 d after seeding calcium-tolerant rod-shaped adult cardiomyocytes on a suitable substrate, the differentiated cells begin to dedifferentiate forming a confluent monolayer. After 7–10 d their beating activities are like those of fetal cells. Therefore, we tried to combine the advantages of both cell types to achieve fully differentiated cardiomyocytes, rod-shaped and rhythmically beating, isolated from adult hearts. Using contractile fetal cells as a substrate for the adult cardiomyocytes, freshly seeded differentiated adult myocytes are paced by the contraction frequency of the fetal monolayer. As a consequence, the rod-shaped adult cardiomyocytes reach frequencies of more than 140 cycles/min without external electrical stimulation. This model enables us to study cardiomyocytes in a state very similar to the in situ situation with respect to morphology, integrity, and contractile behavior. An abstract of this article was previously published in Eur. J. Cell Biol. 57 (Suppl.36): 86; 1992.