Monophasic and Biphasic Electrical Stimulation Induces a Precardiac Differentiation in Progenitor Cells Isolated from Human Heart

Electrical stimulation (ES) of cells has been shown to induce a variety of responses, such as cytoskeleton rearrangements, migration, proliferation, and differentiation. In this study, we have investigated whether monophasic and biphasic pulsed ES could exert any effect on the proliferation and differentiation of human cardiac progenitor cells (hCPCs) isolated from human heart fragments. Cells were cultured under continuous exposure to monophasic or biphasic ES with fixed cycles for 1 or 3 days. Results indicate that neither stimulation protocol affected cell viability, while the cell shape became more elongated and reoriented more perpendicular to the electric field direction. Moreover, the biphasic ES clearly induced the upregulation of early cardiac transcription factors, MEF2D, GATA-4, and Nkx2.5, as well as the de novo expression of the late cardiac sarcomeric proteins, troponin T, cardiac alpha actinin, and SERCA 2a. Both treatments increased the expression of connexin 43 and its relocation to the cell membrane, but biphasic ES was faster and more effective. Finally, when hCPCs were exposed to both monophasic and biphasic ES, they expressed de novo the mRNA of the voltage-dependent calcium channel Cav 3.1(α(1G)) subunit, which is peculiar of the developing heart. Taken together, these results show that ES alone is able to set the conditions for early differentiation of adult hCPCs toward a cardiac phenotype

Human Cardiac Progenitor Spheroids Exhibit Enhanced Engraftment Potential

A major obstacle to an effective myocardium stem cell therapy has always been the delivery and survival of implanted stem cells in the heart. Better engraftment can be achieved if cells are administered as cell aggregates, which maintain their extra-cellular matrix (ECM). We have generated spheroid aggregates in less than 24 h by seeding human cardiac progenitor cells (hCPCs) onto methylcellulose hydrogel-coated microwells. Cells within spheroids maintained the expression of stemness/mesenchymal and ECM markers, growth factors and their cognate receptors, cardiac commitment factors, and metalloproteases, as detected by immunofluorescence, q-RT-PCR and immunoarray, and expressed a higher, but regulated, telomerase activity. Compared to cells in monolayers, 3D spheroids secreted also bFGF and showed MMP2 activity. When spheroids were seeded on culture plates, the cells quickly migrated, displaying an increased wound healing ability with or without pharmacological modulation, and reached confluence at a higher rate than cells from conventional monolayers. When spheroids were injected in the heart wall of healthy mice, some cells migrated from the spheroids, engrafted, and remained detectable for at least 1 week after transplantation, while, when the same amount of cells was injected as suspension, no cells were detectable three days after injection. Cells from spheroids displayed the same engraftment capability when they were injected in cardiotoxin-injured myocardium. Our study shows that spherical in vivo ready-to-implant scaffold-less aggregates of hCPCs able to engraft also in the hostile environment of an injured myocardium can be produced with an economic, easy and fast protocol

Correction: Human Cardiac Progenitor Spheroids Exhibit Enhanced Engraftment Potential

[This corrects the article DOI: 10.1371/journal.pone.0137999.]

Isolation of stromal stem cells from adipose tissue

Adipose tissue has been shown to be particularly advantageous as source of mesenchymal stem cells (MSCs), because of its easy accessibility, and the possibility of obtaining stem cells in high yields. MSCs are obtained from the so-called Stromal Vascular Fraction, (SVF), exploiting their property of adhering to plastic surfaces and can be further purified by positive or negative immunomagnetic selection with appropriately chosen antibodies. These cells (Stromal Stem Cells, SSCs) can then be directly analyzed, frozen in liquid nitrogen, or expanded for further applications, e.g., for tissue engineering and regenerative medicine. The methodology described here in detail for SSCs isolated from mouse subcutaneous adipose tissue can be applied to human tissues, such as epicardium

Inhibition of polarity-regulating kinase PAR1b contributes to <i>Helicobacter pylori</i> inflicted DNA Double Strand Breaks in gastric cells

The serine/threonine kinase Par1 is a core component of the machinery that sets up polarity in the embryo and regulates cell fate decisions but its role in the homeostasis of adult tissues is poorly understood. Inhibition of Par1 by the bacterium Helicobacter pylori (H. pylori) represents the only established pathology that affects Par1 function in an adult epithelium. Thus, during chronic H. pylori infection of the gastric mucosa Par1 is one of the targets of the non-obligate H.pylori cytotoxic protein and oncogene CagA, which stimulates inflammation and triggers morphological changes, both believed to contribute to the gastric cancer risk imposed by H. pylori infection. Based on Par1’s role in cell polarity, it has been speculated that Par1 inhibition affects epithelial polarity. Here we report the unexpected finding that CagA-mediated Par1-inhibition promotes the generation of DNA Double Strand Breaks in primary gastric epithelial cells, which likely contributes to the reported accumulation of mutations in chronically infected mucosal cells. Abbreviations: AGS: human gastric adenocarcinoma cell line; CM: CagA Multimerization (and Par1 binding) domain; H. pylori: Helicobacter pylori; DSB: Double Strand Break; HGECs: human (primary) gastric epithelial cells; IB: immunoblot; IF: immunofluorescence; MOI: Multiplicity of Infection; ROS: reactive oxygen species; Par1: Partitioning Defective 1 kinase; WT: wild type</p

Role of Pleckstrin 2 in Improved Erythropoiesis of Transferrin-Treated Beta-Thalassemic Mice

Abstract Erythropoiesis is a process during which multipotent hematopoietic stem cells proliferate, differentiate and ultimately produce enucleated reticulocytes. Terminal erythroid differentiation begins at the morphologically recognizable pro-erythroblast (pro-E) stage and is completed when orthochromatic erythroblasts (ortho-E) expel their nuclei to produce reticulocytes. Progressive differentiation between these stages occurs in homologous cell division progressively doubling proportions of pro-E, basophilic (baso-E), polychromatophilic (poly-E), and ortho-E, and multiple signaling pathways are involved in the generation of enucleated erythroid cells, including multiple steps requiring actin cytoskeleton reorganization. We have previously shown that β-thalassemic mice (th1/th1) demonstrate a disordered progression from pro-E to baso-E and that exogenous transferrin therapy restores normal proportion of early stage erythroid precursors in th1/th1 mice (Liu Blood 2013). To identify genes that play novel function in different stages of terminal erythropoiesis, we performed RNA seq analysis of sorted bone marrow pro-E from WT, th1/th1, and transferrin-treated th1/th1 mice. We identify pleckstrin-2 (plek2) as a gene of interest with a 15-fold increase in plek2 mRNA expression in th1/th1 relative to WT mice, normalized in transferrin-treated th1/th1 mice. Plek2 is an actin binding protein, like pleckstrin-1, contains a central DEP domain known to bind RacGTPase, is Epo dependent, and is expressed in all stages of terminal erythropoiesis. We evaluate plek2 mRNA and protein expression in sorted bone marrow erythroid precursors from WT, th1/th1, and transferrin-treated th1/th1 mice. Our data demonstrates a statistically significant increase in plek2 mRNA in th1/th1 relative to WT mice, with the highest expression of plek2 in poly-E, normalized in transferrin-treated th1/th1 mice (Figure 1A). A similar pattern of increased protein concentration in th1/th1 relative to WT mice and normalization in transferrin-treated th1/th1 mice is evident in sorted bone marrow samples (Figure 1B). Prior in vitro studies demonstrate that membrane localization of plek2 is required for erythroid differentiation. Thus, we performed sub-cellular fractionation in bone marrow erythroid precursors and determined for the first time that in sorted erythroblasts from WT bone marrow, plek2 is found exclusively in the cytoplasm in pro-E and in both cytoplasm and membrane from baso-E to ortho-E (Figure 2), co-localized with actin filaments in the membrane (data not shown). In contrast, sorted erythroblasts from th1/th1 bone marrow reveal membrane-associated plek2 starting from pro-E, demonstrating earlier co-localization with actin filaments (data not shown) and suggesting an earlier activation of plek2 and consequent actin cytoskeleton reorganization during erythroid differentiation in th1/th1 mice, normalized in transferrin-treated th1/th1 mice (Figure 2). Erythropoiesis involves a complicated and incompletely understood set of potentially related molecular signals influencing cell survival, differentiation, enucleation, and release into the circulation. For example, although Epo increases survival, Epo signaling also activates RacGTPases, inhibiting enucleation. Recent in vitro data demonstrates that knockdown of plek2 affected enucleation with significantly lower reticulocyte count. Although the involvement of RacGTPase in plek2-mediated erythroid differentiation has not been explored, we hypothesize that plek2 activation triggers RacGTPase and prevents enucleation in th1/th1 mice. Our data demonstrates that RacGTPase concentration is increased in sorted bone marrow erythroid precursors from th1/th1 relative to WT mice and normalized in transferrin-treated th1/th1 mice (Figure 1B). These results suggest that plek2 plays an important role in erythropoiesis likely as a key factor in the improved enucleation of transferrin-treated th1/th1 mice. Disclosures No relevant conflicts of interest to declare. </jats:sec