Andrea Zamperone

Human cardiac progenitor cell grafts as unrestricted source of supernumerary cardiac cells in healthy murine hearts.

Human heart harbors a population of resident progenitor cells that can be isolated by stem cell antigen‐1 antibody and expanded in culture. These cells can differentiate into cardiomyocytes in vitro and contribute to cardiac regeneration in vivo. However, when directly injected as single cell suspension, less than 1%‐5% survive and differentiate. Among the major causes of this failure are the distressing protocols used to culture in vitro and implant progenitor cells into damaged hearts. Human cardiac progenitors obtained from the auricles of patients were cultured as scaffoldless engineered tissues fabricated using temperature‐responsive surfaces. In the engineered tissue, progenitor cells established proper three‐dimensional intercellular relationships and were embedded in self‐produced extracellular matrix preserving their phenotype and multipotency in the absence of significant apoptosis. After engineered tissues were leant on visceral pericardium, a number of cells migrated into the murine myocardium and in the vascular walls, where they integrated in the respective textures.

Agonist monoclonal antibodies against HGF receptor protect cardiac muscle cells from apoptosis

Hepatocyte growth factor (HGF), a pleiotropic cytokine with mitogenic, motogenic, morphogenic, and antiapoptotic effects in various cell types, is a cardioprotective growth factor that can counteract the loss of cardiomyocytes usually observed in cardiac diseases. HGF is a quite unstable molecule in its biologically active heterodimeric form. Since all HGF-induced biological responses are mediated by its high-affinity tyrosine kinase receptor (Met/HGF-R) encoded by the Met gene, we asked whether a monoclonal antibody (MAb) that displays receptor full agonist activity could protect cardiac muscle cell lines from hydrogen peroxide-induced apoptosis. We report that the MAb efficiently inhibited hydrogen peroxide-induced cell shrinkage, DNA fragmentation, annexin V positivity, mitochondrial translocation of bax, and caspase activation. The MAb was thus able to counteract apoptosis evaluated by both morphological and biochemical criteria. The agonist activity of the MAb was mediated by Met/HGF-R, since a Met/HGF-R-specific short hairpin RNA (shRNA) inhibited both activation of transduction pathways and motility triggered by MAb DO-24. The protective antiapoptotic effect of MAb DO-24 was dependent on activation of the ras-MAPK Erk1/2 and phosphatidylinositol 3-kinase (PI3-kinase)-Akt transduction pathways, since it was abrogated by treatments with their specific pharmacological inhibitors, PD-98059 and wortmannin. Moreover, the MAb induced a motogenic, but not mitogenic, response in these cells, mimicking in all aspects the natural ligand HGF but displaying a significant higher stability than HGF in culture. This MAb may thus be a valuable substitute for HGF, being more easily available in a biologically active, highly stable, and purified form.

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(α1G) 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.

Electrical conditioning of adipose‐derived stem cells in a multi‐chamber culture platform

In tissue engineering, several factors play key roles in providing adequate stimuli for cells differentiation, in particular biochemical and physical stimuli, which try to mimic the physiological microenvironments. Since electrical stimuli are important in the developing heart, we have developed an easy‐to‐use, cost‐effective cell culture platform, able to provide controlled electrical stimulation aimed at investigating the influence of the electric field in the stem cell differentiation process. This bioreactor consists of an electrical stimulator and 12 independent, petri‐like culture chambers and a 3‐D computational model was used to characterize the distribution and the intensity of the electric field generated in the cell culture volume. We explored the effects of monophasic and biphasic square wave pulse stimulation on a mouse adipose‐derived stem cell line (m17.ASC) comparing cell viability, proliferation, protein, and gene expression. Both monophasic (8 V, 2 ms, 1 Hz) and biphasic (+4 V, 1 ms and −4 V, 1 ms; 1 Hz) stimulation were compatible with cell survival and proliferation. Biphasic stimulation induced the expression of Connexin 43, which was found to localize also at the cell membrane, which is its recognized functional mediating intercellular electrical coupling. Electrically stimulated cells showed an induced transcriptional profile more closely related to that of neonatal cadiomyocytes, particularly for biphasic stimulation. The developed platform thus allowed to set‐up precise conditions to drive adult stem cells toward a myocardial phenotype solely by physical stimuli, in the absence of exogenously added expensive bioactive molecules, and can thus represent a valuable tool for translational applications for heart tissue engineering and regeneration. Biotechnol. Bioeng. 2014;111: 1452–1463.

Isolation and Characterization of a Spontaneously Immortalized Multipotent Mesenchymal Cell Line Derived from Mouse Subcutaneous Adipose Tissue

The emerging field of tissue engineering and regenerative medicine is a multidisciplinary science that is based on the combination of a reliable source of stem cells, biomaterial scaffolds, and cytokine growth factors. Adult mesenchymal stem cells are considered important cells for applications in this field, and adipose tissue has revealed to be an excellent source of them. Indeed, adipose-derived stem cells (ASCs) can be easily isolated from the stromal vascular fraction (SVF) of adipose tissue. During the isolation and propagation of murine ASCs, we observed the appearance of a spontaneously immortalized cell clone, named m17.ASC. This clone has been propagated for more than 180 passages and stably expresses a variety of stemness markers, such as Sca-1, c-kit/CD117, CD44, CD106, islet-1, nestin, and nucleostemin. Furthermore, these cells can be induced to differentiate toward osteogenic, chondrogenic, adipogenic, and cardiogenic phenotypes. m17.ASC clone displays a normal karyotype and stable telomeres; it neither proliferates when plated in soft agar nor gives rise to tumors when injected subcutaneously in NOD/SCID-γ (null) mice. The analysis of gene expression highlighted transcriptional traits of SVF cells. m17.ASCs were genetically modified by lentiviral vectors carrying green fluorescent protein (GFP) as a marker transgene and efficiently engrafted in the liver, when injected in the spleen of NOD/SCID-γ (null) monocrotaline-treated mice. These results suggest that this non-tumorigenic spontaneously immortalized ASC line may represent a useful tool (cell model) for studying the differentiation mechanisms involved in tissue repair as well as a model for pharmacological/toxicological studies.

CagA of Helicobacter pylori interacts with and inhibits the serine-threonine kinase PRK2

CagA is a multifunctional toxin of Helicobacter pylori that is secreted into host epithelial cells by a type IV secretion system. Following host cell translocation, CagA interferes with various host–cell signalling pathways. Most notably this toxin is involved in the disruption of apical–basolateral cell polarity and cell adhesion, as well as in the induction of cell proliferation, migration and cell morphological changes. These are processes that also play an important role in epithelial‐to‐mesenchymal transition and cancer cell invasion. In fact, CagA is considered as the only known bacterial oncoprotein. The cellular effects are triggered by a variety of CagA activities including the inhibition of serine–threonine kinase Par1b/MARK2 and the activation of tyrosine phosphatase SHP‐2. Additionally, CagA was described to affect the activity of Src family kinases and C‐terminal Src kinase (Csk) suggesting that interference with multiple cellular kinase‐ and phosphatase‐associated signalling pathways is a major function of CagA. Here, we describe the effect of CagA on protein kinase C‐related kinase 2 (PRK2), which acts downstream of Rho GTPases and is known to affect cytoskeletal rearrangements and cell polarity. CagA interacts with PRK2 and inhibits its kinase activity. Because PRK2 has been linked to cytoskeletal rearrangements and establishment of cell polarity, we suggest that CagA may hijack PRK2 to further manipulate cancer‐related signalling pathways.

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.

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.

Correction: Human Cardiac Progenitor Spheroids Exhibit Enhanced Engraftment Potential

The fourteenth and fifteenth authors, Antonia Follenzi and Maria Prat, should be noted as contributing equally to this work. In the Author Contributions section, Antonia Follenzi (AF) should be listed as one of the persons who conceived and designed the experiments, contributed reagents/materials/analysis tools, and wrote the paper in addition to analyzed the data.

Human cardiac progenitor cell sheets as a source of autologous contractile and vascular cells for cardiac repair

Adequate cellular in-growth into biomaterials is one of the fundamental requirements in regenerative medicine. Type-I-collagen is the most commonly used material for soft tissue engineering, because it is nonimmunogenic and a highly porous network for cellular support. However, adequate cell in-growth and cell seeding has been suboptimal. Different densities of collagen scaffolds (0.3% to 0.8% (w/v)) with/without polymer knitting (poly-caprolactone (PCL)) were prepared. The structure of collagen scaffolds was characterized using scanning electronic microscopy (SEM) and HE staining. The mechanical strength of hybrid scaffolds was determined using tensile strength analysis. Cellular penetration and interconnectivity were evaluated using fluorescent bead distribution and human bladder smooth muscle cells and urothelium seeding. SEM and HE analysis showed the honeycomb structure and the hybrid scaffolds were adequately connected. The hybrid scaffolds were much stronger than collagen alone. The distribution of the beads and cells were highly dependent on the collagen density: at lower densities the beads and cells were more evenly distributed and penetrated deeper into the scaffold. The lower density collagen scaffolds showed remarkably deeper cellular penetration and by combining it with PCL knitting the tensile strength was enhanced. This study indicated that a 0.4% hybrid scaffold strengthened with knitting achieved the best cellular distribution.Human adult heart harbors a population of resident progenitor cells that can be isolated by Sca-1 antibody and expanded in culture. These cells can differentiate into cardiomyocytes and vascular cells in vitro and contribute to cardiac regeneration in vivo. However, when directly injected as single cell suspension, the survival rate and retention is really poor, less than 1% of injected cells being detectable in the hosttissue within few weeks. The present study aimed at investigating the possibility to produce scaffoldless, thick cardiac progenitor cell-derived cardiac patches by thermo-responsive technology. Human cardiac progenitors obtained from the auricles of patients were cultured as scaffoldless engineered tissues fabricated using temperature-responsive surfaces obtained by poly-N-isopropylacrylamide (PNIPAAm) surface immobilization. In the engineered tissue, progenitor cells established proper three-dimensional intercellular relationships and produced abundant extracellular matrix, while preserving their phenotype and plasticity. Cell phenotype and viability within the 3D construct were followed for 1 week, showing that no significant differentiation or apoptotic events occurred within the construct. After engineered tissues were leant on visceral pericardium, a number of cells migrated into the myocardium and in the vascular walls, where they integrated in the respective textures. The study demonstrates the suitability of such approach to deliver stem cells.Spinal cord injury and repair is one of the important focus areas in tissue regeneration. Mechanical trauma caused due to factors such as contusion, compression or involuntary stretching induce post-traumatic secondary tissue damage in many Spinal Cord Injury (SCI) patients. Therefore, there is a need for scaffolds that provide a conducive threedimensionsal (3D) environment for injured cells to attach and grow. In this study we propose to synthesize 3D polymeric scaffolds in order to study the mechanical and adhesive properties & the nature of the interactions between hyaluronan-based (HY) biomaterials and cells and tissues both in vitroandin vivo. Here we have synthesized 3D HY-based hydrogels with robust mechanical and adhesive properties and demonstrate the use of this material for neuronal-related applications such as the treatment of SCI. Cell culture and survivability studies were done with NSC-34 cells. Live/Dead assay performed on the cells revealed significant differences in the staining of live cells and showed increased viability and proliferation. The number of live cells in the HY-based hydrogels with 0.1% collagen showed higher cell numbers compared with the other hydrogels. In this study we show that Injectable HYbased hydrogels with high elasticity, comparable to the mechanical properties of nervous tissue have been used in this study to study their biocompatibility and neuroprotective properties and they show better affinity for neuronal cells.Calcium phosphates (CaP) obtained by biomineralisation in Simulated Boby Fluid have been used for decades to assess the mineralisation capability of biomaterials. Recently, they have been envisioned as potential agents to promote bone formation. In this study, we have fabricated and coated with calcium phosphate melt electrospun scaffolds whereby macropores permit adequate cell migration and nutrient transfer. We have systematically investigated the effect of coating and osteoinduction onto the response of ovine osteoblasts and we observed that the coating up-regulated alkaline phosphatase activity regardless of the in vitro culture conditions. Micro Computed Tomography revealed that only scaffolds cultured in an osteoinductive cocktail were capable of depositing mineralised matrix, and that CaP coated scaffolds were more efficient at promoting mineralisation. Theses scaffolds were subcutaneously implanted in athymic rats and this demonstrated that the osteoinduction was a pre-requisite for bone formation in this ectopic model. It showed that although the bone formation was not significantly different after 8 weeks, the CaP coated scaffolds were superior at inducing bone formation as evidenced by higher levels of mineralisation at earlier time points. This work demonstrated that CaP coating is not sufficient to induce bone formation; however the combination of osteoinduction and CaP coating resulted in earlier bone formation in an ectopic model.Introduction: Bladder regeneration using minced bladder mucosa is an alternative to costly and time-consuming conventional in vitro culturing of urothelial cells. In this method, the uroepithelium ...