Marilena Minieri

Hepatocyte Growth Factor Effects on Mesenchymal Stem Cells: Proliferation, Migration, and Differentiation

Hepatocyte growth factor (HGF), a pleiotropic cytokine of mesenchymal origin promoting migration, proliferation, and survival in a wide spectrum of cells, can also modulate different biological responses in stem cells, but the mechanisms involved are not completely understood so far. In this context, we show that short‐term exposure of mesenchymal stem cells (MSCs) to HGF can induce the activation of its cognate Met receptor and the downstream effectors ERK1/2, p38MAPK, and PI3K/Akt, while long‐term exposure to HGF resulted in cytoskeletal rearrangement, cell migration, and marked inhibition of proliferation through the arrest in the G1‐S checkpoint. When added to MSCs, the K252A tyrosine kinase inhibitor prevented HGF‐induced responses. HGFs effect on MSC proliferation was reversed by p38 inhibitor SB203580, while the effects on cell migration were abrogated by PI3K inhibitor Wortmannin, suggesting that HGF acts through different pathways to determine its complex effects on MSCs. Prolonged treatment with HGF induced the expression of cardiac‐specific markers (GATA‐4, MEF2C, TEF1, desmin, α‐MHC, β‐MHC, and nestin) with the concomitant loss of the stem cell markers nucleostemin, c‐kit, and CD105.

Cerium oxide nanoparticles protect cardiac progenitor cells from oxidative stress.

Cardiac progenitor cells (CPCs) are a promising autologous source of cells for cardiac regenerative medicine. However, CPC culture in vitro requires the presence of microenvironmental conditions (a complex array of bioactive substance concentration, mechanostructural factors, and physicochemical factors) closely mimicking the natural cell surrounding in vivo, including the capability to uphold reactive oxygen species (ROS) within physiological levels in vitro. Cerium oxide nanoparticles (nanoceria) are redox-active and could represent a potent tool to control the oxidative stress in isolated CPCs. Here, we report that 24 h exposure to 5, 10, and 50 μg/mL of nanoceria did not affect cell growth and function in cardiac progenitor cells, while being able to protect CPCs from H(2)O(2)-induced cytotoxicity for at least 7 days, indicating that nanoceria in an effective antioxidant. Therefore, these findings confirm the great potential of nanoceria for controlling ROS-induced cell damage.

Multiscale three-dimensional scaffolds for soft tissue engineering via multimodal electrospinning

A novel (scalable) electrospinning process was developed to fabricate bio-inspired multiscale three-dimensional scaffolds endowed with a controlled multimodal distribution of fiber diameters and geared towards soft tissue engineering. The resulting materials finely mingle nano- and microscale fibers together, rather than simply juxtaposing them, as is commonly found in the literature. A detailed proof of concept study was conducted on a simpler bimodal poly(epsilon-caprolactone) (PCL) scaffold with modes of fiber distribution at 600 nm and 3.3 microm. Three conventional unimodal scaffolds with mean diameters of 300 nm and 2.6 and 5.2 microm, respectively, were used as controls to evaluate the new materials. Characterization of the microstructure (i.e. porosity, fiber distribution and pore structure) and mechanical properties (i.e. stiffness, strength and failure mode) indicated that the multimodal scaffold had superior mechanical properties (Youngs modulus approximately 40MPa and strength approximately 1MPa) in comparison with the controls, despite the large porosity ( approximately 90% on average). A biological assessment was conducted with bone marrow stromal cell type (mesenchymal stem cells, mTERT-MSCs). While the new material compared favorably with the controls with respect to cell viability (on the outer surface), it outperformed them in terms of cell colonization within the scaffold. The latter result, which could neither be practically achieved in the controls nor expected based on current models of pore size distribution, demonstrated the greater openness of the pore structure of the bimodal material, which remarkably did not come at the expense of its mechanical properties. Furthermore, nanofibers were seen to form a nanoweb bridging across neighboring microfibers, which boosted cell motility and survival. Lastly, standard adipogenic and osteogenic differentiation tests served to demonstrate that the new scaffold did not hinder the multilineage potential of stem cells.

Criticality of the Biological and Physical Stimuli Array Inducing Resident Cardiac Stem Cell Determination

The replacement of injured cardiac contractile cells with stem cell‐derived functionally efficient cardiomyocytes has been envisaged as the resolutive treatment for degenerative heart diseases. Nevertheless, many technical issues concerning the optimal procedures to differentiate and engraft stem cells remain to be answered before heart cell therapy could be routinely used in clinical practice. So far, most studies have been focused on evaluating the differentiative potential of different growth factors without considering that only the synergistic cooperation of biochemical, topographic, chemical, and physical factors could induce stem cells to adopt the desired phenotype. The present study demonstrates that the differentiation of cardiac progenitor cells to cardiomyocytes does not occur when cells are challenged with soluble growth factors alone, but requires strictly controlled procedures for the isolation of a progenitor cell population and the artifactual recreation of a microenvironment critically featured by a fine‐tuned combination of specific biological and physical factors. Indeed, the scaffold geometry and stiffness are crucial in enhancing growth factor differentiative effects on progenitor cells. The exploitation of this concept could be essential in setting up suitable procedures to fabricate functionally efficient engineered tissues.

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.

Cooperation of Biological and Mechanical Signals in Cardiac Progenitor Cell Differentiation

Dr. S. Pagliari , Dr. G. Forte , Dr. F. Pagliari , Dr. M. Minieri , Prof. P. Di Nardo Laboratory of Molecular and Cellular Cardiology Department of Internal Medicine University of Rome “Tor Vergata”Rome 00133, Italy E-mail: dinardo@uniroma2.it Dr. S. Pagliari, Dr. G. Forte, Dr. F. Pagliari, Dr. M. Minieri, Prof. P. Di NardoJapanese-Italian Tissue Engineering Laboratory (JITEL) Tokyo Women’s Medical University-Waseda University Joint Institution for Advanced Biomedical Sciences (TWIns) Tokyo, Japan Dr. S. Pagliari, Dr. G. Forte, Dr. F. Pagliari, Dr. M. Minieri, Prof. P. Di NardoItalian Institute for Cardiovascular Research (INRC) 40126 Bologna, Italy Prof. A. C. Vilela-Silva Instituto de Ciencias Biomedicas and Laboratorio de Tecido Conjuntivo Hospital Universitario Clementino Fraga Filho Rio de Janeiro, Brazil Dr. C. Mandoli , Prof. E. Traversa International Research Center for Materials Nanoarchitectonics (MANA) National Institute for Materials Science (NIMS) 1–1 Namiki, Tsukuba, Ibaraki 305–0044, Japan E-mail: TRAVERSA.Enrico@nims.go.jp Dr. S. Pietronave , Prof. M. Prat Department of Medical Sciences University “A. Avogadro” of Piemonte Orientale 28100 Novara, Italy Dr. G. Vozzi , Prof. A. Ahluwalia Interdepartmental Research Center “E. Piaggio” University of Pisa56126 Pisa, Italy Prof. S. Licoccia , Prof. E. Traversa NAST Centre & Department of Chemical Science and Technology University of Rome “Tor Vergata” Roma 00133, Italy [†] S.P. and A.C.V.S. contributed equally to this work.

Cardiac progenitor cells: Potency and control

Stem cell‐based regeneration of the heart has focused much scientific and public attention being cardiac diseases the major cause of disability and death in industrialized countries. Innumerable efforts have been taken to unveil the mechanisms undergoing stem cell proliferation and fate, but much remains to be endeavoured for their application in clinical practice. Nevertheless, the discovery of progenitor cells resident within the cardiac tissue has sparked off enthusiasm about the possibility of efficiently and safely engineering them to repair the injured myocardium. Indeed, the early applications of the cardiac progenitor cells, mostly based on simplistic concepts and techniques, have failed highlighting the prerequisite of expanding the knowledge about progenitor cell features and microenvironmental conditioning. In this review, recent information on resident cardiac progenitor cells has been systematically gathered in order to create a valuable instrument to support investigators in their efforts to establish an efficient cardiac cell therapy. J. Cell. Physiol. 224: 590–600, 2010.

Stem cell activation sustains hereditary hypertrophy in hamster cardiomyopathy.

Recent studies have documented the presence of stem cells within the myocardium and their role in the repair of ischaemic injury. Nevertheless, the pathogenic role of stem cells in non‐ischaemic myocardial diseases, as well as the factors potentially responsible for their activation, is still under debate. The present study demonstrates the presence of an increased number of c‐kit positive, MDR‐positive, and Sca‐1‐positive stem cells within the myocardium of hereditary δ‐SG null hamsters, a spontaneously occurring model of hypertrophic cardiomyopathy. When hamsters are 80 days old, ie at the ‘hypertrophic’ stage of the disease, but without haemodynamic overload, these cells associate with a multitude of cells co‐expressing c‐kit, cMet, GATA4, or MEF‐2, and proliferating myocytes co‐expressing myosin heavy chain, telomerase, ki67 and cyclin B. Furthermore, at the same animal age, the number of myocardial cells co‐expressing c‐kit and Flk‐1, and the number of capillary vessels, is also amplified. In order to identify factors potentially responsible for stem cell activation, the myocardial expression of HGF and cMet and HGF plasma levels were evaluated, demonstrating their increase in 80‐day‐old δ‐SG null hamsters. To demonstrate the possible ability of HGF to induce stem cell differentiation, bone‐marrow‐derived mesenchymal stem cells were challenged with HGF at the same plasma concentration observed in vivo. HGF induced cMet phosphorylation, and caused loss of stem cell features and overexpression of MEF‐2, TEF1, and MHC. Our results demonstrate that stem cell activation occurs within the cardiomyopathic myocardium, very likely to maintain an efficient cardiac architecture. In this context, elevated levels of HGF might play a role in induction of stem cell commitment to the cardiomyocyte lineage and in cardioprotection through its anti‐apoptotic action. Consistently, when cytokine levels declined to physiological concentrations, as in 150‐day‐old cardiomyopathic animals, myocardial apoptosis prevailed, prejudicing cardiac function. Copyright

Atrial Natriuretic Peptide Effects on Intracellular pH Changes and ROS Production in HEPG2 Cells: Role of p38 MAPK and Phospholipase D

Aims: The present study was performed to evaluate Atrial Natriuretic Peptide (ANP) effects on intracellular pH, phospholipase D and ROS production and the possible relationship among them in HepG2 cells. Cancer extracellular microenvironment is more acidic than normal tissues and the activation of NHE-1, the only system able to regulate pHi homeostasis in this condition , can represent an important event in cell proliferation and malignant transformation. Methods: The ANP effects on pHi were evaluated by fluorescence spectrometry. The effects on p38 MAPK and ROS production were evaluated by immunoblots and analysis of DCF-DA fluorescence, respectively. RT-PCR analysis and Western blotting were used to determine the ANP effect on mRNA NHE-1 expression and protein levels. PLD-catalyzed conversion of phosphatidylcholine to phosphatydilethanol (PetOH), in the presence of ethanol, was monitored by thin layer chromatography. Results: A significant pHi decrease was observed in ANP-treated HepG2 cells and this effect was paralleled by the enhancement of PLD activity and ROS production. The ANP effect on pHi was coupled to an increased p38 MAPK phosphorylation and a down-regulation of mRNA NHE-1 expression and protein levels. Moreover, the relationship between PLD and ROS production was demonstrated by calphostin-c, a potent inhibitor of PLD. At the same time, all assessed ANP-effects were mediated by NPR-C receptors. Conclusion: Our results indicate that ANP recruits a signal pathway associated with p38 MAPK, NHE-1 and PLD responsible for ROS production, suggesting a possible role for ANP as novel modulator of ROS generation in HepG2 cells.

Tuning hierarchical architecture of 3D polymeric scaffolds for cardiac tissue engineering

Tissue engineering combines the fields of engineering, chemistry, biology, and medicine to fabricate replacement tissues able to restore, maintain, or improve structurally and functionally damaged organs. The approach of regenerative medicine is of paramount importance for treating patients with severe cardiac diseases. For successful exploitation, the challenge for cardiac regenerative medicine is to identify the suitable combination between the best cell source for cardiac repair and the design of the optimal scaffold as a template for tissue replacement. Adult stem cells have the potential to improve regenerative medicine with their peculiar feature to self-renew and differentiate into various phenotypes. Insights into the stem cell field lead to the identification of the suitable scaffold features that enhance the ex vivo proliferation and differentiation of stem cells. Scaffolds composed of natural and/or synthetic polymers can organise stem cells into complex architectures that mimic native tissues. To achieve this, a proper design of the chemical, mechanical, and morphological characteristics of the scaffold at different length scales is needed to reproduce the tissue complexity at the cell-scaffold interface. Hierarchical porosities are needed in a single construct, at the millimetre scale to help nutrition and vascularisation, at the micrometer scale to accommodate cells, and at the nanometre scale to favour the expression of extra-cellular matrix components. The present study has been undertaken to setup strategies to integrate stem cells and tailored scaffolds, as a tool to control cardiac tissue regeneration. Among the many available techniques for scaffold fabrication, porogen leaching, phase separation, and electrospinning were selected as low-cost and user-friendly technologies to fabricate tuneable, hierarchically porous matrices that mimic aspects of the cell native surroundings. The biological validation of these scaffolds was performed by implanting adult stem cells.