Cellular approaches to tissue repair in cardiovascular disease: the more we know, the more there is to learn

Pivotal Cytoprotective Mediators and Promising Therapeutic Strategies for Endothelial Progenitor Cell-Based Cardiovascular Regeneration

Cardiovascular diseases (CVDs), including atherosclerosis, stroke, and myocardial infarction, is a major cause of death worldwide. In aspects of cell therapy against CVD, it is generally accepted that endothelial progenitor cells (EPCs) are potent neovascular modulators in ischemic tissues. In response to ischemic injury signals, EPCs located in a bone marrow niche migrate to injury sites and form new vessels by secreting various vasculogenic factors including VEGF, SDF-1, and FGF, as well as by directly differentiating into endothelial cells. Nonetheless, in ischemic tissues, most of engrafted EPCs do not survive under harsh ischemic conditions and nutrient depletion. Therefore, an understanding of diverse EPC-related cytoprotective mediators underlying EPC homeostasis in ischemic tissues may help to overcome current obstacles for EPC-mediated cell therapy for CVDs. Additionally, to enhance EPC's functional capacity at ischemic sites, multiple strategies for cell survival should be considered, that is, preconditioning of EPCs with function-targeting drugs including natural compounds and hormones, virus mediated genetic modification, combined therapy with other stem/progenitor cells, and conglomeration with biomaterials. In this review, we discuss multiple cytoprotective mediators of EPC-based cardiovascular repair and propose promising therapeutic strategies for the treatment of CVDs.

Hyaluronic Acid hydrogels support cord-like structures from endothelial colony-forming cells

The generation of functional vascular networks has the potential to improve treatment for vascular diseases and to facilitate successful organ transplantation. Endothelial colony-forming cells (ECFCs) have robust proliferative potential and can form vascular networks in vivo. ECFCs are recruited from a bone marrow niche to the site of vascularization, where cues from the extracellular matrix instigate vascular morphogenesis. Although this process has been elucidated using natural matrix, little is known about vascular morphogenesis by ECFCs in synthetic matrix, a xeno-free scaffold that can provide a more controllable and clinically relevant alternative for regenerative medicine. We sought to study hyaluronic acid (HA) hydrogels as three-dimensional scaffolds for capillary-like structure formation from ECFCs, and to determine the crucial parameters needed to design such synthetic scaffolds. We found that ECFCs express HA-specific receptors and that vascular endothelial growth factor stimulates hyaluronidase expression in ECFCs. Using a well-defined and controllable three-dimensional HA culture system, we were able to decouple the effect of matrix viscoelasticity from changes in adhesion peptide density. We determined that decreasing matrix viscoelasticity, which corresponds to a loose ultrastructure, significantly increases ECFC vascular tube length and area, and that the effect of local delivery of vascular endothelial growth factor within the hydrogel depends on the makeup of the synthetic environment. Collectively, these results set forth initial design criteria that need to be considered in developing vascularized tissue constructs.

Development of a porcine delayed wound-healing model and its use in testing a novel cell-based therapy

PURPOSE

A delayed full-thickness wound-healing model was developed and used for examining the capacity of adipose-derived stem cells (ASCs), either alone or in platelet-rich fibrin gels, to promote healing.

METHODS AND MATERIALS

Four pigs received electron beam radiation to the dorsal skin surface. Five weeks after radiation, subcutaneous fat was harvested from nonirradiated areas and processed to yield ASCs. Two weeks later, 28 to 30 full-thickness 1.5-cm(2) wounds were made in irradiated and nonirradiated skin. Wounds were treated with either saline solution, ASCs in saline solution, platelet-rich plasma (PRP) fibrin gel, ASCs in PRP, or non-autologous green fluorescence protein-labeled ASCs.

RESULTS

The single radiation dose produced a significant loss of dermal microvasculature density (75%) by 7 weeks. There was a significant difference in the rate of healing between irradiated and nonirradiated skin treated with saline solution. The ASCs in PRP-treated wounds exhibited a significant 11.2% improvement in wound healing compared with saline solution. Enhancement was dependent on the combination of ASCs and PRP, because neither ASCs nor PRP alone had an effect.

CONCLUSIONS

We have created a model that simulates the clinically relevant late radiation effects of delayed wound healing. Using this model, we showed that a combination of ASCs and PRP improves the healing rates of perfusion-depleted tissues, possibly through enhancing local levels of growth factors.

CD47-dependent molecular mechanisms of blood outgrowth endothelial cell attachment on cholesterol-modified polyurethane

We previously showed that blood outgrowth endothelial cells (BOECs) had a high affinity for polyurethane (PU) covalently configured with cholesterol residues (PU-Chol). However, the molecular mechanisms responsible for this enhanced affinity were not determined. CD47, a multifunctional transmembrane glycoprotein involved in cellular attachment, can form a cholesterol-dependent complex with integrin alpha(v)beta(3) and heterotrimeric G proteins. We tested herein the hypothesis that CD47, and the other components of the multi-molecular complex, enhance the attachment of BOECs to PU-Chol. Immunoprecipitation studies, of human and ovine BOECs, demonstrated that CD47 associates with integrin alpha(v) and integrin beta(3) as well as G(alphai-2) protein. The three-fold increase in BOEC attachment to PU-Chol, compared to unmodified PU, was reversed with the addition of blocking antibodies specific for CD47 and integrin alpha(v) and integrin beta(3). Similar results were observed with the addition of methyl-beta-cyclodextrin (MbetaCD), a known disruptor of the CD47 complex as well as of the membrane cholesterol content, to seeded BOEC or PU-Chol films. Reducing CD47 expression, via lentivirus transduced shRNA, decreased BOEC binding to PU-Chol by 50% compared to control groups. These data are the first demonstration of a role for the CD47 cholesterol-dependent signaling complex in BOEC attachment onto synthetic surfaces.

Collagen matrix physical properties modulate endothelial colony forming cell-derived vessels in vivo

Developing tissue engineering approaches to generate functional vascular networks is important for improving treatments of peripheral and cardiovascular disease. Endothelial colony forming cells (ECFCs) are an endothelial progenitor cell (EPC) population defined by high proliferative potential and an ability to vascularize collagen-based matrices in vivo. Little is known regarding how physical properties of the local cell microenvironment guide vessel formation following EPC transplantation. In vitro evidence suggests that collagen matrix stiffness may modulate EPC vessel formation. The present study determined the ability of 3D collagen matrix physical properties, varied by changing collagen concentration, to influence ECFC vasculogenesis in vivo. Human umbilical cord blood ECFCs were cultured within matrices for 18 h in vitro and then fixed for in vitro analysis or implanted subcutaneously into the flank of immunodeficient mice for 14 days. We report that increasing collagen concentration significantly decreased ECFC derived vessels per area (density), but significantly increased vessel sizes (total cross sectional area). These results demonstrate that the physical properties of collagen matrices influence ECFC vasculogenesis in vivo and that by modulating these properties, one can guide vascularization.

Material-based deployment enhances efficacy of endothelial progenitor cells

Cell-based therapies are attractive for revascularizing and regenerating tissues and organs, but clinical trials of endothelial progenitor cell transplantation have not resulted in consistent benefit. We propose a different approach in which a material delivery system is used to create a depot of vascular progenitor cells in vivo that exit over time to repopulate the damaged tissue and participate in regeneration of a vascular network. Microenvironmental conditions sufficient to maintain the viability and outward migration of outgrowth endothelial cells (OECs) have been delineated, and a material incorporating these signals improved engraftment of transplanted cells in ischemic murine hindlimb musculature, and increased blood vessel densities from 260 to 670 vessels per mm(2), compared with direct cell injection. Further, material deployment dramatically improved the efficacy of these cells in salvaging ischemic murine limbs, whereas bolus OEC delivery was ineffective in preventing toe necrosis and foot loss. Finally, material deployment of a combination of OECs with another cell population commonly isolated from peripheral or cord blood, endothelial progenitor cells (EPCs) returned perfusion to normal levels in 40 days, and prevented toe and foot necrosis. Direct injection of an EPC/OEC combination was minimally effective in improving limb perfusion, and untreated limbs underwent autoamputation in 3 days. These results demonstrate that vascular progenitor cell utility is highly dependent on the mode of delivery, and suggest that one can create new vascular beds for a variety of applications with this material-controlled deployment of cells.

Suppression of hepatocyte growth factor production impairs the ability of adipose-derived stem cells to promote ischemic tissue revascularization

The use of adipose-derived stem/stromal cells (ASCs) for promoting repair of tissues is a promising potential therapy, but the mechanisms of their action are not fully understood. We and others previously demonstrated accelerated reperfusion and tissue salvage by ASCs in peripheral ischemia models and have shown that ASCs secrete physiologically relevant levels of hepatocyte growth factor (HGF) and vascular endothelial growth factor. The specific contribution of HGF to ASC potency was determined by silencing HGF expression. RNA interference was used to downregulate HGF expression. A dual-cassette lentiviral construct expressing green fluorescent protein (GFP) and either a small hairpin RNA specifically targeted to HGF mRNA (shHGF) or an inactive control sequence (shCtrl) were used to stably transduce ASCs (ASC-shHGF and ASC-shCtrl, respectively). Transduced ASC-shHGF secreted >80% less HGF, which led to a reduced ability to promote survival, proliferation, and migration of mature and progenitor endothelial cells in vitro. ASC-shHGF were also significantly impaired, compared with ASC-shCtrl, in their ability to promote reperfusion in a mouse hindlimb ischemia model. The diminished ability of ASCs with silenced HGF to promote reperfusion of ischemic tissues was reflected by reduced densities of capillaries in reperfused tissues. In addition, fewer GFP(+) cells were detected at 3 weeks in ischemic limbs of mice treated with ASC-shHGF compared with those treated with ASC-shCtrl. These results indicate that production of HGF is important for the potency of ASCs. This finding directly supports the emerging concept that local factor secretion by donor cells is a key element of cell-based therapies. Disclosure of potential conflicts of interest is found at the end of this article.

Stem cells and cardiac regeneration

Despite many advances in cardiovascular medicine, heart failure (HF) remains the leading cause of death in developed countries affecting at least 10 million people in Western Europe alone. The poor long-term prognosis of HF patients, and immense public health implications has fuelled interest in finding new therapeutic modalities. Recent observations of the beneficial effect of stem cells on the damaged heart in animal experiments have generated tremendous excitement and stimulated clinical studies suggesting that this approach is feasible, safe, and potentially effective in humans. Cell-based myocardial regeneration is currently explored for a wide range of cardiac disease states, including acute and chronic ischemic myocardial damage, cardiomyopathy and as biological heart pacemakers. The aim of the present manuscript is to review the work that has been done to establish the role of stem cells in cardiac repair, give an update on the clinical trials performed so far, as well as to discuss critically the controversies, challenges and future surrounding this novel therapeutic concept.

The host immune response is essential for the beneficial effect of adult stem cells after myocardial ischemia

OBJECTIVE

Multipotent adult progenitor cells (MAPCs) are adult stem cells derived from bone marrow. We investigated the capacity of MAPCs to aid in tissue healing after myocardial ischemia in mice with different levels of immune competence.

METHODS

Adult murine C57BL/6 MAPCs were labeled with firefly luciferase and DsRed2 fluorescent protein and injected into the myocardium of immunocompetent C57BL/6 or T-, B- and natural killer-cell severe combined immunodeficient C57BL/6 Rag2/IL-2Rgammac(-/-) mice at the time of myocardial infarction (MI). Mice were sequentially analyzed using in vivo whole body bioluminescent imaging for MAPC persistence and high-resolution ultrasound biomicroscopy to assess cardiac function.

RESULTS

Luciferase signals emitted from donor MAPCs were significantly higher in Rag2/IL-2Rgammac(-/-) mice compared with C57BL/6 recipients of labeled MAPCs. At 100, 200, and 365 days after MI, left ventricular contractile function was significantly improved (and normalized) in C57BL/6 MAPC recipients. In contrast, despite a greater degree of MAPC persistence compared with C57BL/6 recipients, no cardiac improvement occurred in Rag2/IL-2Rgammac(-/-) recipients of MAPCs. The improved cardiac contractile performance in response to syngeneic MAPC infusion correlated with a prominent increase of vascular density in infarcted and peri-infarcted myocardium, which was dependent upon host immune competency.

CONCLUSION

These data indicate that immune competence of the recipient modulates the therapeutic impact of the adult nonhematopoietic stem cells infused after acute MI injury and that a more vigorous immune response is advantageous for therapeutic myocardial repair after MI.