Culturing of Cardiac Cells in 3D Spheroids Modulates Their Expression Profile and Increases Secretion of Proangiogenic Growth Factors.

We studied the effect of 3D-culturing of cells in the form of cardiospheres on the expression of genes encoding vascular progenitor cell markers and angiogenesis regulators and on the production of proangiogenic factors. Cardiospheres were obtained by culturing mouse cardiac explants followed by self-assembly on poly-D-lysine. Gene expression was assessed by real-time PCR, and the production of proangiogenic factors was assessed by Microarray analysis of the cell secretome. It was found that cells in the cardiospheres in comparison with 2D-culture of cardiosphere-forming cells demonstrated increased expression of vascular progenitor cell markers (Pdgfrα, Kit, and Vegfr1) and angiogenesis regulatory factors (Vegf, Fgf2, and Angpt1), as well as an enhanced secretion of proangiogenic factors (ANGPT1, VEGF, CXCL16, and PIGF-2). Thus, culturing of cells in the form of cardiospheres can be considered as a basis for developing approaches to increasing their angiogenic activity and regenerative properties.

Deficiency of Urokinase-Type Plasminogen Activator Receptor Is Associated with the Development of Perivascular Fibrosis in Mouse Heart.

It was suggested that the urokinase system plays a certain role in the regulation of activity of the endothelial-mesenchymal transition and in the development of perivascular fibrosis. Urokinase (uPA), the key component of the urokinase system, is a serine protease that binds to its receptor on the cell surface (uPAR) and affects the cell microenvironment components through the formation of plasmin, remodeling of the extracellular matrix, release of growth factors, and initiation of intracellular signals. The heart of PLAUR gene knockout C57BL/129 (uPAR-/-) mice showed signs of vasculopathy: reduced number of capillaries/arterioles, signs of endothelial-mesenchymal transition in endothelial cells, vascular wall remodeling, and deposition of extracellular matrix components. These changes were combined with enhanced expression of urokinase and active forms of TGF-ß1. Apparently, uPAR is a part of a multicomponent system that provides multifaceted regulatory effects on the components of forming vessels and vascular wall cells, which allows considering it as a possible target for targeted antifibrotic therapy.

Hypoxia - as a Possible Regulator of the Activity of Epicardial Mesothelial Cells After Myocardial Infarction.

Aim      To study the effect of hypoxia on the activity of epithelial-mesenchymal transition (EMT) in epicardial cells, which provides formation of a specialized microenvironment.Material and methods   This study used a model of experimental myocardial infarction created by ligation of the anterior descendent coronary artery. The activity of epicardial cells after a hypoxic exposure was studied with the hypoxia marker, pimonidazole, bromodeoxyuridine, immunofluorescent staining of heart cryosections, and in vitro mesothelial cell culture.Results The undamaged heart maintained the quiescent condition of mesothelial cells and low levels of their proliferation, extracellular matrix protein production, and of the EMT activity. Acute ischemic injury induced moderate hypoxia in the epicardial/subepicardial region. This caused a global rearrangement of this region due to the initiation of EMT in cells, changes in the cell composition, and accumulation of extracellular matrix proteins. We found that the initiation of EMT in mesothelial cells may result in the formation of smooth muscle cell precursors, fibroblasts, and a population of Sca-1+ cardiac progenitor cells, which may both participate in construction of new blood vessels and serve as a mesenchymal link for the paracrine support of microenvironmental cells. In in vitro experiments, we showed that 72­h hypoxia facilitated activation of EMT regulatory genes, induced dissembling of intercellular contacts, cell uncoupling, and increased cell plasticity.Conclusion      The epicardium of an adult heart serves as a "reparative reserve" that can be reactivated by a hypoxic exposure. This creates a basis for an approach to influence the epicardium to modulate its activity for regulating reparative processes.

Transforming Growth Factor Beta-1 (TGF-ß1) Regulates Assembly of Cardiac Spheroids.

Cells of all tissues in human body interact with their neighboring cells and components of the extracellular matrix thereby creating a unique 3D microenvironment. These interactions are realized through a complex network of biochemical and mechanical signals that are important in maintaining normal cellular homeostasis. Numerous attempts have been undertaken during the last two decades to develop 3D models for studying their properties and understanding the mechanisms of regulation of cell microenvironment in vivo. Cardiac spheroids (cardiospheres) are one these models of cardiac microenvironment. In this study we demonstrate that unique microenvironment formed in cardiospheres consists of stem/progenitor and mesenchymal cells surrounded by extracellular matrix proteins synthesized by these cells. TGF-ß1 participates in the regulation of contraction of cells forming cardiospheres, promotes activation of the epithelial-mesenchymal transition and self-organization of cells, which leads to the formation of larger spheroids. Thereby, the effect of TGF-ß1 on the cells of cardiospheres can serve as a model for studying the mechanisms of regulation of cardiac microenvironment.