Supplementary Material for: Tissue-Derived Signals for Mesenchymal Stem Cell Stimulation: Role of Cardiac and Umbilical Cord Microenvironments Robert A.W. Schittini A.V. Marchini F.K. Batista M. Affonso Da Costa M.B. Senegaglia A.C. Brofman P.R.S. Abud A.P.R. Stimamiglio M.A. 10.6084/m9.figshare.4163235.v1 https://karger.figshare.com/articles/dataset/Supplementary_Material_for_Tissue-Derived_Signals_for_Mesenchymal_Stem_Cell_Stimulation_Role_of_Cardiac_and_Umbilical_Cord_Microenvironments/4163235 <p>The tissue microenvironment regulates such stem cell behaviors as self-renewal and differentiation. Attempts to mimic components of these microenvironments could provide new strategies for culturing and directing the behavior of stem cells. The aim of the present study was to mimic cardiac and umbilical cord tissue microenvironments in vitro and compare the resulting bone marrow-derived mesenchymal stem cell (BM-MSC) behaviors. We generated tissue microenvironments using conditioned medium (CM) and extracellular matrix (ECM) samples obtained from human heart and umbilical cord tissue explant cultures and by tissue decellularization. Mass spectrometry and immunostaining were used to characterize and determine the specific protein profiles of the ECMs and CMs. We demonstrated that the ECMs and CMs were not cytotoxic to BM-MSCs and could thus be tested via cell culture. The BM-MSCs showed a higher proliferation rate when cultured with umbilical cord-derived CM compared with the other analyzed conditions. Furthermore, the ECMs increased cell adhesion and migration. However, although the conditions tested in this work were able to maintain the viability and affect the proliferation, adhesion and migration of BM-MSCs in vitro, mimicking tissue microenvironments using ECM and CM was not sufficient to induce the cardiomyogenic differentiation of BM-MSCs. The present study provides a thorough characterization of the biological activity of these ECMs and CMs in human BM-MSC cultures.</p><br> 2016-11-01 14:29:48 Decellularization Extracellular matrix Mesenchymal stem cells Tissue microenvironment Secretome