Mesenchymal stem cells enhance angiogenesis in mechanically viable prevascularized tissues via early matrix metalloproteinase upregulation.

Angiogenesis, the sprouting of new blood vessels from existing vasculature, is a complex biological process of interest to both the treatment of numerous pathologies and the creation of thick engineered tissues. In the context of tissue engineering, one potential solution to the diffusion limitation is to create a vascular network in vitro that can subsequently anastomose with the host after implantation, allowing the implantation of thicker, more complex tissues. In this study, the ability of endothelial cells to sprout and form stable vascular networks in 3-dimensional (3D) fibrin matrices was investigated as a function of matrix density in a prevascularized tissue model. The results demonstrate that while increasing matrix density leads to a nearly 7-fold increase in compressive stiffness, vascular sprouting is virtually eliminated in the most dense matrix condition. However, the addition of human mesenchymal stem cells (HMSCs) to the denser matrices reverses this effect, resulting in an up to a 7-fold increase in network formation. Although the matrix metalloproteinases (MMPs) MMP-2, MMP-9, and MT1-MMP are all upregulated early on with the addition of HMSCs, MT1-MMP appears to play a particularly important role in the observed angiogenic response among these proteases. This study provides a means to design stiffer prevascularized tissues utilizing naturally derived substrates, and its results may yield new mechanistic insights into stem cell-based angiogenic therapies.

[1]  U. Weidle,et al.  Role and localization of urokinase receptor in the formation of new microvascular structures in fibrin matrices. , 1999, The American journal of pathology.

[2]  Rakesh K. Jain,et al.  Quantitative angiogenesis assays: Progress and problems , 1997, Nature Medicine.

[3]  D. Seliktar,et al.  Biosynthetic hydrogel scaffolds made from fibrinogen and polyethylene glycol for 3D cell cultures. , 2005, Biomaterials.

[4]  Rakesh K Jain,et al.  Molecular regulation of vessel maturation , 2003, Nature Medicine.

[5]  J. Pober,et al.  Induction, differentiation, and remodeling of blood vessels after transplantation of Bcl-2-transduced endothelial cells. , 2005, Proceedings of the National Academy of Sciences of the United States of America.

[6]  L. McIntire,et al.  Therapeutic neovascularization: contributions from bioengineering. , 2005, Tissue engineering.

[7]  V Nehls,et al.  A novel, microcarrier-based in vitro assay for rapid and reliable quantification of three-dimensional cell migration and angiogenesis. , 1995, Microvascular research.

[8]  Dai Fukumura,et al.  Engineering vascularized tissue , 2005, Nature Biotechnology.

[9]  Léone Tranqui,et al.  The formation of tubular structures by endothelial cells is under the control of fibrinolysis and mechanical factors , 2004, Angiogenesis.

[10]  J. Hubbell,et al.  Mechanical properties, proteolytic degradability and biological modifications affect angiogenic process extension into native and modified fibrin matrices in vitro. , 2005, Biomaterials.

[11]  P. Quax,et al.  Membrane-type matrix metalloproteinase-mediated angiogenesis in a fibrin-collagen matrix. , 2003, Blood.

[12]  Z. Werb,et al.  Regulation of matrix biology by matrix metalloproteinases. , 2004, Current opinion in cell biology.

[13]  D. Edwards,et al.  Endothelial tubulogenesis within fibrin gels specifically requires the activity of membrane-type-matrix metalloproteinases (MT-MMPs). , 2002, Journal of cell science.

[14]  D. Kohane,et al.  Engineering vascularized skeletal muscle tissue , 2005, Nature Biotechnology.

[15]  K. Hirschi,et al.  PDGF, TGF-β, and Heterotypic Cell–Cell Interactions Mediate Endothelial Cell–induced Recruitment of 10T1/2 Cells and Their Differentiation to a Smooth Muscle Fate , 1998, The Journal of cell biology.

[16]  Z. Werb,et al.  Focalized proteolysis: spatial and temporal regulation of extracellular matrix degradation at the cell surface. , 1996, Current opinion in cell biology.

[17]  R. Béliveau,et al.  Hypoxia Promotes Murine Bone‐Marrow‐Derived Stromal Cell Migration and Tube Formation , 2003, Stem cells.

[18]  W. Sakr,et al.  Cleavage at the stem region releases an active ectodomain of the membrane type 1 matrix metalloproteinase. , 2005, The Biochemical journal.

[19]  Pieter Koolwijk,et al.  Involvement of membrane-type matrix metalloproteinases (MT-MMPs) in capillary tube formation by human endometrial microvascular endothelial cells: role of MT3-MMP. , 2004, The Journal of clinical endocrinology and metabolism.

[20]  K J Gooch,et al.  The relative magnitudes of endothelial force generation and matrix stiffness modulate capillary morphogenesis in vitro. , 2004, Experimental cell research.

[21]  Noo Li Jeon,et al.  Diffusion limits of an in vitro thick prevascularized tissue. , 2005, Tissue engineering.

[22]  D. Grobelny,et al.  Inhibition of human skin fibroblast collagenase, thermolysin, and Pseudomonas aeruginosa elastase by peptide hydroxamic acids. , 1992, Biochemistry.

[23]  C. Bowman,et al.  Mechanical properties of hydrogels and their experimental determination. , 1996, Biomaterials.

[24]  S. Weiss,et al.  Matrix Metalloproteinases Regulate Neovascularization by Acting as Pericellular Fibrinolysins , 1998, Cell.

[25]  Adam J. Engler,et al.  Myotubes differentiate optimally on substrates with tissue-like stiffness , 2004, The Journal of cell biology.

[26]  E. Donald,et al.  Mechanochemical Switching between Growth and Differentiation during Fibroblast Growth Factor-stimulated Angiogenesis In Vitro : Role of Extracellular Matrix , 2002 .

[27]  R T Tranquillo,et al.  Neuronal contact guidance in magnetically aligned fibrin gels: effect of variation in gel mechano-structural properties. , 2001, Biomaterials.

[28]  Z. Werb,et al.  How matrix metalloproteinases regulate cell behavior. , 2001, Annual review of cell and developmental biology.

[29]  Stephen J. Weiss,et al.  MT1-MMP–dependent neovessel formation within the confines of the three-dimensional extracellular matrix , 2004, The Journal of cell biology.

[30]  Donald E. Ingber,et al.  How does extracellular matrix control capillary morphogenesis? , 1989, Cell.

[31]  Richard A.F. Clark,et al.  The Molecular and Cellular Biology of Wound Repair , 2012, Springer US.

[32]  J. Hubbell,et al.  Molecularly engineered PEG hydrogels: a novel model system for proteolytically mediated cell migration. , 2005, Biophysical journal.

[33]  R. Sainson,et al.  Angiogenic sprouting and capillary lumen formation modeled by human umbilical vein endothelial cells (HUVEC) in fibrin gels: the role of fibroblasts and Angiopoietin-1. , 2003, Microvascular research.

[34]  Dai Fukumura,et al.  Tissue engineering: Creation of long-lasting blood vessels , 2004, Nature.