Fluid forces control endothelial sprouting

During angiogenesis, endothelial cells (ECs) from intact blood vessels quickly infiltrate avascular regions via vascular sprouting. This process is fundamental to many normal and pathological processes such as wound healing and tumor growth, but its initiation and control are poorly understood. Vascular endothelial cell growth factor (VEGF) can promote vessel dilation and angiogenic sprouting, but given the complex nature of vascular morphogenesis, additional signals are likely necessary to determine, for example, which vessel segments sprout, which dilate, and which remain quiescent. Fluid forces exerted by blood and plasma are prime candidates that might codirect these processes, but it is not known whether VEGF cooperates with mechanical fluid forces to mediate angiogenesis. Using a microfluidic tissue analog of angiogenic sprouting, we found that fluid shear stress, such as exerted by flowing blood, attenuates EC sprouting in a nitric oxide-dependent manner and that interstitial flow, such as produced by extravasating plasma, directs endothelial morphogenesis and sprout formation. Furthermore, positive VEGF gradients initiated sprouting but negative gradients inhibited sprouting, promoting instead sheet-like migration analogous to vessel dilation. These results suggest that ECs integrate signals from fluid forces and local VEGF gradients to achieve such varied goals as vessel dilation and sprouting.

[1]  Shu Chien,et al.  Role of integrins in endothelial mechanosensing of shear stress. , 2002, Circulation research.

[2]  James G Truslow,et al.  Effect of mechanical factors on the function of engineered human blood microvessels in microfluidic collagen gels. , 2010, Biomaterials.

[3]  T. Sasaguri,et al.  Laminar shear stress inhibits vascular endothelial cell proliferation by inducing cyclin-dependent kinase inhibitor p21(Sdi1/Cip1/Waf1) , 2000, Circulation research.

[4]  J. Tarbell,et al.  Interstitial flow through the internal elastic lamina affects shear stress on arterial smooth muscle cells. , 2000, American journal of physiology. Heart and circulatory physiology.

[5]  S A Tschanz,et al.  Intussusceptive angiogenesis: its role in embryonic vascular network formation. , 2000, Circulation research.

[6]  P. Carmeliet,et al.  Angiogenesis in cancer and other diseases , 2000, Nature.

[7]  M. Kuchan,et al.  Role of calcium and calmodulin in flow-induced nitric oxide production in endothelial cells. , 1994, The American journal of physiology.

[8]  K. Alitalo,et al.  VEGF guides angiogenic sprouting utilizing endothelial tip cell filopodia , 2003, The Journal of cell biology.

[9]  Frederik De Smet,et al.  Branching morphogenesis and antiangiogenesis candidates: tip cells lead the way , 2009, Nature Reviews Clinical Oncology.

[10]  D P Gaver,et al.  A theoretical model study of the influence of fluid stresses on a cell adhering to a microchannel wall. , 1998, Biophysical journal.

[11]  D. Ingber Mechanical signaling and the cellular response to extracellular matrix in angiogenesis and cardiovascular physiology. , 2002, Circulation research.

[12]  Kayla J Bayless,et al.  Molecular basis of endothelial cell morphogenesis in three‐dimensional extracellular matrices , 2002, The Anatomical record.

[13]  Stanley J. Wiegand,et al.  Vascular-specific growth factors and blood vessel formation , 2000, Nature.

[14]  R. Jain,et al.  Intussusceptive microvascular growth in a human colon adenocarcinoma xenograft: a novel mechanism of tumor angiogenesis. , 1996, Microvascular research.

[15]  P. Davies,et al.  Flow-mediated endothelial mechanotransduction. , 1995, Physiological reviews.

[16]  T. Skalak,et al.  Angiogenesis and Microvascular Remodeling: A Brief History and Future Roadmap , 2005, Microcirculation.

[17]  W. Sessa eNOS at a glance , 2004, Journal of Cell Science.

[18]  R M Nerem,et al.  Vascular endothelial cell proliferation in culture and the influence of flow. , 1990, Biomaterials.

[19]  R. Jain Normalization of Tumor Vasculature: An Emerging Concept in Antiangiogenic Therapy , 2005, Science.

[20]  G. Whitesides,et al.  Rapid Prototyping of Microfluidic Systems in Poly(dimethylsiloxane). , 1998, Analytical chemistry.

[21]  Holger Gerhardt,et al.  Dll4 signalling through Notch1 regulates formation of tip cells during angiogenesis , 2007, Nature.

[22]  L V McIntire,et al.  Flow effects on prostacyclin production by cultured human endothelial cells. , 1985, Science.

[23]  J. Tarbell,et al.  Heparan Sulfate Proteoglycans Mediate Interstitial Flow Mechanotransduction Regulating MMP-13 Expression and Cell Motility via FAK-ERK in 3D Collagen , 2011, PloS one.

[24]  G. Schmid-Schönbein,et al.  Fluid Shear Attenuates Endothelial Pseudopodia Formation into the Capillary Lumen , 2008, Microcirculation.

[25]  Ruo-Pan Huang,et al.  Laminar Shear Inhibits Tubule Formation and Migration of Endothelial Cells by an Angiopoietin-2–Dependent Mechanism , 2007, Arteriosclerosis, thrombosis, and vascular biology.

[26]  Antonio Duarte,et al.  The Notch ligand Delta-like 4 negatively regulates endothelial tip cell formation and vessel branching , 2007, Proceedings of the National Academy of Sciences.

[27]  George Q. Daley,et al.  Biomechanical forces promote embryonic haematopoiesis , 2009, Nature.

[28]  S. Chien,et al.  Selective adapter recruitment and differential signaling networks by VEGF vs. shear stress , 2007, Proceedings of the National Academy of Sciences.

[29]  Ferdinand le Noble,et al.  What determines blood vessel structure? Genetic prespecification vs. hemodynamics. , 2006, Physiology.

[30]  N. Ferrara,et al.  The biology of VEGF and its receptors , 2003, Nature Medicine.

[31]  J. Tarbell,et al.  Effect of pressure on hydraulic conductivity of endothelial monolayers: role of endothelial cleft shear stress. , 1999, Journal of applied physiology.

[32]  C. Anderson,et al.  Capillary sprout endothelial cells exhibit a CD36 low phenotype: regulation by shear stress and vascular endothelial growth factor-induced mechanism for attenuating anti-proliferative thrombospondin-1 signaling. , 2008, The American journal of pathology.

[33]  Federica Boschetti,et al.  Synergy between interstitial flow and VEGF directs capillary morphogenesis in vitro through a gradient amplification mechanism. , 2005, Proceedings of the National Academy of Sciences of the United States of America.

[34]  L. Munn,et al.  Aberrant vascular architecture in tumors and its importance in drug-based therapies. , 2003, Drug discovery today.

[35]  Douglas Lauffenburger,et al.  Interstitial fluid flow intensity modulates endothelial sprouting in restricted Src-activated cell clusters during capillary morphogenesis. , 2009, Tissue engineering. Part A.

[36]  G. Garcı́a-Cardeña,et al.  A new in vitro model to evaluate differential responses of endothelial cells to simulated arterial shear stress waveforms. , 2002, Journal of biomechanical engineering.

[37]  M. Gimbrone,et al.  Identification of vascular endothelial genes differentially responsive to fluid mechanical stimuli: cyclooxygenase-2, manganese superoxide dismutase, and endothelial cell nitric oxide synthase are selectively up-regulated by steady laminar shear stress. , 1996, Proceedings of the National Academy of Sciences of the United States of America.

[38]  R. Kaunas,et al.  Fluid shear stress modulates endothelial cell invasion into three-dimensional collagen matrices. , 2008, American journal of physiology. Heart and circulatory physiology.

[39]  Lei Xu,et al.  Perivascular nitric oxide gradients normalize tumor vasculature , 2008, Nature Medicine.

[40]  Adrian L. Harris,et al.  Hypoxia — a key regulatory factor in tumour growth , 2002, Nature Reviews Cancer.

[41]  R M Nerem,et al.  Effects of pulsatile flow on cultured vascular endothelial cell morphology. , 1991, Journal of biomechanical engineering.

[42]  Peng Yu,et al.  Mass transport and shear stress in a microchannel bioreactor: numerical simulation and dynamic similarity. , 2006, Journal of biomechanical engineering.

[43]  P. Campochiaro,et al.  Hyperoxia causes decreased expression of vascular endothelial growth factor and endothelial cell apoptosis in adult retina , 1999, Journal of cellular physiology.

[44]  G. Garcı́a-Cardeña,et al.  Biomechanical activation of vascular endothelium as a determinant of its functional phenotype , 2001, Proceedings of the National Academy of Sciences of the United States of America.

[45]  J. Frangos,et al.  The shear stress of it all: the cell membrane and mechanochemical transduction , 2007, Philosophical Transactions of the Royal Society B: Biological Sciences.

[46]  T. Secomb,et al.  Structural adaptation increases predicted perfusion capacity after vessel obstruction in arteriolar arcade network of pig skeletal muscle. , 2005, American journal of physiology. Heart and circulatory physiology.

[47]  S. Usami,et al.  Molecular mechanism of endothelial growth arrest by laminar shear stress. , 2000, Proceedings of the National Academy of Sciences of the United States of America.

[48]  A. Pries,et al.  Changes in Capillary Shear Stress in Skeletal Muscles Exposed to Long‐Term Activity: Role of Nitric Oxide , 2006, Microcirculation.

[49]  M E Dickinson,et al.  Measuring hemodynamic changes during mammalian development. , 2004, American journal of physiology. Heart and circulatory physiology.

[50]  R. Jain,et al.  Simultaneous measurement of RBC velocity, flux, hematocrit and shear rate in vascular networks in vivo , 2010 .