Differences in tissue-remodeling potential of aortic and pulmonary heart valve interstitial cells

Tissue Engineering

Volumn 13, Issue 9, 2007, Pages 2281-2289

  Merryman, W David ^a   Liao, Jun ^a   Parekh, Aron ^a   Candiello, Joseph E ^a   Lin, Hai ^a   Sacks, Michael S ^a,b  

^a University of Pittsburgh   (United States)

^b UNIVERSITY OF PITTSBURGH   (United States)

Author keywords

[No Author keywords available]

Indexed keywords

CLUSTERING ALGORITHMS; COLLAGEN; FIBROBLASTS; GELS; STIFFNESS; TISSUE;

MECHANOBIOLOGICAL DIFFERENCES; TISSUE REMODELING; TRANSFORMING GROWTH FACTORS; VALVE INTERSTITIAL CELLS;

TISSUE ENGINEERING;

CYTOKINE; TRANSFORMING GROWTH FACTOR BETA1;

ANIMAL CELL; AORTA VALVE; ARTICLE; ATOMIC FORCE MICROSCOPY; CELL MIGRATION; CELL TYPE; CYTOSKELETON; EXTRACELLULAR MATRIX; FIBROBLAST; HEART VALVE; HEART VALVE INTERSTITIAL CELL; MORPHOLOGY; NONHUMAN; PRIORITY JOURNAL; PULMONARY VALVE; SWINE; TISSUE ENGINEERING;

ANIMALS; AORTIC VALVE; FIBROBLASTS; MICROSCOPY, ATOMIC FORCE; MYOCYTES, SMOOTH MUSCLE; PULMONARY VALVE; REGENERATION; SWINE; TISSUE ENGINEERING;

SUS;

EID: 34548645286     PISSN: 10763279     EISSN: None     Source Type: Journal    
DOI: 10.1089/ten.2006.0324     Document Type: Article

References (36)

1. Merryman, W.D., Youn, I., Lukoff, H.D., Krueger, P.M., Guilak, F., Hopkins, R.A., and Sacks, M.S. Correlation between heart valve interstitial cell stiffness and transvalvular pressure: implications for collagen biosynthesis. Am J Physiol Heart Circ Physiol 290, H224, 2006.
2. Taylor, P.M., Batten, P., Brand, N.J., Thomas, P.S., and Yacoub, M.H. The cardiac valve interstitial cell. Int J Biochem Cell Biol 35, 113, 2003.
3. Taylor, P.M., Allen, S.P., and Yacoub, M.H. Phenotypic and functional characterization of interstitial cells from human heart valves, pericardium and skin. J Heart Valve Dis 9, 150, 2000.
4. Schoen, F.J., and Levy, R.J. Calcification of tissue heart valve substitutes: progress toward understanding and prevention. Ann Thorac Surg 79, 1072, 2005.
5. Jian, B., Narula, N., Li, Q.Y., Mohler, E.R., 3rd, and Levy, R.J. Progression of aortic valve stenosis: TGF-beta1 is present in calcified aortic valve cusps and promotes aortic valve interstitial cell calcification via apoptosis. Ann Thorac Surg 75, 457, 2003.
6. Jian, B., Xu, J., Connolly, J., Savani, R.C., Narula, N., Liang, B., and Levy, R.J. Serotonin mechanisms in heart valve disease I: serotonin-induced up-regulation of transforming growth factor-beta1 via G-protein signal transduction in aortic valve interstitial cells. Am J Pathol 161, 2111, 2002.
7. Walker, G.A., Masters, K.S., Shah, D.N., Anseth, K.S., and Leinwand, L.A. Valvular myofibroblast activation by transforming growth factor-beta: implications for pathological extracellular matrix remodeling in heart valve disease. Circ Res 95, 253, 2004.
8. Rabkin-Aikawa, E., Farber, M., Aikawa, M., and Schoen, F.J. Dynamic and reversible changes of interstitial cell phenotype during remodeling of cardiac valves. J Heart Valve Dis 13, 841, 2004.
9. Taylor, P.M., Allen, S.P., Dreger, S.A., and Yacoub, M.H. Human cardiac valve interstitial cells in collagen sponge: a biological three-dimensional matrix for tissue engineering. J Heart Valve Dis 11, 298, 2002.
10. Butcher, J.T., and Nerem, R.M. Porcine aortic valve interstitial cells in three-dimensional culture: comparison of phenotype with aortic smooth muscle cells. J Heart Valve Dis 13, 478, 2004.
11. Rabkin, E., Hoerstrup, S.P., Aikawa, M., Mayer, J.E., Jr., and Schoen, F.J. Evolution of cell phenotype and extracellular matrix in tissue-engineered heart valves during in-vitro maturation and in-vivo remodeling. J Heart Valve Dis 11, 308, 2002.
12. Merryman, W.D., Engelmayr, G.C., Jr., Liao, J., and Sacks, M.S. Defining biomechanical endpoints for tissue engineered heart valve leaflets from native leaflet properties. Prog Pediatr Cardiol 21, 153, 2006.
13. Messier, R.H., Jr., Bass, B.L., Aly, H.M., Jones, J.L., Domkowski, P.W., Wallace, R.B., and Hopkins, R.A. Dual structural and functional phenotypes of the porcine aortic valve interstitial population: characteristics of the leaflet myofibroblast. J Surg Res 57, 1, 1994.
14. Filip, D.A., Radu, A., and Simionescu, M. Interstitial cells of the heart valves possess characteristics similar to smooth muscle cells. Circ Res 59, 310, 1986.
15. Mulholland, D.L., and Gotlieb, A.I. Cell biology of valvular interstitial cells. Can J Cardiol 12, 231, 1996.
16. Della Rocca, F., Sartore, S., Guidolin, D., Bertiplaglia, B., Gerosa, G., Casarotto, D., and Pauletto, P. Cell composition of the human pulmonary valve: a comparative study with the aortic valve - the VESALIO Project. Vitalitate Exornatum Succedaneum Aorticum labore Ingegnoso Obtinebitur. Ann Thorac Surg 70, 1594, 2000.
17. Mathur, A.B., Collinsworth, A.M., Reichert, W.M., Kraus, W.E., and Truskey, G.A. Endothelial, cardiac muscle and skeletal muscle exhibit different viscous and elastic properties as determined by atomic force microscopy. J Biomech 34, 1545, 2001.
18. Costa, K.D., and Yin, F.C. Analysis of indentation: implications for measuring mechanical properties with atomic force microscopy. J Biomech Eng 121, 462, 1999.
19. Kasas, S., Wang, X., Hirling, H., Marsault, R., Huni, B., Yersin, A., Regazzi, R., Grenningloh, G., Riederer, B., Forro, L., Dietler, G., and Catsicas, S. Superficial and deep changes of cellular mechanical properties following cytoskeleton disassembly. Cell Motil Cytoskeleton 62, 124, 2005.
20. Bell, E., Ivarsson, B., and Merrill, C. Production of a tissue-like structure by contraction of collagen lattices by human fibroblasts of different proliferative potential in vitro. Proc Natl Acad Sci USA 76, 1274, 1979.
21. Cushing, M.C., Liao, J.T., and Anseth, K.S. Activation of valvular interstitial cells is mediated by transforming growth factor-beta1 interactions with matrix molecules. Matrix Biol 24, 428, 2005.
22. Sato, M., Theret, D.P., Wheeler, L.T., Ohshima, N., and Nerem, R.M. Application of the micropipette technique to the measurement of cultured porcine aortic endothelial cell viscoelastic properties. J Biomech Eng 112, 263, 1990.
23. Guilak, F., Ting-Beall, H.P., Baer, A.E., Trickey, W.R., Erickson, G.R., and Setton, L.A. Viscoelastic properties of intervertebral disc cells. Identification of two biomechanically distinct cell populations. Spine 24, 2475, 1999.
24. Na, S., Sun, Z., Meininger, G.A., and Humphrey, J.D. On atomic force microscopy and the constitutive behavior of living cells. Biomech Model Mechanobiol 3, 75, 2004.
25. Berry, D.P., Harding, K.G., Stanton, M.R., Jasani, B., and Ehrlich, H.P. Human wound contraction: collagen organization, fibroblasts, and myofibroblasts. Plast Reconstr Surg 102, 124, 1998.
26. Fu, P., Sodian, R., Luders, C., Lemke, T., Kraemer, L., Hubler, M., Weng, Y., Hoerstrup, S.P., Meyer, R., and Hetzer, R. Effects of basic fibroblast growth factor and transforming growth factor-beta on maturation of human pediatric aortic cell culture for tissue engineering of cardiovascular structures. ASAIO J 50, 9, 2004.
27. Tasab, M., Batten, M.R., and Bulleid, N.J. Hsp47: a molecular chaperone that interacts with and stabilizes correctly-folded procollagen. EMBO J 19, 2204, 2000.
28. Rocnik, E.F., van der Veer, E., Cao, H., Hegele, R.A., and Pickering, J.G. Functional linkage between the endoplasmic reticulum protein Hsp47 and procollagen expression in human vascular smooth muscle cells. J Biol Chem 277, 38571, 2002.
29. Sauk, J.J., Nikitakis, N., and Siavash, H. Hsp47 a novel collagen binding serpin chaperone, autoantigen and therapeutic target. Front Biosci 10, 107, 2005.
30. Peters, T., Sindrilaru, A., Hinz, B., Hinrichs, R., Menke, A., Al-Azzeh, E.A., Holzwarth, K., Oreshkova, T., Wang, H., Kess, D., Walzog, B., Sulyok, S., Sunderkotter, C., Friedrich, W., Wlaschek, M., Krieg, T., and Scharffetter-Kochanek, K. Wound-healing defect of CD18(-/-) mice due to a decrease in TGF-beta(1) and myofibroblast differentiation. EMBO J 24, 3400, 2005.
31. Edwards, J.E. Calcific aortic stenosis: pathologic features. Mayo Clin Proc 36, 444, 1961.
32. Merryman, W.D., Lukoff, H.D., Long, R.A., Engelmayr, G.C., Jr., Hopkins, R.A., and Sacks, M.S. Synergistic effects of cyclic tension and transforming growth factor-β1 on the aortic valve myofibroblast. Cardiovas Pathol (In press).
33. Sales, V.L., Engelmayr, G.C., Mettler, B.A., Johnson, J.A., Sacks, M.S., and Mayer, J.E., Jr. Transforming growth factor-P 1 modulates extracellular matrix production, proliferation and apoptosis of endothelial progenitor cells in tissue-engineering scaffolds. Circulation 114 (1 Suppl), 1193, 2006.
34. Perry, T.E., Kaushal, S., Nasseri, B., Sutherland, F.W.H., Wang, J., Guleserian, K.J., Bischoff, J., Vacanti, J.P., Sacks, M.S., and Mayer, J.E. Peripheral blood as a cell source for tissue engineering heart valves. Surg Forum LII, 99, 2001.
35. Perry, T.E., Kaushal, S., Sutherland, F.W., Guleserian, K.J., Bischoff, J., Sacks, M., and Mayer, J.E. Thoracic Surgery Directors Association Award. Bone marrow as a cell source for tissue engineering heart valves. Ann Thorac Surg 75, 761, 2003.
36. Kadner, A., Hoerstrup, S.P., Zund, G., Eid, K., Maurus, C., Melnitchouk, S., Grunenfelder, J., and Turina, M.I. A new source for cardiovascular tissue engineering: human bone marrow stromal cells. Eur J Cardiothorac Surg 21, 1055, 2002.