Evaluation of transdifferentiation from mesenchymal stem cells to neuron-like cells using microfluidic patterned co-culture system

Springer Science and Business Media LLC - Tập 13 - Trang 517-526 - 2011
De-Yao Wang1, Shinn-Chih Wu2, Shau-Ping Lin3, Shih-Hsiang Hsiao2, Tze-Wen Chung4, Yi-You Huang1
1Institute of Biomedical Engineering, College of Engineering, College of Medicine, National Taiwan University, Taipei, Republic of China
2Department of Animal Science and Technology, College of Bio-Resources and Agriculture, National Taiwan University, Taipei, Republic of China
3Institute of Biotechnology, College of Bio-Resources and Agriculture, National Taiwan University, Taipei, Republic of China
4Department of Chemical and Material Engineering, National Yunlin University of Science and Technology, Dou-Liu, Yun-Lin, Republic of China

Tóm tắt

We design a microfluidic patterned co-culture system for mouse mesenchymal stem cells (mMSCs) and neural cells to demonstrate the paracrine effects produced by the neural cells in facilitating the transdifferentiation from mMSCs to neuron-like cells. Neural cells and mMSC are orderly patterned in the microfluidic co-culturing system without direct cell contact. This configuration provides us to calculate the percentage of neural marker transdifferentiated by mMSCs easily. We obtain higher transdifferentiated ratio of mMSC in the microfluidic co-culturing system (beta III tubulin: 67%; glial fibrillary acidic protein (GFAP): 86.2%) as compared with the traditional transwell co-culturing system (beta III tubulin: 59.8%; GFAP: 52.0%), which is similar to the spontaneous neural marker expression in the undifferentiated MSCs (beta III tubulin: 47.5%; GFAP: 60.1%). Furthermore, mMSCs expressing green fluorescent protein and neural cells expressing red fluorescent protein were also used in our co-culture system to demonstrate the rarely occurring or observed cell fusion phenomenon. The results show that the co-cultured neural cells increased the transdifferentiation efficiency of mMSCs from soluble factors secreted by neural cells.

Tài liệu tham khảo

T. Aigner, J. Stove, Adv Drug Deliv Rev 55, 1569–1593 (2003) A.R. Alexanian, Exp Cell Res 310, 383–391 (2005) F. Anjos-Afonso, E.K. Siapati, D. Bonnet, J Cell Sci 117, 5655–5664 (2004) F. Arai, A. Hirao, T. Suda, Trends Cardiovasc Med 15, 75–79 (2005) S.N. Bhatia, U.J. Balis, M.L. Yarmush, M. Toner, FASEB J 13, 1883–1900 (1999) M. Bowden, O. Geschke, J.P. Kutter, D. Diamond, Lab Chip 3, 221–223 (2003) J.Y. Cheng, M.H. Yen, C.W. Wei, Y.C. Chuang, T.H. Young, J Micromech Microeng 15, 1147–1156 (2005) D.T. Chiu, N.L. Jeon, S. Huang, R.S. Kane, C.J. Wargo, I.S. Choi, D.E. Ingber, G.M. Whitesides, Proc Natl Acad Sci USA 97, 2408–2413 (2000) M. Egerbacher, R. Krestan, P. Bock, Anat Rec 242, 471–482 (1995) B.A. Fogarty, K.E. Heppert, T.J. Cory, K.R. Hulbutta, R.S. Martin, S.M. Lunte, Analyst 130, 924–930 (2005) E. Fuchs, T. Tumbar, G. Guasch, Cell 116, 769–778 (2004) H.J.G. Gundersen, E.B. Jensen, J Microsc -Oxf 147, 229–263 (1987) J.A. Hainfellner, T. Voigtlander, T. Strobel, P.R. Mazal, A.S. Maddalena, A. Aguzzi, H. Budka, J Neuropathol Exp Neurol 60, 449–461 (2001) L.A. Isakova, K. Baker, J. Dufour, D. Gaupp, D.G. Phinney, Mol Ther 13, 1173–1184 (2006) K.K. Johe, T.G. Hazel, T. Muller, M.M. DugichDjordjevic, R.D.G. McKay, Genes Dev 10, 3129–3140 (1996) G.C. Kopen, D.J. Prockop, D.G. Phinney, Proc Natl Acad Sci USA 96, 10711–10716 (1999) C. Krabbe, J. Zimmer, M. Meyer, APMIS 113, 831–844 (2005) J.Y. Lee, C. Jones, M.A. Zern, A. Revzin, Anal Chem 78, 8305–8312 (2006) T.H. Park, M.L. Shuler, Biotechnol Prog 19, 243–253 (2003) D.G. Phinney, D.J. Prockop, Stem Cells 25, 2896–2902 (2007) J. Ray, F.H. Gage, Mol Cell Neurosci 31, 560–573 (2006) J. Sanchez-Ramos, S. Song, F. Cardozo-Pelaez, C. Hazzi, T. Stedeford, A. Willing, R.W. Sands, D.J. Mooney, Curr Opin Biotechnol 18, 448–453 (2007) S.J. Song, J. Sanzhez-Ramos, Exp Neurol 184, 54–60 (2003) W. Tan, T.A. Desai, Tissue Eng 9, 255–267 (2003) R.Y.L. Tsai, R.D.G. McKay, J Neurosci 20, 3725–3735 (2000) F.P. Wachs, S. Couillard-Despres, M. Engelhardt, D. Wilhelm, S. Ploetz, M. Vroemen, J. Kaesbauer, G. Uyanik, J. Klucken, C. Karl, J. Tebbing, C. Svendsen, N. Weidner, H.G. Kuhn, J. Winkler, L. Aigner, Lab Invest 83, 949–962 (2003) M.J. West, L. Slomianka, H.J.G. Gundersen, Anat Rec 231, 482–497 (1991) S. Wislet-Gendebien, G. Hans, P. Leprince, J.M. Rigo, G. Moonen, B. Rogister, Stem Cells 23, 392–402 (2005) M.H. Yen, J.Y. Cheng, C.W. Wei, Y.C. Chuang, T.H. Young, J Micromech Microeng 16, 1143–1153 (2006) H.M. Yu, I. Meyvantsson, I.A. Shkel, D.J. Beebe, Lab Chip 5, 1089–1095 (2005) D.J. Yuan, S. Das, J. Appl. Phys. 101 (2007) B.A. Reynolds, S. Weiss, Science 255, 1707–1710 (1992) R.W. Sands, D.J. Mooney, Curr Opin Biotechnol 18, 448–453 (2007) F.S.H. Hsiao, C.C. Cheng, S.Y. Peng, H.Y. Huang, W.S. Lian, M.L. Jan, Y.T. Fang, E.C.H. Cheng, K.H. Lee, W.T.K. Cheng, S.P. Lin, S.C. Wu, Cell Prolif 43, 235–248 (2010)
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Springer Science and Business Media LLC

Tập 13

517-526

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