Limb derived cells as a paradigm for engineering self-assembling skeletal tissues.

[en] Mimicking developmental events has been proposed as a strategy to engineer tissue constructs for regenerative medicine. However, this approach has not yet been investigated for skeletal tissues. Here, it is demonstrated that ectopic implantation of day-14.5 mouse embryonic long bone anlagen, dissociated into single cells and randomly incorporated in a bioengineered construct, gives rise to epiphyseal growth plate-like structures, bone and marrow, which share many morphological and molecular similarities to epiphyseal units that form after transplanting intact long bone anlage, demonstrating substantial robustness and autonomy of complex tissue self-assembly and the overall organogenesis process. In vitro studies confirm the self-aggregation and patterning capacity of anlage cells and demonstrate that the model can be used to evaluate the effects of large and small molecules on biological behaviour. These results reveal the preservation of self-organizing and self-patterning capacity of anlage cells even when disconnected from their developmental niche and subjected to system perturbations such as cellular dissociation. These inherent features make long bone anlage cells attractive as a model system for tissue engineering technologies aimed at creating constructs that have the potential to self-assemble and self-pattern complex architectural structures.

Disciplines :

Engineering, computing & technology: Multidisciplinary, general & others

Author, co-author :

Fernando, Warnakulasuriya A.

Papantoniou, Ioannis

Mendes, Luis F.

Hall, Gabriella Nilsson

Bosmans, Kathleen

Tam, Wai L.

Teixeira, Liliana M.

Moos, Malcolm Jr

Luyten, Frank

Geris, Liesbet ; Université de Liège - ULiège > Département d'aérospatiale et mécanique > Génie biomécanique

Language :

English

Title :

Limb derived cells as a paradigm for engineering self-assembling skeletal tissues.

Publication date :

2017

Journal title :

Journal of Tissue Engineering and Regenerative Medicine

ISSN :

1932-6254

eISSN :

1932-7005

Publisher :

John Wiley & Sons, United Kingdom

Peer reviewed :

Peer reviewed

European Projects :

FP7 - 279100 - BRIDGE - Biomimetic process design for tissue regeneration: from bench to bedside via in silico modelling

Funders :

CE - Commission Européenne [BE]

Commentary :

Available on ORBi :

since 18 June 2018

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Bibliography

Abad, V., Meyers, J. L., Weise, M., Gafni, R. I., Barnes, K. M., Nilsson, O., … Baron, J. (2002). The role of the resting zone in growth plate chondrogenesis. Endocrinology, 143(5), 1851–1857.
Abad, V., Uyeda, J. A., Temple, H. T., De Luca, F., & Baron, J. (1999). Determinants of spatial polarity in the growth plate. Endocrinology, 140(2), 958–962.
Amano, K., Densmore, M. J., & Lanske, B. (2015). Conditional deletion of Indian hedgehog in limb mesenchyme results in complete loss of growth plate formation but allows mature osteoblast differentiation. Journal of Bone and Mineral Research, 30(12), 2262–2272.
Bhumiratana, S., Eton, R. E., Oungoulian, S. R., Wan, L. Q., Ateshian, G. A., & Vunjak-Novakovic, G. (2014). Large, stratified, and mechanically functional human cartilage grown in vitro by mesenchymal condensation. Proceedings of the National Academy of Sciences of the United States of America, 111(19), 6940–6945.
Chaudhuri, O., Gu, L., Klumpers, D., Darnell, M., Bencherif, S. A., Weaver, J. C., … Mooney, D. J. (2016). Hydrogels with tunable stress relaxation regulate stem cell fate and activity. Nature Materials, 15(3), 326.
Chen, J. K. (2016). I only have eye for ewe: The discovery of cyclopamine and development of hedgehog pathway-targeting drugs. Natural Products Reports, 33(5), 595–601.
Cho, J. Y., Grant, T. D., Lunstrum, G. P., & Horton, W. A. (2001). Col2-GFP reporter mouse – A new tool to study skeletal development. American Journal of Medical Genetics, 106(4), 251–253.
Daly, A. C., Cunniffe, G. M., Sathy, B. N., Jeon, O., Alsberg, E., & Kelly, D. J. (2016). 3D Bioprinting of developmentally inspired templates for whole bone organ engineering. Advanced Healthcare Materials, 5(18), 2353–2362.
Eiraku, M., Takata, N., Ishibashi, H., Kawada, M., Sakakura, E., Okuda, S., … Sasai, Y. (2011). Self-organizing optic-cup morphogenesis in three-dimensional culture. Nature, 472(7341), 51–56.
Eiraku, M., Watanabe, K., Matsuo-Takasaki, M., Kawada, M., Yonemura, S., Matsumura, M., … Sasai, Y. (2008). Self-organized formation of polarized cortical tissues from ESCs and its active manipulation by extrinsic signals. Cell Stem Cell, 3(5), 519–532.
Eyckmans, J., Roberts, S., Bolander, J., Schrooten, J., Chen, C. S., & Luyten, F. P. (2013). Mapping calcium phosphate activated gene networks as a strategy for targeted osteoinduction of human progenitors. Biomaterials, 34(19), 4612–4621.
Galceran, J., Fariñas, I., Depew, M. J., Clevers, H., & Grosschedl, R. (1999). Wnt3a−/−−like phenotype and limb deficiency in Lef1(−/−)Tcf1(−/−) mice. Genes & Development, 13(6), 709–717.
Hippen, B., Ross, L. F., & Sade, R. M. (2009). Saving lives is more important than abstract moral concerns: Financial incentives should be used to increase organ donation. The Annals of Thoracic Surgery, 88(4), 1053–1061.
Huebsch, N., Lippens, E., Lee, K., Mehta, M., Koshy, S. T., Darnell, M. C., … Mooney, D. J. (2015). Matrix elasticity of void-forming hydrogels controls transplanted-stem-cell-mediated bone formation. Nature Materials, 14(12), 1269–1277.
Ikeda, E., Morita, R., Nakao, K., Ishida, K., Nakamura, T., Takano-Yamamoto, T., … Tsuji, T. (2009). Fully functional bioengineered tooth replacement as an organ replacement therapy. Proceedings of the National Academy of Sciences of the United States of America, 106(32), 13475–13480.
Ingber, D. E., Mow, V. C., Butler, D., Niklason, L., Huard, J., Mao, J., … Vunjak-Novakovic, G. (2006). Tissue engineering and developmental biology: Going biomimetic. Tissue Engineering, 12(12), 3265–3283.
Jukes, J. M., Both, S. K., Leusink, A., Sterk, L. M., van Blitterswijk, C. A., & de Boer, J. (2008). Endochondral bone tissue engineering using embryonic stem cells. Proceedings of the National Academy of Sciences of the United States of America, 105(19), 6840–6845.
Kang, H. W., Lee, S. J., Ko, I. K., Kengla, C., Yoo, J. J., & Atala, A. (2016). A 3D bioprinting system to produce human-scale tissue constructs with structural integrity. Nature Biotechnology, 34(3), 312–319.
Kawanami, A., Matsushita, T., Chan, Y. Y., & Murakami, S. (2009). Mice expressing GFP and CreER in osteochondro progenitor cells in the periosteum. Biochemical and Biophysical Research Communications, 386(3), 477–482.
Kronenberg, H. M. (2003). Developmental regulation of the growth plate. Nature, 423(6937), 332–336.
Lenas, P., Luyten, F. P., Doblare, M., Nicodemou-Lena, E., & Lanzara, A. E. (2011). Modularity in developmental biology and artificial organs: A missing concept in tissue engineering. Artificial Organs, 35(6), 656–662.
Lenas, P., Moos, M., & Luyten, F. P. (2009). Developmental engineering: A new paradigm for the design and manufacturing of cell-based products. Part II: From genes to networks: Tissue engineering from the viewpoint of systems biology and network science. Tissue Engineering. Part B, Reviews, 15(4), 395–422.
Lipsitz, Y. Y., Timmins, N. E., & Zandstra, P. W. (2016). Quality cell therapy manufacturing by design. Nature Biotechnology, 34(4), 393–400.
Lutolf, M. P., & Hubbell, J. A. (2005). Synthetic biomaterials as instructive extracellular microenvironments for morphogenesis in tissue engineering. Nature Biotechnology, 23(1), 47–55.
Maye, P., Fu, Y., Butler, D. L., Chokalingam, K., Liu, Y., Floret, J., … Rowe, D. (2011). Generation and characterization of Col10a1-mcherry reporter mice. Genesis, 49(5), 410–418.
Nakao, K., Morita, R., Saji, Y., Ishida, K., Tomita, Y., Ogawa, M., … Tsuji, T. (2007). The development of a bioengineered organ germ method. Nature Methods, 4(3), 227–230.
Occhetta, P., Centola, M., Tonnarelli, B., Redaelli, A., Martin, I., & Rasponi, M. (2015). High-throughput microfluidic platform for 3D cultures of mesenchymal stem cells, towards engineering developmental processes. Scientific Reports, 5, 10288.
Ohazama, A., Modino, S. A., Miletich, I., & Sharpe, P. T. (2004). Stem-cell-based tissue engineering of murine teeth. Journal of Dental Research, 83(7), 518–522.
Sasai, Y. (2013a). Cytosystems dynamics in self-organization of tissue architecture. Nature, 493(7432), 318–326.
Sasai, Y. (2013b). Next-generation regenerative medicine: Organogenesis from stem cells in 3D culture. Cell Stem Cell, 12(5), 520–530.
Scotti, C., Piccinini, E., Takizawa, H., Todorov, A., Bourgine, P., Papadimitropoulos, A., … Martin, I. (2013). Engineering of a functional bone organ through endochondral ossification. Proceedings of the National Academy of Sciences of the United States of America, 110(10), 3997–4002.
Scotti, C., Tonnarelli, B., Papadimitropoulos, A., Scherberich, A., Schaeren, S., Schauerte, A., … Martin, I. (2010). Recapitulation of endochondral bone formation using human adult mesenchymal stem cells as a paradigm for developmental engineering. Proceedings of the National Academy of Sciences of the United States of America, 107(16), 7251–7256.
Takahashi, K., Tanabe, K., Ohnuki, M., Narita, M., Ichisaka, T., Tomoda, K., & Yamanaka, S. (2007). Induction of pluripotent stem cells from adult human fibroblasts by defined factors. Cell, 131(5), 861–872.
Tonnarelli, B., Centola, M., Barbero, A., Zeller, R., & Martin, I. (2014). Re-engineering development to instruct tissue regeneration. Current Topics in Developmental Biology, 108, 319–338.
Zheng, Y., Nace, A., Chen, W., Watkins, K., Sergott, L., Homan, Y., … Stenn, K. (2010). Mature hair follicles generated from dissociated cells: A universal mechanism of folliculoneogenesis. Developmental Dynamics: An Official Publication of the American Association of Anatomists, 239(10), 2619–2626.