"In the MYO-DESMPOPLASIA project the fellow tested the hypothesis that the increase in ECM stiffness and TGFβ activation have additive effects on tumor desmoplasia. To explore this hypothesis, a combination of cutting-edge techniques were employed. Specifically, two and three dimensional (2D and 3D) collagen ECM models, with tunable stiffness were developed. Subsequently, pancreatic normal fibroblasts (FBs) and CAFs were cultured in the ECM models. Cells nanomechanical behavior and their morphodynamic alterations were investigated with Atomic Force Microscopy (AFM) and light/fluorescence microscopy under the presence or absence of TGFβ and under the influence of different stiffness. Also, cell spheroids were formed and cultured in 3D collagen gels with different stiffness in order to assess cells’ mobility/invasion under the influence of different collagen stiffness and the presence of TGFβ. Finally, the effects of TGFβ and matrix stiffness in the expression pattern of specific genes were investigated using real-time PCR.
Our results showed that CAFs present specific characteristic of the myofibroblasts phetotype, such as elongation and a-smooth muscle actin expression, while we demonstrated that CAFs have more lamellipodia and are softer compared to normal FBs. Also, it was revealed that TGFβ and collagen stiffness significantly affect CAFs basic morphodynamic characteristics, such as cell elongation, cell spreading, number of lamellipodia and stress fiber orientation, while this was not the case for normal FBs. For both FBs and CAFs it was found that TGFβ increase their stiffness in term of Young’s modulus values. Moreover, a significant correlation was revealed between cell spreading and RAC expression in both cell lines. Also, RhoA and ROCK expression was altered in CAFs after TGFβ treatment, which in combination with RAC expression is correlated to the increase in the number of lemellipodia, stress fiber orientation, cells’ mobility and stiffness. Although more research is needed to elucidate the exact involvement of TGFβ and ECM stiffness in desmoplasia, these findings provide new insights that need to be taken into consideration for understanding of desmoplasia or even for the development of novel therapeutic approaches for treating cancer having TGFβ as a target molecule.
Exploitation and dissemination
Conferences/forums and public engagement activities
-Stylianou, A, Stylianopoulos, T. (2016) ""Investigation of the effect of Tumor Growth Factor-β on Pancreatic Normal and Cancer Associated Fibroblasts"", Cyprus Researchers' Night 2016, 30 September, Nicosia, Cyprus (poster).
-Stylianou, A, Gkretsi, V. and Stylianopoulos, T. (2016) ""Effects of Tumor Growth Factor β on Pancreatic Cancer Associated Fibroblasts and Fibroblasts"", EUROAFMForum 2016, June, 22-24, 2016, Geneva, Switzerland (podium)
Journal Paper Publications (Peer-reviewed)
-Stylianou, A. (2017) ""Atomic Force Microscopy for Collagen-Based Nanobiomaterial"", Journal of Nanomaterials, art. id. 9234627
-Kontomaris, S.V and Stylianou, A. (2017) ""Atomic Force Microscopy for University Students, Application in Biomaterials"" European Journal of Physics, 38 (3)
-Stylianou, A. and Stylianopoulos, T. (2016) ""Atomic Force Microscopy Probing of Cancer Cells and Tumor Microenvironment Components"" BioNanoScience,6 (1), 33-46
-Gkretsi, V., Stylianou, A., Papageorgios, P., Polydorou, C. and Stylianopoulos, T. (2015) ""Remodeling components of the tumor microenvironment to enhance cancer therapy"" Frontiers in Oncology, 5 (214)
-Two research articles containing all the work performed during the period of the project is currently under preparation
-A book chapter is under publication: Stylianou, A., Gkretsi, V, Patrickios, C. and Stylianopoulos, T. ""Chapter 29: Exploring the nano-surface of fibrotic tissues with AFM"" In: Fibrosis: Methods and Protocols (Rittié L, ed), Springer.
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