Material-driven fibronectin fibrillogenesis to engineer cell function.

Abstract

This thesis ventures with the extracellular matrix protein (ECM) fibronectin (FN) as an interface protein in the interaction between cells and materials to design microenvironment for future use in tissue engineering. It is studied the FN adsorption and conformations, cell behaviour to different FN conformation, cell adhesion, reorganisation and remodelling of FN at the material interface, the role of growth factors (GF) and their interactions with components of the extracellular matrix (ECM), the immunology cell response, and the stem cell fate influenced by the extrinsic signals coming from the engineered microenvironments using ECM's proteins. To investigate the FN response, in terms of adsorbed amount and conformation to different chemical properties of the material, model surfaces were used. Self assembled monolayers (SAM) with different percentages of two different chemical groups were used: CH3 and OH. FN adsorption, initial cell adhesion and signalling (focal adhesions, integrin expression and phosphorylation of FAK) is related with the reorganisation and secretion of FN and matrix degradation. It is shown that matrix degradation at the cell material interface depends on surface chemistry in metalloproteinase-dependent way. A direct relationship between FN activity at the cell-material interface and metalloproteinase 9 (MMP9) expression was found, being the product of a sequence of events that include integrin expression, focal adhesion formation, matrix reorganisation and focal adhesion kinase (FAK) phosphorylation. Two different materials with subtle variations in their chemical composition were employed as a drastically different FN conformation: from a globular conformation on PMA (poly (methyl acrylate)) to the formation of a well-interconnected FN network (similar to the FN physiological fibrillar network) triggered by PEA (poly (ethyl acrylate)). The formation of focal adhesions (vinculin), FAK expression and phosphorylation, specific integrin binding, protein and gene expression for ?5 and ?v was studied, seeking to correlate cell adhesion with matrix degradation. It is demonstrated that the material-driven FN fibrillogenesis on PEA triggers proteolytic activity: MMP activity is higher as a compensatory mechanism to the inability of cells to reorganise this FN network. Looking into the role of protein-material interactions and stem cell fate, and with the knowledge on PEA, we engineer different synergistic microenvironments to direct cell and stem cell fate. FN has a growth factor (GF) binding domain on its molecule (FNIII12-14) and has been demonstrated to produce a synergistic response when occurs at the same time the recognition of the cell binding domain (FNIII9-10). It is demonstrated that this domain is available on the FN coated PEA, and exploiting these interactions between PEA, FN and GF, it is developed a microenvironment to control cell behaviour and tissue repair. It is studied the BMP2 binding and presentation, the effect of BMP2 presentation on MSC proliferation and differentiation. These systems allow not only enhanced activity of GF compared to soluble administration, but also reduce GF doses, improving safety and cost effectiveness. Finally, the immunological reaction of the microenvironment developed is studied using dendritic cells, beside the conformational structure of ECM protein importance in DC integrin-based activation it is studied, helping to establish the field of adhesion-based modulation of DC as a general mechanism that has previously not been defined. The microenvironment didn't induce any maturation in DC, while different FN conformation shows differences in DC morphology and citokine level production (IL-10 and IL-12).