Der Einfluss cyclischer RGD-Peptide auf die Wechselwirkung Fibronectin-Integrin [alpha]5[beta]1[alpha 5 beta 1]

Zimmermann, Dunja.

January 2004

Bielefeld, Universiẗat, Diss., 2004.

Fibronectin

Klonierung, Expression und Charakterisierung einer kryptischen Fibronektin-Proteinase

Mende, Ayşe Aylin.

January 2003

Bielefeld, Universiẗat, Diss., 2002.

Fibronectin

The mitogenic activity of fibronectin fragments

Savill, C. M.

January 1985

No description available.

572

Fibronectin on cell growth

Fibronectin gene expression in higher eukaryotic cells

Dickinson, P.

January 1987

No description available.

572.8

Fibronectin gene regulation

An investigation of the latent mitogenic activity of fibronectin

Burrows, M. A.

January 1987

No description available.

572

Fibronectin mitogenic activity

Structural studies of modular proteins by NMR and molecular modelling

Phan, Isabelle Q. H.

January 1995

No description available.

572

Fibronectin; Integrins

The biochemistry of connective tissue

Vuillard, Laurent Michel Marie

January 1989

No description available.

572

Fibronectin biochemistry

Untersuchungen zur Rolle von PavA und der Fibronektin-vermittelten Interaktion von Streptococcus pneumoniae mit humanen Wirtszellen

Somplatzki, Daniela.

Unknown Date

Würzburg, Universiẗat, Diss., 2007.

Development of conformation-sensitive probes to fibronectin for ECM targeting and imaging of fibrosis

Cao, Lizhi

08 June 2015

Fibronectin (Fn) is an adhesive extracellular matrix protein assembled by fibroblasts into fibrils within ECMs of developing and remodeling tissues. Fn is sensitive to mechanical forces exerted by contractile cells, and can alter its structural conformations in response to mechanical strain within Fn fibrils. We developed probes (both peptide and antibody) to Fn to detect mechano-sensitive perturbations of Fn conformation. Probes were characterized for their binding characteristics (affinity, epitope, mechano-sensitivity) and validated on multiple in vitro and in vivo ECM models. Furthermore, we showed that the mechano-sensitive H5 antibody that we have developed have utility in detection of early molecular signatures of fibrosis in vivo in a mouse model of pulmonary fibrosis. Using the H5 antibody, we also report detection of a conformational switch within the integrin binding FnIII9-10 region. Modulation of Fn’s integrin switching behavior may help in the development of controllable “smart” biomaterials, as well as to the development of conformation-specific imaging probes to detect early molecular signatures of tumor and fibrotic ECMs.

Fibronectin

Fibrosis imaging

Integrin

Design and Engineering of 3D Collagen-Fibronectin Scaffolds for Wound Healing and Cancer Research

Asadishekari, Maryam

01 November 2018

Despite our understanding of the importance of the 3D environment on the behaviour of virtually every cell, most studies are still performed within 2D engineered cell culture devices. In this project, the main goal was to design and engineer tunable three-dimensional (3D) extracellular matrix (ECM)-mimicking scaffolds made of collagen and fibronectin (namely the two major building blocks of the ECM) that recapitulate the ECM structural and mechanical properties essential for wound healing and cancer research. Two different methods were implemented to fabricate 3D scaffolds. First, 3D collagen scaffolds with a ‘porous’ structure (fabricated by a previous student via an ice-templating technique) were used. It was shown that, by increasing collagen concentration to 1.25 wt.%, homogenous scaffolds with interconnected pores (needed for cell invasion through the entire scaffold) were obtained. Fibronectin (Fn) was then incorporated using thermal and mechanical gradients to modify protein content and tune scaffolds microarchitecture. The effect of Fn coating of the collagen underlying structure on cell behaviour such as cell adhesion, invasion and matrix deposition was studied. Results showed that overall more cells adhered to Fn-coated scaffolds with respect to pure collagen scaffolds. Furthermore, our findings indicated that cells were also able to sense the conformation of the Fn coating (as assessed by Fluorescence Resonance Energy Transfer, FRET) since they deposited a more compact ECM on compact Fn coating while a more unfolded and stretched ECM was deposited on unfolded Fn coating. Second, 3D more complex physiologically relevant scaffolds with a ‘fibrillar’ structure were fabricated via a cold/warm casting technique. Pure collagen scaffolds were first generated: in cold-cast scaffolds, clear thin and long collagen fibers were observed while warm-cast scaffolds were denser and comprised shorter collagen fibers. The effect of both collagen concentration and casting temperature on scaffolds’ microstructure was studied. Our results indicate a preponderant effect of temperature. We further engineered dual-protein fibronectin-collagen fibrillar scaffolds by incorporating Fn fibers using thermal gradient. Clear Fn fibers were observed in some conditions. FRET assessment of Fn fibers also showed significant difference of Fn conformation. In this more advanced casting technique, cells were initially embedded into the scaffolds, which provided a more homogeneous cell distribution and a better tissue-mimicking setting. In each case, the effect of resulting ECM properties was tested via cell viability assays. Our data indicate that cells were viable after 72 hours, they could proliferate inside the scaffolds and were able to spread in some conditions. Collectively, our 3D ECM-mimicking scaffolds represent a new tunable platform for biological and biomaterial research with many potential applications in tissue engineering and regenerative medicine. Investigating cell behaviour in 3D ECM-mimicking environment will provide valuable insights to understand cancer progression and approaches to limit the progression and ultimately prevent metastasis.

Biomaterials

Scaffolds

Collagen

Fibronectin