Evaluation of cell binding to collagen and gelatin: a study of the effect of 2D and 3D architecture and surface chemistry

Studies of cell attachment to collagen-based materials often ignore details of the binding mechanisms—be they integrin-mediated or non-specific. In this work, we have used collagen and gelatin-based substrates with different dimensional characteristics (monolayers, thin films and porous scaffolds) in order to establish the influence of composition, crosslinking (using carbodiimide) treatment and 2D or 3D architecture on integrin-mediated cell adhesion. By varying receptor expression, using cells with collagen-binding integrins (HT1080 and C2C12 L3 cell lines, expressing α2β1, and Rugli expressing α1β1) and a parent cell line C2C12 with gelatin-binding receptors (αvβ3 and α5β1), the nature of integrin binding sites was studied in order to explain the bioactivity of different protein formulations. We have shown that alteration of the chemical identity, conformation and availability of free binding motifs (GxOGER and RGD), resulting from addition of gelatin to collagen and crosslinking, have a profound effect on the ability of cells to adhere to these formulations. Carbodiimide crosslinking ablates integrin-dependent cell activity on both two-dimensional and three-dimensional architectures while the three-dimensional scaffold structure also leads to a high level of non-specific interactions remaining on three-dimensional samples even after a rigorous washing regime. This phenomenon, promoted by crosslinking, and attributed to cell entrapment, should be considered in any assessment of the biological activity of three-dimensional substrates. Spreading data confirm the importance of integrin-mediated cell engagement for further cell activity on collagen-based compositions. In this work, we provide a simple, but effective, means of deconvoluting the effects of chemistry and dimensional characteristics of a substrate, on the cell activity of protein-derived materials, which should assist in tailoring their biological properties for specific tissue engineering applications.Graphical Abstract

[1]  R. Cameron,et al.  The synthesis and coupling of photoreactive collagen-based peptides to restore integrin reactivity to an inert substrate, chemically-crosslinked collagen , 2016, Biomaterials.

[2]  W. Zimmermann,et al.  Tissue Engineering of a Differentiated Cardiac Muscle Construct , 2002, Circulation research.

[3]  F. O'Brien Biomaterials & scaffolds for tissue engineering , 2011 .

[4]  R. Cameron,et al.  Bioactive IGF-1 release from collagen–GAG scaffold to enhance cartilage repair in vitro , 2015, Journal of Materials Science: Materials in Medicine.

[5]  Thilo Stehle,et al.  Crystal Structure of the Extracellular Segment of Integrin αVβ3 in Complex with an Arg-Gly-Asp Ligand , 2002, Science.

[6]  J. Liao,et al.  Fabrication of cardiac patch with decellularized porcine myocardial scaffold and bone marrow mononuclear cells. , 2010, Journal of biomedical materials research. Part A.

[7]  Serena M. Best,et al.  Crosslinking and composition influence the surface properties, mechanical stiffness and cell reactivity of collagen-based films , 2012, Acta Biomaterialia.

[8]  P. D. de Groot,et al.  Synergism between platelet collagen receptors defined using receptor-specific collagen-mimetic peptide substrata in flowing blood. , 2010, Blood.

[9]  Y. H. Hui,et al.  Encyclopedia of food science and technology , 1992 .

[10]  R. Farndale,et al.  Integrin recognition motifs in the human collagens. , 2014, Advances in experimental medicine and biology.

[11]  Qizhi Chen,et al.  Biomaterials in cardiac tissue engineering: Ten years of research survey , 2008 .

[12]  A Oosterhof,et al.  Preparation and characterization of porous crosslinked collagenous matrices containing bioavailable chondroitin sulphate. , 1999, Biomaterials.

[13]  Jonathan Boyd,et al.  The three-dimensional structure of the tenth type III module of fibronectin: An insight into RGD-mediated interactions , 1992, Cell.

[14]  P. Siljander,et al.  Use of Synthetic Peptides to Locate Novel Integrin α2β1-binding Motifs in Human Collagen III* , 2006, Journal of Biological Chemistry.

[15]  J. Veerkamp,et al.  Development of tailor-made collagen-glycosaminoglycan matrices: EDC/NHS crosslinking, and ultrastructural aspects. , 2000, Biomaterials.

[16]  Lorna J. Gibson,et al.  In vivo and in vitro applications of collagen-GAG scaffolds , 2008 .

[17]  R. Cameron,et al.  Optimisation of UV irradiation as a binding site conserving method for crosslinking collagen-based scaffolds , 2015, Journal of Materials Science: Materials in Medicine.

[18]  C. Watson,et al.  A 3-D in vitro co-culture model of mammary gland involution. , 2014, Integrative biology : quantitative biosciences from nano to macro.

[19]  P. So,et al.  Biologically active collagen-based scaffolds: advances in processing and characterization , 2010, Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences.

[20]  R. Farndale,et al.  The Collagen-binding A-domains of Integrins α1β1 and α2β1Recognize the Same Specific Amino Acid Sequence, GFOGER, in Native (Triple-helical) Collagens* , 2000, The Journal of Biological Chemistry.

[21]  John T Elliott,et al.  Vascular smooth muscle cell response on thin films of collagen. , 2005, Matrix biology : journal of the International Society for Matrix Biology.

[22]  Chikara Ohtsuki,et al.  A unified in vitro evaluation for apatite-forming ability of bioactive glasses and their variants , 2015, Journal of Materials Science: Materials in Medicine.

[23]  G. Davis,et al.  Affinity of integrins for damaged extracellular matrix: alpha v beta 3 binds to denatured collagen type I through RGD sites. , 1992, Biochemical and biophysical research communications.

[24]  C. Moseke,et al.  Reaction kinetics of dual setting α-tricalcium phosphate cements , 2015, Journal of Materials Science: Materials in Medicine.

[25]  Serena M Best,et al.  Investigating the morphological, mechanical and degradation properties of scaffolds comprising collagen, gelatin and elastin for use in soft tissue engineering. , 2012, Journal of the mechanical behavior of biomedical materials.

[26]  M. Ruel,et al.  Cardiac Tissue Engineering , 2014, Methods in Molecular Biology.

[27]  R. Cameron,et al.  Cell Invasion in Collagen Scaffold Architectures Characterized by Percolation Theory , 2015, Advanced healthcare materials.

[28]  George E. Davis,et al.  Affinity of integrins for damaged extracellular matrix: αvβ3 binds to denatured collagen type I through RGD sites , 1992 .

[29]  Richard O Hynes,et al.  Integrins Bidirectional, Allosteric Signaling Machines , 2002, Cell.

[30]  C. Watson,et al.  Collagen-hyaluronic acid scaffolds for adipose tissue engineering. , 2010, Acta biomaterialia.

[31]  C. Carman,et al.  Structural basis of integrin regulation and signaling. , 2007, Annual review of immunology.

[32]  W. Ouwehand,et al.  Integrin Activation State Determines Selectivity for Novel Recognition Sites in Fibrillar Collagens* , 2004, Journal of Biological Chemistry.

[33]  Oliver H. Lowry,et al.  THE DETERMINATION OF COLLAGEN AND ELASTIN IN TISSUES, WITH RESULTS OBTAINED IN VARIOUS NORMAL TISSUES FROM DIFFERENT SPECIES , 1941 .

[34]  Neil Rushton,et al.  Extruded collagen fibres for tissue engineering applications: effect of crosslinking method on mechanical and biological properties , 2011, Journal of materials science. Materials in medicine.

[35]  Richard W. Farndale,et al.  Structural Basis of Collagen Recognition by Integrin α2β1 , 2000, Cell.

[36]  Simon P Hoerstrup,et al.  Cell therapy, 3D culture systems and tissue engineering for cardiac regeneration. , 2014, Advanced drug delivery reviews.

[37]  R. Weisel,et al.  Construction of a bioengineered cardiac graft. , 2000, The Journal of thoracic and cardiovascular surgery.

[38]  J. Leor,et al.  Cells, scaffolds, and molecules for myocardial tissue engineering. , 2005, Pharmacology & therapeutics.

[39]  R. Cameron,et al.  Control of crosslinking for tailoring collagen-based scaffolds stability and mechanics , 2015, Acta biomaterialia.

[40]  A. Boccaccini,et al.  Strategies for the chemical and biological functionalization of scaffolds for cardiac tissue engineering: a review , 2015, Journal of The Royal Society Interface.

[41]  P. Smethurst,et al.  Identification in Collagen Type I of an Integrin α2β1-binding Site Containing an Essential GER Sequence* , 1998, The Journal of Biological Chemistry.

[42]  Yugyung Lee,et al.  Biomedical applications of collagen. , 2001, International journal of pharmaceutics.

[43]  R. Cameron,et al.  The interplay between physical and chemical properties of protein films affects their bioactivity. , 2012, Journal of biomedical materials research. Part A.

[44]  Neil Rushton,et al.  Effect of 1-ethyl-3-(3-dimethylaminopropyl) carbodiimide and N-hydroxysuccinimide concentrations on the mechanical and biological characteristics of cross-linked collagen fibres for tendon repair , 2015, Regenerative biomaterials.

[45]  J. Ramshaw,et al.  The collagen triple-helix structure. , 1997, Matrix biology : journal of the International Society for Matrix Biology.

[46]  K. Kar,et al.  Triple-helical peptides: an approach to collagen conformation, stability, and self-association. , 2008, Biopolymers.

[47]  J. Feijen,et al.  Cross-linking of dermal sheep collagen using a water-soluble carbodiimide. , 1996, Biomaterials.

[48]  Fergal J O'Brien,et al.  The effect of mean pore size on cell attachment, proliferation and migration in collagen-glycosaminoglycan scaffolds for bone tissue engineering. , 2010, Biomaterials.

[49]  R. Liddington,et al.  Structural basis of collagen recognition by integrin alpha2beta1. , 2000, Cell.