Adsorption-induced fibronectin aggregation and fibrillogenesis

Fibronectin (Fn), a high molecular weight glycoprotein, is a central element of extracellular matrix architecture that is involved in several fundamental cell processes. In the context of bone biology, little is known about the influence of the mineral surface on fibronectin supramolecular assembly. We investigate fibronectin morphological properties induced by its adsorption onto a model mineral matrix of hydroxyapatite (HA). Fibronectin adsorption onto HA spontaneously induces its aggregation and fibrillation. In some cases, fibronectin fibrils are even found connected into a dense network that is close to the matrix synthesized by cultured cells. Fibronectin adsorption-induced self-assembly is a time-dependant process that is sensitive to bulk concentration. The N-terminal domain of the protein, known to be implicated in its self-association, does not significantly inhibit the protein self-assembly while increasing ionic strength in the bulk alters both aggregation and fibrillation. The addition of a non-ionic surfactant during adsorption tends to promote aggregation with respect to fibrillation. Ultimately, fibronectin fibrils appear to be partially structured like amyloid fibrils as shown by thioflavine T staining. Taken together, our results suggest that there might be more than one single organization route involved in fibronectin self-assembly onto hydroxyapatite. The underlying mechanisms are discussed with respect to Fn conformation, Fn/surface and Fn/Fn interactions, and a model of fibronectin fibrillogenesis onto hydroxyapatite is proposed.     

Inhibition of blood coagulation factor XIIIa-mediated cross-linking between fibronectin and collagen by polyamines

Soluble fibronectin is found in body fluids and media of cultured adherent cells. Insoluble fibronectin is found in tissue stroma and in extracellular matrices of cultured cells. Fibronectin is a substrate for factor XIIIa (plasma transglutaminase) and can be cross-linked to collagen and to the alpha chain of fibrin. We have used sodium dodecyl sulfate-polyacrylamide gel electrophoresis to investigate the possibility that factor XIIIa-mediated cross-linking is influenced by polyamines. Spermidine inhibited cross-linking between fibronectin and type I collagen, isolated alpha 1 (I) collagen chains, or iodinated cyanogen bromide fragment 7 of alpha 1 (I) chains (125I-alpha 1 (I)-CB7). Half-maximal inhibition of cross-linking between 125I-alpha (I)-CB7 and fibronectin was observed when 0.1 mM spermine or spermidine was present. Spermidine, 0.7 mM, partially inhibited cross-linking between fibronectin and the alpha chain of fibrin but failed to inhibit cross-linking between the fibrin monomers of a fibrin clot. Spermidine also failed to inhibit cross-linking between fibronectin molecules when aggregation of fibronectin was induced with dithiothreitol. In contrast, 0.7 mM monodanyslcadaverine inhibited fibronectin-collagen, fibronectin-fibrin, fibronectin-fibronectin, and fibrin-fibrin cross-linking. Spermidine or spermine, 0.7 mM, enhanced the cross-linking between molecules of partially amidinated fibronectin, suggesting that N1,8-(di-gamma-glutamyl)-polyamine cross-linkages were formed. Spermidine and spermine failed to enhance cross-linking between monomers of amidinated fibrin. These results indicate that physiologic concentrations of polyamines specifically disturb transglutaminase-catalyzed cross-linking between fibronectin and collagen.     

Liquid crystallinity in collagen systems in vitro and in vivo

Collagens are unique triple helical proteins present in large quantities in a fibrillar form in tissues like tendon, bone, skin, cornea, where type I collagen predominates. The passage from triple helical molecules to fibrils obeys to controlled assembly properties, both in vitro by pH raise and in vivo through enzymatic control. The passage from individual fibrils to ordered fibrillar arrays could rely on self-assembly processes as suggested by the liquid crystalline properties of collagen. The present review considers this question recalling the liquid crystalline ordering properties of collagen or procollagen at high concentrations and the question of molecular packing within fibrils. The presence of alignments, undulations and twist at a suprafibrillar level will be described both from basic data in living tissues and recent experiments in self assembled materials. The possible link between laboratory experiences and biological processes will be discussed.     

Adsorption and conformation behavior of biotinylated fibronectin on streptavidin-modified TiO(X) surfaces studied by SPR and AFM

It is well-known that protein-modified implant surfaces such as TiO(2) show a higher bioconductivity. Fibronectin is a glycoprotein from the extracellular matrix (ECM) with a major role in cell adhesion. It can be applied on titanium oxide surfaces to accelerate implant integration. Not only the surface concentration but also the presentation of the protein plays an important role for the cellular response. We were able to show that TiO(X) surfaces modified with biotinylated fibronectin adsorbed on a streptavidin-silane self-assembly multilayer system are more effective regarding osteoblast adhesion than surfaces modified with nonspecifically bound fibronectin. The adsorption and conformation behavior of biotinylated and nonbiotinylated (native) fibronectin was studied by surface plasmon resonance (SPR) spectroscopy and atomic force microscopy (AFM). Imaging of the protein modification revealed that fibronectin adopts different conformations on nonmodified compared to streptavidin-modified TiO(X) surfaces. This conformational change of biotinylated fibronectin on the streptavidin monolayer delivers a fibronectin structure similar to the conformation inside the ECM and therefore explains the higher cell affinity for these surfaces.     

Influence of collagen denaturation on the nanoscale organization of adsorbed layers

Adsorption (at 37 degrees C) of type I collagen, in native and heat-denatured (30 min at 40 and 90 degrees C) forms, on polystyrene was studied using quartz crystal microbalance with energy dissipation monitoring (QCM-D), atomic force microscopy (AFM) in tapping mode and X-ray photoelectron spectroscopy (XPS). The significance of the parameters deduced from QCM-D data was examined by comparing different approaches. The adsorbed layer of native collagen has a complex organization consisting of a thin mat of molecules near the surface, in which fibrils develop depending on concentration and time, and of a thicker overlayer containing protruding molecules or bundles which modify noticeably the local viscosity. As a result of drastic denaturation, the ability of collagen to assemble into fibrils in the adsorbed phase is lost and the protrusion of molecules into the aqueous phase is much less pronounced. The adsorbed layer of denatured collagen appears essentially as a monolayer of flattened coils. At low concentration, this is easily displaced upon drying, leading to particular dewetting figures; at high concentration, aggregates add to the first layer. Moderate denaturation leads to an adsorbed phase which shows properties intermediate between those observed with native and extensively denatured collagen, regarding the ability to form fibrillar structures and the adlayer thickness and viscosity.     

Observation of geometric structure of collagen molecules by atomic force microscopy

Atomic force microscopy was used to study the geometric structure of collagen fibrils and molecules of rat calcanean tendon tissues. The authors found that the diameter of the fibrils ranged from 124 to 170 nm, and their geometric form suggested a helical winding with spectral period from 59.4 to 61.7 nm, close to the band dimensions reported by electron microscopy. At high magnification, the surface of these bands revealed images that probably correspond to the almost crystalline array of collagen molecules, with the triple helix structure almost visible. The typical helix width is 1.43 nm, with main periods of 1.15 and 8.03 nm, very close to the dimensions reported by X-ray diffraction.     

Characterization of the interaction between human plasma fibronectin and collagen by means of affinity electrophoresis.

The interaction between human plasma fibronectin and different types and forms of collagen were analysed by affinity electrophoresis at different pH values. The fibronectin bound tightly to collagen type I, III and IV, but not to type V. The fibronectin interacted better with the denatured form of collagen type I (gelatin) than with the native form. At pH less than 5.5 the fibronectin exhibited much lower affinity to gelatin than at pH greater than 8.0. The interaction between the fibronectin and gelatin was further analysed by affinity electrophoresis in which apparent dissociation constants (Kd) of the fibronectin for gelatin were calculated, and effects of urea, 2-mercaptoethanol and temperature on the interaction were examined. The fibronectin markedly diminished its affinity to gelatin at 3 M urea to give Kd = 2.5 x 10(-6) M, which was 1000 times larger than the value without urea. The fibronectin dissociated into its monomers and the monomers diminished their affinity to gelatin in a stepwise fashion with increase in concentration of 2-mercaptoethanol. The fibronectin diminished the affinity to gelatin by elevating temperature, and van't Hoff plots of log Kd values against the reciprocal of absolute temperature (T) showed that log Kd was inversely proportional to 1/T in the range 15-50 degrees C, and the thermodynamic parameters of the standard enthalpy change, the standard free energy change and the entropy change at 37 degrees C for association of fibronectin and gelatin were all negative. At 60 degrees C the affinity of fibronectin to gelatin was not detectable.(ABSTRACT TRUNCATED AT 250 WORDS)     

The biochemistry of cell-adhesion

The proposition is examined that adhesion between cells of animal tissues, and between cells and their extracellular matrix, is brought about by specific molecules present at cell-surfaces. Evidence is surveyed which has begun to emerge from the use of antibodies which inhibit or reverse adhesion. Putative cell-adhesion molecules in cellular slime-moulds and cells of chick and mouse embryos have been identified by their ability to neutralize the adhesion-inhibiting activity of monovalent fragments of polyspecific antibodies. In some instances antibodies have also been used to investigate the role of the cell-adhesion molecules in morphogenetic phenomena. A possible parallel is discussed between the effects of calcium ions on the cell-adhesion molecule uvomorulin from mouse blastomeres, and its effects on certain other cell-adhesion molecules.Although the role of fibronectin in promoting attachment and spreading of cells on artificial substrates and on denatured collagen is firmly established, there is little evidence that this glycoprotein is involved in direct intercellular adhesion. The observation that cells spread on adsorbed fibronectin, whereas binding of individual fibronectin molecules to cells is difficult to demonstrate may merely indicate that fibronectin is a relatively weak ligand for cell-surfaces. It is suggested that rather than being a necessary intermediate in the adhesion of cells to collagen, fibronectin may form matrix in its own right which shares with native collagen the ability to promote cell-attachment and spreading.The long-held view that cell-surface oligosaccharides act as receptors in cell-adhesion appears still to be largely unsubstantiated. However the poorly adhesive properties of cells from many different lines with glycosylation defects strongly suggest N-linked oligosaccharides of glycoproteins are involved in some way as yet not determined.     

Comparative Study of The Yield and Physicochemical Properties of Collagen from Sea Cucumber (Holothuria scabra), Obtained through Dialysis and the Ultrafiltration Membrane

Collagen was extracted from the body wall of sea cucumber (Holothuria scabra) using the pepsin-solubilized collagen method followed by isolation using dialysis and the ultrafiltration membrane. The yield and physicochemical properties of the collagen obtained from both isolation methods, denoted as D-PSC and UF-PSC, were compared. The ultrafiltration method affords a higher yield of collagen (11.39%) than that of the dialysis (5.15%). The isolated collagens have almost the same amino acid composition, while their functional groups, referred to as amide A, B, I, II, and III bands, were in accordance with commercial collagen, as verified by Fourier Transform Infrared (FT-IR) spectroscopy. The UV-Vis absorption peaks at 240 nm and 220 nm, respectively, indicated that the collagens produced are type-I collagen. The D-PSC showed interconnecting sheet-like fibrils, while the UF-PSC exhibited a flaky structure with flat-sheets arranged very close to each other. The higher yield and comparable physicochemical properties of the collagen obtained by ultrafiltration as compared with dialysis indicate that the membrane process has high potential to be used in large-scale collagen production for food and pharmaceutical applications.     

Collagen of porcine auricle has unique biochemical and biophysical characteristics

Collagen is a major component of the extracellular matrix and is used as a material in tissue engineering. We demonstrated the extraction of atelocollagen from porcine auricular and characterized its unique physical and biochemical properties. Extracted type I collagens of auricular collagen using acetic acid and pepsin (PAC) showed superior fibrillogenesis and viscoelasticity compared to type I collagen from porcine skin. The observation of PAC fibrils by transmission electron microscopy and Atomic Force Microscope under physiological conditions revealed long fibrils with pronounced 3D structures, while type I collagen from porcine skin revealed a flat structure. Furthermore, a PAC-coated plate promoted higher cell proliferation than when grown on a skin type I collagen-coated plate. Porcine auricular type I collagen has superior biophysical and biological properties in terms of viscoelasticity, fibrillogenesis, and cell proliferation, and can be used in further studies toward novel potential applications in the field of medical materials.     

Quantitative measurement of collagen methylation by capillary electrophoresis

Collagen methylation has been exploited in various applications involving living cells. We have observed correlation between the collagen methylation with the rate of cell proliferation in three-dimensional (3-D) microenvironment. To quantify the degree of collagen methylation, we have developed a capillary zone electrophoresis method. Using a polyvinyl alcohol-coated fused-silica capillary and UV detection at 200 nm, we have optimized pH and separated the native collagen into three major bands in phosphate buffer (50 mM, pH 2.5) with 0.05% hydroxypropylmethylcellulose. Under these conditions, the methylated collagens were separated into four major bands, which changed with different methylation reaction conditions. We propose an index to quantify the degree of collagen methylation that also correlates with their effects on cell proliferation.     

On collagen II fibrillogenesis

Collagen fibrils exhibit noticeable differences in their molecular order in the direction perpendicular to fibril axis. For instance, three-dimensional crystallinity prevails for type I collagen (e.g. tendons) whereas only liquid-like order in the lateral direction prevails for type II collagen (e.g. cartilage). The latter situation has been likened to that of a smectic liquid crystal. It is suggested here that the fibrillogenesis of type II collagen is indeed directed by a possibly metastable liquid crystalline mesophase involving a supramolecular assembling process. The occurrence of decoration on the fibrillar surface enhances a liquid crystalline phase due to preferential growth assumed to continue along the axial direction, and an increasing persistence length with respect to triple-helical collagen molecules.     

Matrix-dependent adhesion of vascular and valvular endothelial cells in microfluidic channels

The interactions between endothelial cells and the underlying extracellular matrix regulate adhesion and cellular responses to microenvironmental stimuli, including flow-induced shear stress. In this study, we investigated the adhesion properties of primary porcine aortic endothelial cells (PAECs) and valve endothelial cells (PAVECs) in a microfluidic network. Taking advantage of the parallel arrangement of the microchannels, we compared adhesion of PAECs and PAVECs to fibronectin and type I collagen, two prominent extracellular matrix proteins, over a broad range of concentrations. Cell spreading was measured morphologically, based on cytoplasmic staining with a vital dye, while adhesion strength was characterized by the number of cells attached after application of shear stresses of 11, 110, and 220 dyn cm(-2). Results showed that PAVECs were more well spread on fibronectin than on type I collagen (P < 0.0001), particularly for coating concentrations of 100, 200, and 500 microg mL(-1). PAVECs also withstood shear significantly better on fibronectin than on collagen for 500 microg mL(-1). PAECs were more well spread on collagen compared to PAVECs (P < 0.0001), but did not have significantly better adhesion strength. These results demonstrate that cell adhesion is both cell-type and matrix dependent. Furthermore, they reveal important phenotypic differences between vascular and valvular endothelium, with implications for endothelial mechanobiology and the design of microdevices and engineered tissues.     

On collagen II fibrillogenesis

Collagen fibrils exhibit noticeable differences in their molecular order in the direction perpendicular to fibril axis. For instance, three‐dimensional crystallinity prevails for type I collagen (e.g. tendons) whereas only liquid‐like order in the lateral direction prevails for type II collagen (e.g. cartilage). The latter situation has been likened to that of a smectic liquid crystal. It is suggested here that the fibrillogenesis of type II collagen is indeed directed by a possibly metastable liquid crystalline mesophase involving a supramolecular assembling process. The occurrence of decoration on the fibrillar surface enhances a liquid crystalline phase due to preferential growth assumed to continue along the axial direction, and an increasing persistence length with respect to triple‐helical collagen molecules.     

Laminated morphology of nontwisting beta-sheet fibrils constructed via peptide self-assembly

A synthetic peptide has been de novo designed that self-assembles into beta-sheet fibrils exhibiting a nontwisted, stacked morphology. The stacked morphology is constituted by 2.5 nm wide filaments that laterally associate to form flat fibril laminates exceeding 50 nm in width and micrometers in length. The height of each fibril is limited to the length of exactly one peptide monomer in an extended beta-strand conformation, approximately 7 nm. Once assembled, these highly ordered, 2-D structures are stable over a wide range of pH and temperature and exhibit characteristics similar to those of amyloid fibrils. Furthermore, the rate of assembly and degree of fibril lamination can be controlled with kinetic parameters of pH and temperature. Finally, the presence of a diproline peptide between two beta-sheet-forming strands in the peptide sequence is demonstrated to be an important factor in promoting the nontwisting, laminated fibril morphology.     

The complexation mode of metal ions with Langmuir monolayers of nitrogen-containing flavonoid glycoside-based surfactants derived from rutin

The nanofibrillar feature of native type I collagen is of great importance in maintaining its functions in vivo. In the field of engineering collagen-based materials in vitro, different fabrications may yield differences in collagen organization and thus affect the nanofibrous structure. Two approaches of fabricating collagen-chitosan (Col-Chi) scaffolds were presented in this study to investigate the respective impacts especially on nanostructures. Compared with glutaraldehyde cross-linking fabrications, thermally triggered cofibrillogenesis showed a preferred capability in fabricating favorable porous scaffolds and preserving uniform and orderly assembled nanofibrils. A detailed kinetic study of the cofibrillogenesis in thermally triggered approach was then carried out to reveal the possible factors affecting the final fibrillar structures. Zeta potential measurements in different Col-Chi blends with varying Chi/Col ratios indicated the influences of electrostatic interactions on the subsequent cofibrillogenesis process. The native D-periodicity of ～64 nm was found on collagen fibrils in the presence of different amounts of chitosan by atomic force microscopy observation. The relevance of nanofibrillar structures to the overall performances of Col-Chi scaffolds was also revealed by assessing swelling behaviors and tensile measurements. The maximum tensile strength obtained in the thermally triggered scaffolds was up to ～361.2 ± 32.3 kPa, emphasizing the significance of preserving biomimetic nanofibrillar structures in reconstruction of Col-Chi scaffolds.     

Artificial periosteum in bone defect repair——A review

We review the development of artifi cial periosteum and classify it into three approaches based on the material source, that is, native tissues, scaffoldfree cell sheets and scaffold-cell composites. Mechanisms, methods and effi cacy of each approach are provided. Existing obstacles and enabling technologies for future directions are also discussed.     

Distribution of a major surface-associated glycoprotein, fibronectin, in cultures of adherent cells

Fibronectin was present in media and cell layers of cultures of adherent cells from human skin, kidney, lung, chest wall, liver, and heart. Cell-surface fibronectin, visualized by immunofluorescence, was in dense fibrillar (cultures from lung), discrete fibrillar (e.g., cultures from skin), or punctate (some cultures from kidney) structures. The subunit sizes of cell-surface fibronectin and fibronectin soluble in medium appeared identical in sodium dodecyl sulfate-polyacrylamide gels. To explain the polymorphism of cell-surface fibronectin, there must be chemical differences among the fibronectins synthesized by different cell strains or factors in the cell layer which influence fibronectin binding and aggregation.     

利用原子力显微镜探针的扫帚机理制备胶原蛋白纳米纤维阵列

利用原子力显微镜能够在微观尺度上对样品材料进行操控和加工的特性,发现并考察了一种自上而下的生物大分子纳米纤维阵列的制备方法。将50μg/mL的天然I型鼠尾胶原蛋白溶液在云母晶面上形成胶原蛋白膜层,接着在原子力显微镜的接触模式下,利用探针对溶液中的胶原蛋白膜层施加100~1000 nN的力时,可以将膜层加工成具有特定取向的蛋白纳米纤维阵列。单根纤维的高度约2~5 nm,宽度在150~350 nm之间。根据纳米纤维阵列的结构与探针扫描方式的关系,对探针的制样原理进行了探讨,验证了原子力显微镜接触模式下的“分子扫帚”机理。此制备方法为生产细胞培养器皿、制备高特异性的生物探针,合成新型微纳材料提供了一种可行技术。