The effect of glycosaminoglycans (GAG) on the intramolecular bindings of collagen.

The subfractions of collagen (alpha, beta and gamma components) precipitated from neutral collagen solution by gelation corresponded to those of collagen precipitated in the same conditions (ion environments) and in the presence of chondroitin-4-sulphate. Collagen fibrils precipitated delayed in the presence of heparin poor in beta chains and rich in alpha chains. The delaying effect of oversulphated GAG on the in vitro fibril formation can be explained by the release or prevention of ion-type intramolecular bonds of collagen. The possible in vivo significance of the above bonds is discussed.     

The structure of the osteoderms in the Gekko: Tarentola mauritanica

Histological and cytological analysis reveals that the osteoderms of Tarentola mauritanica are composed of an outer part superimposed on a basal region. The structure of both parts can be related to that of the surrounding dermis. The basal part of the osteoderms, inserted in the dense dermis, is made up of abundant closely packed collagen fibrils that orient the mineral deposit. The outer part, located in the superficial loose dermis, is crossed by few bundles of mineralized collagen fibrils arising from the basal part. These bundles connect the osteoderm to the overlying loose dermis. The outer superficial part is characterized by the presence of mineralized globules surrounding the mineralized collagen bundles. In these globules, the crystals are deposited on a microfibrillar matrix rich in acidic mucosubstances and composed of radially oriented, tangled microfilaments that lie among the collagen bundles. The two different mineralizing systems in the osteoderms of Tarentola mauritanica may reflect two different organic matrices. The mineral is deposited in a preexisting dermal tissue, as a "metaplastic ossification," and is another expression of the potential retained by the reptilian dermis to form mineralized structures.     

Collagen fibrils of an invertebrate (Sepia officinalis) are heterotypic: immunocytochemical demonstration

Collagen fibrils from the dermis of Sepia officinalis were processed for immunoelectron microscopy to reveal reactions to antibodies against mammalian types I, III, and V, teleost type I and cephalopod type I-like collagens, by single and double immunogold localization. The fibrils were observed: (a) in suspensions of prepared fibrils, (b) in ultrathin sections of embedded fibril preparations, and (c) in ultrathin sections of dermal tissue. Some samples were subjected to acetic acid or urea dissociation. It was found that collagen fibrils from Sepia dermis are heterotypic in that they are composed of type I-like and type V collagens. Type I-like collagen epitopes were present mainly at the periphery of the fibrils; type V collagen epitopes were present throughout the fibrils. This is the first demonstration that collagen fibrils from an invertebrate are heterotypic, suggesting that heterotypy may be an intrinsic characteristic of the fibrils of fibrillar collagens, independent of evolutionary or taxonomic status.     

Type I collagen influences cartilage calcification: an immunoblocking study in differentiating chick limb-bud mesenchymal cell cultures

Chick limb-bud mesenchymal cells, plated in high-density micro-mass culture, differentiate and form a matrix resembling chick epiphyseal cartilage. In the presence of 4 mM inorganic phosphate or 2.5 mM beta-glycerophosphate mineral deposits upon this matrix forming a mineralized tissue that, based on electron microscopy, x-ray diffraction and Fourier Transform Infrared microspectoscopy, is like that of chick calcified cartilage. In this culture system the initial mineral deposits are found on the periphery of the chondrocyte nodules. During differentiation of the cells in the high-density micro-mass cultures there is a switch from expression of type I collagen to type II, and then to type X collagen. However, type I collagen persists in the matrix. Because there is some debate about whether type I collagen influences cartilage calcification, an immunoblocking technique was used to determine the importance of type I collagen on the mineralization process in this system. Studies using nonspecific goat anti-chick IgG demonstrated that 1-100 ng/ml antibody added with the media after the cartilage nodules had developed (day 7) had no effect on the accumulation of mineral in the cultures. Nonspecific antibody added before day 7 blocked development of the cultures. Parallel solution based cell-free studies showed that IgG did not have a strong affinity for apatite crystals, and had no significant effect on apatite crystal growth. Type I collagen antibodies (1-200 ng/ml) added to cultures one time on day 9 (before mineralization started), or on day 11 (at the start of mineralization), slightly inhibited the accumulation of mineral. There was a statistically significant decrease in mineral accretion with 100 or 200 ng/ml collagen antibody addition continuously after these times. Fab' fragments of nonspecific and type I collagen antibodies had effects parallel to those of the intact antibodies, indicating that the decreased mineralization was not attributable to the presence of the larger, bulkier antibodies. The altered accumulation of mineral was not associated with cell death in the presence of antibody (demonstrated by fluorescent labeling of DNA) or with increased apoptosis (TUNEL-stain). In the immunoblocked cultures, EM analysis demonstrated that mineral continued to deposit on collagen fibrils, but there appeared to be fewer deposits. The data demonstrate that type I collagen is important for the mineralization of these cultures.     

Collagen fibril assembly and deposition in the developing dermis: segmental deposition in extracellular compartments

The hierarchy of extracytoplasmic compartmentalization and fibrillar organization as well as the assembly and deposition of collagen fibrils was characterized in the 15-day chick embryo dermis using transmission electron microscopy. At least two levels of extracellular compartmentalization are recognizable at this stage of dermal development. The first compartment consists of a series of narrow channels containing single or small groups (less than 5) of collagen fibrils. These channels course deep within the cell and are open to the extracellular space. The second extracellular compartment consists of fibrils grouped as small bundles in close association with the cell surface and is most often defined by a single fibroblast. A third level of fibril organization and compartmentalization is sometimes apparent at this stage of dermal development consisting of laterally associated bundles, more characteristic of the mature dermis. This compartment is associated with the fibroblast surface, but is less well defined than the fibril channels or bundle-forming compartments. Dermal collagen fibrils within bundles are discontinuous. Numerous fibrils ends are identified from serial sections and the ends gradually taper. These data indicate that the dermal fibroblast compartmentalizes the extracellular space and deposits collagen fibril segments during dermal morphogenesis. A model for the genesis of the extracellular compartments and their role in collagen fibrillogenesis and development of regularly arranged connective tissues, tendon, and cornea has been proposed. Dermal development conforms to this model and we suggest that extracytoplasmic compartmentalization of the steps in matrix assembly and segmental deposition of collagen fibrils are important mechanisms in the development of a wide variety of connective tissues.     

Differential anion effects on thermal stability of collagen in the dispersed and aggregated states (Short Communication)

The effects of KCNS and KI on thermal transition temperatures of calf skin collagen molecules in dilute acid solution and precipitated collagen fibrils from the same source were compared as a function of salt concentration and pH. The two salts produced qualitatively similar effects on each collagen form, but the response shown by single collagen molecules in dilute solution differed from that observed for molecular aggregates present in native-type fibrils.     

Characterization of a variety of standard collagen substrates: Ultrastructure,uniformity, and capacity to bind and promote growth of neurons

Summary Collagen substrates were characterized after preparation by the four methods most commonly used for tissue culture (saline precipitation, exposure to ammonium hydroxide vapor, exposure to ultraviolet light, and air drying). Although roughly equivalent percentages of collagen were precipitated by each technique (87 to 97%), marked differences were found in surface uniformity and ultrastructure. Substrates were quite uniform if precipitated by exposure to ammonium hydroxide or ultraviolet light, of intermediate uniformity if saline precipitated, and not at all uniform if air dried. Scanning electron microscopy revealed that (a) ammonium hydroxide and saline precipitation primarily resulted in formation of collagen fibrils, (b) air drying produced a small number of fibrils plus a large amount of amorphous material, and (c) exposure to ultraviolet light only resulted in the formation of globular, nonfibrillar collagen aggregates. The capacity of collagen substrates to bind and grow neurons differed markedly with the method of preparation and the amount of collagen plated per unit area. Quantification of binding and growth of both cerebral and sympathetic neurons revealed that these are separate measures of the biocompatibility of a surface and that growth was uniformly inferior on globular collagen that had been precipitated by ultraviolet light. Long-term (≥2 wk) growth of sympathetic neurons was optimal on thick beds of saline-precipitated collagen, whereas short-term growth was best on thin layers of either saline or ammonium hydroxide-precipitated collagen. Cerebral neurons bound and grew optimally on thick collagen beds after both short- and long-term culture. In addition, cerebral neurons were found to be more dependent on the method of precipitation of the thin collagen substrates than were sympathetic neurons. This work was supported by National Institute of General Medical Sciences Grant GM 24487 and by contract N00014-80-C-0363 from the Department of the Navy.     

A role for disulphide bridges in the protein core in the interaction of proteodermatan sulphate and collagen

Proteodermatan sulphate from bovine skin retarded precipitation of fibrils from solutions of purified acid-soluble bovine skin collagen. The isolated protein core was as effective as the intact proteoglycan. Thermal denaturation leading to almost complete loss of the native secondary structure, (determined by circular dichroism spectroscopy to consist of about 60% beta structure) did not diminish the effect unless accompanied by reduction of disulphides, of which there were shown to be three per molecule. The reduced and alkylated protein core was totally ineffective. Electron-microscopy revealed a D-periodic arrangement of glycosaminoglycan on the surfaces of collagen fibrils precipitated in the presence of proteodermatan sulphate. Dermatan sulphate (with attached small peptide) prepared from the proteoglycan, had no effect on the rate of fibrillogenesis and was apparently not bound to the fibrils.     

Collagen XI nucleates self-assembly and limits lateral growth of cartilage fibrils

Fibrils of embryonic cartilage are heterotypic alloys formed by collagens II, IX, and XI and have a uniform diameter of approximately 20 nm. The molecular basis of this lateral growth control is poorly understood. Collagen II subjected to fibril formation in vitro produced short and tapered tactoids with strong D-periodic banding. The maximal width of these tactoids varied over a broad range. By contrast, authentic mixtures of collagens II, IX, and XI yielded long and weakly banded fibrils, which, strikingly, had a uniform width of about 20 nm. The same was true for mixtures of collagens II and XI lacking collagen IX as long as the molar excess of collagen II was less than 8-fold. At higher ratios, the proteins assembled into tactoids coexisting with cartilage-like fibrils. Therefore, diameter control is an inherent property of appropriate mixtures of collagens II and XI. Collagen IX is not essential for this feature but strongly increases the efficiency of fibril formation. Therefore, this protein may be an important stabilizing factor of cartilage fibrils.     

Supramolecular interactions in the dermo-epidermal junction zone: anchoring fibril-collagen VII tightly binds to banded collagen fibrils

The dermis and the epidermis of normal human skin are functionally separated by a basement membrane but, together, form a stable structural continuum. Anchoring fibrils reinforce this connection by insertion into the basement membrane and by intercalation with banded collagen fibrils of the papillary dermis. Structural abnormalities in collagen VII, the major molecular constituent of anchoring fibrils, lead to a congenital skin fragility condition, dystrophic epidermolysis bullosa, associated with skin blistering. Here, we characterized the molecular basis of the interactions between anchoring fibrils and banded collagen fibrils. Suprastructural fragments of the dermo-epidermal junction zone were generated by mechanical disruption and by separation with magnetic Immunobeads. Anchoring fibrils were tightly attached to banded collagen fibrils. In vitro binding studies demonstrated that a von Willebrand factor A-like motif in collagen VII was essential for binding of anchoring fibrils to reconstituted collagen I fibrils. Since collagen I and VII molecules reportedly undergo only weak interactions, the attachment of anchoring fibrils to collagen fibrils depends on supramolecular organization of their constituents. This complex is stabilized in situ and resists dissociation by strong denaturants.     

Structure of hematopoietic nodules in the ridgeback prawn,Sicyonia ingentis: Light and electron microscopic observations

The architecture and fine structure of the epigastric hematopoietic nodules of the ridgeback prawn, Sicyonia ingentis, are described. The nodules consist of a highly branched series of tubules that contain the maturing hemocytes within a connective tissue stroma. Hemocytes can exit the hematopoietic nodules by penetrating through fenestrations in the endothelial cell layer into the central hemal space or by migrating through the outer later of capsular cells and associated collagen fibrils. Four hemocyte categories were observed: agranular, small granule with cytoplasmic deposits, small granule without cytoplasmic deposits, and large granule hemocytes. This classification was based upon the presence, size, and type of cytoplasmic granules and the presence of cytoplasmic deposits. Only agranular cells and small granule hemocytes without cytoplasmic deposits appeared capable of division. Intermediate stages were observed between agranular hemocytes and small granule hemocytes with deposits and between small granule hemocytes without deposits and large granule hemocytes, suggesting existence of two distinct hemocyte lines.     

Heparin strongly enhances the formation of beta2-microglobulin amyloid fibrils in the presence of type I collagen

The tissue specificity of fibrillar deposition in dialysis-related amyloidosis is most likely associated with the peculiar interaction of beta2-microglobulin (beta2-m) with collagen fibers. However, other co-factors such as glycosaminoglycans might facilitate amyloid formation. In this study we have investigated the role of heparin in the process of collagen-driven amyloidogenesis. In fact, heparin is a well known positive effector of fibrillogenesis, and the elucidation of its potential effect in this type of amyloidosis is particularly relevant because heparin is regularly given to patients subject to hemodialysis to prevent blood clotting. We have monitored by atomic force microscopy the formation of beta2-m amyloid fibrils in the presence of collagen fibers, and we have discovered that heparin strongly accelerates amyloid deposition. The mechanism of this effect is still largely unexplained. Using dynamic light scattering, we have found that heparin promotes beta2-m aggregation in solution at pH 6.4. Morphology and structure of fibrils obtained in the presence of collagen and heparin are highly similar to those of natural fibrils. The fibril surface topology, investigated by limited proteolysis, suggests that the general assembly of amyloid fibrils grown under these conditions and in vitro at low pH is similar. The exposure of these fibrils to trypsin generates a cleavage at the C-terminal of lysine 6 and creates the 7-99 truncated form of beta2-m (DeltaN6beta2-m) that is a ubiquitous constituent of the natural beta2-m fibrils. The formation of this beta2-m species, which has a strong propensity to aggregate, might play an important role in the acceleration of local amyloid deposition.     

Monomer and oligomer of type I collagen: molecular properties and fibril assembly

Type I collagen purified from calf skin was further separated into monomeric and oligomeric fractions and characterized with gel electrophoresis and measurement of solution viscosity. The thermal stabilities of the triple-helical structure of the collagen molecules of these preparations and the fibrils assembled therefrom were determined with differential UV spectroscopy and scanning microcalorimetry. The monomeric collagen was reduced with NaBH4-, and the kinetics and equilibrium of the reversible fibril assembly-disassembly were examined in detail. Fibril assembly and disassembly of the collagen induced by slow scans of temperature showed hysteresis. The assembly curve was very sharp whereas the disassembly curve was gradual. Equilibrium centrifugation showed the collagen disassembled from the fibrils to be predominantly monomers. However, unlike the unassembled collagen, the collagen disassembled from fibrils by cooling showed no lag phase in subsequent cycles of fibril assembly. The thermodynamic parameters of fibril growth were derived from a fibril disassembly curve. Fibril growth was weaker for the NaBH4-reduced monomeric collagen than the native crude collagen, perhaps due to the removal of oligomers and the changes in the molecular structure brought by the reduction. The results corroborated the strongly cooperative mechanism for the fibril assembly proposed in the preceding paper.     

Fibronectin (cold-insoluble globulin), VI. Influence of heparin and hyaluronic acid on the binding of native collagen.

Fibronectin of human plasma associated readily with denatured collagen but gave only a weak reaction with the native protein. In the presence of heparin, however, solutions of native collagen type III, and fibronectin produced precipitates at an ionic strength of 0.2. In the presence of fibronectin and optimal additions of heparin, up to 60% of soluble native 125I-collagen type III, but only about 10% of native 125I-collagen type I, were insolubilized. Heparin also enhanced the formation of insoluble complexes from fibronectin and denatured collagen type I and type III. In the absence of collagen 125I-fibronectin was partially precipitated by heparin. Electron micrographs showed filamentous structures. Collagen did not increase the amount of 125I-fibronectin precipitated by heparin unless a critical collagen concentration was exceeded. It is suggested that heparin induced the transition of fibronectin from a globular to an elongated form, capable of forming filamentous precipitates which adsorb native collagen. Hyaluronic acid and putrescine prevented the insolubilization of native collagen type III, by fibronectin and heparin.     

Heparin and other glycosaminoglycans stimulate the formation of amyloid fibrils from alpha-synuclein in vitro

Parkinson's disease is the second most common neurodegenerative disease and results from loss of dopaminergic neurons in the substantia nigra. The aggregation and fibrillation of alpha-synuclein have been implicated as a causative factor in the disease. Glycosaminoglycans (GAGs) are routinely found associated with amyloid deposits in most amyloidosis diseases, and there is evidence to support an active role of GAGs in amyloid fibril formation in some cases. In contrast to the extracellular amyloid deposits, the alpha-synuclein deposits in Lewy body diseases are intracellular, and thus it is less clear whether GAGs may be involved. To determine whether the presence of GAGs does affect the fibrillation of alpha-synuclein, the kinetics of fibril formation were investigated in the presence of a number of GAGs and other charged polymers. Certain GAGs (heparin, heparan sulfate) and other highly sulfated polymers (dextran sulfate) were found to significantly stimulate the formation of alpha-synuclein fibrils. Interestingly, the interaction of GAGs with alpha-synuclein is quite specific, since some GAGs, e.g., keratan sulfate, had negligible effect. Heparin not only increased the rate of fibrillation but also apparently increased the yield of fibrils. The molar ratio of heparin to alpha-synuclein and the incorporation of fluorescein-labeled heparin into the fibrils demonstrate that the heparin is integrated into the fibrils and is not just a catalyst for fibrillation. The apparent dissociation constant for heparin in stimulating alpha-synuclein fibrillation was 0.19 microM, indicating a strong affinity. Similar effects of heparin were observed with the A53T and A30P mutants of alpha-synuclein. Since there is some evidence that Lewy bodies may contain GAGs, these observations may be very relevant in the context of the etiology of Parkinson's disease.     

Ultrastructural organization of the basic substance of human dermis]

The data on ultrastructural organization of the ground substance in the human dermis obtained electron histochemically are represented. Five types of ruthenium positive structures of polysaccharide origin are detected: retinal structure (I), amorfous substance (II), membranes of collagen fibrils (III) and elastic fibres (V), fine ruthenium positive streakness of collagen fibrils (IV). These structures, except fine streakness, form a united polysaccharide system of the dermis participating in maintenance of structural-functional integrity of the connective tissue (collagen-elastic) carcass of the dermis. Two mechanisms, interconnected and oppositely directed, perform this function: the buffer mechanism preventing the connective tissue fibers and collagen fibrils to approach each other, and the binding mechanism preventing the fibrils and fibers to dissociate. The reticular structure performs mainly this function at the level of fibers, and the amorphous substance does it at the level of fibrils.     

The effects of dipalmitoyl phosphatidyl choline on the precipitation of native fibrils and segment-long-spacing aggregates from collagen solution

The effect of dipalmitoyl phosphatidyl choline (DPPC), the major phospholipid component of pulmonary surfactant, on the precipitation of collagen in the form of native fibrils and segment-long-spacing (SLS) aggregates was studied in vitro. The effects of DPPC on both phases of collagen fibrillogenesis were analyzed spectrophotometrically, and alterations in the morphology of precipitated fibrils and SLS aggregates were ascertained by transmission electron microscopy (TEM). Low concentrations of DPPC inhibited the growth phase of fibrillogenesis, while higher concentrations were required to inhibit nucleation. Both the meshwork density and mean width of precipitated fibrils were altered by DPPC, as was the size of SLS aggregates. Segment-long-spacing aggregates prepared from pepsin-treated collagen were inhibited to a greater degree than SLS aggregates prepared from untreated collagen, indicating that the pepsin-susceptible residues of the telopeptide extensions of tropocollagen molecules stabilize SLS aggregates against the effects of DPPC. Based on these results and the inhibition of the growth phase at lower concentrations than those which inhibited the nucleation phase of fibrillogenesis, it was concluded that the primary mechanism of DPPC inhibition is electrostatic interference between the positively charged phospholipid molecules and the net positive charge of collagen. It is proposed that pathological conditions involving the pulmonary epithelium may allow interaction between surfactant and collagen, which could further weaken the interstitial connective tissue.     

Biomimetic Synthesis of Collagen/Nano-Hydroxyapitate Scaffold for Tissue Engineering

This paper reports a precipitation method for the fabrication of compositionally graded biomimetic collagen/nano-hydroxyapatite (HA) composite scaffold. The method is centrifugation based and produce the precipitation of nano-HA crystallites in situ (calcium ions (Ca²⁺) react phosphate ions (PO₄³⁻) and precipitate a non-stoichiometric hydroxyapatite). It was observed that prism needle-like nano-HA crystallites (about 2.5 nm × 3 nm× 25 nm) precipitated on collagen fibrils in the interior of collagen matrix. Chemical and microstructure analysis revealed a gradient of the Ca to P ratio across the width of the scaffold, lead to the formation of a HA-rich side and a HA-deplete side of scaffold. The HA-rich side featured low porosity and agglomerates of the nano-HA crystallites; while HA-depleted side featured higher porosity and nano-HA crystallites integrated with collagen fibrils to form a porous network structure.     

Induction and prevention of chondrocyte hypertrophy in culture

Primary chondrocytes from whole chick embryo sterna can be maintained in suspension culture stabilized with agarose for extended periods of time. In the absence of FBS, the cells remain viable only when seeded at high densities. They do not proliferate at a high rate but they deposit extracellular matrix with fibrils resembling those of authentic embryonic cartilage in their appearance and collagen composition. The cells exhibit many morphological and biochemical characteristics of resting chondrocytes and they do not produce collagen X, a marker for hypertrophic cartilage undergoing endochondral ossification. At low density, cells survive in culture without FBS when the media are conditioned by chondrocytes grown at high density. Thus, resting cartilage cells in agarose cultures can produce factors required for their own viability. Addition of FBS to the culture media leads to profound changes in the phenotype of chondrocytes seeded at low density. Cells form colonies at a high rate and assume properties of hypertrophic cells, including the synthesis of collagen X. They extensively deposit extracellular matrix resembling more closely that of adult rather than embryonic cartilage.     

Separation of type III collagen from type I collagen and pepsin by differential denaturation and renaturation.

Types I and III collagens were solubilized from fetal human skin by limited digestion with pepsin and precipitated by dialysis against 0.02 M Na₂HPO₄. Heat denaturation of the collagens in 2 M guanidine-HCl, pH 7.5, resulted in the precipitation of the contaminant pepsin which could be removed by centrifugation. Renaturation of the denatured collagens by dialysis against deionized water at 22° for 2 hours selectively precipitated the type III collagen fibrils. Type I collagen remained in solution. The simplicity and high recovery (77%) make this a suitable approach for the rapid estimation of type III collagen in small tissue samples.