Observations on the different substrate behavior of tropocollagen molecules in solution and intermolecularly cross-linked tropocollagen within insoluble polymeric collagen fibrils.

Bacterial collagenase was used to compare the extent of digestion of tropocollagen monomers in solution and in reconstituted fibrils with that of tropocollagen molecules intermolecularly cross-linked within insoluble polymeric collagen fibrils obtained from mature tendons at given time-intervals. The extent of digestion of tropocollagen monomers in solution was directly proportional to the enzyme concentration (a range of enzyme substrate molar ratios 1:200 to 1:10 was used). The extent of digestion of polymeric collagen was followed by measuring the solubilization of fluorescent peptides from fluorescent-labelled insoluble polymeric collagen fibrils. The extent of digestion of tropocollagen within polymeric collagen was linear over a very small range of enzyme concentrations, when the enzyme/substrate ratio in the reaction mixture was less than 1:400 on a molecular basis. The behavior of tropocollagen in the form of reconstituted collagen fibrils, which had been matured at 37 degrees C for 8 weeks, was intermediate between the behaviour of solutions of tropocollagen and insoluble polymeric collagen fibrils. The significance of the results is discussed in terms of the structure of polymeric collagen fibrils and the protection against enzymic attack provided by tropocollagen molecules on the circumference of the fibril. The results suggest that assays of collagenase activities based on tropocollagen as substrate cannot be directly related to the ability of these enzymes to degrade mature insoluble collagen fibrils.     

Entropic elasticity controls nanomechanics of single tropocollagen molecules

We report molecular modeling of stretching single molecules of tropocollagen, the building block of collagen fibrils and fibers that provide mechanical support in connective tissues. For small deformation, we observe a dominance of entropic elasticity. At larger deformation, we find a transition to energetic elasticity, which is characterized by first stretching and breaking of hydrogen bonds, followed by deformation of covalent bonds in the protein backbone, eventually leading to molecular fracture. Our force-displacement curves at small forces show excellent quantitative agreement with optical tweezer experiments. Our model predicts a persistence length xi(p) approximately 16 nm, confirming experimental results suggesting that tropocollagen molecules are very flexible elastic entities. We demonstrate that assembly of single tropocollagen molecules into fibrils significantly decreases their bending flexibility, leading to decreased contributions of entropic effects during deformation. The molecular simulation results are used to develop a simple continuum model capable of describing an entire deformation range of tropocollagen molecules. Our molecular model is capable of describing different regimes of elastic and permanent deformation, without relying on empirical parameters, including a transition from entropic to energetic elasticity.     

Polymeric collagen fibrils. An example of substrate-mediated steric obstruction of enzymic digestion.

Polymeric collagen fibrils have been reacted with fluorescein and rhodamine isothiocyanates to produce fluorescent dye-labelled fibrils, containing seven dye substituents per molecule of tropocollagen within the polymeric collagen fibrils. Two dye-labelled peptides per molecule of tropocollagen were solubilised by trypsin (EC 3.4.21.4) from the telopeptide regions and four dye-labelled peptides were located in the helical regions solubilised by bacterial collagenase (EC 3.4.24.3). The solubilisation of dye-labelled peptides from these insoluble substrates were employed to measure the kinetics of trypsin and collagenase digestion of the telopeptide and helical regions, respectively, of the insoluble polymeric collagen fibrils. These studies demonstrated an apparent excess of enzyme for the readily available substrate under conditions when it was known that a vast excess of substrate existed in the reaction mixture calculated in terms of a molecular ratio. A point of equivalence was established for both trypsin and bacterial collagenase, approximately one enzyme molecule per 870 substrate molecules. On either side of this point the quantity of products formed was controlled by either the enzyme concentration or the substrate concentration. The results can be explained in terms of the inaccessibility of tropocollagen molecules within the molecular architecture of the polymeric collagen fibrils. The external layer of tropocollagen molecules obstruct collagenolytic enzymes penetrating to, and forming enzyme-substrate complexes with, the bulk of the substrate within the interior of the fibrils.     

Atomic force microscopy-based detection of binding and cleavage site of matrix metalloproteinase on individual type II collagen helices

Type II tropocollagen molecules were reacted with matrix metalloproteinase 8 (MMP-8) and the binding sites as well as the cleavage site of MMP-8 were detected on individual molecules using atomic force microscopy (AFM). Approximately 300-nm-long coiled-coil tropocollagen molecules were straightened and immobilized on an atomically flat surface for detection by AFM. The direct visualization of individual collagen molecules revealed heterogeneous characteristics of MMP-8:collagen complexes. We observed that there existed multiple MMP-8 nonspecific binding sites on the collagen molecules, but cleavage always took place at a unique site. When collagen molecules, straightened and immobilized on the surface, were reacted with MMP-8, a site of cleavage appeared as a gap in stretched molecules. This is the first report to visually show direct collagenase:collagen interactions using AFM. The described AFM-based analysis has potential as a protein analysis tool for understanding a complex mechanism of enzyme:substrate interactions.     

The processing of procollagen in cultures of human and mouse fibroblasts.

Cultures of normal human and mouse fibroblasts convert procollagen to tropocollagen at varying rates. The conversion rate cannot be predicted from the species of origin of the fibroblast nor from the age of the donor tissue. Procollagen is converted to tropocollagen in both the extracellular space of the cell layer and in the culture medium. The collagen fibers of the cell layer are formed mostly from tropocollagen molecules generated in situ.     

Biochemical and physiochemical characterization of pepsin-solubilized type-II collagen from bovine articular cartilage.

Solubilization of collagen from bovine articular with pepsin requires the preliminary extraction of proteoglycans from the ground substance. Biochemical and physiochemical properties of this pepsin-solubilized collagen are independent of the pretreatment (extraction with 1.5M-CaCl2, 5M-guanidinium chloride or 0.2M-NaOH) and of the age range (2-4-year-old and 2-month-old animals). Characterization of the de-natured components, of the CNBr peptides and of the amino acid and cross-link composition shows that the collagen of the hyaline cartilage is all type II. Electrical birefringence measurements showed the presence of tropocollagen molecules (length 280nm) and molecules whose length is slightly less than twice that of the tropocollagen molecules. This latter molecule may be a dimer composed of two monomers linked by intermolecular head-to-tail bonds and whose theoretical length (530nm), according to the quarter-stagger theory, is in good agreement with our measured values (510-530nm). We have verified that the beta-components of this collagen are formed of two alpha-chains linked by the stable intermolecular bond, dehydrodihydroxylysinonorleucine. These dimeric molecules are absent from solutions of skin collagen whose beta-components possess only aldol-type intramolecular cross-links. Although reconstituted fibres from solutions of skin and cartilage collagen are similar, the segment-long spacing crystallites formed with pepsin-solubilized cartilage collagen present a symmetrical and dimeric form corresponding to the lateral aggregation of two monomers with an overlap (90nm) of the C-terminal ends.     

Volume change on formation of native collagen aggregate

The volume change which occurs in dilute tropocollagen solution as a result of the phase transition producing the “native” form of collagen aggregate has been measured dilatometrically. A volume increase of 0.8 × 10^?3 ml./g. collagen in phosphate buffer (pH 7–7.5) was determined. The volume expansion is attributed to a reduction in the organization of water molecules around nonpolar surfaces of the individual tropocollagen units. This volume expansion is consistent with a previous hypothesis that hydro-phobic bonding is the driving force in this collagen aggregation.     

X-ray diffraction studies of the corneal stroma.

A low-angle diffraction pattern has been obtained from corneal stroma. This pattern arises both from the arrangement of the collagen fibrils and from the packing of the tropocollagen molecules along the axes of the fibrils. The spacing arising from the packing of the fibrils increases homogeneously on swelling although the tissue as a whole swells only radially referred to the intact eye. The necessary rearrangement of the fibrils for this type of swelling to occur might result in the formation of regions devoid of collagen fibrils and the water not in the lattice of collagen fibrils could be synonymous with the lakes postulated by Benedek (1971) to explain the loss of transparency on swelling.The spacings due to the packing of the tropocollagen molecules are unusual in that, although they index as the third and fifth orders of the well-known 66 nm repeat, the first order of this spacing is absent. Calculation of the Patterson function for corneal collagen leads to peaks in electron density separated by distances of 0.38 and 0.24 of the repeat distance.     

Thermodynamic studies of the assembly in vitro of native collagen fibrils

Measurements of the solubility of calf-skin tropocollagen in neutral phosphate buffers in the temperature range 20-37 degrees C show that native collagen fibril formation is an endothermic process made thermodynamically favourable by a large positive entropy of precipitation associated with structural changes in the surrounding solvent. The effect of inorganic ions and small solute molecules on precipitation seems to be correlated with their structural effects on liquid water. Heterogeneity in the precipitation properties of the collagen solutions may be related to changes in the configurational entropy of the macromolecules due to intramolecular cross-linking.     

Carbohydrate content of bovine collagen preparations

Collagen preparations from bovine tissues were analysed for their carbohydrate content. Crude preparations of tropocollagen and polymeric collagen were found to be contaminated with considerable amounts of mannose, fucose and hexosamine, sugars known to be present in the mucoprotein of the interfibrillar material with which collagen is associated in vivo. A pure preparation of tropocollagen obtained by ethanol precipitation procedures contained only galactose and glucose in the approximate ratio of 7:3 residues/3000 amino acid residues. Purification of crude polymeric collagen by EDTA extraction or by crude bacterial amylase extraction considerably decreased the mucoprotein contamination, particularly in the enzymic treatment, which yielded a preparation containing predominantly galactose and glucose in the ratio of 4:2 residues/3000 amino acid residues. The results confirm previous work that demonstrated the purity of these collagen preparations as inferred by amino acid analysis. The results also indicate the suitability of the pure tropocollagen and the amylase-extracted polymeric collagen for studies on the role of the carbohydrate residues in intramolecular and intermolecular cross-linking in collagen.     

The size of collagen fibrils that stimulate platelet aggregation in human plasma.

Suspensions of collagen fibrils of different size were prepared from solutions of radioactive tropocollagen type I by either differential centrifugation or differential incubation at elevated temperature. The fractions were compared with respect to their ability to stimulate human blood platelet aggregation in plasma, their binding to human platelets, and their morphology, as seen in the electron microscope. Although small particles with a sedimentation coefficient as low as 4.5 S bound to platelets, aggregation was not observed in the presence of collagen multimers and protofibrils without visible cross-bands in stained specimens. The onset of platelet-aggregating activity before the appearance of turbidity in collagen solutions incubated at elevated temperature is due to the formation of a few banded fibrils; this early onset and the fibrils do not appear in collagen solutions that have been ulctracentrifuged before incubation.     

Identification of two new collagen alpha-chains in extracts of lathyritic chick embryo tendons

Two new collagen polypeptide chains have been identified in extracts of lathyritic embryonic chick tendons. The electrophoretic migration of these polypeptides in sodium dodecyl sulfate-polyacrylamide gels indicates that they have about 20% greater apparent molecular weights than α₁ and α₂ chains of Type I collagen. These chains are not held by disulfide bonds since reduction does not affect their electrophoretic behavior. Further, they do not represent incompletely cleaved procollagen since their apparent molecular size remains greater than that of Type I collagen polypeptides after limited proteolytic digestion. Because the ratio of these polypeptides in the purified extracts is not 2:1 it appears that they are components of two separate tropocollagen molecules.     

A method for the determination of lysine-derived collagen crosslinks

A rapid and inexpensive method was devised for the determination of lysine-derived aldimine crosslink contents in collagen. The aldimines were converted to their secondary amine derivatives by NaBH₄ reduction, and the acid or base collagen hydrolysates analysed $\text{directly}$ for these derivatives (HLHNL and HLNL). It was found that in native bone, dentin and cartilage collagen fibres, every two tropocollagen molecules are joined by a minimum of one aldimine crosslink. Negligible amounts of HLNL and HNHNL were found in unreduced collagens, indicating that maturation does not involve a simple $\text{in vivo}$ reduction of the aldimine crosslinks.     

Interaction between proteoglycan subunit and type II collagen from bovine nasal cartilage, and the preferential binding of proteoglycan subunit to type I collagen.

We studied the interaction of proteoglycan subunit with both types I and II collagen. All three molecular species were isolated from the ox. Type II collagen, prepared from papain-digested bovine nasal cartilage, was characterized by gel electrophoresis, amino acid analysis and CM-cellulose chromatography. By comparison of type I collagen, prepared from papain-digested calf skin, with native calf skin acid-soluble tropocollagen, we concluded that the papain treatment left the collagen molecules intact. Interactions were carried out at 4 degrees C in 0.06 M-sodium acetate, pH 4.8, and the results were studied by two slightly different methods involving CM-cellulose chromatography and polyacrylamide-gel electrophoresis. It was demonstrated that proteoglycan subunit, from bovine nasal cartilage, bound to cartilage collagen. Competitive-interaction experiments showed that, in the presence of equal amounts of calf skin acid-soluble tropocollagen (type I) and bovine nasal cartilage collagen (type II), proteoglycan subunit bound preferentially to the type I collagen. We suggest from these results that, although not measured under physiological conditions, it is unlikely that the binding in vivo between type II collagen and proteoglycan is appreciably stronger than that between type I collagen and proteoglycan.     

Purification and amino acid composition of monomeric and polymeric collagens

The preparations and amino acid compositions of highly purified tropocollagen and insoluble polymerized collagen are described. These collagens appear to be very suitable for comparative studies in an investigation of the cross-linkages that are introduced into tropocollagen during the formation of polymerized collagen.     

Microwave dielectric study on hydration of moist collagen

Two dielectric relaxation peaks were found in moist collagen by the time domain reflectometry. The low-frequency peak around 100 MHz moves little as the water content is varied. Its relaxation strength depends on the content and vanishes for completely dried collagen. This process is concluded to be due to water molecules strongly bound to the tropocollagen. Amount of the bound water is estimated as 0.12 g water/g collagen. Twenty-one water molecules are bound to one repeat of the triple helix. The existence of stringlike water chains is suggested. If the water content is less than 0.5 g water/g collagen, the high frequency peak locates between those of bound and bulk water. Water among the tropo-collagen is weakly bound to the collagen. In the higher region it does not change much with the content, being close to that of bulk water. The bulk water appears in this region.     

Schachtelhalm-structure of the octafibrils in collagen

X-ray diffraction patterns suggest that the microfibrils in the collagen of native rat tail tendon are eight-stranded ropes, quarter staggered and packed together in an orthorhombic lattice with paracrystalline (liquid-like) distortions between adjacent tropocollagen molecules. These so called octafibrils react under stress like synthetic elastomers with a 135 Å periodicity of hard segments.     

Isolation from earthworms of a proteinaceous chemoattractant to garter snakes

We have isolated a potent proteinaceous chemoattractant from aqueous washes of earthworm (Lumbricus terrestris) for garter snakes (Thamnophis sirtalis) by means of a covalent chromatography. It contained free sulfhydryl groups and showed an apparent mass of 20 kDa. The chemoattractive activity of this protein could be destroyed by heating as well as by proteolysis. Its activity could also be reversibly blocked by mixed disulfide formation with dithiodipyridine, suggesting that the free sulfhydryl(s) was essential for its function as a chemoattractant. This bioactive material had a tendency to form intermolecular crosslinked aggregates during isolation, if reducing agents were not included. Some of the high-molecular-weight aggregates cochromatographed with earthworm cuticle collagen on Ultragel AcA 34 or 44 columns. In contrast to an earlier report by D. M. Kirschenbaum, N. Schulman, and M. Halpern [1986) Proc. Natl. Acad. Sci. USA 83, 1213-1216) the purified earthworm collagen showed no chemoattractive activity to garter snakes.     

Negative staining of rat tail tendon collagen fibrils with uranyl formate

Negative staining of rat tail tendon collagen fibrils with uranyl formate appears to reveal more detail in the axial banding pattern than any other positive or negative staining method hitherto employed. In addition, uranyl formate and other uranyl solutions appear to reveal fine, closely spaced, longitudinal filaments which may represent the individual tropocollagen molecules.     

A study of the interaction in vitro between type I collagen and a small dermatan sulphate proteoglycan.

The interaction between a small dermatan sulphate proteoglycan isolated from human uterine cervix and collagen type I from human and rat skin was investigated by collagen-fibrillogenesis experiments. Collagen fibrillogenesis was initiated by elevation of temperature and pH after addition of proteoglycan, chondroitinase-digested proteoglycan or isolated side chains, and monitored by turbidimetry. Collagen-associated and unbound proteoglycan was determined by enzyme-linked immunosorbent assay after aggregation was complete. (1) The binding of proteoglycan to collagen could be explained by the presence of two mutually non-interacting binding sites, with Ka1 = 1.3 x 10(8) M-1 and Ka2 = 1.3 x 10(6) M-1. The number of binding sites per tropocollagen molecule was n1 = 0.11 and n2 = 1.1. The 0.1 high-affinity binding site per tropocollagen molecule indicates that the strong interaction between proteoglycan and collagen results from a concerted action of tropocollagen molecules in fibrils. Digestion of the proteoglycan with chondroitinase ABC did not affect these binding characteristics. (2) Proteoglycan did not affect the rate of fibrillogenesis, but increased the steady-state A400 by up to 90%. This increase was directly proportional to the saturation of the high-affinity type of binding sites. Neither isolated core protein nor isolated side chains induced a similar high increase in steady-state A400. (3) Electron micrographs showed that the fibril diameter was affected only to a minor extent, if at all, by the proteoglycan, whereas bundles of laterally aligned fibrils were common in the presence of proteoglycan. (4) Results obtained with human and rat collagen were similar.