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.     

Birefringence of Protein Solutions and Biological Systems: II. Studies on TMV, Tropocollagen, and Paramyosin

The intrinsic birefringences of TMV, tropocollagen, and paramyosin were calculated from flow birefringence measurements using the theory of Peterlin and Stuart. The values are -0.029, -0.029, and -0.030, respectively. The intrinsic birefringences of TMV and tropocollagen were measured as a function of the refractive index of the solvent in glycerol-water mixtures. In both cases the values were not constant and became less negative as the refractive index increased. Theoretical calculations showed that the large solvent effect could not be caused by a hydration shell of index different from that of the bulk solvent. It is concluded that either (a) the intrinsic birefringence calculated from the Peterlin-Stuart theory is incorrect or (b) the intrinsic birefringence depends markedly on the solvent. These results are of importance to the problem of quantitative polarized light microscopy since the separation of form and intrinsic birefringence contributions is based on the assumption that intrinsic birefringence is independent of solvent.     

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.     

Electron microscopic studies of procollagen from cultured human fibroblasts

Tropocollagen was extracted from the extracellular fibers of the cell layers of cultured human fibroblasts and procollagen was isolated from the medium. The tropocollagen precipitated as segment long spacing (SLS) aggregates from an ATP-acetic acid solution, but procollagen formed predominantly fibrous long spacing (FLS) crystallites in the same solution. The procollagen aggregates were distinguished from those of tropocollagen by the presence of globular caps at one (SLS form) or both (FLS form) ends. The globular caps were selectively removed by limited digestion with pepsin. They are thought to be formed from the nonhelical, aminoterminal peptides of the procollagen molecule. These globular peptides coil back 200 Å on the long axis of the molecule and contribute no more than 90 Å to its length. They appear to prevent the molecules from aggregating as native fibers in vitro.     

Human procollagen : I. An anionic tropocollagen precursor from skin fibroblasts in culture

Tropocollagen is derived from an extracellular precursor, procollagen. Conversion to tropocollagen is accomplished by one or more tissue pioteases dependent in vitro on the presence of serum in the culture medium. Twenty-four hour cultures in which serum has been excluded yield an apparently undegraded precursor, procollagen I. The latter is approximately twice the size of tropocollagen, possesses an acidic pl in contrast to the alkaline pl of tropocollagen, and shares secondary structural characteristics common to tropocollagen. Procollagen I exhibits a sharp thermal transition point at 39° with a ΔT of 2° indicating that the collagenous portion of the molecule is in the triple helical configuration prior to proteolytic excision from the parent molecule. The amino acid composition is remarkable when compared to tropocollagen in the large quantity of acidic residues, decreased glycine and imino acids, and the presence of cystcine. Three models of procollagen I structure are presented and discussed relative to the available experimental evidence.     

Autoradiographic study of the rate of collagen synthesis under conditions of stimulation of the wound process]

A study was made of the rate of the tropocollagen synthesis by the granulation tissue fibroblasts and of its passage into the intercellular space in control animals and under conditions of stimulation of the wound process by potassium orotate, one of the pyrimidine series derivatives. It appeared that the process of tropocollagen synthesis became accelerated under the effect of the stimulant; collagen fiber precursor appeared in the intercellular space earlier than in control and became included into the fibrous structures of the granulation tissue, this correlating with the intensification of the RNA synthesis in the fibroblast nuclei and an accelerated passage of the newly-synthesized RNA from the nucleus into the cell cytoplasm under analogous conditions. There was noted no sharp excess of collagen in the granulation tissue of animals given potassium orotate.     

A study of collagen and gelatin solutions by optical self beat spectroscopy

A study of the conformation of collagen and gelatin in aqueous solution by Optical Self Beat Spectroscopy is reported. The translational diffusion coefficient of monomeric tropocollagen was experimentally measured from the half-width of the Rayleigh scattered radiation and the value obtained is shown to be in good agreement with that calculated from hydrodynamical theory for the tropocollagen rod. The Self Beat Spectrometer was also used to investigate the factors affecting the aggregation and flexing of molecules in dilute gelatin solutions and the gel-sol transition in more concentrated gelatin solutions.     

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.     

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.     

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.     

Heterogeneity of tropocollagen as investigated by chromatography on hydroxyapatite columns

The chromatography of native acid-soluble tropocollagen from calf skin on hydroxyapatite columns has been investigated. Resolution of a number of chromatographic peaks has been obtained by using shallow slopes of the eluting phosphate gradient. The results obtained suggest a heterogeneity of tropocollagen molecules which might be due to different distributions of absorbing sites on the molecules. The results obtained have also been used to study the mechanism of chromatography of proteins on hydroxyapatite and the resolving power of the columns.     

Thermal conformational transformation of tropocollagen. I. Calorimetric study

Effects of heat in heated solution of tropocollagens of different origins were calorimetrically studied. It was found that denaturation enthalpy and entropy of different tropocollagens increase with increasing imino acid content and thermostability. It is shown that the value and dependence of denaturational enthalpy and entropy on the denaturation temperature for tropocollagens with different imino acid contents are inconsistent with the assumption that the native structure of tropocollagen is stabilized only by intramolecular hydrogen bonds. A supposition is made that the regular water structure near the macromolecule plays an essential role in stabilizing the structure. From the character of tropocollagen melting curves in salt-free solution it is found that the tropocollagen macromolecule is linearly heterogeneous. It is shown that the complex pattern of thermal absorption observed in tropocollagen salt, solution is connected with pre-denaturational conformational transformation when approaching conditions close to the physiological.     

Protein-restricted maternal diet during lactation decreases type I and type III tropocollagen synthesis in the skin of mice offspring

We investigated the effects of a low protein (LP) maternal diet during lactation on type I and III tropocollagen synthesis in infant mouse skin. The LP diet decreased the levels of type I and III tropocollagen proteins and COL1A1 and COL3A1 mRNA. Thus, the protein composition of the maternal perinatal diet may influence the skin health of offspring.     

Proteomic Profiling of the Aleurone Layer of Mature Arabidopsis thaliana Seed

The aleurone layer of mature Arabidopsis thaliana seed plays important roles in seed germination and dormancy. However, the proteomic profile of this cell layer is unknown partly because it is difficult to separate this thin cell layer from the mature seeds. In this study, we have used a simple technique to separate the aleurone layer along with the seed coat following germination of seeds and determined for the first time the putative protein composition of this cell layer. By subjecting the total proteins extracted from the seed coat to 2D gel electrophoresis followed by liquid chromatography/tandem mass spectrometry, we identified four AGI loci, AT4G28520, AT5G44120, AT1G03880, and AT1G03890; all of which belong to the seed storage family of proteins. Because in Arabidopsis the diploid aleurone cells of the seed coat perform protein storage functions similar to that of triploid endosperm of other plant species, it is assumed that the above AGI loci are associated with the aleurone layer of the seed coat.     

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.     

Branched-chain amino acids regulate type I tropocollagen and type III tropocollagen syntheses via modulation of mTOR in the skin

Abstract

Branched-chain amino acids (BCAAs) exhibit many physiological functions. However, the potential link and mechanism between BCAA and skin function are unknown. We examined the effects of deletion of branched-chain α-keto acid dehydrogenase kinase (BDK), a key enzyme in BCAA catabolism, on type I and III tropocollagen syntheses in mice. Leucine and isoleucine levels were significantly lower in the skin of BDK-KO mice compared with wild-type mice. No changes in valine concentrations were observed. The levels of type I and III tropocollagen proteins and mRNAs (COL1A1 and COL3A1) were significantly lower in the skin of BDK-KO mice compared with wild-type mice. The phosphorylation of p70 S6 kinase, which indicates mammalian target of rapamycin (mTOR) activation, was reduced in the skin of BDK-KO mice compared with wild-type mice. These findings suggest that deficiencies of leucine and isoleucine reduce type I and III tropocollagen syntheses in skin by suppressing the action of mTOR.     

The effect of chondroitin sulphate–protein on the formation of collagen fibrils in vitro

1. It was found that the precipitation of collagen fibrils at 37 degrees from mixtures of chondroitin sulphate-protein and tropocollagen at physiological ionic strength and pH takes place in two distinct phases. The first occurs immediately on mixing either at 4 degrees or at 37 degrees , and the second occurs only at 37 degrees and after a lag phase whose magnitude depends on the proportions of components. 2. When the second stage of precipitation was inhibited by mixing the reactants at 4 degrees , the initial precipitate was found to contain ;native-type' collagen fibrils and chondroitin sulphate-protein. 3. On the basis of kinetic experiments it was concluded that aggregates of chondroitin sulphate-protein and tropocollagen form instantaneously and that these act as sites for the second stage of precipitation of fibrils. 4. The gels that result after continued incubation at 37 degrees are fibrous in appearance if formed in the presence of the initial precipitate of chondroitin sulphate-protein and tropocollagen. 5. On the basis of these experiments in vitro the authors propose a sequence of events for collagen fibrogenesis in vivo.     

‘Gelatinase-like’ activity from articular chondrocytes in monolayer culture

In addition to releasing collagenase and proteoglycanase activity, rabbit articular chondrocytes in monolayer culture released into the culture medium, latent, neutral enzyme activity which when activated by p-aminophenylmercuric acetate degraded fluorescein-labeled polymeric rat tail tendon Type I collagen and the tropocollagen TC_A and TC_B fragments of human Type II collagen into smaller peptides at 37°C. Enzyme activity was abolished if p-aminophenylmercuric acetate-activated culture medium was preincubated with 1,10-phenanthroline, a metal chelator. Thus, articular chondrocytes in monolayer culture are capable of producing neutral proteinases which acting together can result in complete degradation of tendon and cartilage collagen to small peptides.     

Thermal conformational transformations of tropocollagen. II. Viscometric and light-scattering studies

It was shown by viscometric measurements that a tropocollagen solution at low shear gradients manifests elastic features which can be connected only with the existence of a labile spatial structure which develops in time in the solution. To judge by the concentration dependence of the rate of formation of this structure, it does not represent a molecular net formed by direct contact of macromolecules. Most likely this structure is a result of stabilization of macromolecules at a certain distance from each other. The study of light scattering by tropocollagen solutions demonstrated that it does not correspond with the scattering by rigid rod-shaped units. Anomalies in the character of light scattering are probably the result of intermolecular interference produced by a spatial supermolecular structure and, in turn, indicate that this structure is to some extent regular. In the presence of salts the elastic features in the tropocollagen solution and anomalies in light scattering disappear in a narrow range of temperatures immediately before the process of denaturation which makes it possible to conclude that the supermolecular regular structure is disrupted in this temperature range.     

Collagen-polysaccharide gel as a model of intercellular substance of the connective tissue]

Gel samples forming at 37 degrees C in the solutions containing tropocollagen and various polysaccharides were examined by electron microscopy. Contracting gel clots formed in the solutions containing chondroitin sulfate, proteoglycine from the tracheal cartilage, gum arabic. Electron microscopy showed such clots to be permeated with collagen fibrillae with transverse striations and a period of 640 A. An association between the density of the forming gel and the nature of the polysaccharide component is discussed. Gel forming in the solutions containing tropocollagen and various polysaccharides is regarded as a model of the connective tissue intercellular substance.