Location of procollagen in chick corneal and tendon fibroblasts with ferritin-conjugated antibodies.

Three distinct antiprocollagen preparations were characterized and used in immunocytochemical staining of chick embryo corneal and tendon cells. The several ferritin-conjugated antibody preparations permitted similar location of procollagen in the cisternae of the rough endoplasmic reticulum and in Golgi elements in both cell types. The ability to demonstrate and interpret specific ferritin staining was dependent on the extent of membrane breakage in each of those organelles, coupled with adequate retention of cell morphology. Corneal fibroblasts appeared to suffer more extensive intracellular membrane damage under controlled conditions of homogenization than tendon fibroblasts, facilitating the identification of procollagen in Golgi vacuoles of these cells. None of the labeled material appeared to by cytoplasmic in origin since ferritin was observed in the cytoplasm only in the vicinity of Golgi elements that were extensively broken. This study extends previous immunological evidence for the presence of procollagen in the Golgi complex and calls attention to the problems to be encountered in locating the antigen in small Golgi vesicles and lamellae.

Defect in conversion of procollagen to collagen in a form of Ehlers-Danlos syndrome.

Three patients with a form of the Ehlers-Danlos syndrome, a generalized disorder of connective tissue, have detectable amounts of procollagen in extracts of their skin and tendon. The activity of procollagen peptidase, the enzyme that converts procollagen to collagen, is reduced in cultures of fibroblasts. The clinical manifestations of this syndrome may be related to impaired enzymatic conversion of procollagen to collagen. Cultures of skin fibroblasts from these patients have an increased rate of synthesis of collagenous protein (collagen and procollagen), possibly related to the inability of these cells to convert procollagen to collagen.

Electroconductivity of collagen in vitro and in vivo.

Electrical conductivity was measured on thermally reconstituted collagen fibers in vitro and on isolated rat tail tendon collagen fiber bundles in vivo. The results obtained indicated that collagen per se is not an electroconductor under physiological conditions, but rather a biological insulator.

Collagen crosslinking and cartilage glycosaminoglycan composition in normal and scoliotic chickens.

The amounts of lysine-derived crosslinks in collagens from tendon, cartilage, intervertebral disc, and bone and changes in the composition of sternal cartilage glycosaminoglycans were estimated in two lines of chickens, a control-isogenic line and a line that develops scoliosis. In the scoliotic line, scoliosis first appears at 3-4 weeks and progressively increases in severity and incidence so that 90% of the birds express the lesion by week 10. We have reported previously that cartilage, tendon, and bone collagens from scoliotic birds are more soluble than corresponding collagens from normal birds. Herein, collagen crosslinking and altered proteoglycan metabolism are examined as possible mechanisms for the differences in collagen solubility. At 1 week of age there were fewer reducible crosslinking amino acids (hydroxylysinonorleucine, dihydroxylysinonorleucine, and lysinonorleucine) in collagens from sternal cartilage and tendon in the scoliotic line than in the isogenic line. However, by week 3 and at weeks 5 or 7 values were similar in both groups. The amounts of hydroxypyridinium in vertebral bone and intervertebral disc collagen were also similar in both groups of birds. Consequently, differences in collagen crosslinking do not appear to be a persistent developmental defect underlying the expression of scoliosis in the model. However, differences were observed in cartilage proteoglycans and glycosaminoglycans from the scoliotic line that were not present in cartilage from the isogenic line. The average molecular weight of the uronide-containing glycosaminoglycans was 30% less in the scoliotic line than in the isogenic line, i.e., 12,000 compared to 18,000. The size distribution of cartilage proteoglycans from the scoliotic line also differed from that of proteoglycans from the isogenic line.(ABSTRACT TRUNCATED AT 250 WORDS)

In vivo and in vitro aging of collagen examined using an isometric melting technique.

1. In vivo and in vitro aging of tendon from rat tail, kangaroo tail and human wrist tendon was examined by the technique of isometric melting, in physiological saline. 2. For all these collagens, two mechanisms of structure stabilisation can be distinguished in the melting curves. One of these involves co-valent cross-linking as judged by its increasing stability to heat and acid pH, while the second appears to involve only secondary interactions. 3. The time rate of the first process is slow in vivo; rat tendon up to 2 years does not show it, but it is present in 6-year-old human tendon. However, its in vitro rate is markedly dependent upon the free oxygen content of the physiological saline. At an oxygen concentration of 300 nmol/ml, the in vitro aging rate is about 30 times the in vivo rate for rat tail tendon, and about 20 times for both kangaroo tail tendon and human wrist tendon. At a concentration of 60 nmol/ml (which is about the same as normal arteriovenous blood difference) in vitro aging proceeds close to the in vivo rate.

An unusual collagen periodicity in skin.

The axial periodicity of collagen fibrils was observed by X-ray diffraction to be significantly shorter in wet skin (65.2 nm) than in wet tendon (67.0 nm). This difference appears to be due to some feature in the native skin environment, since purified skin Type I and Type III collagens will both form fibrils with a normal 67.0 nm d-period.

Pepsin-solubilized collagen of human nucleus pulposus and annulus fibrosus.

Human nucleus pulposus and annulus fibrosus, obtained at autopsy from patients 7-30 years of age, were extracted with 2 M guanidine-HCl (pH 5.82) to remove proteoglycans, then stirred with pepsin in 0.5 M acetic acid, followed by three 24-h extractions with 1 M NaCl (pH 7.5) and one 24-h extraction with 2 M KSCN (potassium thiocyanate) (pH 7.2). Pepsin and NaCl solubilized an average of about 30% of nucleus pulposus collagen and 18% of annulus fibrosus collagen. KSCN extracted a further 34% of nucleus pulposus collagen and only 4% of annulus fibrosus collagen. CM-cellulose chromatography of nucleus and annulus collagen purified from the pepsin, NaCl and KSCN supernatants consistently revealed only one peak, always appearing slightly ahead of the alpha1 position for rat tail tendon type I collagen. Polyacrylamide and SDS-gel electrophoresis consistently revealed only one band with the mobility of alpha1 chains. Amino acid composition of collagen from nucleus and annulus is comparable to those of mammalian and avian cartilage type II collagen, and distinctly different from those of rat tail tendonand guinea pig skin type I collagens. Periodate oxidation of nucleus and annulus collagens showed that 81% and 67%, respectively, of the hydroxylysine residues survive treatment, compared to 71% for bovine articular cartilage collagen and 17% for guinea pig skin collagen. Total hexose analysis revealed 1.8 muM and 2.0 muM hexose per muM periodate-stable hydroxylysine in nucleus and annulus collagens, respectively. Ion exchange chromatography showed the presence of glucose and galactose in a ratio of 0.92:1 in nucleas collagen and 1.07:1 in annulus collagen. Pepsin-solubilized, NaCl-extracted collagen from nucleus and annulus formed native-type fibrils in vitro. The banding patterns of ATP-induced segment-long-spacing precipitates of nucleus and annulus collagens were identical to each other and indistinguishable from those of cartilage (type II) collagen, but distinctly different from those of rat tail tendon (type I) collagen. These data suggest that the collagen which can be extracted after limited pepsin attack of human nucleus and annulus is of the form [alpha1 (II)]3.

Collagenase digestion demonstrates carboxy-terminal crosslinking in acid-soluble collagen.

Among the products of the collagenase cleavage of Type I acid-soluble collagen from calf and rabbit tendons, there can be found fragments with the lengths of half alpha-chains. Because purified collagenase cleaves the alpha-chains three-quarters of the length from the amino-terminus, the presence of half-length chains is evidence for the occurrence of crosslinks between two carboxy-terminal, quarter-length fragments, The collagen preparations were reduced with [3H]borohydride, the collagenase-cleaved fragments were separated by gel electrophoresis, and their 3H-labeled crosslink derivatives were analyzed. The major labeled components in the half-length chains were the reduced aldol condensation product and hydroxylysinonorleucine. These experiments demonstrate that the carboxy-terminal telopeptides in monomer-enriched collagen samples form aldol crosslinks which are probably intramolecular, but some intermolecular aldol and aldimine crosslinks may also be formed.

Skin collagen has an unusual d-spacing.

Small angle X-ray diffraction patterns show a d-spacing of 65 +/- 0.5 nm for the collagen in wet intact skin of amphibian larvae (tadpole) as well as from that of nature frogs, chickens and mice. The collagen in these tissues is largely collagen I which exhibits a d-spacing of 67 +/- 0.5 nm in wet intact unstretched tendons. The d-spacing of the skin collagen did not decrease on drying, while it is well known that that of tendon collagen does decrease on drying. The reasons for the decreased d-spacing in the normal skin are not known but we suggest that the different glycosaminoglycan content of skin may be an important factor.

Bovine type I collagen: A study of cross-linking in various mature tissues.

The cyanogen bromide peptides from insoluble and pepsin solubilised type I collagen of bovine bone, dentine, meniscus, tendon, skin and cornea were compared by SDS-polyacrylamide gel electrophoresis. In each case alpha 1CB6 was shown to be the only peptide of molecular weight greater than 10 000 involved in cross-linking. The major helical peptides alpha 1CB3, alpha 1CB8, alpha 1CB7 and alpha 2CB4 were not implicated in cross-linking in any tissue either by end overlap or helix-helix interaction. The C-terminal alpha 2 chain peptide alpha 2CB3,5, which contains a large helical region, was not involved in cross-linking to any large peptides, although a slight increase in molecular weight in all tissues examined did suggest a possible interaction(s) with a very small peptide of molecular weight 4--5000.

Generalized inhibition of cell-free translation by the amino-terminal propeptide of chick type I procollagen.

Fragments of the amino-terminal propeptide of procollagen have been shown to inhibit the synthesis of procollagen in cultured cells and in a reticulocyte lysate cell-free system (for review see Timpl, R. and Glanville, R.W. (1981) Clin. Orth. Rel. Res. 158, 224-242). In this report, we show that the full-length amino-terminal propeptide of chick pro alpha1(I) chains inhibits the translation of chick tendon mRNA and rat brain mRNA in a reticulocyte lysate cell-free system. The synthesis of procollagen and non-collagenous proteins was equally affected. Inhibition was dose-dependent up to 10 microM. A similar pattern of inhibition was observed for the collagenase-resistant fragment, col 1(I).

The presence of gamma-carboxyglutamic acid-containing protein in atheromatous aortae.

It has been established that a gamma-carboxyglutamic acid-containing protein is present in rat aortae after long term atherogenic diet administration. A similar protein was proven to be present in turkey tibial tendons that are predisposed to undergo physiological calcification. The molecular weight and amino acid composition of both proteins were identical. They contained six glutamic acid residues per molecule, three of which were gamma-carboxylated. The proteins studied were also identical in their N-terminal sequence over six residues. This sequence was fully coincident with that published for osteocalcin (Price, P.A., Poser, J.W. and Raman, N. (1976) Proc. Natl. Acad. Sci. U.S.A. 73, 3374--3375). In the region corresponding to residues 20--26 in osteocalcin, a single replacement of valine for isoleucine was found in turkey tendon protein. From the physiological point of view it should be mentioned that the level of the gamma-carboxyglutamic acid containing protein in atherogenic diet fet rat aortae exceeds that found normally in bone or in tissues predisposed for physiological calcification.

Molecular packing in type I collagen fibrils.

Previous studies of the X-ray diffraction pattern of the crystalline regions of type I collagen fibrils yielded information on the unit cell parameters and also the orientation of the pseudo-hexagonally packed molecular segments in the overlap region. The absence of Bragg reflections at high angles attributable to the molecular segments in the gap region led to the suggestion that these segments were more mobile than those in the overlap region. We report a study of the low-angle Bragg reflections in a search for information about the nature of the orientation and packing of the molecular segments in the gap region. We conclude that the (m = 0, n = 0) helix layer plane of the molecular segments in the overlap region makes little or no contribution to the Bragg reflections at low angles, and identify three possible origins for the observed low-angle reflections in the electron density contrast associated with: (1) the "hole" created by the missing molecular segment in the gap region; (2) the telopeptides; or (3) the axial regularities in amino acid residues of a particular type, with periodicities of D/5 or D/6. Sufficient information is available to investigate the first two of these possibilities, and the results obtained suggest specific arrangements for the molecular segments in the overlap and gap regions, and specific connectivities between the molecular segments in successive overlap regions. In addition, we have examined the amino acid sequence and identified features related to the mobility of the molecular segments in the gap region and to the regions where it is thought that molecules are kinked.

Stress-induced molecular rearrangement in tendon collagen.

Tension-induced molecular rearrangements in wet native fibres of rat-tail tendons and human finger flexor tendons are registered with the help of time-resolved diffraction spectra using synchrotron radiation. The tension-induced increase of the 67 nm D period is combined with changes in the intensities of some orders of the meridional small angle reflection. Both effects are reversible when unloading the fibre, but are preserved when the load is held constant until the fibre tears. The increase in the D period is partly due to a sliding of the triple helices relative to each other and partly due to a stretching of the triple helices themselves. The sliding of the triple helices results in an alteration of the D stagger, leading to a change in the length of the gap and overlap regions, and to a stretching of the cross-linked telopeptides. This interpretation is supported by comparison with the relative intensities derived from a model with varying length of gap and overlap regions, as well as by comparison with model calculations that include the telopeptides.

Crystalline fibril structure of type II collagen in lamprey notochord sheath.

We report here the existence of a crystalline molecular packing of type II collagen in the fibrils of the lamprey notochord sheath. This is the first finding of a crystalline structure in any collagen other than type I. The lamprey notochord sheath has a composition similar to that of cartilage, with type II collagen, a minor collagen component with 1 alpha, 2 alpha and 3 alpha chains, and cartilage-like proteoglycan. The high degree of orientation of fibrils in the notochord makes it possible to use X-ray diffraction to determine collagen fibril organization in this type II-containing tissue. The low angle equatorial scattering shows the fibrils are all about 17 nm in diameter and have an average center-to-center separation of 31 nm. These results are supported by electron microscope observations. A set of broad equatorial diffraction maxima at higher angles represents the sampling of the collagen molecular transform by a limited crystalline lattice, extending over a lateral dimension close to the diameter of one fibril. This indicates that each 17 nm fibril contains a crystalline array of molecules and, although a unit cell is difficult to determine because of the broad overlapping reflections, it is clear that the quasi-hexagonal triclinic unit cell of type I collagen in rat tail tendon is not consistent with the data. The meridional diffraction pattern showed 26 orders with the characteristic 67 nm periodicity found for tendon. However, the intensities of these reflections differ markedly from those found for tendon and cannot be explained by an unmodified gap/overlap model within each 67 nm period. Both X-ray diffraction and electron microscope data indicate a low degree of contrast along the fibril axis and are consistent with a periodic binding of a non-collagenous component in such a way as to obscure the gap region.

Glutaraldehyde-induced changes in the axially projected fine structure of collagen fibrils.

The fine structure of the collagen fibril, as seen in axial projection, is changed by treatment with glutaraldehyde. The changes are detectable in electron-optical staining patterns and in the intensities of the low-angle meridional X-ray diffraction maxima. Current knowledge of the amino acid sequence of collagen and of the axial arrangement of molecules in fibrils permits interpretation in terms of specific alterations to the axial distribution of electron density along the fibril. Analysis of fibril staining patterns from glutaraldehyde-treated calf skin collagen shows that uptake of staining ions in positive staining patterns is inhibited at residues known to interact with glutaraldehyde (lysyl, hydroxylysyl and probably histidyl side-chains) and on other charged residues in the immediate neighbourhood of the glutaraldehyde-reactive residues. This can be seen as a "stain-exclusion effect" due to the presence of bulky polymeric complexes of glutaraldehyde molecules at cross-linking sites. Such stain exclusion accounts for the drastic changes in the negative staining pattern following treatment with glutaraldehyde. The intensity changes observed in the low-angle meridional X-ray reflections from rat tail tendon, similarly treated, also can be explained by the presence of these bulky complexes. Existing data have been used to predict a model of the altered electron density profile indicating the axial distribution of glutaraldehyde along a D-period of moist tendon collagen.

Collagen cross-links: location of pyridinoline in type I collagen.

Collagen from bone, dentine and tendon (type I), all of which contain the pyridinoline cross-link at varying levels, were each digested with CNBr. The resulting peptide mixtures were resolved by gel filtration on A1.5m agarose and assayed for pyridinoline. The polymeric cross-linked peptide complex, poly alpha 1CB6 [(1980) Biochem. J. 189, 111] isolated from each of these tissues did not contain pyridinoline. Only one peptide fraction contained the pyridinoline cross-link; that identified as alpha 2CB3,5. However, this peptide showed only a small increase in Mr in its cross-linked form (approx. 2000-5000) demonstrating that pyridinoline is not involved in the formation of polymeric structures like poly alpha 1CB6. These data, considered in the light of the recent finding that pyridinoline is present in type I collagens from different sources in widely varying amounts, cast doubt on its role in collagen maturation.

Tissue determinants of nuclear magnetic resonance relaxation times. Effect of water and collagen content in muscle and tendon.

Previous studies have suggested a possible relationship between tissue collagen content and nuclear magnetic resonance (NMR) relaxation times. To further investigate this relationship, we studied skeletal muscle, tendon, and the muscle/tendon transition area of normal gastrocnemius muscle from 10 dogs, and determined tissue water and collagen (hydroxyproline) content and NMR T1 and T2 relaxation times at 20 MHz. Water and hydroxyproline contents and T1 and T2 were significantly different among the three tissues. Both spin-lattice and spin-spin relaxation times were linearly related to tissue water content. A significant curvilinear inverse relationship between T1 and hydroxyproline (r2 = 0.93) and a significant inverse curvilinear relationship between T2 and hydroxyproline (r2 = 0.92) were found. Statistically controlling for hydroxy-proline concentration eliminated differences in T1 and T2 among the muscle, muscle/tendon transition, and tendon groups. Thus, NMR relaxation times of skeletal muscle and tendon appear to be influenced by both tissue water and collagen content.

Pyridinoline, a non-reducible crosslink of collagen. Quantitative determination, distribution, and isolation of a crosslinked peptide.

Pyridinoline is a crosslink compound isolated from bovine Achilles tendon collagen. It is a 3-hydroxypyridinium derivative with three amino and three carboxyl groups (Fujimoto, D., Akiba, K., & Nakamura, N. (1977) Biochem. Biophys. Res. Commun. 76, 1124-1129). The contents of pyridinoline in collagens from various sources were determined. The pyridinoline content of bovine Achilles tendon was 0.16 residue per 1,000 residues and that of rat Achilles tendon collagen was 0.017 residue per 1,000 residues. Besides Achilles tendon collagens, pyridinoline was found in collagens from costal cartilage, rib and femoral bone of rat. It was not found in collagens from the tail tendon and skin of rat. A crosslinked, triple-chained peptide containing pyridinoline was isolated from bovine Achilles tendon collagen after digestion with pronase. Its amino acid composition suggests that the peptide may be involved in an intermolecular crosslink among a carboxyterminal sequence, a sequence near the aminoterminus and a sequence in the helical region.

Adaptation of bone and tendon to prolonged hindlimb suspension in rats.

The rat hindlimb suspension model was used to ascertain the importance of ground reaction forces in maintaining bone and tendon homeostasis. Young female Sprague-Dawley rats were randomly assigned to either a suspended or a nonsuspended group. After 28 days, femur bones and patellar tendons were obtained for morphological and biochemical analyses. Prolonged suspension induced a significant change in the geometric configuration of the femur middiaphysis by increasing the minimum diameter (12%) without any significant alterations in cortical area, density, mineral, and collagen concentrations. Femur wet weight, length, DNA, and uronic acid concentrations of suspended animals were not significantly different from bones of nonsuspended rats. However, the collagen and proteoglycan concentrations in patellar tendons of suspended rats were 28% lower than the concentrations of matrix proteins in tissues obtained from nonsuspended animals. These data suggest that elimination of ground reaction forces induces alterations in tendon composition and femur diaphyseal shape by changing regional rates in bone remodeling and localized tendon strain. Therefore it appears that ground reaction forces are an important factor in the maintenance of cortical bone and patellar tendon homeostasis during weight-bearing conditions.