Three-dimensional organization of fibroblasts and collagen fibrils in rat tail tendon

Summary The orderly arrangement of fibroblasts and collagen in tendons and ligaments suggests that these cells may have precise relationships with one another and with the collagen fibrils. The spatial organization of rat tail tendon was therefore examined using scanning and transmission electron microscopy and by reconstructing a 35-m long segment of tendon from serial transmission electron micrographs. Fibroblasts were regularly arranged in columns and showed more intimate association in the longitudinal than in the transverse plane. Thin cytoplasmic sheets extended up to 3 m transversely, frequently forming junctional attachments with similar processes from adjacent cells or from the same cell. Longitudinal processes were longer, often extending for more than 20 m and forming junctional attachments with other cells in the same column. Such processes often exhibited invaginations in which there were single fibrils or small groups of fibrils; this arrangement may be indicative of fibril elongation or may serve to transmit tension between the fibroblast and the collagen fibrils. This organization has interesting implications for the growth and function of other fibrous connective tissue, such as the periodontal ligament.     

Fibromodulin and lumican bind to the same region on collagen type I fibrils

Fibromodulin and lumican are closely related members of the extracellular matrix leucine-rich repeat glycoprotein/proteoglycan family. Similar to decorin, another member of this protein family, they bind to fibrillar collagens and function in the assembly of the collagen network in connective tissues. We have studied the binding of recombinant fibromodulin, lumican and decorin, expressed in mammalian cells, to collagen type I. Using a collagen fibril formation/sedimentation assay we show that fibromodulin inhibits the binding of lumican, and vice versa. Fibromodulin and lumican do not affect the binding of decorin to collagen, nor does decorin inhibit the binding of fibromodulin or lumican. Binding competition experiments and Scatchard plot analysis indicate that fibromodulin binds to collagen type I with higher affinity than lumican.     

The crystalline structure of collagen fibrils in tendon.

New data have been collected on the crystalline structure of collagen fibrils in tendon. The unit cell in decrimped tendon has been determined by measurements of the Bragg reflections in the X-ray diffraction pattern. The results are consistent with a triclinic cell with $\text{b = 75.5}\text{A}\text{?}$, β = 93 °, $\text{a =}\text{b}\text{sin}\text{β}$, a = 90 °, $\text{c = n × 668}\text{A}\text{?}$, where n is probably 4 and γ = 90 °. A selection rule observed for prominent reflections is explicable either in terms of a specific orientation of the microfibrils on the lattice, or by a helical distortion of the microfibril axis. The cell parameter β can be varied by changing the ionic envirionment.     

Rotary shadowing of collagen monomers, oligomers, and fibrils during tendon fibrillogenesis

Collagen monomers, oligomers, and fibrillar structures were isolated from chick tendons at various stages of development and studied by rotary shadowing. Monomers of Type I collagen, solubilized in 0.15 M NaCl solutions, were mostly present as collagen, pN-collagen, and pC-collagen with few procollagen molecules. They did not form polymers, nor were they associated with a carrier. Dimers of fibrillar collagen molecules were arranged in a 4-D stagger, suggesting that this was the preferred molecular interaction for the initiation of collagen fibrillogenesis. Type XII collagen molecules were mostly free, but some were attached by their central globular domain to one end of free fibrillar collagen molecules. Tenascin and Type VI collagen were also identified. The fibril populations consisted of collagen and beaded structures. These fibrils consisted of beads (globular domains) about 23 nm in diameter, separated by a period about 27 nm in length. Beads were linked by filamentous structures. These beaded fibrils probably represent the microfibrils of elastin.     

Three-dimensional organization of collagen fibres in tendon

Electron microscopic observations are presented on thin sections of excised chicken breast tendon following the introduction and diffusion of aqueous solutions of heavy metal salts. The dark banded regions of the collagen fibrils are seen to be in near-perfect register throughout the diameter of each fibril and, in many cases, to be continuous across the intervening ground substance. Clusters of uranyl ions form well-defined chains extending across the interfibrillar space between neighbouring fibrils, a distance of several hundred nanometres. It is suggested that the high degree of organization characteristic of collagen fibrils in tissue may perhaps be a property not only of the protein but also of the ground substance in which it is embedded, the fibres merely rendering visible a lattice pattern of their surroundings to which they have conformed.     

Quantitative electron microscope observations of the collagen fibrils in rat-tail tendon

An electron microscope study of collagen fibrils from fixed tail tendons of rats has revealed that from some time shortly after birth until maturity, the fibril diameters have a bimodal distribution. The “two” types of fibril are indistinguishable in both transverse and longitudinal section. Unfixed specimens of eight-week-old-tail tendon showed a similar bimodal distribution of diameters though the positions of the peak values compared to fixed specimens of an eight-week-old-tail tendon were shifted upwards by about 30%. It has also been shown quantitatively that the polar collagen fibrils are directed randomly “up” and “down” with respect to their neighbors. Whilst it has been suggested by others that anastomosis is a feature of collagen structure, the results presented here do not support this hypothesis. Fibrillar units ～ 140 Å in diameter have been observed and the possibilities that these are elastic fibers or the breakdown products of collagen fibrils have been considered.     

Dbh(-/-) mice are hypotensive,have altered circadian rhythms,and have abnormal responses to dieting and stress

We used mice deficient in dopamine beta-hydroxylase [Dbh(-/-)] and their littermate controls [Dbh(+/-)] to examine the role of epinephrine (Epi) and norepinephrine (NE) in the maintenance of cardiovascular parameters during 7 days of caloric restriction and acute exposure to environmental stress. Cardiovascular parameters of the mice were monitored using blood pressure radiotelemeters at an ambient temperature of 29 degrees C. Under normal conditions, Dbh(-/-) mice had a low heart rate, were severely hypotensive, and displayed an attenuated circadian blood pressure rhythm. Upon 50% caloric restriction, Dbh(+/-) mice exhibited decreases in heart rate and mean blood pressure. However, the blood pressures of Dbh(-/-) mice did not fall significantly in response to caloric restriction, and the bradycardia associated with caloric restriction was attenuated in these mice. In response to an open-field test, the blood pressure and heart rate of Dbh(+/-) mice increased substantially and rapidly, whereas Dbh(-/-) mice had blunted changes in blood pressures and no change in heart rate. These data suggest a primary role of Epi and NE in mediating the hypotension induced by dieting. Furthermore, Epi and NE play a smaller, but still significant, role in the bradycardia induced by caloric restriction. In contrast, Epi and NE are required for the tachycardia in an open field but are not required for the increase in blood pressure.     

Alpha 2(I) collagen deficient oim mice have altered biomechanical integrity, collagen content, and collagen crosslinking of their thoracic aorta.

Collagen and elastin are the primary determinants of vascular integrity, with elastin hypothesized to be the major contributor to aortic compliance and type I collagen the major contributor to aortic strength and stiffness. Type I collagen is normally heterotrimeric composed of two alpha1(I) and one alpha2(I) collagen chains, alpha1(I)(2)alpha2(I). Recent investigations have reported that patients with recessively inherited forms of Ehlers Danlos syndrome that fail to synthesize proalpha2(I) chains have increased risks of cardiovascular complications. To assess the role of alpha2(I) collagen in aortic integrity, we used the osteogenesis imperfecta model (oim) mouse. Oim mice, homozygous for a COL1A2 mutation, synthesize only homotrimeric type I collagen, alpha1(I)3. We evaluated thoracic aortas from 3-month-old oim, heterozygote, and wildtype mice biomechanically for circumferential breaking strength (Fmax) and stiffness (IEM), histologically for morphological differences, and biochemically for collagen content and crosslinking. Circumferential biomechanics of oim and heterozygote descending thoracic aortas demonstrated the anticipated reduced Fmax and IEM relative to wildtype mice. Histological analyses of oim descending aortas demonstrated reduced collagen staining relative to wildtype aortas suggesting decreased collagen content, which hydroxyproline analyses of ascending and descending oim aortas confirmed. These findings suggest the reduced oim thoracic aortic integrity correlates with the absence of the alpha2(I)collagen chains and in part with reduced collagen content. However, oim ascending aortas also demonstrated a significant increase in pyridinoline crosslinks/collagen molecule as compared to wildtype ascending aortas. The role of increased collagen crosslinks is uncertain; increased crosslinking may represent a compensatory mechanism for the decreased integrity.     

Dysfunctional tendon collagen fibrillogenesis in collagen VI null mice

Tendons are composed of fibroblasts and collagen fibrils. The fibrils are organized uniaxially and grouped together into fibers. Collagen VI is a non-fibrillar collagen expressed in developing and adult tendons. Human collagen VI mutations result in muscular dystrophy, joint hyperlaxity and contractures. The purpose of this study is to determine the functional roles of collagen VI in tendon matrix assembly. During tendon development, collagen VI was expressed throughout the extracellular matrix, but enriched around fibroblasts and their processes. To analyze the functional roles of collagen VI a mouse model with a targeted inactivation of Col6a1 gene was utilized. Ultrastructural analysis of Col6a1−/− versus wild type tendons demonstrated disorganized extracellular micro-domains and associated collagen fibers in the Col6a1−/− tendon. In Col6a1−/− tendons, fibril structure and diameter distribution were abnormal compared to wild type controls. The diameter distributions were shifted significantly toward the smaller diameters in Col6a1−/− tendons compared to controls. An analysis of fibril density (number/μm²) demonstrated a ~ 2.5 fold increase in the Col6a1−/− versus wild type tendons. In addition, the fibril arrangement and structure were aberrant in the peri-cellular regions of Col6a1−/− tendons with frequent very large fibrils and twisted fibrils observed restricted to this region. The biomechanical properties were analyzed in mature tendons. A significant decrease in cross-sectional area was observed. The percent relaxation, maximum load, maximum stress, stiffness and modulus were analyzed and Col6a1−/− tendons demonstrated a significant reduction in maximum load and stiffness compared to wild type tendons. An increase in matrix metalloproteinase activity was suggested in the absence of collagen VI. This suggests alterations in tenocyte expression due to disruption of cell-matrix interactions. The changes in expression may result in alterations in the peri-cellular environment. In addition, the absence of collagen VI may alter the sequestering of regulatory molecules such as leucine rich proteoglycans. These changes would result in dysfunctional regulation of tendon fibrillogenesis indirectly mediated by collagen VI.     

Caveolin-1 knockout mice have altered serum N-glycan profile and sialyltransferase tissue expression

Journal of Physiology and Biochemistry - Caveolin-1 (Cav-1) is a constitutive protein within caveolar membranes. Previous studies from our group and others indicated that Cav-1 could mediate...     

Development of collagen fibril organization and collagen crimp patterns during tendon healing

Normal tendon comprises coaxially aligned bundles of crimped collagen fibres each of which possesses a fibrillar substructure. In acute traumatic injury this level of organization is disrupted and the mechanical function of the tendon impaired. During repair, a degree of recovery of the fibrillar structure takes place. In this tudy we have assessed the re-establishment of tendon organization after injury on the basis of the collagen fibril diameter distribution and the collagen crimp parameters. Crimp became undetectable following injury but one month later was present throughout the tissue. At this time the periodicity was greatly reduced by comparison with that of the normal tendon and normal values were not re-established within 14 months following injury. Collagen fibril diameters remained abnormally small over this same period of time. In particular, fibrils of diameters in excess of 100 nm, commonly found in normal and contralateral tendons, were totally absent from the observed distributions in the healing tendons. Such large diameter fibrils often account for as much as 50% of the total mass of collagen present in the uninjured tissue. Thus the mechanical properties of the healing tendon may remain significantly different from those of normal tendon for a minimum time of 14 months after injury.     

Ways of collagen separation in pathologically altered tissue

A system of chromatographic methods using two successive DEAE-cellulose chromatographic steps and two successive separations on Bio-Gel A-1.5 m has been worked out for the separation of individual collagen types. The success of the procedure is based on the preliminary removal of proteoglycans during the first DEAE-cellulose run. Alternatively it is possible to replace chromatographic steps, following the removal of proteoglycans, with fraction precipitation.     

Analysis of the crystal arrangement in collagen fibrils of mineralizing turkey tibia tendon

Summary Mineralized pieces of tendons from the tibio-tarsus of turkeys were (i) shock-frozen, freeze-dried, embedded and cut without staining, or (ii) fixed, embedded and stained after sectioning. Micrographs were taken with an electron microscope on longitudinally cut sections. The center-to-center distances of neighboring apatitic needles within collagen fibrils were measured. For shock-frozen and freeze-dried specimens, the average of these distances is 4.7 nm and the most frequent value 4.2 nm; for fixed and stained specimens, 3.8 nm and 3.6 nm, respectively. Laser diffraction of the electron micrographs showed a dumbbell-like intensity pattern (two diffuse maxima of intensity on the equator, one on each side of the central spot), giving an average distance of about 6 nm. This value represents the upper range of the direct measurements. The measurements demonstrate that the arrangement of the collagen microfibrils is mainly preserved during mineralization. However, using laser diffraction, distances of 9–11 nm were also observed. Such large distances can also be demonstrated by X-ray diffraction on collagen fibrils stained under special conditions. This may indicate that special conditions of apatitic mineralization or staining may alter the arrangement of the microfibrils.The authors thank the Deutsche Forschungsgemeinschaft for financial support     

Organisation of collagen fibrils in tendon: changes induced by an anabolic steroid

The organisation of tendon collagen fibrils has been studied by electron microscopy after treatment with an anabolic steroid hormone in a short-term and a long-term study. The effect of anabolic steroids is of interest because of their use in competitive sports and in clinical therapy. In a functional experimental model the unexpected occurrence of dysplastic as well as ruptured and dissociated collagen fibrils was revealed. The striking time-dependent collagen dysplasia and other pathological findings strongly suggest that in mice anabolic steroid treatment predisposes to tendon rupture especially when the animals are exercised. The possible underlying mode of action of anabolic steroid hormone on connective tissue is discussed.     

Organisation of collagen fibrils in tendon: changes induced by an anabolic steroid

Morphometric and stereologic analysis of the organisation of collagen fibrils in tendon tissue after a treatment with an anabolic steroid hormone allowed the following observations: In a short-term study stereological data revealed a potent accumulation of collagen fibrils in the extra-cellular matrix after the administration of an anabolic steroid. Compared with controls, the anabolic steroid significantly increased the number of dysplastic collagen fibrils dependent on duration of treatment. Inter- and intrafibrillary dysplastic collagen fibrils possess characteristic diameter distributions which differ considerably from those of normal collagen fibrils. The functional significance of the changes in mean diameter, diameter distribution, numerical density and volume fraction of collagen fibrils in tendons following hormone treatment may be relevant to the use of these drugs in clinical practice and in competitive sports.     

Degradation and deposition of amyloid AA fibrils are tissue specific

The complete amino acid sequences of two related AA proteins (Mr 9700 and 5300) derived from thyroid tissue from a patient, NOR, with the autosomal recessive disease familial Mediterranean fever were determined. Heterogeneity found at position 52 indicates these proteins are fragments of two allelic or isotypic SAA precursor molecules similarly degraded at unusual sites and deposited in the thyroid. Degradation appears to be tissue and/or enzyme(s) specific since the carboxy terminus of both fragments is Ala-Ala and is different from other AA amyloid fibrils extracted from various tissues in different patients. Electron micrographic studies reveal these fragments retain the characteristics of native amyloid fibrils under physiological conditions even after exposure to dissociating agents.     

Electron microscopic microprobe analysis of mineralized collagen fibrils and extracollagenous regions in Turkey leg tendon

Summary Bundles of tibia tendon from 19 week-old turkeys were deep frozen, freeze dried and embedded in styrol methacrylate or Epon. In the distal mineralized region, bundles of unmineralized collagen fibrils as well as mineralized regions consisting of round microcompartments with low contrast surrounded by a mineral sheath with high contrast were found. The inner regions with low contrast corresponded to the mineralized collagen fibrils, while the contrast-rich peripheral zones corresponded to the mineralized collagen-free ground substance. Using electron microscopic microprobe analysis, it was shown that the peripheral mineralized region, consisting mainly of closely packed needles, often contained 100% more mineral substance than the central, mineralized collagen zone, which consisted mainly of plate-like crystallites. Possible reasons for this difference in mineral content are discussed on the molecular level.The authors would like to express their gratitude to the Deutsche Forschungsgemeinschaft for financial support and to Fräulein Christine Dörnen for valuable technical assistance