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.     

Monitoring micrometer-scale collagen organization in rat-tail tendon upon mechanical strain using second harmonic microscopy

We continuously monitored the microstructure of a rat-tail tendon during stretch/relaxation cycles. To that purpose, we implemented a new biomechanical device that combined SHG imaging and mechanical testing modalities. This multi-scale experimental device enabled simultaneous visualization of the collagen crimp morphology at the micrometer scale and measurement of macroscopic strain-stress response. We gradually increased the ultimate strain of the cycles and showed that preconditioning mostly occurs in the first stretching. This is accompanied by an increase of the crimp period in the SHG image. Our results indicate that preconditioning is due to a sliding of microstructures at the scale of a few fibrils and smaller, that changes the resting length of the fascicle. This sliding can reverse on long time scales. These results provide a proof of concept that continuous SHG imaging performed simultaneously with mechanical assay allows analysis of the relationship between macroscopic response and microscopic structure of tissues.     

The effect of γ-irradiation on soluble collagen

1. A study was made of the effect of gamma-irradiation on the sub-unit composition, as well as the conformational changes taking place in cooled solutions of thermally denatured neutral-salt-soluble and acid-soluble collagen. 2. The increase in negative rotation and viscosity at 15 degrees for irradiated and thermally denatured collagen solutions becomes less as the irradiation dose is increased. 3. The initial effect of gamma-irradiation is the depolymerization of the dimers found in both neutral-salt-soluble and acid-soluble collagen. 4. The principal effect of gamma-irradiation up to 10 Mrads is the fission of peptide bonds, yielding crystalline irradiation-resistant portions of the molecule incapable of associating to the native structure. 5. The effects of gamma-irradiation on both neutral-salt-soluble and acid-soluble collagen are very similar and bear a close resemblance to the effects induced by ultraviolet irradiation.     

The effect of ultraviolet irradiation on soluble collagen

1. The effect of ultraviolet irradiation on acid-soluble and neutral-salt-soluble calf-skin collagen was studied by chromatography, gel filtration, amino acid analysis and sedimentation of the sub-units, and the reaction kinetics of degradation were obtained from viscosity and optical rotation measurements. 2. It was demonstrated that, whereas the structure of neutral-salt-soluble calf-skin collagen may be represented by the formula (alpha(1))(2)alpha(2), the acid-soluble extract has the formula alpha(1).(alpha(2))(2). The acid-soluble collagen is also unusual in containing a large amount of a component that could be beta(22). 3. Ultraviolet irradiation causes the progressive degradation of the collagen molecule into smaller molecular fragments that subsequently lose their helical nature. The rate constants show that the denaturation of soluble collagens by ultraviolet irradiation is much slower, under the conditions used, than denaturation by heat or enzymes.     

The effect of glycols on the renaturation of soluble collagen

The effects of a number of related glycols and substituted glycols on the renaturation kinetics of acid-soluble calf-skin collagen have been investigated. Optical rotation recovery was monitored at a fixed temperature in the presence of perturbants and the initial rates of reaction were determined. The effects of perturbants on stability of the native protein are compared with their action in the renaturing systems. The relationship between initial recovery rates and fixed-time [alpha]-values is shown to be dependent upon the renaturation temperature. The influence of perturbant concentration on recovery rates is discussed in terms of present theories of the mechanism of collagen renaturation.     

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.     

Spatial relationships between fibroblasts during the growth of rat-tail tendon

Sections of tendons from the base of the tail of rats were taken at eight time intervals from 18 days in utero until 244 days after birth and were examined in the electron microscope. For each time period, measurements were made of the relative area of fibroblasts, collagen and interstitial material, of the number of fibroblasts per unit area of tendon and of the average area of individual fibroblasts. The spatial arrangement of fibroblasts in the tendon sections was described quantitatively using the "nearest neighbor" method. Initially there was a rapid increase in the area of collagen accompanied by a decrease in the area occupied by fibroblasts but after 104 days of age these values changed very little. The numbers of fibroblasts per unit area decreased steadily from the embryo until 104 days whereas the average size of each cell increased to reach a maximum area at 40 days of age and then declined. At all time intervals cells were arranged in a regular, dispersed pattern across the tendon fascicles. Growth in width of the rat tail appears to involve the secretion of collagen and other intercellular material symmetrically around each fibroblast, so as to gradually separate the cells until a stage is reached at which cells are sufficiently far apart that there is little contact between adjacent cell processes. This may interfere with the integration of metabolic activity in the tissue. As a consequence, there is shrinkage of the cell bodies and a reduction in secretory activity so that, between 55 and 104 days of age, the tendon enters a period of terminal senescence.     

Age-dependent influence of strain rate on the tensile failure of rat-tail tendon

Sensitivity of tensile strength, failure strain, and failure energy density to strain rate was studied for rat-tail tendon (RTT), a collagen-rich connective tissue. Tendons from animals aged 1-27 months were stretched at a high (720 percent/s) and low (3.6 percent/s) strain rate. Each failure parameter increased with strain rate. However, the sensitivity of tendon failure to rate of strain decreased rapidly during growth and sexual maturation of the animal. The study provides basic data on the rate-sensitive strength of collagen fibers using RTT.     

Unit cell and molecular connectivity in tendon collagen

X-ray diffraction patterns have been recorded from native rat-tail tendon and from rat-tail tendon treated with phosphotungstic acid. The reciprocal space coordinates of a number of Bragg reflections were determined and used to determine both the unit cell of the lattice and its orientation with respect to the fibre axis. The unit cell was found to be triclinic and to contain only one molecule. The results obtained are discussed in terms of the microfibril and of the quasi-hexagonal models for molecular packing. The unit cell dimensions are consistent with the latter model and values are derived for the molecular tilt and azimuth.     

The rat-tail artery maintained in culture: an experimental model

The rat-tail artery was maintained in vitro for 2 weeks to investigate its suitability as an experimental model. The criteria were that (a) it should retain the overall histological organization with normal ultrastructural appearance of the smooth-muscle cells; (b) stored neurotransmitter which could be activated by experimental treatment should be absent; and (c) smooth-muscle ion transport mechanisms should fall within normal range. Vessels were maintained in Falcon tissue-culture dishes in Dulbecco's modified Eagle's medium. Either 2% or no serum supplement was found to be more suitable than 10% serum due to the high rate of cell proliferation induced by the latter. Light and electron microscopy of cross sections of the vessels indicated that the overall normal vessel architecture was retained, and the ultrastructural features predicted normal function. There were no discernible differences dependent on the length (up to 8- to 10-cm lengths) of the cultured vessel. Preliminary experiments with fluorescent microscopy showed that stored neurotransmitter in the nerves of the vessel wall was no longer present after 48 hr. Ultrastructural examination revealed that storage vesicles in vitro lost their dense cores, representing noradrenalin, between 41 and 48 hr in culture. Normal ion transport mechanisms were retained in the smooth-muscle cells of the arteries in vitro for up to 2 weeks when tested with ion-specific electrodes. Morphological and physiological evidence support the suitability of the rat-tail artery as a model for experimental testing of vascular tissues.     

The effect of bovine tendon glycoprotein on the formation of fibrils from collagen solutions.

The formation of collagen fibrils under physiological conditions of ionic strength, pH and temperature was markedly affected by the presence of small amounts of bovine tendon glycoprotein. The absorbance of the gels at 400 nm was decreased, and they took longer to form. Over the range of concentration tested, the negative specific absorbance, -delta Asp., and the specific retardation, Rsp., both increased with the glycoprotein to collagen ratio. When added during the nucleation phase, glycoprotein was still able to exert its effect almost fully, and so must act to inhibit the later stages of fibril formation. Several pieces of evidence showed that glycoprotein acts via a weak binding to the collagen molecule. Electron microscopy established that fibrils formed in the presence of glycoprotein had a normal cross-striation pattern, but were significantly thinner than fibrils formed in control gets. The results suggest that glycoprotein could act in tissues to help regulate the diameter of collagen fibrils.     

The rat-tail artery maintained in culture: An experimental model

Summary The rat-tail artery was maintained in vitro for 2 weeks to investigate its suitability as an experimental model. The criteria were that (a) it should retain the overall histological organization with normal ultrastructural appearance of the smooth-muscle cells; (b) stored neurotransmitter which could be activated by experimental treatment should be absent; and (c) smooth-muscle ion transport mechanisms should fall within normal range. Vessels were maintained in Falcon tissue-culture dishes in Dulbecco's modified Eagle's medium. Either 2% or no serum supplement was found to be more suitable than 10% serum due to the high rate of cell proliferation induced by the latter. Light and electron microscopy of cross sections of the vessels indicated that the overall normal vessel architecture was retained, and the ultrastructural features predicted normal function. There were no discernible differences dependent on the length (up to 8- to 10-cm lengths) of the cultured vessel. Preliminary experiments with fluorescent microscopy showed that stored neurotransmitter in the nerves of the vessel wall was no longer present after 48 hr. Ultrastructural examination revealed that storage vesicles in vitro lost their dense cores, representing noradrenalin, between 41 and 48 hr in culture. Normal ion transport mechanisms were retained in the smooth-muscle cells of the arteries in vitro for up to 2 weeks when tested with ion-specific electrodes. Morphological and physiological evidence support the suitability of the rat-tail artery as a model for experimental testing of vascular tissues. This work was carried out with the aid of grants from the British Columbia Heart Foundation.     

Effect of estrogen on tendon collagen synthesis, tendon structural characteristics, and biomechanical properties in postmenopausal women

The knowledge about the effect of estradiol on tendon connective tissue is limited. Therefore, we studied the influence of estradiol on tendon synthesis, structure, and biomechanical properties in postmenopausal women. Nonusers (control, n = 10) or habitual users of oral estradiol replacement therapy (ERT, n = 10) were studied at rest and in response to one-legged resistance exercise. Synthesis of tendon collagen was determined by stable isotope incorporation [fractional synthesis rate (FSR)] and microdialysis technique (NH(2)-terminal propeptide of type I collagen synthesis). Tendon area and fibril characteristics were determined by MRI and transmission electron microscopy, whereas tendon biomechanical properties were measured during isometric maximal voluntary contraction by ultrasound recording. Tendon FSR was markedly higher in ERT users (P < 0.001), whereas no group difference was seen in tendon NH(2)-terminal propeptide of type I collagen synthesis (P = 0.32). In ERT users, positive correlations between serum estradiol (s-estradiol) and tendon synthesis were observed, whereas change in tendon synthesis from rest to exercise was negatively correlated to s-estradiol. Tendon area, fibril density, fibril volume fraction, and fibril mean area did not differ between groups. However, the percentage of medium-sized fibrils was higher in ERT users (P < 0.05), whereas the percentage of large fibrils tended to be greater in control (P = 0.10). A lower Young's modulus (GPa/%) was found in ERT users (P < 0.05). In conclusion, estradiol administration was associated with higher tendon FSR and a higher relative number of smaller fibrils. Whereas this indicates stimulated collagen turnover in the resting state, collagen responses to exercise were negatively associated with s-estradiol. These results indicate a pivotal role for estradiol in maintaining homeostasis of female connective tissue.     

The dynamics of collagen uncrimping and lateral contraction in tendon and the effect of ionic concentration

Under tensile loading, tendon undergoes a number of unique structural changes that govern its mechanical response. For example, stretching a tendon is known to induce both the progressive “uncrimping” of wavy collagen fibrils and extensive lateral contraction mediated by fluid flow out of the tissue. However, it is not known whether these processes are interdependent. Moreover, the rate-dependence of collagen uncrimping and its contribution to tendon's viscoelastic mechanical properties are unknown. Therefore, the objective of this study was to (a) develop a methodology allowing for simultaneous measurement of crimp, stress, axial strain and lateral contraction in tendon under dynamic loading; (b) determine the interdependence of collagen uncrimping and lateral contraction by testing tendons in different swelling conditions; and (c) assess how the process of collagen uncrimping depends on loading rate. Murine flexor carpi ulnaris (FCU) tendons in varying ionic environments were dynamically stretched to a set strain level and imaged through a plane polariscope with the polarizer and analyzer at a fixed angle. Analysis of the resulting images allowed for direct measurement of the crimp frequency and indirect measurement of the tendon thickness. Our findings demonstrate that collagen uncrimping and lateral contraction can occur independently and interstitial fluid impacts tendon mechanics directly. Furthermore, tensile stress, transverse contraction and degree of collagen uncrimping were all rate-dependent, suggesting that collagen uncrimping plays a role in tendon's dynamic mechanical response. This study is the first to characterize the time-dependence of collagen uncrimping in tendon, and establishes structure–function relationships for healthy tendons that can be used to better understand and assess changes in tendon mechanics after disease or injury.     

The molecular genetics of collagen

In their Bioessays review ‘Current views of collagen degradation’, Gillian Murphy and John Reynolds gave an outline of the molecular structure of the members of the collagen family and described their traditional role in providing stable tissue frameworks.¹ This short review considers the relationship between the different members of that family and what gene structure reveals about their evolution. Mutation of the collagen structural genes has been discovered in patients suffering from brittle-bone syndrome and other inherited connective tissue disorders, and here I attempt to rationalize these results into an overall concept of collagen gene mutation and evolution.