Post-translational modifications in the collagen of human osteoporotic femoral head.

No detailed biochemical analysis has been made of the possible compositional changes in the collagen relating to the fragility of osteoporotic bone. We report for the first time significant changes in the compositional properties of the collagen. The major differences were observed in the post-translational modifications, namely, in the hydroxylation of lysine residues and the nature of the stabilizing cross-links of the collagen fibre. The increase in hydroxylation was greater in the head region compared to the neck region of the femoral head, whilst the decrease in the intermediate cross-links was greater in the neck region. Clearly, the collagen is altered in osteoporosis and it is important that these changes are recognised in studies of bone metabolism in osteoporosis since they may play a role in the pathogenesis of the disease.     

Evaluation of the effect of ascorbic acid treatment on wound healing in mice exposed to different doses of fractionated gamma radiation

Alteration of the radiation-induced changes in wound contraction, collagen synthesis and wound histology by ascorbic acid was studied in mice exposed to 10, 16 and 20 Gy of fractionated (2 Gy/fraction) gamma radiation. The animals were given double-distilled water or ascorbic acid daily before exposure to 2 Gy/day of fractionated irradiation. A full-thickness skin wound was created on the dorsum of the irradiated mice, and the progression of wound contraction and collagen synthesis were examined and histological evaluations were carried out at various times after wounding. Irradiation caused a dose-dependent delay in wound contraction, and pretreatment with ascorbic acid resulted in a significant increase in wound contraction. The greatest increase in wound contraction was observed 6 and 9 days after wounding in both groups. Pretreatment with ascorbic acid augmented the synthesis of collagen significantly as revealed by an increase in hydroxyproline content. The collagen deposition and fibroblast and vasculature densities declined in a dose-dependent manner in groups receiving radiation alone as indicated by histological evaluation. Pretreatment with ascorbic acid ameliorated the observed effect significantly. These studies demonstrate that pretreatment with ascorbic acid resulted in a significant reduction of radiation-induced delay in wound healing as shown by earlier wound closure and increased collagen content and fibroblast and vascular densities.     

Glycation of collagen: the basis of its central role in the late complications of ageing and diabetes

The most serious late complications of ageing and diabetes mellitus follow similar patterns in the dysfunction of retinal capillaries, renal tissue, and the cardiovascular system. The changes are accelerated in diabetic patients owing to hyperglycaemia and are the major cause of premature morbidity and mortality. These tissues and their optimal functioning are dependent on the integrity of their supporting framework of collagen. It is the modification of these properties by glycation that results in many of the damaging late complications. Initially glycation affects the interactions of collagen with cells and other matrix components, but the most damaging effects are caused by the formation of glucose-mediated intermolecular cross-links. These cross-links decrease the critical flexibility and permeability of the tissues and reduce turnover. In contrast to the renal and retinal tissue, the cardiovascular system also contains a significant proportion of the other fibrous connective tissue protein elastin, and its properties are similarly modified by glycation. The nature of these glycation cross-links is now being unravelled and this knowledge is crucial in any attempt to inhibit these deleterious glycation reactions.     

Thermal stability,mechanical properties and reducible cross-links of rat tail tendon in experimental diabetes

Thermal stability (measured as isometric contraction force), biomechanical properties and reducible cross-links were measured in tail tendons from streptozotocin diabetic rats, with and without insulin treatment. After 10 days of diabetes the maximum thermal contraction force was unchanged, but the relaxation following the maximal contraction was retarded. After 30 days the maximum contraction force was increased and the relaxation rate was decreased. The maximum strength and stiffness of the tendons were increased after 10 days of diabetes and even more after 30 days. There was no change in the density of reducible cross-links. However, diabetes increased the amount of glucose attached to the lysine and hydroxylysine residues of collagen. Insulin treatment prevented all changes in thermal stability and mechanical properties. The results indicate that stabilization of collagen fibres in diabetes does not follow the same pattern as that seen in normal ageing.     

Biosynthesis and degradation of collagen in X-irradiated mouse lung

Fibrosis, characterized by accumulation of collagen, is a delayed result of radiation injury in many tissues, including lung. To investigate its development, synthesis and degradation of collagen were measured in lungs of mice after X irradiation of the whole thorax. The ratio of type I (coarse fibered) to type III (meshwork) collagen was also determined. Synthesis of procollagen, measured as the activities of prolyl-4-hydroxylase and protein disulfide isomerase in lung tissue, was increased at 2 months after X-ray doses of 5, 7.5, and 9 Gy. Maximal increases were observed 6 to 7 months after doses of 9 Gy and persisted up to 15 months after exposure. Increases after 5 and 7.5 Gy were more gradual, but by 1 year after irradiation they had reached levels similar to those after 9 Gy. X irradiation had no effect on the degradation of collagen as assessed by collagenase activity in lung. The ratio of type I to type III collagen, analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis of collagen-derived cyanogen bromide peptides, was the same in irradiated lungs as in age-matched controls. Therefore, increased synthesis of procollagen, rather than decreased degradation of collagen or changes in collagen type, is an important factor in the accumulation of collagen in irradiated lung.     

Failure of mineralized collagen fibrils: modeling the role of collagen cross-linking

Experimental evidence demonstrates that collagen cross-linking in bone tissue significantly influences its deformation and failure behavior yet difficulties exist in determining the independent biomechanical effects of collagen cross-linking using in vitro and in vivo experiments. The aim of this study is to use a nano-scale composite material model of mineral and collagen to determine the independent roles of enzymatic and non-enzymatic cross-linking on the mechanical behavior of a mineralized collagen fibril. Stress–strain curves were obtained under tensile loading conditions without any collagen cross-links, with only enzymatic cross-links (modeled by cross-linking the end terminal position of each collagen domain), or with only non-enzymatic cross-links (modeled by random placement of cross-links within the collagen–collagen interfaces). Our results show enzymatic collagen cross-links have minimal effect on the predicted stress–strain curve and produce a ductile material that fails through debonding of the mineral–collagen interface. Conversely, non-enzymatic cross-links significantly alter the predicted stress–strain response by inhibiting collagen sliding. This inhibition leads to greater load transfer to the mineral, which minimally affects the predicted stress, increases modulus and decreases post-yield strain and toughness. As a consequence the toughness of bone that has more non-enzymatically mediated collagen cross-links will be drastically reduced.     

Determination of the relationship between collagen cross-links and the bone-tissue stiffness in the porcine mandibular condyle

Although bone-tissue stiffness is closely related to the degree to which bone has been mineralized, other determinants are yet to be identified. We, therefore, examined the extent to which the mineralization degree, collagen, and its cross-links are related to bone-tissue stiffness. A total of 50 cancellous and cortical bone samples were derived from the right mandibular condyles of five young and five adult female pigs. The degree of mineralization of bone (DMB) was assessed using micro-computed tomography. Using high-performance liquid chromatography, we quantified the collagen content and the number of cross-links per collagen molecule of two enzymatic cross-links: hydroxylysylpyridinoline (HP) and lysylpyridinoline (LP), and one non-enzymatic cross-link: pentosidine (Pen). Nanoindentation was used to assess bone-tissue stiffness in three directions, and multiple linear regressions were used to calculate the correlation between collagen properties and bone-tissue stiffness, with the DMB as first predictor. Whereas the bone-tissue stiffness of cancellous bone did not differ between the three directions of nanoindentation, or between the two age groups, cortical bone-tissue stiffness was higher in the adult tissue. After correction for DMB, the cross-links studied did not increase the explained variance. In the young group, however, LP significantly improved the explained variance in bone-tissue stiffness. Approximately half of the variation in bone-tissue stiffness in cancellous and cortical bone was explained by the DMB and the LP cross-links and thus they cannot be considered the sole determinants of the bone-tissue stiffness.     

Glycated collagen cross-linking alters cardiac mechanics in volume-overload hypertrophy

Alteration of hemodynamic loading induces remodeling that includes changes in myocardial properties and extracellular matrix structure. We investigated the hypothesis that cardiac hypertrophy due to volume overload produces changes in myocardial diastolic mechanics and stiffness that are in part due to alterations in advanced glycation end-product (AGE) collagen cross-linking. Rats developed volume overload induced by arteriovenous fistula (AVF). To assess the dependence of AGE cross-linking on mechanics, we prevented AGE formation by administering the drug aminoguanidine (AG) to one group of AVF rats (AG+AVF). Volume overload did not modify collagen concentration. Right ventricular AGE cross-links were modestly elevated in AVF hearts but were significantly reduced by AG. AVF rats exhibited significantly increased septal AGE cross-links that were inhibited in the AG+AVF group. AVF-induced increases in left ventricular longitudinal stiffness and septal circumferential stiffness were prevented in AG+AVF hearts. Volume overload appears to regionally modify AGE collagen cross-linking and stiffness, and AG treatment prevented these increases, demonstrating that AGE cross-linking plays a role in mediating diastolic compliance in volume-overload hypertrophy.     

Cervical softening during pregnancy: regulated changes in collagen cross-linking and composition of matricellular proteins in the mouse

A greater understanding of the parturition process is essential in the prevention of preterm birth, which occurs in 12.7% of infants born in the United States annually. Cervical remodeling is a critical component of this process. Beginning early in pregnancy, remodeling requires cumulative, progressive changes in the cervical extracellular matrix (ECM) that result in reorganization of collagen fibril structure with a gradual loss of tensile strength. In the current study, we undertook a detailed biochemical analysis of factors in the cervix that modulate collagen structure during early mouse pregnancy, including expression of proteins involved in processing of procollagen, assembly of collagen fibrils, cross-link formation, and deposition of collagen in the ECM. Changes in these factors correlated with changes in the types of collagen cross-links formed and packing of collagen fibrils as measured by electron microscopy. Early in pregnancy there is a decline in expression of two matricellular proteins, thrombospondin 2 and tenascin C, as well as a decline in expression of lysyl hydroxylase, which is involved in cross-link formation. These changes are accompanied by a decline in both HP and LP cross-links by gestation Days 12 and 14, respectively, as well as a progressive increase in collagen fibril diameter. In contrast, collagen abundance remains constant over the course of pregnancy. We conclude that early changes in tensile strength during cervical softening result in part from changes in the number and type of collagen cross-links and are associated with a decline in expression of two matricellular proteins thrombospondin 2 and tenascin C.     

Dynamics of structural parameters of mast cells and accumulation of collagen fibers during radiation-induced pneumosclerosis in rats (a quantitative study)

The methods of stereometry were used to study dynamics of accumulation of collagen fibres and alteration of the number, sizes and state of mast cells of rat lung during the period of 12 months after single local X-irradiation with doses of 10, 14.3 and 20 Gy. A statistically significant correlation between the number of mast cells and spatial density of collagen fibres in the exposed pulmonary tissue was shown. Severity of changes in the structural characteristics of mast cells and the degree of collagen fibres accumulation were a function of radiation dose.     

A semiquantitative probe for radiation-induced normal tissue damage at the molecular level

Sheep antibodies to bovine type I collagen were employed in the immunohistochemical detection of type I collagen in lung tissue sections of irradiated LAF1 mice. A video image digitizing system was developed to estimate collagen levels, by assigning a numerical value (0-63) to each of approximately 53,800 picture elements (pixels) in the microscope field, according to the collagen-dependent fluorescence intensity at each locus. For lungs harvested 52 weeks subsequent to graded doses of 60Co gamma radiation between 0 and 10 Gy, a dose-dependent increase in type I collagen was observed in the alveolar walls. A reproducible increase was evident for doses as low as 5 Gy: doses of 7 to 10 Gy elicited type I collagen levels significantly elevated with respect to those of age-matched controls. These results are consistent with a role for type I collagen in the development of radiation-induced pulmonary fibrosis. The assay system developed here will be used to explore the role of connective tissue macromolecules in the development of radiation pneumonitis and fibrosis.     

Radiation-induced changes in collagen isotypes I, III, and IV in the lung of LAF1 mouse: effects of time, dose, and WR-2721

Alterations in the amount and distribution of pulmonary connective tissue are commonly observed subsequent to thoracic radiotherapy. The extent to which these changes are important in the expression of radiation damage and its repair remains unclear. We have quantitated changes in the parenchymal levels of collagen types I, III, and IV in the lungs of LAF1 mice at intervals to 1 year, following doses of 0-14 Gy, 300 kV X rays, or 0-18 Gy in the presence of the radioprotective compound, WR-2721. The method of quantitation, which involves video image analysis of fluorescent antibody stained, cryostat tissue sections, provides both quantitative and morphological information for the three collagen isotypes. Type I collagen peaked in tissue content at 15 and 30 weeks postirradiation (p.i.), with transient return to control values 20-25 weeks p.i. Type III collagen peaked at 15 and 25 weeks p.i. and declined in tissue content at 20 and 30 weeks. Type IV peaked 15-20 weeks following irradiation, returned to control levels at 25 weeks, and reached a plateau above control values after 30 weeks. Fluctuations in collagen levels in the parenchyma were dose dependent but were not simultaneous, indicating a radiation response characterized by alpha-chain-specific regulation of collagen biosynthesis and breakdown. In general, WR-2721, which enhanced postirradiation survival (DMF, 1.3), reduced the magnitude and altered the timing of collagen fluctuations; again, the effects were type specific. The results clearly demonstrate that the postirradiation response of the connective tissue is dose dependent, is specific to each macromolecule, and involves both deposition and removal of extracellular matrix. These processes are independently influenced by the presence during irradiation of WR-2721.     

Stable, nonreducible cross-links of mature collagen.

During in vivo maturation, and also during in vitro incubation with physiological buffers, native collagen fibers display a progressive increase in tensile strength and insolubility. Paralleling these physiologically important changes is a progressive loss of the reducible cross-links which initially join the triple-chained subunits of collagen fibers. Although there is evidence suggesting that the reducible cross-links are gradually transformed into more stable, nonreducible cross-links during maturation, the nature of the transformation process and the structure of the stable "mature" cross-links has remained a mystery. In order to test the possibility that cross-link transformation involves addition of a nucleophilic amino acid residue to the reducible cross-links, histidine, arginine, glutamate, aspartate, lysine, and hydroxylysine residues were chemically modified, and the effect of each modification procedure on the in vitro transformation of reducible cross-links was ascertained. The results of these experiments indicated that destruction of histidine, arginine, glutamate, and aspartate residues has no measurable effect on the rate and extent of reducible cross-link transformation in hard tissue collagens. In contrast, modification of lysine and hydrocylysine residues with a wide variety of specific reagents completely blocks the transformation of reducible cross-links. Removal of the reversible blocking groups from lysine and hydroxlylysine residues then allows the transformation to proceed normally. These results indicate that collagen maturation involves nucleophilic addition of lysine and/or hydroxylysine residues to the electrophilic double bond of the reducible cross-links, yielding derivatives which are not only more stable but also capable of cross-linking more collagen molecules than their reducible precursors.     

Cross-linking connectivity in bone collagen fibrils: the COOH-terminal locus of free aldehyde.

Quantitative analyses of the chemical state of the 16c residue of the alpha 1 chain of bone collagen were performed on samples from fetal (4-6-month embryo) and mature (2-3 year old) bovine animals. All of this residue could be accounted for in terms of three chemical states, in relative amounts which depended upon the age of the animal. Most of the residue was incorporated into either bifunctional or trifunctional cross-links. Some of it, however, was present as free aldehyde, and the content increased with maturation. This was established by isolating and characterizing the aldehyde-containing peptides generated by tryptic digestion of NaB3H4-reduced mature bone collagen. We have concluded that the connectivity of COOH-terminal cross-linking in bone collagen fibrils changes with maturation in the following way: at first, each 16c residue in each of the two alpha 1 chains of the collagen molecule is incorporated into a sheet-like pattern of intermolecular iminium cross-links, which stabilizes the young, nonmineralized fibril as a whole. In time, some of these labile cross-links maturate into pyridinoline while others dissociate back to their precursor form. The latter is likely due to changes in the molecular packing brought about by the mineralization of the collagen fibrils. The resultant reduction in cross-linking connectivity may provide a mechanism for enhancing certain mechanical characteristics of the skeleton of a mature animal.     

Cross-linking and fluorescence changes of collagen by glycation and oxidation

The non-enzymatic glucosylation of collagen in vivo and in vitro produces blue-fluorescent cross-links very slowly. The mechanism of their formation is unknown. We investigated the role of oxidation in glycation. When native fluorescent collagen from old-rat tail tendon and its CNBr peptides were oxidized by chemically generated singlet oxygen, cross-linking occurred immediately, and the cross-linked products showed an increased blue fluorescence. Further cross-linking and development of blue fluorescence also were accelerated by singlet oxygen when oxidizing in vitro glucosylated collagen CNBr peptides. It was noted that the blue fluorescence developed at the expense of a near-UV fluorescence. This near-UV fluorophore, which is also present in native collagen, was found to be produced by the in vitro glucosylation of collagen and during the cross-linking by glucosylation was slowly converted to the blue fluorophore. These changes indicate the autoxidation of near-UV fluorescent intermediates to blue fluorescent cross-links during glucosylation. Non-enzymatic fructosylation, which occurs in vivo in certain proteins, was more effective than glucosylation in forming fluorophores and cross-links with collagen in vitro. Fructosylated fluorophores were found different from glucosylated products in their oxidation reactivities with singlet oxygen.     

The nature of the collagen cross-links in bone in the chronic uraemic state.

The cross-links from NaB3H4-reduced bone collagen of chronically uraemic rats and pairfed controls were compared. The ratio of the reduced cross-links deltadelta'-dihydroxylysinonorleucine to delta-hydroxylysinonorleucine was significantly increased in the uraemic animals. The observed increment in the dihydroxylysinonorleucine:hydroxylysinonorleucine ratio was accentuated as the uraemic state advanced. The data indicate that osteodystrophy of chronic renal insufficiency is characterized by an alteration of the quantitative relations between cross-links and aldehydic precursors of bone collagen.     

Effect of chronic ionizing irradiation on the structural properties of the apical and mitochondrial membranes of small intestine enterocytes

The different ways of the radiation-induced effect were revealed in the investigations of chronic ionizing radiation influence in total doses of 0.3, 0.6 and 1.0 Gy (0.0072 Gy/day) on the structural properties of the apical and of the mitochondrial membranes of small intestine enterocytes. The modification of the physical properties of the membrane surface area, the decrease of the structural order of the lipid component and conformational changes of the proteins were shown to be specific for the apical membrane. The disturbance of the dynamic properties and topography of the internal mitochondria membrane was revealed in the investigation of the inductive-resonance energy transfer between the pairs of the fluorophores: tryptophan-pyrene, tryptophan-ANS, pyrene-ANS.     

Radiation modification of the ATPase properties of submitochondrial particles

The appreciable changes in hydrophobic properties of ATPase of rat liver submitochondrial particles were discovered 3 days after whole-body X-irradiation with a dose of 7 Gy. The sensitivity of ATPase activity to stimulating anions decreased. The radiation damages to ATPase were detected and the ratio of concentrations of magnesium and ATP exceeded a unity.     

The effects of leucocyte elastase on the mechanical properties of adult human articular cartilage in tension

The effects of leucocyte elastase on the tensile properties of adult human articular cartilage were examined in detail in 99 specimens from hip, knee and ankle joints in the age range 16–83 years. The results showed that elastase reduced the tensile stiffness of cartilage, both at low stress and at fracture. The tensile strength of cartilage was also considerably reduced by the action of elastase. Biochemical analysis of the incubation media, and the specimens, revealed that 90%, or more, of the proteoglycan was released from the cartilage, whilst the release of collagen was negligible. Leucocyte elastase is known to degrade the non-helical terminal peptides of cartilage collagen molecules and thereby disrupt the main intermolecular cross-links in collage fribrils. A previous study (Kempson, G.E., Tuke, M.A., Dingle, J.T., Barrett, A.J. and Horsfield, P.H. (1976) Biochim. Biophys. Acta 428, 741–760) showed the lack of effect of proteoglycan degradation alone on the tensile strength and stiffness of cartilage. The reduction in strength and stiffness recorded in the present study can, therefore, be attributed to the action of elastase on the collagen in cartilage and it emphasises the important of covalent intermolecular cross-links to the mechanical properties of collagen fibrils.