Collagen crosslinks and their relationship to the thermal properties of calf tendons

The hydrothermal isometric tension and thermal transition temperature of collagen were determined in tendons from three different calf muscles. The levels of the nonreducible collagen crosslink, pyridinoline, and the collagen-associated Ehrlich chromogen were also measured in the three tendons. The reducible collagen crosslinks, hydroxylysinonorleucine, dihydroxylysinonorleucine, and histidinohydroxymerodesmosine were measured in two tendons. The thermal properties and levels of crosslinks were found to vary considerably between the different tendons, and also at different sites in two of the tendons. A strong correlation was observed between the thermal transition temperatures and the hydrothermal isometric tensions of the nine tendon sites examined. Both thermal properties correlated with the concentration of both pyridinoline and Ehrlich chromogen. The analogous behavior of the collagen-associated Ehrlich chromogen and the pyridinoline crosslink supports the role of the Ehrlich chromogen as a nonreducible crosslink.     

Cross-linking of collagen in the X-linked Ehlers-Danlos Type V.

The activity and antigenicity of the collagen crosslinking enzyme, lysyl oxidase, and the proportions of reducible crosslink in skin biopsies from Ehlers-Danlos Type V subjects were equivalent to those of control skin. These results reveal that both the potential for crosslinking, and the ability to form reducible crosslinks is present in Ehlers-Danlos syndrome Type V subjects, clearly demonstrating that the defect in this disorder is not due to a defective crosslinking mechanism.     

Aldol-histidine,a new trifunctional collagen crosslink

A new trifunctional crosslink, 2,10-diamino-5-hydroxymethyl-6-(N-1-histidyl)-undecandioic acid, termed aldol-histidine, was isolated from borohydride reduced cow skin insoluble collagen. The compound was characterized by pmr spectroscopy and mass spectrometry of several volatile derivatives. The crosslink may be derived from Michael addition of a histidine residue to the known aldol crosslink, 2,10-diamino-5-formyl-5-undecandioic acid. This is the first example of a histidine containing crosslink found in structural protein.     

Lysyl oxidase-mediated crosslinking in granulation tissue collagen in two models of hyperglycemia

Enzymatically mediated crosslinks and nonenzymatic glycation were quantified in granulation tissue collagen in two models of hyperglycemia, diabetes and galactosemia, that have opposite effects on collagen solubility. The effects of castration, which alters collagen solubility, was also investigated. Collagen from both diabetic and galactosenic rats had significantly increased levels of dihydroxylysinonorleucine (DHLNL), a difunctional reducible crosslink. Galactosemic rats had significantly decreased levels of hydroxypyridinium, a trifunctional product of DHLNL and hydroxylyse, relative to control values, while diabetic rats had normal levels. Values for all other detectable crosslinks in collagen from hyperglycemic rats were indistinguishable from control values. Nonezymatic glycation was increased in both groups of hyperglycemic rats. In diabetic rats, but not in galactosemic rats, nonenzymatic glycation was strongly correlated DHLNL content. Castration had no effect on crosslink content of collagen from diabetic or galactosemic rats. This study demonstrates that (1) collagen crosslinking is abnormal in granulation tissue collagen in both experimental diabetes and galactosemia, (2) these changes are similar to those observed in skin collagen from insulin-dependent diabetic subjects and (3) the crosslinking abnormalities are not correlated with alterations in collagen solubility. We conclude that hyperglycemia-associated increases in immature crosslinks cannot acount for altered collagen solubility, although impaired maturation of such crosslinks may be partially responsible for the lathyrogenic effect of galactosemia.     

Lysyl oxidase-mediated crosslinking in granulation tissue collagen in two models of hyperglycemia.

Enzymatically mediated crosslinks and nonenzymatic glycation were quantified in granulation tissue collagen in two models of hyperglycemia, diabetes and galactosemia, that have opposite effects on collagen solubility. The effects of castration, which alters collagen solubility, was also investigated. Collagen from both diabetic and galactosemic rats had significantly increased levels of dihydroxylysinonorleucine (DHLNL), a difunctional reducible crosslink. Galactosemic rats had significantly decreased levels of hydroxypyridinium, a trifunctional product of DHLNL and hydroxylysine, relative to control values, while diabetic rats had normal levels. Values for all other detectable crosslinks in collagen from hyperglycemic rats were indistinguishable from control values. Nonenzymatic glycation was increased in both groups of hyperglycemic rats. In diabetic rats, but not in galactosemic rats, nonenzymatic glycation was strongly correlated with DHLNL content. Castration had no effect on crosslink content of collagen from diabetic or galactosemic rats. This study demonstrates that (1) collagen crosslinking is abnormal in granulation tissue collagen in both experimental diabetes and galactosemia, (2) these changes are similar to those observed in skin collagen from insulin-dependent diabetic subjects and (3) the crosslinking abnormalities are not correlated with alterations in collagen solubility. We conclude that hyperglycemia-associated increases in immature crosslinks cannot account for altered collagen solubility, although impaired maturation of such crosslinks may be partially responsible for the lathyrogenic effect of galactosemia.     

The structure of pyridinoline,a collagen crosslink

Pyridinoline is an amino acid isolated from collagen and probably serves as a crosslink in collagen fiber. This compound was isolated on a large scale from bovine bone and investigated by ¹H-nmr and ¹³C-nmr spectroscopy, mass spectroscopy and chemical degradation. The structure is proposed on the basis of these data.     

Isolation and characterization of a fluorescent material in bovine achilles tendon collagen

A fluorescent material in bovine achilles tendon collagen was isolated and characterized by ultraviolet spectroscopy, fluorescence spectroscopy and nmr spectroscopy. The data suggest that the compound is a 3-hydroxypyridinium derivative with three amino acid side chains. The name “pyridinoline” is proposed. Pyridinoline is a novel type crosslink of collagen.     

On the dielectric behaviour of collagen-algal sulfated polysaccharide blends: effect of glutaraldehyde crosslinking

In this paper, impedance measurements in the frequency range from 10(-2) to 10(6) Hz are presented for collagen and algal sulfated polysaccharide crosslinked films. We are considering the development of new biomaterials which have potential applications in coating of cardiovascular prostheses, support for cellular growth and in systems for controlled drug delivery. The effect of crosslink sulfated polysaccharide on the physical chemical properties of collagen was studied using FT-infrared spectroscopy, differential scanning calorimetry (DSC), dielectric spectroscopy. The resulting films crosslinked with glutaraldehyde (GA) in concentrations of 0.001% and 0.05% when analysed by DSC, showed that the GA treatment not only left the thermal stability of the collagen unaffected, but it also decreased the thermal transition energy. Dielectric spectroscopy shows that the effect of the crosslink on the blend film was associated to the decrease and stabilization of the dielectric permittivity at low frequencies and decreased its conductivity.     

Biosynthesis of collagen crosslinks in rabbit articular cartilage in vivo

The biosynthesis in vivo of the two reducible aldimine crosslinks of immature rabbit articular collagen, hydroxylysinohydroxynorleucine and hydroxylysinonorleucine, is demonstrated. The peak amount of crosslink was detected 1–2 weeks following labeling of the cartilage with [¹⁴C]lysine. The subsequent diminution which occurred was due primarily to a decrease in the amount of hydroxylysinohydroxynorleucine. Natural reduction of the aldimine crosslinks in vivo did not occur. Glucosylgalactosyl hydroxylysine and galactosylhydroxylysine, in a $\text{1.45}\text{1.00}$ ratio, were synthesized. Seventy-three percent of the hydroxylysine residues were glycosylated. [³H]NaBH₄ reduction of non-¹⁴C-labeled cartilage showed diminished amounts of reducible crosslink with time and the presence of hexosyl lysines and hexosyl hydroxylysines in mature articular cartilage.     

The changes in crosslink contents in tissues after formalin fixation

The aim of this study was to detect crosslinks of collagen and elastin in formalin-fixed tissue, to perform quantification of these crosslinks, and to investigate the effects of formalin fixation on crosslink contents in human yellow ligament and cartilage. Pyridinoline (Pyr) is a stable and nonreducible crosslink of collagen. Pentosidine (Pen) is a senescent crosslink formed between arginine and lysine in matrix proteins, including collagen. Desmosine (Des) and its isomer isodesmosine (Isodes) are crosslinks specifically found in elastin. It is useful to measure crosslink contents of collagen and elastin as a way of investigating the properties of various tissues or their pathological changes. If it is possible to evaluate crosslinks of collagen and elastin in formalin-fixed tissues, we can investigate crosslinks in a wide variety of tissues. We used HPLC to compare the concentrations of Pyr, Pen, Des, and Isodes in the formalin-fixed tissues with their concentrations in the frozen tissues. Pyr and Pen were detected in both the formalin-fixed yellow ligament and the cartilage, and their concentrations were not significantly affected by or related to the duration of formalin fixation. Des and Isodes were detected in the formalin-fixed yellow ligament but in significantly lower amounts compared to the frozen samples. We concluded that crosslinks of collagen were preserved in formalin, but crosslinks of elastin were not preserved in it. The reason for this might be that formalin did not fix elastin tissues sufficiently or it destroyed, masked, or altered elastin crosslinks.     

Thermomechanical analysis of collagen crosslinking in the developing ovine thoracic aorta

We have used hydrothermal isometric tension (HIT) techniques in a sheep model to assess collagen crosslink stability and its contribution to the mechanical properties of the ovine thoracic aorta during perinatal and postnatal development. Aortic tissue was studied from fetal sheep, lambs, and adult sheep. Strips of tissue were loaded under isometric tension and heated to a 90 degrees C isotherm which was sustained for 3 hours. The decrease in load at this temperature is associated with collagen peptide bond hydrolysis and chain slippage, and the rate of this decrease is an inverse indicator of collagen crosslinking. The half-time of load decay (t1/2) was computed before and after tissue was treated with NaBH4 which stabilizes immature, reducible crosslinks. We observed a two-fold increase in t1/2 of untreated tissue from the lamb to the adult, indicating that aortic collagen crosslinking increased during postnatal development. Furthermore, the t1/2 of NaBH4-stabilized lamb tissue was similar to that of the untreated adult tissue, suggesting that much of the immature crosslinking in the lamb is stabilized during postnatal development. These observations suggest (a) increased crosslinking occurs during postnatal development and (b) that this increase is largely due to a conversion of immature crosslinks into their mature heat stable form.     

Analysis of age-associated changes in collagen crosslinking in the skin and lung in monkeys and rats

The present study was designed to address a specific question: can we define collagen aging in vivo in terms of alterations in collagen crosslinking? In order to assess the complete spectrum of change throughout life, tissues from rats, monkeys and (where available) humans were examined at ages ranging from fetal to old. Skin and lung were selected in order to include all of the crosslinks derived from lysyl oxidase-generated aldehydes that have been identified thus far, both reducible and nonreducible. Crosslinks analyzed included hydroxylysinonorleucine, dihydroxylysinorleucine, histidinohydroxymerodesmosine, hydroxypyridinium, lysyl pyridinium, and a deoxy analogue of hydroxypyridinium found in skin that differs structurally from lysyl pyridinium. Tissues from both a short-lived species (rats) and a long-lived species (monkeys) were analyzed to test further the hypothesis that changes in crosslinking are linked predominantly to biological age of the animal, rather than temporal aging. We found that biological aging seems to regulate certain predictable changes during the first part of the lifespan: the disappearance postnatally of dihydroxylysinonorleucine in skin, the rapid decrease in difunctional crosslink content in lung and skin during early growth and development, and the gradual rise in hydroxypyridinium and lysyl pyridinium in lung tissue. Changes in crosslinking were far less predictable during the second half of the lifespan. Although hydroxypridinium content continued to rise or reached a plateau in rat and monkey lungs, respectively, it showed a decrease in human lungs. The analogous trifunctional crosslink in skin, the so-called 'pyridinoline analogue', decreased dramatically in both rats and monkeys in later life. Our data suggest that caution must be taken in drawing inferences about human connective tissue aging from experiments performed in short-lived species such as rodents. Furthermore, the finding that there may be fewer total lysyl oxidase-derived crosslinks per collagen molecule in very old animals as compared with young animals suggests that we may need to expand our concepts of collagen crosslinking.     

The separation and amino acid analysis of collagen crosslinks on an extended basic ion-exchange column

The major reducible crosslinks found in collagen were separated and analyzed on an extended basic amino acid analyzer column. Reaction with ninhydrin allows the direct analysis of collagen crosslinks, including hydroxyaldol-histidine, a naturally occurring, nonreducible crosslink. In addition to known crosslinks, direct amino acid analysis of tissue hydrolysates reveals the presence of an unknown, ninhydrin-reactive component, in both NaB³H₄-reduced and unreduced collagenous tissues. Initial fractionation of hydrolysates on a Bio-Gel P-2 gel filtration column provides partial separaton of amino acids and crosslinks and enables more direct analysis of the crosslinks present in the samples, as well as detecting potential new crosslinks. The results also show that, prior to NaB³H₄ reduction, substantial amounts of known crosslinks are normally present in bovine skin and bone.     

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.     

Effects of singlet oxygen on the extracellular matrix protein collagen: oxidation of the collagen crosslink histidinohydroxylysinonorleucine and histidine

The reaction of singlet oxygen, a putative agent of skin photodamage, with the dermal collagen crosslink histidinohydroxylysinonorleucine (HHL) and its precursor histidine is reported. Reaction studies were performed with both purified HHL and bovine dermal tissue. We demonstrate that singlet oxygen can selectively oxidize HHL and histidine amino acid residues in dermal tissue and that intermediate oxidation products of histidine lead to new crosslink products. A novel mechanism for crosslink formation was proposed to involve nucleophilic addition to a transient imidazolone intermediate formed from singlet oxygen oxidation of the histidine imidazole moiety. The implication for such adduct formation and histidine oxidation in collagen proteins is the expression of aberrant collagen crosslinks, perturbation of the dermal collagen function, and hence an altered dermal state.     

The hydroxypyridinium crosslinks of skeletal collagens: Their measurement,properties and a proposed pathway of formation

A method is described for quantifying both reducible and mature crosslinking amino acids of collagen. The main crosslinking residue in cartilage, dentine and mature bone was the 3-hydroxypyridinium compound identified by Fujimoto et al. (1–3). Adult articular cartilage contained about one residue per collagen molecule, over forty times the content of the reducible crosslinks. We propose that hydroxypyridinium residues are formed by spontaneous interaction of two residues of hydroxylysino-5-ketonorleucine. This reaction explains the disappearance of reducible crosslinks at maturity and provides a novel mechanism for lateral crosslinking within and between fibrils which may account for some of the unique physical properties of hard tissue collagens.     

Collagen cross-linking. Synthesis of collagen cross-links in vitro with highly purified lysyl oxidase.

In this paper, the synthesis of collagen cross-links in vitro was investigated in a defined system consisting of highly purified chick cartilage lysyl oxidase and chick bone collagen fibrils. Cross-link synthesis in vitro was quite similar to the biosynthesis of collagen cross-links in vivo. Enzyme-dependent synthesis of cross-link intermediates and cross-linked collagen derived from lathyritic collagen occurred. The concentration of the two principal reducible cross-links, N6:6'-dehydro-5,5'-dihydroxylysinonorleucine and N6:6'-dehydro-5-hydroxylysinonorleucine, increased to a peak value of approximately two cross-links per molecule and then decreased. Synthesis of histidinohydroxymerodesmosine and a second polyfunctional cross-link of unknown structure began after synthesis of bifunctional cross-links was largely completed and proceeded linearly afterwards. Inhibition of lysyl oxidase after the bulk of bifunctional cross-link synthesis had occurred did not alter the rate of decrease in reducible cross-link concentration but did inhibit further histidinohydroxymerodesmosine synthesis. These results indicate that lysyl oxidase and collagen fibrils are the only macromolecules required for cross-link biosynthesis in vivo. It is likely that the decrease in reducible cross-links observed during fibril maturation results from spontaneous reactions within the collagen fibril rather than additional enzymatic reactions.     

Crosslinking in type III collagen of fetal tissue.

Native bovine amnion tissue was reduced with NaB³H₄ and type III collagen was isolated by pepsin digestion. Examination of the crosslink content of type III collagen following acid hydrolysis revealed the presence of dihydroxy- and hydroxylysinonorleucine in a ratio of 9 to 1. Approximately 80% of the dihydroxylysinonorleucine exists as the glucosyl-galactosyl derivative following alkaline hydrolysis. Less than 2% of the incorporated tritium of amnion tissue is released by pepsin digestion and over 70% of this is accounted for by the crosslink precursors hydroxy- and dihydroxynorleucine.     

Reversible inactivation of soluble liver guanylate cyclase by disulfides

A new amino acid was isolated from the cuticle collagen of $\text{Ascaris lumbricoides}$ and characterized by ultraviolet, mass and nmr spectroscopies and chemical degradation. The results indicate that the compound is an isomer of trityrosine, having an ether linkage. The name “isotrityrosine” is proposed. Its structure suggests that it serves as a crosslink and plays a role in the organization of the collagen structure.