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.     

Collagen type IX: Evidence for covalent linkages to type II collagen in cartilage

A major site of pyridinoline cross-linking in bovine type IX collagen was traced to a tryptic peptide derived from one of the molecule's HMW chains. This peptide gave two amino acid sequences (in 2/1 ratio) consistent with it being a three-chained structure. The major sequence matched exactly that of the C-telopeptide of type II collagen from the same tissue. A second HMW chain that contained pyridinoline cross-links also gave two amino-terminal sequences, one from its own amino terminus, the other matching exactly the N-telopeptide cross-linking sequence of type II collagen. We conclude that type IX collagen molecules are covalently cross-linked in cartilage to molecules of type II collagen, probably at fibril surfaces.     

Non-enzymatic glycosylation induced changesin vitro in some molecular parameters of collagen

Non-enzymatic glycosylation of rat tail tendon collagen was examined by incubation with D-glucosein vitro. The changes in molecular parameters such as viscosity, thermal stability, electrophoretic mobility and solubility were determined on nonenzymatically glycosylated collagenin vitro. Tendons incubated with 8 and 24 mg glucose/ml showed an increase in dissolution temperature and a l.6-3-fold increase in thermal isometric tension respectively when compared to tendons incubated in the absence of glucose, indicating the formation of new intermolecular bonds. This conclusion was further supported by the decreased solubility of glycosylated collagen in 0.5 N acetic acid and the change in sub-unit composition as measured from the sodium dodecyl sulphate Polyacrylamide gel electrophoresis pattern. Glycosylated collagen gave a characteristic absorption spectra λ_max 248 nm) as distinct from that of control (λ_max 242 nm). Denaturation temperature of glycosylated collagen, as determined from temperature dependent viscosity measurements, was reduced. These studies indicate that glycosylation affects the molecular interactions as well as the crosslinking of collagen.     

Collagen cross-linking. Effect of D-penicillamine on cross-linking in vitro.

D-Pencillamine is believed to inhibit collagen cross-link biosynthesis by forming thiazolidine rings with lysyl-derived aldehydes that are intermediates in bifunctional cross-link synthesis. Recently, we showed that aldehyde biosynthesis catalyzed by lysyl oxidase occurs after the onset of fibril formation and that nascent aldehydes form Schiff-base cross-links rapidly in fibrils. This suggested that the accessibility of D-penicillamine to most aldehydes formed during cross-link synthesis might be limited. To study this, reconstituted chick bone collagen fibrils were incubated in vitro with highly purified lysyl oxidase and D-penicillamine. As reported in previous studies in vivo, allysine content increased and polyfunctional cross-link synthesis decreased with D-penicillamine. However, the concentration of bifunctional cross-links increased rather than decreased due to a 2-fold increase in N6:6'-dehydro-5,5'-dihydroxylysinonorleucine. Hydroxyallysine, an intermediate in formation of this Schiff base, decreased. A time study indicated that allysine levels increased primarily after the bulk of Schiff base synthesis. These results indicate that D-penicillamine does not inhibit bifunctional cross-link synthesis as previously suggested. Its principal effect is to block synthesis of polyfunctional cross-link products from Schiff base cross-link precursors and to cause accumulation of these precursors. This effect may be due to interference with the close molecular packing required for polyfunctional cross-link synthesis. These results also suggest a mechanism for the relative insensitivity of tissues such as bone with high hydroxylysine content to D-penicillamine. In this study, D-penicillamine caused selective accumulation of allysyl and not hydroxyallysyl residues. In bone as opposed to soft tissues, hydroxyallysyl residues are intermediates in synthesis of almost all cross-links.     

Bovine tendons. Aging and collagen cross-linking

The level of cross-linking between the polypeptide chains of the collagen molecules in bovine tendons of different ages has been assessed by measuring quantitatively through densitometry the changes in the ratios of individual cyanogen bromide peptides separated on polyacrylamide gels. An increase in the number of cross-links in mature, as compared to young, tendons correlates with a depletion in the proportion of the free, COOH-terminal peptides alpha1-CB6 and alpha2-CB3,5 and with an increase in a broad distribution of peptides moving slowly in the gels: these peptides are not seen in digests of acid-soluble collagen. Some of these peptides which are presumably cross-linked migrate more slowly than beta components and collagen alpha chains and are apparently of a higher molecular weight. No increase in cross-linked peptides is detectable beyond the age of maturation; this analysis refutes, at least in this tissue, the common presumption that progressive cross-linking occurs in collagen through an animal's lifetime.     

The timecourse of collagen cross-linking

The incorporation of [³H] proline into all major denaturation subunits of acid-extractable skin collagen was followed in vivo over a period of 30 days in young male rats. The radioactivity was incorporated into the α₁ and α₂ subunits at an equal rate. It was then transferred to the β subunits, the ratio of specific activity of α:β becoming unity at about 17 days. No transfer of radioactivity from β to γ collagen was seen during the 30 days of the experiment indicating that β units do not cross-link further to γ during this time. A separate group of rats made lathyritic with β-aminopropionitrile showed a similar rate of collagen cross-linking as reflected by the return of α:β ratios to normal values within about 15 days following the cessation of β-aminopropionitrile administration. In the normal rats radioactive proline was incorporated very rapidly into a fraction of collagen eluted from CM-cellulose with 0.5 M NaCl following the salt gradient. It is proposed that this fraction may represent a fibrogenesis nucleation factor.     

The nonenzymatic glycosylation of collagen

Calf skin acid-soluble collagen, containing about 34 residues of lysine plus hydroxylysine per 100,000 dalton polypeptide chain, was treated with [¹⁴C]glucose in the presence or absence of NaCNBH₃. In 144 h, under the conditions employed, the presence of NaCNBH₃ increased the extent of glycosylation from 8 to 15% of the total residues of lysine plus hydroxylysine. The extent of glycosylation was estimated, using acid hydrolysates of the protein, by isolation and determination of reduced adducts (1-lysinohexitols) employing a system of paper chromatography followed by chromatography on an amino acid analyzer. By those means the difficulties of using specific color reactions such as that with thiobarbituric acid were obviated. Identification of the reduced adducts as forms of 1-lysinohexitol was made by comparison of that substance prepared by treatment of polylysine with [¹⁴C]glucose in the presence of NaCNBH₃. Of interest is the fact that treatment of the polymer with glucose for 144 h under conditions similar to those used for the collagen, resulted in an increase of extent of glycosylation from 3 to about 50% of the total lysine residues when NaCNBH₃ was present in the incubation medium. The greater degree of glycosylation of lysine residues in polylysine as compared with collagen (15 versus about 50%) may be ascribed to the different orders of macromolecular structure in the protein that could sequester certain of the residues from reaction with glucose. 1-Lysinohexitol was also identified in hydrolysates of neutral salt-soluble guinea pig skin collagen that had been reacted with glucose and then treated with NaB³H₄. The glycosylated collagens were fragmented by treatment with CNBr, and modified lysine residues were found to occur along the entire length of the collagen chains. The use of NaCNBH₃ in the manner described above permits measurement of both aldimine and ketoamine forms of the adducts made with glucose. The possible physiological significance of the reversibility of the ketoamine form of adduct is discussed briefly.     

The covalent binding of acetaminophen to protein. Evidence for cysteine residues as major sites of arylation in vitro

Covalent binding of the reactive metabolite of acetaminophen has been investigated in hepatic microsomal preparations from phenobarbital-pretreated mice. Low molecular weight thiols (cysteine and glutathione) were found to inhibit this binding, whereas several other amino acids which were tested did not. Bovine serum albumin (BSA), which contains a single free sulfhydryl group per molecule and which thus represents a macromolecular thiol compound, inhibited covalent binding of the reactive acetaminophen metabolite to microsomal protein in a concentration-dependent manner. The acetaminophen metabolite also became irreversibly bound to BSA in these experiments, although this binding was reduced by approx. 47% when the thiol function of BSA was selectively blocked prior to incubation. Covalent binding of the acetaminophen metabolite to bovine alpha s1-casein, a soluble protein which does not contain any cysteine residues, was found to occur to an extent of 37% of that which became bound to native BSA. These results were taken to indicate that protein thiol groups are major sites of covalent binding of the reactive metabolite of acetaminophen in vitro. The covalent binding characteristics of synthetic N-acetyl-p-benzoquinoneimine (NAPQI), the putative electrophilic intermediate produced during oxidative metabolism of acetaminophen, paralleled closely those of the reactive species generated metabolically. These findings support the contention that NAPQI is indeed the reactive arylating metabolite of acetaminophen which binds irreversibly to protein.     

Aldehyde content and cross-linking of type III collagen.

Three phosphorylated dinucleosides designated HS1, HS2, and HS3, isolated from the water-mould $\text{Achlya}$, were shown to significantly inhibit ribonucleotide reductase activity from $\text{Achlya}$. All three compounds decreased CDP reduction in fungal extracts by 50% at concentrations of 0.1mM. At the same concentration HS3 also inhibited partially purified CDP reductase from Chinese hamster ovary cells by at least 80% but showed only 10% inhibition with enzyme from $\text{E.}\text{coli}$. ADP reductase activity from $\text{Achlya}$ was inhibited 50% by both HS1 and HS3 at 0.1mM. HS2 however, showed no inhibitory effect on purine reduction. The levels of ribonucleotide reductase during the asexual growth cycle of $\text{Achlya}$ correlated with thymidine uptake into DNA and with the synthesis of HS compounds.     

Evidence for non-enzymatic glycosylation in Escherichia coli

Non-enzymatic glycosylation (glycation) is a chain of chemical reactions affecting free amino groups in proteins of long-living eukaryotes. It proceeds in several steps leading to the consecutive formation of Schiff bases, Amadori products and advanced glycation end-products (AGEs). To our knowledge, this process has not been observed in prokaryotes so far. However, the present study provides clear-cut evidence that glycation takes place in bacteria despite their short life span. We have detected AGEs in recombinant human interferon gamma (rhIFN-gamma) produced in Escherichia coli as well as in total protein of the same bacterium using three different approaches: (i) Western blotting using two monoclonal antibodies raised against AGEs; (ii) fluorescent spectroscopy; and (iii) investigation of the effect of known AGE inhibitors (such as acetyl salicylic acid and thiamine) on the glycation reaction. Our study shows that non-enzymatic glycosylation is initiated during the normal growth of E. coli and results in AGE formation even after isolation of proteins. This process seems to be tightly associated with some post-translational modifications observed in the cysteineless rhIFN-gamma, such as covalent dimerization and truncation.     

Enzymatic and nonenzymatic cross-linking of collagen and elastin.

Knowledge regarding the steps and mechanisms related to the intra- and interchain cross-linking of collagen and elastin has evolved steadily during the past 30 years. Recently, effort has been directed at identifying the location and types of cross-links that are found in collagen and elastin. There are two major groups of cross-links: those initiated by the enzyme lysyl oxidase and those derived from nonenzymatically glycated lysine and hydroxylysine residues. The formation of enzymatic cross-links depends on specific enzymes, amino acid sequences, and quaternary structural arrangements. The cross-links that are derived nonenzymatically occur more adventitiously and are important to pathobiological processes. Considerable progress has been made in elucidating the pathways of synthesis for several of the enzymatically mediated cross-links, as well as possible mechanisms regulating the specificity of cross-linking. Although less is known about the chemistry of cross-links arising from nonenzymatically glycated residues, recent progress has also been made in understanding possible biosynthetic pathways and control mechanisms. This review focuses on such progress and hopes to underscore the biological importance of collagen and elastin cross-linking.     

Changes in collagen cross-linking and lysyl oxidase by estrogen.

Dermal collagen solubility and lysyl oxidase activity of bones were measured in DDD mice of advancing age. Insoluble fractions of the dermal collagen increased more rapidly in females than in males after 5 weeks of age. Activity of the lysyl oxidase extracted from bones was higher in females than in males after 4 weeks of age. After sexual maturation, such sex differences were always observed in skin as well as in bone tissue. In other experimental animals, dermal collagen solubility was markedly decreased by estrogen treatment and lysyl oxidase was remarkably activated by estrogen in both skin and bone. Thus it is clear that estrogen stimulates the enzyme activity and accelerates the maturation of collagen and elastin in extracellular space.     

Fe2+-catalyzed non-enzymatic glycosylation alters collagen conformation during AGE-collagen formation in vitro

Advanced glycation end-products (AGEs) are one of the major factors of hyperglycemia related complications for diabetic patients. We studied the formation of AGEs in type I collagen after Fe²⁺-catalyzed non-enzymatic glycosylation in vitro. Type I collagen isolated from rat tail tendon was incubated with glucose and increasing concentrations of iron ions Fe²⁺. After 4 weeks incubation, cytotoxity of AGEs was indicated by the cytotoxity assay of primary human umbilical vein endothelial cells and primary human monocytes cultured with glycosylated collagen AGEs. Fourier transform infrared spectroscopy analysis revealed that structural changes of functional groups in glycosylated collagen are accelerated by the catalyst Fe²⁺. Using two-dimensional Fourier-transform infrared correlation spectroscopy analyses, for the first time, we demonstrated that the order of structural changes of these functional groups is -CH- > Amide I > Amide II > Amide III > ν(CO) the carboxylic group of Asn, Gln or polyproline amino acid residue in the course of AGE-collagen formation. Knowing the positions of these functional groups in collagen, this order of changes indicates that during glycation of collagen, the structure of the main chain residues in collagen changed first, and then the side chain changed gradually, which may lead to more carboxylic groups exposed to glucose for further formation of AGE-collagen irreversibly. The findings presented may support the design of new therapeutic strategies to prevent or slow down the Fe²⁺-catalyzed glycosylation of collagen and other matrix proteins.     

Aging and cross-linking of skin collagen

This report represents a clear demonstration of a cross-link in collagen whose abundance is related to chronological aging of an organism. Recently its structure was identified as histidinohydroxylysinonorleucine. Quantification of the cross-link in various aged samples of bovine and human skin indicate that it rapidly increases from birth through maturation. Subsequently, a steady increase occurs with aging, approaching 1 mole/mole of collagen. This compound seems to be related to the relative proportions of soluble to insoluble collagen from skin in neutral salt, dilute acid, and denaturing aqueous solvents (higher concentration in the insoluble portion). It is absent from other major collagenous tissues such as dentin, bone and tendon.     

The changes in glycosylation after partial hepatectomy enhance collagen binding of vitronectin in plasma

Vitronectin is a multifunctional glycoprotein present in the extracellular matrix and plasma. Changes in rat vitronectin were studied during liver regeneration after partial hepatectomy. Carbohydrate concentrations of vitronectin decreased to 2/3 of sham-operated rats at 24 h after partial hepatectomy. Carbohydrate composition and lectin reactivity indicated that N-glycosylation and sialylation of vitronectin changed markedly after partial hepatectomy, while amino acid composition did not change significantly. We previously showed that deN-glycosylation of vitronectin in vitro affects collagen binding among various ligands (Yoneda et al., Biochemistry (1998) 37, 6351-6360). Vitronectins from partially hepatectomized rats at 24 h were found to exhibit markedly enhanced binding to type I collagen. The effect of sialylation on collagen binding was further examined using enzymatically deglycosylated vitronectin of nonoperated rats. Collagen binding increased by 1.2 times after deN-glycosylation of vitronectin, while it increased more than 2.9 times after desialylation. Various glycosyltransferases in liver are known to change after partial hepatectomy, including the attenuation of N-oligosaccharide transferase. The findings therefore suggest that the collagen binding of vitronectin is modulated by the alteration of peptide glycosylation caused by postoperative physiological changes of glycosyltransferases and that the change may contribute to tissue remodeling processes.     

Degradation and covalent cross-linking of glutathione reductase by hemin

Hemin (ferriprotoporphyrin IX-chloride) can mediate the covalent cross-linking and degradation of yeast glutathione reductase. This reaction requires both NADPH and oxygen suggesting the involvement of a reduced oxygen species in the cross-linking and degradation process. During the course of the reaction the enzymatic activity of glutathione reductase is rapidly destroyed. Implications of these findings for a regulatory role of hemin in cell biology are discussed.     

Role of collagen content and cross-linking in large pulmonary arterial stiffening after chronic hypoxia

Chronic hypoxic pulmonary hypertension (HPH) is associated with large pulmonary artery (PA) stiffening, which is correlated with collagen accumulation. However, the mechanisms by which collagen contributes to PA stiffening remain largely unexplored. Moreover, HPH may alter mechanical properties other than stiffness, such as pulse damping capacity, which also affects ventricular workload but is rarely quantified. We hypothesized that collagen content and cross-linking differentially regulate the stiffness and damping capacity of large PAs during HPH progression. The hypothesis was tested with transgenic mice that synthesize collagen type I resistant to collagenase degradation (Col1a1(R/R)). These mice and littermate controls (Col1a1(+/+)) were exposed to hypoxia for 10 days; some were treated with β-aminopropionitrile (BAPN), which prevents new cross-link formation. Isolated PA dynamic mechanical tests were performed, and collagen content and cross-linking were measured. In Col1a1(+/+) mice, HPH increased both collagen content and cross-linking, and BAPN treatment prevented these increases. Similar trends were observed in Col1a1(R/R) mice except that collagen content further increased with BAPN treatment. Mechanical tests showed that in Col1a1(+/+) mice, HPH increased PA stiffness and damping capacity, and these increases were impeded by BAPN treatment. In Col1a1(R/R) mice, HPH led to a smaller but significant increase in PA stiffness and a decrease in damping capacity. These mechanical changes were not affected by BAPN treatment. Vessel-specific correlations for each strain showed that the stiffness and damping capacity were correlated with the total content rather than cross-linking of collagen. Our results suggest that collagen total content is critical to extralobar PA stiffening during HPH.