Collagen II from articular cartilage and annulus fibrosus

Yang, Chunlin; Rui, Haifeng; Mosler, Stephan; Notbohm, Holger; Sawaryn, A.; Müller, Peter

doi:10.1111/j.1432-1033.1993.tb17881.x

Cited by 48 publications

(35 citation statements)

References 23 publications

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“…5). This is in agreement with the thermal unwinding temperature of soluble collagen type II, which is 41-42 °C (Danielsen, 1982;Yang et al, 1993). This supports the feasibility of aCT to digest de natured collagen selectively.…”

Section: Discussionsupporting

confidence: 75%

A simplified measurement of degraded collagen in tissues: Application in healthy, fibrillated and osteoarthritic cartilage

Bank¹,

Krikken²,

Beekman³

et al. 1997

Matrix Biology

177

149

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Intact triple helical collagen molecules are highly resistant to proteolytic enzymes, whereas degraded (unwound) collagen is easily digested. This fact was exploited to develop a simpli fied method for the quantification of the amount of degraded collagen in the collagen net work of connective tissues. Essentially, the method involves extraction of proteoglycans with 4 M guanidinium chloride, selective digestion of degraded collagen by a-chymotrypsin, hydrolysis in 6 M HC1 of the released fragments as well as the residual tissue, and then mea surement of the amount of hydroxyproline in both pools* Since the digestion of degraded collagen by a-chymotrypsin and measurement of hydroxyproline is not restricted to a sper cific collagen type, this technique can be applied to a wide variety of connective tissues. The method was validated with articular cartilage. Levels of in situ degraded collagen were about four-fold higher in degenerated (fibrillated) cartilage than in its healthy counterpart derived from the same donor. More detailed investi gations revealed that the collagen damage in degenerated cartilage is more extensive at the cartilage surface than in the region adjacent to bone. This was not the case in healthy carti lage; identical low values were obtained at the surface and close to the bone. An impaired collagen network has been hypothesized to be the reason for the swelling of cartilage in os-4 ■* teoarthritis (OA). The present paper presents the first experimental evidence to support this hypothesis: more damage to the collagen network (i.e., more degraded collagen molecules within fibrils) is linearly related to more extensive swelling of the OA tissue in hypotonic saline.

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Section: Discussionsupporting

confidence: 75%

A simplified measurement of degraded collagen in tissues: Application in healthy, fibrillated and osteoarthritic cartilage

Bank¹,

Krikken²,

Beekman³

et al. 1997

Matrix Biology

177

149

View full text Add to dashboard Cite

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“…The sensitivity of amino acid analysis may be too low to detect the subtle changes expected in the amino acid composition of the modified domains. Formation of cross-links, however, had an impact on collagen triple helix stability and this has been shown previously for collagen II from intervertebral discs of elderly patients [22]. Our experiments indicated a denaturation with loss of the triple-helicity of the 7S domain already at room temperature.…”

Section: Discussionmentioning

confidence: 47%

“…The effects of carbohydrate-induced reactions in vitro on two distinct domains of collagen IV (7S domain and NC1 domain) have been reported recently [22]. Our study was aimed to describe biochemical and biophysical properties of the collagen IV crosslinking domains 7S and NC1 from human kidneys obtained from patients with diabetes mellitus Type II.…”

mentioning

confidence: 99%

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confidence: 99%

“…Glycation of proteins is associated with the formation of high-molecular aggregates that are stabilised by non-reducible cross-linking components [13, 17±18] with characteristic fluorescence spectra [6,19,20]. Circular dichroism (CD) spectroscopy studies of glycated proteins exhibited a damaging effect of the modifications on protein structure and stability [21,22].In diabetic nephropathy the disordered morphology and functional deficiency of the glomerular basement membrane (GBM) has been explained by glycation of the collagen IV network providing the mechanical scaffold of the membrane texture. Collagen IV monomers consist of a collagenous major triplehelical domain with two specific cross-linking domains, the NC1 domain at the C-terminal end and the N-terminus the 7S domain [23±26], facilitating Diabetologia (1998) Summary Glycation of basement membrane collagen IV has been implicated as a major pathogenetic process leading to diabetic microvascular complications.…”

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confidence: 99%

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Biochemical and biophysical alterations of the 7S and NC1 domain of collagen IV from human diabetic kidneys

et al. 1998

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Glycation and glycoxidative reactions have been recognised to be a major pathogenetic principle for biochemical and biophysical alterations of proteins in diabetes mellitus [1±3]. Both processes have been shown to increase in humans with age and even more in patients with diabetes mellitus with the duration of the disease [4±8].Glycoxidative reactions, e. g. the Maillard reaction, are initiated by the condensation of a reducing sugar with an e-amino group of lysyl-or hydroxylysyl-residues of proteins [9]. The resulting Schiff-base is stabilised subsequently by Amadori rearrangement and processed further in very diverse and not yet fully elucidated chemical reactions resulting in a variety of cross-linked compounds. Only a small number of those, including pentosidine, have been characterised in structure and chemical composition [2, 10±16]. Glycation of proteins is associated with the formation of high-molecular aggregates that are stabilised by non-reducible cross-linking components [13, 17±18] with characteristic fluorescence spectra [6,19,20]. Circular dichroism (CD) spectroscopy studies of glycated proteins exhibited a damaging effect of the modifications on protein structure and stability [21,22].In diabetic nephropathy the disordered morphology and functional deficiency of the glomerular basement membrane (GBM) has been explained by glycation of the collagen IV network providing the mechanical scaffold of the membrane texture. Collagen IV monomers consist of a collagenous major triplehelical domain with two specific cross-linking domains, the NC1 domain at the C-terminal end and the N-terminus the 7S domain [23±26], facilitating Diabetologia (1998) Summary Glycation of basement membrane collagen IV has been implicated as a major pathogenetic process leading to diabetic microvascular complications. To evaluate the relevance of carbohydrate-induced modifications on collagen IV in diabetic nephropathy, we isolated the cross-linking domains 7S and NC1 from the glomerular basement membrane (GBM) of patients with diabetes mellitus. Modifications characteristic for glycated proteins were identified when the domains from diabetic kidney were compared with the same domains from human placenta as an unmodified control. In both domains a marked formation of inter-and intramolecular cross links could be demonstrated by SDS-PAGE. Furthermore circular dichroism studies showed a decrease in helicity of the 7S domain from human diabetic kidneys of 13 %, indicating denaturation already at room temperature. Thermal transition profiles, showing a shift of the denaturation temperature towards a lower temperature, with loss of a distinct second melting point, confirmed this observation. Our data provide further evidence for a possible role of protein-modification by glycoxidative reactions in the onset of diabetic nephropathy in vivo. [Diabetologia (1998

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Collagen analysis with mass spectrometry

Huizen

IJzermans

Burgers

et al. 2019

Mass Spectrometry Reviews

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Mass spectrometry‐based techniques can be applied to investigate collagen with respect to identification, quantification, supramolecular organization, and various post‐translational modifications. The continuous interest in collagen research has led to a shift from techniques to analyze the physical characteristics of collagen to methods to study collagen abundance and modifications. In this review, we illustrate the potential of mass spectrometry for in‐depth analyses of collagen.

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Collagen II from articular cartilage and annulus fibrosus

Cited by 48 publications

References 23 publications

A simplified measurement of degraded collagen in tissues: Application in healthy, fibrillated and osteoarthritic cartilage

A simplified measurement of degraded collagen in tissues: Application in healthy, fibrillated and osteoarthritic cartilage

Biochemical and biophysical alterations of the 7S and NC1 domain of collagen IV from human diabetic kidneys

Collagen analysis with mass spectrometry

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