High-performance liquid chromatographic separation of glycopeptides from Nereis cuticle collagen

To facilitate the structural studies of invertebrate collagens, a sensitive and effective method was developed, using reverse-phase high-performance liquid chromatography for preparative isolation of the collagen subunits and their clostridial collagenase-derived peptides; the methods have been applied to Nereis cuticle collagen. The two subunits of denatured Nereis cuticle collagen, termed A and B, were initially separated by high-performance liquid chromatography. These polypeptides, with Mr of about 0.5 million, were each exhaustively digested with clostridial collagenase. The digest of the A subunit, which contains all of the uronic acid, was enriched for the uronic acid-containing glycopeptides by means of gel filtration. These glycopeptides were resolved into 23 major peaks, using reverse-phase HPLC, over a 5-h elution time, with an acetonitrile gradient (0-20%) containing 0.1% TFA. The amino acid composition data suggests that the peptides are of variable length, from 5 to 17 residues, while beta-elimination studies show that the uronic acid-containing moieties are all O-glycosidically linked to threonine residues, in the peptides examined. The amino acid sequence of one of the major glycopeptides was determined and found to be Gly-Hyp-Ala-Gly-Gly-Ile-Gly-Glu-Thr-Gly-Ala-Val-Gly-Leu-Hyp. The amino acid compositions of glycosylated and nonglycosylated peptides which had eluted, numbering about 100, showed a correspondence between hydrophobicity or hydrophilicity and emergence time from the column. We also found that the peptides most enriched in 4-hydroxyproline emerged earliest. These studies provide a foundation for elucidating the detailed structures of the large, unusual subunits of a well-characterized cuticle collagen.     

Polycystic kidney disease-like domains of clostridial collagenases and their role in collagen recruitment

Bacterial collagenases exhibit a multimodular domain organization. While the N-terminal collagenase unit harbors the catalytic zinc and suffices to degrade peptidic substrates, collagen substrates come in different types, explaining the requirement for accessory domains such as polycystic kidney disease (PKD)-like domains for efficient catalysis. How the recognition and unfolding of (micro-)fibrillar or triple-helical collagen is accomplished are only poorly understood. Here, we present the crystal structure of the PKD-like domain of collagenase G from Clostridium histolyticum. The β-barrel structure reveals a two-tier architecture, connected by kinked hinge segments. Together with sheet extension as a generic oligomerization mechanism, this explains the cooperativity among accessory domains as well as their adaptivity to varying substrates.     

Nereis cuticle collagen. Isolation and properties of a large fragment resistant to proteolysis by bacterial collagenase.

Native cuticle collagen, obtained from Nereis virens, was incubated with purified bacterial collagenase (EC 3.4.4.19). The kinetics of proteolysis were monitored by viscometry, in parallel with similar digestions of calf skin collagen. Comparison of the kinetics of digestion of the two collagens, at similar enzyme to substrate ratios (w/w), showed that the native cuticle collagen was relatively refractory to digestion by bacterial collagenase. Characterization of the cuticle collagen digest by sodium dodecyl sulfate-polyacrylamide electrophoresis and agarose gel filtration in CaCl2 showed a large polypeptide, of about 300,000 daltons, to be a major product. The native form of this product, a unique fragment, was isolated from the digest by ethanol precipitation. It was found to have an intrinsic viscosity of 120 dl/g, to have an optical rotary dispersion curve characteristic of collagen, to undergo a typical collagenous thermal transition with a Tm of 23.2 degrees, and to have a calculated molar mass of 900,000 g with molecular dimensions of 9,000 X 13 A. It had an amino acid composition which was similar, but not identical with the native cuticle collagen. Although the original substrate contained two dissimilar chains, A and B, in a molar ratio of 1:2, the collagenase-resistant product appeared to be composed of only one type of polypeptide fragment. Possibly, the original subunits contain similar, if not identical collagenase-resistant regions.     

A model for interstitial collagen catabolism by mammalian collagenases.

Mammalian collagenases cleave all three alpha chains of native, triple-helical types I, II, and III collagens after the Gly residue of the partial sequence Gly-[Ile or Leu]-[Ala or Leu] at a single locus approximately three-fourths from the amino terminus. There are an additional 31 sites in the triple-helical regions of types I, II, III, and IV collagens that contain the same partial sequence but are not hydrolyzed. A model has been developed to explain this remarkable specificity. The mammalian collagenase cleavage site in interstitial collagens is distinguished by: (a) a low side-chain molal volume-, high imino acid (greater than 33%)-containing region that is tightly triple-helical, consisting of four Gly-X-Y triplets preceding the cleavage site, (b) a low imino acid-containing (less than 17%), loosely triple-helical region consisting of four Gly-X-Y triplets following the cleavage site, and (c) a maximum of one charged residue for the entire 25 residue cleavage site region, which is always an Arg that follows the cleavage site in subsite P'5 or P'8. In addition, the high imino acid-containing region cannot have an imino acid adjacent to the cleaved Gly-[Ile or Leu] bond (i.e. in subsite P2). Careful scrutiny of the 31 non-cleaved sequences reveals that none of those sites shares all of the characteristics of the cleavage site. The criterion of this model thus explain both cleaved and non-cleaved sequences in the triple-helical regions of types I, II, III, and IV collagen, and are supported by all known experimental and theoretical results on collagen catabolism and structure.     

Differences in the degradation of native collagen by two microbial collagenases.

The early stages of degradation of native collagen by two bacterial collagenases were studied by electron microscopy and by automatic Edman degradation. The purified collagenase from Clostridium histolyticum was shown to cleave native collagen at several sites, but not progressively from the N-terminus, as had been previously suggested. The homogeneous collagenase from Achromobacter iophagus cleaves native collagen preferentially at two sites corresponding to the interbands 33-34 and 41-42. The latter lies within the region cleaved by the eukaryotic collagenases.     

SLRP interaction can protect collagen fibrils from cleavage by collagenases

Decorin, fibromodulin and lumican are small leucine-rich repeat proteoglycans (SLRPs) which interact with the surface of collagen fibrils. Together with other molecules they form a coat on the fibril surface which could impede the access to collagenolytic proteinases. To address this hypothesis, fibrils of type I or type II collagen were formed in vitro and treated with either collagenase-1 (MMP1) or collagenase-3 (MMP13). The fibrils were either treated directly or following incubation in the presence of the recombinant SLRPs. The susceptibility of the uncoated and SLRP-coated fibrils to collagenase cleavage was assessed by SDS/PAGE. Interaction with either recombinant decorin, fibromodulin or lumican results in decreased collagenase cleavage of both fibril types. Thus SLRP interaction can help protect collagen fibrils from cleavage by collagenases.     

Carbamylation differentially alters type I collagen sensitivity to various collagenases.

Carbamylation is a post-translational modification due to nonenzymatic binding of cyanate, a by-product of urea, on free amino groups of proteins. Post-translational modifications are known to induce alterations in structural and functional properties of proteins, thus disturbing protein-protein or cell-protein interactions. We report the impact of carbamylation on type I collagen sensitivity to enzymatic proteolysis. Type I collagen was extracted from rat tail tendons and carbamylated by incubation with 0.1 M potassium cyanate at 37 degrees C for 2, 6 or 24 h. Degradation assays revealed that carbamylated collagen exhibited a greater resistance to collagenases (i.e. bacterial collagenase, matrix metalloproteinase(MMP)-1, MMP-8 and MMP-13), together with an increased sensitivity to MMP-2. Evaluation of collagen triple helix conformation by polarimetry indicated that local destabilizations of triple helix structure related to carbamylation could be responsible for the observed differences in sensitivity. These results confirm the crucial role of triple helix integrity in the degradation of type I collagen by MMPs, and support the deleterious impact of post-translational modifications in vivo by altering the balanced remodeling of collagen within connective tissue.     

Action of bacterial collagenase on Ascaris cuticle collagen.

The collagen from the cuticle of Ascaris lumbricoides was digested by Clostridium histolyticum collagenase [EC 3.4.24.3] in the presence and absence of CaCl2. About 1.2 mumoles of amino groups per mg collagen was liberated when the digestion was performed in the presence of 5 mM CaCl2, whereas about 0.5 mumole of amino groups per mg collagen was liberated by digestion in the absence of CaCl2. In contrast, CaCl2 influenced the extent of hydrolysis of rat tail tendon collagen only slightly. The results suggest that CaCl2 is necessary for the hydrolysis of certain regions in the molecule of Ascaris collagen and that such structures may not be present in mammalian collagens.     

The resolution of Ascaris cuticle collagen into three chain types.

Reduced and methylated collagen from Ascaris lumbricoides cuticle was resolved into three major components by chromatography on phosphocellulose. The components have similar molecular weights of about 52,000 by sedimentation equilbrium and molecular sieve chromatography, but they have different amino acid compositions. Since they do not appear to be stoichiometrically related, they apparently represent chains from collagens of more than one type. All three chains contain about 27 residue % glycine, 36 residues of proline, and 17 residues of methylcysteine, suggesting that the collagens can be maximally about 80% triple helical and are extensively disulfide cross-linked in the native state. Two minor components from the cuticle are apparently derived from one of the major chains by cleavage in a single region to give two-third and one-third fragments.     

Inhibition of human collagenases by sulfur-based substrate analogs.

A series of sulfhydryl and novel sulfur-based substrate-analog inhibitors has been synthesized and tested against human fibroblast and neutrophil collagenases. Absolute stereospecific synthesis of several sulfhydryl inhibitors establishes that it is the diastereomers with the R-configuration of the P'1 residues, which correspond to the unnatural D-amino acid analogs, that are the most potent inhibitors. The corresponding disulfide, sulfonate, sulfinate, sulfide, sulfoxide and sulfone analogs exhibit widely variable levels of potency, but all less than the sulfhydryl compounds. No correlation between inhibitor potency and any single structural feature of these new compounds is apparent. However, differences in potency can be ascribed to the different affinities of these functional groups for zinc coordination and hydrogen bonding to nearby active site residues.     

Production and properties of two collagenases from bacteria and their application for collagen extraction

Two collagenolytic protease (collagenase) producing bacteria, a Gram positive Bacillus cereus CNA1 and a Gram negative Klebsiella pneumoniae CNL3, were isolated under alkaline and acidic conditions, respectively. The production of collagenase by these two bacteria was optimized. Glycerol was the suitable carbon source for collagenase production by both strains. The optimal initial pH values for collagenase production by CNA1 and CNL3 were 7.5 and 6.0, respectively, and the optimal temperature was 37°C for both strains. The maximum activity of the partially purified collagenase from CNA1 was at pH 7.0 and 45°C. Its pH and thermal stability were in the range of 6-8 and below 40°C, respectively. The maximum activity of the partially purified collagenase from CNL3 was at pH 6.0 and 40°C. Its pH and thermal stability were in the range of 5-7 and below 37°C, respectively. The collagenase from CNL3 was more stable at a low pH compared with that from CNA1. Collagenases from both strains were used to extract collagen from salmon fish skin. The use of collagenases from CNA1 and CNL3 combined with acid treatment yielded a high collagen extraction of 54.6% and 53.0%, of the fish skin dry weight, respectively.     

Spatial organization of collagen in annelid cuticle: order and defects

The epidermis of Paralvinella grasslei (Polychaete, Annelida) is covered by an extracellular matrix, the cuticle, mainly composed as in other annelids of superimposed layers of non-striated collagen fibrils. The collagen fibrils of annelid cuticle are shown to be composed of parallel and sinuous microfibrils (thin sections and freeze-fracture replicas). The 3-dimensional organization of collagen is characterized by 2 different types of geometrical order: (a) Fibrils form a quasiorthogonal network, whose structure is comparable to that of a "plywood"; (b) Fibrils are helical, and goniometric studies show that microfibrils present a definite order within each fibril, which is termed "cylindrical twist". These 2 characteristics are those which have recently been evidenced in "blue phases", i.e., liquid crystals which are closely related to cholesteric liquid crystalline phases. Non-fluid analogues of cholesteric liquids are widespread among invertebrate cuticles and the presence of blue phase analogues suggests that a self-assembly mechanisms is involved in cuticle morpho-genesis, which is derived from that governing blue phase growth. The cuticular network presents local rearrangements of fibrils called "defects", despite the fact that they are elaborate structures which trigonal and pentagonal singularities. Branched fibrils are regularly observed. We discuss the involvement of these pattern disruptions in the cuticle growth process.