The structure of l-CB3, a cyanogen bromide fragment from the central portion of the l chain of rat collagen. The tryptic peptides from skin and dentin collagens

The mixture of peptides released by tryptic hydrolysis of the collagen CNBr peptide, αl-CB3, has been resolved by ion-exchange chromatography. The resultant eleven tryptic peptides ranged in size from 3 to 46 amino acids and accounted for all the amino acids of the parent CNBr peptide. Two of the lysines in αl-CB3 from rat dentin collagen were shown to be hydroxylated to a substantial degree by isolation of the appropriate hydroxylysine-containing tryptic peptides. An analysis of the tryptic peptides indicated that αl-CB3 from dentin collagen is identical in structure to that from skin collagen, if hydroxylysine and hydroxyproline are considered equivalent to lysine and proline, respectively.     

Immobilization of pig muscle enolase. Studies on the activity of subunits

The native dimeric form of enolase from pig muscle was immobilized on Sepharose 4B activated with cyanogen bromide. The amount of matrix-bound enolase, its specific activity and kinetic properties depend on the extent of gel activation with CNBr. Only on the Sepharose activated with small quantities of CNBr the amount of protein which remained after treatment with Gdn.HCl was about 50% of the initially bound enolase, indicating that the enzyme was bound covalently to the matrix through a single subunit. The matrix-bound monomers obtained in this way were inactive and were unable to reassociate to dimers on addition of free subunits. The matrix-bound monomers obtained after KBr treatment were inactive but retained the ability to reassociate into active dimers after addition of free subunits. The results indicate that single matrix-bound subunits of pig muscle enolase are enzymatically inactive and dimeric structure is essential for catalytic activity.     

Insulin binds to type V collagen with retention of mitogenic activity

The abilities of eight extracellular matrix proteins, fibronectin, vitronectin, laminin, and collagen types I, II, III, IV, and V to bind insulin were examined by binding studies with insulin conjugated with peroxidase. At a physiological pH and ionic strength, type V collagen bound to insulin most strongly. The other types of collagen, laminin, and vitronectin also bound insulin with affinity lower than that of type V collagen. The insulin-binding site of type V collagen was in a 30-kDa CNBr fragment of the alpha 1 (V) chain. Analysis of the amino acid sequence showed that this 30-kDa fragment was identical to the heparin-binding fragment of type V collagen. The insulin-binding sites of laminin and vitronectin were located in the A chain and in the heparin-binding domain, respectively. Insulin bound to type V collagen stimulated the synthesis of DNA by mouse mammary tumor MTD cells, indicating that bound insulin retained mitogenic activity.     

Non-collagenous proteins of predentine from dentinogenically active bovine teeth.

Predentin(e) was dissected out from unerupted permanent bovine teeth. The non-collagenous proteins were extracted at -13 degrees C by 4 M-guanidinium chloride containing proteinase inhibitors and separated by DEAE-Sepharose and Sephadex G-100 chromatography. In addition to a few minor constituents, the only major non-collagenous components that could be demonstrated were albumin and proteoglycan. The localization of the former, demonstrated by optical-microscopical immunochemistry, was such that it was concluded that albumin is not a constituent of predentin matrix. Very low amounts of phosphoprotein were found in predentin matrix. This was of two types, high- and low-phosphorylated. Larger amounts of phosphoprotein were not present until the dissection was carried deeper into newly formed dentin(e). On the basis of the present results and previously obtained morphological data the conclusion was drawn that predentin matrix, containing virtually only collagen type I and proteoglycan, is similar in composition to that of loose connective tissue and primarily aimed at the production and maturation of collagen fibres. Only immediately before the mineralization front are the non-collagenous protein components secreted that initiate and govern calcium-phosphate mineral formation.     

High-resolution solid-state nuclear magnetic resonance spectra of dentin collagen

Insoluble collagen of bovine dentin was characterized by high-resolution solid-state 13C nuclear magnetic resonance (NMR) spectroscopy using a cross-polarization magic angle spinning procedure. A downfield shift was observed in the signal of hydroxyproline C beta compared with that in skin collagen, indicating a distortion in the hydroxyproline structure. A signal of 31P NMR was detected in dentin collagen that was compatible with the presence of matrix-associated phosphoprotein.     

Electron spin resonance studies on tooth phosphoproteins using manganese ions as probes.

The binding of manganese ion to tooth phosphoproteins and to model compounds containing carboxyl and phosphate groups was analyzed with the Langmuir equation applied to data obtained from esr spectra. The Langmuir isotherms suggested that both bovine molar and rat incisor phosphoprotein preparations bound manganese primarily to phosphate groups. A purified sample of the bovine dentin protein showed a greatly increased number of binding sites for manganese as well as an increased affinity.     

Collagen cross-linking. Isolation of cross-linked peptides from collagen of chicken bone

Cross-linked peptides were isolated from chicken bone collagen that had been digested with CNBr or with bacterial collagenase. Analyses of (3)H radioactivity in disc electrophoretic profiles of the CNBr peptides from bone collagens that had been treated with NaB(3)H indicated that a major site of intermolecular cross-linking in chicken bone collagen is located between the carboxy-terminal region of an alpha1 chain and a small CNBr peptide, probably situated near the amino-terminus of an alpha1 or alpha2 chain in an adjacent collagen molecule. A small amount of this cross-linked CNBr peptide was isolated from a CNBr digest of chicken bone collagen by column chromatography. Amino acid analysis showed that the CNBr peptide, alpha1CB6B, the carboxy-terminal peptide of the alpha1 chain, was the major CNBr peptide in the preparation, and the reduced cross-linking components were identified as hydroxylysinohydroxynorleucine (HylOHNle), with a smaller amount of hydroxylysinonorleucine (HylNle). However, the composition and the low recovery of the cross-linking amino acids suggested that the preparation was a mixture of CNBr peptides alpha1CB6B and alpha1CB6B cross-linked to a small CNBr peptide whose identity could not be determined. A small cross-linked peptide was isolated from chicken bone collagen that had been reduced with NaB(3)H(4) and digested with bacterial collagenase. This peptide was the major cross-linked peptide in the digest and contained a stoicheiometric amount of the reduced cross-linking compounds. A peptide which had the same amino acid composition, but contained the cross-linking compounds in their reducible forms, was isolated from a collagenase digest of chicken bone collagen that had not been treated with NaBH(4). The absence of the reduced cross-links from this peptide indicates that, at least for the cross-linking site from which the peptide derives, natural reduction is not a significant pathway for biosynthesis of stable cross-links. However, most of the reducible cross-linking component in the peptide appeared to stabilize in the bone collagen by rearrangement from aldimine to ketoamine form.     

Dentin sialoprotein: biosynthesis and developmental appearance in rat tooth germs in comparison with amelogenins,osteocalcin and colagen type-I

A non-collagenous protein, extracted from rat incisor dentin, is a dentin sialoprotein (DSP). We examined immunohistochemically the developmental appearance and tissue distribution of DSP in 1 to 3-day-old rat molar and incisor tooth germs. The earliest staining for DSP was observed in newly differentiated odontoblasts. In more advanced stages, immunostaining for DSP gradually increased in pre-dentin, odontoblasts and dentin, and appeared in many cells of the dental papilla. In early stages of development before the breakdown of the dental basement membrane, pre-ameloblasts were also positive for DSP. This staining disappeared from the ameloblast cell body soon after deposition of the first layer of mineralized dentin. Radiolabelling of tooth matrix proteins with ¹⁴C-serine in vitro followed by immunoprecipitation and fluorography confirmed that DSP was synthesized by tooth-forming cells. The immunolocalization for DSP was different from that of either collagen type-I, osteocalcin or the amelogenins. Whereas collagen type-I and osteocalcin were restricted to the mesenchymal dental tissues, the amelogenins were detectable in both epithelial and mesenchymal dental cells and tissues at the epithelio-mesenchymal interface at early stages of development, prior to the onset of dentin mineralization. We conclude that DSP is expressed in and secreted by odontoblasts and some dental papilla cells from early stages of dentinogenesis onwards, i.e. later than type-I collagen, but before deposition of the first layer of mineralized dentin. In pre-mineralizing stages, some of the matrix proteins may be endocytosed from the pre-dentin by both cell types involved in the epithelio-mesenchymal interaction.     

Phosphorylation of ribosomal proteins in rat cerebral cortex in vitro.

Incubation of cerebral cortical tissue from immature rats in the presence of [32P]orthophosphate resulted in similar rates of incorporation of radioactivity into the proteins of free and membrane-bound ribosomes. Incorporation of label into ribosomal proteins of both species continued actively for at least 3 hours. Since recovery of membrane-bound ribosomes from rat cerebral cortex is quite low, further analyses of the radioactive phosphoproteins were restricted to the free ribosome population. A significant fraction of the radioactivity which was precipitated with trichloroacetic acid was not removed by heating in trichloroacetic acid at 90 degrees or extracted with organic solvents and therefore was presumed to be covalently bound to protein. The radioactive phosphoryl groups present in the ribosomal proteins were mainly in ester linkages since they were readily removed by exposure to 1 N NaOH, relatively unaltered by 1N HCl, and unaffected by hydroxylamine. This conclusion was supported by the isolation of labeled o-phosphoserine and o-phosphothreonine residues from hydrolysates of ribosomal proteins. A significant fraction of the labeled phosphoproteins in the purified ribosomes appeared to be bound tightly to the ribosome structure since only 40% of the radioactivity could be removed by extraction of these ribosomes with 1 M KCl. Phosphorylation of proteins of cerebral monoribosomes was more rapid than the same process in polyribosomes from the same source. Eight radioactive phosphoprotein bands could be detected by electrophoresis of proteins obtained from unfractionated cerebral ribosomes on unidimensional polyacrylamide gels containing sodium dodecyl sulfate. The protein nature of these materials was confirmed by pronase digestion. Proteins of subribosomal particles isolated from the total free ribosomal population were labeled differentially. When dissociation was carried out in the presence of EDTA, the small subunit contained four radioactive phosphoprotein bands, whereas the large subunit contained five. Three of the radioactive phosphoprotein components of the small subunit were removed when dissociation of cerebral ribosomes which were previously washed with high salt media was carried out in the presence of puromycin and high salt. However, only the largest labeled phosphoprotein band of the large subunit was removed by this procedure. This component exhibited the same electrophoretic mobility as one of the radioactive phosphoprotein bands which was removed from the small subunit by high salt treatment..     

Characterization of the skin collagen of a surface water fish Scomberoides commersonianus.

The molecular organization of the skin collagen in the fish S. commersonianus has been investigated. The contents of imino acids proline and hydroxyproline are less in the skin collagen. The major collagenous component of fish skin is homologous to type I collagen. The number of CNBr peptides in fish skin collagen alpha 1 chains is two times that of rat skin alpha 1 CNBr peptides. The proline-hydroxyproline ratio in the six peptides studied was 1.66-3.5 as compared to that of rat skin collagen (0.67-1.94). This indicates that proline and hydroxyproline are not uniformly distributed in the collagen molecule in fish skin collagen.     

Immunodetection of osteoadherin in murine tooth extracellular matrices

An antiserum was generated from synthetic peptides highly conserved between different mammalian species to immunolocalise the small leucine-rich proteoglycan osteoadherin (OSAD) in murine teeth. In 19-day-old embryos of rats and mice, a positive staining was found in incisor predentin and alveolar bone surrounding developing incisors and molars. In newborns, OSAD was detected at the tip of the first molar cusp where it accumulated in predentin concomitantly with odontoblast differentiation. In 2-day-old rats and mice, in the first molar, immunostaining revealed positive predentin, enamel matrix close to the apical pole of ameloblasts and a strong signal in dentin. At this stage, OSAD was detected in predentin in the second molar. Ultrastructural immunocytochemistry showed gold particles associated with collagen fibres in predentin and in foci at the dentin mineralisation front. Gold particles were also detected near the secretory pole of ameloblasts where enamel crystallites elongate. No staining was detected in pulp tissue and dental follicle. Restriction of OSAD expression to the extracellular matrix of bone, dentin and enamel suggests a role of this proteoglycan in the organisation of mineralised tissues.     

Studies of the distribution of proteins bound to CNBr-activated Sepharose 6B at the electron-microscopic level.

Proteins were covalently attached to Sepharose by the CNBr method. Their distribution across the carrier beads was studied at the electron microscopic level. The approach has been to ferritinstain and to section the gel beads. Ferritin was either coupled directly to the polysaccharide backbone of the carrier or conjugated with pure rabbit anti-aminopeptidase in order to visualize covalently bound leucine aminopeptidase by the immunferritin technique. The results corroborate earlier fluorescence microscopic findings of a uniform protein distribution, provided that a number of conditions are fulfilled.     

Ca-ATPase and ALPase activities at the initial calcification sites of dentin and enamel in the rat incisor

Summary Enzymatic activities of calcium-magnesium dependent adenosine triphosphatase (Ca-ATPase) and nonspecific alkaline phosphatase (ALPase) were localized at the initial calcification sites of dentin and enamel of rat incisor teeth using electron-microscopic cytochemistry.Ca-ATPase was localized in the Golgi cisternae, cytoplasmic vesicles and along the outer surface of the presecretory and secretory ameloblasts, whereas it was totally absent from the odontoblasts in the pulp. Inversely, ALPase reaction was localized along the outer surface of the odontoblasts, but almost completely absent from the ameloblasts.Diffuse extracellular reactions of both enzymes were distributed throughout the unmineralized fibrous matrix of mantle dentin in which a large number of matrix vesicles were scattered. Both Ca-ATPase and ALPase reactions, which appeared in the matrix vesicles in the process of formation of mantle dentin, became most conspicuous at the site of initial dentin calcification. At this stage, an intense Ca-ATPase reaction also appeared along some of the collagen fibrils adjacent to the reactive matrix vesicles. No ALPase reaction was localized along these Ca-ATPase reactive collagen fibrils.Our observations suggest strongly that Ca-ATPase in the matrix vesicles originates from the inner enamel epithelium and/or preameloblasts whereas ALPase originates from the odontoblasts in the pulp. The importance of the coexistence of both enzymes for the control of initial calcification of dental hard tissues is suggested.     

Dentin matrix protein 1 immobilized on type I collagen fibrils facilitates apatite deposition in vitro

During bone and dentin mineralization, the crystal nucleation and growth processes are considered to be matrix regulated. Osteoblasts and odontoblasts synthesize a polymeric collagenous matrix, which forms a template for apatite initiation and elongation. Coordinated and controlled reaction between type I collagen and bone/dentin-specific noncollagenous proteins are necessary for well defined biogenic crystal formation. However, the process by which collagen surfaces become mineralized is not understood. Dentin matrix protein 1 (DMP1) is an acidic noncollagenous protein expressed during the initial stages of mineralized matrix formation in bone and dentin. Here we show that DMP1 bound specifically to type I collagen, with the binding region located at the N-telopeptide region of type I collagen. Peptide mapping identified two acidic clusters in DMP1 responsible for interacting with type I collagen. The collagen binding property of these domains was further confirmed by site-directed mutagenesis. Transmission electron microscopy analyses have localized DMP1 in the gap region of the collagen fibrils. Fibrillogenesis assays further demonstrated that DMP1 accelerated the assembly of the collagen fibrils in vitro and also increased the diameter of the reconstituted collagen fibrils. In vitro mineralization studies in the presence of calcium and phosphate ions demonstrated apatite deposition only at the collagen-bound DMP1 sites. Thus specific binding of DMP1 and possibly other noncollagenous proteins on the collagen fibril might be a key step in collagen matrix organization and mineralization.     

Developmental appearance of dentin matrix protein 1 during the early dentinogenesis in rat molars as identified by high-resolution immunocytochemistry

Dentin matrix protein 1 (DMP 1) is an acidic phosphoprotein that has been postulated to play an important role in mineralized tissue formation. We have examined rat molar tooth germs by applying a high-resolution immunocytochemical approach with the purpose to identify the temporal and spatial localization of DMP 1 at the onset of dentinogenesis. Upper molar tooth germs of 2- to 3-day-old Wistar rats were fixed in a cacodylate-buffered 0.1% glutaraldehyde + 4% formaldehyde fixative, left unosmicated and embedded in LR White resin. The sections were incubated with a polyclonal DMP 1 antibody for postembedding colloidal gold immunolabeling and examined in a Jeol 1010 transmission electron microscope. The earliest localization of DMP 1 was in the Golgi region as well as in the nucleus of differentiating odontoblasts. When mineralization spread from matrix vesicles to the surrounding matrix, DMP 1 was extracellularly detected around the mineralizing globules. In the regions of fully mineralized mantle dentin, it was present in the mineralized regions, mainly around the peritubular dentin. The appearance of DMP 1 during early dentinogenesis implies a direct role for this protein in both odontoblast differentiation and matrix mineralization.     

Microquantitation of insoluble tissue collagen (types I and III) by radiodilution assay

The individual collagen types of the extracellular matrix of small tissue samples have been difficult to quantitate accurately both due to their marked insolubility and their relatively low immunogenicity. Thus no microassay with the sensitivity of a radioimmunoassay is currently available for quantitation of insoluble collagen types I and III in extremely small tissue samples. A radiochemical assay has been developed which allows direct processing of small tissue samples containing as little as 1-3 micrograms of a given collagen alpha chain. Unprocessed lyophilized tissues were digested with cyanogen bromide (CNBr) in the presence of a tritiated probe containing a soluble mixture of 3H-alpha 1(I) and 3H-alpha 1(III) collagen previously extracted and purified from tissue minces incubated with [3H]leucine. The resulting mix of radiolabeled peptides was separated on sodium dodecyl sulfate-polyacrylamide gradient gels. Reduction of the specific radioactivity of free leucine in acid hydrolysates of each individual CNBr peptide can be used to quantitate the amount of collagen types I or III in the original sample. Similar radiodilution analysis using a 3H-alpha 2(I) probe indicated a normal 2:1 ratio of alpha chains of type I collagen in the tissues tested. This method is also applicable to cell culture, easily measuring the collagen associated with fibroblast cell layers or medium in individual microtiter wells. When applied to various tissues of known collagen-type composition, it provides reproducible results which compare well with values published in the literature.     

Isolation and partial characterization of collagen chains dimerized by sugar-derived cross-links

Incubation of tail tendon from a young rat in solutions containing D-ribose resulted in attachment of the monosaccharide to collagen and subsequent cross-link formation at a rate much faster than found for glucose. The collagen rapidly became resistant to solubilization and showed increasing fluorescence. Ribose bound to all major CNBr peptides of collagen, with some preference for the alpha 2-CB3,5 peptide and the triple-helical region of alpha 1-CB6, and was incorporated into higher molecular weight material. Extensive pepsin digestion permitted isolation of dimers of alpha chains cross-linked in triple-helical regions as a result of incubation with ribose. The dimers were identified as beta 11, beta 12, and beta 22 components, and the limited degree of heterogeneity of these components indicated that cross-linking occurred at several sites, some of which must be intermolecular. Isolated beta components were strongly fluorescent with a spectrum similar to that of collagen in aged tissues. Fluorescent dimers with similar characteristics were found in pepsin digests of tail tendons from older rats.     

Collagenase-Released Non-Collagenous Proteins of Cortical Bone Matrix

Two distinct groups of non-collagenous components were isolated from rat cortical bone gelatin which had previously been digested with purified bacterial col-lagenase. One component was disulfide-bonded, strongly acidic, trypsin-labile glycoprotein aggregate with a molecular mass of more than 100, 000 daltons. When reduced with β-mercaptoethanol this protein disaggregated into subunits with a molecular mass of about 60, 000 daltons. The other components consisted of a group of polypeptides with a molecular mass of about 5, 000 daltons. The latter group was present in collagenase digests prepared from normal bone gelatin but was hardly detectable or absent in digests of gelatin prepared from either autolyzed, trypsinized or lathyritic bone, or from the residue of neutral salt extracted rat tail tendon.

A recently discovered group of non-collagenous proteins is tightly bound to the highly crosslinked insoluble structure of collagen fibrils of bone and dentin. Dische et al ¹ predicted the existence of these proteins in bone by analyzing the products of KOH hydrolysis of the EDTA-insoluble residues of cortical bone collagen. Comparable products were separated following digestion of bone matrix with collagenase by Herring², and oxidation of dentin matrix by alkaline sodium metaperiodate by Shuttleworth and Veis.³ Leaver et al ⁴ proposed the name collagenase-released proteins (CRP) for non-collagenous proteins obtained from the EDTA-insoluble residue of bone and dentin. There are at least two limitations in information about CRP in the above-cited reports. The first is that the collagenases were not certified to be protease-free. The second is that EDTA-insoluble residues of cortical bone were only partly digestable by bacterial collagenase. We report here isolation and partial characterization of CRP from a special preparation of bone matrix gelatin which is quantitatively digested by a protease-free bacterial collagenase-gelatinase purified by the method of Peterkofsky and Diegelmann.^{5, 6}     

Immunofluorescent localization of type III collagen and the N-terminal propeptide of type III procollagen in dentin matrix in osteogenesis imperfecta

Demineralized deciduous and permanent teeth from seven patients with six different types of osteogenesis imperfecta (OI) and from four unaffected controls were stained for type III collagen and for the N-terminal propeptide of type III procollagen using indirect immunofluorescence. Sillence types IA, IB and III OI were each represented by one patient. Two patients had type IVB and two had unclassifiable OI. After enzymatic treatment, the dentin matrix of one patient each with type IB OI, type IVB, and unclassifiable OI reacted with the specific antibodies against both type III collagen and the N-terminal propeptide. Positive staining was observed around the pathological canal-like structures and as delicate strands traversing the matrix. The similar patterns of immunofluorescence for both antigens in dentin in OI are suggestive of retention of the N-terminal propeptide in association with type III collagen identical to that in normal nonmineralized connective tissues. The abnormal presence of type III collagen in dentin in OI may be secondary to the aberrant structure of type I collagen. The failure of dentin matrix of all patients with OI to immunostain for type III collagen and the N-terminal propeptide may reflect heterogeneity or additional secondary changes in matrix macromolecule interactions.     

Inhibition of chondroitin sulfate glycosaminoglycans incorporation affected odontoblast differentiation in cultured embryonic mouse molars

Chondroitin sulfate proteoglycan (CSPG) is an important component of extracellular matrix (ECM), it is composed of a core protein and one or more chondroitin sulfate glycosaminoglycan side chains (CS-GAGs). To investigate the roles of its CS-GAGs in dentinogenesis, the mouse mandibular first molar tooth germs at early bell stage were cultivated with or without β-xyloside. As expected, the CS-GAGs were inhibited on their incorporation to CSPGs by β-xyloside, accompanied by the change of morphology of the cultured tooth germs. The histological results and the transmission electron microscopy (TEM) investigation indicated that β-xyloside exhibited obvious inhibiting effects on odontoblasts differentiation compared with the control group. Meanwhile the results of immunohistochemistry, in situ hybridization and quantitative RT-PCR for type I collagen, dentin matrix acidic phosphoprotein 1 and dentin sialophosphoprotein, the products of differentiated odontoblasts, further proved that odontoblasts differentiation was inhibited. Collagen fibers detected in TEM decreased and arranged in disorder as well. Thus we conclude that the inhibition of CS-GAGs incorporation to CSPGs can affect odontoblast differentiation in cultured embryonic mouse molars.