A role for disulphide bridges in the protein core in the interaction of proteodermatan sulphate and collagen

The versatile roles of lumican in eye diseases: A review

Lumican is a keratan sulfate proteoglycan that belongs to the small leucine-rich proteoglycan family. Research has lifted the veil on the versatile roles of lumican in the pathogenesis of eye diseases. Lumican has pivotal roles in the maintenance of physiological tissue homogenesis and is often upregulated in pathological conditions, e.g., fibrosis, scar tissue formation in injured tissues, persistent inflammatory responses and immune anomaly, etc. Herein, we will review literature regarding the role of lumican in pathogenesis of inherited congenital and acquired eye diseases, e.g., cornea dystrophy, cataract, glaucoma and chorioretinal diseases, etc.

Evidence of biglycan structure-function in bone homeostasis and aging

Purpose: Biglycan is a proteoglycan of the small leucine-rich repeat family. It is present in all connective tissues and plays key structural and signaling roles. This review aimed to compile available evidence in the characteristics and distribution of biglycan and its glycosylated and non-glycosylated forms in connective tissues with a specific focus on the contribution to homeostasis of bone and changes of biglycan structure with aging.Methods: The Pubmed database was searched and included the terms "biglycan", "proteoglycans", "glycosaminoglycans", "bone", "osteoblast", "osteocyte", "osteoclast", "aging", "inflammation", "cartilage". Abstracts were appraised and a series of original articles and reviews studied to generate this narrative review.Results: Based on the search, biglycan significantly affects bone development and homeostasis and can be significantly changed by the aging process in several connective tissues, which in turn affects the behavior of tissue and cell responses in aged networks. Further, as the understanding of the various forms of biglycan in vivo is expanded and the function of its components in vitro is dissected, this proteoglycan can potentially serve as a therapeutic or biomarker molecule to detect tissue destruction.Conclusions: Biglycan is a key player in skeletal bone homeostasis, and overall, there is more evidence on the role of biglycan in development and less in the adult physiological or diseased young and aged systems. Further understanding of its conformation, degradation peptides and post-translational modifications will be required to understand the role of biglycan in bone maintenance and to support the development of treatments for age-related bone dysfunctions.

In situ D-periodic molecular structure of type II collagen

Collagens are essential components of extracellular matrices in multicellular animals. Fibrillar type II collagen is the most prominent component of articular cartilage and other cartilage-like tissues such as notochord. Its in situ macromolecular and packing structures have not been fully characterized, but an understanding of these attributes may help reveal mechanisms of tissue assembly and degradation (as in osteo- and rheumatoid arthritis). In some tissues such as lamprey notochord, the collagen fibrillar organization is naturally crystalline and may be studied by x-ray diffraction. We used diffraction data from native and derivative notochord tissue samples to solve the axial, D-periodic structure of type II collagen via multiple isomorphous replacement. The electron density maps and heavy atom data revealed the conformation of the nonhelical telopeptides and the overall D-periodic structure of collagen type II in native tissues, data that were further supported by structure prediction and transmission electron microscopy. These results help to explain the observed differences in collagen type I and type II fibrillar architecture and indicate the collagen type II cross-link organization, which is crucial for fibrillogenesis. Transmission electron microscopy data show the close relationship between lamprey and mammalian collagen fibrils, even though the respective larger scale tissue architecture differs.

Decorin core protein (decoron) shape complements collagen fibril surface structure and mediates its binding

Decorin is the archetypal small leucine rich repeat proteoglycan of the vertebrate extracellular matrix (ECM). With its glycosaminoglycuronan chain, it is responsible for stabilizing inter-fibrillar organization. Type I collagen is the predominant member of the fibrillar collagen family, fulfilling both organizational and structural roles in animal ECMs. In this study, interactions between decoron (the decorin core protein) and binding sites in the d and e₁ bands of the type I collagen fibril were investigated through molecular modeling of their respective X-ray diffraction structures. Previously, it was proposed that a model-based, highly curved concave decoron interacts with a single collagen molecule, which would form extensive van der Waals contacts and give rise to strong non-specific binding. However, the large well-ordered aggregate that is the collagen fibril places significant restraints on modes of ligand binding and necessitates multi-collagen molecular contacts. We present here a relatively high-resolution model of the decoron-fibril collagen complex. We find that the respective crystal structures complement each other well, although it is the monomeric form of decoron that shows the most appropriate shape complementarity with the fibril surface and favorable calculated energies of interaction. One molecule of decoron interacts with four to six collagen molecules, and the binding specificity relies on a large number of hydrogen bonds and electrostatic interactions, primarily with the collagen motifs KXGDRGE and AKGDRGE (d and e₁ bands). This work helps us to understand collagen-decorin interactions and the molecular architecture of the fibrillar ECM in health and disease.

LRRCE: a leucine-rich repeat cysteine capping motif unique to the chordate lineage

Background

The small leucine-rich repeat proteins and proteoglycans (SLRPs) form an important family of regulatory molecules that participate in many essential functions. They typically control the correct assembly of collagen fibrils, regulate mineral deposition in bone, and modulate the activity of potent cellular growth factors through many signalling cascades. SLRPs belong to the group of extracellular leucine-rich repeat proteins that are flanked at both ends by disulphide-bonded caps that protect the hydrophobic core of the terminal repeats. A capping motif specific to SLRPs has been recently described in the crystal structures of the core proteins of decorin and biglycan. This motif, designated as LRRCE, differs in both sequence and structure from other, more widespread leucine-rich capping motifs. To investigate if the LRRCE motif is a common structural feature found in other leucine-rich repeat proteins, we have defined characteristic sequence patterns and used them in genome-wide searches.

Results

The LRRCE motif is a structural element exclusive to the main group of SLRPs. It appears to have evolved during early chordate evolution and is not found in protein sequences from non-chordate genomes. Our search has expanded the family of SLRPs to include new predicted protein sequences, mainly in fishes but with intriguing putative orthologs in mammals. The chromosomal locations of the newly predicted SLRP genes would support the large-scale genome or gene duplications that are thought to have occurred during vertebrate evolution. From this expanded list we describe a new class of SLRP sequences that could be representative of an ancestral SLRP gene.

Conclusion

Given its exclusivity the LRRCE motif is a useful annotation tool for the identification and classification of new SLRP sequences in genome databases. The expanded list of members of the SLRP family offers interesting insights into early vertebrate evolution and suggests an early chordate evolutionary origin for the LRRCE capping motif.

Decorin Modulates Fibrin Assembly and Structure

Emerging evidence indicates that fibrin clotting is regulated by different external factors. We demonstrated recently that decorin, a regulator of collagen fibrillogenesis and transforming growth factor-beta activity, binds to the D regions of fibrinogen (Dugan, T.A., Yang, V. W.-C., McQuillan, D.J., and Höök, M. (2003) J. Biol. Chem. 278, 13655-13662). We now report that the decorin-fibrinogen interaction alters the assembly, structure, and clearance of fibrin fibers. Relative to fibrinogen, substoichiometric amounts of decorin core protein modulated clotting, whereas an excess of an active decorin peptide was necessary for similar activity. These concentration-dependent effects suggest that decorin bound to the D regions sterically modulates fibrin assembly. Scanning electron microscopy images of fibrin clotted in the presence of increasing concentrations of decorin core protein showed progressively decreasing fiber diameter. The sequestration of Zn(2+) ions from the N-terminal fibrinogen-binding region abrogated decorin incorporation into the fibrin network. Compared with linear thicker fibrin fibers, the curving thin fibers formed with decorin underwent accelerated tissue-type plasminogen activator-dependent fibrinolysis. Collectively, these data demonstrate that decorin can regulate fibrin organization and reveal a novel mechanism by which extracellular matrix components can participate in hemostasis, thrombosis, and wound repair.

Structural correlations in the family of small leucine-rich repeat proteins and proteoglycans

The family of small leucine-rich repeat proteins and proteoglycans (SLRPs) contains several extracellular matrix molecules that are structurally related by a protein core composed of leucine-rich repeats (LRRs) flanked by two conserved cysteine-rich regions. The small proteoglycan decorin is the archetypal SLRP. Decorin is present in a variety of connective tissues, typically "decorating" collagen fibrils, and is involved in important biological functions, including the regulation of the assembly of fibrillar collagens and modulation of cell adhesion. Several SLRPs are known to regulate collagen fibrillogenesis and there is evidence that they may share other biological functions. We have recently determined the crystal structure of the protein core of decorin, the first such determination of a member of the SLRP family. This structure has highlighted several correlations: (1) SLRPs have similar internal repeat structures; (2) SLRP molecules are far less curved than an early model of decorin based on the three-dimensional structure of ribonuclease inhibitor; (3) the N-terminal and C-terminal cysteine-rich regions are conserved capping motifs. Furthermore, the structure shows that decorin dimerizes through the concave surface of its LRR domain, which has been implicated previously in its interaction with collagen. We have established that both decorin and opticin, another SLRP, form stable dimers in solution. Conservation of residues involved in decorin dimerization suggests that the mode of dimerization for other SLRPs will be similar. Taken together these results suggest the need for reevaluation of currently accepted models of SLRP interaction with their ligands.

Crystal Structure of the Biglycan Dimer and Evidence That Dimerization Is Essential for Folding and Stability of Class I Small Leucine-rich Repeat Proteoglycans

Biglycan and decorin are two closely related proteoglycans whose protein cores contain leucine-rich repeats flanked by disulfides. We have previously shown that decorin is dimeric both in solution and in crystal structures. In this study we determined whether biglycan dimerizes and investigated the role of dimerization in the folding and stability of these proteoglycans. We used light scattering to show that biglycan is dimeric in solution and solved the crystal structure of the glycoprotein core of biglycan at 3.40-angstroms resolution. This structure reveals that biglycan dimerizes in the same way as decorin, i.e. by apposition of the concave inner surfaces of the leucine-rich repeat domains. We demonstrate that low concentrations of guanidinium chloride denature biglycan and decorin but that the denaturation is completely reversible following removal of the guanidinium chloride, as assessed by circular dichroism spectroscopy. Furthermore, the rate of refolding is dependent on protein concentration, demonstrating that it is not a unimolecular process. Upon heating, decorin shows a single structural transition at a T(m) of 45-46 degrees C but refolds completely upon cooling to 25 degrees C. This property of decorin enabled us to show both by calorimetry and light scattering that dimer to monomer transition coincided with unfolding and monomer to dimer transition coincided with refolding; thus these processes are inextricably linked. We further conclude that folded monomeric biglycan or decorin cannot exist in solution. This implies novel interrelated functions for the parallel beta sheet faces of these leucine-rich repeat proteoglycans, including dimerization and stabilization of protein folding.

Modulation of collagen fibrillogenesis by dentinal proteoglycans

Studies have identified different pools of proteoglycan (PG) species present within the unmineralized matrix of the predentine, the transitional phase at the predentine-dentine interface and the mineralized dentine. These PGs alter with respect to the chemical nature of their glycosaminoglycan (GAG) chains and as a result of extracellular processing of the macromolecule in the matrix. The present study has examined the influence of the PGs isolated from these phases and the influence of the attached GAG chains, upon their ability to control collagen fibrillogenesis. PGs isolated from the three phases were characterized and determined to contain a mixture of decorin and biglycan. Results have indicated that predentine PGs, which are substituted with a higher proportion of dermatan sulfate, significantly delayed fibril formation while ultimately promoting the formation of thicker fibrils. Removal of the GAG chains further delayed fibrillogenesis, leading to the formation of thinner fibrils, compared with the collagen-only control. PGs isolated from predentine-dentine, which contained a higher proportion of chondroitin sulfate, also significantly delayed fibrillogenesis, resulting in thicker collagen fibrils. GAG chains attached to the predentine-dentine interface PGs played a role in the timing of fibrillogenesis with fibril formation initiated at the same time as the collagen control, but yielding thicker fibrils. Dentine PGs significantly inhibited fibrillogenesis and fibril thickness over concentrations of 50-25 microg/mL protein. In conclusion, the PGs isolated from the distinct phases have indicated differing roles in the orchestrated organization of the extracellular matrix during dentinogenesis, with roles for both the core protein and attached GAG chains indicated.

Overexpressed decorin in pancreatic cancer: potential tumor growth inhibition and attenuation of chemotherapeutic action

PURPOSE

The aim of this study was to investigate the expression and significance of decorin in pancreatic cancer.

EXPERIMENTAL DESIGN

Decorin expression in normal pancreas and excised tumors was examined by real-time quantitative PCR, Western blot analysis, and immunohistochemistry. Reverse transcription-PCR was used to analyze cultures of pancreatic cancer and stellate cells. Growth-inhibitory effects of decorin in vitro were assessed by 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide test, Western blot, and fluorescence-activated cell-sorting analysis.

RESULTS

Pancreatic cancer was characterized by striking overexpression of decorin mRNA in tumor tissues (9-fold by real-time quantitative PCR; 44 patients versus 18 healthy donors; P < 0.01). Strong decorin immunostaining was observed in the extracellular matrix of pancreatic cancer tissue, whereas tumor cells were devoid of decorin. Double staining for anti-smooth muscle actin and decorin and reverse transcription-PCR analysis of primary cultures revealed pancreatic stellate cells as the putative source of decorin. Human recombinant decorin was able to suppress growth of pancreatic cancer cells in vitro through p21 mediated G(1)-S block of the cell cycle. However, in contrast to the previously described chemotherapy-potentiating capacity of decorin, this proteoglycan attenuated the cytostatic action of carboplatin and gemcitabine toward pancreatic cancer cells.

CONCLUSIONS

Decorin might exert an antiproliferative effect toward pancreatic cancer cells, thus playing a role in a host stromal reaction aimed at sequestering and inhibiting growing malignant cells. However, in clinical settings, the importance of collagen-associated decorin as a moderate antitumor modality would be undermined by its ability to attenuate the efficiency of chemotherapeutics. Considering the general failure of adjuvant therapies in pancreatic cancer, the role of decorin in this process warrants further investigation.

Crystal structure of the dimeric protein core of decorin, the archetypal small leucine-rich repeat proteoglycan

Decorin is a ubiquitous extracellular matrix proteoglycan with a variety of important biological functions that are mediated by its interactions with extracellular matrix proteins, cytokines, and cell surface receptors. Decorin is the prototype of the family of small leucine-rich repeat proteoglycans and proteins (SLRPs), characterized by a protein core composed of leucine-rich repeats (LRRs), flanked by two cysteine-rich regions. We report here the crystal structure of the dimeric protein core of decorin, the best characterized member of the SLRP family. Each monomer adopts the curved solenoid fold characteristic of LRR domains, with a parallel beta-sheet on the inside interwoven with loops containing short segments of beta-strands, 3(10) helices, and polyproline II helices on the outside. Two main features are unique to this structure. First, decorin dimerizes through the concave surfaces of the LRR domains, which have been implicated previously in protein-ligand interactions. The amount of surface buried in this dimer rivals the buried surfaces of some of the highest-affinity macromolecular complexes reported to date. Second, the C-terminal region adopts an unusual capping motif that involves a laterally extended LRR and a disulfide bond. This motif seems to be unique to SLRPs and has not been observed in any other LRR protein structure to date. Possible implications of these features for decorin ligand binding and SLRP function are discussed.

Characterization of opticin and evidence of stable dimerization in solution

Opticin is a class III member of the extracellular matrix small leucine-rich repeat protein (SLRP) family that was initially identified in the eye in association with the collagen fibrils of the vitreous humor. Recombinant and tissue-extracted forms of bovine opticin were subjected to biochemical and biophysical characterization. Following SDS-PAGE the predominant component produced by both forms was a broad band between 45-52 kDa. There was evidence for two-stage processing and, additionally, a proteolytic cleavage product of approximately 25 kDa. Deconvolution of circular dichroism spectra revealed beta-sheet (41%), beta-turn (21%), and alpha-helix (10%), and thermal denaturation experiments showed a transition with a midpoint of 47 degrees C. Weight-averaged molecular mass measurements using both light scattering and analytical ultracentrifugation demonstrated that opticin exists in solution as a stable dimer of approximately 90 kDa, which can be dissociated into a monomer by denaturation with 2.5 m guanidine hydrochloride or during SDS-polyacrylamide electrophoresis. Opticin remains a dimer after removal of the amino-terminal region by O-sialoglycoprotein endopeptidase digestion, suggesting that dimer formation is mediated by the leucine-rich repeats. Dimerization could have a number of functional consequences, including divalent ligand interactions.

Light and X-ray scattering show decorin to be a dimer in solution

Decorin is a widely distributed member of the extracellular matrix small leucine-rich repeat glycoprotein/proteoglycan family. For investigation of its physical properties, decorin from two sources (young steer skin and a recombinant adenovirus) was used. The first sample was extracted into 7 m urea and purified, while the second was isolated from medium conditioned by 293A cells infected with adenovirus and purified without chaotropes. The only chemical differences detected between these materials were a slightly shorter glycosaminoglycan chain and the retention of the propeptide on the latter. Circular dichroism spectra of the two samples were virtually identical, showing a high proportion of beta-sheet and beta-turn and little alpha-helix. The protein cores were completely denatured in 2.25 m guanidine HCl (GdnHCl) but recovered their secondary structure on removal of chaotrope. Light scattering of material eluted from gel-filtration columns in Tris-buffered saline, pH 7.0, gave molecular mass values of 165 +/- 1 kDa and 84.6 +/- 4 kDa for intact decorin and the glycoprotein core produced by digestion with chondroitin ABC lyase, respectively. Intact recombinant prodecorin had a mass of 148 +/- 18 kDa. These values, which are double those estimated from SDS gel electrophoresis or from the known sequences and compositions, were halved in 2.5 m GdnHCl. Data from solution x-ray scattering of intact decorin and its core in Tris-buffered saline are consistent with a dimeric particle whose protein component has a radius of gyration of 31.6 +/- 0.4 A, a maximum diameter of 98 +/- 5 A, and approximates two intertwined C shapes.

LGI1 is mutated in familial temporal lobe epilepsy characterized by aphasic seizures

Autosomal dominant lateral temporal lobe epilepsy previously has been linked to chromosome 10q22-q24, and recently mutations in the LGI1 gene (Leucine-rich gene, Glioma Inactivated) have been found in some autosomal dominant lateral temporal lobe epilepsy families. We have now identified a missense mutation affecting a conserved cysteine residue in the extracellular region of the LGI1 protein. The C46R mutation is associated with autosomal dominant lateral temporal lobe epilepsy in a large Norwegian family showing unusual clinical features like short-lasting sensory aphasia and auditory symptoms.

Roles of lumican and keratocan on corneal transparency

Lumican and keratocan are members of the small leucine-rich proteoglycan (SLRP) family, and are the major keratan sulfate (KS) proteoglycans in corneal stroma. Both lumican and keratocan are essential for normal cornea morphogenesis during embryonic development and maintenance of corneal topography in adults. This is attributed to their bi-functional characteristic (protein moiety binding collagen fibrils to regulate collagen fibril diameters, and highly charged glycosaminoglycan (GAG) chains extending out to regulate interfibrillar spacings) that contributes to their regulatory role in extracellular matrix assembly. The absence of lumican leads to formation of cloudy corneas in homozygous knockout mice due to altered collagenous matrix characterized by larger fibril diameters and disorganized fibril spacing. In contrast, keratocan knockout mice exhibit thin but clear cornea with insignificant alteration of stromal collaegenous matrix. Mutations of keratocan cause cornea plana in human, which is often associated with glaucoma. These observations suggest that lumican and keratocan have different roles in regulating formation of stromal extracellular matrix. Experimental evidence indicates that lumican may have additional biological functions, such as modulation of cell migration and epithelium-mesenchyme transition in wound healing and tumorgenesis, besides regulating collagen fibrillogenesis.

Deficiency of the decorin core protein in the variant form of Ehlers-Danlos syndrome with chronic skin ulcer

Decorin belongs to a family of small leucine-rich dermatan sulfate proteoglycans that are involved in the control of matrix organization and cell growth. Here, we described a patient whose skin glycosaminoglycans showed extremely decreased amount of dermatan sulfate compared with a normal control skin. This patient presented clinical features of Ehlers-Danlos syndrome with a chronic skin ulcer. Western blotting revealed that the deficiency of dermatan sulfate was due to the defect of decorin core protein. Beta-xyloside, an initiator of dermatan sulfate glycosaminoglycan chain elongation, enhanced the synthesis of dermatan sulfate in the fibroblasts of the patient to a similar extent to that of control. This result indicated that the enzymes for the elogation of dermatan sulfate side chains were normal. Northern blotting demonstrated remarkable reduction of decorin mRNA level, while biglycan mRNA level was concomitantly increased and procollagen alpha1(I) mRNA level was normal. cDNA and exons sequencing analysis showed there was no mutation in decorin gene of the patient. IL-1beta stimulated decorin expression to about 140% in control fibroblasts while about 110% in patient fibroblasts. On the other hand, TGF-beta1 resulted in 40% reductions of decorin expression in both control and patient fibroblasts. These data suggested that reduced decorin expression of fibroblasts from the patient of Ehlers-Danlos syndrome may be due to abnormalities in the regulatory regions, which is responsible for the IL-1beta stimulation.

Surface ultrastructure of collagen fibrils and their association with proteoglycans in human cornea and sclera by atomic force microscopy and energy-filtering transmission electron microscopy

PURPOSE

We aimed to investigate the possible association of proteoglycans with D-periodic collagen fibrils in the human cornea and sclera, using energy-filtering transmission electron microscopy (EF-TEM) and atomic force microscopy (AFM).

METHODS

Human cornea and sclera were digested with keratanase to eliminate keratan sulfate proteoglycans (KSPGs). For EF-TEM observation, surface proteoglycans were detected by cupromeronic blue (CB) staining. For AFM observation, cornea and sclera were treated with sodium hydroxide before and after keratanase digestion, and the surface topology of collagen fibrils was analyzed.

RESULTS

With CB staining, numerous CB-positive short filaments of surface proteoglycans (proteoglycan filaments) were observed in the interfibrillar spaces of cornea and sclera associated with collagen fibrils. AFM imaging showed that the depth and periodicity of D-periodic collagen fibrils in keratanase-treated corneal collagens were deeper and more regular than in untreated ones. Moreover, the depth and periodicity of keratanase-untreated corneal collagens were shallow and irregular in comparison with keratanase-untreated scleral collagens. On the other hand, there was no difference in depth or regularity between keratanase-treated and -untreated scleral collagen fibrils. Using AFM imaging, additional thin grooves sub-bands were detected on the surface of keratanase-treated corneal collagen fibrils. The grooves were not detected in keratanase-untreated collagen fibrils nor in scleral collagen fibrils with or without keratanase digestion. Comparing densitometry waves, the grooves of D-periodic corneal collagen sub-bands corresponded to a and c bands.

CONCLUSION

Using AFM and EF-TEM to study corneal and scleral collagen fibrils and their association with proteoglycans, we conclude that KSPG is found in ample amounts in the human cornea in comparison with sclera. Moreover, we topologically detected KSPG attached to a and c bands of collagen fibrils.

Biglycan and decorin bind close to the n-terminal region of the collagen VI triple helix

The binding of native biglycan and decorin to pepsin-extracted collagen VI from human placenta was examined by solid phase assay and by measurement of surface plasmon resonance in the BIAcore(TM)2000 system. Both proteoglycans exhibited a strong affinity for collagen VI with dissociation constants (K(D)) of approximately 30 nm. Removal of the glycosaminoglycan chains by chondroitinase ABC digestion did not significantly affect binding. In coprecipitation experiments, biglycan and decorin bound to collagen VI and equally competed with the other, suggesting that biglycan and decorin bind to the same binding site on collagen VI. This was confirmed by electron microscopy after negative staining of complexes between gold-labeled proteoglycans and collagen VI, demonstrating that both biglycan and decorin bound exclusively to a domain close to the interface between the N terminus of the triple helical region and the following globular domain. In solid phase assay using recombinant collagen VI fragments, it was shown that the alpha2(VI) chain probably plays a role in the interaction.

Structural and functional comparison of polysaccharide-degrading enzymes

Sugar molecules as well as enzymes degrading them are ubiquitously present in physiological systems, especially for vertebrates. Polysaccharides have at least two aspects to their function, one due to their mechanical properties and the second one involves multiple regulatory processes or interactions between molecules, cells, or extracellular space. Various bacteria exert exogenous pressures on their host organism to diversity glycans and their structures in order for the host organism to evade the destructive function of such microbes. Many bacterial organism produce glycan-degrading enzymes in order to facilitate their invasion of host tissues. Such polysaccharide degrading enzymes utilize mainly two modes of polysaccharide-degradation, a hydrolysis and a beta-elimination process. The three-dimensional structures of several of these enzymes have been elucidated recently using X-ray crystallography. There are many common structural motifs among these enzymes, mainly the presence of an elongated cleft transversing these molecules which functions as a polysaccharide substrate binding site as well as the catalytic site for these enzymes. The detailed structural information obtained about these enzymes allowed formulation of proposed mechanisms of their action. The polysaccharide lyases utilize a proton acceptance and donation mechanism (PAD), whereas polysaccharide hydrolases use a direct double displacement (DD) mechanism to degrade their substrates.

Decorin binds near the C terminus of type I collagen

Decorin belongs to a family of small leucine-rich proteoglycans that are directly involved in the control of matrix organization and cell growth. Genetic evidence indicates that decorin is required for the proper assembly of collagenous matrices. Here, we sought to establish the precise binding site of decorin on type I collagen. Using rotary shadowing electron microscopy and photoaffinity labeling, we mapped the binding site of decorin protein core to a narrow region near the C terminus of type I collagen. This region is located within the cyanogen bromide peptide fragment alpha1(I) CB6 and is approximately 25 nm from the C terminus, in a zone that coincides with the c(1) band of the collagen fibril d-period. This location is very close to one of the major intermolecular cross-linking sites of collagen heterotrimers. Thus, decorin protein core possesses a unique binding specificity that could potentially regulate collagen fibril stability.

Quantification of hyaluronan and chondroitin/dermatan sulfates in the tissue sections on glass slides

The method for the determination of hyaluronan and chondroitin/dermatan sulfates in the tissue sections on a glass slide, which were prepared by histological technique, was established by applying to porcine skin. The degradation of these glycosaminoglycans to the unsaturated disaccharides in porcine skin sections on a glass slide was achieved by chondroitinase ABC and ACII in the presence of highly purified bacterial collagenase. Subsequently, the resulting unsaturated disaccharides were determined by HPLC with fluorometric postcolumn derivatization using 2-cyanoacetamide as a reagent. So far, the determination of the glycosaminoglycans in the tissues has taken up more than 5 days, whereas the determination of the glycosaminoglycans in the frozen sections by the present method was completed within a day. In addition, applications of the present method to the serial polyester wax sections processed with a small surgical knife made it possible to determine the glycosaminoglycans in a local part in the tissue section. The present method should open a way for the clinical analysis of glycosaminoglycans in the pathological tissue samples.

Matrix proteoglycans: from molecular design to cellular function

The proteoglycan superfamily now contains more than 30 full-time molecules that fulfill a variety of biological functions. Proteoglycans act as tissue organizers, influence cell growth and the maturation of specialized tissues, play a role as biological filters and modulate growth-factor activities, regulate collagen fibrillogenesis and skin tensile strength, affect tumor cell growth and invasion, and influence corneal transparency and neurite outgrowth. Additional roles, derived from studies of mutant animals, indicate that certain proteoglycans are essential to life whereas others might be redundant. The review focuses on the most recent genetic and molecular biological studies of the matrix proteoglycans, broadly defined as proteoglycans secreted into the pericellular matrix. Special emphasis is placed on the molecular organization of the protein core, the utilization of protein modules, the gene structure and transcriptional control, and the functional roles of the various proteoglycans. When possible, proteoglycans have been grouped into distinct gene families and subfamilies offering a simplified nomenclature based on their protein core design. The structure-function relationship of some paradigmatic proteoglycans is discussed in depth and novel aspects of their biology are examined.

Apolipoprotein(a) binds via its C-terminal domain to the protein core of the proteoglycan decorin. Implications for the retention of lipoprotein(a) in atherosclerotic lesions

Although it is known that lipoprotein(a) (Lp(a)) binds to proteoglycans, the mechanism for this binding has not been fully elucidated. In order to shed light on this subject, we examined the interactions of decorin, a proteoglycan with a well defined protein core and a single glycosaminoglycan (GAG) chain, with Lp(a) and derivatives, namely Lp(a) deprived of apo(a), or Lp(a-), free apo(a), and the two main proteolytic fragments, F1 and F2. By circular dichroism criteria, the decorin preparations used had the same secondary structure as that previously reported for native decorin. Authentic low density lipoprotein from the same human donor was used as a control. In a solid phase system, Lp(a-)and low density lipoprotein bound to decorin in a comparable manner. This binding required Ca2+/Mg2+ ions, was lysine-mediated, and was markedly decreased in the presence of GAG-depleted decorin, suggesting the ionic nature of the interaction likely involving apoB100 and the GAG component of decorin. Free apo(a) also bound to decorin; however, the binding was neither cation-dependent nor lysine-mediated, unaffected by sialic acid depletion of apo(a), and markedly decreased when either reduced and alkylated apo(a) or reduced and alkylated decorin was used in the assay. Of note, the binding of apo(a) was unaffected when it was incubated with a spectrally native decorin that had been renatured from either 4 M guanidine hydrochloride by extensive dialysis or cooled from 65 to 25 degrees C. On the other hand, the binding significantly increased when decorin was depleted of GAGs, which by themselves had no affinity for apo(a). The binding of apo(a) to the decorin protein core was also elicited by the C-terminal domain of apo(a), and it was favored by high NaCl concentrations, 1 to 2 M. No binding was exhibited by the N-terminal domain accounting for the lack of effect of apo(a) size polymorphism on the binding. In the case of whole Lp(a), the binding to immobilized decorin was mostly GAG-dependent and ionic in nature. A minor contribution by apo(a) was detected when GAG-depleted decorin was used in the assay. Our results indicate that the binding of Lp(a) to decorin involves interactions both electrostatic (apoB100-GAG) and hydrophobic (apo(a)-decorin protein core), and that the binding of apo(a) requires decorin protein core to be in its native state.

Increased diameters of collagen fibrils precipitated in vitro in the presence of decorin from various connective tissues

Proteoglycans were isolated from bovine skin, sclera, deep flexor tendon and the periphery of the temporomandibular joint disc with urea. Decorin was purified from each of these extracts by ion-exchange, hydrophobic-interaction and gel-filtration chromatography. Purities were assessed by amino acid analysis and by sodium dodecylsulphate polyacrylamide gel electrophoresis (SDS-PAGE) of the protein cores released by digestion with chondroitin-ABC-lyase. In these respects the decorins were indistinguishable. However the glycosaminoglycan chains released by digesting the proteoglycans with papain varied widely in mobility on SDS-PAGE: that from skin decorin migrating fastest and that from tendon decorin slowest. The effects of each of the decorins on collagen fibrillogenesis in vitro were similar, all reducing the rate of fibril growth (by 55 to 71%, depending on the source of the proteoglycan) and increasing the diameters of the fibrils formed (by 27 to 66%). Core protein alone, isolated from skin decorin, reduced the rate of fibril growth as effectively as intact decorin, but had no effect on the diameter of fibrils formed. The dermatan sulphate chain and the protein thus appear to play different roles in the interaction of intact decorin with collagen. These data suggest that decorin found in fibrous connective tissues may increase Type I collagen fibril diameters, resulting in tissues that are better able to withstand tensile forces.

The structure of interfibrillar proteoglycan bridges (shape modules') in extracellular matrix of fibrous connective tissues and their stability in various chemical environments

Collagen fibrils in extracellular matrices of connective tissues (tendon, cornea, etc.) are bridged and linked by the anionic glycosaminoglycans (AGAGs) of the small proteoglycans (decoron, etc.). It was proposed that these bridges and ties maintain the collagen fibril dispositions in relation to each other, helping to define tissue shape, and hence called shape modules. This investigation describes chemical and physicochemical conditions in which these structures are stable and what treatments cause their disruption. The effects on fixed and unfixed sections of tendon, cornea, lung and ear from rat, mouse and rabbit of pH, electrolyte concentration, EDTA, mercaptoethanol, hydrogen peroxide, free radicals, periodate, acetylation, urea, nonionic detergent and organic solvents were assessed by staining with Cupromeronic blue or Alcec blue in CEC techniques to localise AGAG bridges or their disintegration products. Ca2+ was not involved in the structures, oxidation/reduction had no effect and Triton X100, a nonionic detergent did not damage them. They were stable between pH 4.5 and 9.5. Periodate as a glycol-cleaving reagent did not affect them. High concentrations of urea (> 2.0 M) and MgCl2 (0.5 M) disrupted the tissues. The combination of Triton and urea at concentrations too low to cause damage separately was disruptive. Free radicals in periodate solutions were damaging. Organic solvents caused collapse and rearrangements of the AGAG filaments. Acetylation caused considerable disruption of shape modules. Dermochondan but not keratan sulphate AGAGs were removed by treatment with NaOH. After fixing with glutaraldehyde only free radical and NaOH treatments were severely disruptive of shape modules. The results are compatible with a previously proposed structure for the shape modules, stabilised by hydrophobic and hydrogen bonding.

Leucine-rich repeat glycoproteins of the extracellular matrix

The extracellular matrix plays an integral role in the pivotal processes of development, tissue repair, and metastasis by regulating cell proliferation, differentiation, adhesion, and migration. This review is focused on a family of related glycoproteins represented by at least one member in all specialized extracellular matrices. This family currently comprises nine members grouped together on the basis of their presence in the extracellular matrix and by virtue of a leucine-rich repeat motif that dominates the structure of the core protein. It is likely that most, if not all the members of this group exist as proteoglycans in some tissues, and thus have been termed the Small Leucine-Rich Proteoglycan family, or SLRPs. The leucine-rich repeat (LRR) is usually present in tandem array and has been described in an increasing number of proteins, giving rise to a LRR-superfamily. The LRR domain of the SLRP family is unique within the superfamily in that it is flanked by cysteine clusters, and the 24 amino acid consensus for SLRP members is x-x-I/V/L-x-x-x-x-F/P/L-x-x-L/P-x-x-L-x-x-L/I-x-L-x-x-N-x-I/L, where x is any amino acid. Enormous progress has been made in describing the membership, structure and localization of this family, and recently new insight has emerged into the putative function of these molecules not just as modulators of matrix assembly but also on their intriguing role in regulating cell growth, adhesion, and migration. Determination of membership, structure and putative function of this fascinating class of molecules is summarized in this review.

Isolation and characterization of small proteoglycans from different zones of the porcine knee meniscus

Pig knee menisci were dissected into three zones of equal width representing inner, i.e. medial (zone 1), middle (zone 2) and outer, i.e. lateral (zone 3) tissue. Proteoglycans (PGs) were extracted with guanidinium chloride, isolated by ion-exchange chromatography and separated into two groups ('small' and 'large') by gel filtration. The small PGs were further fractionated by hydrophobic-interaction chromatography on Octyl-Sepharose. The PG eluting earliest from Octyl-Sepharose was identified as decorin on the basis of the size of the protein core produced by digestion with chondroitinase ABC, its recognition by monoclonal antibodies raised against bovine decorin and its N-terminal sequence, 23 of 24 amino acids of which were identified. Decorin represented about 23%, 28% and 32% of the total small PG recovered from Octyl-Sepharose from zones 1, 2 and 3, respectively. The major small PG in the meniscus, eluting from Octyl-Sepharose after decorin, was identified as biglycan by the size of core, recognition by a polyclonal antiserum raised against bovine biglycan and sequence of the N-terminal 26 amino acids. Biglycan accounted for approximately 53%, 52% and 38% of PG recovered from zones 1, 2 and 3, respectively. The glycosaminoglycan chains on both decorin and biglycan were identified as dermatan sulphate by their susceptibility to chondroitinase-B. Stains-All staining of SDS gels of Octyl-Sepharose eluates revealed the presence of a third small PG eluting slightly later than biglycan. This PG was purified by a further cycle of chromatography on Octyl-Sepharose and identified as fibromodulin on the basis of its amino acid composition and the N-terminal sequence obtained after digestion with pyroglutamate aminopeptidase. It was obtained in highest amounts from the inner (zone 1) tissue, which also yielded more biglycan and less decorin. Fibromodulin from the meniscus was shown to inhibit the formation of fibrils from a solution of type I collagen, independently of the effects of decorin. These results support the concept that the distributions and characteristics of the small PGs in knee meniscus reflect regional adaptation to functional demands.

Targeted disruption of decorin leads to abnormal collagen fibril morphology and skin fragility

Decorin is a member of the expanding group of widely distributed small leucine-rich proteoglycans that are expected to play important functions in tissue assembly. We report that mice harboring a targeted disruption of the decorin gene are viable but have fragile skin with markedly reduced tensile strength. Ultrastructural analysis revealed abnormal collagen morphology in skin and tendon, with coarser and irregular fiber outlines. Quantitative scanning transmission EM of individual collagen fibrils showed abrupt increases and decreases in mass along their axes. thereby accounting for the irregular outlines and size variability observed in cross-sections. The data indicate uncontrolled lateral fusion of collagen fibrils in the decorindeficient mice and provide an explanation for the reduced tensile strength of the skin. These findings demonstrate a fundamental role for decorin in regulating collagen fiber formation in vivo.

The family of the small leucine-rich proteoglycans: key regulators of matrix assembly and cellular growth

The focus of this review is on conceptual and functional advances in our understanding of the small leucine-rich proteoglycans. These molecules belong to an expanding gene class whose distinctive feature is a structural motif, called the leucine-rich repeat, found in an increasing number of intracellular and extracellular proteins with diverse biological attributes. Three-dimensional modeling of their prototype protein core proposes a flexible, arch-shaped binding surface suitable for strong and distinctive interactions with ligand proteins. Changes in the properties of individual proteoglycans derive from amino acid substitutions in the less conserved surface residues, changes in the number and length of the leucine-rich repeats, and/or variation in glycosylation. These proteoglycans are tissue organizers, orienting and ordering collagen fibrils during ontogeny and in pathological processes such as wound healing, tissue repair, and tumor stroma formation. These properties are rooted in their bifunctional character: the protein moiety binding collagen fibrils at strategic loci, the microscopic gaps between staggered fibrils, and the highly charged glycosaminoglycans extending out to regulate interfibrillar distances and thereby establishing the exact topology of fibrillar collagens in tissues. These proteoglycans also interact with soluble growth factors, modulate their functional activity, and bind to cell surface receptors. The latter interaction affects cell cycle progression in a variety of cellular systems and could explain the purported changes in the expression of these gene products around the invasive neoplastic cells and in regenerating tissues.

Small proteoglycans from different regions of the fibrocartilaginous temporomandibular joint disc

Proteoglycans were isolated from two zones--the periphery and the inner zone--of bovine temporomandibular joint articular discs and separated into two pools by gel-filtration. Proteoglycans in the low molecular mass pool were further resolved by hydrophobic affinity chromatography into two groups identified by cyanogen bromide peptide analysis, amino acid analysis and amino-terminal sequence analysis as PGI (biglycan) and PGII (decorin). These two proteoglycans were isolated in approximately equal proportions from the 'inner' disc tissue but PGII predominated in the 'outer' tissue. Direct chemical analysis showed that the glycosaminoglycan chains on both PGI and PGII were high in iduronate (64-68% of total uronic acid). The dermatan sulfate chains on proteoglycans from the inner disc tissue were longer than those from the outer tissue. Comparison of the galactosamine contents of the intact proteoglycans with electrophoretic mobilities of the isolated dermatan sulfate chains showed that the PGI from the disc carries two dermatan sulfate chains. Inclusion of disc DS-PGI in a solution of soluble type I collagen lengthened the lag-phase, steepened the turbidity-time curve and increased the final opacity attained during fibril formation in vitro. The median fibril diameter and the range of diameters were both higher in the presence of DS-PGI. By contrast, disc DS-PGII reduced the slope of the turbidity-time curve but had little effect on the final turbidity or the fibril diameter.

Decorin-type I collagen interaction. Presence of separate core protein-binding domains

Interactions between the core protein of the small dermatan sulfate proteoglycan decorin and type I collagen have been considered to influence the kinetics of collagen fibrillogenesis and the diameter of and the distance between the fibrils. A variety of recombinant core protein fragments were expressed in Escherichia coli, extracted from inclusion bodies, and renatured in the presence of bovine serum albumin, which was essential for obtaining functional activity. A recombinant protein lacking the first 14 amino acids of the mature core protein (P15-329) interacted with reconstituted type I collagen fibrils and inhibited collagen fibrillogenesis almost as efficiently as intact decorin purified from fibroblast secretions under non-denaturing conditions. Peptides comprising amino acids 15-183 (P15-183) and 185-329 (P185-329) were able to compete for the binding of wild-type decorin, with P15-183 being more active than P185-329. Several other peptides were much less effective. Binding studies using radioactively labeled peptides P15-183 and P185-329 gave direct evidence for the independent binding of both peptides. Peptides 15-183 and 15-125 had the capability of inhibiting collagen fibrillogenesis, whereas peptide 185-329 was inactive. These data suggest (i) that there are at least two separate binding domains for the interaction between decorin core protein and type I collagen and (ii) that binding is not necessarily correlated with an alteration of collagen fibrillogenesis.

Interaction of biglycan with type I collagen

The small proteoglycan decorin is known to interact with type I collagen fibrils, thereby influencing the kinetics of fibril formation and the distance between adjacent collagen fibrils. The structurally related proteoglycan biglycan has been proposed not to bind to fibrillar collagens. However, when osteosarcoma cells were cultured on reconstituted type I collagen fibrils, both decorin and biglycan were retained by the matrix. Immunogold labeling at the electron microscopic level showed that both proteoglycans were distributed along collagen fibrils not only in osteosarcoma cell-populated collagen lattices but also in human skin. Reconstituted type I collagen fibrils were able to bind in vitro native and N-glycan-free biglycan as well as recombinant biglycan core protein. From Scatchard plots dissociation, constants were obtained that were higher for glycanated biglycan (8.7 x 10(-8) mol/liter) than for glycanated decorin (7 x 10(-10) mol/liter and 3 x 10(-9) mol/liter, respectively). A similar number of binding sites for either proteoglycan was calculated. Recombinant biglycan and decorin were characterized by lower dissociation constants compared with the glycanated forms. Glycanated as well as recombinant decorin competed with glycanated biglycan for collagen binding, suggesting that identical or adjacent binding sites on the fibril are used by both proteoglycans. These data suggest that, because of its trivalency, biglycan could have a special organizing function on the assembly of the extracellular matrix.

Iduronic acid-rich proteoglycans (PGIdoA) and human post-burn scar maturation: isolation and characterization

Proteoglycans (PGs) were extracted from human hypertrophic and normal scar tissues from two different stages of maturation after burn injury, under dissociative conditions (4 M guanidinium chloride containing proteinase inhibitors). The extracts were fractionated by ion-exchange chromatography, followed by ethanol precipitation, to give PG-containing iduronic acid (PGIdoA). The size of the PGIdoA decreased with the maturation of scars. Glycosaminoglycan (GAG) chains from PGIdoA were released by alkaline borohydride treatment, and their M(r) values were evaluated by polyacrylamide gel electrophoresis. The M(r) values for PGIdoA protein cores of the hypertrophic scars (5+ years and 2-5 years) and normal scar (5+ years and 2-5 years) were 22.6, 25, 19 and 21 kDa, respectively. The iduronic acid content of PGIdoA from both types of scar increased in their maturation phase. The M(r) values of PGIdoA decreased with maturation. PGIdoA carried the sulfate group mainly attached at C-4 of the 2-amino-2-deoxy-D-galactose residue. The NH2-terminal amino acid sequences of all the PGIdoA were similar to those of normal human skin or bone PG II (decorin) (i.e., Asp-Glu-Ala-B-Gly-Ile-Gly-Pro-Glu-Val-Pro-Asp-Asp-Arg).

Changes in the expression of decorin and biglycan in human articular cartilage with age and regulation by TGF-beta

In chondrocytes isolated directly from human articular cartilage, without subsequent culture, biglycan mRNA levels decreased with the age of the donor, whereas those for decorin increased. In cultured chondrocytes in the presence of FCS, mRNA levels for biglycan remained similar to those in uncultured counterparts, while decorin transcription became depressed. The differential effect on decorin and biglycan mRNA expression was mimicked by the addition of TGF-beta. In the absence of exogenously added growth factors (TGF-beta or FCS) biglycan mRNA levels decreased, while those for decorin increased. In contrast, IGF-I showed no differential modulation of the relative abundance of the two messages. The opposite regulation of these two proteoglycans by TGF-beta was also reflected at the level of protein synthesis. It would appear that the need of articular cartilage for decorin is greatest in the adult, whereas the need for biglycan is greatest in the juvenile.

The interaction of decorin core protein fragments with type I collagen

To further define the molecular interaction between decorin and type I collagen we generated a 20 kD fragment containing the N-terminal half of the core protein by Endoproteinase Arg C digestion and a 40 kD fragment including all leucine-rich repeats in the central part of decorin core by cleavage with 2-nitro-5-thiocyanobenzoate. The fragments did not influence collagen fibril formation, even at high concentration, and radioactive fragments showed little binding to collagen fibrils. Our observations suggest that neither the N-terminal half nor the central leucine-rich repeats of the decorin core protein can, by itself, interact fully with fibrillar collagen.

Presence of small proteoglycan fragments in normal and arthritic human cartilage

OBJECTIVE

To characterize the small proteoglycans decorin and biglycan in normal human patellar cartilage and in cartilage from individuals with chronic polyarthritis.

METHODS

Cartilage extracts were chromatographed on DEAE-Trisacryl and further separated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis before and after enzymatic degradation of the glycosaminoglycan chains. Decorin and biglycan were visualized after Western blotting, using core protein-specific polyclonal and monoclonal antibodies.

RESULTS

Core protein fragments of both proteoglycans were observed even in normal cartilage. In the case of decorin they amounted to up to 15% of the immunoreactive material, and up to 5% of the core protein was glycosaminoglycan free. The quantity of decorin core protein was reduced in arthritic cartilage, but the core protein fragments represented up to 45% of the immunoreactive material. Different zones of cartilage differed in their content of the fragments. Evidence for an increased proportion of biglycan fragments was not obtained.

CONCLUSION

Chronic polyarthritis leads to increased degradation of small proteoglycans. A considerable proportion of decorin fragments is retained in the tissue. These alterations may have a negative influence on the mechanical stability of tissue.

Influence of continuous infusion of interleukin-1 alpha on the core protein and the core protein fragments of the small proteoglycan decorin in cartilage

Decorin, a collagen-binding small proteoglycan, is considered to have a specific function in the organization or stability of the collagen network. Therefore, alteration of its molecular properties may be of pathophysiological relevance during the development of cartilage damage. It is shown here that normal cartilage from rabbit knee-joint contains glycosaminoglycan chain-bearing core protein fragments of 39, 23, and 18 kDa, each one amounting to approximately 5-6% of the intact decorin core protein. Continuous infusion of human recombinant interleukin-1 alpha for 14 days (200 ng/day) into a knee-joint led in condylar cartilage to a reduction in the amount of intact core protein from 2 micrograms/mg wet tissue to about 1.1 micrograms/mg. The increase in its quantity found after infusion of heat-inactivated interleukin-1 was not statistically significant. The concentration of all three core protein fragments became reduced to a similar extent as the intact core protein under the influence of the cytokine, and additional fragments were not found. Surprisingly, there was a much smaller response to interleukin-1-treatment in patellar cartilage.

Binding of heparin and of the small proteoglycan decorin to the same endocytosis receptor proteins leads to different metabolic consequences

Decorin, a small interstitial dermatan sulfate proteoglycan, is turned over in cultured cells of mesenchymal origin by receptor-mediated endocytosis followed by intralysosomal degradation. Two endosomal proteins of 51 and 26 kD have been implicated in the endocytotic process because of their interaction with decorin core protein. However, heparin and protein-free dermatan sulfate were able to inhibit endocytosis of decorin in a concentration-dependent manner. After Western blotting of endosomal proteins, there was competition for binding to the 51- and 26-kD proteins between heparin and decorin. In spite of its high-affinity binding, heparin was poorly cleared from the medium of cultured cells and then catabolized in lysosomes. In contrast to decorin, binding of heparin to the 51- and 26-kD proteins was insensitive to acidic pH, thus presumably preventing its dissociation from the receptor in the endosome. Recycling of heparin to the cell surface after internalization could indeed be demonstrated.

Characterization of thrombospondin binding to collagen (type I) fibres: role of collagen telopeptides

We have shown that thrombospondin (tsp), like fibronectin (fn) and von Willebrand factor (vWf), exhibits a rapid, specific and saturable binding to collagen type I fibres (from bovine tendon). The level of binding at saturation is very similar to that of vWf. As with fn and vWf, the interaction is ionic in character and appears to occur by a polyvalent mechanism since there is little inhibition of interaction by monomeric collagen. The conformation of tsp, like that of fn and vWf, is important since denaturation causes reduced complexing. Furthermore, conformational changes in tsp due to the presence of Ca++ can modulate the amount of complex formed under physiological conditions. Tsp, like vWf but in contrast to fn, shows little affinity for denatured fibres emphasizing the importance of collagen conformation. Pepsin digestion suggests an important role for collagen telopeptides; vWf- and fn-binding sites are located more within the collagen triple helix. Comparison of the effect on binding after leucine aminopeptidase or carboxypeptidase digestion suggests involvement of the N- rather than C-terminal telopeptides. No evidence was found for a role for fn, the proteoglycan PG2 or collagen type V, which could be present in type I fibres, in mediating the interaction between tsp and the fibres. VWf did not inhibit the interaction of tsp, but fn did slightly when tested in large excess. This suggests separate binding sites in collagen for all three ligands since fn and vWf are also known to bind independently of each other.

Biosynthesis of bone proteins by fetal porcine calvariae in vitro. Rapid association of sulfated sialoproteins (secreted phosphoprotein-1 and bone sialoprotein) and chondroitin sulfate proteoglycan (CS-PGIII) with bone mineral

To study the biosynthesis of bone proteins, fragments of fetal porcine calvariae were cultured in the presence of 50 micrograms/ml ascorbate and 10 mM beta-glycerophosphate and individual cultures labeled for either 4 h or 48 h with [35S]-methionine, Na2[35SO4], Na3[32PO4] or [14C]-glycine plus [14C]-proline. The radiolabeled proteins in tissue extracts were obtained by sequential extraction with 4 M GuHCl (G1-extract), 0.5 M EDTA (E-extract), and again with 4 M GuHCl (G2-extract) and analyzed together with the radiolabeled proteins secreted into the medium. SPP-1 (secreted phosphoprotein 1, osteopontin) was the major non-collagenous protein deposited into the bone matrix, with lesser amounts of BSP (bone sialoprotein), osteocalcin and chondroitin sulfate proteoglycans (CS-PG II and CS-PG III). SPP-1 was also the major phosphorylated protein and was recovered, together with several fragmented forms, almost entirely in the demineralizing extracts. Moreover, approximately one-half of the [35SO4] incorporated into E-extract proteins was present in SPP-1, the remainder being incorporated into PGs with smaller amounts associated with BSP. Over 65% of the [35SO4] in the proteoglycans of the demineralizing extracts was recovered in the small CS-PG III with less than 35% in CS-PG II, the bone homologue of DS-PG II (decorin). In contrast, CS-PG II was the predominant small proteoglycan in culture media and in guanidine extracts. Some sulfated BSP was also observed in guanidine extracts and small amounts appeared to bind to collagen. Radiolabeled SPARC (osteonectin), a prominent protein of fetal porcine bone, was not detected in the mineralized bone tissues but was prominent in the culture medium. These results demonstrate that following secretion, the major proteins expressed by osteoblastic cells are initially incorporated into different tissue compartments, with most of the sulfated sialoproteins and CS-PG III associating rapidly with the hydroxyapatite crystals. The initial distribution of these proteins is of importance in the evaluation of their role in bone formation and mineralization.

The small proteoglycans of cartilage matrix

The small proteoglycans (PGs) of cartilage matrix represent a small fraction of the total mass of PGs, but with a small size they can be present in equivalent moles to the large PGs. Three types of PGs with a wide skeletal and extraskeletal distribution, biglycan (PGI), decorin (PGII) and fibromodulin have distinct but homologous core proteins containing leucin-rich sequences. Carbohydrate substituants (one or two chondroitin sulfate/dermatan sulfate chains for decorin and biglycan respectively, chains of keratan sulfate for fibromodulin and oligosaccharides) present variations from tissue to tissue and with age and other factors. Decorin and fibromodulin appear to interact with collagen and to participate in the regulation of collagen matrices. In vitro experiments indicate a role for small PGs in adhesion, multiplication, differentiation, and migration of cells. Recent data on molecular biology of the small PGs contribute to a better understanding of their functions and make the evaluation of their role in hereditary diseases.

Characteristics of the in vitro interaction of a small proteoglycan (PG II) of bovine tendon with type I collagen

Binding of the small dermatan sulfate proteoglycan of bovine tendon (PG II type/decorin-like) to type I collagen was characterized in an in vitro fibril-forming assay, using native collagen prepared from bovine tendon by acid extraction and radiolabeled proteoglycans synthesized by bovine tendon fibroblasts in culture. Substantial binding to collagen was noted for both intact small proteoglycan and core protein from which the glycosaminoglycan chain was removed. However, binding to collagen was minimal for free glycosaminoglycan chains or large proteoglycans. Binding of the small proteoglycan was optimal at approximately physiological conditions of salt concentration and pH. Scatchard analysis showed a binding affinity constant of 3.3 x 10(7) M-1 with 0.054 proteoglycan binding sites/collagen molecule, when about 0.25-6 micrograms proteoglycan was combined with 100 micrograms collagen. Binding to preformed fibrils of native tendon collagen and to pepsin-treated bovine skin collagen was similar to binding to native tendon collagen. Binding occurred in non-ionic detergents at concentrations up to 1% and once bound, the proteoglycan was not released by washing with up to 2 M NaCl. When both PG I and PG II small proteoglycans were added to collagen, only PG II was bound. This difference is not readily explained by differences in disulfide bond position. These studies indicate a strong, specific interaction between type I collagen fibrils and the core protein of the small (PG II) proteoglycan of tendon.

Self-aggregation of bovine skin proteodermatan sulphate promoted by removal of the three N-linked oligosaccharides

Progressive digestion of native bovine skin proteodermatan sulphate with glycopeptidase F (EC. 3.2.2.18), followed by electrophoresis and affinity-blotting with concanavalin A, demonstrated the presence of three N-linked oligosaccharide chains on the protein core. These oligosaccharides were localized to the C-terminal portion of the protein core. Proteodermatan sulphate purified after removal of the oligosaccharides exhibited an altered circular dichroism spectrum and apparently enhanced thermal stability which were explained by the finding that it had aggregated. The aggregates could be partially dissociated by urea. Aggregation could also be demonstrated without intervening preparative steps between digestion with glycopeptidase-F and electrophoresis. Oligosaccharide-free proteodermatan sulphate retained its ability to inhibit fibril formation from monomeric collagen but showed a tendency to self-aggregate in solution. These results suggest a role for the oligosaccharides of proteodermatan sulphate in maintaining the molecule in a predominantly monomeric form in the tissue, thus indirectly promoting its interaction with collagen.

Secondary structure of a core protein from pig skin proteodermatan sulfate: CD and Fourier transform IR spectroscopic studies in solution

The secondary structure of a 38 kDa core protein from pig skin proteodermatan sulfate (PDS), was investigated in solution using CD and Fourier transform (FT) ir spectroscopy. Both techniques generally have provided complementary data on the secondary structures of proteins. CD spectral analysis has shown that the core protein contains 60% beta-turn and alpha-helical structures, the rest being "unordered" structure. FT ir data do not permit calculation of quantitative contributions of substructures, at the present time, to the overall secondary structure of the core protein. CD spectrum of the intact PDS is similar to the core protein CD spectrum.

Dermatan sulphate proteoglycans of human articular cartilage. The properties of dermatan sulphate proteoglycans I and II

Dermatan sulphate proteoglycans were purified from juvenile human articular cartilage, with a yield of about 2 mg/g wet wt. of cartilage. Both dermatan sulphate proteoglycan I (DS-PGI) and dermatan sulphate proteoglycan II (DS-PGII) were identified and the former was present in greater abundance. The two proteoglycans could not be resolved by agarose/polyacrylamide-gel electrophoresis, but could be resolved by SDS/polyacrylamide-gel electrophoresis, which indicated average Mr values of 200,000 and 98,000 for DS-PGI and DS-PGII respectively. After digestion with chondroitin ABC lyase the Mr values of the core proteins were 44,000 for DS-PGI and 43,000 and 47,000 for DS-PGII, with the smaller core protein being predominant in DS-PGII. Sequence analysis of the N-terminal 20 amino acid residues reveals the presence of a single site for the potential substitution of dermatan sulphate at residue 4 of DS-PGII and two such sites at residues 5 and 10 for DS-PGI.