The primary structure of the core protein of the small, leucine-rich proteoglycan (PG I) from bovine articular cartilage

Two forms of small, interstitial proteoglycans have been isolated from bovine articular cartilage and have different core proteins, based on NH2-terminal analysis and peptide mapping (Choi, H. U., Johnson, T. L., Pal, S., Tang, L-H., Rosenberg, L. C., and Neame, P. J. (1989) J. Biol. Chem. 264, 2876-2884). These proteoglycans have been called PG I and PG II. Since they were first described, they have also been called "biglycan" (PG I), "decorin," and "DS-PG" (PG II). This report describes the primary structure of PG I from bovine articular cartilage. The protein core consists of 331 amino acids with a molecular mass of 37,280 Da. The amino acid sequence shows 55% identity to the cDNA-derived sequence of PG II from bovine bone. There are four discrete domains in the amino acid sequence. Domain 1, at the NH2 terminus (approximately 23 amino acids), contains two sites of attachment of dermatan sulfate, both of which match the consensus sequence of Asp/Glu-X-X-Ser-Gly-hydrophobic. Neither of these sites is substituted to 100% with glycosaminoglycan in native PG I. Domain 2, near the NH2 terminus and containing approximately 28 amino acids, has a cysteine pattern similar to a domain near the COOH terminus of mouse metallothionein and contains at least one disulfide bond (between the first and fourth cysteine residues). The majority of the core protein of PG I (domain 3) is a leucine-rich domain containing ten repeating units (approximately 231 amino acids). Patthy [1987) J. Mol. Biol. 198, 567-577) has shown that for PG II, the majority of domain 3 shows considerable similarity to leucine-rich alpha 2-glycoprotein (LRG) from serum. Domain 2 of PG I or PG II also has an analog in LRG, in that it has two cysteines in a similar place. The major motif in the PG I described here, in PG II and in LRG, is a series of leucine-rich repeats. PG I and PG II both contain 10 leucine-rich repeats which are 14 amino acids long and which are somewhat irregularly spaced, while LRG contains 9 leucine-rich repeats spaced 10 amino acids apart. Other proteins which contain leucine repeats are the platelet glycoprotein Ib, which is involved in platelet adherence to subendothelium (eight repeats in the alpha chain and two in the beta chain), the protein encoded by the Toll gene (involved in lateral and ventral spatial organization in Drosophila) and chaoptin (a protein involved in Drosophila photoreceptor morphogenesis).(ABSTRACT TRUNCATED AT 400 WORDS)     

Temporal regulation of hyaluronan and proteoglycan metabolism by human bone cells in vitro

Osteoblasts elaborate a dynamic extracellular matrix that is constructed and mineralized as bone is formed. This matrix is primarily composed of collagen, along with noncollagenous proteins which include glycoproteins and proteoglycans. After various times in culture, human bone cells were labeled with [35S]sulfate, [3H] leucine/proline, or [3H]glucosamine and the metabolism of hyaluronan and four distinct species of proteoglycans (PGs) was assayed in the medium, cell layer, and intracellular pools. These cells produce hyaluronan (Mr approximately 1,400,000; a chondroitin sulfate PG (CSPG), Mr approximately 600,000; a heparan sulfate PG (HSPG), Mr approximately 400,000; and two dermatan sulfate PGs with Mr approximately 270,000 (biglycan, PG I) and Mr approximately 135,000 (decorin, PG II) that distribute between the medium and cell layer. Two days following subculture, 12 h [35S]sulfate steady-state labeling yielded a composition of 24, 27, 31, and 18% for total CSPG, HSPG, biglycan, and decorin, respectively. While HSPG and decorin levels and distribution between medium and cell layer remained relatively constant during steady-state labeling at different times in culture, CSPG and biglycan levels increased dramatically at late stages of growth, and their distribution changed throughout culture. These results were independent of cell density, media depletion, and labeling pool effects. In contrast, hyaluronan synthesis was uncoupled from PG synthesis and apparently density-dependent. Pulse chase labeling at different stages of culture showed that the CSPG and decorin behaved as secretory PGs. Both HSPG and biglycan underwent catabolism, with HSPG possessing a t1/2 of 8 h and biglycan a t1/2 of 4 h. While the rate of HSPG turnover did not appreciably change between early and late culture, that of biglycan decreased. The mRNA for decorin was constant, while that of biglycan changed during culture. These results suggest that each PG possesses a distinct pattern of cellular and temporal distribution that may reflect specific stages in matrix formation and maturation.     

Endocytosis of different members of the small chondroitin/dermatan sulfate proteoglycan family.

The family of small interstitial chondroitin/dermatan sulfate proteoglycans consists of at least three different molecular species: biglycan (proteoglycan I), decorin (proteoglycan II), and proteoglycan-100, which has a glycosylated core protein of about 100 kDa. The core protein of decorin has been shown to be responsible for receptor-mediated endocytosis of this proteoglycan species by a variety of mesenchymal cells. It is now demonstrated that skin fibroblasts and articular chondrocytes endocytose biglycan with an efficiency similar to that of decorin. Uptake of biglycan is also mediated by its core protein and can be inhibited by decorin in a partially competitive manner. In human fibroblasts, endosomal proteins of 51 and 26 kDa, which are known to bind decorin core protein, also interact with biglycan. This interaction can be inhibited by decorin. Bovine articular chondrocytes contained binding proteins of 48 and 25 kDa. Proteoglycan-100 can be distinguished from biglycan and decorin by its low clearance rate, which however, exceeds the rate of fluid phase endocytosis.     

Super-motifs and evolution of tandem leucine-rich repeats within the small proteoglycans--biglycan, decorin, lumican, fibromodulin, PRELP, keratocan, osteoadherin, epiphycan, and osteoglycin

Leucine-rich repeats (LRRs) with 20-30 amino acids in unit length are present in many proteins from prokaryotes to eukaryotes. The LRR-containing proteins include a family of nine small proteoglycans, forming three distinct subfamilies: class I contains biglycan/PG-I and decorin/PG-II; class II: lumican, fibromodulin, PRELP, keratocan, and osteoadherin; and class III: epiphycan/PG-Lb and osteoglycin or osteoinductive factor. Comparative sequence analysis of the 34 available protein sequences reveals that these proteoglycans have two types of LRRs, which we call S and T. The type S LRR is 21 residues long and has the consensus sequence of xxaPzxLPxxLxxLxLxxNxI. The type T LRR has 26 residues; its consensus sequence is zzxxaxxxxFxxaxxLxxLxLxxNxL. In both "x" indicates variable residue; "z" is frequently a gap; "a" is Val, Leu, or Ile; and I is Ile or Leu. These type S and TLRRs are ordered into two super-motifs--STT with about 73 residues in classes I and II and ST with about 47 residues in class III. The 12 LRRs in the small proteoglycans of I and II are best represented as (STT)4; the seven LRRs of class III as (ST)T(ST)2. Our analyses indicate that classes I/II and III evolved along different paths after the establishment of the precursor ST, and classes I and II also diverged after the establishment of the precursor (STT)4.     

Complete amino acid sequence of a human platelet proteoglycan

The primary structure of a human platelet proteoglycan (P.PG) core was established by a combination of amino acid sequence analysis and cDNA cloning. The deduced 131 amino acid long protein contains eight Ser-Gly repeats. The significance of homologies observed between P.PG and promyelocytic leukemia cell line proteoglycans is discussed.     

Differential regulation of extracellular matrix proteoglycan (PG) gene expression. Transforming growth factor-beta 1 up-regulates biglycan (PGI), and versican (large fibroblast PG) but down-regulates decorin (PGII) mRNA levels in human fibroblasts in culture

Proteoglycans (PGs) comprise a group of extracellular matrix macromolecules which play an important role in matrix biology. In this study, normal human skin and gingival fibroblast cultures were incubated with transforming growth factor-beta 1 (TGF-beta 1), and the expression of three PGs, viz. biglycan (PGI), decorin (PGII), and versican (a large fibroblast proteoglycan) was examined. The results indicate that TGF-beta 1 (5 ng/ml) markedly increased the expression of biglycan (up to 24-fold) and versican (up to 6-fold) mRNAs and the enhancement of biglycan expression was coordinate with elevated type I procollagen gene expression in the same cultures. In contrast, the expression of decorin mRNA was markedly (up to approximately 70%) inhibited by TGF-beta 1. The response to TGF-beta 1 was similar in both skin and gingival fibroblasts, although the gingival cells were clearly more responsive to stimulation by TGF-beta 1 with respect to biglycan gene expression. Analysis of 35S-labeled proteoglycans in the culture media of skin and gingival fibroblasts also revealed stimulation of biglycan and versican production, and reduction in decorin production. Quantitation of both [35S]sulfate and [3H]leucine-labeled decorin in cell culture media by immunoprecipitation revealed a 50% reduction in decorin production in cell cultures treated with TGF-beta 1. This TGF-beta 1-elicited reduction was accompanied by an apparent increase in the size of the decorin molecules, although the size of the core protein was not altered, as judged by Western immunoblotting following chondroitinase ABC digestion. Analysis of the proteoglycans in the matrix and membrane fractions also revealed increased amounts of versican in cultures treated with TGF-beta 1. These results indicate differential regulation of PG gene expression in fibroblasts by TGF-beta 1, and these observations emphasize the role of PGs in the extracellular matrix biology and pathology.     

Proteoglycan-Lb, a small dermatan sulfate proteoglycan expressed in embryonic chick epiphyseal cartilage, is structurally related to osteoinductive factor.

We have isolated cDNA clones encoding the core protein of PG-Lb, proteoglycan which has been shown to be preferentially expressed in the zone of flattened chondrocytes of the developing chick limb cartilage (Shinomura, T., Kimata, K., Oike, Y., Yano, S., and Suzuki, S. (1984) Dev. Biol. 103, 211-220). The deduced amino acid sequence from the cDNA analysis indicates the presence of consensus leucine-rich repeats which are present in other small proteoglycans, decorin, biglycan, and fibromodulin. However, the homology analysis revealed that chick PG-Lb showed a higher homology (about 50% in the region containing leucine-rich repeats) to human osteoinductive factor, OIF, rather than to the other small proteoglycans. Furthermore, 6 cysteine residues are detected in both PG-Lb and OIF with invariant relative positions. Therefore, such an evolutionarily conserved structure in the PG-Lb core protein might be involved in some important biological functions of this molecule. In close relation to the structural similarity to OIF, the unique expression of PG-Lb in the ossifying area of cartilage suggested the possible participation of this proteoglycan in osteogenic processes.     

Alterations in the extracellular matrix proteoglycan profile in Dupuytren's contracture affect the palmar fascia

Dupuytren's disease is a palmar fibromatosis associated with changes in fibroblast activity that also affect the metabolism of extracellular matrix components. In contrast to disease connected alterations in collagen and non-collagenous glycoproteins (mainly fibronectin), the metabolism of proteoglycans, being glycosaminoglycan modified glycoproteins, is poorly understood. Thus, the aim of the present study was the characterization of matrix proteoglycans (PGs) derived from normal fascia and Dupuytren's fascia. Extracted and purified PGs (particularly small PGs) were analysed for content, molecular mass, immunoreactivity and glycosaminoglycan chain structure. The matrix of normal fascia mainly contains decorin [small dermatan sulfate (DS) PG] with biglycan (another small DSPG) and large chondroitin sulfate(CS)/DSPG representing minor components. Dupuytren's disease is associated with the remodeling of matrix PG composition. The most prominent alteration is an accumulation of biglycan frequently bearing DS chains with higher molecular masses. Moreover, the amount of large CS/DSPG is increased. In contrast, decorin displays changes affecting mainly DS chain structure reflected in (i) an increase in some chain molecular masses, (ii) an enhanced content of iduronate disaccharide clusters, and (iii) oversulfation of disaccharide repeats. The PG alterations observed in Dupuytren's fascia may influence the matrix properties and contribute to disease progression.     

Identification and characterization of asporin. a novel member of the leucine-rich repeat protein family closely related to decorin and biglycan

Asporin, a novel member of the leucine-rich repeat family of proteins, was partially purified from human articular cartilage and meniscus. Cloning of human and mouse asporin cDNAs revealed that the protein is closely related to decorin and biglycan. It contains a putative propeptide, 4 amino-terminal cysteines, 10 leucine-rich repeats, and 2 C-terminal cysteines. In contrast to decorin and biglycan, asporin is not a proteoglycan. Instead, asporin contains a unique stretch of aspartic acid residues in its amino-terminal region. A polymorphism was identified in that the number of consecutive aspartate residues varied from 11 to 15. The 8 exons of the human asporin gene span 26 kilobases on chromosome 9q31.1-32, and the putative promoter region lacks TATA consensus sequences. The asporin mRNA is expressed in a variety of human tissues with higher levels in osteoarthritic articular cartilage, aorta, uterus, heart, and liver. The deduced amino acid sequence of asporin was confirmed by mass spectrometry of the isolated protein resulting in 84% sequence coverage. The protein contains an N-glycosylation site at Asn(281) with a heterogeneous oligosaccharide structure and a potential O-glycosylation site at Ser(54). The name asporin reflects the aspartate-rich amino terminus and the overall similarity to decorin.     

Molecular cloning and sequence analysis of the cDNA for small proteoglycan II of bovine bone.

The cDNA for the full-length core protein of the small chondroitin sulphate proteoglycan II of bovine bone was cloned and sequenced. A 1.3 kb clone (lambda Pg28) was identified by plaque hybridization with a previously isolated 1.0 kb proteoglycan cDNA clone (lambda Pg20), positively identified previously by polyclonal and monoclonal antibody reactivity and by hybrid-selected translation in vitro [Day, Ramis, Fisher, Gehron Robey, Termine & Young (1986) Nucleic Acids Res. 14, 9861-9876]. The cDNA sequences of both clones were identical in areas of overlap. The 360-amino-acid-residue protein contains a 30-residue propeptide of which the first 15 residues are highly hydrophobic. The mature protein consists of 330 amino acid residues corresponding to an Mr of 36,383. The core protein contains three potential glycosaminoglycan-attachment sites (Ser-Gly), only one of which is within a ten-amino-acid-residue homologous sequence seen at the known attachment sites of related small proteoglycans. Comparisons of the published 24-residue N-terminal protein sequence of bovine skin proteoglycan II core protein with the corresponding region in the deduced sequence of the bovine core protein reveals complete homology. Comparison of the cDNA-derived sequences of bovine bone and human embryonic fibroblast proteoglycans shows a hypervariable region near the N-terminus. Nucleotide homology between bone and fibroblast core proteins was 87% and amino acid homology was 90%.     

cDNA to chick lumican (corneal keratan sulfate proteoglycan) reveals homology to the small interstitial proteoglycan gene family and expression in muscle and intestine.

A 1.9-kb cDNA clone to chick lumican (keratan sulfate proteoglycan) was isolated by screening an expressing vector library made from chick corneal RNA with antiserum to chick corneal lumican. The cDNA clone contained an open reading frame coding for a 343-amino acid protein, Mr = 38,640. Structural features of the deduced sequence include: a 18-amino acid signal peptide, cysteine residues at the N- and C-terminal regions, and a central leucine-rich region (comprising 62% of the protein) containing nine repeats of the sequence LXXLXLXXNXL/I, where X represents any amino acid. Lumican contains three variations of this sequence that are tandemly linked to form a unit and three units tandemly linked to form the leucine-rich region. The sequential arrangement of these repeats and their spacing suggest that this region arose by duplication. The deduced sequence shows five potential N-linked glycosylation sites, four of which are in the leucine-rich region. These sites are also potential keratan sulfate attachment sites. The cDNA clone to lumican hybridizes to a 2.0-kb mRNA found in tissues other than cornea, predominantly muscle and intestine. Radiolabeling and immunoprecipitation studies show that lumican core protein is also synthesized by these tissues. The primary structure of lumican is similar to fibromodulin, decorin, and biglycan, which indicates it belongs to the small interstitial proteoglycan gene family. The expression of lumican in tissues other than cornea indicates a broader role for lumican besides contributing to corneal transparency.     

Expression and localization of the two small proteoglycans biglycan and decorin in developing human skeletal and non-skeletal tissues

The messenger RNAs and core proteins of the two small chondroitin/dermatan sulfate proteoglycans, biglycan and decorin, were localized in developing human bone and other tissues by both 35S-labeled RNA probes and antibodies directed against synthetic peptides corresponding to nonhomologous regions of the two core proteins. Biglycan and decorin expression and localization were substantially divergent and sometimes mutually exclusive. In developing bones, spatially restricted patterns of gene expression and/or matrix localization of the two proteoglycans were identified in articular regions, epiphyseal cartilage, vascular canals, subperichondral regions, and periosteum, and indicated the association of each molecule with specific developmental events at specific sites. Study of non-skeletal tissues revealed that decorin was associated with all major type I (and type II) collagen-rich connective tissues. Conversely, biglycan was expressed and localized in a range of specialized cell types, including connective tissue (skeletal myofibers, endothelial cells) and epithelial cells (differentiating keratinocytes, renal tubular epithelia). Biglycan core protein was localized at the cell surface of certain cell types (e.g., keratinocytes). Whereas the distribution of decorin was consistent with matrix-centered functions, possibly related to regulation of growth of collagen fibers, the distribution of biglycan pointed to other function(s), perhaps related to cell regulation.     

Characterisation of proteoglycans and their catabolic products in tendon and explant cultures of tendon.

Tendons are collagenous tissues made of mainly Type I collagen and it has been shown that the major proteoglycans of tendons are decorin and versican. Little is still known about the catabolism of these proteoglycans in tendon. Therefore, the aim of the study was to characterise the proteoglycans including their catabolic products present in uncultured bovine tendon and in the explant cultures of tendon. In this study, the proteoglycans were extracted from the tensile region of deep flexor tendon and isolated by ion-exchange chromatography and after deglycosylation analysed by SDS-polyacrylamide electrophoresis, Western blotting and amino-terminal amino acid sequence analysis. Based on amino acid sequence analysis, approximately 80% of the total proteoglycan core proteins in fresh tendon was decorin. Other species that were detected were biglycan and the large proteoglycans versican (splice variants V(0) and/or V(1)) and aggrecan. Approximately 35% of decorin present in the matrix showed carboxyl-terminal proteolytic processing at a number of specific sites. The analysis of small proteoglycans lost to the medium of tendon explants showed the presence of biglycan and decorin with the intact core protein as well as decorin fragments that contained the amino terminus of the core protein. In addition, two core protein peptides of decorin starting at residues K(171) and D(180) were observed in the matrix and one core protein with an amino-terminal sequence commencing at G(189) was isolated from the culture medium. The majority of the large proteoglycans present in the matrix of tendon were degraded and did not contain the G1 globular domain. Furthermore the aggrecan catabolites present in fresh tendon and lost to the medium of explants were derived from aggrecanase cleavage of the core protein at residues E(373)-A(374), E(1480)-G(1481) and E(1771)-A(1772). The analysis of versican catabolites (splice variants V(0) and/or V(1)) also showed evidence of degradation of the core protein by aggrecanase within the GAG-beta subdomain, as well as cleavage by other proteinase(s) within the GAG-alpha and GAG-beta subdomains of versican (variants V(0) and/or V(2)). Degradation products from the amino terminal region of type XII collagen were also detected in the matrix and medium of tendon explants. This work suggests a prominent role for aggrecanase enzymes in the degradation of aggrecan and to a lesser extent versican. Other unidentified proteinases are also involved in the degradation of versican and small leucine-rich proteoglycans.     

Fibrils of different collagen types containing immobilised proteoglycans (PGs) as coatings: characterisation and influence on osteoblast behaviour

Collagen, the main organic component of bone, is used as a coating on titanium implants and as a scaffold material in bone tissue engineering. Surface modifications of titanium which promote osteoblast adhesion, proliferation and synthesis of collagen by osteoblasts are desirable. One biomimetic approach is the coating of titanium with collagen in fibrillar form. Other organic components of bone may be bound to fibrils and exert additional effects. In this study, the collagen types I-III were compared regarding their ability to bind the proteoglycans decorin and biglycan, which are found in bone. More collagen was bound to collagen II fibrils than to those of types I and III. Therefore, titanium surfaces were coated with fibrils of collagen type II containing biglycan or decorin or neither to investigate the effect of the proteoglycans on human primary osteoblast behaviour. In addition, the growth factor TGF-beta1 was adsorbed onto surfaces coated with fibrils of collagen type II containing biglycan or decorin or neither to investigate the influence of decorin and biglycan on the effect of TGF-beta1 on osteoblasts. Fibril-bound biglycan and decorin influence primary osteoblast behaviour by themselves. The presence of substrate-bound biglycan or decorin influences the effect of TGF-beta1. These results may be important when designing collagen-based coatings or scaffolds for tissue engineering, including those loaded with growth factors.     

Age-related changes in hyaluronan, proteoglycan, collagen, and osteonectin synthesis by human bone cells.

Human bone cells grown in culture, representative of a preosteoblastic stage of maturation, produce an extracellular matrix composed of collagen, several noncollagenous glycoproteins, hyaluronan, and four distinct proteoglycans (PGs). The influence of donor age on the levels of expression of these molecules in vitro has not been well characterized. In this study, human bone cells derived from sources ranging from fetal to 60-year-old donors were grown in culture, radiolabeled for 24 h, and the amount of incorporation of [35S]sulfate into PGs, [3H]glucosamine into hyaluronan, [3H]leucine/proline into osteonectin, and [3H]proline into collagen was determined. Cell proliferation was most rapid in fetal-derived bone cells and decreased with increasing age. Total protein and PG synthesis also decreased with increasing age, falling to 1/3 and 1/4, respectively, of fetal levels after age 30. A large chondroitin sulfate PG (Mr approximately 600,000 Da) was the major fetal PG and its levels were highly correlated with cellular proliferation. [3H]Collagen and [35S]decorin levels increased with the increasing age of the donor, reached a maximum in puberty-derived cells, and decreased to 1/3 maximal levels after age 20. The heparan sulfate PG (Mr approximately 400,000 Da) exhibited steady-state levels regardless of donor age. [3H]Osteonectin and [35S]biglycan levels were high in fetal-derived cells and in cells derived from pubescent donors. The percentage of collagen and four proteoglycans associated with the cell layer pool changed with donor age. All fetal-derived PG core proteins possessed more N- and O-linked oligosaccharides than newborn or adult derived PGs.     

A collagen-binding 59-kd protein (fibromodulin) is structurally related to the small interstitial proteoglycans PG-S1 and PG-S2 (decorin).

We have determined the primary structure of a 59 kd collagen binding protein which is present in many types of connective tissues, e.g. cartilage, tendon, skin, sclera and cornea. The amino acid sequence, deducted from a 2662 bp cDNA clone, predicts a 42 kd protein with a high content of leucine residues. Most of the protein consists of homologous 23 amino acid residues repeats with predominantly leucine residues in conserved positions. Similar leucine rich repeats have been identified in a number of proteins including the small interstitial proteoglycans decorin and PG-S1. The 59 kd protein and the two proteoglycans are homologous in their entire sequences suggesting that they have evolved from a common ancestral gene. The 59 kd protein and decorin are also functionally related in that both bind to collagen type I and II, and affect their fibrillogenesis. The substitution with glycosaminoglycan chains appears to be a feature shared by all three members of this family of leucine rich motif extracellular proteins, since the 59 kd protein isolated from cartilage is substituted with at least one keratan sulfate chain.