Distinct secondary structures of the leucine-rich repeat proteoglycans decorin and biglycan. Glycosylation-dependent conformational stability.

Biglycan and decorin have been overexpressed in eukaryotic cells and two major glycoforms isolated under native conditions: a proteoglycan substituted with glycosaminoglycan chains; and a core protein form secreted devoid of glycosaminoglycans (Hocking, A. M., Strugnell, R. A., Ramamurthy, P., and McQuillan, D. J. (1996) J. Biol. Chem. 271, 19571-19577; Ramamurthy, P., Hocking, A. M., and McQuillan, D. J. (1996) J. Biol. Chem. 271, 19578-19584). Far-UV CD spectroscopy of decorin and biglycan proteoglycans indicates that, although they are predominantly beta-sheet, biglycan has a significantly higher content of alpha-helical structure. Decorin proteoglycan and core protein are very similar, whereas the biglycan core protein exhibits closer similarity to the decorin glycoforms than to the biglycan proteoglycan form. However, enzymatic removal of the chondroitin sulfate chains from biglycan proteoglycan does not induce a shift to the core protein structure, suggesting that the final form is influenced by polysaccharide addition only during biosynthesis. Fluorescence emission spectroscopy demonstrated that the single tryptophan residue, which is at a conserved position at the C-terminal domain of both biglycan and decorin, is found in similar microenvironments. This indicates that in this specific domain the different glycoforms do exhibit apparent conservation of structure. Exposure of decorin and biglycan to 10 M urea resulted in an increase in fluorescent intensity, which indicates that the emission from tryptophan in the native state is quenched. Comparison of urea-induced protein unfolding curves provide further evidence that decorin and biglycan assume different structures in solution. Decorin proteoglycan and core protein unfold in a manner similar to a classic two-state model, in which there is a steep transition to an unfolded state between 1 and 2 M urea. The biglycan core protein also shows a similar steep transition. However, biglycan proteoglycan shows a broad unfolding transition between 1 and 6 M urea, probably indicating the presence of stable unfolding intermediates.

Mechanism and function of signal transduction by the Wnt/beta-catenin and Wnt/Ca2+ pathways.

Communication between cells is often mediated by secreted signaling molecules that bind cell surface receptors and modulate the activity of specific intracellular effectors. The Wnt family of secreted glycoproteins is one group of signaling molecules that has been shown to control a variety of developmental processes including cell fate specification, cell proliferation, cell polarity and cell migration. In addition, mis-regulation of Wnt signaling can cause developmental defects and is implicated in the genesis of several human cancers. The importance of Wnt signaling in development and in clinical pathologies is underscored by the large number of primary research papers examining various aspects of Wnt signaling that have been published in the past several years. In this review, we will present a synopsis of current research with particular attention paid to molecular mechanism of Wnt signal transduction and how the mis-regulation of Wnt signaling leads to cancer.

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.

Eukaryotic expression of recombinant biglycan. Post-translational processing and the importance of secondary structure for biological activity.

Biglycan is a small chondroitin sulfate proteoglycan found in many tissues and is structurally related to decorin, fibromodulin, and lumican. The biological function of biglycan is poorly understood, although several studies have indicated interaction with other extracellular matrix components. We have initiated studies of structural and functional domains of biglycan by transient eukaryotic expression using the vaccinia virus/T7 bacteriophage expression system. A recombinant vaccinia virus, vBGN4 encoding the mature biglycan core protein as a polyhistidine fusion protein under control of the T7 phage promoter was expressed in HT-1080 cells and UMR106 cells. The structure of the recombinant biglycan secreted by these cells was defined by analyzing molecules labeled in the presence of [35S]sulfate, [3H]glucosamine, and [35S]methionine. Glycoforms of biglycan were separated by imidazole gradient elution, under non-denaturing conditions, and comprised: a large proteoglycan form substituted with two chondroitin sulfate chains of molecular mass approximately 34 kDa (HT-1080 cells) or approximately 40 kDa (UMR106 cells); a small proteoglycan form substituted with two chondroitin sulfate chains with a median molecular mass approximately 28 kDa; and a core protein form secreted devoid of glycosaminoglycan chains. All the glycoforms were substituted with two N-linked oligosaccharides, and the disaccharide composition of the two glycosaminoglycan populations were identical. Approximately 70% of the recombinant biglycan secreted by HT-1080 cells was substituted with chondroitin sulfate chains, whereas about 50% of the biglycan expressed by UMR106 cells was substituted with chondroitin sulfate chains. Infection with vBGN4 in both HT-1080 and UMR106 cells resulted in the production of approximately 10 mg of biglycan/10(9) cells per 24 h. The native recombinant biglycan was shown to bind to collagen type V and the complement protein, C1q. However, when the secondary structure of recombinant biglycan was disrupted by exposure to 4 M guanidine hydrochloride, the affinity for collagen type V was dramatically reduced. These data demonstrate the importance of secondary structure to the function of this small proteoglycan.

Recombinant decorin glycoforms. Purification and structure.

The vaccinia virus/T7 bacteriophage expression system was used to express human decorin in HT-1080 cells by co-infection with vTF7-3, encoding T7 RNA polymerase, and vDCN1, encoding the decorin core protein fused to a polyhistidine-insulin signal sequence fusion-protein cassette. Overexpression using the vaccinia virus/T7 phage system resulted in secretion of approximately 30 mg of decorin/10(9) cells per 24 h which enabled purification and separation of multiple glycoforms under native conditions. Cells were cultured in the presence of [35S]methionine or a mixture of [3H]glucosamine and [35S]sulfate, and recombinant glycoprotein purified by metal affinity chromatography which resolved the secreted decorin into two classes, a proteoglycan form and a core protein form. About 25% of the recombinant protein was secreted into the culture medium as core protein devoid of glycosaminoglycan chains. The decorin core protein was resolved into two forms (approximately 49 and approximately 53 kDa) that differed in the extent of N-linked oligosaccharide substitution (2 and 3 N-linked oligosaccharides, respectively). Deglycosylation of the recombinant proteoglycans and core proteins resulted in a single band migrating with an apparent molecular mass approximately 43 kDa when analyzed by SDS-polyacrylamide gel electrophoresis. Far-UV circular dichroism spectra of native decorin proteoglycan showed a minima at 218 nm, consistent with a secondary structure that is predominantly beta-sheet. Circular dichroism spectra of bovine decorin extracted from articular cartilage and recombinant decorin similarly treated revealed a minima of 205 nm indicating a loss of secondary structure. The affinity of decorin proteoglycan and core protein for collagen-like molecules was demonstrated, with the complement component C1q exhibiting the most striking affinity for decorin, although adherence to collagen types I and V was also observed. The extensive secondary structure maintained in the purified recombinant protein is likely to be important for the biological function of decorin.

Site-directed mutagenesis of human type X collagen. Expression of alpha1(X) NC1, NC2, and helical mutations in vitro and in transfected cells.

Type X collagen is a short chain collagen expressed in the hypertrophic zone of calcifying cartilage during skeletal development and bone growth. The alpha1(X) homotrimer consists of three protein domains, a short triple helix (COL1) flanked by nonhelical amino-terminal (NC2) and carboxyl-terminal (NC1) domains. While mutations of the NC1 domain result in Schmid metaphyseal chondrodysplasia, which suggests a critical role for this protein domain, little biochemical detail is known about type X collagen synthesis, secretion, and the mechanisms of molecular assembly. To study these processes, a range of mutations were produced in human alpha1(X) cDNA and the biochemical consequences determined by in vitro expression, using T7-driven coupled transcription and translation, and by transient transfection of cells. Three NC1 mutants, which were designed to be analogous to Schmid mutations (1952delC, 1963del10, and Y598D), were unable to assemble into type X collagen homotrimers in vitro, but the mutant chains did not associate with, or interfere with, the efficiency of normal chain assembly in co-translations with a normal construct. Expression in transiently transfected cells confirmed that mutant type X collagen assembly was also compromised in vivo. The mutant chains were not secreted from the cells but did not accumulate intracellularly, suggesting that the unassociated mutant chains were rapidly degraded. In-frame deletions within the helix (amino acid residues 72-354) and the NC2 domain (amino acid residues 21-54) were also produced. In contrast to the NC1 mutations, these mutations did not prevent assembly. Mutant homotrimers and mutant-normal heterotrimers were formed in vitro, and the mutant homotrimers formed in transiently transfected cells had assembled into pepsin-stable triple helical molecules which were secreted.

Proteoglycans synthesized by an osteoblast-like cell line (UMR 106-01).

The proteoglycans synthesized by an osteoblast-like cell line of rat origin (UMR 106-01) were defined after biosynthetic labelling with [35S]sulphate and [3H]glucosamine. Newly synthesized labelled proteoglycans were characterized by differential enzymic digestion in combination with analytical gel filtration and SDS/PAGE. UMR 106-01 cells were found to synthesize three major species of proteoglycan: a large chondroitin sulphate proteoglycan of Mr approximately 1 x 10(6), with a core protein of Mr approximately 350,000-400,000; a small chondroitin sulphate-containing species of Mr approximately 120,000 with a core protein of Mr 43,000; and a heparan sulphate proteoglycan of Mr approximately 150,000, with a core protein of Mr approximately 80,000. Over 70% of the newly synthesized intact proteoglycan species are associated with the cell layer of near-confluent cells; however, accessibility to trypsin digestion suggests an extracellular location. Chemical characteristics of the proteoglycans and preliminary mRNA hybridization indicate that the small chondroitin sulphate proteoglycan is probably PG II (decorin). The large chondroitin sulphate proteoglycan is most likely related to a hyaluronate-aggregating species from fibroblasts (versican), and the heparan sulphate proteoglycan bears striking similarities to cell-membrane-intercalated species described for a number of cell types.