Temporal expression of CD44 during embryonic chick limb development and modulation of its expression with retinoic acid.

Hyaluronan-cell interactions are initiated co-ordinately with mesenchymal condensation during chondrogenic differentiation in the limb bud. Hyaluronan is responsible for the retention and organization of proteoglycan within the cartilage matrix. Hyaluronan-CD44 binding also retains proteoglycan aggregates to the chondrocyte plasma membrane. A sequence for CD44 protein in chick has recently been reported, but never evaluated in chick chondrocytes. Total RNA was isolated from embryonic chick limb buds, stages 18, 19, 24, 25 and 30. Using semi-quantitative RT-PCR, expression of aggrecan, this chick CD44 orthologue and GAPDH mRNA was analyzed. Aggrecan expression was detected at all stages, but was increased at stage 30. CD44 mRNA was detected at extremely low levels at stage 18 to higher levels in the latter stages. Thus, the temporal expression of CD44 mRNA correlated with the onset of pre-cartilage condensation. The full-length chick chondrocyte CD44 cDNA was obtained following RT-PCR using RNA derived from tibial chondrocytes from stage 37 chick embryos. The nucleotide sequence was used to generate an amino acid sequence and analyses revealed homologies of 44.4% with mouse, 47.8% with bovine and 46.3% with human CD44. Tibial chondrocytes were cultured in the presence or absence of retinoic acid for 36 or 72 h. By RT-PCR, expression of aggrecan and the CD44 mRNA by chick chondrocytes was decreased after retinoic acid treatment, while GAPDH expression showed no change. As expected, control chondrocytes exhibited a round morphology while retinoic acid-treated chondrocytes were elongated. The retinoic acid-treated chondrocytes also exhibited reduced hyaluronan binding. This functional assay indicates a role for a CD44 receptor in matrix retention by chick chondrocytes.     

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.     

Chick cartilage chondroitin sulfate proteoglycan core protein. II. Nucleotide sequence of cDNA clone and localization of the S103L epitope.

A lambda gt11 expression library containing cDNA from total chick embryo was screened with S103L, a rat monoclonal antibody which reacts specifically with the core protein of the chick cartilage chondroitin sulfate proteoglycan. One clone was identified which produced a 220-kDa beta-galactosidase/S103L-binding fusion protein. Sequencing the entire 1.5-kilobase cDNA insert showed that it contained a single open reading frame, which encoded a portion of the proteoglycan core protein from the chondroitin sulfate domain. This was confirmed by comparison with amino acid sequence data from peptide CS-B, which was derived from the chondroitin sulfate domain (Krueger, R.C., Jr., Fields, T. A., Hildreth, J., IV, and Schwartz, N.B. (1990) J. Biol. Chem. 265, 12075-12087). Furthermore, the 3' end of the insert overlapped with 23 bases at the 5' end of the published sequence for the C-terminal globular domain (Sai, S., Tanaka, T., Kosher, R. A., and Tanzer, M. L. (1986) Proc. Natl. Acad. Sci. U. S. A. 83, 5081-5085), which oriented this clone, as well as the CS peptide, along the protein core. The cDNA insert hybridized with a 9-kilobase mRNA from sternal chondrocytes as well as a similar sized message in brain but did not hybridize to any message from rat chondrosarcoma or from undifferentiated limb bud mesenchyme. In further studies, the fusion protein as well as a cyanogen bromide fragment (70 kDa) derived from it were isolated and shown to react with S103L, indicating that cleavage at methionine residues does not disrupt the antibody recognition site. Purification and N-terminal sequencing of the antigenic CNBr fragment derived from the fusion protein revealed that its N terminus is preceded by a methionine in the fusion protein and overlaps with the N terminus of peptide CS-B. As peptide CS-B is not recognized by S103L and the C terminus of peptide CS-B lies beyond the proteoglycan portion of the antigenic CNBr fragment, the S103L epitope is either contained within the 11 amino acids preceding the N terminus of peptide CS-B or it spans the clostripain cleavage site at the origin of the N terminus of peptide CS-B.     

cDNA clone to chick corneal chondroitin/dermatan sulfate proteoglycan reveals identity to decorin.

A 1.6-kb cDNA clone was isolated by screening a library prepared from chick corneal mRNA with a cDNA clone to bovine decorin. The cDNA contained an open reading frame coding for a M(r) 39,683 protein. A 19-amino-acid match with sequence from the N-terminus of core protein from the corneal chondroitin/dermatan sulfate proteoglycan confirmed the clone as a corneal proteoglycan and the homology with human and bovine decorin confirmed its identity as decorin. Structural features of the deduced sequence include a 16-amino-acid signal peptide, a 14-amino-acid propeptide, cysteine residues at the N- and C-terminal regions, and a central leucine-rich region (comprising 63% of the protein) containing nine repeats of the sequence LXXLXLXXNXL/I. Chick decorin 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 presence of beta bend amino acids flanking the units may serve to delineate the units as structural elements of the leucine-rich region. Sequence homology within the repeats and the spacing of the repeats suggest that this region arose by duplication. Chick decorin primarily differs from mammalian decorins in the 19-amino-acid sequence that starts the N-terminus of the core protein. Within this region, the serine that serves as a potential acceptor for the chondroitin/dermatan sulfate side chain is preceded by a glycine instead of being followed by a glycine as it is in the mammalian decorins and all other mammalian proteoglycans.     

Extracellular matrix and the maintenance of the differentiated state: proteoglycans synthesized by replated chondrocytes and nonchondrocytes

It has been previously shown that undifferentiated stage 23 to 24 chick limb bud mesenchymal cells can be maintained in culture under conditions which promote chondrogenesis. As the chondrocytes mature in vitro, their proteoglycan synthesis progresses through a specific and reproducible biosynthetic program. By the eighth day of culture, the chondrocytes are making proteoglycans that are similar to proteoglycans isolated from adult animal tissues. Relative to the Day 8 proteoglycans, the proteoglycans synthesized by chick limb bud chondrocytes earlier in culture have a smaller monomer size, longer chondroitin sulfate chains, shorter keratan sulfate chains, a higher ratio of chondroitin-6-sulfate to chondroitin-4-sulfate, and a decreased ability to interact with hyaluronic acid. We have reported a procedure to remove the cells from Day 8 cultures and strip away most, if not all, of the extracellular matrix. In addition, the chondrocytes can be separated from the 40-50% nonchondrocytic cells normally found in Day 8 cultures, and the two cell populations replated separately. This report describes the analysis of the proteoglycans synthesized by replated cells; this analysis demonstrates quantitative and qualitative differences between chondrocyte and nonchondrocyte proteoglycans. The overall rate of proteoglycan synthesis is fourfold higher and the rate of synthesis of high buoyant density proteoglycans 30-fold higher for replated chondrocytes relative to nonchondrocytes. Qualitatively, more newly synthesized nonchondrocyte proteoglycans partition at lower buoyant density on CsCl equilibrium density gradients than do chondrocyte proteoglycans. Nonchondrocyte proteoglycans are of two major classes: One has a monomer size slightly smaller than that of Day 8 chondrocyte proteoglycan, but has much longer glycosaminoglycan chains. The other is considerably smaller than Day 8 chondrocyte proteoglycans, but has glycosaminoglycans of slightly larger size. In contrast, replated chondrocytes synthesize, even as soon as 4.5 hr after replating, proteoglycans that are identical to Day 8 chondrocyte proteoglycan in monomer size, in glycosaminoglycan chain size, in aggregability, and in the ratio of 6-sulfated to 4-sulfated chondroitin. Since denuding mature Day 8 chondrocytes of their extracellular matrix does not cause them to recapitulate their developmentally regulated program for the biosynthesis of proteoglycans, it is concluded that the quality of mature chondrocyte proteoglycan is not altered by the absence of extracellular matrix.     

Immunochemical analysis of cartilage proteoglycans. Cross-reactivity of molecules isolated from different species.

Antibodies directed against whole bovine nasal-cartilage proteoglycan and against the hyaluronic acid-binding region and chondroitin sulphate peptides from the same molecule were used in immunodiffusion and immunoelectromigration experiments. Proteoglycans from bovine nasal and tracheal cartilage showed immunological identity, with all three antisera. Proteoglycans from pig hip articular cartilage, dog hip articular cartilage, human tarsal articular cartilage and rat chondrosarcoma reacted with all the antisera and showed immunological identity with the corresponding structures isolated from bovine nasal-cartilage proteoglycans. In contrast, proteoglycans from rabbit articular cartilage, rabbit nasal cartilage and cultured chick limb buds did not react with the antibodies directed against the hyaluronic acid-binding region, though reacting with antibodies raised against whole proteoglycan monomer and against chondroitin sulphate peptides. All the proteoglycans gave two precipitation lines with the anti-(chondroitin sulphate peptide) antibodies. Similarly, the proteoglycans reacting with the anti-(hyaluronic acid-binding region) antibodies gave two precipitation lines. The results indicate the presence of at least two populations of aggregating proteoglycan monomers in cartilage. The relative affinity of the antibodies for cartilage proteoglycans and proteoglycan substructures from various species was determined by radioimmunoassay. The affinity of the anti-(hyaluronic acid-binding region) antibodies for the proteoglycans decreased in the order bovine, dog, human and pig cartilage. Rat sternal-cartilage and rabbit articular-cartilage proteoglycans reacted weakly, whereas chick limb-bud and chick sternal-cartilage proteoglycans did not react. In contrast, the affinity of antibodies to chondroitin sulphate peptides for proteoglycans increased in the order bovine cartilage, chick limb bud and chick sternal cartilage, dog cartilage, rat chondrosarcoma, human cartilage, pig cartilage, rat sternal cartilage and rabbit cartilage.     

Kinetics of intracellular processing of chondroitin sulfate proteoglycan core protein and other matrix components

Pulse-chase labeling techniques are used in conjunction with subcellular fractionation and quantitative immunoprecipitation to define the kinetics of intracellular translocation and secretion of proteoglycan core protein, along with link protein and type II collagen. In embryonic chick chondrocytes the core protein is processed very rapidly, exhibiting a t 1/2 in both the rough endoplasmic reticulum and golgi region of less than 10 min. Link protein appears to be processed as rapidly as the core protein, but the kinetics of type II collagen secretion is 3-4 times slower. These results are consistent with possible segregation and coordinate intracellular processing of link protein and core protein, macromolecules which are known to associate extracellularly. In contrast, rat chondrosarcoma chondrocytes translocated and secreted the core protein much more slowly (t 1/2 = 40 min) than the chick cells, perhaps due to the significantly reduced levels of galactosyltransferase I observed in the transformed chondrocytes.     

Characterization of bone PG II cDNA and its relationship to PG II mRNA from other connective tissues.

Two cDNA clones encoding the small proteoglycan II (PG II) of bone were isolated from a lambda gt11 expression library. These clones expressed recombinant protein which was cross-reactive with polyclonal and monoclonal antisera to PG II molecules from several connective tissues. The longest clone, lambda Pg 20 was studied in detail. The clone was shown to encode PG II by hybrid selected translation and immunoprecipitation. Northern analysis showed two species of the PG II message of approximately 1.4 and 1.8 kb. Substantial amounts of PG II message were found in bone, tendon, articular cartilage, skin, smooth muscle and cornea. Trace amounts of message were also detected in liver and brain. Radiolabeled bovine PG II cDNA hybridized to RNA from several other species including the human, rat and chicken. The level of PG II mRNA in chick embryonic fibroblasts was sensitive to transformation by Rous sarcoma virus.     

cis elements that control the expression of chick aggrecan

Aggrecan is a large chondroitin sulfate proteoglycan whose expression is both cell-specific and developmentally regulated. Cloning and sequencing of the 1.8-kilobase genomic 5'-flanking sequence of the chick aggrecan gene revealed the presence of potential tissue-specific control elements including a consensus sequence found in the cartilage-associated silencers, CSIIS1 and CSIIS2, that were first characterized in the type II collagen promoter sequences, as well as numerous other cis elements. Transient transfections of chick sternal chondrocytes and fibroblasts with reporter plasmids bearing progressively deleted portions of the chick aggrecan promoter and enhancer region demonstrated cell type-specific promoter activity and identified a 420-base pair region in the genomic 5-flanking region responsible for negative regulation of the aggrecan gene. In this report, three complementary methods, DNase I footprinting assays, transient transfections, and electrophoretic mobility shift assays (EMSA), provided an integral approach to better understand the regulation of the aggrecan gene. DNase I footprinting revealed that six regions of this genomic sequence bind to nuclear proteins in a tissue-specific manner. Transient transfection of reporter constructs bearing ablations of these protected sequences showed that four of the six protected sequences, which contain the sequence TCCTCC or TCCCCT, had repressor activities in transfected chick chondrocytes. Cross-competition EMSA using nuclear protein extracted from chondrocytes or fibroblasts explored the contributions of the different sequence elements in formation of DNA-protein complexes specific to cell type. This is the first parallel examination of the EMSA patterns for six functionally defined cis elements with highly similar sequences, using protein from primary cultured cells.     

The splicing pattern of fibronectin mRNA changes during chondrogenesis resulting in an unusual form of the mRNA in cartilage

Chondrogenesis, the differentiation of mesenchyme into cartilage, results in a change in composition of the extracellular matrix. The cartilage matrix contains several unique components, including type II collagen and chondroitin sulfate proteoglycan; it also contains fibronectin, a glycoprotein that mediates the interaction of cells with their matrix. We show that chick cartilage fibronectin mRNA contains an unusual pattern of alternatively spliced exons. Specifically, it contains exon IIIB but does not contain exon IIIA whereas fibronectin mRNA from mesenchyme contains both exons IIIB and IIIA. Thus the splicing pattern of the fibronectin mRNA must change from B+A+ to B+A- during chondrogenesis. Most fibronectin mRNA in other mesenchymal tissues contains exon IIIA but little exon IIIB (B-A+). Culturing of chondrocytes (cartilage-producing cells) results in loss of exon IIIB from fibronectin mRNA (B-A-). Manipulation of culture conditions to produce more adhesive chondrocytes (treatment with hyaluronidase, transformation with Rous sarcoma virus, and treatment with retinoic acid) increases the amount of fibronectin mRNA containing exon IIIA. These results suggest that exon IIIB may mediate the interactions of chondrocytes with the unique components of the cartilage matrix and exon IIIA may play a role in chondrocyte adhesion.     

Effects of procollagen peptides on the translation of type II collagen messenger ribonucleic acid and on collagen biosynthesis in chondrocytes

Type II procollagen messenger ribonucleic acid (mRNA) was isolated from chick sternum and rat chondrosarcoma cells and translated in a reticulocyte lysate cell-free system. A high molecular weight band was identified as type II procollagen by gel electrophoresis, collagenase digestion, and specific immunoprecipitation. The translation of type II mRNA was specifically inhibited by addition of type I procollagen amino-terminal extension peptide. When this peptide was added to the media of cultured fetal calf chondrocytes, chick sternal chondrocytes, or chick tendon fibroblasts, no inhibition of collagen synthesis was evident. These data suggest a general regulation of collagen biosynthesis by these peptides in the cell-free translation system. However, as indicated by the cell culture experiments, cellular characteristics and evolutionary divergence of animal species seem to restrict the effect of the peptides.     

Isolation of cDNA and genomic DNA clones encoding type II collagen.

A cDNA library constructed from total chick embryo RNA was screened with an enriched fraction of type II collagen mRNA. Two overlapping cDNA clones were characterized and shown to encode the COOH propeptide of type II collagen. In addition, a type II collagen clone was isolated from a Charon 4A library of chick genomic fragments. Definitive identification of the clones was based on DNA sequence analysis. The 3' end of the type II collagen gene appears to be similar to that of other interstitial collagen genes. Northern hybridization data indicates that there is a marked decrease in type II collagen mRNA levels in chondrocytes treated with the dedifferentiating agent 5-bromodeoxyuridine. The major type II collagen mRNA species is 5300 bases long, similar to that of other interstitial collagen RNAs.     

The expression of NG2 proteoglycan in the developing rat limb

NG2 is a chondroitin sulfate proteoglycan previously found to be expressed by glial progenitor cells of the O2A lineage. We have examined the expression of NG2 in the developing rat limb by immunohistochemistry and northern blot analysis. Staining of embryonic day 14 (E14) rat limb bud sections with polyclonal and monoclonal anti-NG2 antibodies reveals reactivity in the precartilaginous mesenchymal condensation. The staining intensity increases with the differentiation of chondrocytes until E16. NG2 staining is not detected in the mature hypertrophic chondrocytes of E17 and postnatal day 3 (P3) limbs even after treatment of the sections with hyaluronidase or collagenase. Immuno-precipitations with anti-NG2 antibody using 125I-labeled limb cells in culture showed a 400 to 800 x 10(3) Mr proteoglycan species with a core protein size of 300 x 10(3) Mr, comparable to NG2 from O2A cells and neural cell lines. Northern blot analysis reveals the expression of an 8.9 kb mRNA in E16 limbs and at a lower level in P1 cartilage. The northern blot analyses also show that NG2 is distinct from the large aggregating proteoglycan of the cartilage. Our results indicate that in the developing limb cartilage, as in the differentiating oligodendrocytes, NG2 is present on immature cells in the process of differentiating, but its expression is downregulated as terminal differentiation of chondrocytes takes place.     

Characterization of the core protein of the large chondroitin sulfate proteoglycan synthesized by chondrocytes in chick limb bud cell cultures

The core protein of high buoyant density proteoglycans synthesized by chondrocytes in stage 24 chick limb bud mesenchymal cell cultures was cleaved with cyanogen bromide to produce 17 resolvable peptides on sodium dodecyl sulfate-polyacrylamide slab gels. Of these peptides, 10 appear to originate from the chondroitin sulfate-rich region, 2 appear to be derived from the keratan sulfate-rich region, and 5 seem to be derived from the hyaluronic acid-binding region. The peptides from the chondroitin sulfate-rich region are almost all large (200 to 64 kDa). In contrast, the peptides from the keratan sulfate-rich and hyaluronic acid-binding regions are relatively small (47 to 12 kDa). One peptide from the hyaluronic acid-binding region appears to contain mannose-rich N-linked oligosaccharides as inferred from its observed binding by concanavalin A. A different hyaluronic acid-binding region peptide and one of the keratan sulfate-rich peptides were shown to contain disulfide bonds and therefore may be involved in contributing to the tertiary structure of the hyaluronic acid-binding region. Based on these observations, a map of the chick chondrocyte proteoglycan core protein has been constructed.     

Chondrocyte protein with a poly-proline region is a novel protein expressed by chondrocytes in vitro and in vivo

Chondrogenic differentiation is a multistep process entailing the sequential activation and inhibition of the expression of a number of genes. To identify genes preferentially expressed at the hypertrophic stage rather than early differentiation stages of chicken chondrocyte differentiation, a subtracted cDNA library was generated. Here we describe the characterization of a cDNA isolated from this library and that of the encoded protein referred to as Chondrocyte Protein with a Poly-proline Region (CHPPR).The cDNA coding for CHPPR hybridizes with a 3.0-kb mRNA expressed at extremely low levels in dedifferentiated chondrocytes, cultured in adherent conditions, at low levels in differentiating chondrocytes and at very high levels in hypertrophic chondrocytes in suspension culture. The Parathyroid Hormone peptide [PTH (1-34)] enhances accumulation of CHPPR mRNA in cultured chondrocytes. This 3.0-kb mRNA is also detectable in several chick embryo tissues but at a lower extent when compared to that present in cartilage and in hypertrophic chondrocytes. The CHPPR cDNA has a complete open reading frame coding for a polypeptide with a calculated mass of 35.6 kDa containing a proline-rich region with a PPLP motif (single-letter amino acid code). We demonstrate by Western blot analysis that two CHPPR isoforms are detected in the cell lysates from cultured chondrocytes when they are not in the culture medium; furthermore, we find that the CHPPR gene is expressed in vivo by chick embryo chondrocytes at higher levels in the prehypertrophic and hypertrophic zones.     

A new epidermal growth factor-like domain in the human core protein for the large cartilage-specific proteoglycan. Evidence for alternative splicing of the domain

A series of cDNA clones for the human core protein of the large cartilage-specific proteoglycan was isolated. Nucleotide sequencing of the clones provided over 2 kilobases of new coding sequences for the human protein. Comparison with published data for cDNA clones covering the same region in rat and chick indicated that domain 8, the lectin-like domain, is highly conserved among species. In contrast, domain 7 is poorly conserved among species. Some of the cDNA clones also contained an additional structural domain between domains 7 and 8 which was not described in the rat or chick sequences. The additional domain of 38 amino acids was highly homologous to epidermal growth factor (EGF)-like sequences seen in other proteins. Because some cDNA clones contained codons for the EGF-like domain and some did not, the results suggested that the EGF-like domain underwent alternative RNA splicing. To confirm alternative splicing of the EGF-like domain, RNA from cartilage cells was used as a template for the polymerase chain reaction. Products of two sizes were obtained. One had the size predicted for mRNA containing the domain and the other had the size predicted for mRNA not containing the domain. Alternative splicing of an EGF-like domain may provide a mechanism of feedback regulation for both the biosynthetic activity and the proliferation of cartilage cells.