Cell proliferation, extracellular matrix mineralization, and ovotransferrin transient expression during in vitro differentiation of chick hypertrophic chondrocytes into osteoblast-like cells.

Differentiation of hypertrophic chondrocytes toward an osteoblast-like phenotype occurs in vitro when cells are transferred to anchorage-dependent culture conditions in the presence of ascorbic acid (Descalzi Cancedda, F., C. Gentili, P. Manduca, and R. Cancedda. 1992. J. Cell Biol. 117:427-435). This process is enhanced by retinoic acid addition to the culture medium. Here we compare the growth of hypertrophic chondrocytes undergoing this differentiation process to the growth of hypertrophic chondrocytes maintained in suspension culture as such. The proliferation rate is significantly higher in the adherent hypertrophic chondrocytes differentiating to osteoblast-like cells. In cultures supplemented with retinoic acid the proliferation rate is further increased. In both cases cells stop proliferating when mineralization of the extracellular matrix begins. We also report on the ultrastructural organization of the osteoblast-like cell cultures and we show virtual identity with cultures of osteoblasts grown from bone chips. Cells are embedded in a dense meshwork of type I collagen fibers and mineral is observed in the extracellular matrix associated with collagen fibrils. Differentiating hypertrophic chondrocytes secrete large amounts of an 82-kD glycoprotein. The protein has been purified from conditioned medium and identified as ovotransferrin. It is transiently expressed during the in vitro differentiation of hypertrophic chondrocytes into osteoblast-like cells. In cultured hypertrophic chondrocytes treated with 500 nM retinoic acid, ovotransferrin is maximally expressed 3 d after retinoic acid addition, when the cartilage-bone-specific collagen shift occurs, and decays between the 5th and the 10th day, when cells have fully acquired the osteoblast-like phenotype. Similar results were obtained when retinoic acid was added to the culture at the 50 nM "physiological" concentration. Cells expressing ovotransferrin also coexpress ovotransferrin receptors. This suggests an autocrine mechanism in the control of chondrocyte differentiation to osteoblast-like cells.

Expression of the cartilage matrix protein gene at different chondrocyte developmental stages.

Cartilage matrix protein (CMP), a major noncollagenous component of certain types of hyaline cartilage, is synthesized by chondrocytes in a developmentally regulated manner. In this study, we monitored the accumulation of CMP in the developing chicken limb and sternum by immunostaining. In older embryos, the specific extracellular staining was restricted to the resting/proliferative zone of metaphyseal cartilage and to the immediately adjacent hypertrophic cartilage. A lack of staining was observed in the peripheral layers of articular cartilage. Data were compared with the accumulation of CMP mRNA measured by Northern analysis relative to other cartilage-specific messages in cell cultures representing different stages of chondrocyte differentiation, as well as with the steady state mRNA levels in tissue samples. We found a correlation between the gene expression pattern of the in vitro cultures and the one observed in certain in vivo differentiation stages. The high-density mesenchyme culture was utilized as a model for studying the events at early stage I (stage Ia) of chondrogenesis. This culture was characterized by relatively low steady state mRNA levels for cartilage proteins, including the later activation of the CMP gene as compared to type II collagen or link protein genes, and relatively high steady state mRNA levels for type VI collagen and beta-actin. Chicken embryo chondrocyte cultures obtained from sterna of 14-day-old embryos, however, consisted predominantly of stage Ib chondrocytes, and showed high steady state levels for cartilage proteins, but relatively lower levels for type VI collagen and beta-actin mRNAs. In accordance with the in vivo data, a relatively high steady state level was detected for CMP mRNA in cultures of hypertrophic (stage II) chondrocytes. We also performed transient expression assays in the various culture systems to study the role of the promoter upstream and intronic control regions in the tissue- and developmental stage-specific regulation of the CMP gene. We showed that the enhancer worked in a lineage-specific manner, by further stimulating the minimal promoter activity independent of the developmental stage of chondrocytes, while it did not in other tissues. The promoter upstream control regions, however, seemed to play a role in restricting the promoter activity to a certain chondrocyte developmental stage.

Detection of enterotoxigenic Bacteroides fragilis and its toxin in stool samples from adults and children in Italy.

Stool samples from children and adults with and without diarrhea were examined for the presence of enterotoxigenic Bacteroides fragilis (ETBF) and its enterotoxin. A cytotoxic assay with HT-29 cells followed by neutralization with a hyperimmune antiserum were used to detect B. fragilis enterotoxin. ETBF isolates were recovered from 12% of healthy children and 17% of children with diarrhea (P = .42) and from 15% of healthy adults and 9.4% of adults with diarrhea (P = .31). Fecal B. fragilis enterotoxin was detected in four children (two with diarrhea and two without diarrhea) and in four adults with diarrhea. This study shows that in Italy, the rate of ETBF carriage is high, regardless if diarrhea is present. In some instances, the presence of ETBF is associated with detectable levels of fecal enterotoxin, but the significance of this finding deserves further evaluation.

Laminin chain expression by chick chondrocytes and mouse cartilaginous tissues in vivo and in vitro.

We have observed that laminins are expressed in the chondrocytes of chick embryo sternum, mouse limb bud, and adult mouse knee joint by the methods of in situ hybridization, immunohistochemistry, Western blotting, and immunoprecipitation. From in situ hybridization using similar sized RNA probes for different mouse laminin chains, mRNAs for the alpha 1, alpha 2, beta 1, beta 2, and gamma 1 chains were expressed in the chondrocytes of chick embryo sternum, mouse limb bud, and the articular cartilage cap and epiphyseal growth plate of adult mouse knee joint. Through the use of chain-specific antibodies, staining for laminins was observed in the cytoplasm of chondrocytes from chick embryo sternum, mouse limb bud, and adult mouse knee joint. Western blot analysis confirmed the presence of laminin chains in the cells and sternal tissues. Cultured chick embryonic sternal chondrocytes expressed laminin mRNAs in the proliferating stage (2-3 days of culture) but the level increased in the aggregated cells during the maturation stage (5-7 days of culture). Comparable data were also obtained after immunostaining the cells. Thus, laminins are expressed in significant amounts by chondrocytes and may have an important role in cartilage development.

Detection of enterotoxigenic Bacteroides fragilis by PCR.

Strains of enterotoxigenic Bacteroides fragilis (ETBF) are associated with diarrhea in young farm animals and, at least in particular settings, in children. Enterotoxin production by ETBF is currently detected by a tissue culture assay with HT-29 cells. We have developed a PCR assay based on the detection of the enterotoxin gene to identify ETBF in culture and in stool samples. Overall, 113 bacterial strains were examined, including 3 B. fragilis reference strains, 75 B. fragilis isolates (comprising 40 ETBF isolates), 20 Bacteroides spp. other than B. fragilis, and 15 strains belonging to other genera. Complete agreement was found between the results of the tissue culture assay and those of the PCR for our strains. PCR was also used to detect ETBF directly in fecal samples. Stools from two healthy volunteers were spiked with known numbers of ETBF and were processed by three different methods. A culture method, which required inoculation of the stools on selective plates and the collection of the whole bacterial growth ("sweeps"), was found to be the most sensitive. PCR performed with the plate sweeps yielded amplification products with a detection limit of 10(5) to 10(4) CFU/g of feces. By this method 18 samples of diarrheic stools (10 positive and 8 negative for ETBF) were examined. The results of the PCR were in accordance with the culture results in all cases. The proposed PCR assay represents a diagnostic tool for the rapid identification of ETBF in culture as well as in fecal samples.

The developmentally regulated avian Ch21 lipocalin is an extracellular fatty acid-binding protein.

Ch21, a developmentally regulated extracellular protein expressed in chick embryos and in cultured chondrocytes, was expressed in the baculovirus system, and the recombinant protein was purified to homogeneity by gel-filtration chromatography. Separation of two isoforms was achieved on an ion-exchange column. Previous work had shown that Ch21 belongs to the superfamily of lipocalins, which are transport proteins for small hydrophobic molecules. Studies were performed to identify the Ch21 ligand. By analysis of recombinant Ch21 on native polyacrylamide gel electrophoresis and by Lipidex assay, the binding of fatty acid to the protein was shown and a preferential binding of long-chain unsaturated fatty acids was observed. Both isoforms had the same behavior. The binding was saturable. Stoichiometry was about 0.7 mol of ligand/mol of protein. The protein binds the ligand in its monomeric form. Calculated dissociation constants were 2 X 10(-7) M for unsaturated fatty acids and 5 X 10(-7) M for stearic acid. The binding was specific; other hydrophobic molecules, as retinoic acid, progesterone, prostaglandins, and long-chain alcohols and aldehydes did not bind to the protein. Short-chain fatty acids did not bind to the protein. Ch21, also present in chicken serum, represents the first extracellular protein able to selectively bind and transport fatty acid in extracellular fluids and serum. We propose to rename the Ch21 protein as extracellular fatty acid-binding protein (Ex-FABP).