Objective: The aim of this immunocytochemical study was to characterize the expression and distribution of the progesterone receptor (PR) and estrogen receptor (ER) in gingival fibroblasts using culture cells derived from people at various ages. Background: The reaction of female hormones is tissue or cell specific, and receptor availability in the cell is one of the major causes for the different reactions. Gingiva is a target tissue for female hormones; however, the characteristics of PR and ER in both the fibroblasts and the other component cells remain largely unknown. Materials: Gingival tissue was obtained from six people at various ages and culture fibroblasts were established. At least three passages of each cell line were strained for PR and ER with monoclonal antibodies (Clone 1A6, Clone 1D5, respectively). Results: PR positive cells were detected in all six cell lines through early passages to late ones, but ER were only observed in two of six samples with faint reactions. The staining intensity for PR was greater than for ER, but less than that shown in the MCF‐7 breast cancer cells, positive control. In every positive control test, ER reactivity was equal to or higher than that of PR. During the interphase, significantly fewer positive fibroblasts occurred compared with negative fibroblasts, and positive nuclei were even fewer. Meanwhile, most of the mitotic cells were PR positive, showing intense localization around chromosomes and on microtubules. These findings suggest that gingival fibroblasts are fundamentally capable of expressing PR and transmit the signal to target genes. Conclusions: The present study may conclude that in either gender or at any age, gingival fibroblasts express PR rather low in level and do not necessarily localize PR in a nuclear dominant fashion, which is an essential feature for reproductive organ cells. The poor ER reactivity shown in the gingival fibroblasts was discussed in view of the receptor subtype.
Basic fibroblast growth factor (bFGF) stimulates proliferation of chondrocytes and their extracellular matrix synthesis but inhibits terminal differentiation to hypertrophic cells (Kato, Y., and Iwamoto, M., (1990) J. Biol. Chem. 265, 5903-5909). In the present study, we examined changes in bFGF binding during chondrocyte cytodifferentiation. In cultures of pelleted growth plate chondrocytes, binding of 125I-bFGF to 140-kDa receptors was observed during the mitotic and matrix-forming stages but decreased to a very low level as chondrocytes became hypertrophic. Scatchard plot analysis showed that the decrease in binding of bFGF was due to a decrease in the number not in the affinity of the receptor. The loss of bFGF receptor was associated with a decrease in biological responses to bFGF. On the other hand, the binding of transforming growth factor-beta and epidermal growth factor was constant throughout all stages of growth plate chondrocytes. A rapid decrease in bFGF binding was not observed with articular chondrocytes or bFGF-exposed growth plate chondrocytes, perhaps because they scarcely underwent terminal differentiation. A decrease in bFGF binding associated with terminal differentiation in situ was also demonstrated by examination of sequential slices of growth plates. These observations suggest that rapid reduction in bFGF receptor is a special event during terminal differentiation.
To investigate the effects of hyaluronic acid (HA) on the release of proteoglycan by cultured rabbit chondrocytes.Articular cartilage chondrocytes were isolated from the knee joints of New Zealand white rabbits. Proteoglycan synthesis after incubation with HA was determined by measuring 35S-sulfate incorporation. Cells incubated with HA were labeled with 3H-glucosamine and applied to a Sepharose CL-2B column. After incubation of confluent cells with 35S-sulfate and then with HA in various concentrations in the presence or absence of cytokines, proteoglycan release from the cell matrix layer was measured.HA (M(r) 3 x 10(5) to 19 x 10(5)), at 10 micrograms/ml to 1 mg/ml, had little effect on the incorporation of 35S-sulfate or 3H-glucosamine into cartilage matrix proteoglycans, or on the hydrodynamic size of proteoglycan monomers, in rabbit chondrocyte cultures. However, at 10-1,000 micrograms/ml, HA suppressed the release of 35S-proteoglycans from the cell matrix layer into the medium in the presence and absence of interleukin-1, tumor necrosis factor alpha, or basic fibroblast growth factor.These results suggest that HA is a potent inhibitor of the displacement of matrix proteoglycan into culture medium.
The effect of PTH on chondrocyte proliferation as a function of cartilage age was examined. PTH[1-34] induced a 12- to 15-fold increase in the efficiency of colony formation in soft agar by chondrocytes from embryonic 13- to 19-d-old chickens and fetal 25-d-old rabbits with a 10-fold increase in their DNA content. It also caused a 2.5-fold increase in [3H]thymidine incorporation into DNA in fetal 25-d-old rabbit chondrocytes. No mitogenic responses to PTH were observed, however, in postnatal 7- to 21-d-old chick chondrocytes or postnatal 21-d-old rabbit chondrocytes. This age dependency was observed only with PTH: fibroblast growth factor, epidermal growth factor, and insulin stimulated chondrocyte proliferation irrespective of cartilage age. The absence of a mitogenic effect in postnatal chondrocytes was not due to a decrease in number or a reduction in affinity of receptors for PTH. PTH also increased [35S]sulfate incorporation into proteoglycans and the cyclic AMP level in fetal and postnatal chondrocytes, but at 100-fold higher concentrations (10(-8)-10(-7) M) than those (10(-10)-10(-9) M) required for the stimulation of cell division. These results suggest that PTH is a potent mitogen for embryonic chondrocytes, and that its mitogenic effect disappears selectively after birth.
During endochondral ossification, chondrocytes progress through several stages of maturation before they are replaced by bone cells. Chondrocyte proliferation, the first step in this complex multistage process, is strictly controlled both spatially and temporally but its underlying mechanisms of regulation remain unclear. In this study we asked whether chondrocytes produce syndecan-3, a cell surface receptor for growth factors such as fibroblast growth factor 2 (FGF-2), and whether syndecan-3 may play a role in proliferation during chondrocyte maturation. We found that proliferating immature cartilage from chick embryo tibia and sternum contained significant amounts of syndecan-3 mRNA, whereas mature hypertrophic cartilage contained markedly lower transcript levels. Immunohistochemical analyses on sections of Day 18 chick embryo tibia revealed that syndecan-3 was spatially restricted and indeed detectable only in immature proliferating chondrocytes in the top zone of growth plate. These syndecan-3-rich proliferating chondrocytes lay beneath developing articular chondrocytes rich in their typical matrix protein tenascin-C, resulting in a striking boundary between these two populations of chondrocytes. Immature proliferating chondrocyte populations reared in growth-promoting culture conditions displayed strong continuous syndecan-3 gene expression; upon induction of maturation by vitamin C treatment, syndecan-3 gene expression was markedly down-regulated. Treatment with FGF-2 for 24 h stimulated both syndecan-3 gene expression and chondrocyte proliferation; this growth stimulation was counteracted by cotreatment with heparinase I or III. The results of the study indicate that syndecan-3 participates in the maturation of chondrocytes during endochondral ossification and represents a regulator of the proliferative phase of this multistage process.
Abstract. A primary objective in the treatment of periodontal disease is the regeneration of the mineralized and soft connective tissue. PDL cells produce mineralized nodules in vitro which is one of the important functions of PDL cells for regenerative therapy. The purpose of this study was to investigate the effects of estradiol on mineralized nodule formation by human PDL cells. PDL cells were obtained from healthy donors and maintained in DMEM with 10% fetal bovine serum. Serum‐free medium was used when the effects of estradiol were tested. ALP activity in the supernatant of cells disrupted by sonication was analyzed spectrophotometrically. The formation of mineralized nodules was assessed by staining the PDL cells with alizarine red and counting the number of nodules. at Estradiol 20 ng/ml significantly enhanced the ALP activity and mineralized nodule formation compared to the control. These results suggested that estrogen status may modify the regenerative activity of periodontal tissue.
Membrane-bound transferrin-like protein (MTf), a glycosylphosphatidylinositol-anchored protein, is expressed at high levels in many tumors and in several fetal and adult tissues including cartilage and the intestine, as well as in the amyloid plaques of Alzheimer's disease, although its role remains unknown. MTf is one of the major concanavalin A-binding proteins of the cell surface. In this study, we examined the effects of anti-MTf antibodies and concanavalin A on cell shape and gene expression, using cultures of chondrocytes and MTf-overexpressing ATDC5 and C3H10T1/2 cells. In cultures expressing MTf at high levels, concanavalin A induced cell-shape changes from fibroblastic to spherical cells, whereas no cell-shape changes were observed with wild-type ATDC5 or C3H10T1/2 cells expressing MTf at very low levels. The cell-shape changes were associated with enhanced proteoglycan synthesis and expression of cartilage-characteristic genes, including aggrecan and type II collagen. Some anti-MTf antibodies mimicked this action of concanavalin A, whereas other antibodies blocked the lectin action. The findings suggest that the crosslinking of MTf changes the cell shape and induces chondrogenic differentiation. MTf represents the first identification of a plant lectin receptor involved in cell-shape changes and the differentiation of animal cells.
The effects of PTH and calcitonin (CT) on the expression of mineralization-related phenotypes by chondrocytes were examined. In cultures of pelleted growth-plate chondrocytes. PTH caused 60-90% decreases in alkaline phosphatase activity, the incorporation of 45Ca into insoluble material, and the calcium content during the post-mitotic stage. These effects of PTH were dose-dependent and reversible. In contrast, CT increased alkaline phosphatase activity, 45Ca incorporation into insoluble material, and the calcium content by 1.4- to 1.8-fold. These observations suggest that PTH directly inhibits the expression of the mineralization-related phenotypes by growth-plate chondrocytes, and that CT has the opposite effects.
