A plasmin-derived hexapeptide from the carboxyl end of osteocalcin counteracts oxytocin-mediated growth inhibition [corrected] of osteosarcoma cells.

We have previously described the presence of the functional plasminogen activator system on the surfaces of bone neoplastic cells and the fact that plasmin specifically cleaves bone matrix protein osteocalcin (OC). The cleavage of OC to NH2-midterminal (1-44) and COOH-terminal RFYGPV hexapeptide (44-49) proceeds with detachment of both products from bone mineral. Because the sequence of OC-derived hexapeptide (HP) is nearly identical to the E2 region of the oxytocin receptor (OTR), we set out to ascertain whether the HP interferes with the osteosarcoma (OS)-associated oxytocin (OT) system. We documented the presence and functional activity of OTRs in several OS cells by means of (a) OT-mediated inhibition of OS growth; (b) expression of OTR mRNA by means of reverse transcription-PCR; (c) immunofluorescence staining with IF3 monoclonal antibody specific for human OTR; and (d) saturation binding and Scatchard analysis of OT binding to the receptors of isolated membranes or intact OS cells. Although we could not demonstrate direct binding of HP to OT, the presence of HP in cultures of OS cells antagonizes the inhibitory effect of OT on these cells. Additionally, in competitive binding assays, the HP effectively competes with binding of OT to its cognate receptors. The results indicate the existence of an OTR/OT system in tumor cells of bone origin. Suggested plasminogen activator-OC-OTR/OT interactions may have an effect on the regulation of cell proliferation within the bone tissue as well as properties of the extracellular matrix surrounding the tumor foci in the bone.

Plasmin-mediated proteolysis of osteocalcin.

Plasmin cleaves osteocalcin at a site within its carboxyl end, thus creating an N-midterminal 1-43 and a short C-terminal 44-49 peptides. The products of the cleavage were identified by matrix assisted laser desorption ionization time of flight mass spectrophotometry and by reversed phase high performance liquid chromatography followed by N-terminal sequence determination. When separated by sodium dodecyl sulfide-polyacrylamide gel electrophoresis in the presence of reducing agents, large (LF; N-midterminal) and a small molecular weight (SF; C-terminal) fragments can be identified. The major cleavage site involves arg43-arg44 amino acid residues, and the resulting 44-49 C-terminal fragment appears as a slow migrating band on native gels (SFnat). Elevated levels of calcium ion inhibit the plasmin-mediated lysis of osteocalcin. Plasmin-mediated cleavage of osteocalcin occurs both in solution and when bound to hydroxyapatite. Both osteocalcin cleavage products detach from the hydroxyapatite substrate. Diisopropyl fluorophosphate-inhibited plasmin does not displace osteocalcin from the hydroxyapatite surface. Previously, the C-terminal pentapeptide has been shown to be chemotactic for bone cells while bone particles lacking osteocalcin were resistant to bone resorption. We therefore hypothesize that the plasmin-mediated digestion of free and hydroxyapatite-bound osteocalcin could play a role in the regulation of bone remodeling.

Mycoplasma-mediated bone resorption in bone organ cultures.

Mycoplasmas have been identified as one of many aetiological factors associated with experimental or human joint disease. Mycoplasma hyorhinis and M. arthritidis, but not M. pulmonis were found to cause significant release of calcium from murine long bone explants. The resorption process is inhibited by calcitonin, acetazolamide and by indomethacin. Mycoplasma-derived bone resorbing activity (M-BRA) is not an endotoxin as its effect is equally potent in cultures of bones obtained from endotoxin-responsive and -unresponsive mice. M-BRA is a high molecular weight compound resistant to proteases and heat but sensitive to hyaluronidase, lipase, detergents and in part to alkali and acid conditions. The active component is associated with the particulate fraction of the mycoplasma and its yield is enhanced by sonication. The damage to the subchondral bone in arthritis associated with a mycoplasma infection may be caused by a potent bone resorption inducing agent of mycoplasma origin.

Acquisition of resistance to 6-azauridine through DNA amplification in neoplastic but not normal osteoblasts.

In this communication, we have characterized the resistance to AZUrd in tumorigenic mouse C3H-OS osteosarcoma cells and non-tumorigenic MC3T3-E1 osteoblast cells. DNA and RNA blot analysis showed a 30-fold increase in UMP synthase specific DNA and a 10-fold increase in mRNA, respectively, in resistant versus non-resistant C3H-OS cells. No corresponding increases in either UMP synthetase DNA or mRNA were evident in resistant MC3T3-E1 osteoblasts. Karyotype analysis of MC3T3-E1 and C3H-OS cells revealed translocations in the resistant cells. Regardless of drug-sensitive or resistant phenotype, the normal and neoplastic cells exhibited aneuploidy which was significantly more pronounced in the non-resistant tumor cells. Additionally, the number of chromosomes decreased in all resistant cells whether normal or neoplastic. We conclude that genomic instability in neoplastic cells is a prerequisite for the generation of drug resistant variants via the process of gene amplification.

Binding and activation of plasminogen on the surface of osteosarcoma cells.

Plasmin (Pm) is a broad action serine protease implicated in numerous physiological functions. In bone, Pm may play a role in growth, resorption, metastasis, and the activation of growth factors. The various components of the Pm system are known to bind and function on the cell surface of various cell types, but no pertinent data are available describing membrane-bound Pm or its zymogen, plasminogen (Pg), in either normal or neoplastic bone cells. We report here that Pg binds to the surface of the human osteosarcoma cell line MG-63 and is activated to Pm by endogenous urokinase plasminogen activator (uPA). These conclusions are based on experiments utilizing radiolabeled compounds and a cell surface proteolytic assay measuring amidolytic activity of Pm. 125I-Pg binding to cells was time dependent, saturable, reversible, and specific. Binding was characterized by a relatively low affinity (Kd approximately 0.9 microM) and a high capacity (approximately 7.5 x 10(6) sites/cell). The binding of 125I-Pg was associated with lysine binding sites of the plasminogen molecule. Activation of 125I-Pg to 125I-Pm occurred on the cell surface and was dependent upon cell bound uPA, as determined by inhibitory antibodies. Binding of Pg to MG-63 monolayers represented approximately 80% bound specifically to the cell surface and the remainder to the surrounding extra-cellular matrix. Either co-incubation with uPA or pre-incubation with Pm resulted in increased 125I-Pg binding to osteosarcoma cells. Cell surface Pm proteolytic activity was confirmed by an amidolytic chromogenic assay. Both Pm and Pg bound to cells with Pg being activated by endogenous uPA. Plasmin activated on the cell surface was partially protected from inhibition by alpha 2-antiPm (requiring Pm lysine binding site interaction) but inhibited by aprotinin, (interacting directly with the Pm catalytic site). Resistance of cell bound Pm to alpha 2-antiPm inhibition suggests that cell surface proteolysis can occur in the presence of a soluble Pm inhibitor known to exist in the extracellular space. Based on these results, we speculate that the various bone physiological processes implicating Pm may occur at or near the bone cell surface.

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Involvement of the plasmin system in dissociation of the insulin-like growth factor-binding protein complex.

A variety of treatments, including acid, heparin, and proteases, are known to free insulin-like growth factors (IGFs) from their binding proteins (IGFBPs). However, the physiologically relevant mechanism regulating the interaction of IGFs and IGFBPs is unknown. We report here the ability of plasmin to dissociate IGFs from IGFBPs. In chromatographic experiments, plasmin completely dissociated complexes of [125I] IGF-I-BP and [125I]IGF-II-BP formed with purified decidual IGFBP (hIGFBP-1) or IGFBPs present in medium conditioned by human osteosarcoma MG-63 cells. Plasmin dissociation of IGF-BP complexes was dose dependent. Neither plasminogen nor plasminogen activators (PAs) alone affected dissociation; however, activation of plasminogen to plasmin by either urokinase PA or tissue-type PA resulted in the dissociation of IGF-BP complexes. Plasmin dissociated immunoreactive and bioactive IGF from IGFBP equivalent to approximately 70% and approximately 60% of the acid control value, respectively. In medium conditioned by MG-63 cells, dissociation of IGF-BP complexes was catalyzed by PAs secreted by MG-63 cells, principally urokinase PA. Limited plasmin degradation of IGF was suggested by chromatographic experiments involving [125I] IGF. Treatment of uncomplexed IGF-I with plasmin concentrations equivalent to those in chromatographic experiments did not result in a significant loss of bioactivity, although a 2-fold increase in the plasmin concentration resulted in a approximately 20% loss of activity. Similar plasmin treatment of equimolar concentrations of hIGFBP-1 resulted in a marked degradation of IGFBP, with loss of IGF-binding ability. In vitro experiments confirmed plasmin dissociation of bioactive IGF-I from hIGFBP-1. In MG-63 cells, IGFBPs can form an IGF reservoir in the pericellular space surrounding the cells by combining IGFs with IGF-BP to form complexes that are incapable of binding to the IGF receptors. The secretion of PAs by osteosarcoma cells and the availability of plasminogen in the extravascular tissues indicate the possibility of a regulatory system in osteosarcoma cells in which pericellular plasmin affects the availability of IGFs to their membrane receptors.

Insulin-like growth factor binding protein (IGFBP) inhibits IGF action on human osteosarcoma cells.

The influence of a human insulin-like growth factor binding protein, hIGFBP-1, on the action of IGFs on human osteosarcoma cells was examined. hIGFBP-1 was found to block binding of IGFs to their receptors on MG-63 cells and subsequent IGF stimulation of DNA synthesis. Concurrent incubation of hIGFBP-1 with either 125I-IGF-I or 125I-IGF-II prevented the binding of both 125I-IGFs to cells in a dose-dependent manner. hIGFBP-1 inhibition of IGF binding occurred similarly under both 4 degrees and 37 degrees C conditions. Additionally, hIGFBP-1 facilitated the dissociation of IGFs bound to cells. The inhibitory effect of hIGFBP-1 on IGF-1 mediated 3H-thymidine incorporation into DNA was dose dependent. hIGFBP-1 did not inhibit binding to or stimulation of growth in MG-63 cells by des3-IGF-1, an IGF-I analog with a 100-fold less affinity for hIGFBP-I. This confirmed that hIGFBP-1 competed for IGF receptor binding sites on MG-63. Since hIGFBP-1 did not bind to cells, inhibition of IGF action was indirect, presumably through the formation of extracellular soluble bioinactive IGF-BP complexes.

Resistance to pyrazofurin and 6-azauridine in normal MC3T3-E1 murine osteoblasts.

Stable variants resistant to pyrazofurin (PF) and 6-azauridine (AZUrd) were serially selected in increasing drug concentrations from an MC3T3-E1 nontumorigenic murine osteoblastic cell line. Monophosphates of both AZUrd and PF competitively inhibit orotidine-5'-monophosphate decarboxylase (ODCase) activity of the UMP synthase multifunctional enzyme. When compared to the wild type cells, the AZUrdr and PFr lines were 3000- and 10,000-fold more resistant, respectively. Flow cytometry indicated tetraploidy in wild type cells and a reduction of DNA content in both resistant cell lines. DNA dot blot analysis showed no amplification of the gene coding for UMP synthase in either AZUrdr or PFr cells. Measurements of UMP synthase showed a 6-fold higher activity in AZUrdr cells and no significant difference in PFr cells as compared to wild type. Sensitivity to 5-fluorouracil was increased in the AZUrdr line as opposed to PFr and normal cell lines, indicating an increased orotate phosphoribosyltransferase activity in the AZUrdr cells. In comparison to wild type cells, PFr cells were 100-fold resistant to 6-methylmercaptopurine riboside, suggesting a lack of adenosine kinase activity. The control and AZUrdr cells showed equal sensitivity to 5-fluorouridine, thus indicating unchanged uridine kinase levels. While PFr cells were not cross-resistant to AZUrd, the AZUrdr cells were cross-resistant to PF. These results indicate the possibility of an altered ODCase active site. Although amplification of unrelated sequences cannot be excluded, our findings show that bone tetraploid, nontumorigenic cells acquire drug resistance through mechanisms other than the amplification of a target gene and that this resistance is accompanied by the partial loss of a chromosomal complement.

Bone resorption in osteogenic sarcoma--II. Resorption of the bone collagenous matrix by tumor cells, normal fibroblasts and macrophages.

Three osteogenic sarcoma cell lines of human and canine origin were compared to normal fibroblastic cells and peptone-induced murine peritoneal macrophages in terms of bone collagenous matrix (BCM) resorption capacity. The dissolution of the BCM was measured in an in vitro system consisting of the tested cells and live or killed [3H]-proline-labeled fetal mouse long bones. Experiments with osteogenic sarcoma cells revealed a paradoxical phenomenon indicating an inverse relationship between the number of tumor cells and the rate of collagen resorption from live bones. On the other hand, collagen matrix of devitalized bones, particularly those denatured by exposure to heat, is strongly resorbed by osteogenic sarcoma cells even in the presence of serum. Contrary to osteogenic sarcoma cells, normal fibroblasts do not resorb collagen from either live or killed bones, regardless of the devitalization method and culture conditions utilized. Macrophages resorb collagenous matrix from live bones, but their collagen resorption activity from devitalized bones depends greatly on choice of the incubation condition. Results have shown that osteogenic sarcoma tumor cells, when acting alone, may not have the capacity to destroy healthy bone. We suggest, therefore, that bone destruction seen in osteogenic sarcoma patients depends on the metabolic condition of the affected bone, and the interaction between the tumor and normal host cells and tissues.

Bone resorption in osteogenic sarcoma. I. Release of calcium by tumor cells, normal fibroblasts, and macrophages.

The bone calcium resorption activities of three different types of cells that are present either within or in the vicinity of an osteogenic sarcoma tumor mass were examined: osteogenic sarcoma cells, normal fibroblasts, and macrophages. Release of calcium was measured in bone organ cultures in live and killed 45Ca-labeled fetal or newborn mouse long bones. The bone explants, tibiae and humeri, were co-cultured with various numbers of effector cells in microwell plates. Cultured osteogenic sarcoma cells resorb calcium from both live and heat-devitalized bones in a cell-number-dependent manner. A reduced effect of the tumor cells on killed bone suggests that the release of calcium from living bone by tumor cells is mediated partially through stimulation of the endogenous bone-resorbing systems. Fibroblasts also resorb calcium both from live and killed bones but at a lower rate than osteogenic sarcoma cells. Peptone-elicited peritoneal macrophages are capable of sustaining calcium resorption from live bones as well as from bones devitalized by a mild nondenaturating method. Macrophages, however, failed to resorb calcium from heat-killed bones. The release of osseous calcium and bone damage associated with osteogenic sarcoma are manifestations of the resorbing properties and interactions among the tumor, bone, and host tumor infiltrating cells.

Effect of 6-azauridine and pyrazofurin on fibrinolysis by L1210 leukemic cells.

The expression of plasminogen activator activity (PA) by L1210 leukemic ascitic cells, obtained from the peritoneum of BDF1 mice, increases in the terminal stages of the disease. Treatment of mice carrying advance leukemia (day 6 following inoculation with 10(6) cells i.p.) with 6-azauridine (AzUR) results in prolonged survival (2-3 days) and also in increased expression of PA activity by the ascitic cell population. Similar treatment with pyrazofurin (PF), another inhibitor of orotidylate decarboxylase and of de novo pyrimidine synthesis, fails to produce either of these effects. Neither AzUR or PF, given at the early stage of tumor growth (day 3), extend the life span nor do they cause increase of the PA activity. Thus, the elevation in PA activity following treatment with AzUR is associated with the asymptotic stage of the disease and this phenomenon correlates positively with the life-prolonging effects of this drug. An analysis of the PA activity elicited by intact cells, secretions, and cellular digests suggests that most of the activity originates on the surface of the cells. The results indicate that the described in vivo effect of AzUR, but not that of PF, on late-stage leukemia, is mediated by the changes in the fibrinolytic potential of the tumor or host cells rather than through the inhibition of the de novo pyrimidine synthesis.

Delayed growth inhibition of human leukaemic cells in culture following treatment with aminonucleoside of puromycin.

The effects of the aminonucleoside analogue of puromycin (AMS) on the growth of the CCRF-CEM human leukaemic lymphoblast cell line have been studied. CEM lymphoblasts are capable of growth in the presence of AMS for a limited period of time, in a manner similar to other transformed cell lines in culture. However, a delayed effect of AMS was found to take place at the time of the third cell division after application of the drug. This phenomenon of delayed growth inhibition has not yet been described for any other type of cell. The delayed inhibition of CEM cells caused by AMS manifests regardless of the subsequent presence or absence of the drug. The magnitude of the delayed inhibition is linearly dependent on the concentration of AMS during the initial incubation period. Cell proliferation during drug application is not necessary for establishing the inhibition. Following the inhibition period, the cells resume a normal rate of growth.

Fusobacterium in presumed Actinomyces canaliculitis.

Based on stained smears of material obtained from the canaliculus, three cases of canaliculitis were presumed to be caused by Actinomyces. Cultures of these cases showed Fusobacterium to be the probable infectious agent producing the disease.