Localization of cell groups sensitive to parathyroid hormone and calcitonin in rat skeletal tissue.

The level of cyclic AMP in various fractions of rat skeletal tissue was measured after in vitro or in vivo administration of parathyroid hormone and calcitonin. Incubations of bone fractions prepared from young (5 weeks of age thyroparathyroidectomized rats revealed that both parathyroid hormone and calcitonin increased the cyclic AMP level in fractions of epiphysis, metaphysis and marrow cells. Cyclic AMP accumulation in incubated perisoteum and diaphysis were induced solely by parathyroid hormone. In in vivo experiments the cyclic AMP level in the tibia of the thyroparathyroidectomized rat was increased by infusion of either parathyroid hormone or calcitonin, and the simultaneous administration of each maximally effective dose of the two hormones exhibited an additive effect. Within 2 min, parathyroid hormone infusion caused an elevation of cyclic AMP content in periosteum and metaphysis. Rapid increase of cyclic AMP in the metaphysis was also induced by calcitonin, and the effect of the two hormones on cyclic AMP accumulation in this fraction was additive. Small but significant increase of cyclic AMP in the diaphysis was detected at 5 min after the administration of parathyroid hormone. Calcitonin infusion did not show any consistent effects on periosteum and diaphysis.     

Hormone-specific responses and biosynthesis of sulfolipids in cell lines derived from mammalian kidney.

The established cell lines isolated from mammalian kidney were characterized by its receptor activities against hormones and the ability to synthesize sulfolipids localized in the renal tubule. The level of 3':5'-cyclic AMP in JTC-12.P3 (monkey kidney) cells increased in 2 min as much as 2.5-5-fold on activation with 1.0 unit/ml of bovine parathyroid hormone or 1.9 units/ml of synthetic parathyroid hormone (1-34) resulting in intracellular cyclic AMP concentration of more than 40 pmol/mg protein. Prostaglandin E1 (14 micronM) and isopropylnorepinephrine (10 micronM) were also found to increase the concentration of cyclic AMP by more than 30- and 9-fold, respectively. Addition in medium of calcitonin, arginine vasopressin, adrenocorticotropic hormone and glucagon caused no significant changes of cyclic AMP level in the cell. In contrast, MDCK, a cell line isolated from canine kidney, reacted to arginine vasopressin, isopropylnorepinephrine and prostaglandin E1 and only slightly to parathyroid hormone. MDBK cell line derived from bovine kidney or fibroblast cell lines from rat lung and guinea pig kidney did not react to any of the hormones specific to kidney, i.e. arginine vasopressin, calcitonin or parathyroid hormone in the presence of theophylline. However, in the presence of 2 mM isobutylmethylxanthine, small but significant elevation of cellular cyclic AMP levels in response to calcitonin, arginine vasopressin, isopropylnorepinephrine and prostaglandin E1 was observed. The cell lines JTC-12, MDCK and MDBK, when incubated with H235SO4, incorporated the isotope into sulfolipids assigned as sulfatides and ceramide dihexoside sulfate or in MDCK also into cholesterol sulfate. The results suggested that JTC-12, MDCK and MDBK cell lines are epithelial origin and also JTC-12 and MDCK originated most probably from renal tubular cells of cortex and medulla, respectively.     

Cyclic AMP-dependent and -independent effects on tissue-type plasminogen activator activity in osteogenic sarcoma cells; evidence from phosphodiesterase inhibition and parathyroid hormone antagonists

The plasminogen activator (PA) in clonal osteogenic sarcoma cells of rat origin (UMR 106-01 and UMR 106-06) and in osteoblast-rich rat calvarial cells has been characterized using specific antibodies to be tissue-type PA (tPA). An Mr value of 75,000 by SDS-polyacrylamide gel electrophoresis and fibrin autoradiography supports this characterization. There was also evidence for an Mr 105,000 component, which could be due to a proteinase-inhibitor complex. The mechanism of regulation of this tPA activity has been studied in the clonal osteogenic sarcoma cells. Parathyroid hormone (PTH) and prostaglandin E2, which increase cyclic AMP production in the sarcoma cells, also increased tPA activity. The sensitivity and magnitude of the tPA response to PTH and prostaglandin E2 were increased by simultaneous treatment with isobutylmethylxanthine (IBMX) at drug concentrations which had little effect themselves on tPA activity. In UMR 106-06 cells, which unlike UMR 106-01 cells show a cyclic AMP response to calcitonin, tPA activity was also increased in response to calcitonin, and the effect was enhanced by IBMX. 1,25-Dihydroxyvitamin D-3 also increased tPA activity in the cells, but this response was not modified by IBMX. Synthetic peptide antagonists of PTH-responsive adenylate cyclase, [34Tyr]-hPTH (3-34) amide and [34Tyr]-hPTH (5-34) amide, inhibited the PTH-induced increase in tPA activity over the same concentration range at which they inhibited cyclic AMP production, but the antagonist peptides had no effect on the tPA responses to prostaglandin E2, calcitonin or 1,25-dihydroxyvitamin D-3. These data indicate that cyclic AMP mediates the actions of PTH, prostaglandin E2 and calcitonin in increasing tPA activity in the clonal osteogenic sarcoma cells. 1,25-Dihydroxyvitamin D-3, on the other hand, increases tPA activity through a mechanism independent of cyclic AMP.     

Failure to demonstrate the stimulative effect of calcitonin on cyclic AMP accumulation in avian bone in vitro

The effect of calcitonin on the metabolism of calcium and cyclic AMP in the avian bone was examined in vitro. In the chick embryonic cortical bone, calcitonin affected neither the level of cyclic AMP nor the parathyroid hormone-induced stimulation of calcium release from bone. Also, the level of cyclic AMP in the cortical or medullary bone of Japanese quails was not increased by calcitonin. The medullary bone did not respond to calcitonin either in freshly prepared tissue or in tissue cultured for 48 hr in the absence of calcitonin. The activity of renal adenylate cyclase of Japanese quails was also calcitonin-insensitive. The inability of calcitonin to increase the level of cyclic AMP and to antagonize the parathyroid hormone-induced stimulation of calcium release from bone may account for the lack of hypocalcemic effect of calcitonin in birds as reported by other investigators.     

Stimulation by defined parathyroid hormone fragments of cell proliferation in skeletal-derived cell cultures.

We have reported previously that parathyroid hormone (PTH) acts on cultured bone cells to stimulate creatine kinase (CK) activity and [3H]thymidine incorporation into DNA via phosphoinositide turnover, in addition to its other actions via increased cyclic AMP production. We also found that mid-region fragments of PTH stimulate [3H]thymidine incorporation into avian chondrocytes. In the present study of mammalian systems, we demonstrate differential effects of defined synthetic PTH fragments on CK activity and DNA synthesis, as compared with cyclic AMP production, in osteoblast-enriched embryonic rat calvaria cell cultures, in an osteoblast-like clone of rat osteosarcoma cells (ROS 17/2.8) and in chondroblasts from rat epiphysial cartilage cell cultures. Unlike full-length bovine (b)PTH-(1-84) or the fully effective shorter fragment human (h)PTH-(1-34), fragments lacking the N-terminal region of the hormone did not increase cyclic AMP formation, whereas they did stimulate increases in both DNA synthesis and CK activity. Moreover, the PTH fragment hPTH-(28-48) at 10 microM inhibited the increase in cyclic AMP caused by 10 nM-bPTH-(1-84). The increase of CK activity in ROS 17/2.8 cells caused by bPTH-(1-84) or hPTH-(28-48) was completely inhibited by either cycloheximide or actinomycin D, as was shown previously for rat calvaria cell cultures. These results indicated the presence of a functional domain of PTH in the central part of the molecule which exerts its mitogenic-related effects on osteoblast- and chondroblast-like cells in a cyclic AMP-independent manner. Since cyclic AMP formation by PTH leads to bone resorption, specific mid-region fragments of PTH might prove suitable for use in vivo to induce bone formation without concomitant resorption.     

Effect of prostaglandin E on the adenyl cyclase-cyclic AMP system and gluconeogenesis in rat renal cortical slices.

Prostaglandin E was found to increase the formation of cyclic acdenosine 3',5'-monophosphate (cyclic AMP) by renal cortical slices. This increased release of cyclic AMP was not influenced by the absence of Ca2+ in the incubating media. The enhanced production of cyclic AMP was probably mediated by stimulation of membrane-bound adenylate cyclase activity. An increase in adenyl cyclase activity was observed with increasing concentrations of prostaglandin E. Furthermore, prostaglandin E augmented glucose production from alpha-ketoglutarate. This effect on gluconeogenesis was abolished by the removal of Ca2+ from the incubating medium. These effects are similar to those described for parathyroid hormone and suggest that the renal cortex is a prostaglandin-dependent system. Prostaglandin E decreased cyclic AMP production and glucose production (from alpha-ketoglutarate) in response to submaximal doses of parathyroid hormone, suggesting that prostaglandin may be important in modulating the intracelluar action of parathyroid hormone in the kidney cortex.     

Studies in vivo on the effects of parathyroid hormone upon kidney cyclic adenosine 3',5'-monophosphate content using rapid tissue fixation by microwave irradiation.

Microwave irradiation is shown to be a useful method for simultaneously killing chicks and fixing tissues. Renal adenylate cyclase and phosphodiesterase activities were rapidly abolished by microwaving. The increase in chick kidney cyclic adenosine 3',5'-monophosphate (cyclic AMP) content produced by intravenous bovine parathyroid hormone (PTH) injection was much greater in microwaved birds than in those killed by cervical dislocation with subsequent tissue fixation in liquid nitrogen. After PTH injection there was a prolonged elevation of renal cyclic AMP content. At the time of maximum response (2 minutes), log. dose-response curves were linear in the dose range 0.1-10 U. The responses to three different bovine PTH preparations were indistinguishable. Arginine vasopressin, arginine vasotocin, salmon calcitonin and prostaglandin E1 did not affect kidney cyclic AMP content within 2 minutes. Because of its specificity and precision, the method is of use for the in vivo bioassay of PTH. Injection of CaCl2 (20 mumoles) 1 minute before, or conjointly with, bovine PTH inhibited the subsequent increase in kidney cyclic AMP content. The synthetic bovine PTH peptide fragments BPTH (1-34) and BPTH (2-34) both increased chick kidney cyclic AMP content. The use of such fragments allows investigation of the structural requirements of PTH for interaction with the systems regulating cyclic AMP metabolism in the kidney in vivo.     

Parathyroid hormone-induced changes in cyclic nucleotide levels during relaxation of the rabbit [correction of rat] aorta

Parathyroid hormone is a potent vasodilator in vivo and relaxes vascular tissue in vitro. Since parathyroid hormone action in kidney and bone is thought to be mediated by stimulation of cellular cyclic AMP production, the present study was designed to monitor changes in cyclic AMP and cyclic GMP in vascular tissue during relaxation by parathyroid hormone. Rabbit aortic strips were quick-frozen at various times after exposure to parathyroid hormone and the percent relaxation and cyclic nucleotide levels were determined. Cyclic AMP concentrations were elevated about 3-fold within 30 seconds after treatment with hormone. This corresponded to a 10% relaxation of the norepinephrine-contracted tissue. After five minutes, cyclic AMP was still elevated 2-fold above basal and the relaxation response was maximal (36%). The cyclic AMP and relaxation responses to parathyroid hormone were markedly potentiated by forskolin or methylisobutylxanthine. Parathyroid hormone produced a small but significant increase in cyclic GMP concentrations only at early time points whereas sodium nitroprusside substantially increased cyclic GMP and relaxed the strips at all times studied. The increase in cyclic AMP levels after exposure to parathyroid hormone occurred prior to or coincident with the onset of relaxation of the aortic strips. These findings are supportive of the hypothesis that the vascular actions of parathyroid hormone involve cyclic AMP.     

Alterations in calcitonin and parathyroid hormone responsiveness of adenylate cyclase in F9 embryonal carcinoma cells treated with retinoic acid and dibutyryl cyclic AMP

Teratocarcinoma cells in culture offer an in vitro system for studying certain aspects of embryonic differentiation. To gain some insight into regulatory systems that might be operative during early development, we have characterized the alterations that occur in the hormonal responsiveness of the F9 embryonal carcinoma cell membrane adenylate cyclase with differentiation. Adenylate cyclase of F9 cells is stimulated in the presence of 10 μM GTP by calcitonin, prostaglandin E₁, (?) isoproterenol, and epinephrine, while parathyroid hormone is only slightly effective. Of these active hormones, calcitonin is the most potent stimulator of cyclic AMP production. Exposure of F9 cells to retinoic acid induces differentiation to parietal endodermal cells. Basal, GTP-, and fluoride-stimulated adenylate cyclase activities show a progressive increase with the retinoic acid-induced change to the endodermal phenotype. Differentiation to the endodermal cell type markedly alters the adenylate cyclase response to calcitonin and parathyroid hormone; the cyclase of endodermal cells exhibits a low response to calcitonin while parathyroid hormone dramatically enhances cyclic AMP formation. Treatment of the retinoic acid-generated endodermal cells with dibutyryl cyclic AMP converts these cells to a type exhibiting neural-like morphology. The adenylate cyclase system of these cells is only stimulated by parathyroid hormone, prostaglandin E₁, isoproterenol, and epinephrine. Calcitonin responsiveness has been lost in these cells. These variations in calcitonin and parathyroid hormone responsiveness suggest a possible regulatory role for these hormones during embryonic development. Further more, the results indicate that changes in adenylate cyclase hormonal responsiveness might serve as useful markers during early stages of differentiation.     

Stimulation of bone resorption in organ culture by cholera toxin

Bone resorption in organ cultures of neonatal mouse calvaria was stimulated by choleragen (cholera enterotoxin) in a dose-related manner (0.5 to 5.0 ng/ml). Stimulation was potentiated by the cyclic nucleotide phosphodiesterase inhibitor isobutylmethylxanthine (4 μM) and was inhibited by human calcitonin (100 ng/ml), but not by indomethacin (0.7 μM), an inhibitor of the fatty acid cyclooxygenase. The action of choleragen on cyclic AMP accumulation and bone resorption was consistent with the known characteristics of this toxin: 1. choleragen increased cyclic AMP accumulation in bone cultures; 2. there was a lag period (20 – 120 min) prior to an increase in cyclic AMP accumulation following addition of choleragen; 3. incubation with choleragen for only 4 h stimulated bone resorption in the subsequent 44 h as much as did continuous incubation with choleragen for 48 h; and 4. choleragenoid, the biologically inactive toxoid, did not stimulate bone resorption in the concentration range in which choleragen was active. We conclude that activation of adenylyl cyclase and the subsequent increase in cyclic AMP production can stimulate bone resorption, and that cyclic AMP may, therefore, be involved in the enhanced bone resorption mediated by parathyroid hormone and other agents which increase cyclic AMP in bone.     

The effect of prostaglandin I2 and 6a-Carba-PGI2 on the motility of isolated osteoclasts

We have recently found that calcitonin (CT), a hormone which inhibits osteoclastic bone resorption, completely abolishes the normally intense cytoplasmic movement of isolated osteoclasts. We have also found that prostaglandin (PG)I2 causes an identical change in behaviour. In this paper we extend our investigations into the mode of action of PGI2 and a stable analogue, 6a-Carba-PGI2. We found that, unlike CT which causes prolonged immotility in osteoclasts, the effect of PGI2 and 6a-Carba-PGI2 were transient. Our results suggest that the transient nature of the inhibition was neither caused by inactivation of these compounds, nor was it due to production in the cultures of an osteoclastic stimulator. CT, PGI2 and 6a-Carba-PGI2 all appear to operate by increasing the intracellular cyclic AMP level. We found no refractoriness to either CT, dibutyryl cyclic AMP or 8-bromo cyclic AMP, and neither PGI2 nor 6a-Carba-PGI2 affected the sensitivity of osteoclasts to CT or dibutyryl cyclic AMP. This implies that refractoriness of osteoclasts to PGI2 and 6a-Carba-PGI2 develops at some stage in the interaction between PG and cell proximal to cyclic AMP production. We also found that there was cross-tachyphylaxis between PGI2 and 6a-Carba-PGI2, and this suggests that these two compounds share a receptor site on osteoclasts.     

The influence of sex steroids on calcium- and magnesium-induced mitogenesis in isolated rat thymic lymphocytes

Elevated calcium and magnesium concentrations promoted mitotic activity in rat thymic lymphocyte cultures. Oestradiol inhibited calcium- but not magnesium-induced mitogenesis. One prerequisite for the mitogenic action of calcium is a raised intracellular concentration of cyclic adenosine 3′5′ monophosphate (cyclic AMP) but cyclic AMP-induced mitogenesis was insensitive to oestradiol. This suggests that the steroid blocks the mitogenic process at a stage preceding the endogenous cyclic AMP elevation. Furthermore the mitogenic actions of adrenaline, which stimulates adenylate cyclase (the enzyme responsible for cyclic AMP biosynthesis), and caffeine, which inhibits phosphodiesterase (the enzyme which degrades cyclic AMP) were also insensitive to oestradiol inhibition. This precludes a direct effect of the steroid on these enzymes. However, oestradiol did inhibit the mitogenic action of parathyroid hormone (PTH). Since the mitogenic action of PTH probably involves increased calcium entry to the cell, oestradiol may block this ion influx. The inhibition of calcium- and PTH-induced mitogenesis must be attributable to some structurally specific action of oestradiol. The steroids cholesterol, progesterone and testosterone all failed to reduce calcium-induced mitogenesis, whereas both α and β oestradiol were effective. In addition to its insensitivity to oestradiol inhibition, magnesium-stimulated mitosis was unaffected by both imidazole and calcitonin at concentrations which significantly reduced calcium-stimulated proliferation. These findings are compatible with the thesis that magnesium-induced mitogenesis does not involve the elevation of cyclic AMP concentrations.     

Effects of prostaglandins and other drugs on the cyclic AMP content of cultured bone cells.

Prostaglandins of the E-series (PGE1 and PGE2) may be involved in disease-related, localized loss of bone. E-prostaglandins increase the cyclic AMP content of many cells; and, to determine if their effects on bone are mediated by cyclic AMP, we examined the effects of E-prostaglandins and of other agents on the cyclic AMP content of cultured bone cells. PGE2 produced a rapid, marked and dose-related increase in the cyclic AMP content of confluent monolayers of bone cells isolated from newborn rat calvaria. At 2.8 X 10(-6) M, PGE1 and PGE2 had approximately the same effect, while the effect of PGF2alpha was much less pronounced. In the presence of theophylline, PGE2 had a more marked effect than parathyroid hormone (PTH) and the combination of PGE2 and PTH had a synergistic effect. The divalent, cationic, ionophore, A23187, produced an increase in cellular cyclic AMP and had an additive effect in combination with PGE2. Synthetic salmon calcitonin (CT), which inhibits the bone resorptive effect of PGE2, increased cellular cyclic AMP and had an additive effect in combination with PGE2. A prostaglandin antagonist, SC-19220, partially inhibited the resorptive effect of PGE2 and reduced its effect on cellular cyclic AMP. The calcium antagonist, D600, inhibited the bone resorptive effects of PGE2 but had no effect on increased cellular cyclic AMP produced by PGE2. The marked effect of PGE2 on bone cell cyclic AMP suggests that this action is involved in the mechanism of PGE2-related bone loss. The fact that agents with different effects on PGE2-induced increases in cellular cyclic AMP can inhibit its resorptive actions, suggests that PGE2-induced changes in cyclic AMP may be related less to its resorptive actions than to its inhibitory effect on bone formation.     

Hormone-specific responses and biosynthesis of sulfolipids in cell lines derived from mammalian kidney

The established cell lines isolated from mammalian kidney were characterized by its receptor activities against hormones and the ability to synthesize sulfolipids localized in the renal tubule.The level of 3′: 5′-cyclic AMP in JTC-12.P3 (monkey kidney) cells increased in 2 min as much as 2.5–5-fold on activation with 1.0 unit/ml of bovine parathyroid hormone or 1.9 units/ml of synthetic parathyroid hormone (1–34) resulting in intracellular cyclic AMP concentration of more than 40 pmol/mg protein. Prostaglandin E₁ (14 μM) and isopropylnorepinephrine (10 μM) were also found to increase the concentration of cyclic AMP by more than 30- and 9-fold, respectively. Addition in medium of calcitonin, arginine vasopressin, adrenocorticotropic hormone and glucagon caused no significant changes of cyclic AMP level in the cell.In contrast, MDCK, a cell line isolated from canine kidney, reacted to arginine vasopressin, isopropylnorepinephrine and prostaglandin E₁ and only slightly to parathyroid hormone. MDBK cell line derived from bovine kidney or fibroblast cell lines from rat lung and guinea pig kidney did not react to any of the hormones specific to kidney, i.e. arginine vasopressin, calcitonin or parathyroid hormone in the presence of theophylline. However, in the presence of 2 mM isobutylmethylxanthine, small but significant elevation of cellular cyclic AMP levels in response to calcitonin, arginine vasopressin, isopropylnorepinephrine and prostaglandin E₁ was observed.The cell lines JTC-12, MDCK and MDBK, when incubated with H₂³⁵SO₄, incorporated the isotope into sulfolipids assigned as sulfatides and ceramide dihexoside sulfate or in MDCK also into cholesterol sulfate.The results suggested that JTC-12, MDCK and MDBK cell lines are epithelial origin and also JTC-12 and MDCK originated most probably from renal tubular cells of cortex and medulla, respectively.     

Bioactivity of amino terminal fragments of parathyroid hormone and parathyroid hormone related peptide in rat kidney slices: no effect of dietary phosphate deprivation

Humoral hypercalcemia of malignancy has been associated with the production of a recently cloned peptide human parathyroid hormone related protein (hPTHRP). One of the markers of this disease is an increased urinary excretion of cyclic AMP. The postreceptor mechanism of action and physiological role of hPTHRP remain obscure. To study the activity of hPTHRP 1-34 compared to rat and human parathyroid hormone (PTH) 1-34 we incubated these peptides with rat kidney slices and measured the cyclic AMP generated in the supernatant. hPTHRP 1-34 was equipotent with human PTH 1-34 but both were 5 times less active than rat PTH 1-34. Previous studies have suggested that a low dietary phosphate intake results in renal resistance to the phosphaturic action of PTH perhaps mediated by reduced adenylate cyclase activation by PTH. To determine whether, during dietary phosphate restriction, hPTHRP 1-34 has actions different from hPTH 1-34 we studied their effects following dietary phosphate deprivation. Dietary phosphate restriction had no significant effect on the cyclic AMP generating activity of any of the peptides. We conclude that hPTHRP 1-34 may be operating through similar mechanisms as human PTH 1-34 and that the previously observed effects of dietary phosphate deprivation on PTH mediated cyclic AMP generation in a broken cell preparation do not occur in intact cell preparations.     

Effects of parathyroid hormone and calcitonin on adenylate cyclase in murine mononuclear phagocytes

Peritoneal mononuclear phagocytes elicited by thioglycollate demonstrate responsiveness to parathyroid hormone (PTH) and calcitonin (CT) which differs from that seen in the normal resident population. PTH causes a twofold stimulation of adenylate cyclase activity in elicited cells but inhibits this activity in resident cells. CT causes a greater stimulation of adenylate cyclase in elicited than in resident cells. Both CT and PTH cause an increase in cyclic AMP accumulation in cultures of elicited mononuclear phagocytes. These results indicate that cells of the mononuclear phagocyte lineage have functional receptors for both PTH and CT. This is the first biochemical evidence to support the hypothesis that mononuclear phagocytes are precursors of the bone resorbing osteoclast.     

Production of immunoreactive calcitonin and parathyroid hormone by embryonal carcinoma cells: alteration with retinoic acid-induced differentiation

To determine possible ectopic production of, and altered responsiveness to, specific hormones and growth factors which may be involved in mediating embryonic differentiation and development embryonal carcinoma cells in culture have been employed to serve as an in vitro system of embryogenesis. Exposure of F9 embryonal carcinoma cells to all-trans-retinoic acid previously has been shown to induce differentiation of these undifferentiated stem cells to parietal endoderm and to markedly alter the ability of calcitonin and parathyroid hormone to stimulate adenylate cyclase activity. Evidence is presented that F9 cells secrete immunoreactive calcitonin into the culture medium (200 pg/12 hr/10(7) cells) while parietal yolk sac (PYS) cells secrete immunoreactive parathyroid hormone (800 pg/12 hr/10(7) cells). Retinoic-induced differentiation of F9 cells to endoderm results in a progressive reduction in immunoreactive calcitonin production, while there is an increase in the level of immunoreactive parathyroid hormone found in the conditioned medium. After exposure of F9 cells to retinoic acid for 5 days, little calcitonin is detectable in 12-hr conditioned medium. Changes in the intracellular levels of immunoreactive calcitonin and PTH follow a pattern similar to that noted for changes in the amount of secreted hormones. Thus, immunoreactive calcitonin is produced by undifferentiated F9 cells which possess a calcitonin responsive adenylate cyclase system, while parathyroid hormone is produced by parietal endoderm cells which respond to parathyroid hormone with increased cyclic AMP synthesis. Sephadex G50 gel filtration of F9-conditioned medium shows two peaks of immunoreactive calcitonin with Mr of 3500 and 20,000. Immunoprecipitation of calcitonin from 35S-labeled F9 cells reveals a specific band of 20,000 Mr. Likewise, two peaks of parathyroid hormone immunoreactive material of Mr 8000 and 39,000 are noted after gel filtration of PYS cell-conditioned medium, whereas parathyroid hormone immunoprecipitation from the same cells reveals a specific band of 39,000 Mr. These results raise the possibility that embryo production of these two hormones at specific stages in development may contribute to the regulation of subsequent steps of differentiation.     

The effect of cyclic nucleotides on the incorporation of 3H-glucosamine into hyaluronate in bone organ culture.

Addition of dibutyryl cyclic AMP or parathyroid hormone to bone organ cultures markedly increased the incorporation of 3H-glucosamine into non-dialyzable macromolecules. Other cyclic nucleotides or their dibutyryl derivatives did not stimulate glucosamine incorporation. DEAE-cellulose chromatography of the papain-digested calvaria and culture medium resolved the labeled material into four peaks. A four-fold increase in radioactivity was observed in peak III. Previous studies of peak III have identified the labeled material as hyaluronic acid. The results suggest that the parathyroid hormone stimulated increase in glucosamine incorporation is mediated via the adenylate cyclase-cyclic AMP system, and that the increased amount of radioactivity is due to an increased amount of hyaluronic acid. Turnover studied of the labeled material suggest that the release of proteoglycans into the culture medium is not inhibited in the cultures treated with dibutyryl cyclic AMP. The role of hyaluronate in this experimental system remains to be elucidated.     

The effects of calcitonin, parathyroid hormone and prostaglandin E2 on cyclic AMP levels of isolated osteoclasts

Cyclic AMP (cAMP) levels were measured in both isolated and attached osteoclasts. The level of cAMP was 0.1 pmol/10(5) osteoclasts. No change in cAMP level of osteoclasts could be detected following calcitonin treatment. Parathyroid hormone (PTH) and prostaglandin E2 (PGE2) treatment stimulated cAMP production in proportion to alkaline phosphatase levels and divergent to acid phosphatase levels. This indicates that osteoblasts, not osteoclasts, were responsive to PTH and PGE2.     

The effect of prostaglandin I2 and 6a-Carba-PGI2 on the motility of isolated osteoclasts

We have recently found that calcitonin (CT), a hormone which inhibits osteoclastic bone resorption, completely abolishes the normally intense cytoplasmic movement of isolated osteoclasts. We have also found that prostaglandin (PG)I₂ causes an identical change in behaviour. In this paper we extend our investigations into the mode of action of PGI₂ and a stable analogue, 6a-Carba-PGI₂. We found that, unlike CT which causes prolonged immotility in osteoclasts, the effect of PGI₂ and 6a-Carba-PGI₂ were transient. Our results suggest that the transient nature of the inhibition was neither caused by inactivation of these compounds, nor was it due to production in the cultures of an osteoclastic stimulator. CT, PGI₂ and 6a-Carba-PGI₂ all appear to operate by increasing the intracellular cyclic AMP level. We found no refractoriness to either CT, dibutyryl cyclic AMP or 8-bromo cyclic AMP, and neither PGI₂ nor 6a-Carba-PGI₂ affected the sensitivity of osteoclasts to CT or dibutyryl cyclic AMP. This implies that refractoriness of osteoclasts to PGI₂ and 6a-Carba-PGI₂ develops at some stage in the interaction between PG and cell proximal to cyclic AMP production. We also found that there was cross-tachyphylaxis between PGI₂ and 6a-Carba-PGI₂, and this suggests that these two compounds share a receptor site on osteoclasts.