Glucocorticoids induce glutamine synthetase expression in human osteoblastic cells: a novel observation in bone.

Glucocorticoids have marked effects on bone metabolism, and continued exposure of skeletal tissue to excessive amounts of these steroids results in osteoporosis. Therefore, in the present proteomic study, we characterized the potential effects of glucocorticoids on protein expression in human osteoblastic cells. Using two-dimensional gel electrophoresis and mass spectrometry, we identified an increased expression of glutamine synthetase (GS) in dexamethasone (Dex)-treated human MG-63 osteosarcoma cells. GS is an enzyme catalyzing the conversion of glutamate and ammonia to glutamine. Intracellular and extracellular glutamate levels may be important in cell signalling mediated by glutamate transporters and receptors which have recently been found in bone cells. The induction of GS protein by Dex was accompanied by an increase in mRNA level and enzyme activity. Dex induction of GS was also mediated by glucocorticoid receptors (GRs) because it was blocked by the GR antagonist RU-38486. In addition, Dex induction of GS expression was partially blocked by cyclohexamide indicating that it at least partly required new protein synthesis. GS induction by Dex was not associated with apoptosis as determined by Bax/Bcl-2 ratio and DNA staining. In addition to MG-63 cells, Dex induction of GS was also observed in human G-292 osteosarcoma cells as well as conditionally immortalized human preosteoblastic (HOB-03-C5) and mature osteoblastic (HOB-03-CE6) cells. However, in two other human osteosarcoma cell lines, SaOS-2 and U2-OS, GS expression was not affected by Dex. This observation may be explained by the lower levels of GR protein in these cells. In summary, this is the first report of the regulation of GS expression by glucocorticoids in bone cells. The role of GS in bone cell metabolism and glucocorticoid action on the skeleton is not yet known, but as a modulator of intracellular glutamate and glutamine levels, it may have an important role in these processes.

Transcriptional profiling of human osteoblast differentiation.

Osteoblast differentiation is a key aspect of bone formation and remodeling. To further our understanding of the differentiation process, we have developed a collection of conditionally immortalized adult human osteoblast cell lines representing discrete stages of differentiation. To evaluate changes in gene expression associated with differentiation, polyA((+)) RNA from pre-osteoblasts, early and late osteoblasts, and pre-osteocytes was subjected to gene chip analysis using the Affymetrix Hu6800 chip in conjunction with an Affymetrix custom chip enriched in bone and cartilage cDNAs. Overall, the expression of 47 genes was found to change threefold or more on both chips between the pre-osteoblastic and pre-osteocytic stages of differentiation. Many of the observed differences, including down-regulation of collagen type I and collagen-processing enzymes, reflect expected patterns and support the relevance of our results. Other changes have not been reported and offer new insight into the osteoblast differentiation process. Thus, we observed regulation of factors controlling cell cycle and proliferation, reflecting decreased proliferation, and increased apoptosis in pre-osteocytic cells. Elements maintaining the cytoskeleton, extracellular matrix, and cell-cell adhesion also changed with differentiation reflecting profound alterations in cell architecture associated with the differentiation process. We also saw dramatic down-regulation of several components of complement and other immune response factors that may be involved in recruitment and differentiation of osteoclasts. The decrease in this group of genes may provide a mechanism for controlling bone remodeling of newly formed bone. Our screen also identified several signaling proteins that may control osteoblast differentiation. These include an orphan nuclear receptor DAX1 and a small ras-related GTPase associated with diabetes, both of which increased with increasing differentiation, as well as a high mobility group-box transcription factor, SOX4, that was down-regulated during differentiation. In summary, our study provides a comprehensive transcriptional profile of human osteoblast differentiation and identifies several genes of potential importance in controlling differentiation of osteoblasts.

Expression and regulation of Runx2/Cbfa1 and osteoblast phenotypic markers during the growth and differentiation of human osteoblasts.

The runt family transcription factor (AML-3/PEBP2alphaA1/Cbfa1/RUNX2) plays a crucial role in formation of the mineralized skeleton during embryogenesis and regulates maturation of the osteoblast phenotype. Because steroid hormones and growth factors significantly influence growth and differentiation properties of osteoblasts, we addressed Cbfa1 as a target gene for regulation by dexamethasone (Dex), 1,25(OH)D(3) (vitamin D(3)), 17beta-estradiol, and transforming growth factor-beta1 (TGF-beta1). The representation of functional protein levels by Western blot analyses and gel mobility shift assays was examined during the growth and mineralization of several conditionally immortalized human osteoblast cell lines HOB 04-T8, 03-CE6, and 03-CE10, each representing different stages of maturation. In situ immunofluorescence demonstrates Cbfa1 is associated with nuclear matrix in punctate domains, some of which are transcriptionally active, colocalizing with phosphorylated RNA polymerase II. Although each of the cell lines exhibited different responses to the steroid hormones and to TGF-beta1, all cell lines showed a similar increase in Cbfa1 protein and DNA binding activity induced only by Dex. On the other hand, Cbfa1 mRNA levels were not altered by Dex treatment. This regulation of Cbfa1 by steroid hormones in human osteoblasts contrasts to modifications in Cbfa1 expression in primary rat calvarial osteoblasts and the mouse MC3T3-E1 osteoblast cell line. Thus, these results reveal multiple levels of regulation of Cbfa1 expression and activity in osteoblasts. Moreover, the data suggest that in committed human osteoblasts, constitutive expression of Cbfa1 may be required to sustain the osteoblast phenotype.

Evidence that conditionally immortalized human osteoblasts express an osteocalcin receptor.

Osteocalcin (OC) is an abundant noncollagenous bone matrix protein, yet its function is largely unknown. However, targeted ablation of two OC genes in mice lead to increased bone formation (Ducy et al. Nature 382:448-452; 1996). This implied that OC inhibits osteoblast activity, and that these cells express an OC receptor. In order to characterize the putative OC receptor, we used the Cytosensor microphysiometer to measure responses of a proliferative-stage, conditionally immortalized human osteoblast cell line (HOB-03-C5) to purified bovine OC (bOC). The Cytosensor measures a change in the extracellular acidification rate, which is primarily a measurement of metabolic activity. Treatment of the HOB cells for 5-60 sec with 0.17 micromol/L bOC generated a time-dependent, transient increase in the acidification rate that became optimal after 25 sec. Likewise, treatment of the cells for 25 sec with 0.021 to 1.9 micromol/L bOC caused a dose-dependent 70% increase in the acidification rate. Pre-treatment of the cells for 2 h with inhibitors of adenylyl cyclase, phospholipase C, and intracellular calcium release inhibited the response of the cells to bOC by 50%-100%, which suggested that the putative OC receptor was coupled to a G-protein. These observations from the Cytosensor were confirmed by measuring intracellular cyclic-adenosine monophosphate (cAMP) concentrations in response to bOC. Treatment of the cells for 10 min with bOC decreased basal cAMP levels by 65% in a dose-dependent manner with an IC50 of 0.22 microM. However, cotreatment of the cells with forskolin, which activates adenylyl cyclase, blunted this suppression. Moreover, pretreatment of the cells with pertussis toxin for 48 h, which inhibits G(alpha)i proteins, reversed the suppressive effects of bOC on cAMP production. Treatment of the HOB cells for 48 h with 0.19 to 1.5 micromol/L bOC caused a dose-dependent 40% decrease in alkaline phosphatase activity with an IC50 of 0.21 micromol/L, which suggested that OC may inhibit HOB activity. Finally, although the maturation stage, conditionally immortalized HOB-02-C1 cells also responded to bOC as measured by the Cytosensor, two osteosarcoma cell lines, SaOS-2 and ROS 17/2.8, exhibited a 5- to 10-fold lower response to the bone matrix protein, suggesting that the putative OC receptor was downregulated in these cells. However, all of these bone cell lines responded to parathyroid hormone treatment. In conclusion, these results provide evidence that the HOB cells express an OC receptor, and that this receptor appears to be coupled to a G(alpha)-protein.

Suppression of ligand-dependent estrogen receptor activity by bone-resorbing cytokines in human osteoblasts.

Estrogens are important for bone homeostasis and are classified as antiresorptive agents. One of the mechanisms for this effect is the inhibition of cytokine-induced bone resorption, which is mediated in part through an interaction between the estrogen receptor (ER) and nuclear factor (NF)-kappaB in osteoblasts. We present evidence that bone-resorbing cytokines that activate NF-kappaB conversely inhibit ligand-dependent ER activity in the conditionally immortalized human osteoblast cell line, HOB-03-CE6. Treatment of HOB-03-CE6 cells with 17beta-estradiol (17beta-E2) up-regulated reporter gene activity [ERE-thymidine kinase (tk)-luciferase] 3- to 5-fold in a dose-dependent manner (EC50 = 1.0 pM). However, cotreatment of the cells with 17beta-E2 and increasing concentrations of either tumor necrosis factor-alpha (TNF alpha), interleukin-1alpha (IL-1alpha), or IL-1beta completely suppressed ERE-tk-luciferase activity in a dose-dependent manner (IC50 = 0.05-5.0 pM). On the other hand, treatment of the cells with growth factors either up-regulated or had no effect on ERE-tk-luciferase expression. Neither TNF alpha, IL-1alpha, nor IL-1beta treatment affected basal reporter gene activity in the cells, and the TNF alpha effect was reversed by a neutralizing antibody to the cytokine. TNF alpha treatment also suppressed ligand-dependent ER activity in MCF-7 human breast cancer cells, but not in Chinese hamster ovary cells that overexpressed human ER alpha, even though both cell lines responded to the cytokine as measured by the up-regulation of NFkappaB-tk-luciferase activity. TNF alpha treatment did not affect the steady state levels of either ER alpha or ER beta messenger RNA expression by the HOB-03-CE6 cells, nor did it reduce [125I]17beta-E2 binding. Moreover, TNF alpha treatment only weakly inhibited ligand-dependent glucocorticoid receptor activity in the HOB-03-CE6 cells. Bone-resorbing cytokines, which do not signal through the NF-kappaB pathway, did not suppress ERE-tk-luciferase activity in HOB-03-CE6 cells. Treatment of the cells with 17beta-E2 partially suppressed the activation of NF-kappaB by TNF alpha, but did not block cytokine-induced IL-6 secretion. Finally, cotreatment of HOB-03-CE6 cells with an antisense oligonucleotide to NF-kappaB p50 partially reversed the suppression of ERE-tk-luciferase activity by TNF alpha. In summary, these data provide evidence for a potent feedback inhibition of estrogen action in human osteoblasts that is at least partly mediated by the activation of NF-kappaB.

Estrogen receptor-alpha is developmentally regulated during osteoblast differentiation and contributes to selective responsiveness of gene expression.

Estrogen responsiveness of bone is a fundamental regulatory mechanism operative in skeletal homeostasis. We examined the expression of estrogen receptor-alpha (ER) messenger RNA (mRNA) in cultured rat calvarial-derived osteoblasts during progressive development of the osteoblast phenotype. Levels of ER message were compared with the expression of traditional osteoblastic markers that have been mapped throughout the differentiation process of these cells. ER transcripts, measured using semiquantitative RT-PCR analysis, were expressed at low levels in early stage proliferating osteoblasts and increased at confluence upon initial expression of bone cell phenotypic genes. A 23-fold up-regulation of ER mRNA expression coincided with the initiation of alkaline phosphatase activity (day 8). ER mRNA levels progressively increased 70-fold, reaching a maximum level on days 22-25 in fully differentiated osteoblasts when osteocalcin expression peaked, but declined precipitously by day 32 in osteocytic cells. Analysis of RNA isolated directly from rat calvaria confirmed these in vitro results and demonstrated that ER message levels become more abundant postnatally as bone becomes more mineralized. We also examined the responsiveness of osteoblasts to 17beta-estradiol (17beta-E2) at two periods of maturation: the nodule-forming stage (day 14) and the late mineralization stage (day 30). Estradiol suppressed the levels of alkaline phosphatase, osteocalcin, osteonectin, and ER mRNAs on day 14, but up-regulated these messages on day 30. In contrast, 17beta-E2 treatment regulated the steady state levels of transforming growth factor-beta1 and type I procollagen mRNAs only in the late mineralization stage, whereas histone H4 message was unaffected by the steroid at either stage of differentiation. Thus, the observed developmental expression of ER mRNA correlates with progressive osteoblast differentiation and may be a contributing factor to differential regulation of bone cell gene expression by 17beta-E2.

Functional properties of a conditionally phenotypic, estrogen-responsive, human osteoblast cell line.

Osteoblasts are established targets of estrogen action in bone. We screened 66 conditionally immortalized clonal human osteoblast cell lines for estrogen receptors (ERs) using reverse transcriptase-polymerase chain reaction (RT-PCR) analysis for ER alpha mRNA and transactivation of adenovirus-estrogen response element (ERE)-tk-luciferase by 17 beta-estradiol (17 beta-E2) for functional ER protein. One of these cell lines, termed HOB-03-CE6, was chosen for further characterization. The cells, which were conditionally immortalized with a temperature-sensitive SV40 large T antigen, proliferated at the permissive temperature (34 degrees C) but stopped dividing at the nonpermissive temperature (> or = 39 degrees C). Alkaline phosphatase activity and osteocalcin secretion were upregulated by 1 alpha, 25-dihydroxyvitamin D3 in a dose-dependent manner. The cells also expressed type I collagen and other bone matrix proteins, secreted a variety of growth factors and cytokines, formed mineralized nodules based on alizarin red-S and von Kossa histochemical staining, and responded to dexamethasone, all-trans retinoic acid, and transforming growth factor-beta 1. This cell line expressed 42-fold less ER message than MCF-7 human breast cancer cells, as determined by quantitative RT-PCR. However, adenovirus-ERE-tk-luciferase activity was upregulated three- to fivefold in these cells by 17 beta-E2 with an EC50 of 64 pM. Furthermore, this upregulation was suppressed by co-treatment with the anti-estrogen ICI-182, 780. Cytosolic extracts of these cells specifically bound [125I]-17 beta-E2 in a concentration-dependent manner with a Bmax of 2.7 fmoles/mg protein (approximately 1,200 ERs/cell) and a Kd of 0.2 nM. DNA gel-shift analysis using a [32P]-ERE demonstrated the presence of ERs in nuclear extracts of these cells. Moreover, binding of the extracts to this ERE was blocked by a monoclonal antibody to the human ER DNA-binding domain. We evaluated these cells for 14 of 20 reported endogenous responses to 17 beta-E2 in osteoblasts. Although most of these responses appeared to be unaffected by the steroid, 17 beta-E2 suppressed parathyroid hormone-induced cAMP production, as well as basal interleukin-6 mRNA expression; conversely, the steroid upregulated the steady-state expression of alkaline phosphatase message in these cells. In summary, we have identified a clonal, conditionally phenotypic, human osteoblast cell line that expresses functional ERs and exhibits endogenous responses to 17 beta-E2. This cell line will be a valuable in vitro model for exploring some of the molecular mechanisms of estrogen action in bone.

Establishment and hormonal regulation of a conditionally transformed preosteocytic cell line from adult human bone.

Osteocytes are differentiated forms of osteoblasts that arise upon entrapment within the bone matrix. In this report, we describe the establishment and hormonal regulation of the first conditionally transformed human preosteocytic cell line. Primary adult bone cells were obtained from protease cell line. Primary adult bone cells were obtained from protease digestion of cancellous chips. The cells were infected with adenovirus-ori- SV40 tsA 209, which encodes for a temperature-sensitive large T-antigen. After immortalization, we isolated a clone designated HOB-01-C1. This cell line expressed the mutant T-antigen and proliferated at the permissive temperature (34 C) but stopped dividing at the nonpermissive temperature (39-40 C). Electron microscopy of cells incubated at 39 C demonstrated the presence of preosteocytic cellular processes, some of which appeared to form gap junctions or were rich in microfilaments. The clone expressed alpha 1 type (I) procollagen messenger RNA (mRNA) and secreted type I procollagen C peptide at both temperatures, and this expression was elevated 1.6-fold to 1.8-fold at 40 degrees C. The cells expressed very low basal levels of alkaline phosphatase activity (approximately 0.02 nmol/min.mg), which was increased 2- to 5-fold in a dose-dependent manner by 0.1-100 nM 1 alpha,25-dihydroxyvitamin D3 (vitamin D3) at both temperatures. Vitamin D3 also increased osteocalcin secretion in a dose-dependent manner when the clone was maintained at 34 C (approximately 6-fold), and this stimulation was enhanced > 5 fold at 40 C. In contrast to the low expression of alkaline phosphatase, the cells secreted high amounts of osteocalcin in response to vitamin D3 (approximately 15 ng/mg cell protein); this biochemical profile also resembled that of preosteocytes. Alizarin red-S histochemical staining demonstrated that these cells rapidly produced mineralized nodules at both temperatures. PTH (10 and 100 nM) had no effect on the intracellular accumulation of cAMP at 34 C but stimulated a 14- to 18-fold increase in the production of this second messenger at 40 C. In contrast, 100 nM prostaglandin E2 and 1 microM forskolin stimulated cAMP synthesis better at 34 C. Western blot analysis indicated that the cells expressed CD44, a putative osteocytic marker, at both temperatures. Finally, interleukin-1 beta and tumor necrosis factor-alpha (1-1000 pM) stimulated dose-dependent increases in the secretion of interleukin-6 and monocyte chemoattractant protein-1 at 34 C and 40C. We conclude that the HOB-01-C1 cell line has a preosteocytic phenotype. Moreover, these cells respond to calcitropic hormones and bone resorbing cytokines.

Development and characterization of a conditionally transformed adult human osteoblastic cell line.

Many osteoblastic cell lines are currently in use, but these have limitations either in terms of their relevance to adult human biology and disease or in terms of their suitability for biochemical and molecular analyses. Consequently, we undertook the development of conditionally transformed adult human osteoblastic cell lines. Osteoblasts were obtained from a normal explant cancellous bone chip culture. These cells were infected with adenovirus-ori-SV40 tsA 209, which encodes a temperature-sensitive large T-antigen mutant. Cells immortalized with this virus express a transformed phenotype at the permissive temperature of 34 degrees C but revert to a normal phenotype at the nonpermissive temperature of 40 degrees C. Using this approach, we have isolated several cell clones and describe the characterization of one that was designated HOB-02-C1. Immunocytochemistry revealed that > 95% of the cells express the large T-antigen at both temperatures. These cells exponentially proliferate at 34 degrees C with a doubling time of approximately 2 days but irreversibly stop dividing at 40 degrees C. However, cell volume increases > 2-fold when the cells are maintained for 6 days at the higher temperature. This clone expresses alpha 1 type (I) procollagen mRNA and secretes type I procollagen C-peptide at both temperatures, although the levels were slightly elevated at 40 degrees C. The cell line expresses alkaline phosphatase activity at 34 degrees C, and the basal level of this enzyme increases 2- to 6-fold at 40 degrees C. Alkaline phosphatase activity is induced 4- to 8-fold by 1 alpha,25-dihydroxyvitamin D3 (vitamin D3) at both temperatures, but transforming growth factor-beta 1 (TGF-beta 1) suppresses enzyme expression > 90% at 40 degrees C. Vitamin D3 also induces a 10-fold increase in osteocalcin secretion when the clone is maintained at 34 degrees C, and this induction is enhanced > 8-fold at 40 degrees C. Parathyroid hormone and forskolin stimulate a 4- to 6-fold increase in the production of intracellular cyclic AMP (cAMP) by the cells at 34 degrees C, and this stimulation is enhanced 2- to 4-fold at 40 degrees C. In contrast, prostaglandin E2 stimulates a 7- to 8-fold increase in cAMP only when the cells are maintained at 34 degrees C. This cell line secretes TGF-beta 1 and interleukin-6 (IL-6) at 34 degrees C, but only the basal secretion of IL-6 increases 70% at 40 degrees C. Finally, alizarin red-S histochemical staining demonstrates that these cells produce mineralized nodules at both temperatures. In summary, the results of this study indicate that the HOB-02-C1 cells have a mature osteoblastic phenotype. Consequently, this new cell line and others obtained in a similar fashion should be valuable in vitro tools for cellular, biochemical, and molecular studies of adult human osteoblast biology.

Modulator inhibits nuclear translocation of the glucocorticoid receptor and inhibits glucocorticoid-induced apoptosis in the human leukemic cell line CEM C-7.

Modulator is an endogenous low-molecular-weight regulator of both glucocorticoid and mineralocorticoid receptors as well as protein kinase C. Structural analysis of modulator purified to apparent homogeneity suggests that it is a novel ether aminophosphoglyceride. In this report, we show that modulator inhibits cytosolic human glucocorticoid receptor (GR) complex activation as measured by DNA-cellulose binding. In addition, modulator blocks glucocorticoid-induced nuclear translocation of the GR in intact human leukemic (CEM C-7) cells, as illustrated by immunocytochemical localization. Furthermore, we demonstrate that modulator, by blocking the activation and subsequent translocation of GR, inhibits glucocorticoid-mediated apoptosis, characterized by chromatin condensation, internucleosomal DNA fragmentation, and cell death in glucocorticoid-sensitive CEM C-7 cells. Modulator inhibits glucocorticoid-induced c-myc gene repression and glucocorticoid receptor gene up-regulation. These data suggest that modulator functions to regulate the GR in intact cells as well as in cytosolic preparations. In addition, the inhibition of glucocorticoid-induced programmed cell death by modulator sheds light on the cellular function of modulator as well as on the mechanism by which apoptosis occurs in CEM C-7 cells.

Regulation of c-fos expression and TGF-beta production by gonadal and adrenal androgens in normal human osteoblastic cells.

Although the role of estrogens in bone formation is becoming clarified, the function of androgens in this process remains to be defined. Consequently, we have explored the mechanism of action for both gonadal and adrenal androgens in normal human osteoblastic (hOB) cells, which are responsible for the synthesis and mineralization of bone. Changes in the steady-state mRNA levels for two nuclear proto-oncogenes (c-fos and c-jun) and one cytokine (TGF-beta 1) were quantified in response to short (30 min) and long (24-48 h) treatments of these cells with physiologic concentrations of steroids. In addition, the levels of TGF-beta protein in the hOB cells conditioned-media were measured using a bioassay. The results indicated that neither 10 nM dihydrotestosterone, 10-20 nM testosterone, nor 10-100 nM androstenedione had a significant effect on the steady-state levels of c-fos, c-jun, or TGF-beta 1 mRNAs. Interestingly, 10-1000 nM dehydroepiandrosterone (DHEA) and 1-10 microM DHEA-sulfate rapidly reduced the steady-state level of c-fos mRNA by 60-80% in a dose-dependent manner within 30 min. In contrast, neither of these adrenal steroids had a significant effect on the message levels for c-jun or TGF-beta 1. Surprisingly, although TGF-beta 1 mRNA levels remained unchanged, the total amount of TGF-beta activity in the hOB cell conditioned-media increased 2-5-fold in response to 24-48 h treatments of the cells with gonadal or adrenal androgens. This increase in TGF-beta activity by DHEA-sulfate was both time- and dose-dependent, and was not blocked by cotreatment with the specific aromatase inhibitor 4-hydroxyandrostenedione (1 microM). Immunoprecipitations of the hOB cell conditioned-media with isoform-specific TGF-beta neutralizing-antibodies indicated that TGF-beta 2 was predominantly produced by the cells in response to DHEA-sulfate treatment. These results demonstrate that differences exist between the actions of estrogens and androgens on normal human osteoblasts with regard to the regulation of c-fos expression and TGF-beta production. Moreover, these data suggest that DHEA and DHEA-sulfate may play a distinct role in the regulation of human osteoblast function via the rapid repression of c-fos message levels and the slower increase in TGF-beta 2 protein levels.

Synthetic peptides derived from the steroid binding domain block modulator and molybdate action toward the rat glucocorticoid receptor.

Modulators are endogenous low-mol-wt inhibitors of glucocorticoid receptor activation, and are mimicked by exogenous sodium molybdate. Activation involves the dissociation of the 90-kDa heat-shock protein from the receptor. The heat-shock protein is thought to bind to a conserved 20-amino-acid region in the steroid-binding domain of the receptor (595-614 of the rat protein). Synthetic peptides corresponding to this amino acid sequence prevented the modulators and sodium molybdate from inhibiting receptor activation. These results imply that the region 595-614 of the rat glucocorticoid receptor is also a modulator/molybdate binding site.

Purification of the glucocorticoid receptor-mineralocorticoid receptor modulator-2 from rabbit liver.

Modulators-1 and -2 are endogenous low-mol-wt regulators of glucocorticoid and mineralocorticoid receptors and protein kinase C. Structural analysis of apparently purified modulators suggested that these molecules were novel ether aminophosphoglycerides. Subsequent X-ray crystallography and NMR spectroscopy indicated that the ultra-large scale modulator preparations were contaminated with glutamate and aspartate, although these amino acids lacked modulator activity. In this article, we describe the purification of modulator-2 from rabbit liver cytosol and the separation of this phosphoglyceride from these amino acids. This purification was similar to the ultra-large scale version (Bodine, P.V. and Litwack, G. [1990] J. Biol. Chem. 265, 9544-9554), but involved the chromatography of trypsinized rabbit liver cytosol on the 7-L bed volume Sephadex G-15 gel-filtration column. As before, two peaks of modulator activity (modulator-1 and -2), as well as a DNA-binding inhibitor (peak-3), eluted from the gel-filtration column. The resulting modulator-2 pool was incubated with glutamate decarboxylase and treated batch-wise with Dowex-50W cation-exchange resin and Chelex-100 resin. This enzyme/resin-treated modulator-2 preparation was then chromatographed on a Dowex-1 anion-exchange column. Finally, modulator-2 was purified by preparative silica TLC. This last purification step resulted in the separation of modulator-2 from glutamate, aspartate, and gamma-aminobutyrate. In summary, rabbit liver cytosol appears to be a reasonable source of modulator-2. In addition, treatment of the preparation with glutamate decarboxylase seems to facilitate the subsequent separation of modulator-2 from the contaminating amino acids.

A new synthetic ether aminophosphoglyceride exhibits partial modulator activity towards the glucocorticoid receptor.

Modulator is an endogenous low-molecular weight regulator of both glucocorticoid and mineralocorticoid receptors, as well as protein kinase C. Analogs of the putative modulator structure have been synthesized. These compounds include 1-O-(3'-carboxypropyl) or (5'-carboxypentyl)-L-glycero-3-phospho-L-serine or L-threonine, and the D-glycerol stereoisomers. These compounds were tested for in vitro modulator activity using the glucocorticoid-receptor complex activation inhibition and steroid-binding stabilization assays. One of the ether phosphoglycerides, 1-O-(5'-carboxypentyl)-L-glycero-3-phospho-L-threonine (H-GPT-1), partially inhibited steroid-receptor complex activation in a dose-dependent manner. However, none of the other compounds exhibited any modulator activity towards the glucocorticoid-receptor complex. Like modulator, H-GPT-1 did not inhibit activated glucocorticoid-receptor complex binding to DNA-cellulose. Surprisingly, in contrast to modulator, H-GPT-1 partially inhibited unoccupied receptor steroid-binding in a dose-dependent manner. These results suggest that although modulator is not exactly mimicked by this compound, H-GPT-1 is the first synthetic organic molecule to exhibit some modulator activity towards the glucocorticoid receptor.

Modulators of the glucocorticoid receptor also regulate mineralocorticoid receptor function.

Modulators are proposed to be novel ether aminophosphoglycerides that stabilize unoccupied and occupied glucocorticoid receptor steroid binding and inhibit glucocorticoid receptor complex activation. Two isoforms, modulator 1 and modulator 2, have been purified from rat liver cytosol [Bodine, P.V., & Litwack, G. (1990) J. Biol. Chem. 265, 9544-9554]. Since the mineralocorticoid receptor is relatively resistant to activation, modulator's effect on rat distal colon mineralocorticoid receptor function was examined. Warming of unoccupied receptor decreased residual specific [3H]aldosterone binding by 86 +/- 2%. Both modulator isoforms completely prevented this destabilization with Km's of 2 +/- 1 microM modulator 1 and 24 +/- 5 microM modulator 2. Warming of occupied mineralocorticoid receptors decreased [3H]aldosterone binding by 56 +/- 3%. Modulator only partially stabilized occupied receptor binding with Km's of 10 +/- 2 microM modulator 1 and 68 +/- 8 microM modulator 2. Modulator inhibited receptor activation with Km's of 3 +/- 1 microM modulator 1 and 33 +/- 10 microM modulator 2. Double-reciprocal analysis showed linear kinetics, and mixing modulator isoforms together had additive effects on unoccupied and occupied receptor steroid binding stabilization and activation inhibition. Colon cytosol contained a low molecular weight, heat-stable factor(s) which inhibited receptor activation and stabilized occupied receptor steroid binding. Molybdate completely stabilized unoccupied mineralocorticoid receptor steroid binding and inhibited activation with half-maximal effects at 3-4 mM but only stabilized occupied receptor binding by approximately 40%. These data indicate that (i) apparent physiologic concentrations of modulator stabilize mineralocorticoid receptor steroid binding and inhibit receptor activation, (ii) an aldosterone-responsive tissue contains a modulator-like activity, and (iii) molybdate mimics the effects of modulator.(ABSTRACT TRUNCATED AT 250 WORDS)

Endogenous modulators of glucocorticoid receptor function also regulate purified protein kinase C.

Modulator-1 and -2, proposed to be novel ether-linked aminophosphoglycerides, were originally identified as regulators of glucocorticoid receptor function (Bodine, P. V., and Litwack, G. (1990) J. Biol. Chem. 265, 9544-9554). We now demonstrate that these modulators are also potent new stimulators of protein kinase C activity in vitro. These endogenous biomolecules regulate purified protein kinase C activity in a biphasic and dose-dependent pattern, as determined by histone phosphorylation. Modulators, at concentrations within their apparent cellular range, stimulate protein kinase C-catalyzed histone phosphorylation 2-4-fold when added separately, or 10-12-fold when added together. This enhancement of kinase activity apparently is specific for protein kinase C, since neither protein kinase M, nor cAMP-dependent protein kinase A are stimulated by the modulators. The stimulation of purified protein kinase C occurs only when the enzyme has been initially activated by calcium, phosphatidylserine, and diacylglycerol, indicating that the modulators do not simply substitute for one of the enzyme cofactors. In addition, the modulators appear to interact directly with protein kinase C, perhaps with the regulatory domain of the enzyme, since these biomolecules inhibit the binding of phorbol ester to purified protein kinase C. Finally, time-course studies of protein kinase C-catalyzed histone phosphorylation indicate that the velocity of the enzyme reaction is increased by the modulators. Taken together, these results suggest that the modulators are a new class of regulators of protein kinase C.

Evaluation of synthetic novel ether aminophosphoglycerides for glucocorticoid-receptor complex modulator activity.

Modulator is an endogenous low-mol wt regulator of the glucocorticoid-receptor complex. Structural analysis of purified modulator suggested that it was a novel ether aminophosphoglyceride (Bodine and Litwack 1988b). Analogs of the putative modulator structure have now been synthesized. The synthetic compounds are 1-O-(6-carboxylhexyl)-glycero-3-phosphoserine and the sn-2-methoxy and sn-1-ethylester derivatives. Like modulator, these novel synthetic compounds are water soluble. However, thin-layer chromatography and spectroscopic analysis of these phosphoglycerides indicated significant structural differences between modulator and the synthetic analogs. In particular, the chromatographic behavior of the compounds suggests that modulator is more highly charged than the synthetic derivatives. The synthetic compounds, as well as lysophosphatidylserine, were also tested for in vitro modulator activity using the glucocorticoid-receptor complex activation inhibition and steroid-binding stabilization assays. None of the analogs exhibited modulator activity in these assays. However, the synthetic compounds were generally less detrimental to receptor steroid-binding than lysophosphatidylserine. From this work, we conclude that although modulator is not mimicked by one of these synthetic phosphoglycerides, a starting point for future structure-function studies has nonetheless been established.