Identification and characterization of A-105972, an antineoplastic agent.

A high-throughput screening assay was designed to select compounds that inhibit the growth of cultured mammalian cells. After screening more than 60,000 compounds, A-105972 was identified and selected for further testing. A-105972 is a small molecule that inhibits the growth of breast, central nervous system, colon, liver, lung, and prostate cancer cell lines, including multidrug-resistant cells. The cytotoxic IC50 values of A-105972 were between 20 and 200 nM, depending on the specific cell type. The potency of A-105972 is similar in cells expressing wild-type or mutant p53. A majority of cells treated with A-105972 were trapped in the G2-M phases, suggesting that A-105972 inhibits the progression of the cell cycle. Using [3H]A-105972, we found that A-105972 bound to purified tubulin. Unlabeled A-105972 competed with [3H]A-105972 binding with an IC50 value of 3.6 microL. Colchicine partially inhibited [3H]A-105972 binding with an IC50 value of approximately 90 microM, whereas paclitaxel and vinblastine had no significant effect. Tumor cells treated with A-105972 were observed to contain abnormal microtubule arrangement and apoptotic bodies. DNA ladder studies also indicated that A-105972 induced apoptosis. A-105972 caused a mobility shift of bcl-2 on SDS-PAGE, suggesting that A-105972 induced bcl-2 phosphorylation. A-105972 treatment increased the life span of mice inoculated with B16 melanoma, P388 leukemia, and Adriamycin-resistant P388. These results suggest that A-105972 is a small molecule that interacts with microtubules, arrests cells in G2-M phases, and induces apoptosis in both multidrug resistance-negative and multidrug resistance-positive cancer cells. A-105972 and its analogues may be useful for treating cell proliferative disorders such as cancer.

SV40 virus transformation down-regulates endothelin receptor.

Simian virus 40 (SV40) is an oncogenic DNA virus that induces malignant transformation. Endothelin (ET), a 21 amino acid peptide with mitogenic and anti-apoptotic effects, binds to G-protein coupled ETA and ETB receptors. This report examines the effect of SV40 transformation on the expression of ET receptors. Results from receptor binding and reverse transcription (RT)-polymerase chain reaction (PCR) studies show that human lung fibroblasts IMR90 and WI38 express both ETA and ETB receptors, and that the expression of both receptors is significantly down-regulated in IMR90-SV40 and WI38-SV40, cell lines derived from IMR90 and WI38 with SV40 virus transformation. Receptor binding and RT-PCR analysis of 3A(tPA-30-1), a cell line derived from human placenta that expresses a higher level of SV40 large T-antigen at the permissive temperature (33 degrees C) than at the restrictive temperature (40 degrees C), further demonstrates that there is an inverse correlation between the expression of SV40 T-antigen and the expression of ET receptor. ET-1 and fetal bovine serum stimulate DNA synthesis in non-transformed cells; however, proliferation of transformed cells is independent of either fetal bovine serum or ET-1. We conclude that SV40 transformation down-regulates the expression of ET receptors, and that expression of ET receptors is inversely correlated with expression of SV40 large T-antigen.

Endothelin receptor agonists and antagonists exhibit different dissociation characteristics.

Endothelins (ETs) are vasoconstricting peptides that bind to membrane receptors to initiate their physiological effects. This report compares the dissociation characteristics of selected ET agonists and antagonists, and studies the effects of any difference in dissociation characteristics on the potency of antagonists. Competition studies using various ET receptor ligands against [125I]ET-1 or [125I]ET-3 binding demonstrated that porcine cerebellum membranes contain predominantly ETB receptor. [125I]IRL1620 associated with the receptors in a time-dependent manner. Although bound [125I]IRL1620 was easier to dissociate than bound [125I]ET-3, both agonists exhibited a dissociation half life > 20 h. For non-radiolabeled ligands, bind-and-wash studies were employed in which membranes were pre-incubated with unlabeled ligand followed by extensive washing before assaying for [125I]ET-1 binding. Results from bind-and-wash studies confirmed that bound non-radiolabeled IRL1620 and ET were as difficult to dissociate as [125I]ligands. In contrast, bound PD142893 and Ro46-2005 were easily dissociated from ETB receptors. Consequently, the inhibitory effects of PD142893 and Ro46-2005 on [125I]agonist binding diminished following incubation time. In cloned human ETA and ETB receptors, bound ET-1 was also more difficult to dissociate than bound antagonists. These results suggest that the differences in the dissociation characteristics of ET receptor agonists vs. antagonists may account for the diminished potency of Ro46-2005 and PD142893 as a function of incubation time.

Design, synthesis, and activity of a series of pyrrolidine-3-carboxylic acid-based, highly specific, orally active ET(B) antagonists containing a diphenylmethylamine acetamide side chain.

The endothelin (ET)-B receptor subtype is expressed on vascular endothelial and smooth muscle cells and mediates both vasodilation and vasoconstriction. On the basis of the pharmacophore of the previously reported ET(A)-specific antagonist 1, (ABT-627), we are reporting the discovery of a novel series of highly specific, orally active ET(B) receptor antagonists. Replacing the dibutylaminoacetamide group of 1 with a diphenylmethylaminoacetamide group resulted in antagonist 2 with a complete reversal of receptor specificity. Structure-activity relationship studies revealed that ortho-alkylation of the phenyl rings could further increase ET(B) affinity and also boost the ET(A)/ET(B) activity ratio of the resulting antagonists. A similar antagonism selectivity profile could also be achieved when one of the phenyl rings of the acetamide side chain was replaced with an alkyl group, preferably a tert-butyl group (10h). Combining these features with modification of the 2-aryl group of the pyrrolidine core, we have identified a potent antagonist (9k, A-308165) with over 27 000-fold selectivity favoring the ET(B) receptor and an acceptable pharmacokinetic profile (F = 24%) in rats.

Pyrrolidine-3-carboxylic acids as endothelin antagonists. 5. Highly selective, potent, and orally active ET(A) antagonists.

The synthesis and structure-activity relationships (SAR) of a series of pyrrolidine-3-carboxylic acids as endothelin antagonists are described. The data shows an increase in selectivity when the methoxy of Atrasentan (ABT-627) is replaced with methyl, and the benzodioxole is replaced with dihydrobenzofuran. Adding a fluorine further increases the binding activity and provides a metabolically stable and orally bioavailable ET(A)-selective antagonist.

Pyrrolidine-3-carboxylic acids as endothelin antagonists. 4. Side chain conformational restriction leads to ET(B) selectivity.

When the dialkylacetamide side chain of the ET(A)-selective antagonist ABT-627 is replaced with a 2,6-dialkylacetanilide, the resultant analogues show a complete reversal of receptor selectivity, preferring ET(B) over ET(A). By optimizing the aniline substitution pattern, as well as the alkoxy group on the 2-aryl substituent, it is possible to prepare antagonists with subnanomolar affinity for ET(B) and with selectivities in excess of 4000-fold. A number of these compounds also show promising pharmacokinetic profiles; a useful balance of properties is found in A-192621 (38). Pharmacology studies with A-192621 serve to reveal the role of the ET(B) receptor in modulating blood pressure; the observed hypertensive response to persistent ET(B) blockade is consistent with previous postulates and indicates that ET(B)-selective antagonists may not be suitable as agents for long-term systemic therapy.

Potent and selective non-benzodioxole-containing endothelin-A receptor antagonists.

The benzodioxole ((methylenedioxy)benzene) group is present in a number of endothelin (ET) receptor antagonists thus far reported. As part of our own endothelin antagonist program we have developed (2R*,3R*,4S*)-1-(N,N-dibutylacetamido)-4-(1,3-benzodioxol-5- yl)-2-(4-methoxyphenyl)pyrrolidine-3-carboxylic acid (A-127722). This is a potent antagonist, binding to the ETA and ETB receptor subtypes with affinities (IC50) of 0.4 and 520 nM, respectively, and also contains the aforementioned benzodioxole. While this compound was seemingly optimized at its N-terminus, no effort had been directed toward understanding the contributions to binding affinity or receptor subtype selectivity conferred by the benzodioxole. Substitution by 1- or 2-naphthyl yielded weak antagonists. Oxygenated benzenes, such as p-anisyl, were potent compounds with IC50s in the low-nanomolar range. Simple deletion of either of the two oxygen atoms (dihydrobenzofurans) yielded extremely potent agents, possessing subnanomolar affinity for the ETA receptor. Additionally, the compounds showed enhanced selectivity, binding to the ETB receptor subtype in the micromolar range. This paper describes the development of this novel class of compounds.

Pyrrolidine-3-carboxylic acids as endothelin antagonists. 3. Discovery of a potent, 2-nonaryl, highly selective ETA antagonist (A-216546).

Previously we have reported the discovery of ABT-627 (1, A-147627, active enantiomer of A-127722), a 2,4-diaryl substituted pyrrolidine-3-carboxylic acid based endothelin receptor-A antagonist. This compound binds to the ETA receptor with an affinity (Ki) of 0. 034 nM and with a 2000-fold selectivity for the ETA receptor versus the ETB receptor. We have expanded our structure-activity studies in this series, in an attempt to further increase the ETA selectivity. When the p-anisyl group of 1 was replaced by an n-pentyl group, the resultant antagonist 3 exhibited substantially increased ETB/ETA activity ratio, but a decreased ETA affinity. Structure-activity studies revealed that substitution and geometry of this alkyl group, and substitution on the benzodioxolyl ring, are important in optimizing this series of highly ETA selective antagonists. In particular, the combination of a (E)-2,2-dimethyl-3-pentenyl group and a 7-methoxy-1,3-benzodioxol-5-yl group provided hydrophobic compound 10b with subnanomolar affinity for human ETA receptor subtype and with an ETB/ETA activity ratio of over 130000. Meanwhile, synthetic efforts en route to olefinic compounds led to the discovery that 2-pyridylethyl (9o) and 2-(2-oxopyrrolidinyl)ethyl (9u) replacement of the p-anisyl group of 1yielded very hydrophilic ETA antagonists with potency and selectivity equal to those of 10b. On the basis of overall superior affinity, high selectivity for the ETA receptor (Ki, 0.46 nM for ETA and 13000 nM for ETB), and good oral bioavailability (48% in rats), A-216546 (10a) was selected as a potential clinical backup for 1.

New antimitotic agents with activity in multi-drug-resistant cell lines and in vivo efficacy in murine tumor models.

During a screen for compounds that could inhibit cell proliferation, a series of new tubulin-binding compounds was identified with the discovery of oxadiazoline 1 (A-105972). This compound showed good cytotoxic activity against non-multi-drug-resistant and multi-drug-resistant cancer cell lines, but its utility in vivo was limited by a short half-life. Medicinal chemistry efforts led to the discovery of indolyloxazoline 22g (A-259745), which maintained all of the in vitro activity seen with oxadiazoline 1, but also demonstrated a better pharmacokinetic profile, and dose-dependent in vivo activity. Over a 28 day study, indolyloxazoline 22g increased the life span of tumor-implanted mice by up to a factor of 3 upon oral dosing. This compound, and others of its structural class, may prove to be useful in the development of new chemotherapeutic agents to treat human cancers.

2,4-Diarylpyrrolidine-3-carboxylic acids--potent ETA selective endothelin receptor antagonists. 1. Discovery of A-127722.

We have discovered a novel class of endothelin (ET) receptor antagonists through pharmacophore analysis of the existing non-peptide ET antagonists. On the basis of this analysis, we determined that a pyrrolidine ring might replace the indian ring in SB 209670. The resultant compounds were readily prepared and amenable to extensive SAR studies. Thus a series of N-substituted trans,trans-2-(4-methoxyphenyl)-4-(1,3-benzodioxol-5-yl)pyrroli din e-3- carboxylic acids (8) have been synthesized and evaluated for binding at ET(A) and ET(B) receptors. Compounds with N-acyl and simple N-alkyl substituents had weak activity. Compounds with N-alkyl substituents containing ethers, sulfoxides, or sulfones showed increased activity. Much improved activity resulted from compounds where the N-substituents were acetamides. Compound 17u (A-127722) with the N,N-dibutylacetamide substituent is the best of the series. It has an IC(50)=0.36 nM for inhibition of ET-1 radioligand binding at the ET(A) receptor, with a 1000-fold selectivity for the ET(A) vs the ET(B) receptor. It is also a potent inhibitor (IC(50)=0.16 nM) of phosphoinositol hydrolysis stimulated by ET-1, and it antagonized the ET-1-induced contraction of the rabbit aorta with a pA(2)=9.20. The compound has 70% oral bioavailability in rats.

Dissociation characteristics of endothelin receptor agonists and antagonists in cloned human type-B endothelin receptor.

The human type-B endothelin receptor (h-ETB) was cloned from human lung poly A+RNA and stably expressed in CHO cells. Endothelin (ET) receptor binding and stimulation of PI hydrolysis demonstrated that the cloned h-ETB receptor is functional and linked to intracellular signal transduction pathways in CHO cells. The molecular mass of the h-ETB receptor was determined to be 65 KDa, and Bmax and Kd were 0.36 pmol/mg and 80 pM, respectively. Competition studies employing receptor ligands revealed that the potencies of the test ligands (IRL1620, PD142893, and Ro46-2005) were dependent on the length of the incubation time, whereas the natural agonists (ET-1 and ET-3) were not. When competing with ET-1 in the h-ETB receptor binding, the IC50 increased from 1.2 nM to 8.2 nM for IRL1620, 0.068 microM to 1.9 microM for PD142893, and 0.76 microM to 12.7 microM for Ro46-2005, as the incubation time increased from 1 hr to 24 hr. These time-induced changes are likely due to differences in the dissociation characteristics between the artificial ligands and the natural ligands.

Pharmacology of A-216546: a highly selective antagonist for endothelin ET(A) receptor.

Endothelins, 21-amino acid peptides involved in the pathogenesis of various diseases, bind to endothelin ET(A) and ET(B) receptors to initiate their effects. Here, we characterize the pharmacology of A-216546 ([2S-(2,2-dimethylpentyl)-4S-(7-methoxy-1,3-benzodioxol-5-yl )-1-(N,N-di(n-butyl) aminocarbonylmethyl)-pyrrolidine-3R-carboxylic acid), a potent antagonist with > 25,000-fold selectivity for the endothelin ET(A) receptor. A-216546 inhibited [125I]endothelin-1 binding to cloned human endothelin ET(A) and ET(B) receptors competitively with Ki of 0.46 and 13,000 nM, and blocked endothelin-1-induced arachidonic acid release and phosphatidylinositol hydrolysis with IC50 of 0.59 and 3 nM, respectively. In isolated vessels, A-216546 inhibited endothelin ET(A) receptor-mediated endothelin-1-induced vasoconstriction, and endothelin ET(B) receptor-mediated sarafotoxin 6c-induced vasoconstriction with pA2 of 8.29 and 4.57, respectively. A-216546 was orally available in rat, dog and monkey. In vivo, A-216546 dose-dependently blocked endothelin-1-induced pressor response in conscious rats. Maximal inhibition remained constant for at least 8 h after dosing. In conclusion, A-216546 is a potent, highly endothelin ET(A) receptor-selective and orally available antagonist, and will be useful for treating endothelin-1-mediated diseases.

Oxidant-induced activation of protein kinase C in UC11MG cells.

Free radical formation and subsequent lipid peroxidation may participate in the pathogenesis of tissue injury, including the brain injury induced by hypoxia or trauma and cardiac injury arising from ischemia and reperfusion. However, the exact cellular mechanisms by which the initial oxidative insult leads to the ultimate tissue damage are not known. A number of reports have indicated that protein kinase C (PKC) may be activated following oxidative stress and that this enzyme may play an important role in the steps leading to cellular damage. In this work, we have examined in a cell model whether PKC is activated following oxidative exposure. UC11MG cells, a human astrocytoma cell line, were treated with H2O2. Incubation with 0.5 mM H2O2 increased malondialdehyde levels by as early as 15 minutes. To assess the effects of H2O2 treatment on PKC activation, we measured phosphorylation of an endogenous PKC substrate, the MARCKS (myristoylated alanine-rich C kinase substrate) protein. Treatment of cells with 0.2-1.0 mM H2O2 resulted in a rapid increase in MARCKS phosphorylation. Phosphorylation was stimulated approximately 2.5-fold following treatment with 0.5 mM H2O2 for ten minutes. Treatment with phorbol 12-myristate 13-acetate, a PKC activator, increased MARCKS phosphorylation approximately 4-fold. The H2O2-induced MARCKS phosphorylation was inhibited by the addition of the kinase inhibitors H-7 and staurosporine. Furthermore, specific down-regulation of PKC by phorbol ester also inhibited H2O2-induced MARCKS phosphorylation. These results indicate that PKC is rapidly activated in cells following an oxidative exposure and that this cell system may be a good model to further investigate the role of PKC in regulating oxidative damage in the cell.

Endothelin receptor antagonists exhibit diminishing potency following incubation with agonist.

Endothelins (ET) are 21-amino acid peptides that bind to membrane receptors to initiate a wide range of pathophysiological effects. ET binding to receptors has been shown to be almost irreversible because bound ET is difficult to dissociate. This report studies the dissociation characteristics of receptor antagonists and further examines the effects of ET's difficult-to-dissociate binding on the potency of antagonists. In membranes prepared from porcine cerebellum, [125I]ET-1 binding was effectively blocked by ET-1 and ET-3 with similar IC50 values (0.08 nM vs. 0.17 nM), suggesting that porcine cerebellum contains predominantly the ETB receptor subtype. [125I]ET-3 binding was inhibited by Ro46-2005 and PD142893, two non-selective antagonists, with IC50 values of 570 +/- 50 nM and 410 +/- 100 nM, respectively. Consistent with previous observations, bound [125I]ET-1 in porcine cerebellum membranes was also difficult to dissociate. In contrast, bound Ro46-2005 or PD142893, but not bound ET-1, could be readily washed away from membranes, suggesting that antagonist binding was more reversible than ET-1 binding. Although Ro46-2005 or PD142893 at 0.5 microM inhibited 0.1 nM [125I]ET-1 binding by > 80% after 15 min of incubation, the inhibitory effect decreased to approximately 50% after 3 h of incubation, and further decreased to < 10% at 24 h. This decrease in antagonizing potency was further confirmed by the results that the IC50 values of the two antagonists against [125I]ET-3 binding increased with increasing incubation time. Control experiments indicate that the observed decrease in the potency of Ro46-2005 and PD142893 was not the result of ligand degradation. These results suggest that the potency of antagonists is critically dependent on the incubation time because antagonist binding is more reversible than ET binding.

Characterization of two endothelin converting enzymes and their preference for big endothelin-1 and -2 as substrates.

Two proteolytic activities that convert big ET to ET at neutral pH were identified in solubilized membranes prepared from rat lung. The endothelin-converting activities were partially purified by using A80227 ((2S,3R,4S)-2-([N-acetylcyclohexylalanyl-isoleucyl]amino)-1-(2-nap hthyl)-3,4-dihydroxy-6-methylheptane) coupled to an affinity-gel column (Affigel), and subsequently by concanavalin-A immobilized gel chromatography. An endothelin-converting activity was identified in the fraction containing proteins that did not bind to A80227-Affigel. This protease was sensitive to phosphoramidon, soybean trypsin inhibitor, and chymostatin, and preferred big ET-1 or big ET-2 as its substrate over bit ET-3. A second endothelin-converting activity was identified in the fraction containing proteins that bound to the A80227-coupled gel and was eluted by raising the pH. This protease exhibited activities throughout a range of pH 5.5-9.5, was inhibited by pepstatin A and A80227, and also preferred big ET-1 or big ET-2 over big ET-3 as its substrate. Both enzymes were glycoproteins based on their binding to concanavalin-A immobilized gel and were readily eluted by a buffer containing 0.5 M manopyranoside. The results from the pH and protease inhibitor profiles suggesting that these two ET-converting activities extracted from rat lung membranes are distinct and are different from the previously reported endothelin-converting enzymes.

Direct determination of endothelin receptor antagonist levels in plasma using a scintillation proximity assay.

An assay using scintillation proximity bead technology has been developed suitable for the quantitation of endothelin (ET) receptor antagonists in preclinical and clinical samples of plasma. The assay measures the competitive inhibition of radiolabelled ET-1 binding to ET(A) receptor membranes bound to wheat germ agglutinin (WGA)-coated scintillation proximity assay (SPA) beads in the presence of plasma containing A-127722, a potent orally active, ET(A) selective ET antagonist. The assay requires as little as 50 microl plasma and no extraction procedure is needed. The SPA methodology eliminates the need for the separation of bound from free ligand. Using this method, A-127722 could be directly quantified in rat plasma with a detection limit of 1 ng/ml.

Endothelins and endothelin receptor antagonists: binding to plasma proteins.

Endothelins (ET) are 21-amino acid peptides that bind to membrane receptors to initiate a wide range of pathophysiological effects. PD-156707, L-749329, Ro-470203, and A-127722 are potent non-peptide ET receptor antagonists developed recently. When tested in human and rat plasma, both ET-1 and -3 and the four aforementioned antagonists exhibited a high degree (> 98%) of plasma protein binding. When ET-1 binding to the receptors was examined, 5% (v/v) of human plasma inhibited ET-1 binding to both ETA and ETB receptors by 80 - 90%. Similarly, 5% (w/v) of human serum albumin inhibited ET-1 binding by 82%, suggesting that the major protein component in plasma which interfered with ET-1 binding to the receptors was serum albumin. Competition studies show that, in the absence of human serum albumin, the IC50 values of PD-156707, L-749329, Ro-47-0203, and A-127722 were 0.37, 0.29, 5.7, and 0.22 nM, respectively. Addition of increasing doses of human serum albumin incrementally decreased the potency of the antagonists; in the presence of 5% of human serum albumin, the IC50 values increased to 62.8, 50.2, 122.7, and 6.72 nM for PD-156707, L-749329, Ro-47-0203, and A-127722, respectively. In conclusion, ET and ET receptor antagonists exhibit a high degree of binding to plasma proteins, especially serum albumin. Consequently, serum albumin inhibits ET binding to its receptors, and also decreases the potency of ET receptor antagonists. Our findings may explain the discrepancy observed for ET receptor antagonists between in vitro and in vivo potencies.

The effects of diminishing albumin binding to some Endothelin receptor antagonists.

As a pharmacological class, Endothelin-A receptor (ET(A)) antagonists are highly bound (>98%) to serum albumin. In the presence of physiological concentrations of albumin, their affinities for ET(A) decrease 10 to 100 fold. We have prepared ET(A) antagonists which exhibit lower degrees of binding to albumin, while maintaining potency and selectivity for the ET(A) receptor. The protein induced IC50 shift is reduced or eliminated in this new series of compounds. The compounds also display altered in vivo and pharmacokinetic profiles which may be consistent with their lower degree of protein binding.

Extracellular signal-regulated kinases are involved in the antiapoptotic effect of endothelin-1.

An imbalance between proliferation and apoptosis is an important causal factor for disorders involving abnormal cell accumulation. The role and mechanism of how G protein-coupled receptors are linked to apoptosis are poorly understood. Endothelin-1 (ET-1), a 21-amino acid peptide that binds to G protein-coupled receptors with mitogenic and vasoconstricting activities, suppressed apoptosis of human prostatic smooth muscle cells induced by paclitaxel treatment or serum withdrawal. Serum withdrawal or paclitaxel (1-10 microM) treatment for 48 h resulted in DNA fragmentation, a characteristic of apoptosis. The addition of ET-1 attenuated DNA fragmentation. The attenuating effect of ET-1 on DNA fragmentation was not affected by wortmannin, bisindolylmaleimide I, tyrphostin AG490, or AG1478. However, PD98059, an inhibitor for the extracellular signal-regulated kinase (ERK) kinase, induced apoptosis, potentiated the effect of serum withdrawal on inducing apoptosis, and blocked the antiapoptotic effect of ET-1. The ERK1/2 activity in these cells decreased rapidly after paclitaxel treatment or serum withdrawal, but was maintained at a 2-fold higher level in the presence of ET-1 for at least 4 h. These results suggest that the ERK1/2 pathway is activated by ET-1, and blocking this pathway abolishes the antiapoptotic effect of ET-1.

Obligatory action of polypeptide growth factors for the IL-1-mediated prostaglandin E2 production in fibroblasts. Potential role of growth factors in modulation of tissue response to IL-1.

Our studies show that in connective tissue cells, induction of PGE2 synthesis in response to IL-1 requires costimulation with platelet-derived growth factor (PDGF) or fibroblast growth factor (FGF). In cells incubated in medium containing fresh serum, IL-1 induced a dose-dependent synthesis of PGE2. However, when the cells were incubated in medium containing low serum or platelet poor plasma (lacking PDGF), IL-1 alone failed to induce PGE2 synthesis. PGE2 synthesis was restored when platelet poor plasma was supplemented with PDGF. Addition of PDGF or FGF together with IL-1 resulted in a 14- and 66-fold stimulation of PGE2 synthesis, respectively. Stimulation was dependent on the concentration of both IL-1 and the growth factor. PGE2 synthesis was also dependent on the synthesis of new proteins. In cells simultaneously treated with IL-1 and PDGF, PGE2 synthesis was initiated after a lag of 2 to 3 h, proceeded first with a rapid rate for 6 h, and then with a slower rate through 24 h. PGE2 synthesis during the latter, slower phase was greatly enhanced by pretreatment with PDGF, but not by pretreatment with IL-1. PDGF pretreatment also resulted in maintenance of 10- to 12-fold higher cell surface IL-1-binding during this phase. These data provide evidence for potentially novel interactions between PDGF and IL-1 activities, one of which is the modulation of IL-1 receptors by PDGF. Furthermore, these studies suggest that by virtue of their effect on IL-1 activities, PDGF and FGF may play additional roles in connective tissues, including an indirect role in inflammatory processes.