A peptidomimetic antagonist of the integrin alpha(v)beta3 inhibits Leydig cell tumor growth and the development of hypercalcemia of malignancy.

The integrin alpha(v)beta3 interacts with the arginine-glycine-aspartic acid (RGD) tripeptide recognition sequence of a variety of extracellular matrix proteins. Recent studies show that alpha(v)beta3 plays an important role in tumor-induced angiogenesis and tumor growth and that antagonists of alpha(v)beta3 inhibit angiogenic processes that include endothelial cell adhesion and migration. Consequently, we reasoned that an RGD-based peptidomimetic antagonist of alpha(v)beta3 might inhibit tumor angiogenesis and tumor growth in vivo. An RGD-peptidomimetic library was screened to identify antagonists of vitronectin binding to alpha(v)beta3, and the compounds chosen were modified to produce selective and potent inhibitors of alpha(v)beta3. One of these compounds, beta-[[2-2-[[[3-[(aminoiminomethyl)amino]-phenyl]carbonyl]amino]ac etyl]amino]-3,5-dichlorobenzenepropanoic acid (SC-68448), inhibited vitronectin binding to both alpha(v)beta3 and the closely related platelet receptor, alpha(IIb)beta3, in a dose-responsive manner. SC-68448 inhibited vitronectin binding to alpha(v)beta3 (IC50, 1 nM) and fibrinogen binding to the platelet receptor alpha(IIb)beta3 (IC50, >100 nM), demonstrating that SC-68448 was 100-fold more potent as an inhibitor of alpha(v)beta3 versus alpha(IIb)beta3. In cell-based studies, SC-68448 inhibited alpha(v)beta3-mediated endothelial cell proliferation in a dose-dependent manner but did not inhibit tumor cell proliferation, suggesting that effects on endothelial cell proliferation were not due to SC-68448-induced cytotoxicity. In accord with these results, SC-68448 inhibited angiogenesis in vivo in a basic fibroblast growth factor-induced rat corneal neovascularization model. A xenogeneic severe combined immune deficiency mouse/rat Leydig cell tumor model was developed for testing SC-68448 as an inhibitor of tumor growth in vivo. Rat Leydig cell tumors grew rapidly in severe combined immune deficiency mice and produced humoral hypercalcemia of malignancy. SC-68448 inhibited the growth of the tumors in mice by up to 80% and completely blocked the development of hypercalcemia. Together, these results demonstrate the feasibility of antitumor therapies based upon the development of nontoxic small molecule pharmacological antagonists of integrin alpha(v)beta3.

Radioiodinated rat parathyroid hormone-(1-34) binds to its receptor on rat osteosarcoma cells in a manner consistent with two classes of binding sites.

Binding of 125I-labeled rat (r) PTH-(1-34) to ROS 17/2.8 osteoblastic bone cells and to membranes from these cells was examined. Competitive binding inhibition experiments were performed using unlabeled rPTH-(1-34) with particular emphasis on concentrations of peptide below 1 nM. In intact cells, binding of labeled rPTH-(1-34) was highly specific, and inhibition of binding by unlabeled ligand suggested the presence of two classes of binding sites, one with high affinity and low capacity (KD = 40 pM, approximately 20% of total binding sites) and the other with lower affinity and high capacity (KD = 2 nM, approximately 80% of the sites). Membranes prepared from ROS cells also exhibited a pattern of binding from competitive inhibition curves consistent with two distinct binding sites (KD = 30 pM and 6 nM). In intact ROS cells, cellular cAMP levels increased over the range of 10(-11)-10(-9) M rPTH-(1-34) with an ED50 intermediate between the two KD values (0.25 nM). These data suggest that osteoblastic bone cells possess two distinct classes of membrane receptors for PTH. Since the KD of the higher affinity site more closely approximates circulating concentrations of PTH, binding to this site may have physiologic relevance.

Identification and characterization of parathyroid hormone receptors in rat renal cortical plasma membranes using radioligand binding.

Parathyroid hormone (PTH) receptors have been described in renal tissue from several species, but not in the rat. In this study, radioligand binding techniques were used to identify and characterize PTH receptors in rat kidney cortical membranes. The sulfur-free PTH analog [Nle8,18Tyr34]bovine PTH-(1-34)amide was iodinated using the iodogen method. This ligand was suitable for use in identifying PTH receptors in canine renal membranes, but not rat renal membranes. Synthetic, unsubstituted rat PTH-(1-34) was iodinated using the milder, lactoperoxidase technique and was purified by HPLC on a C8 column. [125I]rat PTH-(1-34) bound rapidly to both rat and dog renal membranes. At 22 degrees C reaction reached steady state within 20 minutes, and this level was maintained for at least 3 h. Specific binding was routinely greater than 90% for rat kidney and greater than 95% for dog kidney. Similar results were obtained at 4 degrees C with a longer time required to attain steady state (approximately 45 minutes). Binding was reversible as demonstrated by dissociation of bound ligand after either infinite dilution or displacement with excess nonradioactive PTH. Binding was saturable and of high affinity (rat kidney: Bmax = 2.3 pmol/mg protein, Kd = 3.1 nM, dog kidney: Bmax = 2.1 pmol/mg protein, Kd = 3.7 nM). Rat renal cortical adenylate cyclase activity was stimulated by rat PTH in a dose-dependent manner with an EC50 of 4 nM, a value in good agreement with the binding data. This study demonstrates the feasibility of identifying and characterizing parathyroid hormone receptors in rat renal cortical plasma membranes using radioligand binding techniques.

Binding of parathyroid hormone and parathyroid hormone-related protein to vascular smooth muscle of rabbit renal microvessels.

The humoral hypercalcemia of malignancy factor (also called PTH-related protein or PTHrp) has been shown to produce effects similar to PTH in the kidney, bone, and cardiovascular system. Binding of PTHrp and PTH has been characterized in renal and osseous tissues, but not in vascular tissue. We have attempted to characterize the interaction of both human PTHrp and rat PTH to renal microvessels as a model of vascular smooth muscle and in a renal tubule preparation from the same rabbit kidneys. Previous studies have shown the microvessel and tubule preparations to be distinct based upon morphological examination, differential enzyme markers, calcitonin and vasopressin-sensitive adenylate cyclase distribution, and different characteristics of guanine nucleotide and of oxidized PTH activation of the adenylate cyclases associated with the preparations. Human PTHrp and rat PTH were iodinated by standard techniques and purified by HPLC. Both ligands bound to microvessels and tubules in a saturable, specific manner, Maximal specific binding of either ligand was 65-75% in microvessels and 80-90% in renal tubules. The time courses of binding of both ligands were identical with steady state achieved within 20 min in the smooth muscle of microvessels and 15 min in the tubules at 22 C. In equilibrium competition binding experiments, bound 125I-PTHrp was displaced by both PTHrp and PTH in microvessels and tubules. Rat PTH displayed slightly higher affinity in microvessels and tubules than PTHrp. Identical results were obtained with 125I-PTH as ligand. Specificity of binding of PTHrp and PTH to both microvessels and tubules was excellent, with competition observed between the radioactive ligand and bovine and rat PTH, PTHrp, and the antagonists, [Nle8,18, Tyr34]bovine PTH and [Nle8,18, Tyr34]bovine PTH but not with several other peptides of unrelated structure. The only major difference in binding between microvessels and tubules was a smaller number of binding sites in microvessels compared to tubules. These results indicate that vascular tissue contains receptor sites for PTH and PTHrp as identified by radioligand binding techniques. These receptors are similar in characteristics to the receptors of renal tubular tissue. Both PTH and PTHrp appear to interact with the receptors of rabbit kidney microvessels and tubules.

Cardiovascular responsiveness to parathyroid hormone (PTH) and PTH-related protein in genetic hypertension.

Hypertension is often accompanied by abnormalities of calcium homeostasis, including hyperparathyroidism with reduced target organ responses to PTH in kidney and bone. Due to this association between PTH and hypertension and since PTH and the paracrine factor PTH-related protein (PTHrp) have both been shown to exert marked changes in cardiovascular activity, these actions of PTH and PTHrp were examined in spontaneously hypertensive rats (SHR) and in control normotensive Wistar-Kyoto rats (WKY). Fourteen-week-old SHR [systolic blood pressure (SBP), 201 +/- 4.4 mm Hg] and WKY (SBP, 141 +/- 2.5 mm Hg) were studied. Renal cortical membranes were prepared and assayed for radioligand binding with [125I]PTH-(1-34) and [125I]PTHrp-(1-34). There was no apparent alteration in the affinity of the binding sites to either peptide in the SHR, but specific binding in SHR renal tissue was only 60% of that observed in WKY tissue for both peptides. Serum immunoreactive PTH levels were 4-fold higher in SHR than WKY, while serum total calcium and 1,25-dihydroxyvitamin D3 levels were not different. The iv administration of both PTH and PTHrp produced dose-dependent reductions in SBP and increases in heart rate in conscious unrestrained SHR and WKY. Both peptides caused greater absolute reductions in blood pressure in SHR than in WKY. However, when the hypotensive response was normalized for the higher baseline pressure in the SHR, the blood pressure reductions caused by PTH and PTHrp were not different in SHR and WKY. Conversely, the chronotropic responses to PTH and PTHrp were lower in SHR compared to WKY. These findings indicate that the SHR exhibits elevated PTH levels, with a reduced number of renal PTH/PTHrp receptors and a depressed chronotropic response to either PTH or PTHrp. In contrast, the hypotensive response to PTH or PTHrp was not altered, indicating possible tissue-specific receptor subclasses or tissue-specific regulation of PTH and PTHrp receptors.

Hypotension and cardiac stimulation due to the parathyroid hormone-related protein, humoral hypercalcemia of malignancy factor.

Patients with humoral hypercalcemia of malignancy display markedly increased serum calcium levels, reduced blood pressure, and tachycardia. The causative agent, humoral hypercalcemia of malignancy factor [also called PTH-related protein (PTHrp)] has been shown to interact with PTH receptors in bone and kidney. We compared human PTHrp-(1-34) with rat PTH-(1-34) for the effects of each peptide on cardiovascular function in unrestrained conscious rats. Both PTHrp and PTH decreased blood pressure in a dose-dependent manner over the concentration range of 0.3-30 micrograms/kg. PTHrp was approximately 3-fold more potent than PTH, producing up to a 50 mm Hg decrease in pressure within 2 min at 10 micrograms/kg. Both peptides increased heart rate more than 70 beats/min at this dose. However, PTH appeared to exert greater efficacy and potency than PTHrp in increasing heart rate in vivo. In the isolated and perfused rat heart, PTHrp and PTH produced positive chronotropic and positive inotropic effects as well as increased coronary flow. PTHrp was more potent and more effective than PTH. The time courses of these effects in the perfused heart preparations indicated that both peptides produced maximal effects within 1 min, with all responses returning to baseline within 10 min. In isolated helical strips of rat aorta, PTHrp and PTH relaxed norepinephrine-contracted tissues in a concentration-dependent fashion. A functional endothelium was not required for the relaxing effects of either peptide. These studies indicate that PTHrp and PTH decrease blood pressure by relaxing vascular tissue in an endothelium-independent manner. Also, these peptides directly increased heart rate, contractility, and coronary flow. Since PTHrp has recently been found in normal human cells, these studies suggest the possibility of PTHrp as a regulator or modulator of cardiovascular function.