Shouxi Xu

Ocular Hypotensive FP Prostaglandin (PG) Analogs: PG Receptor Subtype Binding Affinities and Selectivities, and Agonist Potencies at FP and Other PG Receptors in Cultured Cells

Natural prostaglandins (PGs) such as PGD2, PGE2, PGF2(2alpha), and PGI2 exhibited the highest affinity for their respective cognate receptors, but were the least selective agents when tested in receptor binding assays. Travoprost acid ([+]-fluprostenol) was the most FP-receptor-selective compound, exhibiting a high affinity (Ki = 35 +/- 5 nM) for the FP receptor, and minimal affinity for DP (Ki = 52,000 nM), EP1 (Ki = 9540 nM), EP3 (Ki = 3501 nM), EP4 (Ki = 41,000 nM), IP (Ki > 90,000 nM), and TP (Ki = 121,000 nM) receptors. Travoprost acid was the most potent PG analog tested in FP receptor functional phosphoinositide turnover assays in the following cell types: human ciliary muscle (EC50 = 1.4 nM), human trabecular meshwork (EC50 = 3.6 nM), and mouse fibroblasts and rat aortic smooth muscle cells (EC50 = 2.6 nM). Although latanoprost acid exhibited a relatively high affinity for the FP receptor (Ki = 98 nM), it had significant functional activity at FP (EC50 = 32-124 nM) and EP1 (EC50 = 119 nM) receptors. Bimatoprost acid was less selective, exhibiting a relatively high affinity for the FP (Ki = 83 nM), EP1 (Ki = 95 nM), and EP3 (Ki = 387 nM) receptors. Bimatoprost acid exhibited functional activity at the EP1 (EC50 = 2.7 nM) and FP (EC50 = 2.8-3.8 nM in most cells) receptors. Bimatoprost (nonhydrolyzed amide) also behaved as an FP agonist at the cloned human FP receptor (EC50 = 681 nM), in h-TM (EC50 = 3245 nM) and other cell types. Unoprostone and S-1033 bound with low affinity (Ki = 5.9 microM to > 22 microM) to the FP receptor, were not selective, but activated the FP receptor. In conclusion, travoprost acid has the highest affinity, the highest FP-receptor-selectivity, and the highest potency at the FP receptor as compared to the other ocular hypotensive PG analogs known so far, including free acids of latanoprost, bimatoprost, and unoprostone isopropyl ester.

Levobetaxolol (Betaxon™) and Other β-Adrenergic Antagonists: Preclinical Pharmacology, IOP-Lowering Activity and Sites of Action in Human Eyes

The pharmacological characteristics of levobetaxolol, a single active isomer of betaxolol, were determined and compared with activities of other beta-adrenoceptor antagonists. Levobetaxolol (43-fold beta1-selective) exhibited a higher affinity at cloned human beta1 (Ki = 0.76 nM) than at beta2 (Ki = 32.6 nM) receptors, while dextrobetaxolol was much weaker at both receptors. Levobetaxolol potently antagonized functional activities at cloned human beta1 and beta2 receptors, and also at guinea pig atrial beta1, tracheal beta2 and rat colonic beta3 receptors (IC50s = 33.2 nM, 2970 nM and 709 nM, respectively). Thus, levobetaxolol was 89-times beta1-selective (vs beta2). Levobetaxolol (Ki = 16.4 nM) was more potent than dextrobetaxolol (Ki = 2.97 microM) at inhibiting isoproterenol-induced cAMP production in human non-pigmented ciliary epithelial cells. Levobunolol and (l)-timolol had high affinities at beta1 and beta2 receptors but were considerably less beta1-selective than levobetaxolol. Levo-, dextro- and racemic-betaxolol exhibited little or no affinity, except at sigma sites and Ca2+-channels (IC50s > 1 microM), at 89 other receptor/ligand binding sites. Levobetaxolol exhibited a micromolar affinity for L-type Ca2+-channels. In conscious ocular hypertensive cynomolgus monkeys, levobetaxolol was more potent than dextrobetaxolol, reducing intraocular pressure by 25.9+/-3.2% at a dose of 150 microg/eye (n = 15-30). Quantitative [3H]-levobetaxolol autoradiography revealed high levels of binding to human ciliary processes, iris, choroid/retina, and ciliary muscles. In conclusion, levobetaxolol is a potent, high affinity and beta1-selective IOP-lowering beta-adrenoceptor antagonist.

Rapid Identification of Novel Inhibitors of the Human Aquaporin-1 Water Channel.

Aquaporins (AQPs) are a family of membrane proteins that function as channels facilitating water transport in response to osmotic gradients. These play critical roles in several normal physiological and pathological states and are targets for drug discovery. Selective inhibition of the AQP1 water channel may provide a new approach for the treatment of several disorders including ocular hypertension/glaucoma, congestive heart failure, brain swelling associated with a stroke, corneal and macular edema, pulmonary edema, and otic disorders such as hearing loss and vertigo. We developed a high‐throughput assay to screen a library of compounds as potential AQP1 modulators by monitoring the fluorescence dequenching of entrapped calcein in a confluent layer of AQP1‐overexpressing CHO cells that were exposed to a hypotonic shock. Promising candidates were tested in a Xenopus oocyte‐swelling assay, which confirmed the identification of two lead classes of compounds belonging to aromatic sulfonamides and dihydrobenzofurans with IC50s in the low micromolar range. These selected compounds directly inhibited water transport in AQP1‐enriched stripped erythrocyte ghosts and in proteoliposomes reconstituted with purified AQP1. Validation of these lead compounds, by the three independent assays, establishes a set of attractive AQP1 blockers for developing novel, small‐molecule functional modulators of human AQP1.

Human Non-Pigmented Ciliary Epithelium Bradykinin B2-Receptors: Receptor Localization, Pharmacological Characterization of Intracellular Ca2+ Mobilization, and Prostaglandin Secretion

Abstract Purpose: To characterize the bradykinin (BK) receptor system in human non-pigmented ciliary epithelium (NPCE) using immunohistochemistry and functional cell-based techniques. Methods: B2-receptor protein expression was studied in sections of human donor eyes and in Cynomolgus monkey eyes using immunohistochemical methods. The pharmacological characteristics of intracellular Ca2+ ([Ca2+]i) mobilization in response to BK and related peptides, and blockade by two antagonists, was studied in primary human (p-h-NPCE) and in immortalized human NPCE (imh-NPCE) cells. Prostaglandins (PGs) release induced by BK was also studied in both cell-types using ELISA assays. Limited studies on primary human ciliary muscle (h-CM) cells and human trabecular meshwork (h-TM) cells and Chinese hamster ovary cells expressing human cloned B2-receptors (CHO-B2) were performed to compare with responses in both the NPCE cell-types. Results: B2-receptor immunoreactivity was observed on human and Cynomolgus monkey NPCE cells on eye sections from both species. BK and related analog peptides differentially activated signaling mechanisms in NPCE cells by mobilizing [Ca2+]i, and the BK-evoked responses were blocked by B2-receptor-selective antagonists, HOE-140 and (S)-WIN-64338. Relative agonist potencies (EC50, nM) in p-h-NPCE cells [and in imh-NPCE cells] were: BK = 3.4 ± 0.4 [6.3 nM]; Hyp3-BK EC50 = 1.7 ± 0.2 [6.0 nM], Lys-BK EC50 = 7.0 ± 0.3 [19.8 nM]; Met-Lys-BK EC50 = 106 ± 57.8 [125 nM]; Des-Arg9-BK EC50 = >10,000 [16 µM]. The antagonist potencies for attenuating BK-induced mobilization of [Ca2+]i in these cells were: HOE-140 (Ki = 7.9 ± 1.8 nM, n = 4) and (S)-WIN-64338 (Ki = 451 ± 44 nM, n = 4). These NPCE cell data correlated well with those obtained for h-CM and h-TM cells, and with B2-receptor binding (r = 0.99, p < 0.0001). However, BK failed to stimulate total PGs production in both NPCE cell-types even though 10% bovine serum increased PG release (by 4.9-fold above baseline), and even though BK stimulated PG release from h-CM, h-TM and in CHO-B2 cells. BK (1 µM) also failed to increase nitric oxide (NO) levels in NPCE cells even though sodium nitropruside increased NO production by 3-fold. Conclusions: Human and monkey NPCE express immunoreactive B2-receptor proteins. These proteins were functionally active, since BK and related peptides potently stimulated mobilization of [Ca2+]i in p-h-NPCE and imNPCE cells that was blocked by two B2-selective antagonists. Down-stream signaling from B2-receptor activation did not appear to involve PG synthesis/release (or NO production) in NPCE cell-types under the present conditions, even though h-CM, h-TM and CHO-B2 cells exhibited robust PG synthesis and release in response to BK.

Preclinical pharmacology, ocular tolerability and ocular hypotensive efficacy of a novel non-peptide bradykinin mimetic small molecule

We sought to characterize the ocular pharmacology, tolerability and intraocular pressure (IOP)-lowering efficacy of FR-190997, a non-peptidic bradykinin (BK) B2-receptor agonist. FR-190997 possessed a relatively high receptor binding affinity (Ki = 27 nM) and a high in vitro potency (EC50 = 18.3 ± 4.4 nM) for inositol-1-phosphate generation via human cloned B2-receptors expressed in host cells with mimimal activity at B1-receptors. It also mobilized intracellular Ca2+ in isolated human trabecular meshwork (h-TM), ciliary muscle (h-CM), and in immortalized non-pigmented ciliary epithelial (h-iNPE) cells (EC50s = 167-384 nM; Emax = 32-86% of BK-induced response). HOE-140, a selective B2-receptor antagonist, potently blocked the latter effects of FR-190997 (e.g., IC50 = 7.3 ± 0.6 nM in h-CM cells). FR-190997 also stimulated the release of prostaglandins (PGs) from h-TM and h-CM cells (EC50s = 60-84 nM; Emax = 29-44% relative to max. BK-induced effects). FR-190997 (0.3-300 μg t.o.) did not activate cat corneal polymodal nociceptors and did not cause ocular discomfort in Dutch-Belted rabbits, but it was not well tolerated in New Zealand albino rabbits and Hartley guinea pigs. A single topical ocular (t.o.) dose of 1% FR-190997 in Dutch-Belted rabbits and mixed breed cats did not lower IOP. However, FR-190997 efficaciously lowered IOP of conscious ocular hypertensive cynomolgus monkey eyes (e.g., 34.5 ± 7.5% decrease; 6 h post-dose of 30 μg t.o.; n = 8). Thus, FR-190997 is an unexampled efficacious ocular hypotensive B2-receptor non-peptide BK agonist that activates multiple signaling pathways to cause IOP reduction.

FR-190997, a nonpeptide bradykinin B2-receptor partial agonist, is a potent and efficacious intraocular pressure lowering agent in ocular hypertensive cynomolgus monkeys.

Preclinical Research