Characterization of the transport system of prostaglandin A2 in L-1210 murine leukemia cells

Biochemistry of prostaglandins A

This review considers modern concepts on the structural-functional properties and antiproliferative, antitumor, and antiviral effects of cyclopentenone prostaglandins A and mechanisms underlying their actions. Possible directions of pharmacological application of these compounds and their analogs are discussed.

Prostaglandin A2 acts as a transactivator for NOR1 (NR4A3) within the nuclear receptor superfamily

Within the nuclear receptor superfamily, Nur77, Nurr1, and NOR1 constitute the nuclear receptor subfamily 4 group A. Modulation of NOR1 function would be therapeutic potential for diseases related to dysfunction of NOR1, including extraskeletal myxoid chondrosarcoma and autoimmune diseases. By screening arachidonate metabolites for their capacity of transcriptional activation, we have identified prostaglandin (PG) A2 as a transactivator for NOR1. PGA2 acted as a potent activator of NOR1-dependent transcription through the GAL4-based reporter system. The putative ligand-binding domain (LBD) of the receptor directly bound PGA2, and LBD-deleted receptor showed little transcriptional activation by PGA2. Primary cultured spleen cells derived from transgenic mice overexpressing NOR1, showed higher sensitivity to PGA2 compared to those from wild-type mice. These observations suggest that PGA2 can serve as a transactivator of NOR1, and thus suggest a possibility of pharmacological modulation of the NOR1 pathways by PGA2-related compounds.

Nuclear prostaglandin receptors: role in pregnancy and parturition?

The key regulatory role of prostanoids [prostaglandins (PGs) and thromboxanes (TXs)] in the maintenance of pregnancy and initiation of parturition has been established. However, our understanding of how these events are fine-tuned by the recruitment of specific signaling pathways remains unclear. Whereas, initial thoughts were that PGs were lipophilic and would easily cross cell membranes without specific receptors or transport processes, it has since been realized that PG signaling occurs via specific cell surface G-protein coupled receptors (GPCRs) coupled to classical adenylate cyclase or inositol phosphate signaling pathways. Furthermore, specific PG transporters have been identified and cloned adding a further level of complexity to the regulation of paracrine action of these potent bioactive molecules. It is now apparent that PGs also activate nuclear receptors, opening the possibility of novel intracrine signaling mechanisms. The existence of intracrine signaling pathways is further supported by accumulating evidence linking the perinuclear localization of PG synthesizing enzymes with intracellular PG synthesis. This review will focus on the evidence for a role of nuclear actions of PGs in the regulation of pregnancy and parturition.

Preparation and evaluation of o/w type emulsions containing antitumor prostaglandin

Antitumor prostaglandins(PGs) such as Delta12-PGJ2 and Delta7-PGA1 possess a cyclopentenone or cross-conjugated dienone structures. Antitumor PGs are actively incorporated through cell membrane and control gene expression. Very recent studies clarified that P53 independent expression of p21 and gadd 45, activation of PPARgamma are involved in antitumor mechanism of these PGs. At the low concentration, these PGs exhibit physiological or pathological activity such as osteoblast calcification, promotion of colon cancer cell proliferation. COMPARE PROGRAM using human 38 tumor cell lines suggested that antitumor mechanism of Delta7-PGA1 and 13, 14-dihydro-15-deoxy-Delta7-PGA1 methyl ester (TEI-9826) are quite different from other anticancer agents which are clinically used. Lipid microspheres and Lipiodol formulation were examined as dosage form of the PGs and lipid microspheres were selected for further study. At first lipid microspheres integrated TEI-9038 (Lipo TEI-9038) was chosen as a candidate for clinical trial. However Lipo TEI-9038 failed to exhibit substantial antitumor effect because of its enzymatic instability and toxicity in vivo. Lipo TEI-9826 was then selected as promising candidate for clinical trial because of its stability in serum. Lipo TEI-9826 exhibited marked antitumor effect in several animal models including CDDP resistant nude mice model. Pharmacokinetic and toxicological studies using rats suggested that continuous infusion is the most suitable administration method for Lipo TEI-9826. New type emulsifier, Controlled High Pressure Process Homogenizer (De-BEE 2000 and mini De-BEE) was developed during the preclinical studies on manufacturing process of Lipo TEI-9826. These results warrant the clinical trial for Lipo TEI-9826 in CDDP resistant cancer.

Subcellular localization of prostaglandin H synthase-2 in a human amnion cell line: implications for nuclear localized prostaglandin signaling pathways

We have determined that prostaglandin H synthase-2 localises strongly to the nuclear membrane as well as being found in the endoplasmic reticulum in human amnion-derived WISH cells which have been stimulated with interleukin 1beta and phorbol ester. This is consistent with findings in cells of non-reproductive origin. There is strong evidence that prostaglandin J2 derivatives, which in other tissues exhibit tumour suppressing, antiproliferative and/or differentiation promoting activities, act through binding of intracellular receptors which then enter the nucleus. In addition, some arachidonic acid derivatives are clearly generated by enzymes at the nuclear envelope and localise to sites in nuclei or bind sites in nuclei. The WISH cell line will make an excellent system for studying these perinuclear intracellular prostanoid signaling mechanisms.

Interactions of prostaglandin A2 with the glutathione-mediated biotransformation system

The cyclopentenone prostaglandin A2 (PGA2) is known to inhibit cell proliferation, and metabolism of this compound thus might be important in controlling its ultimate function. The glutathione-related metabolism of PGA2 was therefore investigated both with purified glutathione S-transferase P1-1 (GSTP1-1) and with IGR-39 human melanoma cells. Firstly, the irreversible inhibition of human GSTP1-1 and its mutants C47S, C101S, and C47S/C101S was studied. PGA2 appeared to inhibit GSTP1-1 mainly by binding to the cysteine 47 moiety of the enzyme. This binding was reversed by a molar excess of GSH, indicating that retro-Michael cleavage occurs. Secondly, after exposing IGR-39 human melanoma cells to PGA2, both diastereoisomers of the PGA2-glutathione conjugate are excreted into the medium, although with a clear excess of the S-form, due to its preferential formation by the GSTP1-1 present in the cells. Thirdly, the effect of PGA2 on intracellular GST activity was determined by quantification of the excreted glutathione conjugate S-(2,4-dinitrophenyl)glutathione (DNPSG) after exposure to 1-chloro-2,4-dinitrobenzene. DNPSG excretion was inhibited after incubation with 10 or 20 microM PGA2 for 1 or 4 hr, as a result of glutathione depletion, reversible GST inhibition, and covalent modification of intracellular GST. Furthermore, PGA2 also inhibited transport of DNPSG by the multidrug resistance-associated protein, an effect that was reversible and competitive. In conclusion, PGA2 modulates all three aspects of the glutathione-mediated biotransformation system, i.e. GSH levels, GSTP1-1 activity, and transport of GSH conjugates. A role for GSTP1-1 as a specific transport protein inside the cell is indicated.

Molecular mechanisms of prostaglandin transport

Despite the fact that prostaglandins (PGs) have low intrinsic permeabilities across the plasma membrane, they must cross it twice: first upon release from the cytosol into the blood, and again upon cellular uptake prior to oxidation. Until recently, there were no cloned carriers that transported PGs. PGT is a broadly-expressed, 12-membrane-spanning domain integral membrane protein. When heterologously expressed in HeLa cells or Xenopus oocytes, it catalyzes the rapid, specific, and high-affinity uptake of PGE2, PGF2 alpha, PGD2, 8-iso-PGF2 alpha, and thromboxane B2. Functional studies indicate that PGT transports its substrate as the charged anion. The PGT substrate specificity and inhibitor profile match remarkably well with earlier in situ studies on the metabolic clearance of PGs by rat lung. Because PGT expression is especially high in this tissue, it is likely that PGT mediates the membrane step in PG clearance by the pulmonary circulation. Evidence is presented that PGT may play additional roles in other tissues and that there may be additional PG transporters yet to be identified molecularly.

Intracellular glutathione level modulates the induction of apoptosis by delta 12-prostaglandin J2

We studied the effect of intracellular glutathione (GSH), which was known to conjugate readily with an alpha, beta-unsaturated carbonyl of 9-deoxy-delta 9,12-13,14-dihydroPGD2 (delta 12-PGJ2), on the cytotoxicity of delta 12-PGJ2. delta 12-PGJ2 caused DNA fragmentation in human hepatocellular carcinoma Hep 3B cells, which was blocked by cycloheximide (CHX). The delta 12-PGJ2-induced apoptosis was augmented by GSH depletion resulted from pretreatment with buthioninine sulfoximine (BSO), an inhibitor of gamma-glutamylcysteine synthetase. On the contrary, N-acetyl-cysteine (NAC), a precursor of cysteine, elevated the GSH level and protected cells from initiating apoptosis by delta 12-PGJ2. Sodium arsenite, a thiol-reactive agent, also induced apoptosis, which was potentiated or attenuated by BSO or NAC treatment respectively. These results suggest that the apoptosis-inducing activity of delta 12-PGJ2 is due to thiol-reactivity and intracellular GSH modulates the delta 12-PGJ2-induced apoptosis by regulating the accessibility of delta 12-PGJ2 to target proteins containing thiol groups.

Prostaglandin A2 blocks the activation of G1 phase cyclin-dependent kinase without altering mitogen-activated protein kinase stimulation

Prostaglandin A2 (PGA2) reversibly blocked the cell cycle progression of NIH 3T3 cells at G1 and G2/M phase. When it was applied to cells synchronized in G0 or S phase, cells were blocked at G1 and G2/M, respectively. The G2/M blockage was transient. Microinjected oncogenic leucine 61 Ras protein could not override the PGA2 induced G1 blockage, nor could previous transformation with the v-raf oncogene. The serum-induced activation of mitogen-activated protein kinase was not inhibited by PGA2 treatment. These data suggest that PGA2 blocks cell cycle progression without interfering with the cytosolic proliferative signaling pathway. Combined microinjection of E2F-1 and DP-1 proteins or microinjected adenovirus E1A protein, however, could induce S phase in cells arrested in G1 by PGA2, indicating that PGA2 does not directly inhibit the process of DNA synthesis. In quiescent cells, PGA2 blocked the normal hyperphosphorylation of the retinoblastoma susceptible gene product and the activation of cyclin-dependent kinase (CDK) 2 and CDK4, in response to serum stimulation. PGA2 treatment elevated the p21Waf1/Cip1/Sdi1 protein expression level. These data indicate that PGA2 may arrest the cell cycle in G1 by interfering with the activation of G1 phase CDKs.

Prostaglandin A2 protein interactions and inhibition of cellular proliferation

Some prostaglandins inhibit cellular proliferation in a wide variety of cell types, but the mechanism of inhibition is not known. The most potent inhibitors of proliferation appear to be prostaglandins of the A and J series. These prostaglandins have been reported to form covalent bonds to cellular proteins (Narumiya, S., Ohno, K., Fukushima, M., Fujiwara, M. (1987) J. Pharm. Exp. Ther., 242, 306-311). However, the proteins have not been identified or shown to be involved in the inhibition of proliferation. Prostaglandin A2-biotin provided a sensitive method to demonstrate binding of prostaglandin A2 (PGA2) to cellular proteins of 43, 50, and 56 kilodaltons in K562 erythroleukemia cells. Similar PGA2-binding proteins were also present in mouse fibroblasts and porcine aortic endothelial cells. The PGA2-binding proteins preexist in K562 cells and were not induced by exposure to the prostaglandin. Furthermore, binding of PGA2 to these proteins correlated to the inhibition of proliferation. Therefore, one or more of the PGA2-binding proteins may be involved in the inhibition of cellular proliferation by PGA2.