ABSTRACT
The enantioselective de novo synthesis of pharmacologically important 14-hydroxy-6-oxomorphinans is described. 4,5-Desoxynaltrexone and 4,5-desoxynaloxone were prepared using this route and their biological activities against the opioid receptors were measured.
Subject(s)
Morphinans , Stereoisomerism , Morphinans/chemistry , Morphinans/chemical synthesis , Naltrexone/analogs & derivatives , Naltrexone/chemistry , Naltrexone/chemical synthesis , Molecular Structure , Narcotic Antagonists/chemical synthesis , Receptors, Opioid/metabolismABSTRACT
Introduction: The Epidermal Growth Factor Receptor is a member of the Erb receptor tyrosine kinase family. It binds several ligands including EGF, betacellulin (BTC) and TGF-α, controls cellular proliferation and invasion and is overexpressed in various cancer types. Nanobodies (VHHs) are the antigen binding fragments of heavy chain only camelid antibodies. In this paper we used NanoBRET to compare the binding characteristics of fluorescent EGF or two distinct fluorescently labelled EGFR directed nanobodies (Q44c and Q86c) to full length EGFR. Methods: Living HEK293T cells were stably transfected with N terminal NLuc tagged EGFR. NanoBRET saturation, displacement or kinetics experiments were then performed using fluorescently labelled EGF ligands (EGF-AF488 or EGF-AF647) or fluorescently labelled EGFR targeting nanobodies (Q44c-HL488 and Q86c-HL488). Results: These data revealed that the EGFR nanobody Q44c was able to inhibit EGF binding to full length EGFR, while Q86c was able to recognise agonist bound EGFR and act as a conformational sensor. The specific binding of fluorescent Q44c-HL488 and EGF-AF488 was inhibited by a range of EGFR ligands (EGF> BTC>TGF-α). Discussion: EGFR targeting nanobodies are powerful tools for studying the role of the EGFR in health and disease and allow real time quantification of ligand binding and distinct ligand induced conformational changes.
Subject(s)
Single-Domain Antibodies , Humans , Transforming Growth Factor alpha , Ligands , Epidermal Growth Factor , HEK293 Cells , ErbB Receptors , Coloring Agents , Immunoglobulin Heavy ChainsABSTRACT
The human P2Y2 receptor ( hP2Y2R) is a G-protein-coupled receptor that shows promise as a therapeutic target for many important conditions, including for antimetastatic cancer and more recently for idiopathic pulmonary fibrosis. As such, there is a need for new hP2Y2R antagonists and molecular probes to study this receptor. Herein, we report the development of a new series of non-nucleotide hP2Y2R antagonists, based on the known, non-nucleotide hP2Y2R antagonist AR-C118925 (1), leading to the discovery of a series of fluorescent ligands containing different linkers and fluorophores. One of these conjugates, 98, displayed micromolar affinity for hP2Y2R (p Kd = 6.32 ± 0.10, n = 17) in a bioluminescence-energy-transfer (BRET) assay. Confocal microscopy with this ligand revealed displaceable membrane labeling of astrocytoma cells expressing untagged hP2Y2R. These properties make 98 one of the first tools for studying hP2Y2R distribution and organization.
Subject(s)
Dibenzocycloheptenes/pharmacology , Fluorescent Dyes/chemical synthesis , Fluorescent Dyes/pharmacology , Purinergic P2 Receptor Antagonists/chemical synthesis , Purinergic P2 Receptor Antagonists/pharmacology , Pyrimidinones/pharmacology , Receptors, Purinergic P2Y2/drug effects , Astrocytoma/metabolism , Cell Line , Dibenzocycloheptenes/chemistry , Humans , Ligands , Microscopy, Confocal , Molecular Probes , Protein Binding , Pyrimidinones/chemistry , Recombinant Proteins/chemistry , Structure-Activity RelationshipABSTRACT
G protein-coupled receptors (GPCRs) constitute the largest family of transmembrane receptors in eukaryotes. The adenosine A1 receptor (A1AR) is a class A GPCR that is of interest as a therapeutic target particularly in the treatment of cardiovascular disease and neuropathic pain. Increased knowledge of the role A1AR plays in mediating these pathophysiological processes will help realise the therapeutic potential of this receptor. There is a lack of enabling tools such as selective fluorescent probes to study A1AR, therefore we designed a series of (benzimidazolyl)isoquinolinols conjugated to a fluorescent dye (31-35, 42-43). An improved procedure for the synthesis of isoquinolinols from tetrahydroisoquinolinols via oxidation with 2,3-dichloro-5,6-dicyano-1,4-benzoquinone (DDQ) and atmospheric oxygen is reported. This synthetic method offers advantages over previous metal-based methods for the preparation of isoquinolinols and isoquinolines, which are important scaffolds found in many biologically active compounds and natural products. We report the first synthesis of the (benzimidazolyl)isoquinolinol compound class, however the fluorescent conjugates were not successful as A1AR fluorescent ligands.
ABSTRACT
Prostaglandin E(2) (PGE(2)) has intriguing effects on platelet function in the presence of agents that raise cyclic adenosine 3'5'-monophosphate (cAMP). PGE(2) reverses inhibition of platelet aggregation by agents that stimulate cAMP production via a G(s)-linked receptor, but adds to the inhibition of platelet function brought about by agents that raise cAMP through other mechanisms. Here, we used the EP receptor antagonists DG-041 (which acts at the EP3 receptor) and ONO-AE3-208 (which acts at the EP4 receptor) to investigate the role of these receptors in mediating these effects of PGE(2). Platelet aggregation was measured in platelet-rich plasma obtained from healthy volunteers in response to adenosine diphosphate (ADP) using single platelet counting. The effects of a range of concentrations of PGE(2) were determined in the presence of (1) the prostacyclin mimetic iloprost, which operates through G(s)-linked IP receptors, (2) the cAMP PDE inhibitor DN9693 and (3) the direct-acting adenylate cyclase stimulator forskolin. Vasodilator-stimulated phosphoprotein (VASP) phosphorylation was also determined as a measure of cAMP. PGE(2) reversed the inhibition of aggregation brought about by iloprost; this was prevented in the presence of the EP3 antagonist DG-041, indicating that this effect of PGE(2) is mediated via the EP3 receptor. In contrast, PGE(2) added to the inhibition of aggregation brought about by DN9693 or forskolin; this was reversed by the EP4 antagonist ONO-AE3-208, indicating that this effect of PGE(2) is mediated via the EP4 receptor. Effects on aggregation were accompanied by corresponding changes in VASP phosphorylation. The dominant role of EP3 receptors circumstances where cAMP is increased through a Gs-linked mechanism may be relevant to the situation in vivo where platelets are maintained in an inactive state through constant exposure to prostacyclin, and thus the main effect of PGE(2) may be prothrombotic. If so, the results described here further support the potential use of an EP3 receptor antagonist in the control of atherothrombosis.
Subject(s)
Blood Platelets/drug effects , Dinoprostone/pharmacology , Platelet Aggregation/drug effects , Receptors, G-Protein-Coupled/blood , Receptors, Prostaglandin E, EP3 Subtype/blood , Receptors, Prostaglandin E, EP4 Subtype/blood , Acrylamides/pharmacology , Blood Platelets/physiology , Cell Adhesion Molecules/blood , Colforsin/pharmacology , Cyclic AMP/blood , Humans , Microfilament Proteins/blood , Naphthalenes/pharmacology , Phenylbutyrates/pharmacology , Phosphoproteins/blood , Phosphorylation , Platelet Aggregation Inhibitors/pharmacology , Prostaglandin Antagonists/pharmacology , Quinazolines/pharmacology , Receptors, Prostaglandin E, EP3 Subtype/antagonists & inhibitors , Receptors, Prostaglandin E, EP4 Subtype/antagonists & inhibitors , Sulfones/pharmacologyABSTRACT
ADP induces platelet aggregation in human whole blood and platelet-rich plasma (PRP). ATP induces aggregation in whole blood only; this involves leukocytes and is mediated by ADP. Here we studied ATP- and ADP-induced aggregation in patients with raised leukocyte counts (mean 46.2x10(3) leukocytes/microl). Platelet aggregation was measured by platelet counting. ATP, ADP and metabolites were measured by HPLC. Aggregation to ADP (1-10 microM) and ATP (10-100 microM) was markedly reduced, but to ATP (1000 microM) was enhanced (all p<0.001). Aggregation to ADP in PRP was normal. Increasing the leukocyte count in normal blood reproduced the findings in the patients. Adding leukocytes (either MNLs or PMNLs) to normal PRP enabled a response to ATP and caused marked inhibition of ADP-induced aggregation. Breakdown of ATP or ADP to AMP and adenosine in leukocyte-rich plasma was rapid (t1/2=4 min) and far higher than in cell-free plasma or PRP. With ATP there was also formation of ADP, maximal at 4 min. The presence of the ectonucleotidase NTPDase1 (CD39) was demonstrated on MNLs (all of the monocytes and a proportion of the lymphocytes) and all PMNLs by flow cytometry. We conclude that leukocytes provide a means of dephosphorylating ATP which enables ATP-induced aggregation via conversion to ADP, but also convert ADP to AMP and adenosine. Platelet aggregation extent is a balance between these activities, and high white cell counts influence this balance.
Subject(s)
Adenosine Diphosphate/pharmacology , Adenosine Triphosphatases/physiology , Adenosine Triphosphate/pharmacology , Leukocytes/enzymology , Leukocytes/physiology , Platelet Aggregation/drug effects , Adenosine Diphosphate/metabolism , Adenosine Monophosphate , Adenosine Triphosphatases/analysis , Adenosine Triphosphate/metabolism , Antigens, CD/analysis , Apyrase/analysis , Cell Communication , Humans , Leukocyte Count , Phosphorylation , Platelet Function TestsABSTRACT
OBJECTIVE: Effects on platelet aggregation of adenosine triphosphate (ATP) released from damaged cells and from platelets undergoing exocytosis have not been clearly established. In this study we report on the effects of ATP on platelet aggregation in whole blood. METHODS AND RESULTS: Aggregation, measured using a platelet-counting technique, occurred in response to ATP and was maximal at 10 to 100 micromol/L. It was abolished by MRS2179, AR-C69931, and creatine phosphate/creatine phosphokinase, implying that conversion to adenosine diphosphate (ADP) is required. ATP did not induce aggregation in platelet-rich plasma, but aggregation did occur when apyrase or hexokinase was added. Aggregation also occurred after addition of leukocytes to platelet-rich plasma (as a source of ecto-ATPase), and this was potentiated on removal of adenosine by adenosine deaminase, indicating that adenosine production modulates the response. Dipyridamole, which inhibits adenosine uptake into erythrocytes, inhibited aggregation induced by ATP in whole blood, and adenosine deaminase reversed this. DN9693 and forskolin synergized with dipyridamole to inhibit ATP-induced aggregation. CONCLUSIONS: ATP induces aggregation in whole blood via conversion of ATP to ADP by ecto-ATPases on leukocytes. This is inhibited by agents that prevent adenosine removal. Reduced aggregation at high concentrations of ATP (>100 micromol/L) may be a consequence of inhibition by ATP of ADP action at ADP receptors.