PHA 316 Other Mediators Purine Nucleoside and Nucleotides 2022 PDF

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Summary

This document provides an overview of purine nucleosides and nucleotides as mediators. It discusses their roles in various physiological processes, including their effects on the cardiovascular, respiratory, and other systems. The document also explores pharmacological interventions related to these molecules.

Full Transcript

Other Peripheral Mediators Purine nucleosides and nucleotides Objectives Purines – List the different purine nucleoside an nucleotides that act as mediators – List the different purinergic receptors and their principal endogenous ligands – Describe the ro...

Other Peripheral Mediators Purine nucleosides and nucleotides Objectives Purines – List the different purine nucleoside an nucleotides that act as mediators – List the different purinergic receptors and their principal endogenous ligands – Describe the role of adenosine, ADP and ATP as extracellular signaling molecules/ mediators and list some of the physiological processes mediated by them – Describe pharmacological interventions affecting purinergic signalling, key drug examples and their mechanisms of action and clinical use, and key interactions Nitric oxide Purines Overview Recall that nitrogenous bases present in the DNA can be grouped into two categories: purines (Adenine (A) and Guanine (G)), and pyrimidine (Cytosine (C) and Thymine (T)) Purines are found in all of the body’s cells They are found in many foods with high purine foods are also high-protein foods and they include organ meats like kidney, fish like mackerel, herring, sardines and also yeas Purine nucleoside and nucleotides Overview Recall purine nucleosides, especially adenosine, and nucleotides, especially ADP and ATP because of their crucial role in DNA/RNA synthesis and energy metabolism. But it is also important to note that they also produce a wide range of pharmacological effects that are unrelated to their role in energy metabolism. Purine nucleoside and nucleotides as mediators - Overview Focus for this lesson is on purine nucleoside (adenosine) and purine nucleotides (ADP and ATP) as mediators There is an increasing interest in purine pharmacology and the potential role of purinergic agents in the treatment of pain and a variety of disorders, particularly of thrombotic and respiratory origin The full complexity of purinergic control systems, and their importance in many pathophysiological mechanisms, is only now emerging. The physiological significance; and hence therapeutic relevance of the various receptor subtypes is still being unraveled Nucleosides/Nucleotide as mediators – Site of action ATP,ADP and Adenosine work extracellularly as signalling molecules and produce diverse physiological/pharmacological effects. Fig 17.1 Nucleosides/Nucleotide as mediators – Physiological effects Purinergic signalling is involved in controlling a number of physiological processes Physiological control by purinergic signalling Regulation of Regulation of Regulation of Regulation of Neurotransmi coronary myocardial platelet immune tter in both blood flow function aggregation response CNS and PNS Nucleosides/Nucleotide as mediators – Purinergic Receptors - Overview There are three main families of purine receptors each with several subtypes.(A, PY and PX) They utilize either cAMP or phospholipase C activation as their signalling system They respond to various adenine nucleoside and nucleotides, generally adenosine, ADP or ATP The subtypes in each family may be distinguished on the basis of their molecular structure as well as their agonist and antagonist selectivity. Refer to table Rang and Dale 17.1 for details including signal transduction. Summary molecular mechanism by receptor type is as follows: – Adenosine receptors (A1, A2A, A2B, A3): G-protein coupled – P2Y and subtypes: G-protein coupled – P2X and subtypes: receptor gated cation selective ion channels (ligand gated) EXERCISE: From table 17.1 what is the principal endogenous ligand for each of the above receptors? Adenosine as mediator The simplest of the purines, adenosine is found in biological fluids throughout the body. Figure 17.1 Adenosine differs from ATP in that it is not stored by and released from secretory vesicles. Rather, it exists free in the cytosol of all cells and is transported in and out of cells mainly via a membrane transporter. Extracellular adenosine in tissues comes partly from this intracellular source and partly from extracellular hydrolysis of released ATP or ADP Adenosine can be inactivated to inosine by adenosine deaminase Virtually, all cells express one or more A-receptors and so adenosine produces many pharmacological effects, both in the periphery and in the CNS. Adenosine Receptors: Adenosine receptors Adenosine receptors (subtypes A1, A2A, A2B and A3), formerly known as P1-receptors; These respond to adenosine, and are G-protein-coupled receptors (GPCRs) that regulate cAMP – Linked to stimulation or inhibition of adenylate cyclase – table 17.1 How does activation on A1 receptors by adenosine affect cAMP levels? – Respiratory Effect = mediator release from mast cells, enhanced mucus secretion, bronchoconstriction, leukocyte activation How does activation on A2A receptors by adenosine affect cAMP levels? – Respiratory Effect = Largely protective and anti-inflammatory effect Adenosine as mediator: Cardiovascular System The main effects of adenosine in the CVare: CV it exerts: Heart: a negative chronotropic effect by suppressing the automaticity of cardiac pacemakers, and a negative dromotropic effect through inhibition of AV-nodal conduction (antidysarrhythmic effect) Vasculature: Vasodilation and can cause hypotension (A2?) and cardiac depression (A1) Platelets: inhibition of platelet aggregation acting via A2A and A2B Adenosine as mediator: Respiratory System The main effects of adenosine in Resp are:Respiratory system Adenosine receptors are found on all the cell types involved in asthma and the overall pharmacology is complex A1 receptors: promotion of mediator release from mast cells and hence Enhanced mucus secretion Bronchoconstriction Activation of leukotriens A2A receptors: Anti-inflammatory response Adenosine related pharmacological agents: Clinical utility Areas of Clinical utility Cardiovascular system Asthma inflammation CNS later Clinical uses of Adenosine and drugs that affect adenosine – CV system Cardio-Vascular system: Adenosine: – via intravenous bolus injection to terminate supraventricular tachycardia and convert to sinus rhythm. It is safer than Beta-blockers or verapamil, because of its short duration of action Dipyridamole: – Blocks adenosine cellular uptake. Used as antiplatelet drug with vasodilatory effects. Dipyridamole is used with other drugs to reduce the risk of blood clots after heart valve replacement. – Explain how inhibition of adenosine uptake contributes to activity of dipyridamole as antiplatelet agents? Clinical uses of Adenosine and drugs that affect adenosine CV – Drug Interactions Drug Interactions: – Adenosine is reported to interact with dipyridamole and concurrent administration requires reduction in dose of adenosine. – From your understanding of their respective mechanisms of action, explain the underlying mechanism for this interaction between adenosine and dipyridamole Clinical uses of Adenosine and drugs that affect adenosine – Respiratory Respiratory system: Methylxanthines e.g. theophylline Block adenosine receptors and used in asthma Also said to inhibit phosphodiesterase – Explain how inhibition of adenosine receptors contributes to activity of theophylline as anti asthma agent? – Which adenosine receptors need to be blocked to produce the above effect in asthmatics? Clinical uses of Adenosine and drugs that affect adenosine - Summary Drug Interactions: methylxanthines e.g. theophylline or caffeine interaction with adenosine – Theophylline and caffeine interact with exogenously administered adenosine. What do you think would be the effect of this interaction between theophylline and adenosine? Adenosine Adverse effects Caution in asthma? Explain the possible underlying mechanism Side effects include bradycardia, hypotension, dyspnoea Adenosine diphosphate (ADP) as mediator ADP usually stored in vesicles and released by exocytosis – Exerts its activity thro P2Y receptors – When released, it exerts its biological effects predominantly through the P2Y family of receptors – Once released can be converted to adenosine by extonucletidases ADP as mediator – Physiological Function Physiological function: ADP and platelets – ADP acts on platelets, causing aggregation How does this differ from effects of adenosine on platelets? – Released when platelets are activated - The secretory vesicles of blood platelets store both ATP and ADP in high concentrations, and release them when the platelets are activated – ADP acts on platelets, causing aggregation – The receptor involved is P2Y12. How does activation of P2Y12 receptors by ADP affect cAMP levels? Clinical uses of drugs that affect ADP - Summary Pharmacological agents – Clopidogrel, It is is a P2Y12 antagonists and exert their anti- aggregating effects through this mechanism. Used for prevention of arterial thromboembolic disorders usually in combination with aspirin Adenosine and related products ATP as a mediator ATP as neurotransmitter ATP in nociception ATP in inflammation ATP AS A MEDIATOR It is present in all cells in millimolar quantities and released when cells are damaged, Release is via number of mechanisms – Exocytosis – ATP transporter – Channels on membrane ATP exerts its action primarily through the P2X receptors primarily but also interact with P2Y receptors. When activated, the receptor gates the cation-selective ion channels that trigger ongoing intracellular signalling The other actions of ATP in mammals are mediated through the P2Y receptors. ATP released from cells is rapidly dephosphorylated by a range of tissue- specific nucleotidases, producing ADP and adenosine, both of which produce a wide variety of receptor mediated effects. The role of intracellular ATP in controlling membrane potassium channels, which is important in the control of vascular smooth muscle and of insulin secretion is quite distinct from its transmitter function

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