187-2017

Idiopathic pulmonary arterial hypertension (PAH) is a progressive and potentially fatal condition; signs and symptoms include dyspnea, chest pain, syncope, cardiac arrhythmias, and right heart failure. Continuous nasal oxygen supplementation is required for most patients and anticoagulants are commonly used. Medical treatments directed at elevated pulmonary vascular resistance have been less successful than those used in ordinary hypertension (see Chapter 11). In addition to the endothelin antagonists mentioned in the text (bosentan, ambrisentan, and macitentan are approved for use in PAH), vasoactive agents that have been promoted for PAH include prostaglandins (epoprostenol, treprostinil, iloprost), nitric oxide, PDE-5 inhibitors (sildenafil, tadalafil), and Ca2+ channel

in cholinergic presynaptic neurons in the central nervous system, and in peripheral peptidergic neurons innervating diverse tissues including the heart, lungs, gastrointestinal and urogenital tracts, skin, eyes, ovaries, and thyroid gland. Many blood vessels are innervated by VIP neurons. VIP is also present in key organs of the immune system including the thymus, spleen, and lymph nodes. Although VIP is present in blood, where it undergoes rapid degradation, it does not appear to function as a hormone. VIP participates in a wide variety of biologic functions including metabolic processes, secretion of endocrine and exocrine glands, cell differentiation, smooth muscle relaxation, and modulation of the immune response.

VIP exerts significant effects on the cardiovascular system. It produces marked vasodilation in most vascular beds and in this regard is more potent on a molar basis than acetylcholine. In the heart, VIP causes coronary vasodilation and exerts positive inotropic and chronotropic effects. It may thus participate in the regulation of coronary blood flow, cardiac contraction, and heart rate.

The effects of VIP are mediated by two G protein-coupled receptors, VPAC1 and VPAC2. Both receptors are widely distributed in the central nervous system and in the heart, blood vessels, and other tissues. VIP has a high affinity for both receptor subtypes. Binding of VIP to its receptors results in activation of adenylyl cyclase and formation of cAMP, which is responsible for the vasodilation and many other effects of the peptide. Other actions may be mediated by inositol trisphosphate synthesis and calcium mobilization. VIP can also bind with low affinity to the VIP-like peptide pituitary adenylyl cyclase-activating peptide receptor, PAC1.

In view of its potent vasodilator action, VIP has potential for the treatment of systemic and pulmonary hypertension and heart failure, but this is limited by its short half-life in the circulation. However, PB1046 (Vasomera), a stable long-acting form of VIP that is selective for VPAC2 receptors, has been developed. Vasomera reduces blood pressure in animal models of hypertension and heart failure and has been shown to be safe and well tolerated after single subcutaneous or intravenous injection in phase 1 studies in patients with essential hypertension.

blockers (nifedipine, amlodipine, diltiazem). Riociguat, a smallmolecule activator of soluble guanylyl cyclase, increases cGMP independently of nitric oxide, reduces pulmonary vascular pressure, and increases exercise duration. Riociguat was approved in the USA in 2013. Selexipag is an oral nonprostanoid prodrug that is rapidly hydrolyzed to the selective prostaglandin I receptor agonist ACT-333679. It has a mechanism of action similar to prostacyclin and was approved in 2015 (see Chapter 18). It is extraordinarily expensive. Fasudil is an investigational selective RhoA/Rho kinase (ROCK) inhibitor that appears to reduce pulmonary artery pressure in PAH. Surgical treatment for advanced disease includes creation of a right atrial to left atrial shunt and lung transplantation.

■ SUBSTANCE P

Substance P belongs to the tachykinin family of peptides, which share the common carboxyl terminal sequence Phe-Gly- Leu-Met. Other members of this family are neurokinin A and neurokinin B. Substance P is an undecapeptide, while neurokinins A and B are decapeptides.

Substance P is widely distributed in the central and peripheral nervous systems and in the cardiovascular system. It is also present in the gastrointestinal tract, where it may play a role as a transmitter in the enteric nervous system and as a local hormone (see Chapter 6).

Substance P is the most important member of the tachykinin family. It exerts a variety of central actions that implicate the peptide in behavior, anxiety, depression, nausea, and emesis. It is present in peripheral afferent pain fibers and participates in nociception. It is a potent arteriolar vasodilator, producing marked hypotension in humans and several animal species. The vasodilation is mediated by release of nitric oxide from the endothelium. Substance P causes contraction of venous, intestinal, and bronchial smooth muscle. It stimulates secretion by the salivary glands and causes diuresis and natriuresis by the kidneys.

The actions of substance P and neurokinins A and B are mediated by three Gq protein-coupled tachykinin receptors designated NK1, NK2, and NK3. Substance P is the preferred ligand for the NK1 receptor. This receptor is widespread throughout the body and is the predominant tachykinin receptor in the human brain. However, neurokinins A and B also possess considerable affinity for this receptor. In humans, most of the central and peripheral effects of substance P are mediated by NK1 receptors. All three receptor subtypes are coupled to inositol trisphosphate synthesis and calcium mobilization.

Several nonpeptide NK1 receptor antagonists have been developed. These compounds are highly selective and orally active, and enter the brain. Recent clinical trials have shown that these antagonists may be useful in treating depression and other disorders and in preventing chemotherapy-induced emesis. The first of these

to be approved for the prevention of chemotherapy-induced and postoperative nausea and vomiting is aprepitant (see Chapter 62). Fosaprepitant is a prodrug that is converted to aprepitant after intravenous administration and may be a useful parenteral alternative to oral aprepitant.

The substance P-NK1 system has also been implicated in cancer. Substance P and NK1 receptors are present in a variety of tumor cells, and NK1 receptor antagonists exert an antitumor action. Thus, drugs such as aprepitant may have potential as anticancer agents.

■ NEUROTENSIN

Neurotensin (NT) is a tridecapeptide that was first isolated from the central nervous system but subsequently was found to be present in the gastrointestinal tract. It is also present in the circulation and in several organs including the heart, lungs, liver, pancreas, and spleen.

NT is synthesized as part of a larger precursor that also contains neuromedin N, a six-amino-acid NT-like peptide. In the brain, processing of the precursor leads primarily to the formation of NT and neuromedin N; these are released together from nerve endings. In the gut, processing leads mainly to the formation of NT and a larger peptide that contains the neuromedin N sequence at the carboxyl terminal. Both peptides are secreted into the circulation after ingestion of food. Most of the activity of NT is mediated by the last six amino acids, NT(8-13).

Like many other neuropeptides, NT serves a dual function as a neurotransmitter or neuromodulator in the central nervous system and as a local hormone in the periphery. When administered centrally, NT exerts potent effects including hypothermia, antinociception, and modulation of dopamine and glutamate neurotransmission. When administered into the peripheral circulation, it causes vasodilation, hypotension, tachycardia, increased vascular permeability, increased secretion of several anterior pituitary hormones, hyperglycemia, inhibition of gastric acid and pepsin secretion, and inhibition of gastric motility. It also exerts effects on the immune system.

In the central nervous system, there are close associations between NT and dopamine systems, and NT may be involved in clinical disorders involving dopamine pathways such as schizophrenia, Parkinson’s disease, and drug abuse. Consistent with this, it has been shown that central administration of NT produces effects in rodents similar to those produced by antipsychotic drugs.

The effects of NT are mediated by three subtypes of NT receptors, designated NTR1, NTR2, and NTR3, also known as NTS1, NTS2, and NTS3. NTR1 and NTR2 receptors belong to the Gq protein-coupled superfamily. NTR1 has a higher affinity for NT than NTR2 and is the major mediator of the diverse effects of NT. The NTR3 receptor is a single-transmembrane protein that is structurally unrelated to NTR1 or NTR2. It belongs to a family of sorting proteins and is therefore known as NTR3/sortilin.

The potential use of NT as an antipsychotic agent has been hampered by its rapid degradation in the circulation and inability

to cross the blood-brain barrier. However, a series of analogs of NT(8-13) that exert antipsychotic-like activity in animal studies has been developed. These agonists include NT69L, which binds with high affinity to NTR1 and NTR2; and NT79, which preferentially binds to NTR2. Another agonist, PD149163, has improved metabolic stability.

In addition to their possible role as antipsychotic drugs, these agonists may be useful in the treatment of pain, psychostimulant abuse, and Parkinson’s disease. Potential adverse effects include hypothermia and hypotension. Development of tolerance to some of the effects of the agonists may occur.

NT receptors can be blocked with the nonpeptide antagonists SR142948A and meclinertant (SR48692). SR142948A is a potent antagonist of the hypothermia and analgesia produced by centrally administered NT. It also blocks the cardiovascular effects of systemic NT.

■ CALCITONIN GENE RELATED PEPTIDE

Calcitonin gene-related peptide (CGRP) is a member of the calcitonin family of peptides, which also includes calcitonin, adrenomedullin, and amylin. CGRP consists of 37 amino acids. In humans, CGRP exists in two forms termed α-CGRP and β-CGRP, which are derived from separate genes and differ by three amino acids but exhibit similar biological activity. Like calcitonin, CGRP is present in large quantities in the C cells of the thyroid gland. It is also distributed widely in the central and peripheral nervous systems, cardiovascular and respiratory systems, and gastrointestinal tract. In the cardiovascular system, CGRP-containing neuronal fibers are more abundant around arteries than around veins and in atria than in ventricles. CGRP fibers are associated with most smooth muscles of the gastrointestinal tract. CGRP is found with substance P (see above) in some of these regions and with acetylcholine in others.

When CGRP is injected into the central nervous system, it produces a variety of effects, including hypertension and suppression of feeding. When injected into the systemic circulation, the peptide causes hypotension and tachycardia. The hypotensive action of CGRP results from the potent vasodilator action of the peptide; indeed, CGRP is the most potent vasodilator yet discovered. It dilates multiple vascular beds, but the coronary circulation is particularly sensitive. The vasodilation is mediated via a nonendothelial mechanism through activation of adenylyl cyclase.

The actions of CGRP are mediated via a single receptor type. This heterodimeric receptor consists of the G protein-coupled calcitonin receptor-like receptor (CLR) combined with the receptor activity-modifying protein RAMP1.

Peptide and nonpeptide antagonists of the CGRP receptor have been developed. CGRP8-37 has been used extensively to investigate the actions of CGRP but displays affinity for other related receptors including those for adrenomedullin (see below). Nonpeptide CGRP receptor antagonists target the interface between CLR and

RAMP1 and thereby make them more selective for the CGRP receptor. Examples are olcegepant and telcagepant.

Evidence is accumulating that release of CGRP from trigeminal nerves plays a central role in the pathophysiology of migraine. The peptide is released during migraine attacks, and successful treatment of migraine with a selective serotonin agonist normalizes cranial CGRP levels. Clinical trials showed olcegepant to be effective in treating migraine, but because of its low bioavailability, it has to be administered by intravenous injection. Telcagepant is also effective and is orally active but has exhibited liver toxicity in a small number of patients.

■ ADRENOMEDULLIN

Adrenomedullin (AM) was first discovered in human adrenal medullary pheochromocytoma tissue. It is a 52-amino-acid peptide with a six-amino-acid ring and a C-terminal amidation sequence. Like CGRP, AM is a member of the calcitonin family of peptides. A related peptide termed adrenomedullin 2, also called intermedin, has been identified in humans and other mammals.

AM is widely distributed in the body. The highest concentrations are found in the adrenal glands, hypothalamus, and anterior pituitary, but high levels are also present in the kidneys, lungs, cardiovascular system, and gastrointestinal tract. AM in plasma apparently originates in the heart and vasculature.

In animals, AM dilates resistance vessels in the kidney, brain, lung, hind limbs, and mesentery, resulting in a marked, long-lasting hypotension. The hypotension in turn causes reflex increases in heart rate and cardiac output. These responses also occur during intravenous infusion of the peptide in healthy human subjects. AM also acts on the kidneys to increase sodium excretion and renin release, and it exerts other endocrine effects including inhibition of aldosterone and insulin secretion. It acts on the central nervous system to increase sympathetic outflow.

The diverse actions of AM are mediated by a receptor closely related to the CGRP receptor (see above). CLR co-assembles with RAMP subtypes 2 and 3, thus forming the AM receptor. Binding of AM to CLR activates Gs and triggers cAMP formation in vascular smooth muscle cells, and increases nitric oxide production in endothelial cells. Other signaling pathways are also involved.

Circulating AM levels increase during intense exercise. They also increase in a number of pathologic states, including essential and pulmonary hypertension, acute myocardial infarction, and cardiac and renal failure. Plasma AM levels are increased in proportion to the severity of these diseases and this can be a useful prognostic marker. The roles of AM in these states remain to be defined, but it is currently thought that the peptide functions as a physiologic antagonist of the actions of vasoconstrictors including ET-1 and ANG II. By virtue of these actions, AM may protect against cardiovascular overload and injury, and AM may be beneficial in the treatment of some cardiovascular diseases.

■ NEUROPEPTIDE Y

The neuropeptide Y family is a multiligand/multireceptor system consisting of three polypeptide agonists that bind and activate four distinct receptors with different affinity and potency. The peptides are pancreatic polypeptide (PP), peptide YY (PYY), and neuropeptide Y (NPY). Each peptide consists of 36 amino acids and has an amidated C-terminus. PP is secreted by the islets of Langerhans after food ingestion in proportion to the caloric content and appears to act mainly in the brainstem and vagus to promote appetite suppression, inhibit gastric emptying, and increase energy expenditure; it also exerts direct actions in the gut. PYY is released by entero-endocrine L cells of the distal gut in proportion to food intake and produces anorexigenic effects.

NPY is one of the most abundant neuropeptides in both the central and peripheral nervous systems. Whereas PYY and PP act as neuroendocrine hormones, NPY acts as a neurotransmitter. In the sympathetic nervous system, NPY is frequently localized in noradrenergic neurons and apparently functions both as a vasoconstrictor and as a cotransmitter with norepinephrine. The remainder of this section focuses on NPY.

NPY produces a variety of central nervous system effects, including increased feeding (it is one of the most potent orexigenic molecules in the brain), hypotension, hypothermia, respiratory depression, and activation of the hypothalamic-pituitary-adrenal axis. Other effects include vasoconstriction of cerebral blood vessels, positive chronotropic and inotropic actions on the heart, and hypertension. The peptide is a potent renal vasoconstrictor and suppresses renin secretion, but can cause diuresis and natriuresis. Prejunctional neuronal actions include inhibition of transmitter release from sympathetic and parasympathetic nerves. Vascular actions include direct vasoconstriction, potentiation of the action of vasoconstrictors, and inhibition of the action of vasodilators. NPY promotes angiogenesis and cardiomyocyte remodeling.

The diverse effects of NPY (and PP and PYY) are mediated by four subtypes of NPY receptors designated Y1, Y2, Y4, and Y5. All are Gi protein-coupled receptors linked to mobilization of Ca2+ and inhibition of adenylyl cyclase. Y1 and Y2 receptors are of major importance in the cardiovascular and other peripheral effects of the peptide. Y4 receptors have a high affinity for pancreatic polypeptide and may be a receptor for the pancreatic peptide rather than for NPY. Y5 receptors are found mainly in the central nervous system and may be involved in the control of food intake. They also mediate the activation of the hypothalamic-pituitary-adrenal axis by NPY.

Some selective nonpeptide NPY receptor antagonists are available for research. The first nonpeptide Y1 receptor antagonist, BIBP3226, is also the most thoroughly studied. It has a short half-life in vivo. In animal models, it blocks the vasoconstrictor and pressor responses to NPY. Structurally related Y1 antagonists include BIB03304 and H409/22; the latter has been tested in humans. SR120107A and SR120819A are orally active Y1 antagonists and have a long duration of action. BIIE0246 is the first nonpeptide antagonist selective for the Y2 receptor; it does not cross the blood-brain barrier. Useful Y4 antagonists are not available. The Y5 antagonists MK-0557 and S-2367 have been tested in clinical trials for obesity.

These drugs have been useful in analyzing the role of NPY in cardiovascular regulation. It now appears that the peptide is not important in the regulation of hemodynamics under normal resting conditions but may be of increased importance in cardiovascular disorders including hypertension and heart failure. Other studies have implicated NPY in eating disorders, obesity, alcoholism, anxiety, depression, epilepsy, pain, cancer, and bone physiology. Y1 and particularly Y5 receptor antagonists have potential as antiobesity agents.

■ UROTENSIN

Urotensin II (UII) was originally identified in fish, but isoforms are now known to be present in the human and other mammalian species. Human UII is an 11-amino-acid peptide. An eight- amino-acid peptide, UII-related peptide (URP), which is almost identical to the C-terminal of UII has also been identified. Major sites of UII expression in humans include the central nervous system, cardiovascular system, lungs, liver, and endocrine glands including the pituitary, pancreas, and adrenal. UII is also present in plasma, and potential sources of this circulating peptide include the heart, lungs, liver, and kidneys. The stimulus to UII release has not been identified, but increased blood pressure has been implicated in some studies.

In vitro, UII is a potent constrictor of vascular smooth muscle; its activity depends on the type of blood vessel and the species from which the vessel was obtained. Vasoconstriction occurs primarily in arterial vessels, where UII can be more potent than ET-1, making it the most potent known vasoconstrictor. However, under some conditions, UII may cause vasodilation. In vivo, UII

has complex hemodynamic effects, the most prominent being regional vasoconstriction and cardiac depression. In some ways, these effects resemble those produced by ET-1. Nevertheless, the role of the peptide in the normal regulation of vascular tone and blood pressure in humans appears to be minor. In addition to its cardiovascular effects, UII exerts osmoregulatory actions, induces collagen and fibronectin accumulation, modulates the inflammatory response, and inhibits glucose-induced insulin release.

The actions of UII are mediated by a Gq protein-coupled receptor referred to as the UT receptor. UT receptors are widely distributed in the brain, spinal cord, heart, vascular smooth muscle, skeletal muscle, and pancreas. They are located at the cell surface, but specific UII-binding sites have also been observed in heart and brain cell nuclei. Some effects of the peptide including vasoconstriction are mediated by the phospholipase C, inositol trisphosphate, diacylglycerol signal transduction pathway.

Although UII appears to play only a minor role in health, evidence is accumulating that it is involved in cardiovascular and other diseases. In particular, it has been reported that plasma UII levels are increased in hypertension, heart failure, atherosclerosis, diabetes mellitus, and renal failure. For this reason, the development of UII receptor antagonists is of considerable interest. Urantide (“urotensin antagonist peptide”) is a penicillaminesubstituted derivative of UII. Palosuran is an orally active nonpeptide antagonist of the UII receptor. It has displayed beneficial effects in animal models of renal failure but not in hypertensive patients with type 2 diabetic nephropathy. More potent UII antagonists are available. GSK1440115 has undergone phase 1 testing for the treatment of asthma but was found to be ineffective. Thus, the role of UII in disease remains to be defined.

P R E P A R A T I O N S

A V A I L A B L E

GENERIC NAME AVAILABLE AS

ANGIOTENSIN CONVERTING ENZYME INHIBITORS

(SEE CHAPTER 11)

ANGIOTENSIN RECEPTOR BLOCKERS

(SEE CHAPTER 11)

RENIN INHIBITOR

Aliskiren Tekturna

KININ INHIBITOR

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General

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C A S E S T U D Y A N S W E R

Enalapril lowers blood pressure by blocking the conversion of angiotensin I to angiotensin II (ANG II). Since converting enzyme also inactivates bradykinin, enalapril increases bradykinin levels, and this is responsible for adverse side effects such as cough and angioedema. This problem might be avoided by using a renin inhibitor, eg,

aliskiren, or an ANG II receptor antagonist, eg, valsartan, instead of an angiotensin-converting enzyme inhibitor, to block the renin-angiotensin system. A β-adrenoceptor- blocking drug might also be tried since, in addition to their cardiac action, these drugs can inhibit renin secretion.

C A S E S T U D Y

A 40-year-old woman presented to her doctor with a 6-month history of increasing shortness of breath. This was associated with poor appetite and ankle swelling. On physical examination, she had elevated jugular venous distention, a soft tricuspid regurgitation murmur, clear lungs, and mild peripheral edema. An echocardiogram revealed tricuspid regurgitation, severely elevated

The eicosanoids are oxygenation (oxidation) products of polyunsaturated 20-carbon long-chain fatty acids (eicosa, Greek for “twenty”). They are ubiquitous in the animal kingdom and are also found—together with their precursors—in a variety of plants. They constitute a very large family of compounds that are highly potent and display an extraordinarily wide spectrum of important biologic activities. Thus, their specific receptors, receptor ligands, and enzyme inhibitors, and their plant and fish oil precursors, are therapeutic targets for a growing list of conditions.

The authors thank Emer M. Smyth, PhD, and Garret A. FitzGerald, MD, for their contributions to previous editions of this chapter.

pulmonary pressures, and right ventricular enlargement. Cardiac catheterization confirmed the severely elevated pulmonary pressures. She was commenced on appropriate therapies. Which of the eicosanoid agonists have been demonstrated to reduce both morbidity and mortality in patients with such a diagnosis? What are the modes of action?

ARACHIDONIC ACID & OTHER POLYUNSATURATED PRECURSORS

Arachidonic acid (AA), or 5,8,11,14-eicosatetraenoic acid, the most abundant of the eicosanoid precursors, is a 20-carbon (C20) fatty acid containing four double bonds (designated C20:4–6). The first double bond in AA occurs at 6 carbons from the methyl end, defining AA as an omega-6 fatty acid. AA must first be released or mobilized from the sn-2 position of membrane phospholipids by one or more lipases of the phospholipase A2 (PLA2) type (Figure 18–1) for eicosanoid synthesis to occur. The phospholipase A2 superfamily consists of 16 groups (over 30 isoforms), with at least three classes of phospholipases contributing to arachidonate release from membrane lipids: (1) cytosolic (c) PLA2,

and (2) secretory (s) PLA2, which are calcium-dependent; and

(3) calcium-independent (i) PLA2. Chemical and physical stimuli activate the Ca2+-dependent translocation of cPLA2, to the plasma membrane, where it releases arachidonate for metabolism to eicosanoids. In contrast, under nonstimulated conditions, AA liberated by iPLA2 is reincorporated into cell membranes, so there is negligible eicosanoid biosynthesis. While cPLA2 dominates in the acute release of AA, inducible sPLA2 contributes under conditions

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of sustained or intense stimulation of AA production. AA can also be released from phospholipase C-generated diacylglycerol esters by the action of diacylglycerol and monoacylglycerol lipases.

Following mobilization, AA is oxygenated by four separate routes: enzymatically via the cyclooxygenase (COX), lipoxygenase, and P450 epoxygenase pathways; and nonenzymatically via the isoeicosanoid pathway (Figure 18–1). Among factors determining the type of eicosanoid synthesized are (1) the substrate lipid species, (2) the cell type, and (3) the cell stimulus. Distinct but related products can be formed from precursors other than AA. For example, an omega-6 fatty acid such as homo-γ-linoleic acid (C20:3–6), in comparison to the omega-3 fatty acid eicosapentaenoic acid (C20:5–3), yields products that differ quantitatively and qualitatively from those derived from AA. This serves as the basis for dietary manipulation of eicosanoid generation using fatty acids obtained from cold-water fish or from plants as nutritional supplements. For example, thromboxane (TXA2), a powerful vasoconstrictor and platelet agonist, is synthesized from AA via the COX pathway. COX metabolism of eicosapentaenoic acid (an omega-3 fatty acid) yields TXA3, which is relatively inactive. 3-Series prostaglandins, such as prostaglandin E3 (PGE3), can also act as partial agonists or antagonists, thereby having reduced activity in comparison to their AA-derived 2-series counterparts. The hypothesis that dietary eicosapentaenoate (omega-3 fatty acid) substitution for arachidonate could reduce the incidence of cardiovascular disease and cancer is an area of intense study.