Carta Acesso aberto Revisado por pares

Nitric Oxide and Viral Cardiomyopathy

2000; Lippincott Williams & Wilkins; Volume: 102; Issue: 18 Linguagem: Inglês

10.1161/01.cir.102.18.2162

ISSN

1524-4539

Autores

Mitchell S. Finkel,

Tópico(s)

Cardiomyopathy and Myosin Studies

Resumo

HomeCirculationVol. 102, No. 18Nitric Oxide and Viral Cardiomyopathy Free AccessEditorialPDF/EPUBAboutView PDFView EPUBSections ToolsAdd to favoritesDownload citationsTrack citationsPermissions ShareShare onFacebookTwitterLinked InMendeleyReddit Jump toFree AccessEditorialPDF/EPUBNitric Oxide and Viral Cardiomyopathy Mitchell S. Finkel Mitchell S. FinkelMitchell S. Finkel From the West Virginia University School of Medicine, WVU Cardiology, Morgantown, WVa, and Louis A. Johnson VA Medical Center, Clarksburg, WVa. Originally published31 Oct 2000https://doi.org/10.1161/01.CIR.102.18.2162Circulation. 2000;102:2162–2164The report by Badorff et al1 in this issue of Circulation provides an opportunity to reflect on the enormous impact that the discovery of nitric oxide (NO) has already had in furthering our understanding of the basic biology of human disease processes. This report also helps to illustrate how basic insights coupled with clinical observations will ultimately lead to redefining previously unrelated clinical conditions along more pathophysiologically relevant lines.The 1998 Nobel Prize for Medicine or Physiology was awarded to Louis J. Ignarro, Ferid Murad, and Robert Furchgott for the discovery of the role of NO as a signaling molecule in the cardiovascular system.2 Ignarro studied the mechanism of action of nitroglycerin, which was first synthesized by Sobrero more than 150 years ago, and discovered that it mediates its effects through NO. Murad discovered that NO mediates effects through that "other," less appreciated (ie, not cAMP), cyclic nucleotide, cGMP. Furchgott's simple experiments with rabbit aortas provided physiological relevance by revealing that vascular endothelium normally produces a relaxing factor, endothelium-derived relaxing factor, which Ignarro showed to be NO. Shortly thereafter, inhibitors were identified, enzyme proteins isolated, and NO synthases (NOS) successively cloned from neurons (type 1), macrophages (type 2), and endothelial cells (type 3).3 It was clear from the beginning that the constitutive, basal production of small quantities of NO by NOS types 1 and 3 played a critical role in normal physiological processes. What has been less obvious, however, is the benefits conferred by the production of much larger quantities of NO by NOS 2 in response to cytokines.Sepsis has served as the paradigm for cytokine-induced expression of NO.3 Much unsuccessful effort has been invested in regulating the presumed exclusively deleterious effects of cytokine-induced NO production in sepsis. This view of cytokine-induced NO production appears to be too simplistic and avoids a truly important fundamental question: What is the biological advantage to cytokine-induced NO production? Is cytokine-induced NO simply the evil twin of constitutive NO? Evidence has already been provided that cytokine-induced NO production by so-called inducible NO synthase (iNOS) plays an important role in the normal host response to infection.3 This report by Badorff et al helps to shed some additional light on these important questions by providing a potential molecular mechanism for a protective role for NO in viral infection. The authors previously demonstrated that coxsackievirus B3 (CVB3) possesses a protease (2A) that cleaves an integral membrane glycoprotein, dystrophin, in human and mouse cardiac membranes.4 In the present article, they provide evidence that NO donors can S-nitrosylate a cysteine residue that is essential for catalytic activity of protease 2A. Thus, the elaboration of NO by cardiac myocytes may prevent dystrophin cleavage by inactivating viral protease 2A. These data help to explain previous reports that NO inhibits CVB3 replication in vitro and the augmentation of CVB3 infection in iNOS-deficient mice.4 More definitive conclusions must await the demonstration of the same mechanism in human cardiomyopathy specimens and ex vivo experiments in animal models infected with CVB.This report should have an immediate impact on the way we view viral cardiomyopathy, as well as other causes of heart failure. The rationale for exploring the effects of NO on dystrophin cleavage evolved from previous work by others demonstrating the presence of a dystrophin defect in genetic cardiomyopathy.4 This illustrates the potential for evoking the same molecular mechanism for an acquired as for a genetic defect. A genetic defect in dystrophin alone is sufficient to result in development of a rare cardiomyopathy. A virally acquired defect in a susceptible dystrophin isoform may also be sufficient to develop a relatively more common cardiomyopathy. Yet, both of these are relatively uncommon diseases. Badorff and colleagues provide evidence that cytokine-induced elaboration of NO may have evolved as an important adaptive mechanism in preventing the development of dilated cardiomyopathy after exposure to CVB3. This would further suggest that defects in this NO-mediated host response to viral infection could also contribute to some of the variability in the natural history of idiopathic cardiomyopathy. Too little NO could allow greater viral invasion. Too much NO in response to norepinephrine and/or angiotensin II could depress mitochondrial activity and lead to apoptosis.5The implications of this study extend beyond CVB3-induced cardiomyopathy to more common clinical problems. The cytokine and NO host response to infection appears to share important features with the host response to other injuries, including ischemia. Historically, and until only recently, the reversible myocardial depression and β-adrenergic desensitization seen experimentally and clinically in ischemia (eg, "stunned myocardium") were viewed as unrelated to a similar phenomenon that occurs in sepsis. Basic and clinical investigators and clinicians interested in the effects of ischemia on myocardial function had little interaction with their colleagues who studied the effects of infection and immunity in other systems. However, an interdisciplinary approach that recognized the heart as a target of immune modulation was applied to understand the reversible myocardial depression and β-adrenergic desensitization described in septic patients.6 The so-called "proinflammatory" cytokines were identified as potential endogenous mediators of myocardial depression in these patients.6 These cytokines were subsequently demonstrated to directly and reversibly depress myocardial contractility within minutes and over hours through NO-dependent and independent mechanisms in animal models in vitro.57 Data supporting a myocardial depressant effect of cytokine-induced NO production in patients with sepsis have also been reported.8 It is now clear that cytokines and NO are elaborated locally and systemically during a variety of stresses, including ischemia and infection.35 This has led to the proposal that cytokines and NO are common mediators of reversible myocardial depression and β-adrenergic desensitization in such disparate clinical and experimental conditions as Sepsis, Trauma, Ischemia, Transplant rejection, myoCarditis, and Heart failure ("STITCH syndrome").5 This report by Badorff et al may provide a rationale in support of the hypothesis that cytokines and NO are mediators of the myocardial response to ischemia and infection. This brings us to the next question: Just how similar are the molecular mechanisms involved in the host responses to ischemia and infection? An answer to this question may be provided from insights derived from elegant parallel studies into the mechanisms responsible for lipopolysaccharide (LPS) tolerance and ischemic preconditioning.Murry et al9 described "ischemic preconditioning" as the phenomenon of myocardial protection that occurs after brief periods of ischemia with intermittent reperfusion. From the results of clinical trials, astute clinicians appreciated that patients who presented with a stuttering course of intermittent chest pain before their myocardial infarction fared better than those who did not.10 It is reasonable to infer that patients with recurrent, brief episodes of chest pain before a myocardial infarction are undergoing the clinical correlate of the experimental condition involving brief periods of coronary ligation followed by complete occlusion, ie, ischemic preconditioning. This potentially clinically relevant protective effect has been reproduced and studied in a variety of animal models as an unprecedented and unique means of myocardial protection from subsequent ischemia.11121314151617 The molecular mechanisms responsible for the early and delayed protective effects are not fully understood. The early benefits that occur within minutes appear to be related to adenosine-mediated potassium channel regulation.11 Presumably, the opening of ATP-sensitive potassium channels (KATP) causes a repolarizing current that reduces the duration of the cardiac action potential, which results in reduction in calcium entry and thereby, myocardial injury.11Experimental data suggest that activation of protein kinase C (PKC) via an inhibitory GTP regulatory protein (Gi protein) might be a crucial step in the mediation of late preconditioning that occurs over hours.12 This is supported by studies that show that activation of PKC elicits protection against ischemia, whereas inhibition of PKC activation results in the loss of the late/delayed protection conferred by preconditioning.12 PKC-induced preconditioning could be due to the phosphorylation of other proteins, such as the mitogen-activated protein kinase cascade, and the subsequent phosphorylation of gene transcription factors.12 More recently, Ping et al13 reported that the NO donor SNAP induces preconditioning via activation of PKC in the rabbit heart. NO donors have also been shown to induce late preconditioning by generation of the oxidant species ONOO– and/or · OH.14Pretreatments with LPS and with monophosphoryl lipid A (MLA; a nontoxic analogue of endotoxin) have each been reported to induce a cardioprotective effect against subsequent ischemia.15 Of particular interest to this discussion, NO appears to play an important role in LPS- and MLA-induced cardioprotection. Cytokines are well known to induce NO production after LPS exposure in vivo.358 The sources of cytokines have been attributed largely to noncardiac origins. Growing evidence now suggests that the heart itself is also a cytokine-producing organ.3817 Thus, LPS and/or ischemia can each trigger a cytokine-mediated response to injury by cardiac myocytes or other resident intramyocardial cells to produce NO to protect the heart from subsequent potential insults such as ischemia or reinfection. It is interesting to note that both tumor necrosis factor-α and interleukin-1β have been identified in postischemic, reperfused myocardium.17 These same cytokines can stimulate NO production by cardiac myocytes.358 Taken together, these clinical and experimental studies raise the intriguing possibility that ischemic preconditioning and LPS tolerance share common molecular mechanisms involving cytokines and NO.A role for NO in the programmed host response to a variety of injuries conforms with the principles of simplicity and redundancy in evolutionary biology. The host responses to infection and ischemia are clearly essential for survival. The adaptations to these stresses would be expected to share common phenotypic features and signaling pathways. Elucidating the molecular mechanisms that regulate these responses has the potential to enhance our basic understanding and management of patients with seemingly unrelated cardiac conditions. Considerably more work needs to done before we can draw definitive and clinically applicable conclusions. However, the report by Badorff et al in this issue of Circulation does help us to appreciate that "big" NO is not "little" NO's evil twin.The opinions expressed in this editorial are not necessarily those of the editors or of the American Heart Association.FootnotesCorrespondence to Mitchell S. Finkel, MD, Department of Medicine, West Virginia University School of Medicine, Medical Center Dr, PO Box 9157, Morgantown, WV 26506-9157. E-mail [email protected] References 1 Badorff C, Fichtlscherer B, Rhoads RE, et al. Nitric oxide inhibits dystrophin proteolysis by coxsackieviral protease 2a through S-nitrosylation: a protective mechanism against enteroviral cardiomyopathy. Circulation.2000; 102:2276–2281.CrossrefMedlineGoogle Scholar2 Mitka M. Nobel prize winners are announced: three discoverers of nitric oxide activity. JAMA.1998; 280:1648.CrossrefMedlineGoogle Scholar3 Lowenstein CJ, Dinerman JL, Snyder SH. Nitric oxide: a physiologic messenger. Ann Intern Med.1994; 120:227–237.CrossrefMedlineGoogle Scholar4 Badorff C, Berkley N, Mehrotra S, et al. Enteroviral protease 2A directly cleaves dystrophin and is inhibited by a dystrophin-based substrate analogue. J Biol Chem. In press.Google Scholar5 Finkel MS. Effects of proinflammatory cytokines on the contractility of mammalian heart. Heart Failure Rev.1996; 1:203–210.CrossrefGoogle Scholar6 Parker MM, Shelhamer JH, Bacharach SL, et al. Profound but reversible myocardial depression in patients with septic shock. Ann Intern Med.1984; 100:483–490.CrossrefMedlineGoogle Scholar7 Finkel MS, Oddis CV, Jacob TD, et al. Negative inotropic effects of cytokines on the heart mediated by nitric oxide. Science.1992; 257:387–389.CrossrefMedlineGoogle Scholar8 Kumar A, Brar R, Wang P, et al. Role of nitric oxide and cGMP in human septic serum-induced depression of cardiac myocyte contractility. Am J Physiol.1999; 276:R265–R276.CrossrefMedlineGoogle Scholar9 Murry CE, Jennings RB, Reimer KA. Preconditioning with ischemia a delay of cell injury in ischemic myocardium. Circulation.1986; 74:1124–1136.CrossrefMedlineGoogle Scholar10 Kloner RA, Shook T, Przyklenk K, et al. Previous angina alters in-hospital outcome in TIMI-4: a clinical correlate to preconditioning? Circulation.1995; 91:37–47.CrossrefMedlineGoogle Scholar11 Parratt JR, Kane KA. KATP channels in ischaemic preconditioning. Cardiovasc Res.1994; 28:783–787.CrossrefMedlineGoogle Scholar12 Baines CP, Wang L, Cohen MV, et al. Protein tyrosine kinase is downstream of protein kinase C for ischemic preconditioning's anti-infarct effect in the rabbit heart. J Mol Cell Cardiol.1998; 30:383–392.CrossrefMedlineGoogle Scholar13 Ping P, Takano H, Zhang J, et al. Isoform-selective activation of protein kinase C by nitric oxide in the heart of conscious rabbits: a signaling mechanism for both nitric oxide–induced and ischemia-induced preconditioning. Circ Res.1999; 84:587–604.CrossrefMedlineGoogle Scholar14 Takano H, Tang XL, Qiu Y. Nitric oxide donors induce late preconditioning against myocardial stunning and infarction in conscious rabbits via an antioxidant-sensitive mechanism. Circ Res.1998; 83:73–84.CrossrefMedlineGoogle Scholar15 Brown JM, Grosso MA, Terada LS. Endotoxin pretreatment increases endogenous myocardial catalase activity and decreases ischemia reperfusion injury of isolated rat hearts. Proc Natl Acad Sci U S A.1989; 86:2516–2520.CrossrefMedlineGoogle Scholar16 Xi L, Jarrett NC, Hess ML, et al. Essential role of inducible nitric oxide synthase in monophosphoryl lipid A–induced late cardioprotection: evidence from pharmacological inhibition and gene knockout mice. Circulation.1999; 99:2157–2163.CrossrefMedlineGoogle Scholar17 Herskowitz A, Choi S, Ansari AA, et al. Cytokine mRNA expression in postischemic/reperfused myocardium. Am J Pathol.1995; 146:419–428.MedlineGoogle Scholar eLetters(0)eLetters should relate to an article recently published in the journal and are not a forum for providing unpublished data. Comments are reviewed for appropriate use of tone and language. Comments are not peer-reviewed. Acceptable comments are posted to the journal website only. Comments are not published in an issue and are not indexed in PubMed. Comments should be no longer than 500 words and will only be posted online. References are limited to 10. Authors of the article cited in the comment will be invited to reply, as appropriate.Comments and feedback on AHA/ASA Scientific Statements and Guidelines should be directed to the AHA/ASA Manuscript Oversight Committee via its Correspondence page.Sign In to Submit a Response to This Article Previous Back to top Next FiguresReferencesRelatedDetailsCited By Vanin A (2020) Dinitrosyl Iron Complexes with Thiol-Containing Ligands Can Suppress Viral Infections as Donors of the Nitrosonium Cation (Hypothesis), Biophysics, 10.1134/S0006350920040260, 65:4, (698-702), Online publication date: 1-Jul-2020. Herrmann J, Lerman L and Lerman A (2010) Simply say yes to NO? Nitric oxide (NO) sensor-based assessment of coronary endothelial function, European Heart Journal, 10.1093/eurheartj/ehq279, 31:23, (2834-2836), Online publication date: 1-Dec-2010. Glück B, Dahlke K, Zell R, Krumbholz A, Decker M, Lehmann J and Wutzler P (2010) Cardioprotective effect of NO-metoprolol in murine coxsackievirus B3-induced myocarditis, Journal of Medical Virology, 10.1002/jmv.21928, 82:12, (2043-2052), Online publication date: 1-Dec-2010. Kan H and Finkel M (2003) Inflammatory mediators and reversible myocardial dysfunction, Journal of Cellular Physiology, 10.1002/jcp.10213, 195:1, (1-11), Online publication date: 1-Apr-2003. Chandra M, Tanowitz H, Petkova S, Huang H, Weiss L, Wittner M, Factor S, Shtutin V, Jelicks L, Chan J and Shirani J (2002) Significance of inducible nitric oxide synthase in acute myocarditis caused by Trypanosoma cruzi (Tulahuen strain), International Journal for Parasitology, 10.1016/S0020-7519(02)00028-0, 32:7, (897-905), Online publication date: 1-Jun-2002. Mirza H, Finkel M and Johnson L (2002) Inflammatory mediators in congenital heart disease *, Critical Care Medicine, 10.1097/00003246-200204000-00045, 30:4, (941-942), Online publication date: 1-Apr-2002. Finkel M (2002) Source of inflammatory mediators in cardiopulmonary bypass, Critical Care Medicine, 10.1097/00003246-200201000-00039, 30:1, (249-251), Online publication date: 1-Jan-2002. Dembo D (2001) Nitric oxide and cardiopulmonary resuscitation, Critical Care Medicine, 10.1097/00003246-200103000-00041, 29:3, (672-673), Online publication date: 1-Mar-2001. October 31, 2000Vol 102, Issue 18 Advertisement Article InformationMetrics Copyright © 2000 by American Heart Associationhttps://doi.org/10.1161/01.CIR.102.18.2162 Originally publishedOctober 31, 2000 KeywordsEditorialsheart failureischemiainfectionPDF download Advertisement

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