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Vol. 49, Issue 2, 137-142, June 1997
The Cruciform Project, University College London, London, United Kingdom (S.M., A.H.) and Department of Pharmacology, State University of New York Health Science Center at Brooklyn, Brooklyn, New York (R.F.)
I. Introduction
II. Nitric Oxide Synthases
III. Inhibitors of Nitric Oxide Synthase
IV. Nitric Oxide Donors
V. Recommended Nomenclature and Abbreviations
A. Abbreviations for the Isoenzymes of Nitric Oxide Synthase
B. Abbreviations for Nitric Oxide Synthase Substrates
C. Abbreviations for Inhibitors of Nitric Oxide Synthase
D. Abbreviations for Certain Nitric Oxide Donors
E. Nitrergic Nerves
VI. Conclusion
Acknowledgements
References
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I. Introduction |
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The discovery that the biological actions of endothelium-derived
relaxing factor (Furchgott and Zawadzki, 1980
) are due to the
endogenous release of nitric oxide (NO)c (Palmer et al.,
1987; Ignarro et al., 1987; Khan and Furchgott, 1987) revealed the
existence of a ubiquitous biochemical pathway (Moncada et al., 1989).
NO is formed from the amino acid L-arginine by a family of
enzymes, the NO synthases (NOSs), and plays a role in many
physiological functions. Its formation in vascular endothelial cells,
in response to chemical stimuli and to physical stimuli such as shear
stress, maintains a vasodilator tone that is essential for the
regulation of blood flow and pressure (Moncada et al., 1989; Vanhoutte,
1989; Furchgott, 1990; Ignarro, 1990; Vane et al., 1990; Luscher,
1991). NO produced by the endothelium and/or platelets also inhibits
platelet aggregation and adhesion, inhibits leukocyte adhesion and
modulates smooth muscle cell proliferation (Moncada and Higgs, 1993).
NO is synthesized in neurons of the central nervous system, where it
acts as a neuromediator with many physiological functions, including
the formation of memory, coordination between neuronal activity and
blood flow, and modulation of pain (Garthwaite, 1991; Snyder and Bredt,
1992). In the peripheral nervous system, NO is now known to be the
mediator released by a widespread network of nerves, previously
recognized as nonadrenergic and noncholinergic. These nerves mediate
some forms of neurogenic vasodilation and regulate certain
gastrointestinal, respiratory and genitourinary functions (Gillespie et
al., 1990; Rand, 1992; Toda, 1995). These physiological actions of NO
are mediated by activation of the soluble guanylate cyclase and
consequent increase in the concentration of cyclic guanosine
monophosphate in target cells (Murad et al., 1990; Ignarro, 1991).
In addition, NO is generated in large quantities during host defense
and immunological reactions (Nathan and Hibbs, 1991; Nussler and
Billiar, 1993). Such generation of NO was first observed in activated
macrophages (Hibbs et al., 1988; Marletta et al., 1988; Stuehr et al.,
1989), where it contributes to their cytotoxicity against tumor cells,
bacteria, viruses and other invading microorganisms. The
cytostatic/cytotoxic actions of NO result from its inhibitory actions
on key enzymes in the respiratory chain and in the synthesis of
deoxyribonucleic acid in the target cells (Hibbs et al., 1990; Nguyen
et al., 1992). NO may also interact with oxygen-derived radicals to
produce other toxic substances (Hibbs, 1992) such as peroxynitrite
(Beckman et al., 1990). Peroxynitrite is a powerful oxidant; however,
there seem to be very effective mechanisms for its removal and
inactivation (Moro et al., 1994). Thus, NO plays a role in
immunological host defense and is also involved in the pathogenesis of
conditions such as septic shock and inflammation.
NO is a gas at temperatures down to 
152°C. It is slightly soluble
in many solvents and can diffuse relatively easily across biological
membranes. Its solubility in water is low so that it can only occur in
dilute solution. Nitrite, rather than nitrite plus nitrate, is believed
to be the product of NO in oxygenated water (see Butler et al., 1995;
Williams, 1996). Table 1 shows several chemical species
related to NO.
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II. Nitric Oxide Synthases |
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NOS is a heme-containing enzyme with a sequence similarity to
cytochrome P-450 reductase. Several isoforms of NOS are now known to
exist, two of which are constitutive and one of which is inducible by
immunological stimuli (for reviews see Knowles and Moncada, 1994;
Morris and Billiar, 1994; Nathan and Xie, 1994; Sessa, 1994; Stuehr and
Griffith, 1992). The constitutive NOS (cNOS) that was first discovered
in the vascular endothelium has been designated as eNOS, whereas that
present in the brain, spinal cord and peripheral nervous system is
termed nNOS. The form of NOS induced by immunological or inflammatory
stimuli is known as iNOS. A comparison of the properties of these three
major isoforms of the enzyme is shown in table 2.
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The complementary deoxyribonucleic acids for all three of these
isoforms have been cloned from several species, including humans
(Charles et al., 1993; Geller et al., 1993; Marsden et al., 1992;
Nakane et al., 1993). This has revealed further differences among them,
which are shown in table 3. Knockout mice have been generated for each of the three NOS isoforms and have provided useful
information concerning the role of each isoform and the effects of its
deletion in whole animals (Huang and Fishman, 1996).
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The apparent association of the three NOS isoenzymes with the
endothelium, neurons and inducibility (table 2) is an
oversimplification. For example, eNOS is located not only in the
vascular endothelial cells but also in platelets (Radomski et al.,
1990) and in certain neuronal populations in the brain (Dinerman et
al., 1994), whereas nNOS has been found in the epithelium of the
bronchi and trachea (Kobzik et al., 1993), as well as in skeletal
muscle (Kobzik et al., 1994). Furthermore, some differences have been
identified between iNOSs obtained from different tissues within the
same species (Mohaupt et al., 1994). In addition, the constitutive eNOS
can be induced in certain situations such as during chronic exercise
(Sessa et al., 1994) or during pregnancy, when both eNOS and iNOS are
induced (Weiner et al., 1994), whereas iNOS appears to be present
constitutively in some tissues, including human bronchial epithelium
(Kobzik et al., 1993), rat kidney (Mohaupt et al., 1994) and some fetal
tissues (Baylis et al., 1994).
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III. Inhibitors of Nitric Oxide Synthase |
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The generation of NO from L-arginine proceeds via
the formation of N
-hydroxy-L-arginine
(Pufahl et al., 1992). This L-arginine/NO pathway can be
inhibited by several analogues of L-arginine, of which the
first to be identified was
N-monomethyl-L-arginine (see Moncada and
Higgs, 1993). Before the discovery of NO as a biological mediator,
N-monomethyl-L-arginine had been found to
prevent L-arginine-dependent cytotoxicity in murine
macrophages (see Hibbs et al., 1990). It has subsequently been shown to
be a competitive inhibitor of the formation of NO in the vasculature
and elsewhere (see Moncada et al., 1989), and, as such, it has become a
valuable tool for unraveling the biological actions of NO.
Many other analogues of L-arginine are now known to act as
competitive (and in some cases, irreversible) inhibitors of both the
constitutive and the inducible NOS. Other non-amino acid compounds that
mimic the guanidinium moiety of L-arginine also inhibit the enzyme. Some inhibitors of NOS are shown in figure 1.
Interestingly, asymmetric dimethyl-L-arginine
(NG-NG-dimethyl-L-arginine,
L-ADMA), an inhibitor of NOS, and
N-monomethyl-L-arginine are
present in human plasma and urine (Vallance et al., 1992). Accumulation
of these compounds in the plasma may contribute to the pathophysiology
of some conditions.
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There are several clinical situations in which it may be desirable to
inhibit the production of NO, either by a constitutive NOS (for
example, in cerebral ischemia or epilepsy, in which overproduction of
NO by nNOS may lead to neurotoxicity) or by iNOS in conditions such as
septic shock or certain chronic inflammatory diseases. Although much
effort is being put into the search for a selective inhibitor of iNOS
and some of the known inhibitors have shown some degree of selectivity
in vitro toward one or another NOS isoform (fig. 1), thus far, the
drugs available affect both the inducible and the constitutive isoforms
(for review, see Griffith and Gross, 1996).
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IV. Nitric Oxide Donors |
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The clinical actions of the nitrovasodilators are now known to
result from their ability to liberate NO (Feelisch, 1991); thus, the
term "NO donors" has been adopted for this class of drug. Such
compounds include the organic nitrates (e.g., glyceryl trinitrate) and
nitrites (e.g., amyl nitrite), inorganic nitroso compounds (e.g.,
sodium nitroprusside), sydnonimines (e.g., molsidomine) and
S-nitrosothiols (e.g., S-nitrosoglutathione) (Feelisch and Stamler,
1996 and table 4).
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Although NO donors have been used traditionally as vasodilators, other
clinical applications are emerging as our understanding of the
biological actions of NO itself increases. Thus, compounds such as
S-nitrosoglutathione, which potently inhibits platelet aggregation at
concentrations that do not affect blood pressure (de Belder et al.,
1995), may be useful in the treatment of certain thrombotic disorders.
Other NO donors have been shown to reduce intimal thickening in injured
arteries in an animal model (Lefer and Lefer, 1994). Impaired
generation of NO by nitrergic nerves, i.e., those that liberate NO as a
neuromodulator, may underlie certain gastrointestinal, genitourinary
and respiratory disorders. In such cases, NO donors may mimic nitrergic
nerve-mediated responses and have been shown to be effective in the
treatment of achalasia and other malfunctions of sphincters in the
gastrointestinal tract, as well as in the treatment of impotence in
diabetes (see Moncada and Higgs, 1995).
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V. Recommended Nomenclature and Abbreviations |
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In the research literature of the past few years regarding the biological actions of NO, several different names or abbreviations have been used by investigators to identify the same enzyme or the same substance. To avoid confusion arising from nonuniform nomenclature and abbreviations, the following recommendations are made (see sections V.A to V.E.). These reflect current usage and, as such, contain anomalies. In the future, new compounds will be named and abbreviated with greater consistency.
A. Abbreviations for the Isoenzymes of Nitric Oxide Synthase
The abbreviations for the isoenzymes of the NOS are:
B. Abbreviations for Nitric Oxide Synthase Substrates
The recommended abbreviations for NOS substrates are as follows:
-hydroxy-L-arginine: L-OHArg.
C. Abbreviations for Inhibitors of Nitric Oxide Synthase
The recommended abbreviations for inhibitors of NOS are as follows:
-monomethyl-L-arginine:
L-NMMA;
-nitro-L-arginine: L-NA;
-nitro-L-arginine methyl ester:
L-NAME;
-amino-L-arginine: L-NAA;
-N-dimethyl-L-arginine:
L-ADMA;
-N'-dimethyl-L-arginine:
L-SDMA;
Other compounds have recently been described as inhibitors of NOS
but are not in common use. These include the isothioureas (Garvey et
al., 1994; Southan et al., 1995) and L-thiocitrulline (Frey
et al., 1994).
D. Abbreviations for Certain Nitric Oxide Donors
The recommended abbreviation for certain NO donors are shown in table 4.
E. Nitrergic Nerves
The term `nitrergic' should be applied to nerves whose transmitter function depends on the release of NO or to transmission mechanisms that are brought about by NO.
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VI. Conclusion |
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Since the identification in 1987 of NO as a biological mediator, more than 14,000 papers have been published in this field. Some basic guidelines for standardization of terminology have been given in this short document. As the amount of work in this area continues to grow, it will be necessary to update and expand these recommendations.
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Acknowledgements |
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The authors thank Timothy R. Billiar, Ian G. Charles, Richard G. Knowles and David J. Madge for their assistance in the preparation of this manuscript.
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Footnotes |
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a Composition of the nitric oxide research subcommittee of the International Union of Pharmacology Committee on Receptor Nomenclature and Drug Classification: M. Feelisch, Department of Nitric Oxide Research, Schwarz Pharma AG, Monheim, Germany; R. Furchgott, State University of New York Health Science Center at Brooklyn, Department of Pharmacology, Brooklyn, New York; J. Garthwaite, The Cruciform Project, University College London, London, United Kingdom; J.B. Hibbs, Jr., Veterans Affairs Medical Center and Department of Medicine, Division of Infectious Diseases, University of Utah Medical Center, Salt Lake City, Utah; A. Higgs, The Cruciform Project, University College London, London, United Kingdom; L. Ignarro, University of California, Los Angeles School of Medicine, Department of Molecular Biology, Los Angeles, California; T. Luscher, Division of Cardiology, University Hospital Bern, Bern, Switzerland; M.A. Marletta, College of Pharmacy, School of Medicine, University of Michigan, Ann Arbor, Michigan; W. Martin, University of Glasgow, Clinical Research Initiative, Glasgow, Scotland; S. Moncada, The Cruciform Project, University College London, London, United Kingdom; M. Rand, Royal Melbourne Institute of Technology, Department of Medical Laboratory Science, Melbourne, Australia; M. Spedding, Institut de Recherches Servier, Centre de Recherches de Croissy, Croissy sur Seine, France; S. Snyder, Department of Neuroscience, Johns Hopkins University School of Medicine, Baltimore, Maryland; N. Toda, Department of Pharmacology, Shiga University of Medical Sciences, Seta, Japan; J.R. Vane, The William Harvey Research Institute, St. Bartholomew's Hospital Medical College, London, United Kingdom; P. Vanhoutte, Institut de Recherches International Servier, Courbevoie, France.
b Address correspondence to: Salvador Moncada, The Cruciform Project, University College London, 140 Tottenham Court Road, London W1P 9LN, United Kingdom.
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Abbreviations |
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NO, nitric oxide; NOS, NO synthase.
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References |
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0031-6997/97/4902-0137$03.00/0
PHARMACOLOGICAL REVIEWS
Copyright © 1997 by The American Society for Pharmacology and Experimental Therapeutics
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