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From the Department of Urology, The James Buchanan Brady Urological Institute, Johns Hopkins Hospital, Baltimore, Maryland.
| Correspondence to: Dr Arthur L. Burnett, Department of Urology, Marburg 407, Johns Hopkins Hospital, 600 N Wolfe St, Baltimore, MD 21287 (e-mail: aburnett{at}jhmi.edu). |
| Received for publication May 6, 2002; accepted for publication May 13, 2002. |
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At the same time, this premier signal transduction mechanism has been exploited for therapeutic purposes, specifically in the clinical management of erectile dysfunction. Discoveries pertaining to the field of NO biology in the penis have, in recent years, been rapidly translated into the clinical development of the first orally effective pharmacotherapy for erectile dysfunction, sildenafil citrate (Viagra) (Goldstein et al, 1998). This medication and other similarly acting agents, either currently awaiting governmental regulatory agency approval for clinical distribution or undergoing scientific investigation (Noto et al, 2000; Oh et al, 2000; Hosogai et al, 2001; Padma-Nathan et al, 2001; Porst et al, 2001), describe a class of phosphodiesterase-5 (PDE-5) inhibitors that uniquely interact with the biochemical processing of NO to boost the erectile signal (Boolell et al, 1996; Turko et al, 1999). It is apparent that various mechanistic opportunities related to NO signaling and processing in erectile tissue will be promoted as eventual pharmacotherapeutic strategies in the treatment of erectile dysfunction. Such expectations for promising treatment modalities based on the science of NO in the penis would imply continued optimism for the future management of erectile dysfunction.
NO-Dependent Signal Transduction
While NO may operate in several ways to direct the relaxation of corporal
smooth muscle in the penis, it is best characterized as initiating a prominent
biochemical mechanism of action for penile erection. Its key role involves
signal transduction (defined as the intracellular or transcellular delivery
mechanism in which an initially released chemical signal is transmitted and
amplified by a second-messenger molecule)
(Figure 1). According to this
mechanism, NO is constitutively produced and released from autonomic nerve
terminals and endothelial cells in the corporal tissue, diffuses locally into
adjacent smooth muscle cells, and binds with intracellular guanylate cyclase,
which serves as a physiologic "receptor" for the molecule
(Burnett, 1995,
1997). This binding induces a
conformational change of guanylate cyclase, activating the enzyme so that it
catalyzes the conversion of guanosine triphosphate (GTP) to cGMP. cGMP then
operates through a cGMP-dependent protein kinase to regulate the contractile
state of the corporal smooth muscle
(Hedlund et al, 2000a). Among
possible mechanisms for the downstream activities of cGMP, this molecule may
direct phosphorylation changes of myosin light chain cross-bridging, control
calcium and potassium ion fluxes and stores, interact with other signal
transduction mechanisms, and otherwise exert effects on cellular contractile
proteins independent of phosphorylation biochemistry
(Burnett, 1995;
Chuang et al, 1998). Recent
experimental studies further suggest that cGMP inhibits the presynaptic
release and contractile effects of the adrenergic contractile
neurotransmitter, norepinephrine (Minhas
et al, 2000).
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NO-associated relaxatory effects in corporal smooth muscle, independent of cGMP action, have also been described. This agent stimulates Na+/K+-ATP, resulting in direct hyperpolarization of the corporal smooth muscle cell, which prevents the opening of voltage-dependent calcium channels and thereby attenuates tissue contraction (Gupta et al, 1995). NO may also influence a potassium conductance pathway within corporal smooth muscle cells, resulting in hyperpolarization (Seftel et al, 1996; Lee and Kang, 2001).
NO Biology in the Penis
Classic Concepts—
Traditional understanding of the action of NO in the penis invokes the
constitutive formation of this molecule under normal physiologic conditions
with the expression and activities of the enzyme sources localized to neural
and endothelial components of the corporal tissue. The verification that NO
derives from the autonomic innervation supplying the penis has directly
supported the description of this molecule as a peripheral neurotransmitter of
nonadrenergic, noncholinergic-mediated penile erection
(Kim et al, 1991;
Burnett et al, 1992; Rajfer et al, 1992). The
confirmation that the molecule also is produced within the vascular and
trabecular endothelium comprising the penile vascular supply has offered
additional support for the role of NO serving as an endothelial relaxation
factor of penile erection (Kimoto et al,
1990; Knispel et al,
1991; Azadzoi et al,
1992; Hedlund et al,
2000b).
The catalytic production of NO requires NO synthase (NOS), expressed in many biological tissues as 3 main isoforms: neuronal NOS (nNOS or NOS I), inducible NOS (iNOS or NOS II), and endothelial NOS (eNOS or NOS III) (Forstermann et al, 1998). Both nNOS and eNOS, which do pertain to the original cellular sites of their identifications, are constitutive isoforms requiring calcium-binding protein calmodulin, oxygen, and reduced NADPH for catalytic activity. These isoforms generate NO transiently and in low amounts, appropriate for cell-cell signaling, after a rise in intracellular calcium and calcium-calmodulin binding. The iNOS isoform, which primarily is expressed in immune tissue and involves alternative calcium-independent mechanisms, is not perceived to be involved in normal penile erection.
In the science of NO related to penile erection, primary attention has thus far been given to the neuronal source of NO, whereas the endothelial source has been relegated to secondary importance as an auxiliary basis for producing NO for erectile function. The liberation of NO into the erectile tissue from nNOS requires neuronal depolarization resulting from electrical impulses transmitted neurally in response to psychogenic and reflexive erogenous stimuli that converge upon nNOS-containing efferent nerve fibers coursing within the corporal bodies. Facilitation of the neuronal release of NO in the penis may involve neuroactive amino acids such as glutamate and neuropeptides such as vasoactive intestinal peptide (Burnett, 1997). The intracorporal delivery of NO from eNOS has been perceived to involve mainly neurogenic stimuli that are transmitted through efferent nerves coursing within the erectile tissue that directly make contact with the endothelium. Acetylcholine, as well as other neurotransmitters such as substance P and bradykinin, is best characterized as stimulating NO release from endothelial sources in the penis (Kimoto et al, 1990; Knispel et al, 1991; Azadzoi et al, 1992; Hedlund et al, 2000b; Burnett et al, 2002). These neurotransmitters exert their effects by inducing a transient increase of calcium entry into endothelial cells, which briefly stimulates NO production by eNOS. Acute increases in "shear stress," the term used to describe pressure forces exerted on endothelial cells by the flow of blood over them, act to drive rapid but limited amounts of NO release by similar biochemical mechanisms (Burnett, 1997; Busse and Fleming, 1998).
Consistent with current notions that the constitutive NOS isoforms critically mediate penile erection, scientific findings have shown that pathologic disease processes associated with erectile dysfunction manifest decreased expression and/or activity of these enzymes (Burnett, 1997; Champion et al, 1999; Gonzalez-Cadavid and Rajfer, 2000; Akingba and Burnett, 2001).
Novel Concepts— The supposition that diverse mechanisms operate in the penis exerting precise regulatory control of NO release is entirely reasonable. Commonly accepted modulators of NO effects in the penis conceivably include neurotransmitters, hormones, paracrine factors, and autocrine substances derived from the erectile tissue itself, besides exogenously administered agents. More recent considerations have extended to molecular mechanisms involved in the gene expression of the enzymes responsible for NO synthesis, which may actually adhere to a genitourinary-specific manner of control (Gonzalez-Cadavid et al, 2000). Further interest has centered on the roles of NOS-associated proteins, which could influence the intracellular transmission of the NO signal (Busse and Fleming, 1998; Gonzalez-Cadavid and Rajfer, 2000). Other areas that have generated great interest in yielding potential therapeutic approaches for erectile dysfunction include gene transfer and application of trophic effectors designed to augment NO biosynthesis in the penis (Garban et al, 1997; Champion et al, 1999; Bakircioglu et al, 2001).
A new direction in studying the biology of NO has determined that constitutive eNOS regulation can occur independent of transient calcium influx, as occurs with acute increases in shear stress or by acetylcholine stimulation, thereby permitting NO release in a sustained manner (Dimmeler et al, 1999; Fulton et al, 1999; Michell et al, 1999). The process for long-term production of NO from endothelial sources that can result from physical stimuli and biochemical signals has been described to involve other cellular components, including integrins, G proteins, and protein kinases (Busse and Fleming, 1998). Recently, it was discovered that sustained NO production in response to chronic shear stress and growth factor stimuli involves activation of phosphatidylinositol-3-kinase (P13-kinase) and its effector, the serine/threonine protein kinase Akt, which subsequently causes constitutive activation of eNOS (Dimmeler et al, 1999; Fulton et al, 1999; Michell et al, 1999).
This discovery has now been extended to the basic science of erection physiology, with an investigation showing that this protein kinase cascade physiologically mediates penile erection. Using rodent animal models, Burnett et al (2002) recently found that both electrical stimulation of the cavernous nerve and direct intracorporal vasoactive drug delivery elicited rapid increases in phosphorylated (activated) Akt and eNOS, which were blocked by wortmannin and LY294002, inhibitors of P13-kinase, the upstream activator of Akt (Hurt et al, 2002). These 2 drugs also markedly attenuated erectile responses. In addition, penile erection caused by intracorporal vasoactive drug delivery was profoundly reduced in mice with targeted deletion of eNOS. These findings led the investigators to postulate that the rapid, brief, calcium-dependent activation of nNOS initiates the erectile process, whereas P13-kinase/Akt-dependent phosphorylation of eNOS results in sustained NO production and thereby elicits full erection attainment (Table).
Clinical Therapeutics
NO-Based Therapy—
The established importance of the NO-dependent regulatory system for penile
erection has spurred approaches to stimulate this system for the treatment of
erectile dysfunction, particularly that associated with defective NO
regulation (Figure 2).
Pharmacologic approaches advanced for consideration include synthetic NO
donors explored for intracavernosal administration
(Truss et al, 1994);
L-arginine, the precursor amino acid for NO production, administered orally
(Klotz et al, 1999); and
nitrosylated alpha-adrenergic antagonists, under development for various
possible routes of delivery (Saenz de
Tejada et al, 1999). Gene therapies with NOS constructs have
represented another exciting approach to alleviate erectile dysfunction
(Garban et al, 1997; Champion et al, 1999). The
recent initial description of a biochemical system producing activated
constitutive NOS that regulates penile erection also has therapeutic
implications (Hurt et al,
2002). Drugs that inhibit dephosphorylation of eNOS or that
activate this enzyme or its upstream regulatory kinase, or alternatively,
methods for gene transfer involving activated eNOS could offer novel
therapeutic approaches for erectile dysfunction. A mechanistic basis for the
angiogenic effects of statins involving Akt phosphorylation of eNOS in
isolated vascular preparations (Brouet et
al, 2001) suggests that statin medications, for example, could
have direct clinical relevance in the management of erectile dysfunction.
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PDE-5 Inhibition— The NO-dependent signal transduction system required for penile erection involves a complex biochemical pathway in which several targets are available for pharmacologic manipulation. The most prominent one identified thus far is PDE-5, which enzymatically converts cGMP to its inactive form (Boolell et al, 1996; Turko et al, 1999). By its preservation, cGMP in turn is present to a greater extent than at baseline conditions to activate PKG, which then facilitates a cascade of biochemical events resulting in corporal smooth muscle relaxation and hence penile erection (Burnett, 1995; Boolell et al, 1996; Chuang et al, 1998; Turko et al, 1999; Hedlund et al, 2000a). This mechanism still requires the primary synthesis of cGMP, driven by NO production and release during sexual arousal. Therein lies the essence of the PDE-5 inhibitory mechanism for erection, that sexual stimulation and arousal are necessary for the therapeutic action of PDE-5 inhibitors. Succinctly, PDE-5 inhibitors augment, but do not cause, erection. This principle has clinical importance for the use of PDE-5 inhibitors to be effective in the management of erectile dysfunction. The fact that the PDE-5 enzyme is expressed in high concentrations in corporal smooth muscle of the penis compared with other structures of the body lends additional support to the value of PDE-5 inhibition as a therapeutic strategy for erectile disorders.
The biochemical mechanism of action of PDE-5 inhibitors as erectogenic agents is clinically relevant in the context of their therapeutic efficacy and safety profiles. The specific pharmacologic properties that refer to these concerns are the pharmacodynamics and pharmacokinetics of such agents (Corbin and Francis, 1999). With respect to pharmacodynamics, the biochemical potencies and selectivities of alternative PDE-5 inhibitors can be studied and compared. The biochemical potency refers to the capacity of the PDE-5 inhibitor to competitively bind to and block PDE-5 and is commonly described by its IC50, the determinant defining the concentration of compound required to produce 50% inhibition of the enzyme. Accordingly, a lower IC50 of the compound implies its higher biochemical potency. The respective IC50 values in descending order (and hence ascending biochemical potency order) are 3.9, 0.94, and 0.7 nmol/L concentrations for sildenafil, tadalafil, and vardenafil of the newly described PDE-5 inhibitor class of agents. Importantly, while the greater biochemical potency of a select PDE-5 inhibitor might suggest its proclivity toward superior clinical performance, only comparative clinical assessments permit such conclusions.
The biochemical selectivity refers to the capacity of the PDE-5 inhibitor to block PDE-5 relative to at least 10 other PDE enzymes in the PDE isoform family. This determinant is commonly presented as a selectivity ratio. Accordingly, a higher biochemical selectivity is assigned to the compound with a higher selectivity ratio. This concept relates to the compound manifesting reduced overlaps in specificity, or cross-reactivity, that might be associated with undesirable side effects. In this regard, PDE-5 inhibitor cross-reactivity with PDE-6, which is localized to the retina, is reported to occur with sildenafil, producing visual disturbances (Goldstein et al, 1998). Clinical trials with both vardenafil and tadalafil are also reported to cross-react but apparently less avidly with PDE-6, such that visual disturbances are reportedly even less common (Porst, 2002; Pryor, 2002). Other side effects commonly involving PDE-5 inhibitor therapy include headaches, facial flushing, dyspepsia, and rhinitis. These side effects are perceived to result from the inhibitory effects of PDE-5 present to some extent in tissues other than the corporal smooth muscle.
With respect to pharmacokinetics, the onset of action and the duration of
action can be applied to characterize alternative PDE-5 inhibitors.
Tmax, the time to maximum plasma concentrations, is
reportedly shorter for vardenafil (0.66 hour) than for sildenafil (1.16 hours)
or tadalafil (2.0 hours) (Porst,
2002), suggesting that vardenafil offers a better opportunity for
immediate drug efficacy. The half-life (t
), the
time required to eliminate or metabolize half the amount of drug, is
reportedly 3.82, 3.94, and 17.5 hours for sildenafil, vardenafil, and
tadalafil, respectively (Porst,
2002). The aspect of a longer half-life suggests that a drug has a
potentially advantageous longer duration of action, although a prolonged
half-life may also yield significant adverse effects and other adverse
biochemical interactions.
Although the main focus in PDE-5 biology of the penis is to target its enzymatic activity for pharmacologic interventions for erectile dysfunction, new interest has been advanced with regard to regulating the expression levels of PDE-5 in the corpus cavernosum. Recent studies suggest that diverse mechanisms may exist for regulation of PDE-associated signaling in the penis (Kim et al, 2000; Gopal et al, 2001; Lin et al, 2001). Changes in PDE-5 substrate concentrations, the interplay of NO and cyclic nucleotide stimulatory systems, and the action of transcription factors affecting PDE-5 gene expression represent several aspects that deserve ongoing investigation with the development of PDE-5-based therapies. Besides considerations to modulate PDE-5 activity on a molecular level, some interest has been given to exploring pharmacologic synergism between PDE-5 inhibitors and other effectors of the erectile response. Early studies in animal models have shown that the combination of PDE-5 inhibitors with the central dopaminergic agent, apomorphine, or with the cyclic adenosine monophosphate (cAMP) inducer, prostaglandin E1, potently stimulates penile erection (Andersson et al, 1999; Doherty et al, 2001).
Alternative Possibilities— An alternative molecular target of the NO-dependent signal transduction system for pharmacologically stimulating erections is guanylate cyclase. This enzyme, which is expressed in the corpus cavernosum, is conventionally described to be activated by NO for the synthesis of cGMP. A provocative, novel concept pertains to heightening guanylate cyclase activation to facilitate penile erection NO independently. In this light, the feasibility of agents that bind to the enzyme at an allosteric site different from the NO binding site and induce penile erection has been demonstrated (Brioni et al, 2002; Mizusawa et al, 2002). Most interestingly, while these agents may serve as independent effectors of cGMP production through guanylate cyclase activation, they could effect a potentiated response from NO stimulation, with the chemical acting on the enzyme at a heightened activation state. Such considerations underscore that diverse opportunities can be explored on the basis of mechanisms of NO biology in the penis for the treatment of erectile dysfunction.
It is also intriguing to speculate that cGMP-dependent protein kinase (PKG) can be pharmacologically manipulated to a heightened activation state and thereby facilitate the NO-based biochemical cascade further downstream. Recent descriptions of autoinhibition of cyclic nucleotide-dependent protein kinase (Francis et al, 2002) suggest mechanistic possibilities not only to inactivate PKG (and likewise cAMP-dependent protein kinase A) but also potentially to facilitate its activity. It will be interesting to carry out additional evaluations of mechanisms involving protein kinases interacting with the NO-dependent signal transduction system in the penis, which may eventually translate as well into therapeutic utility.
Summary
In this brief review, the various aspects of the enzymology, biochemistry,
and molecular pharmacology of the NO-dependent signal transduction system in
the penis have been discussed. Scientific investigations of this system have
certainly provided academic excitement while affording practical applications
for the clinical management of erectile dysfunction. Recent and ongoing
discoveries relating to this system may eventuate in the identification and
manipulation of a host of molecular sites for therapeutic benefit.
Appendix
Question 1—
Can you foresee in the future a combination therapy using different aspects
of the guanylate-cyclase pathway to produce a more potent or synergistic
effect?
Answer— It will be interesting to see how we can manipulate this guanylate-cyclase pathway using agents with different sites of action in order to enhance the effect. For example, if you look at guanylate-cyclase and some of the new compounds that are being developed, by binding to an allosteric site on guanylate cyclase, a better activational state for PKG activation can occur. But more interestingly, if NO is also present, there is an exponential effect in regard to cGMP production. This concept is very exciting in that various interactions within the pathway can lead to downstream effects to augment smooth muscle relaxation.
Question 2— The NOS knockout mice had reportedly sexually deviant behavior and aggression. Do you have any insight into this behavior or its cause?
Answer— In regard to the aggressive behavior reported in some nNOS knockout mice, this has not been significant as with endothelial NOS knockout. Aggressive behavior is not related to penile erection, but it may have something to do with brain mechanisms of aggression, which is certainly distinct from what we are working on at this time.
Question 3— Are you aware of any new research on NO-releasing compounds?
Answer— Many groups are trying to develop novel NO-releasing agents. These NO donors or nitrosylated agents may, in combination, augment the smooth muscle relaxing effect. Frankly, that part of the system has not really demonstrated as substantial an efficacy as has been shown with other downstream enzyme systems.
Question 4— Recently, there was an article published in JAMA claiming a protective effect by PDE-5 inhibitors. Before, this family of enzymes was considered dangerous to vasculature and to people with heart disease. These recent studies on large cohorts of men actually show fewer myocardial infarctions (MIs) and greater longevity. Do you think these PDE-5 inhibitors may benefit some men with specific vascular conditions that predispose them to early death?
Answer— The data are somewhat circumstantial if you review these recently reported series. It appears that for some men on the drug, there were fewer adverse vascular effects, including MIs. What is the science behind this? Possibly, there is some remodeling of the vascular system of the penis when there is an increased blood flow. This may have some relevance in regard to examining why PDE-5 inhibitor therapy may cause long-term benefits in restoring erectile function. It has been described in a number of recent reports, with currently available drug therapy, that some men discontinue use of the drug because of significant improvements in spontaneous activity. This is very exciting and suggests that the science needs to evolve further in this field to explore some of these different medical issues.
Footnotes
Supported by grant DK-02568 from the National Institute of Diabetes and Digestive and Kidney Diseases.
References
Akingba AG, Burnett AL. Endothelial nitric oxide synthase protein expression, localization, and activity in the penis of the alloxan-induced diabetic rat. Mol Urol.2001; 5:189 –197.[Medline]
Andersson KE, Gemalmaz H, Waldeck K, Chapman TN, Tuttle JB, Steers WD. The effect of sildenafil on apomorphine-evoked increases in intracavernous pressure in the awake rat. J Urol.1999; 161:1707 –1712.[Medline]
Azadzoi KM, Kim N, Brown ML, Goldstein I, Cohen RA, Saenz de Tejada I. Endothelium-derived nitric oxide and cyclooxygenase products modulate corpus cavernosum smooth muscle tone. J Urol.1992; 147:220 –225.[Medline]
Bakircioglu ME, Lin CS, Fan P, Sievert KD, Kan YW, Lue TF. The effect of adeno-associated virus mediated brain derived neurotrophic factor in an animal model of neurogenic impotence. J Urol.2001; 165:2103– 2109.[Medline]
Boolell M, Allen MJ, Ballard SA, Gepi-Attee S, Muirhead GJ, Naylor AM, Osterloh IH, Gingell C. Sildenafil: an orally active type 5 cyclic GMP-specific phosphodiesterase inhibitor for the treatment of penile erectile dysfunction. Int J Impotence Res.1996; 8:47 –52.[Medline]
Brioni JD, Nakane M, Hsieh GC, Moreland RB, Kolasa T, Sullivan JP. Activators of soluble guanylate cyclase for the treatment of male erectile dysfunction. Int J Impotence Res.2002; 14:8 –14.[Medline]
Brouet A, Sonveaux P, Dessy C, Moniotte S, Balligand JL, Feron O.
Hsp90 and caveolin are key targets for the proangiogenic nitric oxide-mediated
effects of statins. Circ Res.2001; 89:866
–873.
Burnett AL. Nitric oxide control of lower genitourinary tract functions: a review. Urology.1995; 45:1071 –1083.[Medline]
Burnett AL. Nitric oxide in the penis: physiology and pathology. J Urol. 1997;157:320 –324.[Medline]
Burnett AL, Chang AG, Crone JK, Huang PL, Sezen SF. Noncholinergic penile erection in mice lacking the gene for endothelial nitric oxide synthase. J Androl.2002; 23:92 –97.[Abstract]
Burnett AL, Lowenstein CJ, Bredt DS, Chang TS, Snyder SH. Nitric
oxide: a physiologic mediator of penile erection.
Science. 1992;257:401
–403.
Busse R, Fleming I. Pulsatile stretch and shear stress: physical stimuli determining the production of endothelium-derived relaxing factors. J Vasc Res.1998; 35:73 –84.[Medline]
Champion HC, Bivalacqua TJ, Hyman AL, Ignarro LJ, Hellstrom WJ,
Kadowitz PJ. Gene transfer of endothelial nitric oxide synthase to the penis
augments erectile responses in the aged rat. Proc Natl Acad Sci
USA. 1999;96:11648
–11652.
Chuang AT, Strauss JD, Steers WD, Murphy RA. cGMP mediates corpus cavernosum smooth muscle relaxation with altered cross-bridge function. Life Sci. 1998;63:185 –194.[Medline]
Corbin JD, Francis SH. Cyclic GMP phosphodiesterase-5: target of
sildenafil. J Biol Chem.1999; 274:13729
–13732.
Dimmeler S, Fleming I, Fisslthaler B, Hermann C, Busse R, Zeiher AM. Activation of nitric oxide synthase in endothelial cells by Akt-dependent phosphorylation. Nature.1999; 399:601 –605.[Medline]
Doherty PC, Bivalacqua TJ, Champion HC, Kadowitz PJ, Greenwood-Van Meerveld B, Berzetei-Gurske I, Hellstrom WJ. Direct effects of selective type 5 phosphodiesterase inhibitors alone or with other vasodilators on the erectile response in cats. J Urol.2001; 165:1004 –1009.[Medline]
Forstermann U, Boissel JP, Kleinert H. Expressional control of the
"constitutive" isoforms of nitric oxide synthase (NOS I and NOS
III). FASEB J.1998; 12:773
–790.
Francis SH, Poteet-Smith C, Busch JL, Richie-Jannetta R, Corbin JD. Mechanisms of autoinhibition in cyclic nucleotide-dependent protein kinases. Front Biosci.2002; 7:D580 –D592.
Fulton D, Gratton JP, McCabe TJ, et al. Regulation of endothelium-derived nitric oxide production by the protein kinase Akt. Nature. 1999; 399:597 –601.[Medline]
Garban H, Marquez D, Magee T, et al. Cloning of rat and human inducible penile nitric oxide synthase. Application for gene therapy of erectile dysfunction. Biol Reprod.1997; 56:954 –963.[Abstract]
Goldstein I, Lue TF, Padma-Nathan H, Rosen RC, Steers WD, Wicker
PA. Oral sildenafil in the treatment of erectile dysfunction. Sildenafil Study
Group. N Engl J Med.1998; 338:1397
–1404.
Gonzalez-Cadavid NF, Burnett AL, Magee TR, Zeller CB, Vernet D,
Smith N, Gitter J, Rajfer J. Expression of penile neuronal nitric oxide
synthase variants in the rat and mouse penile nerves. Biol
Reprod. 2000;63:704
–714.
Gonzalez-Cadavid NF, Rajfer J. Therapeutic stimulation of penile nitric oxide synthase (NOS) and related pathways. Drugs Today. 2000;36:163 –174.
Gopal VK, Francis SH, Corbin JD. Allosteric sites of phosphodiesterase-5 (PDE5). A potential role in negative feedback regulation of cGMP signaling in corpus cavernosum. Eur J Biochem.2001; 268:3304 –3312.[Medline]
Gupta S, Moreland RB, Munarriz R, Daley J, Goldstein I, Saenz de Tejada I. Possible role of Na(+)-(K(+)-ATPase in the regulation of human corpus cavernosum smooth muscle contractility by nitric oxide. Br J Pharmacol. 1995;116:2201 –2206.[Medline]
Hedlund P, Aszodi A, Pfeifer A, Alm P, Hofmann F, Ahmad M, Fassler
R, Andersson KE. Erectile dysfunction in cyclic GMP-dependent kinase
I-deficient mice. Proc Natl Acad Sci USA.2000a; 97:2349
–2354.
Hedlund P, Ny L, Alm P, Andersson KE. Cholinergic nerves in human corpus cavernosum and spongiosum contain nitric oxide synthase and heme oxygenase. J Urol.2000b; 164:868 –875.[Medline]
Hosogai N, Hamada K, Tomita M, et al. FR226807: a potent and selective phosphodiesterase type 5 inhibitor. Eur J Pharmacol. 2001;428:295 –302.[Medline]
Hurt KJ, Musicki B, Palese MA, Crone JK, Becker RE, Moriarity JL,
Snyder SH, Burnett AL. Akt-dependent phosphorylation of endothelial
nitric-oxide synthase mediates penile erection. Proc Natl Acad Sci
USA. 2002;99:4061
–4066.
Kim N, Azadzoi KM, Goldstein I, Saenz de Tejada I. A nitric oxide-like factor mediates nonadrenergic-noncholinergic neurogenic relaxation of penile corpus cavernosum smooth muscle. J Clin Invest. 1991;88:112 –118.
Kim NN, Huang Y, Moreland RB, Kwak SS, Goldstein I, Traish A. Cross-regulation of intracellular cGMP and cAMP in cultured human corpus cavernosum smooth muscle cells. Mol Cell Biol Res Commum. 2000; 4:10 –14.[Medline]
Kimoto Y, Kessler R, Constantinou CE. Endothelium dependent relaxation of human corpus cavernosum by bradykinin. J Urol. 1990;144:1015 –1017.[Medline]
Klotz T, Mathers MJ, Braun M, Bloch W, Engelmann U. Effectiveness of oral L-arginine in first-line treatment of erectile dysfunction in a controlled crossover study. Urol Int.1999; 63:220 –223.[Medline]
Knispel HH, Goessl C, Beckmann R. Basal and acetylcholine-stimulated nitric oxide formation mediates relaxation of rabbit cavernous smooth muscle. J Urol.1991; 146:1429 –1433.[Medline]
Lee SW, Kang TM. Effects of nitric oxide on the Ca2+-activated potassium channels in smooth muscle cells of the human corpus cavernosum. Urol Res. 2001;29:359 –365.[Medline]
Lin CS, Chow S, Lau A, Tu R, Lue TF. Identification and regulation of human PDE5A gene promoter. Biochem Biophys Res Commun. 2001; 280:684 –692.[Medline]
Michell BJ, Griffiths JE, Mitchelhill KI, et al. The Akt kinase signals directly to endothelial nitric oxide synthase. Curr Biol. 1999;9:845 –848.[Medline]
Minhas S, Eardley I, Joyce AD, Morrison JB. The effect of cyclic GMP on rabbit corporal smooth muscle tone and its modulation by cyclooxygenase products. Prostaglandins Leukotrienes Essential Fatty Acids. 2000;62:153 –160.[Medline]
Mizusawa H, Hedlund P, Brioni JD, Sullivan JP, Andersson KE. Nitric oxide independent activation of guanylate cyclase yy YC-1 causes erectile responses in the rat. J Urol.2002; 167:2276 –2281.[Medline]
Noto T, Inoue H, Ikeo T, Kikkawa K. Potentiation of penile
tumescence by T-1032, a new potent and specific phosphodiesterase type V
inhibitor, in dogs. J Pharmacol Exp Ther.2000; 294:870
–875.
Oh TY, Kang KK, Ahn BO, Yoo M, Kim WB. Erectogenic effect of the selective phosphodiesterase type 5 inhibitor, DA-8159. Arch Pharm Res. 2000;23:471 –476.[Medline]
Padma-Nathan H, McMurray JG, Pullman WE, Whitaker JS, Saoud JB, Ferguson KM, Rosen RC. IC351 On-Demand Dosing Study Group. On-demand IC351 (Cialis) enhances erectile function in patients with erectile dysfunction. Int J Impotence Res.2001; 13:2 –9.[Medline]
Porst H. IC351 (tadalafil, Cialis): update on clinical experience. Int J Impotence Res.2002; 14(suppl 1):S57 –S64.
Porst H, Rosen R, Padma-Nathan H, Goldstein I, Giuliano F, Ulbrich E, Bandel T. The efficacy and tolerability of vardenafil, a new, oral, selective phosphodiesterase type 5 inhibitor, in patients with erectile dysfunction: the first at-home clinical trial. Int J Impotence Res. 2001; 13:192 –199.[Medline]
Pryor J. Vardenafil: update on clinical experience. Int J Impotence Res.2002; 14(suppl 1):S65 –S69.
Rajfer J, Aronson WJ, Bush PA, Dorey FJ, Ignarro LJ. Nitric oxide as a mediator of relaxation of the corpus cavernosum in response to non-adrenergic, noncholinergic neurotransmission. N Engl J Med. 1992; 326:90 –94.[Abstract]
Saenz de Tejada I, Garvey DS, Schroeder JD, et al. Design and
evaluation of nitrosylated alpha-adrenergic receptor antagonists as potential
agents for the treatment of impotence. J Pharmacol Exp
Ther. 1999; 290:121
–128.
Seftel AD, Viola KA, Kasner SE, Ganz MB. Nitric oxide relaxes rabbit corpus cavernosum smooth muscle via a potassium-conductive pathway. Biochem Biophys Res Commun.1996; 219:382 –387.[Medline]
Truss MC, Becker AJ, Djamilian MH, Stief CG, Jonas U. Role of the nitric oxide donor linsidomine chlorhydrate (SIN-1) in the diagnosis and treatment of erectile dysfunction. Urology.1994; 44:553 –556.[Medline]
Turko IV, Ballard SA, Francis SH, Corbin JD. Inhibition of cyclic
GMP-binding cyclic GMP-specific phosphodiesterase (type 5) by sildenafil and
related compounds. Mol Pharmacol.1999; 56:124
–130.
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