Use of a Nitronyl Nitroxide to Discriminate the Contribution of Nitric Oxide Radical in Endothelium-Dependent Relaxation of Control and Diabetic Blood Vessels

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Vol. 283, Issue 1, 138-147, 1997

Use of a Nitronyl Nitroxide to Discriminate the Contribution of Nitric Oxide Radical in Endothelium-Dependent Relaxation of Control and Diabetic Blood Vessels¹

Galen M. Pieper and Wolfgang Siebeneich

Department of Transplant Surgery, Medical College of Wisconsin, Milwaukee Wisconsin

	Abstract

Top Abstract Introduction Materials & Methods Results Discussion References

Nitronyl nitroxides react with nitric oxide radical (·NO) to form imino nitroxides. We used a nitronyl nitroxide, [2-(4-carboxyphenyl)-4,4,5,5-tetramethylimidazoline-1-oxyl3 oxide] (CPTIO) to evaluate the contribution of ·NO to basaltone and acetylcholine-induced endothelium-dependent relaxationin control vs. diabetic rat aortic rings. In rings precontractedwith phenylephrine, CPTIO produced an additional increment intension that was greater in control vs. diabetic rings. Tensionafter CPTIO was similar to that observed in rings pretreated withthe NO synthase inhibitor, L-nitroarginine or in rings withoutendothelium. This increment was insensitive to indomethacin, cysteine,tetraethylammonium or catalase, but was sensitive to inhibitionby the soluble guanylate cyclase inhibitor, 1H-[1,2,4]oxadiazolo[4,3,-a]quinoxaline-1-one.L-Nitroarginine blocked relaxation to ACH by 100 and 90% in controland diabetic rings, respectively. In contrast, CPTIO produceda concentration-dependent inhibition of ACH-induced relaxationthat was greater in control rings. The residual CPTIO-resistantcomponent of relaxation was equivalent to 26 and 43% of initialprecontraction in control vs. diabetic rings, respectively, andwas not altered by indomethacin, catalase, cysteine or tetraethylammoniumbut was significantly inhibited by 1H-[1,2,4]oxadiazolo[4,3,-a]quinoxaline-1-one.These data suggest the release of additional unknown factor(s)that cannot be discerned using NO synthase inhibitors only. ThisCPTIO-resistant dilator is likely not a cyclooxygenase productor a hyperpolarizing factor but a factor that acts, in part, byactivation of guanylate cyclase. This substance is possibly ·NOthat is not available for reaction with CPTIO either by its diffusibilityand sequestration or molecular rearrangement to a redox activeform (i.e., not free ·NO) or is a completely different vasodilator.The use of a more lipid soluble nitronyl nitroxide derivativesuggests a portion of the CPTIO-resistant relaxation in diabetic(but not control) rings could be explained by ·NO sequesteredin the lipid phase.

	Introduction

Top Abstract Introduction Materials & Methods Results Discussion References

Furchgott and Zawadski (1980) were the first to report the phenomenon of endothelium-dependent relaxation of blood vessels.It has been suggested that this action results from the releaseof an EDRF that was likely to be NO or a closely related entity(Palmer et al., 1988). Since these initial reports, it has becomeapparent that the endothelium-dependent relaxation of certainblood vessels to certain stimulants is not entirely mediated byEDRF/NO but may also include other relaxation factors such asEDHF or prostanoids (Cohen and Vanhoutte, 1995).

Arginine analogs that are competitive antagonists to NOS have been used to assess the contribution of NO to relaxation inducedby a variety of endothelium-dependent agonists. These compoundsdo not antagonize NO directly but only block NO synthesis viaNOS. A different approach to assess the role of NO is by usingpharmacological probes that directly react with or scavenge NO.Indeed, we have previously reported that the iron-thiol containingNO scavenger, MGDFe, significantly attenuated ACH-stimulated relaxationin both control and diabetic rat aortic rings; however, a significantcomponent of relaxation was resistant to MGDFe antagonism (Pieperand Lai, 1997). These observations were interesting because ACH-mediatedrelaxation in both experimental groups is virtually abolishedby L-NA and relaxation to ACH is not modified by indomethacin(Pieper et al., 1997). Taken together, these studies raise somequestion whether endothelium-dependent relation in this modelis, in fact, entirely mediated by NO radical (·NO) per se.

To further understand this discrepancy, we used an agent belonging to a uniquely different class of NO antagonist known asnitronyl nitroxides. One of these nitronyl nitroxides, CPTIO,has been shown to be a valuable probe to discount the specificrole of ·NO in antimicrobial action (Yoshida et al., 1993). CPTIOhas also been used to distinguish the role of ·NO in relaxationof rat aorta compared to nerve-stimulated relaxation in anoccygeousmuscle and gastric fundus strips (Rand and Li, 1995). CPTIO completelyinhibited relaxation induced by NO gas in rat aorta (Rand andLi, 1995) and inhibited by >90% the relaxation elicited by authenticEDRF using ACH in rabbit aorta (Akaike et al., 1993). Thus, weused CPTIO to discriminate a role of NO-dependent vs. NOS-dependent,endothelium-dependent relaxation to ACH in control and diabeticrat aorta.

	Materials and Methods

Top Abstract Introduction Materials & Methods Results Discussion References

Male Sprague-Dawley rats were made diabetic by an i.v. injection of 55 mg/kg streptozotocin as previously described (Pieperand Peltier, 1995). Diabetes was verified at 1 wk using an ExacTech glucometer and test strips. Diabetic and age-matched controlrats were housed for 8 wk before evaluation of vascular function.After this duration, animals were anesthetized with 65 mg/kg sodiumpentobarbital. The descending thoracic aorta was carefully isolated,cleaned and sectioned into 3-mm long aortic rings. Extreme carewas taken to avoid damage during the isolation process. In a fewof the rings, the endothelium was intentionally removed by rubbingthe lumen with a forceps.

Rings were mounted between parallel wires in isolated tissue baths at 37°C. The bath medium contained Krebs bicarbonate bufferwhich was oxygenated at 95% O₂:5% CO₂ to maintain pH at 7.4. Thebuffer contained (in mM): NaCl 118, KCl 4.7, CaCl₂ 2.5, MgSO₄1.2, NaHCO₃ 24 and glucose 10.5. Rings were equilibrated underoptimal tensions of 2.0 g for both control and diabetic ringsbefore performing measurements of contractile reactivity to PE.Isometric tension were recorded on a Gould (Valley View, OH) TA6000recorder using Radnoti (Monrovia, CA) model 159901 force-displacementtransducers.

Each ring was contracted with cumulative concentrations of PE. After washing and equilibrium, rings were contracted with asubmaximal concentration of PE (i.e., 1 µM) before evaluatingrelaxation produced by increasing concentrations of the endothelium-dependentvasodilator, ACH. In a few rings, nitroglycerin was used as avasodilator for endothelium-independent relaxation.

Previously, we showed that endothelium-dependent relaxation to ACH is impaired in diabetic aortic rings that are contractedwith either norepinephrine or PE (Pieper et al., 1997). In thesestudies as in many other investigations, the concentration wasvaried, if necessary, to provide equipotent contraction basedon concentration-response curves to each agonist. In our study,an equimolar PE concentration was used in both control and diabeticpreparations. This protocol was designed to prevent variabilityin the proportion of NO vs. EDHF that contributes to total ACH-inducedrelaxation. This proportion is known to vary at different concentrationsof vasoconstrictor (Hatake et al., 1995) and might confound theinterpretation of the efficacy of CPTIO in control versus diabeticrings.

After the initial ACH challenge to verify similar baseline responses between rings from the same animal, individual ringswere washed, equilibrated and contracted a second time to PE.At the peak of PE-induced contraction, various concentrationsof CPTIO were added. At the peak of response to CPTIO, the ringswere then challenged a second time to increasing ACH concentrations.Previous studies indicated that relaxation between the first andsecond challenges to ACH in both control and diabetic rings aresimilar (Pieper and Peltier, 1995, Pieper et al., 1996a). In aselect few experiments, we also used a related nitronyl nitroxidederivative known as PTIO. In a few other experiments, we challengedrings with a single ACH concentration of 30 µM to evaluate whetherdrug interventions altered either the initial rapid phase vs.maximum sustained phase of relaxation to ACH since the factorsor molecular species responsible for hyperpolarization and relaxationhas been suggested to be different at each phase (Vanheel et al.,1994; Rubanyi et al., 1985).

To evaluate the CPTIO-resistant component of ACH-mediated relaxation, we also performed several experiments using specificdrug interventions. These included 10 µM indomethacin (to inhibitcyclooxygenase); 100 µM L-NA (to inhibit NOS); 1 mM TEA (to inhibitK⁺ channels); 1 mM L-cysteine (to scavenge nitroxyl anion and/orperoxynitrite anion); 1000 U/ml catalase (to decompose H₂O₂) and3 µM of ODQ to inhibit soluble guanylate cyclase (Garthwaite etal., 1995; Moro et al., 1996).

Data are presented as the mean ± S.E.M. where n equal the number of individual animals. Data were analyzed by analysis ofvariance or repeated analysis of variance followed by FishersPLSD test for multiple mean comparisons, where appropriate; orby unpaired t test and paired t test for comparison of two groupmeans, where appropriate. A P < .05 was considered to designatestatistical significance.

	Results

Top Abstract Introduction Materials & Methods Results Discussion References

Contractile function. The average maximum tension development of all aortic rings in response to increasing PE concentrations was reduced by diabetes(table 1); however, tension normalized for cross-sectional areawas not different. The sensitivity (pD₂) to PE was modestly differentbetween the two groups. Removal of the endothelium increased thetension development in both control and diabetic rings; however,the increase was greater in control vs. diabetic rings.

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TABLE 1
Contractile effects of phenylephrine in control vs. diabetic aortic rings

Addition of increasing concentrations of CPTIO (30-300 µM) enhanced the contractile tension in both control and diabetic ringspreviously contracted with 1 µM PE. There was no increase in tensionfollowing addition of CPTIO in rings under resting tension (i.e.,without PE, data not shown). The incremental change in CPTIO-inducedtension development was greater in control compared to diabeticrings (example for 300 µM CPTIO shown in fig. 1 and fig. 7, Aand C). Similar differences between control and diabetic ringswere seen using 300 µM PTIO (not shown). The CPTIO-induced incrementin tension was not modified by prior incubation with either indomethacin,TEA, cysteine or catalase (fig. 1). Although the increment wasslightly reduced by cysteine in diabetic rings compared to theentire group without cysteine (P < .05), this effect was not seenif analyzed compared to the smaller subset of pair-matched rings(P = 2.229, not significant). In contrast, previous incubationwith ODQ markedly inhibited CPTIO-induced tension developmentby 83 and 86% in control vs. diabetic rings, respectively. Similarly,the addition of the combination of ODQ with either indomethacin,TEA and catalase produced no further inhibition of CPTIO-inducedtension than by ODQ alone.

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Fig. 1. Effects of 300 µM CPTIO on tension development in control (upper panel) and diabetic (lower panel) aortic rings contractedwith 1 µM PE. Rings are untreated (control: n = 23; diabetic:n = 23), treated with 10 µM indomethacin (control: n = 7; diabetic:n = 9), 1 mM TEA (control: n = 10; diabetic: n = 11), 1000 U/mlcatalase (control: n = 9; diabetic: n = 10), 1 mM L-cysteine (control:n = 4; diabetic: n = 7), 3 µM ODQ (control: n = 8; diabetic: n= 15) or ODQ in combination with either TEA, indomethacin andcatalase (n = 3-4 each). $Dagger$ P < .01 vs. untreated

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Fig. 7. Example showing acetylcholine (ACH)-induced relaxation in control rings (tracings a and b) or diabetic rings (tracings c andd) and inhibition of relaxation following pretreatment with 300µM CPTIO (tracings a and c), or reversal by CPTIO given afterincreasing ACH concentrations (tracings b and d). ACH concentrationsare noted by dots and listed as the -log M. Boxes indicate whenACH or CPTIO is present. PE (phenylephrine: 1 µM).

At the highest concentration of CPTIO tested (i.e., 300 µM), the tension development was similar to that seen in rings withoutendothelium but without CPTIO or in rings pretreated with L-NA(fig. 2). Addition of CPTIO to rings without endothelium or inrings with endothelium but pretreated with L-NA produced no significantincrease in tension development (not shown).

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Fig. 2. Tension development in rings contracted with PE after addition of 100 µM CPTIO (control: n = 23; diabetic: n = 32) comparedto rings without CPTIO but after pretreatment with the NOS inhibitor,L-NA (control: n = 12; diabetic: n = 14), and in rings withoutendothelium (control: n = 12; diabetic: n = 11). $Dagger$ P < .01 vs.corresponding control rings

Vascular relaxation analysis. For all rings, the 1 µM PE concentration used for the relaxation studies produced 66 ± 2 and 58 ± 2% maximum tension for controlvs. diabetic rings, respectively. ACH fully relaxed both controland diabetic rings (examples shown in fig. 7, b and d) and thisrelaxation was significantly inhibited by L-NA, ODQ or by removalof the endothelium in both groups (fig. 3). Although blockadeof ACH -mediated relaxation by L-NA and ODQ was complete in controlrings, a significant residual component of ACH -stimulated relaxationwas present in diabetic rings equivalent to 15 ± 5 and 27 ± 6%in L-NA-treated and ODQ-treated rings, respectively. In contrast,ODQ caused complete and equivalent inhibition of nitroglycerin-inducedrelaxation in both control and diabetic rings (not shown).

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Fig. 3. Effects of removal of endothelium (n = 11 each) or incubation with either 100 µM L-NA (control: n = 4; diabetic: n = 7) or3 µM ODQ (control: n = 4; diabetic: n = 7) on ACH-induced relaxationcompared to untreated control (total n = 13) or untreated diabetic(total n = 20) rings. *P < .05 and $Dagger$ P < .01 vs. correspondinguntreated rings

Effects of CPTIO on ACH-induced relaxation. Addition of 30 to 300 µM CPTIO to control rings caused a concentration-dependent inhibition in the ACH-induced relaxation(fig. 4). Addition of 500 µM CPTIO caused no further inhibition(not shown). CPTIO also caused a concentration-dependent inhibitionof relaxation in diabetic rings (not shown). We used 300 µM CPTIOto further evaluate the role of NO in ACH -mediated relaxationof control and diabetic rings. The % residual ACH -induced relaxationthat was resistant to CPTIO was greater in diabetic rings thanin control rings (fig. 5). Addition of either indomethacin (notshown), catalase or TEA or L-cysteine did not alter the CPTIO-resistantcomponent of ACH-induced relaxation in both control and diabeticrings (fig. 6). In contrast, the CPTIO-resistant component ofACH-mediated relaxation was inhibited completely by preincubationwith ODQ in control rings but left a small residual portion ofrelaxation in diabetic rings (fig. 6). Although pretreatment withCPTIO alone before addition of increasing concentrations of ACHpartially inhibited the relaxation in control and diabetic rings,the addition of CPTIO after addition of the highest concentrationof ACH completely restored tension in both control and diabeticrings to levels greater than that observed prior to the additionof ACH (fig. 7).

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Fig. 4. Concentration-dependent inhibition of acetylcholine-induced relaxation in control aortic rings by 30 to 300 µM CPTIO (n =4-11 each). *P < .05; $Dagger$ P < .01 vs. relaxation in the same ringsbefore treatment with CPTIO

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Fig. 5. Acetylcholine-mediated relaxation which is insensitive to antagonism by 300 µM CPTIO in control (n = 16) and diabetic (n =19) rings. $Dagger$ P < .01 vs. control rings

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Fig. 6. Failure of incubation with 1 mM TEA (control: n = 5; diabetic: n = 6), 1 mM L-cysteine (control: n = 4; diabetic: n = 5),or 1,000 U/ml catalase (control: n = 5; diabetic: n = 6) but not3 µM ODQ (control: n = 3; diabetic: n = 6), to alter the ACH-inducedrelaxation component resistant to antagonism by 300 µM CPTIO incontrol and diabetic rings. TEA. *P < .05 vs. pair-matched, untreatedrings with CPTIO alone

To gather additional information regarding the nature of the CPTIO-resistant portion of ACH -mediated relaxation, we challengedboth control and diabetic rings with a single concentration ofACH (i.e., 30 µM) rather than cumulative ACH concentrations. Despitetotal relaxation of both control and diabetic rings with thissingle ACH concentration (not shown), pretreatment with 300 µMCPTIO inhibited relaxation to ACH in control (to 17 ± 1% residualrelaxation, n = 7) and diabetic rings (to 35 ± 4% residual relaxation,n = 12) (fig. 8). Addition of 30 µM ACH produced an initial rapidphase of relaxation in rings pretreated with CPTIO. The peak CPTIO-resistantportion of relaxation to 30 µM ACH was unaltered in both controland diabetic rings by prior treatment with either indomethacinor TEA or catalase (fig. 8). In contrast, the CPTIO-resistantcomponent of relaxation to ACH was essentially abolished in ODQ-treatedcontrol rings (i.e., 3.5 ± 1.5% residual relaxation) and significantly,but only partially, reduced in ODQ-treated diabetic rings (i.e.,11 ± 2% residual relaxation). Superimposition of either indomethacin,TEA or catalase in combination with ODQ did not further modifythe responses seen in CPTIO-treated, ODQ-treated rings (not shown).

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Fig. 8. Residual relaxation to a single concentration of acetylcholine (30 µM) that is resistant to inhibition by 300 µM CPTIO incontrol or diabetic rings. The CPTIO-insensitive component ofrelaxation is inhibited by 3 µM ODQ (control: n = 4; diabetic:n = 9) but not by either 10 µM indomethacin (control: n = 4; diabetic:n = 6), 1 mM TEA (n = 5 each) or 1000 U/ml catalase (n = 4 each). $Dagger$ P < .01 vs. pair-matched untreated rings with CPTIO only (totalcontrol: n = 7; total diabetic: n = 12)

To evaluate the effects of another nitronyl nitroxide, we repeated the studies using a challenge with increasing concentrationsof ACH. Substitution with 300 µM PTIO caused inhibition of ACH-mediated relaxation in control and diabetic rings (fig. 9). Thecombination of both CPTIO and PTIO (300 µM each) did not causeany further inhibition of ACH -mediated relaxation of controlrings than that achieved by CPTIO or PTIO alone (fig. 9, upperpanel). In contrast in diabetic rings, PTIO alone or PTIO in combinationwith CPTIO caused a greater inhibition of relaxation to ACH thandid CPTIO alone (fig. 9, lower panel). In contrast to that seenwith CPTIO alone, the residual relaxation to ACH that was insensitiveto PTIO or CPTIO + PTIO was not different between control vs.diabetic rings. Nevertheless, a significant portion in ACH -mediatedrelaxation (approximately 20%) still remained in both controland diabetic rings despite the addition of PTIO.

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Fig. 9. Failure of substitution with 300 µM PTIO or addition of PTIO plus 300 µM CPTIO to alter the CPTIO-resistant portion of acetylcholine-inducedrelaxation in control rings (n = 5 or 8) but not diabetic rings(n = 6-7 each). *P < .05 vs. pair-matched rings treated with CPTIOalone

	Discussion

Top Abstract Introduction Materials & Methods Results Discussion References

In our study, we have characterized the contribution of NO to basal tone and ACH-stimulated endothelium-dependent relaxationof control and diabetic rat aortic rings. Our studies suggestthat the nitronyl nitroxide, CPTIO, antagonized all of the NOreleased under basal conditions in both control and diabetic rings.In addition, CPTIO inhibited a significant portion of ACH-stimulatedrelaxation in both control and diabetic rings; however, a residualcomponent of relaxation remained which was larger in diabeticrings. This effect occurred despite the observation that relaxationwas virtually eliminated in both groups using the NOS inhibitor,L-NA. Although our study is the first known application of thenitronyl nitroxide class of NO antagonists to provide valuableinsight into the nature of endothelium-dependent relaxation indiseased blood vessels, it is clear that these agents give importantinformation about NO-like activity that would not be achievedusing NOS inhibitors alone.

Basal NO tone. Our studies suggest that ·NO per se is the likely product released by both control and diabetic rings under control unstimulatedconditions and that the nitronyl nitroxide, CPTIO, is effectivein counteracting all of the ·NO activity released under theseconditions. This conclusion is based on several observations including:1) the CPTIO-sensitive incremental increase of tension developmentin PE-contracted rings was insensitive to indomethacin, cysteine,TEA and catalase but was inhibited by ODQ; 2) the CPTIO-sensitivecomponent of tension development was equivalent to that achievedby removal of the endothelium or by pretreatment with L-NA and3) the addition of CPTIO to rings without endothelium or L-NA-treatedrings with endothelium did not produce any significant changein tension.

This effect on PE-induced contractile tone is not unique to the nitronyl nitroxide CPTIO since we have observed that the iron-thiol-containingscavenger of NO (e.g., MGDFe) also completely scavenged basalNO activity (Pieper and Lai, 1996

). The observation that the incrementalincrease in tension in response to both CPTIO and MGDFe was greaterin control vs. diabetic rings and that treatment with L-NA orremoval of endothelium produces a greater increase in tensionin control vs. diabetic rings without CPTIO (this study) or MGDFe(Pieper and Lai, 1997

) suggests reduced basal NO activity in diabeticblood vessels.

Agonist-stimulated endothelium-dependent relaxation in diabetes. Endothelium-dependent relaxation to ACH and other agonists is impaired in a variety of conduit and resistance blood vesselstaken from experimental diabetic animals. Because endothelium-dependentrelaxation is also impaired in both type I (Johnstone et al.,1993) and type II (McVeigh et al., 1992) diabetes mellitus inhumans, information derived from experimental diabetic modelsmay provide insight to the defect in human diabetes. Several studiesusing a variety of vessels from different species show that indomethacindoes not shift the relaxation responses to ACH (Oyama et al.,1986; Hattori et al., 1991; Cameron and Cotter, 1992; Chang andStevens, 1992; Pieper et al., 1992, 1997; Mayhan, 1992; Dai etal., 1993; Taylor et al., 1994, Diederich et al., 1994; Kamataand Kobayashi, 1996). These collective observations suggest thatprostanoid factors cannot account for this dysfunction and thatnon-prostanoid factors such as deficits in NO per se can readilyaccount for endothelial dysfunction in diabetes.

Role of NO in diminished endothelium-dependent relaxation in diabetes. In support of deficits in NO activity, cGMP concentration in response to ACH was diminished (Kamata et al., 1989; Abiru etal., 1990 Pieper et al., 1996a; Abiru et al., 1993). The assumptionthat the ACH-stimulated cGMP generation and relaxation is entirelymediated by free NO radical, ·NO, is based on the observationthat the cGMP generated is essentially blocked by L-NA. This assumptionmay not be entirely valid because NO-independent molecular speciesarising from the NOS reaction (see discussion below) or molecularrearrangement of ·NO in equilibrium with other redox-dependentforms such as the nitrosonium cation (NO⁺) or the nitroxyl anion (NO) may occur. Indeed, both NO⁺ and NO have been claimed to be vasodilators (Fukoto et al., 1992; Pinoand Feelisch, 1994; Stamler et al., 1992), although others haveargued that only ·NO can activate purified guanylate cyclase (Dierksand Burstyn, 1996). Nevertheless, the biological evidence of anyof these transformed species under physiological or pathophysiologicalcondition has yet to be documented.

Potential role of an aberrant NOS reaction/reaction products. In the presence of an arginine deficiency or limited cofactor, purified NOS enzyme can reduce molecular oxygen to H₂O₂ orsuperoxide anion radical accompanied by diminished productionof ·NO (Heinzel et al., 1992; Pou et al., 1992). This may havesome implications in diabetic blood vessels. Indeed, the concentrationof tetrahydrobiopterin has been shown to be diminished in braintissue of diabetic animals (Hamon et al., 1989) although supplementationwith a tetrahydrobiopterin derivative in vitro restores endothelium-dependentrelaxation to ACH in diabetic rat aorta (Pieper, 1997). In addition,we have shown decreases in plasma arginine concentration (Pieperand Peltier, 1995) and in arginine content in vascular tissueof diabetic rats (Pieper and Dondlinger, 1996). Furthermore, supplementationwith L-arginine in vitro or in vivo restores endothelium-dependentrelaxation to ACH in diabetic rat aortic rings and improves cGMPgeneration (Pieper and Peltier, 1995; Pieper and Dondlinger, 1996;Pieper et al., 1996a). We have also shown that superoxide dismutaseplus catalase restores ACH-induced relaxation to normal in diabeticaortic rings (Pieper et al., 1997) which would be consistent withincreased basal production of superoxide anion radicals, ·O₂ (Chang et al., 1993; Pieper, 1995) and H₂O₂ (Pieper, 1995) bydiabetic aorta. Thus, it is theoretically possible that an aberrantNOS may be a source of increased reactive oxygen production fromdiabetic endothelium.

Comparison of the effects of nitronyl nitroxide vs. NOS inhibitors. The CPTIO-resistant component of relaxation to ACH that was greater in diabetic vs. control rings is not unique to CPTIO becausea similar observation was shown using MGDFe (Pieper and Lai, 1997),an agent that acts to interact with NO in a manner quite differentthan that achieved by CPTIO. Our use of a nitronyl nitroxide comparedwith L-NA appears be a useful candidate probe to discriminatethe effects of ·NO vs. other products of the NOS reaction on endothelium-dependentrelaxation in control vs. diabetic blood vessels. Reliance aloneon the efficacy of L-NA to inhibit relaxation to ACH in both controland diabetic rings does not prove that relaxations are, in fact,entirely mediated via ·NO. Rather, it simply suggests that relaxationarises from a NOS pathway. Indeed, L-NA might also eliminate thereactive oxygen by-products of the NOS reaction as well. We suggest,therefore, that a portion of the L-NA-sensitive, ACH -mediatedrelaxation that was insensitive to CPTIO and larger in diabeticrings might result from increased generation of products arisingfrom an aberrant NOS reaction in diseased blood vessels.

One possibility to explain the larger CPTIO-insensitive component of relaxation to ACH in diabetic blood vessels is that H₂O₂as well as the product of ·O₂ and ·NO, known as ONOO are also vasodilators (Wei et al., 1996

; Liu et al., 1994

) thatcan activate guanylate cyclase (Tarpey et al., 1995

). This explanationis attractive based on observation of enhanced rates of ·O₂ and H₂O₂ production in diabetic rat aorta (Pieper, 1995

). Atpresent, we cannot exclude the possibility that production ofONOO by diabetic rings could impact CPTIO activity because nitronylnitroxides are susceptible to reduction by reactive oxygen (Akaikeand Maeda, 1996

). In this case, there would be less active CPTIOavailable to react with and neutralize ·NO. We believe that thisexplanation would be insufficient because the addition of CPTIOat the end of ACH completely restored tension in both controland diabetic rings. This could be explained by the rapid decayof an ·NO -independent factor released initially upon ACH stimulation.

Our additional studies do suggest that a major portion of the CPTIO-resistant portion of ACH -induced relaxation in both controland diabetic rings is likely mediated by a substance that activatessoluble guanylate cyclase based on the studies using ODQ. Unlikemethylene blue, ODQ is a potent, highly selective inhibitor ofsoluble guanylate cyclase that also does not alter NOS activity(Brunner et al., 1996

). The actions of ODQ to block the CPTIO-resistantportion of relaxation to ACH would also be consistent with theactions of both H₂O₂ or ONOO as candidate molecules especially in diabetic blood vessels.Thus, taken together with the studies using L-NA, our data suggestthat a greater proportion of ACH-mediated relaxation in diabeticblood vessels occurs via a substance or factor that: 1) arisesfrom the NOS reaction, 2) is insensitive to antagonism by CPTIO,3) is an activator of guanylate cyclase, but 4) may not be ·NO.

Potential role of EDHF. We considered the possibility that the CTPIO-resistant component of relaxation to ACH is related to release of an EDHF thatmay act via cGMP-dependent or cGMP-independent pathways (Cohenand Vanhoutte, 1995). Previous studies discounted a role of alterationsin EDHF to account for impaired endothelium-dependent relaxationin diabetic rat aorta (Endo et al., 1995). In our study, our endothelium-dependentrelaxation protocols using CPTIO in the presence of indomethacin,TEA or catalase suggest that any putative alteration in prostanoidproduction, activation of calcium-activated K⁺ channel-sensitive hyperpolarizing factor or H₂O₂ generation indiabetic rings is unlikely to account for this larger CPTIO-resistantcomponent of relaxation to ACH in diabetic compared to controlrings.

Potential role of nitrosothiols. We also considered the possibility that a portion of the relaxation produced by ACH arises from release of a thiol-bound derivativesuch as S-nitrosocysteine (Myers et al., 1990; Rubanyi et al.,1991) because CPTIO is unable to interact chemically with nitrosothiols(Akaike and Maeda, 1996). Reaction of ·NO with cysteine producesS-nitrosocysteine that increases the potency of authentic EDRFand increases its half-life. In this regard, L-cysteine has beenshown to potentiate ·NO-dependent relaxation but inhibit relaxationmediated by NO (Pino and Feelisch, 1994) and might also interact with ONOO (Pfeiffer et al., 1997). Because L-cysteine did not change theCPTIO-resistant portion of relaxation to ACH in either controlor diabetic rings, we conclude that the CPTIO-resistant portionof relaxation to ACH in diabetic rings is likely not mediatedby ONOO.

We also considered the possibility that the CPTIO-resistant portion of relaxation to ACH is mediated by the product of reactionof endothelial-derived ·NO with CPTIO. In this regard, the reactionof CPTIO with ·NO is a radical-radical reaction producing theproducts, 2-(4-carboxyphenyl)-4,4,5,5-tetramethylimidazoline-1oxyl (known as CPTI) and NO₂. CPTI did cause vasodilation in caninecoronary arteries (Tsunoda et al., 1994

) that was inhibited bymethylene blue suggesting activation of soluble guanylate cyclase,this would be consistent with our results showing that the CPTIO-resistantcomponent is sensitive to ODQ. This explanation would be inadequateto explain the CPTIO-resistant relaxation to ACH particularlyin diabetic rings for two reasons. First, the lipophilic nitronylnitroxide, PTIO, used alone or in combination with CPTIO (seebelow) caused further inhibition. Second, addition of CPTIO afteraddition of ACH completely abolished ACH-mediated relaxation inboth groups and restored tension to above baseline.

Role of sequestration of ·NO in the lipid phase. Previous cell-free studies using nitroxide compounds (rather than nitronyl nitroxides) suggest that ·NO might partition inlipid environments (Singh et al., 1994). In fact, at least tworeports suggest that ·NO might be sequestered in large quantititiesin lipid bilayers (Lancaster, 1996; Denicola et al., 1996). Thus,we considered the possibility that some of the ·NO escapes reactionwith CPTIO (as with our previous studies using MGDFe) due to thefact that both are predominately water-soluble agents and, therefore,might be unable to effectively counteract the high diffusibilityof ·NO under agonist-stimulated conditions.

To evaluate this contingency, we performed additional experiments using a structurally related ·NO antagonist, PTIO, whichhas a 100-fold increase in lipophilicity. PTIO used either aloneor in combination with CPTIO also failed to alter relaxation toACH in control rings suggesting that lipid sequestration mightnot account for the portion resistant to relaxation in normalblood vessels. Interestingly, the addition of PTIO partially inhibitedthe relaxation to ACH only in diabetic rings and in an amountgreater than that achieved by CPTIO alone. The results in controlrings show that there was no difference in the degree of inhibitionof relaxation to ACH by PTIO and CPTIO suggesting that this couldnot be explained simply on an intrinsic difference in potencybetween the two nitronyl nitroxides.

Alternatively, potential alterations in the lipid composition in diabetic membranes might sequester more PTIO than in controlmembranes. This is an attractive explanation for other reasonsbecause this lipid environment could serve as a reservoir for·NO increasing the probability of inactivation by interactionwith fatty acids, especially peroxyl radicals that are known toreact with ·NO (Padmaja and Huie, 1993

). This would reduce theeffective ·NO activity and be consistent with the observationof decreased endothelium-dependent relaxation in diabetic bloodvessels. Nevertheless, the potential increased sequestration cannotaccount for all of the (CPTIO + PTIO)-resistant portion of relaxationto ACH because a significant portion equivalent to 30% remainedin both control and diabetic rings.

In summary, use of nitronyl nitroxides rather than reliance solely on NOS inhibition has allowed a greater understanding ofthe role of ·NO in endothelium-dependent relaxation in controland diabetic blood vessels. Our studies suggest a large portionof relaxation to ACH in control blood vessels is mediated by ·NObut an additional portion that is larger in diabetic blood vesselsmay be another species derived either directly or indirectly fromthe NOS reaction. Furthermore, our studies suggest that the lipidfraction of diabetic blood vessels may serve as a larger sinkfor sequestration of ·NO that may potentially limit its biologicalaction on diabetic vascular smooth muscle.

	Footnotes

Accepted for publication June 16, 1997.

Received for publication March 24, 1997.

¹ This work was supported by Grant HL47072 from the National Institutes of Health, Heart and Lung Institute.

Send reprint requests to: Dr. Galen M. Pieper, Department of Transplant Surgery, Medical College of Wisconsin, Froedtert Memorial Lutheran Hospital, 9200 West Wisconsin Avenue, Milwaukee WI 53226.

	Abbreviations

ACH, acetylcholine; PE, phenylephrine; ·NO, nitric oxide radical; NOS, nitric oxide synthase; L-NA, L-nitroarginine; EDRF, endothelium-derived relaxing factor; CPTIO, 2-(4-carboxyphenyl)-4,4,5,5-tetramethylimidazoline-1-oxyl-3 oxide; PTIO, 2-phenyl-4,4,5,5-tetramethylimidazoline-1-oxyl-3 oxide; ONOO, peroxynitrite; ODQ, 1H-[1,2,4]oxadiazolo[4,3,-a]quinoxaline-1-one; TEA, tetraethylammonium; MGDFe, N-methyl-D-glucamine dithiocarbamate-Fe⁺⁺; EDHF, endothelium-derived hyperpolarizing factor.

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Use of a Nitronyl Nitroxide to Discriminate the Contribution of Nitric Oxide Radical in Endothelium-Dependent Relaxation of Control and Diabetic Blood Vessels1

Use of a Nitronyl Nitroxide to Discriminate the Contribution of Nitric Oxide Radical in Endothelium-Dependent Relaxation of Control and Diabetic Blood Vessels¹