485umb_tanaka.qxd

Naunyn-Schmiedeberg’s Arch Pharmacol (2001) 364 : 538–550DOI 10.1007/s002100100485 Fumiko Yamaki · Momoko Kaga · Takahiro Horinouchi ·
Hikaru Tanaka · Katsuo Koike · Koki Shigenobu ·
Ligia Toro · Yoshio Tanaka

MaxiK channel-mediated relaxation of guinea-pig aorta following stimulation of IP receptor with beraprost via cyclic AMP-dependent and -independent mechanisms Received: 12 March 2001 / Accepted: 24 August 2001 / Published online: 23 October 2001 Abstract The present study was aimed to elucidate the
did not affect beraprost-induced relaxation though it al- cellular pathway(s) controlling vascular relaxation triggered most totally inhibited the elevation of cyclic AMP con- by stimulation of prostaglandin I2 (PGI2, IP) receptor tents induced by beraprost, suggesting the existence of anwith a stable PGI2 analog, beraprost. Beraprost caused a additional mechanism that is cyclic AMP-independent.
concentration-dependent relaxation in de-endothelialized Moreover, cholera toxin (CTX, 1 µg/ml for 6 h), which guinea-pig aorta contracted with prostaglandin F2α (PGF2α).
activates the stimulatory G protein of adenylyl cyclase Beraprost-induced relaxation was almost abolished in (Gs), significantly suppressed PGF2α-induced contraction high-KCl-contracted tissue, indicating a major role of K+ both in the absence and presence of SQ 22,536 (10–4 M).
conductances. In contrast to other PGI2 analogs (e.g. ci- Iberiotoxin (10–7 M) was also capable of restoring the re- caprost and iloprost), beraprost-induced relaxation was prac- laxation induced by CTX. These findings suggest that tically abolished by a selective voltage and Ca2+-activated MaxiK channel plays a primary role in mediating smooth K+ (MaxiK, BK) channel blocker Iberiotoxin (10–7 M) or muscle relaxation following stimulation of IP receptor with by tetraethylammonium (2×10–3 M). The relaxation in- beraprost in guinea-pig aorta. Both cyclic AMP-depen- duced by beraprost was not significantly affected by other dent and -independent pathways contribute to the MaxiK K+ channel blockers glibenclamide (10–6 M) or Ba2+ (10–5 M), channel-mediated relaxation following IP receptor stimu- but was slightly attenuated by 4-aminopyridine (10–4 M).
lation in this vascular tissue. Direct regulation of MaxiK Beraprost increased intracellular cyclic AMP levels, sug- channels by Gs may partly account for the cyclic AMP-in- gesting a role for cyclic AMP-dependent pathways. A se- lective inhibitor of cyclic AMP-specific phosphodiesterase,RO-20-1724 (10–4 M), significantly potentiated beraprost- Keywords Adenosine 3’:5’-cyclic monophosphate ·
induced relaxation. Iberiotoxin (10–7 M) completely coun- Beraprost · BK channel · Cholera toxin · Guinea-pig teracted this potentiation. Moreover, tension decrement due aorta · Iberiotoxin · MaxiK channel · Prostaglandin I2 to forskolin (3×10–7 M) or 8-bromo-cyclic AMP (10–2 M) receptor · SQ 22,536 · Stimulatory G protein of adenylyl was thoroughly restored by Iberiotoxin (10–7 M), confirm- ing a role for a cyclic AMP-dependent mechanism. How-ever, SQ 22,536 (10–4 M), an adenylyl cyclase inhibitor, Prostaglandin I2 (PGI2, prostacyclin) is an arachidonic F. Yamaki · M. Kaga · H. Tanaka · K. Shigenobu · Y. Tanaka (✉) acid metabolite of the cyclooxygenase pathway, which is Department of Pharmacology, Toho University School of Pharmaceutical Sciences, synthesized mainly in vascular endothelial cells but also Miyama 2-2-1, Funabashi-City, Chiba 274-8510, Japan in vascular smooth muscle cells (Leffler 1997; Moncada et al. 1977; Narumiya et al. 1999). Although PGI2 itself Tel.: +81-47-4722099, Fax: +81-47-4722113 potently inhibits vascular tone as well as platelet aggrega- tion, a number of stable PGI2 analogues have been devel- oped for clinical use since the half-life of PGI2 is less than Toho University School of Pharmaceutical Sciences, Miyama 2-2-1, Funabashi-City, Chiba 274-8510, Japan logues (iloprost, cicaprost, beraprost) inhibit vascular contractions in guinea-pig aorta (Clapp et al. 1998; Ozaki Departments of Anesthesiology and Molecular et al. 1996), rat mesenteric and tail arteries (Adeagbo and and Medical Pharmacology, and Brain Research Institute, UCLA School of Medicine, Los Angeles, CA 90095, USA Malik 1990; Schubert et al. 1997), and dog arteries (cere- bral, carotid, mesenteric, renal, femoral arteries; Akiba et ing cyclic AMP-independent MaxiK channel activation al. 1986; Siegel et al. 1989). Moreover, PGI2 analogues and muscle relaxation? (4) Does stimulatory G protein seem to be beneficial in the treatment of circulatory disor- of adenylyl cyclase (Gs) produce MaxiK channel-medi- ders especially for pulmonary hypertension (Wise and ated vascular relaxation independent of cyclic AMP? In Jones 1996). Thus, uncovering the mechanisms by which the present study, we addressed these questions using PGI2 and its analogues relax vascular smooth muscle is guinea-pig aorta and a different PGI2 analog, beraprost relevant from both physiological and therapeutic points of (TRK-100; Akiba et al. 1986; Murata et al. 1989). Our re- sults demonstrate that in guinea-pig aorta, both cyclic Increasing electrophysiological and pharmaco-mechan- AMP-dependent and cyclic AMP-independent mecha- ical evidence suggests that PGI2 analogues exhibit their nisms mediate the IP agonist-induced relaxation via acti- vasorelaxant actions through activation of plasma mem- vation of MaxiK channels. The cyclic AMP-independent brane K+ channels, which leads to membrane hyperpolar- mechanism is predominant in this vessel and cholera toxin ization. Recent studies have focused on the role of the experiments suggest that it may be due to a direct action large conductance Ca2+-activated K+ (MaxiK, BK) chan- nel in the relaxant effects of PGI2 analogues, iloprost andcicaprost (Clapp et al. 1998; Dumas et al. 1997; Schubertet al. 1996, 1997). It is likely that activation of MaxiK channels with the resultant membrane hyperpolarizationlimits sarcolemmal Ca2+ influx through L-type voltage- Hartley guinea-pigs of either sex (Oriental Yeast, Tokyo, Japan)were housed under controlled conditions (temperature 21°–22°C, gated Ca2+ channels, and thus, produces vascular relax- relative air humidity 50±5%). Food and water were available ad li- ation by decreasing cytoplasmic Ca2+ levels ([Ca2+]cyt) bitum to all animals. This study was conducted in accordance with (Nelson and Quayle 1995; Toro et al. 1998). Consistent the Guideline for the Care and Use of Laboratory Animals adopted with the observations in pharmaco-mechanical studies, the by the Committee on the Care and Use of Laboratory Animals ofToho University School of Pharmaceutical Sciences (accredited by PGI2 receptor (IP receptor) agonist iloprost has been the Ministry of Education, Science, Sports and Culture, Japan).
shown to increase MaxiK channel current in isolated arte-rial cells (Schubert et al. 1996, 1997). On the other hand, Preparation of thoracic aortic rings. A section of the thoracic in some blood vessels like rat cerebral (Lombard et al.
aorta between aortic arch and diaphragm was removed and placedin normal Tyrode’s solution (mM): NaCl, 158.3; KCl, 4.0; CaCl 1999), pulmonary (Dumas et al. 1997) and tail arteries (Schubert et al. 1997), and rabbit coronary vessels (Jack- 2, 1.05; NaH2PO4, 0.42; NaHCO3, 10.0 and glucose, 5.6.
The aorta was cleaned of loosely adhering fat and connective tis- son et al. 1993), the ATP-sensitive K+ (KATP) channel sue. To remove the endothelium, a thread moistened with normal seems to also play a substantial role in the vascular relax- Tyrode’s solution was inserted into the internal side of the blood vessel. The internal surface was gently rubbed by rolling the thread using fingers on the palm covered with a rubber glove. The aorta tion of K+ channel subtypes to vascular relaxations due to was cut into ring segments about 2 mm in length.
PGI2 analogues may vary depending on the vascular bedemployed, and on the relative expression and/or colocal- Measurement of tension changes. The ring segments were mounted ization of different proteins in each vascular bed.
using stainless steel hooks (outer diameter, 200 µm) under the op-timal resting tension of 1.0 g (Tanaka et al. 2000) in a 5-ml organ PGI2 and its analogs elevate intracellular adenosine bath (UC-5; UFER Medical Instrument, Kyoto, Japan) containing 3’:5’-cyclic monophosphate (cyclic AMP) levels due to normal Tyrode’s solution. Tension changes of the muscle prepara- activation of adenylyl cyclase via the specific cell surface tion were isometrically recorded with a force-displacement trans- IP receptor-coupled guanine nucleotide regulatory pro- ducer (T7-8-240; Orientec, Tokyo, Japan) connected to a minipoly-graph (RM-6100; Nihon Kohden, Tokyo, Japan or Signal Condi- tein, Gs (Leffler 1997; Narumiya et al. 1999; Wise and tioner: Model MSC-2; Labo Support, Suita-City, Japan). Ring prepa- Jones 1996). Concomitantly in rat tail artery, it is thought rations were equilibrated for 60–90 min prior contraction with iso- that channel phosphorylation by cyclic AMP-dependent tonic high-KCl (80 mM) Tyrode’s solution (mM): NaCl, 82.3; protein kinase (PKA) is responsible for the MaxiK chan- KCl, 80.0; CaCl2, 2.0; MgCl2, 1.05; NaH2PO4, 0.42; NaHCO3, nel-mediated vascular relaxation due to IP receptor stimu- 10.0 and glucose, 5.6. After washing out, the absence of endothe-lial cells was confirmed by the lack of relaxation induced by lation by iloprost (Schubert et al. 1996, 1997). In contrast, acetylcholine (ACh; 10–5 M), and experiments were started after a in guinea-pig aorta, cyclic AMP-independent pathways 30-min equilibration period. Normal Tyrode’s solution was contin- were recently proposed to underlie the relaxation induced uously gassed with 95% O2 – 5% CO2, and kept at 36.5±0.5°C 2 analogues, iloprost and cicaprost (Clapp et al.
1998; Turcato and Clapp 1999). Although these mecha- Relaxant effects of test compounds on the contractions induced by nistic differences may be attributed to the nature of the prostaglandin F2α or high-KCl. To investigate the relaxation in- vascular beds or species, there are several questions that duced by test compounds beraprost, cromakalim, forskolin and remain unanswered: (1) Do cyclic AMP-dependent and membrane-permeant cyclic nucleotides, aorta was contracted with -independent mechanisms co-regulate MaxiK channel and 2α (PGF2α; 10–5 M) or high-KCl (80 mM). After the muscle contractions reached a steady-state level, test compounds vascular smooth muscle relaxation mediated via IP recep- were applied cumulatively to the bath medium. Concentration-re- tor occupancy in the same vessel (i.e. guinea-pig aorta)? sponse relationships were obtained by measuring the relaxant ef- (2) Is MaxiK channel activation involved in the IP recep- tor-triggered relaxation mediated via cyclic AMP-inde- Effects of K+ channel blockers, RO-20-1724, SQ 22,536 and ODQ. pendent pathways? (3) What are the mechanisms underly- Possible involvement of the activation of K+ channels in drug-in- duced vasorelaxation was examined in the absence and presence of penta [b] benzofuran-5-butyrate (beraprost sodium) was kindly do- several K+ channel blockers. K+ channel blockers used in the pre- nated by Toray Industries (Kamakura-City, Kanagawa, Japan).
sent study were: Iberiotoxin (10–7 M) and tetraethylammonium Cromakalim was a kind gift from Nissan Chemical Industries (TEA; 2×10–3 M) as MaxiK channel blockers; glibenclamide (Tokyo, Japan). Other chemicals were: prostaglandin F2α (PGF2α), (10–6 M) as KATP channel blocker; Ba2+ (10–5 M) as inward recti- 7-[3-[[2-[(phenylamino)carbonyl]hydrazino]methyl]-7-oxabicyclo fier K+ channel blocker; and 4-aminopyridine (4-AP; 10–4 M) as [2.2.1]hept-2-yl]-, [1S-[1α,2α(Z),3α,4α]]-5-heptenoic acid (SQ delayed rectifier K+ (Kv) channel blocker. Iberiotoxin, TEA, Ba2+ 29,548) (Cayman Chemical, Ann Arbor, Mich., USA); l-noradren- and 4-AP were added to the bath 20 min before starting cumulative aline bitartrate (NA), forskolin, papaverine hydrochloride (Wako application of test compounds. Glibenclamide was applied to the Pure Chemical Industries, Osaka, Japan); acetylcholine chloride bath solution 20 min before application of PGF2α. For forskolin- (ACh; Daiichi, Tokyo, Japan); Iberiotoxin (Peptide Institute, Minoh- and 8-bromo-cyclic AMP-induced relaxation, Iberiotoxin (10–7 M) Shi, Osaka, Japan); glibenclamide (Sigma, St. Louis, Mo., USA); was applied to the bath medium after the relaxant responses had 8-bromo-cyclic AMP, dibutyryl cyclic AMP (BIOLOG Life Sci- reached a steady-state level; in this case, the reversion of relax- ence Institute, Bremen, Germany); 9-(tetrahydro-2-furanyl)-9H- purin-6-amine (SQ 22,536) (Research Biochemicals International, RO-20-1724 (10–4 M; 4-(butoxy-4-methoxybenzyl)-2-imidazo- Natick, Mass., USA); 4-(butoxy-4-methoxybenzyl)-2-imidazolidi- lidinone), a selective inhibitor of cyclic AMP-specific phosphodi- none (RO-20-1724), 1H-[1,2,4]oxadiazolo[4,3a]quinoxaline-1-one esterase (soluble cyclic GMP-insensitive type IV PDE; Katano and (ODQ) (Biomol Research Laboratories, Plymouth Meeting, Pa., Endoh 1990), was added to the bath solution 20 min before stimu- USA); nitroglycerin (Nihon Kayaku, Tokyo, Japan); cholera toxin lation with PGF2α (10–5 M) or after beraprost (10–7 M)-induced re- (CTX; List Biological Laboratories, Campbell, Calif., USA). All laxation reached a steady-state level.
other reagents used were commercially available and of reagent SQ 22,536 (10–4 M; 9-(tetrahydro-2’-furyl)adenine), an adenylyl cyclase inhibitor, was added to the bath solution 20 min before cu- PGF2α, forskolin and RO-20-1724 were dissolved in pure mulative application of beraprost. ODQ (10–5 M; 1H-[1,2,4]oxa- ethanol as a stock solution at 10–2 M. Cromakalim was dissolved in diazolo[4,3a]quinoxaline-1-one), an inhibitor of soluble guanylyl 70% ethanol at 10–2 M. Glibenclamide was dissolved in pure di- cyclase, was applied to the bath solution when the relaxation due methyl sulfoxide (DMSO) at 10–3 M. SQ 29,548 was dissolved in to beraprost (10–5 M) or nitroglycerin (10–5 M) reached a steady- 100% ethanol at 10–2 M. ODQ was dissolved in 100% DMSO at 10–2 M. Dilutions were performed in water. Final ethanol andDMSO concentrations in the bath medium did not exceed 1% and Determination of tissue cyclic AMP contents. Thoracic aortas were 0.1%, respectively, which did not affect the vascular responses. All cut into segments about 15 mm in length and cleaned of loosely drugs are expressed in molar concentrations in bathing solution.
adhering fat and connective tissue. Endothelium was removed asdescribed for contraction studies. Each aorta was opened along the Analysis and statistics. The percentage of relaxation was calcu- longitudinal axis of the artery to prepare a flat sheet. Each sheet lated by considering the maximum tension level obtained just be- was incubated in organ bath containing normal Tyrode’s solution fore addition of vasorelaxants as 0% relaxation, and the full recov- (25 ml) which was continuously gassed with 95% O2 – 5% CO2 ery to the basal tension before application of PGF2α (10–5 M), NA and maintained at 36.5±0.5°C (pH=7.35). After 60-min incuba- (3×10–6 M) or high-KCl (80 mM) as 100% relaxation. Data were tion, artery segments were exposed to beraprost (10–5 M) or plotted as a function of drug concentrations and fitted to the equa- forskolin (10–5 M) for 20 min. When treated with SQ 22,536, this adenylyl cyclase inhibitor (10–4 M) was applied to the bath me- dium 20 min before stimulation with beraprost. At the end of the protocol, tissues were rapidly frozen in liquid N2 to terminate the where E is the % relaxant response at a given drug concentration, reaction. The arteries were homogenized in 6% trichloroacetic acid (TCA) solution and then centrifuged at 3000 rpm for 15 min at max is the maximum relaxant response, A is the concentration of 5°C. The supernatant fraction and the tissue pellets were used for H is the slope function and EC50 is the effective drug concentration that produces a 50% response. Curve fitting was per- the measurement of cyclic AMP and protein contents, respectively.
formed using GraphPad Prism (version 2.01; GraphPad Software, The cyclic AMP in the supernatant was extracted with water- saturated ether for four times to remove TCA and then lyophilized.
Cyclic AMP contents were measured using an enzyme-immunoas- 50 (the drug concentration required to induce 50% inhibition) were also determined from the concentration-re- say system (Amersham Pharmacia Biotech UK, Buckinghamshire, sponse relationship of individual experiments and expressed as UK). Tissue pellets were dissolved in 2 ml NaOH for protein de- termination (Lowry et al. 1951). The cyclic AMP contents were 50 (negative logarithm of IC50) for statistical analysis.
Data are presented as means ± SEM and n refers to the number expressed as picomoles per milligram of sample protein. In these of experiments. The significance of the difference between mean measurements, vascular tissues were not exposed to phosphodi- values was evaluated with GraphPad Prism by paired or unpaired esterase inhibitors since the inhibitors could elevate cyclic AMP to t-test, unpaired t-test with Welch’s correction if necessary, and extremely unphysiologically high levels, and as a consequence one-way analysis of variance (ANOVA) followed by Tukey’s mul- could elevate cyclic GMP levels, both of which may complicate tiple comparison test. A P-value less than 0.05 was considered sta- the interpretation of data (Turcato and Clapp 1999).
Inhibitory effects of cholera toxin on PGF2α-induced contraction. Aortic tissues were pre-contracted with PGF2α (10–5 M) and then were incubated with cholera toxin (CTX; 1 µg/ml) in the continued presence of PGF2α for 6 h. During the incubation with CTX, bath solution was exchanged after 3 h with a fresh solution containing Beraprost induces relaxation of guinea-pig aorta mainly PGF2α (10–5 M) plus CTX (1 µg/ml). In a separate series of exper- iments, aortic tissues were first contracted with PGF2α (10–5 M) and washed out with fresh normal Tyrode’s solution. After themuscle tension returned to the basal level, the tissue was incubated First, we determined whether activation of K+ channels is with CTX (1 µg/ml) for 6 h with a fresh solution exchange after involved in the relaxation induced by the IP receptor ago-3 h during the incubation. After 6 h, the muscle tissue was again nist beraprost in guinea-pig aorta. This was investigated by comparing the beraprost-induced relaxation in muscles Sodium (±)-(1R,2R,3aS,8bS)-2,3,3a,8b-tetrahydro-2-hy- contracted with PGF2α and high-KCl, which was used to droxy-1-[(E)-(3S)-3-hydroxy-4-methyl-1-octen-6-ynyl]-1H-cyclo- abolish the driving force for K+ efflux and the subsequent At concentration ranges over 10–6 M, a small contractioninstead of relaxation was attained by beraprost (Fig. 1B).
Note that PGF2α and high-KCl induced similar contrac-tion levels (Fig. 1C), indicating that the lack of beraprost-induced relaxation with high-KCl is not due to an excesscontractile response with KCl. pIC50 values for beraprostagainst the contractions induced by PGF2α (10–5 M) andhigh-KCl (80 mM), and the maximum relaxant responsesare shown in Table 1. These observations strongly indi-cate that the relaxation of guinea-pig aorta in response toberaprost is mainly mediated via an activation of plas-malemmal K+ channels.
MaxiK channels are key contributors of beraprost-induced relaxation MaxiK channel activation partially contributes (~40%–50%) to the relaxation induced by the IP agonists iloprostand cicaprost (Clapp et al. 1998). However, it is notknown whether MaxiK channels are involved in bera-prost-induced relaxation and to what extent. As shown inFig. 2A,B, beraprost-induced relaxation was concentra-tion-dependent and was strongly diminished in the prepa-rations treated with the MaxiK channel blocker, Ibe-riotoxin (10–7 M). Similarly, tetraethylammonium TEA (2×10–3 M), which blocks MaxiK channels at this concen-tration, strongly inhibited beraprost-induced relaxation (Fig. 2C). Note that MaxiK channels contribute by ~80%to the beraprost-induced relaxation as assessed by bothMaxiK channel blockers (Iberiotoxin and TEA; Fig. 2B,C;Table 1). These observations strongly indicate that activa-tion of MaxiK channel plays a major role in the relaxationinduced by beraprost in guinea-pig aorta, and that be- Fig. 1A–C High-KCl suggests a primary role of K+ channels in
beraprost-induced relaxation of guinea-pig aorta. A Typical me-
raprost is a better MaxiK channel activator than iloprost chanical traces showing the relaxant effect of beraprost on the con- traction induced by PGF2α (10–5 M; upper trace) or high-KCl (80 mM; lower trace). Numbers are the negative logarithm of be-raprost concentration. SQ 29,548, an antagonist of PGF2α, was added at the end of the experiment and produced near 100% relax- ation. Papaverine was used to test the ability of the muscle to relax.
B Concentration-response relationships for the relaxant effect of
beraprost in rings precontracted with PGF2α (❍) or high-KCl (●).
The effect of glibenclamide on beraprost-induced relax- Percentage of vascular relaxation is calculated with respect tobasal tension (100% relaxation) and PGF ation was examined to determine whether the activation (80 mM) steady-state contractile responses (0% relaxation). Data of ATP-sensitive K+ (KATP) channel significantly con- are means ± SEM of 4–6 experiments. *P<0.05, **P<0.01 signif- tributes to the relaxant response as is the case of iloprost icant differences between two groups. C Contractions of guinea-
in rat arteries (Dumas et al. 1997; Schubert et al. 1997).
pig aorta in response to PGF2α (10–5 M) and high-KCl (80 mM).
Glibenclamide (10–6 M) was not able to prevent be- The contractions are normalized with respect to high-KCl (80 mM)-induced muscle tension obtained at the beginning of experiments raprost-induced relaxation in guinea-pig aorta (Fig. 3A;Table 2). As control, when cromakalim, a KATP channelopener, was used to cause relaxation, glibenclamide membrane hyperpolarization. Figure 1A shows represen- (10–6 M) almost abolished its relaxant effect (Fig. 3B).
tative traces for the relaxant effect of beraprost on the These findings rule out the role of KATP channel as a mechanism by which beraprost causes relaxation of lated guinea-pig aorta. Beraprost (3×10–8–3×10–5 M) clearly elicited a concentration-dependent relaxation in the mus- In the next series of experiments, we examined the ef- fects of Ba2+ (an inward rectifier K+ channel blocker) and contracted with noradrenaline (3×10–6 M; not shown). On 4-AP (a voltage-dependent K+ (Kv) channel blocker) to the other hand, beraprost-induced relaxation was strongly determine whether the activation of these K+ channels diminished in vessels contracted with high-KCl (80 mM).
contributes to beraprost-induced relaxation. Ba2+ (10–5 M) Table 1 Effects of high-KCl and MaxiK channel blockers on the
beraprost; also represented as % change with respect to high-KCl relaxation induced by beraprost in guinea-pig aorta. Tension (g) is (80 mM)-induced contraction obtained at the beginning of experi- the muscle tension developed by PGF2α, high-KCl and PGF2α in ments. pIC50 and Emax values refer to the relaxation induced by the absence or presence of MaxiK channel blockers (Iberiotoxin; 3×10–5 M beraprost. Results are represented as means ± SEM of n tetraethylammonium, TEA) just before cumulative application of an=5bResponse obtained by 3×10–7 M beraprost**P<0.01 significant differences between two groups Fig. 2A–C MaxiK channel blockers prevent the relaxation induced
concentrations, suggesting a minor role of Kv channels in by beraprost in guinea-pig aorta. A Typical mechanical traces
the beraprost-induced relaxation of guinea-pig aorta.
showing the relaxant effect of beraprost on the contraction induced Higher concentrations of Ba2+ and 4-AP were difficult to by PGF2α (10–5 M) in the absence (left trace) and presence (right assess in this blood vessel since both agents caused an in- trace) of Iberiotoxin (IbTX, 10–7 M). Numbers are the negative log- crease in basal tension (not shown).
arithm of beraprost concentration. Addition of SQ 29,548 (10–5 M),
an antagonist of PGF2α, produced almost 100% relaxation. B, C
Concentration-response relationships for beraprost-induced vascu-
lar relaxation in the absence (❍, control) and presence (●) of
Iberiotoxin (10–7 M; B) and TEA (2×10–3 M; C). Vascular relax-
An inhibitor of cyclic AMP-specific phosphodiesterase, ation was calculated with respect to basal tension (100% relax- RO-20-1724, reveals a cyclic AMP-dependent ation) and steady-state contractile responses to PGF2α (10–5 M) or PGF2α plus Iberiotoxin or TEA (0% relaxation). Note that Iberio- toxin (10–7 M) and TEA (2×10–3 M) further enhanced muscle ten-sion due to PGF2α from 1.88±0.09 g to 1.95±0.10 g (n=6 for each, P<0.05), and from 2.48±0.15 g to 2.73±0.18 g (n=5 for each, Cyclic AMP has been thought to be the key intracellular P>0.05), respectively. Data are means ± SEM of 5–6 experiments.
messenger mediating vascular smooth muscle relaxation *P<0.05, **P<0.01 significant differences between two groups after stimulation of IP receptors (Kukovetz et al. 1979;Miller et al. 1979; Ozaki et al. 1996). However, in guinea- did not significantly affect beraprost-induced relaxation pig aorta an inhibitor of adenylyl cyclase, SQ 22,536, did (Fig. 3C; Table 2). However, 4-AP (10–4 M; Fig. 3D; Table 2) not prevent relaxation by the IP agonist iloprost, suggest- had a modest but significant inhibitory effect at higher ing that iloprost-induced relaxation is exclusively medi- Fig. 3A–D 4-Aminopyridine (4-AP) but not glibenclamide or
(n=4 for each, P>0.05), and 2.10±0.23 g to 2.21±0.24 g (n=6, Ba2+ (10–5 M) affect beraprost-induced relaxation in guinea-pig P<0.05), respectively. Data are means ± SEM of 4–7 experiments.
aorta. A,C,D Concentration-response relationships for the relax-
*P<0.05 significant differences between two groups. B Concentra-
ation induced by beraprost in the absence (❍, control) and pres- tion-response relationships for the relaxation induced by cro- ence (●) of glibenclamide (10–6 M; A), Ba2+ (10–5 M; C) and 4-AP
makalim in the absence (❍, control) and presence (●) of gliben- (10–4 M; D). Vascular relaxation was calculated with respect to
clamide (10–6 M). Vascular relaxation is expressed as percent inhi- basal tension (100% relaxation) and steady-state contractile re- bition against the tension elevation just before addition of cro- sponses to PGF2α (10–5 M) or PGF2α plus Ba2+ or 4-AP (0% relax- makalim. Data are means ± SEM of four experiments. *P<0.05, ation). Note that Ba2+ (10–5 M) and 4-AP (10–4 M) changed the **P<0.01 significant differences between two groups muscle tension due to PGF2α from 2.11±0.17 g to 2.18±0.18 g Table 2 Effects of K+ channel blockers, RO-20-1724 and SQ
22,536 (adenylyl cyclase inhibitor) just before cumulative admin- 22,536 on the relaxation induced by beraprost in guinea-pig aorta istration of beraprost; also represented as % change of high-KCl contracted with PGF2α (10–5 M). Tension (g) is the muscle tension (80 mM)-induced contraction obtained at the beginning of experi- development due to PGF2α (10–5 M; control) or PGF2α (10–5 M) ments. pIC50 and Emax values refer to the relaxant effects of 3×10–5 plus K+ channel blockers (glibenclamide, Ba2+, 4-aminopyridine), M beraprost. Results are represented as means ± SEM of n number RO-20-1724 (cAMP-specific phosphodiesterase inhibitor) or SQ *P<0.05 significant differences between two groups ated by cyclic AMP-independent mechanisms (Turcato slightly inhibited by the K+ channel blocker TEA (Clapp and Clapp 1999). In line with this view, relaxation by et al. 1998), raising the possibility (but not demonstrating) forskolin, an activator of adenylyl cyclase, was only that IP-agonists activate MaxiK channels solely by cyclic Fig. 4B). Note that muscle tension decrement due to RO-20-1724 (10–4 M) alone was only 3.9±1.2% (n=3).
These mechanical studies with RO-20-1724 indicate thatberaprost elevates intracellular cyclic AMP contents, andprovide direct evidence that cyclic AMP-dependentmechanisms also participate in beraprost-induced relax-ation via opening of MaxiK channels in this blood vessel.
Forskolin and 8-bromo-cyclic AMP mimic the beraprost-induced relaxation via activation of MaxiK channels In the next series of experiments, we bypassed IP-receptorstimulation and determined whether cyclic AMP-mediatedrelaxation can be attributed to the activation of MaxiKchannels using the specific blocker Iberiotoxin. For thispurpose, we used two agents as vasorelaxants: forskolin, adirect activator of adenylyl cyclase, and 8-bromo-cyclicAMP, a membrane permeant cyclic AMP analogue. Fig-ure 5A shows the effects of pretreatment with Iberiotoxinon the relaxation induced by forskolin. Forskolin (10–9–10–5 M) fully relaxed PGF2α (10–5 M)-contracted musclein a concentration-dependent fashion. As previously ob-served for TEA (Clapp et al. 1998), forskolin-induced re- Fig. 4 A, B Potentiation of beraprost-induced relaxation by a cyclic
laxation was not significantly affected by pretreatment AMP-specific phosphodiesterase inhibitor, RO-20-1724: inhibi- with Iberiotoxin (10–7 M). However, forskolin-induced re- tion by a MaxiK channel blocker. A Concentration-response rela-
laxation was substantially diminished in the muscle con- tionships for beraprost-induced relaxation in the absence (❍, con-trol) and presence (●) of RO-20-1724 (10–4 M). Vascular relax- tracted with high-KCl (80 mM). pIC50 value of forskolin ation is expressed as percent inhibition against the tension eleva- against high-KCl-induced contraction (5.72±0.28, n=6) tion due to PGF2α (10–5 M) just before addition of beraprost. Data was significantly different from the values obtained with are means ± SEM of six experiments. *P<0.05 significant differ- PGF2α-induced contractions in the absence and presence ences between two groups. B Iberiotoxin inhibits the RO-20-1724-
of Iberiotoxin (6.90±0.27, n=13 and 6.91±0.19, n=8; induced potentiation of relaxation by beraprost. RO-20-1724 (10–4 M) was applied to the bath after beraprost (10–7 M)-induced P<0.01, one-way ANOVA), indicating the participation of relaxation reached a steady-state level. Iberiotoxin (10–7 M) was K+ channels in the forskolin-induced relaxation. There- administered after the relaxant response of beraprost was potenti- fore, we decided to apply Iberiotoxin (10–7 M) during the ated by RO-20-1724. RO-20-1724 (10–4 M) alone had a small re- muscle relaxation with forskolin. In this case, the toxin laxant effect. Data are means ± SEM of 3–4 experiments. Meanabsolute values of the tension development in response to PGF completely counteracted the tension decrease caused by (10–5 M) were 2.51±0.20 g (n=4; preparations used for the relax- forskolin (3×10–7 M; Fig. 5B). Consistent with a role of ation by beraprost) and 2.13±0.43 g (n=3; preparations used for the MaxiK channels in forskolin-induced relaxation, pretreat- relaxation by RO-20-1724). a)**P<0.01 significant differences ment with TEA (2×10–3 M) slightly but significantly at- from control (beraprost alone), b)**P<0.01 significant differencesfrom the response to beraprost (10–7 M) plus RO-20-1724 (10–4 M) tenuated forskolin-induced relaxation at some concentra-tions (Fig. 5C), which was further confirmed by a signifi-cant decrease in the pIC50 value (control, 6.54±0.18, n=6 AMP-independent mechanisms in this blood vessel.
vs. TEA, 5.95±0.16, n=8; P<0.05).
Therefore, we examined the role of cyclic AMP and di- To elucidate further the role of cyclic AMP in MaxiK rectly tested the participation of MaxiK channels in the re- channel-mediated vascular relaxation, the effect of Iberio- laxation induced by beraprost in guinea-pig aorta. To this toxin on the relaxation induced by 8-bromo-cyclic AMP end, we used several pharmacological tests on beraprost- was investigated. In this vascular preparation, 8-bromo- induced relaxation using agonists and antagonists of cyclic cyclic AMP elicited relaxation at concentration ranges over 10–3 M, and the relaxation obtained by 10–2 M 8-bromo- Figure 4A shows the effect of the cyclic AMP-specific cyclic AMP was 61.0±6.9% (n=6; Fig. 5D). A similar phosphodiesterase inhibitor RO-20-1724 on the relaxation concentration-response relationship was also obtained for induced by beraprost. In the presence of RO-20-1724 the relaxation induced by another membrane-permeant (10–4 M), beraprost-induced relaxation was significantly cyclic AMP analog, dibutyryl-cyclic AMP (pIC50, 2.76; potentiated, as seen from the significant increases in both Emax, 74.3% at 3×10–3 M, n=2 for each). In this case, ap- the pIC50 value and the maximum relaxant response (see plication of Iberiotoxin during relaxation was not neces- also Table 2). Furthermore, this potentiation was com- sary since pretreatment with Iberiotoxin (10–7 M) almost pletely counteracted by addition of Iberiotoxin (10–7 M; completely eliminated 8-bromo-cyclic AMP-elicited re- Fig. 5A–E MaxiK channel blockers also inhibit the relaxations in-
laxation (Fig. 5D vs. Fig. 5A). As expected, when Iberio- duced by forskolin and 8-bromo-cyclic AMP in guinea-pig aorta.
toxin (10–7 M) was applied during the muscle relaxation, A,B Iberiotoxin inhibits forskolin-induced relaxation depending
it completely restored the tension previously decreased by on the application sequence. Iberiotoxin (10–7 M) applied prior 10–2 M 8-bromo-cyclic AMP (Fig. 5E) as with the case of forskolin treatment was unable to prevent forskolin-induced relax-
ation (A). However, Iberiotoxin (10–7 M) applied during forskolin
forskolin (Fig. 5B). These results strongly suggest that (3×10–7 M)-induced relaxation was able to fully prevent this relax- cyclic AMP-mediated mechanisms contribute to the acti- ation (B). Consistent with a K+ channel role, high-KCl (80 mM)
vation of MaxiK channel in guinea-pig aorta.
also prevented forskolin-induced relaxation (A). Vascular relax-
ation is expressed as percent inhibition against the tension devel-
opment due to PGF2α (10–5 M; ❍, control), PGF2α (10–5 M) plus
Iberiotoxin (10–7 M; ●), or high-KCl (80 mM; ■), just before ad- Inhibition of cyclic AMP production with SQ 22,536 ministration of forskolin. Mean absolute values of the tension de- does not affect beraprost-induced relaxation velopment prior addition of forskolin were (A): 1.90±0.12 g (n=
13; control, 10–5 M PGF2α); 2.08±0.15 g (n=8; 10–5 M PGF2α plus
10–7 M Iberiotoxin); 2.02±0.13 g (n=6; 80 mM KCl). Data are The mechanical studies using RO-20-1724 and cyclic AMP means ± SEM of 5–13 experiments. A a)*P<0.05 significant dif-
elevating agents can lead to the hypothesis that stimula- ference from control; b)*P<0.05, b)**P<0.01 significant difference tion of IP receptor with beraprost elevates cyclic AMP from the response in the presence of Iberiotoxin. B *P<0.05 sig-
nificant difference from the response in the absence of Iberiotoxin.
contents, and thus, causes MaxiK channel-mediated relax- C Inhibitory effect of TEA on forskolin-induced relaxation. TEA
ation. If the cyclic AMP-mediated pathway is one of the (2×10–3 M) was applied prior forskolin treatment. Mean absolute mechanisms by which beraprost elicits MaxiK channel- values of the tension development just before cumulative addition mediated relaxation, the inhibition of adenylyl cyclase of forskolin are 1.93±0.28 g (n=6; ❍, control, 10–5 M PGF2α) and should diminish vasorelaxation induced by this IP ago- 1.96±0.18 g (n=8; ●, 10–5 M PGF2α plus 2×10–3 M TEA). Data are means ± SEM of 6–8 experiments. *P<0.05 significant differences nist. Thus, we inhibited adenylyl cyclase and examined its between two groups. D,E Iberiotoxin inhibits 8-bromo-cyclic
effect on beraprost-induced vascular relaxation. As shown AMP-induced relaxation regardless of the addition sequence. Iberio- in Fig. 6A and Table 2, SQ 22,536 (10–4 M), an inhibitor toxin (10–7 M) was applied prior 8-bromo-cyclic AMP (8-Br-cAMP) of adenylyl cyclase, did not significantly affect the relax- (D) or during 8-bromo-cyclic AMP-induced relaxation (E). Mean
absolute values of the tension development prior 8-bromo-cyclic
ant response to beraprost. These results are similar to those AMP treatment are: 2.43±0.17 g (n=6; ❍, control, 10–5 M PGF2α) obtained with iloprost (Turcato and Clapp 1999).
and 2.82±0.27 g (n=5; ●, 10–5 M PGF2α plus 10–7 M Iberiotoxin).
Figure 6B shows the increase in cyclic AMP content in In E, the control experiment corresponds to the last addition of response to beraprost and its inhibition by SQ 22,536. Be-
8-bromo-cyclic AMP (10–2 M) of the control concentration-response
curve in D, at which point Iberiotoxin (10–7 M) was added. Data
raprost (10–5 M) elevated cyclic AMP content from are means ± SEM of 5–6 experiments. *P<0.05, **P<0.01 signif- 2.5±0.5 pmol per mg protein to 75.9±10.8 pmol per mg protein (n=6 for each, P<0.01), producing a 30.4-fold rise.
In contrast, cyclic AMP content was not significantly ele-vated due to the stimulation with beraprost (10–5 M) in thepresence of SQ 22,536 (10–4 M). SQ 22,536 (10–4 M) it- able to relax the vascular muscle even when the adenylylcyclase activity is strongly inhibited by SQ 22,536 (Fig. 6C).
Furthermore, Fig. 6C shows that the elevation of cyclicAMP content is much less by beraprost than by forskolinfor generating the same amount of muscle relaxation. Thepharmaco-mechanical studies with SQ 22,536 togetherwith the measurement of cyclic AMP content suggest thatrelaxation induced by beraprost is primarily produced viacyclic AMP-independent pathways. However, experi-ments performed with RO-20-1724 indicate that beraprostmay trigger a secondary cyclic AMP-mediated path-way(s) that produces relaxation and that this pathway ac-tivates MaxiK channels. This view is supported by thefact that Iberiotoxin inhibits forskolin- and 8-bromo-cyclic AMP-induced relaxations.
MaxiK channels participate in the cyclic AMP-independent component of beraprost-induced relaxation Since the involvement of MaxiK channels in the cyclicAMP-independent component of IP agonist-induced re-laxation has not been tested experimentally, we directlyblocked channel activity with Iberiotoxin to determinetheir role. We now show that Iberiotoxin (10–7 M) signifi-cantly diminishes the beraprost-induced relaxant compo-nent in the presence of SQ 22,536 (10–4 M; Fig. 7). BothpIC50 (control, 6.50±0.14, n=7 vs. Iberiotoxin, 5.49±0.39,n=8, P<0.05) and the maximum response values (at 3×10–5 M beraprost; control, 92.6±3.4%, n=7 vs. Iberio-toxin, 50.1±10.4%, n=8, P<0.01) were significantly atten-uated by Iberiotoxin. Note that the maximum inhibition atequivalent beraprost values (>1×10–6 M) was ~80% in be- Fig. 6A–C SQ 22,536 inhibits production of cyclic AMP but has
negligible effect on beraprost-induced relaxation in guinea-pig
raprost-induced relaxations without SQ 22,536 (Fig. 2), aorta. A Concentration-response relationships for beraprost-in-
whereas it was only ~50% when the adenylyl cyclase path- duced relaxation in the absence and presence of the adenylyl cy-clase inhibitor SQ 22,536 (10–4 M). SQ 22,536 did not affect be-raprost-induced relaxation. Vascular relaxation is expressed as apercent inhibition against the muscle contraction induced byPGF2α (10–5 M). Data are means ± SEM of 3–4 experiments. B Basal cyclic AMP content (control) was not affected by SQ
22,536 (10–4 M, SQ). Beraprost (10–5 M, Bera) increased tissue
cyclic AMP content, which was inhibited by SQ 22,536. Data are
means ± SEM of 5–6 experiments (in duplicates). **P<0.01 sig-
nificant differences from control; from SQ 22,536 (10–4 M) treat-
ment; and from SQ 22,536 (10–4 M) plus beraprost (10–5 M) treat-
ment (one-way ANOVA). C Comparison between elevation of
cyclic AMP content and relaxation in guinea-pig aorta. Basal lev-
els of cyclic AMP content (2.5±0.5 pmol per mg protein, n=6 in
duplicates) were not subtracted from the total. Percent relaxation
values are the total mean values of all preparations used in the pre-
sent study. In the case of beraprost, less cyclic AMP was needed to
produce equivalent relaxation as observed with forskolin. Bera-
prost (10–5 M; n=6 for cyclic AMP and n=43 for tension); Bera-
prost (10–5 M) + SQ 22,536 (10–4 M; n=5 for cyclic AMP and n=10
Fig. 7 Iberiotoxin is able to inhibit the beraprost-induced relax-
for tension); Forskolin (10–5 M) (n=2 for cyclic AMP and n=18 for ation of guinea-pig aorta in the presence of SQ 22,536. Vascular relaxation is expressed as percent inhibition against the tension de-velopment due to PGF2α (10–5 M) just before administration of be- self did not significantly affect the basal level of cyclic raprost. Mean absolute values of the tension development just be-fore addition of beraprost are 2.10±0.15 g (n=7; ❍, SQ 22,536) AMP content. A comparison of beraprost-induced relax- and 2.43±0.23 g (n=8; ●, SQ 22,536 plus Iberiotoxin). Data are ation with the levels of cyclic AMP (in the absence and means ± SEM. *P<0.05, **P<0.01 significant differences between presence of SQ 22,536) clearly shows that beraprost is two groups (SQ 22,536 10–4 M, Iberiotoxin 10–7 M) by CTX was also observed in the presence of the adenylylcyclase inhibitor SQ 22,536 (10–4 M), supporting the viewthat Gs can cause relaxation independent of cyclic AMP.
As control experiment, CTX was boiled for 20 min at100°C, which practically eliminated its relaxant effect. Todetermine the role of MaxiK channels in this CTX-in-duced relaxation, Iberiotoxin was added after CTX treat-ment. CTX-induced relaxation was significantly counter-acted by Iberiotoxin (10–7 M) in the presence or absenceof SQ 22,536 (10–4 M; Fig. 8B). To rule out the possibilitythat tension decrement in the presence of CTX is only dueto spontaneous muscle fatigue and not due to Gs-mediatedrelaxation, we performed experiments preincubating themuscle with CTX prior PGF2α and Iberiotoxin treatments.
Similar results as those shown in Fig. 8A,B were obtained(n=4 to eight experiments). In conclusion, activation of theCTX-sensitive G protein, Gs, is able to induce a signifi-cant (~60%) muscle relaxation of guinea-pig aorta thatcan be explained in part by activation of MaxiK channelindependent of cyclic AMP-mediated mechanisms.
Fig. 8 A, B Cholera toxin (CTX), a stimulator of Gs, produces an
Iberiotoxin-sensitive relaxation of guinea-pig aorta in the presence
or absence of the adenylyl cyclase inhibitor SQ 22,536. A Relax-
ation by CTX (1 µg/ml, 6-h incubation) in the muscle contractedwith PGF2α (10–5 M). Vascular relaxation is expressed as percent The present findings indicate that activation of MaxiK 2α-induced contraction just before CTX ad- ministration. CTX induced similar vascular relaxation in the pres- channels plays a major role in mediating the relaxation in- ence or absence of SQ 22,536 (SQ, 10–4 M). Boiling (100°C, duced by stimulation of smooth muscle IP receptors in 20 min) CTX prevented its relaxant effect. Mean absolute values guinea-pig aorta. We also provide evidence for a dual of the tension development by PGF2α (10–5 M) after 1-h incubation mechanism of action for IP receptor stimulation by be- are: 2.40±0.36 g (n=4; control), 2.53±0.30 g (n=3; SQ 22,536 10–4 M), 2.33±0.20 g (n=10; CTX 1 µg/ml), 2.43±0.34 g (n=5; SQ raprost including both cyclic AMP-dependent and -inde- 22,536 10–4 M plus CTX 1 µg/ml), and 2.11±0.11 g (n=5; CTX, pendent (via Gs) pathways, which facilitate MaxiK chan- boiled). Note that SQ 22,536 was applied prior (20 min) contrac- nel activity leading to vascular relaxation.
tion with PGF2α. Data are means ± SEM. **P<0.01 significant dif- The relaxation of guinea-pig aorta in response to be- ferences from control group. B Iberiotoxin inhibits vascular relax-
ation by CTX or CTX plus SQ 22,536. Iberiotoxin (10–7 M) was
raprost is mediated via an activation of plasma-membrane applied 6 h after the incubation with CTX (1 µg/ml). Data are K+ channels since the relaxant response to beraprost was means ± SEM of 5–8 experiments. *P<0.05 significant difference almost abolished in the presence of high-KCl (Fig. 1). The driving force for K+ efflux and the subsequent membranehyperpolarization would be considerably reduced by diminu-tion of the chemical gradient in the medium containing way was inhibited (Fig. 7). These findings strongly indi- high K+ (Wise and Jones 1996). The main K+ channel in- cate that the activation of MaxiK channel contributes at volved in beraprost-induced relaxation is the MaxiK least by ~50% to the cyclic AMP-independent component channel because of the following observations: (1) Iberi- otoxin (10–7 M) dramatically diminished beraprost-in-duced relaxation close to the level obtained in high-KClsolution (Fig. 2 vs. Fig. 1). MaxiK channel is not inhibited Activation of Gs with cholera toxin relaxes guinea-pig by glibenclamide (10–5 M), apamin (10–7 M), 4-aminopy- aorta in a cyclic AMP-independent manner ridine (10–2 M; Wallner et al. 1995), but is blocked selec- tively by Iberiotoxin (Galvez et al. 1990); (2) Beraprost-induced relaxation was also inhibited by TEA at a con- To test the possibility that beraprost-induced cyclic AMP- centration that is considered to block MaxiK channels independent activation of MaxiK channels occurs via a di- (<2×10–3 M; Nelson and Quayle 1995; Wallner et al. 1995), rect G protein channel stimulation, we first investigated and the inhibition was similar to that observed in the pres- whether cholera toxin (CTX), a stimulator of Gs, could ence of Iberiotoxin (Fig. 2); (3) The relaxation induced by mimic the relaxant effect of beraprost. CTX (1 µg/ml) beraprost was not affected by glibenclamide (10–6 M), was applied to the bath solution after the contraction due which as expected almost abolished the relaxation due to to PGF2α (10–5 M) reached a steady-state level, and was cromakalim (Fig. 3). Thus, although the KATP channel has maintained in the bath for 6 h in the continued presence of a significant contribution to the vascular relaxation in- PGF2α. As shown in Fig. 8A, CTX by itself significantly duced by PGI2 analogues in some blood vessels (Jackson relaxed PGF2α-contracted vessels. Moreover, relaxation et al. 1993; Lombard et al. 1999; Schubert et al. 1997), in guinea-pig aorta the participation of this class of K+ chan- dent mechanism(s) to the overall muscle relaxation is def- nel can be ruled out; and (4) low concentrations of Ba2+ initely important. A significant role of cyclic AMP-inde- (10–5 M) did not affect beraprost-induced relaxation pendent pathway(s) in the regulation of muscle tone was(Fig. 3), indicating that an inward rectifier type of K+ also implied in the vascular relaxations induced by other channel (Bradley et al. 1999) may also be ruled out as the PGI2 analogues, iloprost and cicaprost, and by a β-adreno- main K+ channel involved in the relaxation induced by be- ceptor agonist, isoprenaline (Clapp et al. 1998; Kume et al. 1994; Scornik et al. 1993; Turcato and Clapp 1999).
Both Iberiotoxin (10–7 M) and TEA (2×10–3 M) did not A cyclic AMP-independent mechanism responsible for completely eliminate the overall relaxant effect of be- the activation of MaxiK channel has been shown with raprost, whereas the relaxation was almost abolished in β-adrenoceptor stimulation in the smooth muscle from high-KCl solution. This implies that a small portion of be- coronary artery (Scornik et al. 1993) and airway muscle raprost-induced relaxation can be ascribed to a K+ channel (Kume et al. 1994). In these reports, direct stimulatory ac- other than the MaxiK channel. This non-MaxiK channel- tion of the guanine nucleotide regulatory protein, Gs, un- mediated relaxant component may be attributed to Kv derlies the cyclic AMP-independent modulation of the channel since 4-AP (10–4 M) inhibited beraprost-induced MaxiK channel (Kume et al. 1994; Scornik et al. 1993).
relaxation to a small degree. The extent of the inhibition The cell surface IP receptor is known to be coupled to by 4-AP (~15%; Fig. 3) was close to the relaxant compo- adenylyl cyclase via Gs (Leffler 1997; Narumiya et al.
nent remaining in the presence of Iberiotoxin (~19%) or 1999; Wise and Jones 1996). Thus, IP receptor stimula- TEA (~25%) at 3×10–5 M beraprost. Indeed, the modula- tion may activate the MaxiK channel through a direct Gs- tion of Kv channel(s) (4-aminopyridine-sensitive, delayed protein coupling in guinea-pig aortic smooth muscle cells.
rectifier K+ channels) by cyclic AMP elevating stimuli in Consistent with this idea, in the present study we showed vascular smooth muscle cells has been suggested (Cole et that CTX (1 µg/ml), an activator of the stimulatory G pro- al. 1996; Standen and Quayle 1998). Nevertheless, the tein of adenylyl cyclase (Gs), substantially relaxed PGF2α- main K+ channel contributing to the overall relaxation due induced muscle contraction both in the absence and pres- to beraprost seems to be the MaxiK channel in guinea-pig ence of SQ 22,536 (10–4 M; Fig. 8A). Moreover, the re- aorta. Since we used endothelium-denuded preparations laxation due to CTX was partially but significantly coun- in this study, a possible participation of endothelial K+ teracted by Iberiotoxin (10–7 M; Fig. 8B). These mechani- cal studies strongly suggest that activation of Gs-protein As mentioned above, another important implication of could produce relaxation of guinea-pig aorta through di- the present findings is that cyclic AMP-independent mech- rect modulation of smooth muscle cell MaxiK channels.
anism(s) significantly (but not exclusively) contributes to In addition, several lines of evidence indicate that IP re- MaxiK channel-mediated relaxation induced by beraprost ceptors can be coupled to non-Gs type of G-proteins in- in guinea-pig aorta. This conclusion is based on the fol- cluding Gi, Go and Gp (Leffler 1997; Narumiya et al. 1999; lowing observations: (1) Similar to the iloprost-induced Wise and Jones 1996); thus, possible coupling with these relaxation (Turcato and Clapp 1999), the relaxation in- additional pathways needs to be investigated.
duced by beraprost was not affected by the adenylyl cy- Our present data clearly show that IP receptor activa- clase inhibitor, SQ 22,536 (10–4 M); although the same tion by beraprost elevates cyclic AMP contents in guinea- concentration of SQ 22,536 prevented the increase in pig aortic smooth muscle cells (Fig. 6), and that additional cyclic AMP content by this IP agonist. This pharmaco- cyclic AMP-dependent mechanisms are partially involved mechanical and biochemical evidence indicates that be- in beraprost induced-relaxation. Elevated cyclic AMP raprost is able to relax guinea-pig aorta even when the can produce MaxiK channel-mediated muscle relaxation adenylyl cyclase is blocked, and thus, implies the exis- (Fig. 5), and RO-20-1724 (cyclic AMP-specific phospho- tence of cyclic AMP-independent mechanism(s) responsi- diesterase inhibitor) can potentiate the beraprost-induced ble for MaxiK channel-mediated vascular relaxation; (2) relaxation in an Iberiotoxin-sensitive manner (Fig. 4). In Iberiotoxin blocked about 50% of beraprost-induced re- agreement with this view, 8-bromo-cyclic AMP-induced laxation in the presence of SQ 22,536; whereas it blocked relaxation was significantly suppressed by Iberiotoxin ap- ~80% in the absence of this adenylyl cyclase inhibitor; plied either before or after stimulation with this cyclic and (3) the level of cyclic AMP needed to elicit the same AMP analogue. Furthermore, a complete counteracting amount of vascular relaxation was much less for beraprost action of Iberiotoxin was obtained for forskolin-induced than for forskolin. This was more evident when the relaxation when this channel blocker was applied during adenylyl cyclase was inhibited with SQ 22,536 (Fig. 6C).
the muscle relaxation. However, and as previously re- Although the compartmentalization of cyclic AMP neces- ported (Clapp et al. 1998), if Iberiotoxin was pre-applied sary for the regulation of muscle tone has been postulated to block forskolin-induced relaxation of guinea-pig aorta, (Laurenza et al. 1989), our finding may indicate that ele- the channel blocker was unable to prevent this relaxation; vation of cyclic AMP itself cannot efficiently generate at present, we do not have an explanation for this phe- vascular smooth muscle relaxation. Since the concentra- tion-response relationships for the relaxant effect of be- In contrast to guinea-pig aorta, in rat tail artery smooth raprost were almost identical in the absence and presence muscle a cyclic AMP-dependent mechanism has a sub- of SQ 22,536, the contribution of cyclic AMP-indepen- stantial contribution in the MaxiK channel-mediated mus- cle relaxation after IP receptor stimulation (Schubert et al.
Acknowledgements This study was supported in part by Grant-
1996, 1997). Mechanisms proposed for the explanation of in-Aid (12672226) from the Ministry of Education, Science,Sports, and Culture, Japan (Y.T.), the Nestle Foundation (Y.T.), cyclic AMP-dependent MaxiK channel activation are: (1) the Pharmacological Research Foundation, Tokyo (Y.T.), and NIH phosphorylation by cyclic AMP-dependent protein kinase (PKA; Kume et al. 1989; Meera et al. 1995; Schubert etal. 1996; Scornik et al. 1993); (2) PKA-triggered increasein Ca2+ spark frequency through ryanodine-sensitive Ca2+ release channels (Porter et al. 1998); and (3) modulation Adeagbo ASO, Malik KU (1990) Mechanism of vascular actions by cyclic GMP-dependent protein kinase via cyclic AMP of prostacyclin in the rat isolated perfused mesenteric arteries.
(Lincoln and Cornwell 1993). However, experiments us- ing the soluble guanylyl cyclase inhibitor, ODQ (10–5 M), Akiba T, Miyazaki M, Toda N (1986) Vasodilator actions of TRK- showed that beraprost-induced relaxation was not affected 100, a new prostaglandin I2 analogue. Br J Pharmacol 89:703–711 by this compound (not shown). Thus, a possible participa- Bradley KK, Jaggar JH, Bonev AD, Heppner TJ, Flynn ER, Nel- tion of cyclic GMP as a mechanism involved in the relax- son MT, Horowitz B (1999) Kir2.1 encodes the inward rectifier ation due to beraprost seems unlikely.
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Galvez A, Gimenez-Gallego G, Reuben JP, Roy-Contancin L, Feigenbaum P, Kaczorowski J, Garcia ML (1990) Purification 1998), which would counterbalance its relaxant effect in and characterization of a unique, potent, peptidyl probe for thehigh conductance calcium-activated potassium channel from guinea-pig aorta. However, in our experiments involve- venom of the scorpion Buthus tamulus. J Biol Chem 265: ment of constrictor prostaglandin(s) (e.g. prostaglandin Jackson WF, König A, Dambacher T, Busse R (1993) Prostacy- 2, prostaglandin F2α) and/or TXA2 seems unlikely since beraprost-induced relaxation was not affected by gliben- clin-induced vasodilation in rabbit heart is mediated by ATP-sensitive potassium channels. Am J Physiol 264:H238–H243 clamide (Fig. 3A), which in other vascular beds inhibits vas- Katano Y, Endoh M (1990) Differential effects of Ro 20-1724 and cular contractions induced by these vasoactive substances isobutylmethylxanthine on the basal force of contraction and (Cocks et al. 1990; Delaey and Van de Voorde 1995).
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Kume H, Takai A, Tokuno H, Tomita T (1989) Regulation of MaxiK channel is the predominant mediator of vascular Ca2+-dependent K+-channel activity in tracheal myocytes by relaxation following stimulation of IP receptor; while K Kume H, Hall IP, Washabau RJ, Takagi K, Kotlikoff MI (1994) channel(s) may be modestly involved in the relaxant Beta-adrenergic agonists regulate KCa channels in airway mechanism. Contribution of KATP channel can be ruled out smooth muscle by cAMP-dependent and -independent mecha- as the mechanism by which beraprost relaxes guinea-pig aorta. Although cyclic AMP content is significantly ele- Laurenza A, Sutkowski EM, Seamon KB (1989) Forskolin: a spe- cific stimulator of adenylate cyclase or a diterpene with multi- vated by beraprost in this vascular tissue, the opening of ple sites of action? Trends Pharmacol Sci 10:442–447 MaxiK channel dependent on the elevation of intracellular Leffler CH (1997) Prostanoids: intrinsic modulators of cerebral cyclic AMP is not overwhelming; whereas the cyclic AMP-independent component seems to be the major con- Lincoln TM, Cornwell TL (1993) Intracellular cyclic GMP recep- tributor of the total relaxation induced by this IP agonist.
Lombard JH, Liu Y, Fredricks KT, Bizub DM, Roman RJ, Rusch The mechanism of cyclic AMP-independent relaxation is NJ (1999) Electrical and mechanical responses of rat middle due in part to the direct activation of MaxiK channels by cerebral arteries to reduced PO2 and prostacyclin. Am J Phys- Lowry OH, Rosebrough NJ, Farr AL, Randall RJ (1951) Protein Schubert R, Serebryakov VN, Mewes H, Hopp H-H (1997) Ilo- measurement with the folin phenol reagent. J Biol Chem 193: prost dilates rat small arteries: role of KATP- and KCa-channel activation by cAMP-dependent protein kinase. Am J Physiol Meera P, Anwer K, Monga M, Oberti C, Stefani E, Toro L, San- born BM (1995) Relaxin stimulates myometrial calcium-acti- Scornik FS, Codina J, Birnbaumer L, Toro L (1993) Modulation of vated potassium channel activity via protein kinase A. Am J coronary smooth muscle KCa channels by Gsα independent of phosphorylation by protein kinase A. Am J Physiol 265:H1460– Miller OV, Aiken JW, Hemker DP, Shebuski RJ, Gorman RR (1979) Prostacyclin stimulation of dog arterial cyclic AMP lev- Siegel G, Carl A, Adler A, Stock G (1989) Effect of the prostacy- clin analogue iloprost on K+ permeability in the smooth muscle Moncada S, Herman AG, Higgs EA, Vane JR (1977) Differential cells of the canine carotid artery. Eicosanoids 2:213–222 formation of prostacyclin (PGX or PGI2) by layer of the arter- Standen NB, Quayle JM (1998) K+ channel modulation in arterial ial wall. An explanation for the anti-thrombotic properties of smooth muscle. Acta Physiol Scand 164:549–557 vascular endothelium. Thromb Res 11:323–344 Tanaka Y, Igarashi T, Takayanagi K, Yamaki F, Imai T, Tanaka H, Murata T, Murai T, Kanai T, Ogaki Y, Sanai K, Kanda H, Sato S, Shigenobu K (2000) Comparison of pharmacological charac- Kajikawa N, Umetsu T, Matsuura H, Fukatsu Y, Isogaya M, teristics of noradrenaline- and thapsigargin-activated Ca2+ en- Yamada N, Nishio S (1989) General pharmacology of be- try channels responsible for mechanical responses of guinea- raprost sodium. 2nd communication: effect on the autonomic, pig aorta. Naunyn-Schmiedeberg’s Arch Pharmacol 362:160– cardiovascular and gastrointestinal systems, and other effects.
Toro L, Wallner M, Meera P, Tanaka Y (1998) Maxi-KCa, a unique Narumiya S, Sugimoto Y, Ushikubi F (1999) Prostanoid receptors: member of the voltage-gated K channel superfamily. News structures, properties, and functions. Physiol Rev 79:1193– Turcato S, Clapp LH (1999) Effects of the adenylyl cyclase in- Nelson MT, Quayle JM (1995) Physiological roles and properties hibitor SQ22536 on iloprost-induced vasorelaxation and cyclic of potassium channels in arterial smooth muscle. Am J Physiol AMP elevation in isolated guinea-pig aorta. Br J Pharmacol Ozaki H, Abe A, Uehigashi Y, Kinoshita M, Hori M, Mitsui-Saito Vegesna RV, Diamond J (1986) Elevation of cyclic AMP by M, Karaki H (1996) Effects of a prostaglandin I2 analog ilo- prostacyclin is accompanied by relaxation of bovine coronary prost on cytoplasmic Ca2+ levels and muscle contraction in iso- arteries and contraction of rabbit aortic rings. Eur J Pharmacol lated guinea pig aorta. Jpn J Pharmacol 71:231–237 Porter VA, Bonev AD, Knot HJ, Heppner TJ, Stevenson AS, Klep- Wallner M, Meera P, Ottolia M, Kaczorowski GJ, Latorre R, Gar- pisch T, Lederer WJ, Nelson MT (1998) Frequency modulation cia ML, Stefani E, Toro L (1995) Characterization of and mod- of Ca2+ sparks is involved in regulation of arterial diameter by ulation by a β-subunit of a human maxi KCa channel cloned cyclic nucleotides. Am J Physiol 274:C1346–C1355 from myometrium. Receptors Channels 3:185–199 Schubert R, Serebryakov VN, Engel H, Hopp H-H (1996) Iloprost Wise H, Jones RL (1996) Focus on prostacyclin and its novel activates KCa channels of vascular smooth muscle cells: role of mimetics. Trends Pharmacol Sci 17:17–21 cAMP-dependent protein kinase. Am J Physiol 271:C1203–C1211

Source: http://www.anes.ucla.edu/~ltoro/PAPERS/N-S-ArchPharmacol-Yamaki.pdf

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