Docosahexaenoic Acid and Eicosapentaenoic Acid Inhibit the Contractile Responses of the Guinea Pig Lower Gastrointestinal Tract.

Docosahexaenoic acid (DHA) and eicosapentaenoic acid (EPA) are n-3 polyunsaturated fatty acids (PUFAs), and are abundant in fish oil. These n-3 PUFAs have been reported to improve the lower gastrointestinal (LGI) disorders such as ulcerative colitis and Crohn's disease through their anti-inflammatory effects. However, there are few studies on the effect of n-3 PUFAs on motility of the LGI tract, such as the ileum and colon, the parts frequently affected by these inflammatory disorders. To elucidate the effects of DHA and EPA on the LGI tract motility, we performed comparative evaluation of their effects and linoleic acid (LA), an n-6 PUFA, on contractions in the ileal and colonic longitudinal smooth muscles (LSMs) isolated from guinea pigs. In the ileal and colonic LSMs, DHA and EPA (3 × 10-5 M each) significantly inhibited contractions induced by acetylcholine (ACh), histamine, and prostaglandin (PG) F2α (vs. control), and these effects are stronger than that of LA (3 × 10-5 M). In the colonic LSMs, DHA and EPA also significantly inhibited contractions induced by PGD2 (vs. control). In addition, DHA and EPA significantly inhibited CaCl2-induced ileal and colonic LSM contractions in Ca2+-free 80 mM-KCl solution (vs. control). Any ileal and colonic LSM contractions induced by ACh, histamine, PGF2α, and CaCl2 were completely suppressed by verapamil (10-5 M), a voltage-gated/dependent Ca2+ channel (VGCC/VDCC) inhibitor. These findings suggest that DHA and EPA could improve the abnormal contractile functions of the LGI tract associated with inflammatory diseases, partly through inhibition of VGCC/VDCC-dependent ileal and colonic LSM contractions.

Inhibitory Effects of Antipsychotics on the Contractile Response to Acetylcholine in Rat Urinary Bladder Smooth Muscles.

The clinical applications of antipsychotics for symptoms unrelated to schizophrenia, such as behavioral and psychological symptoms, in patients with Alzheimer's disease, and the likelihood of doctors prescribing antipsychotics for elderly people are increasing. In elderly people, drug-induced and aging-associated urinary disorders are likely to occur. The most significant factor causing drug-induced urinary disorders is a decrease in urinary bladder smooth muscle (UBSM) contraction induced by the anticholinergic action of therapeutics. However, the anticholinergic action-associated inhibitory effects of antipsychotics on UBSM contraction have not been sufficiently assessed. In this study, we examined 26 clinically available antipsychotics to determine the extent to which they inhibit acetylcholine (ACh)-induced contraction in rat UBSM to predict the drugs that should not be used by elderly people to avoid urinary disorders. Of the 26 antipsychotics, six (chlorpromazine, levomepromazine (phenothiazines), zotepine (a thiepine), olanzapine, quetiapine, clozapine (multi-acting receptor targeted antipsychotics (MARTAs))) competitively inhibited ACh-induced contractions at concentrations corresponding to clinically significant doses. Further, 11 antipsychotics (perphenazine, fluphenazine, prochlorperazine (phenothiazines), haloperidol, bromperidol, timiperone, spiperone (butyrophenones), pimozide (a diphenylbutylpiperidine), perospirone, blonanserin (serotonin-dopamine antagonists; SDAs), and asenapine (a MARTA)) significantly suppressed ACh-induced contraction; however, suppression occurred at concentrations substantially exceeding clinically achievable blood levels. The remaining nine antipsychotics (pipamperone (a butyrophenone), sulpiride, sultopride, tiapride, nemonapride (benzamides), risperidone, paliperidone (SDAs), aripiprazole, and brexpiprazole (dopamine partial agonists)) did not inhibit ACh-induced contractions at concentrations up to 10-5 M. These findings suggest that chlorpromazine, levomepromazine, zotepine, olanzapine, quetiapine, and clozapine should be avoided by elderly people with urinary disorders.

Normetadrenaline and metadrenaline induce rat thoracic aorta/prostate contraction via α1D/1A-adrenoceptor stimulation.

Certain catecholamine metabolites exert significant pharmacological effects. Herein, we evaluated the pharmacological activities of catecholamine metabolites in the rat thoracic aorta, prostate, and spleen to determine whether these metabolites affect the contractile functions of smooth muscle tissue via direct action on α-adrenoceptors and α-adrenoceptor subtypes. Among the catecholamine metabolites examined, normetadrenaline and metadrenaline (10-4 M each) produced relatively strong contractions in the rat thoracic aorta. Maximum aortic contractions induced by normetadrenaline (≈70% of phenylephrine (3 × 10-7 M)-induced contractions) and metadrenaline (≈45%) were significantly smaller than those induced by phenylephrine (≈95%). Normetadrenaline and metadrenaline (10-4 M each) inhibited phenylephrine (3 × 10-7 M)-induced aortic contractions, which were not affected by propranolol (10-6 M), by 5-20%. Normetadrenaline- and metadrenaline (3 × 10-5 M each)-induced aortic contractions were strongly inhibited by prazosin (10-8 M; an α1-adrenoceptor antagonist) and BMY 7378 (10-8-10-7 M; a selective α1D-adrenoceptor antagonist). Metadrenaline (3 × 10-5 M)-induced aortic contractions were also significantly inhibited by silodosin (10-9 M; a selective α1A-adrenoceptor antagonist). Normetadrenaline and metadrenaline (3 × 10-5 M each) caused silodosin (10-9 M)-sensitive prostate contractions but did not cause a prominent spleen contraction. Maximum prostate contractions induced by metadrenaline (≈100% of phenylephrine (3 × 10-5 M)-induced contractions) were nearly identical to those induced by phenylephrine (≈100%) but were significantly larger than those induced by normetadrenaline (≈80%). These findings suggest that normetadrenaline and metadrenaline act as a partial α1D/α1A-adrenoceptor agonist and partial α1D-adrenoceptor/full α1A-adrenoceptor agonist, respectively, functioning as adrenaline system stabilizers in α1D/α1A-adrenoceptor-abundant smooth muscle tissues.

Effects of Catecholamine Metabolites on Beta-Adrenoceptor-Mediated Relaxation of Smooth Muscle: Evaluation in Mouse and Guinea-Pig Trachea and Rat Aorta.

The ß-adrenoceptor (ß-AR)-mediated pharmacological effects of catecholamine (CA) metabolites are not well known. We examined the effects of seven CA metabolites on smooth muscle relaxation in mouse and guinea pig (GP) tracheas and rat thoracic aorta. Among them, metadrenaline (MA) significantly relaxed GP trachea (ß2-AR dominant), even in the presence of clorgiline, a monoamine oxidase-A inhibitor. In mouse trachea (ß1-AR dominant), normetadrenaline (NMA) and MA (10-4 M each) apparently did not affect isoprenaline (ISO)-induced relaxation, but significantly inhibited it in the presence of clorgiline. ISO-induced relaxation was also unaffected by 3,4-dihydroxyphenylglycol (DHPG) (10-4 M), but significant suppression was observed with the addition of 3,5-dinitrocatechol, a catechol-O-methyltransferase inhibitor. In GP trachea, NMA, MA, 3,4-dihydroxymandelic acid (DOMA), and DHPG (10-4 M each) significantly augmented ISO-induced relaxation. However, in the presence of clorgiline plus 3,5-dinitrocatechol, both NMA and MA (10-4 M) significantly suppressed ISO-induced relaxation. DHPG (10-4 M) also significantly suppressed ISO-induced relaxation in the presence of 3,5-dinitrocatechol. In rat thoracic aorta, DHPG (10-4 M) significantly suppressed relaxation induced by CGP-12177 A (a ß3-AR partial agonist) in the presence of 3,5-dinitrocatechol plus propranolol. Our findings indicate that 1) MA may possess ß2-AR agonistic action; 2) NMA and MA augment ß2-AR-mediated tracheal relaxation in the absence of CA metabolic inhibitors, though themselves possessing ß1-, ß2-AR antagonistic action (ß2 > ß1); 3) DHPG exhibits ß1-, ß2-, ß3-AR antagonistic action, and this is particularly marked for ß3-AR. Our observations may help explain some of the pathologies associated with pheochromocytoma, which is characterized by increased CA metabolite levels.

Pharmacological Characteristics of Anxiolytics on Acetylcholine-Induced Contractions in Rat Detrusor Smooth Muscle.

INTRODUCTION: Benzodiazepine anxiolytics are believed to cause urination disorders due to their anticholinergic effects. OBJECTIVE: This study was carried out to investigate the potential inhibitory effects of 15 clinically available anxiolytics in Japan on acetylcholine (ACh)-induced contractions in rat detrusor smooth muscle (DSM) to predict whether these anxiolytics could induce urination disorders. METHODS: -Effects of anxiolytics on contractions induced by ACh and 80 mmol/L KCl solution in rat DSM and effects of anxiolytics on specific binding of [N-methyl-3H]scopolamine ([3H]NMS) in mouse cerebral cortex were investigated. RESULTS AND CONCLUSIONS: ACh-induced contractions in rat DSM were inhibited by clotiazepam and diazepam (benzodiazepine anxiolytics) at concentrations that were clinically relevant. These contractions were also significantly inhibited by paroxetine, escitalopram (selective serotonin reuptake inhibitors -[SSRIs]), and hydroxyzine (a histamine H1 receptor antagonist), albeit at concentrations that substantially exceeded clinically achievable blood levels. At a concentration of 10-5 mol/L, paroxetine, escitalopram, and hydroxyzine inhibited 80 mmol/L high-KCl solution-induced rat DSM contractions but not clotiazepam and diazepam. Paroxetine, escitalopram, and hydroxyzine also inhibited specific binding of [3H]NMS in mouse cerebral cortex but clotiazepam and diazepam did not. In contrast to the effects of the abovementioned anxiolytics, ACh-induced contractions were not significantly affected by tofisopam, alprazolam, lorazepam, bromazepam, oxazolam, chlordiazepoxide, clonazepam, ethyl loflazepate (benzodiazepine anxiolytics), fluvoxamine (an SSRI), or tandospirone (a serotonin 5-HT1A receptor agonist). These findings suggest that most clinically used anxiolytics are not likely to result in anticholinergic-induced urination disorders within their clinically achievable blood concentration ranges. However, clotiazepam and diazepam may induce urination disorders within their clinical dose ranges via nonanticholinergic inhibition of DSM contractility.

Characterization of binding of antipsychotics to muscarinic receptors using mouse cerebral cortex.

Antipsychotics are often the first-line treatment for behavioral and psychological symptoms of dementia. However, the potential anticholinergic effects of antipsychotics could counteract the therapeutic effects of cholinesterase inhibitors used to treat dementia. We investigated the inhibitory effects of 26 antipsychotics on [N-Methyl-3H]scopolamine specific binding in mouse cerebral cortex. At 10-5 M, chlorpromazine, levomepromazine, prochlorperazine, timiperone, zotepine, pimozide, blonanserin, olanzapine, quetiapine, and clozapine inhibited [N-Methyl-3H]scopolamine binding by > 45%. Furthermore, the pKi values of chlorpromazine, levomepromazine, zotepine, olanzapine, and clozapine overlapped with their clinically achievable blood concentrations. Therefore, the anticholinergic properties of these antipsychotics could attenuate the effects of cholinesterase inhibitors.

Inhibition of Recombinant Human Acetylcholinesterase Activity by Antipsychotics.

BACKGROUND/AIMS: Extrapyramidal symptoms (EPS) are representative side effects of antipsychotics, caused by their inhibitory action on dopaminergic nerves in nigrostriatal pathways. EPS could be also caused by direct augmentation of cholinergic effects, for example, by acetylcholinesterase (AChE) inhibition. We investigated the potential inhibitory effects of 26 clinically available antipsychotics on the activity of recombinant human AChE (rhAChE) to predict the role of antipsychotic-induced AChE inhibition in EPS onset. METHOD: The degree of rhAChE activity inhibition was calculated using the 5,5'-dithio-bis-(2-nitrobenzoic acid) method. RESULTS: At a concentration of 10-5 mol/L, haloperidol, bromperidol, timiperone, nemonapride, pimozide, risperidone, blonanserin, aripiprazole, and brexpiprazole inhibited rhAChE activity by >20%. Risperidone, aripiprazole, and brexpiprazole inhibited rhAChE activity in a concentration-dependent manner, and their effects were more potent than those of other antipsychotics. The inhibitory effects of these 3 drugs were evident from 10-6 mol/L, and their pIC50 values were 4.74 ± 0.04, 4.80 ± 0.04, and 4.93 ± 0.06, respectively. Notably, the concentration range in which aripiprazole inhibited rhAChE activity (≥10-6 mol/L) overlapped with its clinically achievable blood levels. CONCLUSION: Aripiprazole may cause EPS at clinical dosages by augmenting cholinergic effects via AChE inhibition, in addition to its suppressive effect on dopaminergic neurons.

Noradrenaline-Induced Relaxation of Urinary Bladder Smooth Muscle Is Primarily Triggered through the ß3-Adrenoceptor in Rats.

ß-Adrenoceptors are subclassified into 3 subtypes (ß1-ß3). Among these, ß3-adrenoceptors are present in various types of smooth muscle and are believed to play a role in relaxation responses of these muscles. ß3-Adrenoceptors are also present in urinary bladder smooth muscle (UBSM), although their expression varies depending on the animal species. To date, there has been little information available about the endogenous ligand that stimulates ß3-adrenoceptors to produce relaxation responses in UBSM. In this study, to determine whether noradrenaline is a ligand of UBSM ß3-adrenoceptors, noradrenaline-induced relaxation was analyzed pharmacologically using rat UBSM. We also assessed whether noradrenaline metabolites were ligands in UBSM. In isolated rat urinary bladder tissues, mRNAs for ß1-, ß2-, and ß3-adrenoceptors were detected using RT-PCR. In UBSM preparations contracted with methacholine (3 × 10-5 M), noradrenaline-induced relaxation was not inhibited by the following antagonists: atenolol (10-6 M; selective ß1-adrenoceptor antagonist), ICI-118,551 (3 × 10-8 M; selective ß2-adrenoceptor antagonist), propranolol (10-7 M; non-selective ß-adrenoceptor antagonist), and bupranolol (10-7 M; non-selective ß-adrenoceptor antagonist). In the presence of propranolol (10-6 M), noradrenaline-induced relaxation was competitively inhibited by bupranolol (3 × 10-7-3 × 10-6 M) or SR59230A (10-7-10-6 M; selective ß3-adrenoceptor antagonist), with their pA2 values calculated to be 6.64 and 7.27, respectively. None of the six noradrenaline metabolites produced significant relaxation of methacholine-contracted UBSM. These findings suggest that noradrenaline, but not its metabolites, is a ligand for ß3-adrenoceptors to produce relaxation responses of UBSM in rats.

[Angiotensin II Regulates Excitability and Contractile Functions of Myocardium and Smooth Muscles through Autonomic Nervous Transmission].

Angiotensin II (Ang II) is an intrinsic peptide having strong vasopressor effects, and thus, it plays an important role in the physiological regulation of blood pressure. The vasopressor effects of Ang II include direct contraction of myocardium and vascular smooth muscles (SMs) along with aldosterone-mediated sodium retention. In addition, indirect vascular contractions induced by noradrenaline (NA), the release of which is mediated through Ang II receptor type 1 (AT1) existing at the sympathetic nerve terminals (SNTs), also contribute to the vasopressor effects of Ang II. Stimulation of NA release from SNTs by Ang II also occurs in the myocardium leading to an increase in heart rate and cardiac contraction. Furthermore, Ang II enhances the contractions of non-vascular SMs, such as vas deferens, through induction of NA release from the SNTs. We have found that Ang II attenuated vagus nerve stimulation-induced bradycardia in a losartan-sensitive manner. This suggests that Ang II attenuates vagus nerve stimulation-induced bradycardia by inhibiting acetylcholine (ACh) release from the parasympathetic nerve terminals (PNTs) through activation of the AT1 receptor. Ang II was also reported to attenuate the release of ACh from the PNTs in SMs, such as stomach and airway, thus suppressing their contractile functions. There are, however, conflicting reports of the effects of Ang II on parasympathetic nerve-mediated contractile regulation of SMs. In this review, we have highlighted the relevant research articles including our experimental reports on the regulation of sympathetic and parasympathetic nerve-mediated excitation and contraction by Ang II along with the future prospects.

Assessment of Inhibitory Effects of Hypnotics on Acetylcholine-Induced Contractions in Isolated Rat Urinary Bladder Smooth Muscle.

The present study aimed to investigate the potential inhibitory effects of 21 clinically available hypnotics on acetylcholine (ACh)-induced contractions in rat urinary bladder smooth muscle (UBSM) in order to predict whether these hypnotics could induce voiding impairment. ACh-induced contraction in rat UBSM was inhibited only by diphenhydramine (a histamine H1 receptor antagonist) at a concentration that was clinically relevant. ACh-induced contraction was also significantly inhibited by flurazepam (a benzodiazepine hypnotic) and suvorexant (an orexin receptor antagonist), albeit at concentrations that substantially exceeded clinically achievable blood levels. These three drugs (at 10-5 M) also inhibited high-KCl (80 mM) Locke-Ringer solution-induced contractions. In contrast to the effects of the abovementioned hypnotics, ACh-induced contractions were not significantly affected by triazolam, etizolam, brotizolam, lormetazepam, estazolam, flunitrazepam, nitrazepam (benzodiazepine hypnotics), thiopental, thiamylal, pentobarbital, amobarbital, secobarbital, phenobarbital (barbiturate hypnotics), zolpidem (an imidazopyridine hypnotic), zopiclone (a cyclopyrrolone hypnotic), ramelteon (a melatonin receptor agonist), bromovalerylurea, and chloral hydrate. These findings suggest that most clinically used hypnotics are not likely to result in anticholinergic-induced dysuria within their clinically achievable blood concentration ranges. Diphenhydramine may, however, induce voiding impairment, an action attributable to diminished UBSM contractility within its clinical dose range.

Evaluation of the potentiating effects of antidepressants on the contractile response to noradrenaline in guinea pig urethra smooth muscles.

We investigated the potential augmenting effects of 19 clinically available antidepressants on noradrenaline (NA)-induced contractions in guinea pig urethra smooth muscle (USM). Concentration-response curves for NA-induced contractions in guinea pig USM strips were obtained in the absence or presence of selected antidepressants. Desipramine, an active metabolite of imipramine, produced a contraction and potentiated NA-induced contraction at the distal urethra without affecting the proximal urethra. Further, nortriptyline and amoxapine, tricyclic antidepressants, produced a contraction and potentiated NA-induced contraction at the distal urethra. NA-induced contraction was unaffected or reduced by imipramine, clomipramine, trimipramine, and amitriptyline at the proximal and distal urethra. Maprotiline, a tetracyclic antidepressant, potentiated NA-induced contraction at the distal urethra. NA-induced contraction was unaffected by mianserin at the proximal and distal urethra. Paroxetine, a selective serotonin reuptake inhibitor (SSRI), potentiated NA-induced contraction at the distal urethra, while NA-induced contraction was unaffected by fluvoxamine, sertraline, and escitalopram at the proximal and distal urethra. Milnacipran, a serotonin-noradrenaline reuptake inhibitor (SNRI), potentiated NA-induced contraction at the proximal and distal urethra, whereas duloxetine potentiated it at the distal urethra. Mirtazapine slightly inhibited NA-induced contraction at the distal urethra. Aripiprazole and sulpiride did not affect NA-induced contractions at the proximal nor distal urethra. Trazodone inhibited NA-induced contraction at both urethras. Desipramine, nortriptyline, amoxapine, maprotiline, paroxetine, milnacipran, and duloxetine likely induce urinary disturbance by increasing urethral resistance and augmenting NA-induced contraction, which should be carefully considered when delivering guidance for drug administration to patients.

Evaluation of Antidepressant Effects on Recovery of Electrical Field Stimulation-Induced Contractions that have been Suppressed by Clonidine in Isolated Rat Vas Deferens.

BACKGROUND: A report examining whether clinically available antidepressants increase urethral smooth muscle contraction via antagonistic effects on the α2-adrenoceptor (α2-AR) is lacking. OBJECTIVES: The present study was performed to evaluate the potential of clinically available antidepressants to reverse α2-AR-mediated contractile inhibition in rat vas deferens, in order to predict whether they can induce voiding impairment. METHOD: The effects of 18 antidepressants of different classes on electrical field stimulation (EFS)-induced contractions suppressed by 10-8 mol/L clonidine (a selective α2-AR agonist) in isolated rat vas deferens were investigated and related to their respective clinical blood concentrations. RESULTS: The EFS-induced contractions suppressed by clonidine were recovered by amitriptyline (a tricyclic antidepressant), mirtazapine (a noradrenergic and specific serotonergic antidepressant), and trazodone (a serotonin 5-HT2A receptor antagonist) at concentrations close to the clinical blood levels. EFS-induced contractions were also recovered by trimipramine, clomipramine (tricyclic antidepressants), mianserin (a tetracyclic antidepressant), sertraline (a selective serotonin reuptake inhibitor [SSRI]), and sulpiride (a dopamine D2-receptor antagonist), albeit at concentrations that substantially exceeded their clinically-achievable blood levels. EFS-induced contractions were not significantly affected by imipramine, nortriptyline, amoxapine (tricyclic antidepressants), maprotiline (a tetracyclic antidepressant), fluvoxamine, paroxetine, escitalopram (SSRIs), milnacipran, duloxetine (serotonin and noradrenaline reuptake inhibitors), and aripiprazole (a dopamine partial agonist). CONCLUSIONS: These findings suggest that amitriptyline, mirtazapine, and trazodone induce voiding impairment caused by increased urethral resistance by enhancing sympathetic nerve activities attributed to α2-AR antagonism.

ß-Adrenoceptor subtypes and cAMP role in adrenaline- and noradrenaline-induced relaxation in the rat thoracic aorta.

Object We identified the ß-adrenoceptor (ß-AR) subtypes responsible for the relaxant responses to adrenaline (AD) and noradrenaline (NA) in the rat thoracic aorta and examined the role of cAMP which is involved in these relaxant responses. Methods The effects of ß-AR antagonists or the adenylyl cyclase inhibitor SQ 22,536 on AD- and NA-induced relaxant responses in phenylephrine-induced contraction and increases in cAMP levels were examined in isolated, endothelium-denuded rat thoracic aorta segments. Results AD-induced relaxation was completely suppressed by propranolol (10-7 M) or by ICI-118,551 (10-8 M) plus atenolol (10-6 M), and was also very strongly inhibited by ICI-118,551 (10-8 M) alone. AD (10-5 M) increased tissue cAMP levels by approximately 1.9-fold compared with that in non-stimulated aortic tissue, but did not significantly increase cAMP levels in the presence of ICI-118,551 (10-8 M) or SQ 22,536 (10-4 M). AD-induced relaxation was strongly suppressed by SQ 22,536 (10-4 M). NA-induced relaxation was almost completely suppressed by atenolol (10-6 M) plus ICI-118,551 (10-8 M) although it was hardly affected by ICI-118,551 (10-8 M) alone. NA (10-5 M) increased tissue cAMP levels by approximately 2.2-fold compared with that in non-stimulated aortic tissue, but did not significantly increase cAMP levels in the presence of atenolol (10-6 M) or SQ 22,536 (10-4 M). NA-induced relaxation was strongly suppressed by SQ 22,536 (10-4 M). Conclusion In rat thoracic aorta, AD- and NA-induced relaxations, which are both strongly dependent on increased tissue cAMP levels, are mainly mediated through ß2- and ß1-adrenoceptors respectively.

Pharmacological identification of ß-adrenoceptor subtypes mediating isoprenaline-induced relaxation of guinea pig colonic longitudinal smooth muscle.

Object We aimed to identify the ß-adrenoceptor (ß-AR) subtypes involved in isoprenaline-induced relaxation of guinea pig colonic longitudinal smooth muscle using pharmacological and biochemical approaches. Methods Longitudinal smooth muscle was prepared from the male guinea pig ascending colon and contracted with histamine prior to comparing the relaxant responses to three catecholamines (isoprenaline, adrenaline, and noradrenaline). The inhibitory effects of subtype-selective ß-AR antagonists on isoprenaline-induced relaxation were then investigated. Results The relaxant potencies of the catecholamines were ranked as: isoprenaline > noradrenaline ≈ adrenaline, whereas the rank order was isoprenaline > noradrenaline > adrenaline in the presence of propranolol (a non-selective ß-AR antagonist; 3 × 10-7 M). Atenolol (a selective ß1-AR antagonist; 3 × 10-7-10-6 M) acted as a competitive antagonist of isoprenaline-induced relaxation, and the pA2 value was calculated to be 6.49 (95% confidence interval: 6.34-6.83). The relaxation to isoprenaline was not affected by ICI-118,551 (a selective ß2-AR antagonist) at 10-9-10-8 M, but was competitively antagonized by 10-7-3 × 10-7 M, with a pA2 value of 7.41 (95% confidence interval: 7.18-8.02). In the presence of propranolol (3 × 10-7 M), the relaxant effect of isoprenaline was competitively antagonized by bupranolol (a non-selective ß-AR antagonist), with a pA2 value of 5.90 (95% confidence interval: 5.73-6.35). Conclusion These findings indicated that the ß-AR subtypes involved in isoprenaline-induced relaxation of colonic longitudinal guinea pig muscles are ß1-AR and ß3-AR.

Angiotensin AT(1)-receptor blockers enhance cardiac responses to parasympathetic nerve stimulation via presynaptic AT(1) receptors in pithed rats.

In the present study, we investigated the effects of angiotensin AT1-receptor blockers, KT3-671 and losartan, on the cardiac vagal neurotransmission in pithed rats. The bradycardia induced by vagal nerve stimulation (VNS, at 5 Hz) was potentiated significantly and dose-dependently by KT3-671 and also losartan. This enhancement effect of KT3-671 (10 mg/kg) was slightly potent than that of losartan (10 mg/kg). On the other hand, an angiotensin AT2-receptor blocker, PD123319 (10 mg/kg), did not affect VNS-induced bradycardia. KT3-671 and losartan did not affect the exogenous acetylcholine-evoked bradycardia. Intravenous infusion of AngII (100 ng/kg per min) attenuated the VNS-induced bradycardia. This inhibitory effect of AngII on bradycardia was restored by both KT3-671 and losartan. These results suggest that endogenous AngII can have a tonic inhibitory effect on cardiac vagal transmission by stimulating the presynaptic AT1 receptors not AT2 receptors. Suppression of this mechanism by the AT1-receptor blockers causes the facilitation of acetylcholine release from vagal nerve endings. This acceleratory effect of AT1-receptor blockers on cardiac vagal neurotransmission may contribute to the lack of reflex tachycardia following hypotension.

Capsaicin-induced glutamate release is implicated in nociceptive processing through activation of ionotropic glutamate receptors and group I metabotropic glutamate receptor in primary afferent fibers.

Glutamate (Glu) is the major excitatory neurotransmitter in the central nervous system. The role of peripheral Glu and Glu receptors (GluRs) in nociceptive transmission is, however, still unclear. In the present study, we examined Glu levels released in the subcutaneous perfusate of the rat hind instep using a microdialysis catheter and the thermal withdrawal latency using the Plantar Test following injection of drugs associated with GluRs with/without capsaicin into the hindpaw. The injection of capsaicin into the rat hind instep caused an increase of Glu level in the s.c. perfusate. Capsaicin also significantly decreased withdrawal latency to irradiation. These effects of capsaicin were inhibited by pretreatment with capsazepine, a transient receptor potential vanilloid receptor 1 (TRPV1) competitive antagonist. Capsaicin-induced Glu release was also suppressed by combination with each antagonist of ionotropic GluRs (iGluRs: NMDA/AMPA receptors) and group I metabotropic GluR (mGluR), but not group II and group III mGluRs. Furthermore, these GluRs antagonists showed remarkable inhibition against capsaicin-induced thermal hyperalgesia. These results suggest that Glu is released from the peripheral endings of small-diameter afferent fibers by noxious stimulation and then activates peripheral iGluRs and group I mGluR in development and/or maintenance of nociception. Furthermore, the activation of peripheral NMDA/AMPA receptors and group I mGluR may be important in mechanisms whereby capsaicin evokes nociceptive responses.

New insights into the intracellular mechanisms by which PGI2 analogues elicit vascular relaxation: cyclic AMP-independent, Gs-protein mediated-activation of MaxiK channel.

Prostaglandin I2 (PGI2, prostacyclin), an eicosanoid of the cyclooxygenase pathway, causes relaxation of vascular smooth muscle in most blood vessels and inhibits platelet aggregation. PGI2 and its stable analogues activate a specific cell-surface receptor (IP receptor, IPR), which is coupled to adenylyl cyclase through G(s)-protein. Elevation of 3': 5'-cyclic monophosphate (cyclic AMP, cAMP) levels has been considered to be a key cellular event to trigger blood vessel relaxation by IP agonists; however, its exclusive role has been recently challenged. Downstream effectors of the IP agonist metabolic cascade are plasma membrane K+ channels that upon activation would cause smooth muscle cell hyperpolarization and relaxation. The K+ channel candidates include ATP-sensitive K+ (KATP) channel and large conductance, Ca2+ -activated K+ (MaxiK, BK) channel. The contribution of each K+ channel subtype would be governed by their relative expression and/or particular co-localization with different proteins of the IPR signaling cascade in each vascular bed. Scrutiny of the cellular mechanisms underlying IPR-activated vascular relaxation of a large conduit artery revealed that relaxation by an IP agonist, beraprost, is elicited through cAMP-independent pathway as well as by a cAMP-dependent route. Both mechanisms include activation of MaxiK channels. The cAMP-independent vasorelaxant mechanism is partly attributed to a direct activation of MaxiK channel by G(s)-protein. In this review article, we discuss cAMP-dependent and -independent mechanisms by which IPR stimulation activates MaxiK channel. Our recent work demonstrates a functional tight coupling between IPR and MaxiK channel through a cAMP-independent, G(s)-protein mediated mechanism(s) in vascular smooth muscle.

Beta1-adrenoceptor-mediated relaxation with isoprenaline and the role of MaxiK channels in guinea-pig esophageal smooth muscle.

The possible functional coupling between beta1-adrenoceptor and MaxiK channels which results in smooth muscle relaxation was examined in the guinea-pig esophageal muscularis mucosae. Isoprenaline-elicited relaxation of esophageal smooth muscle was confirmed to be mediated through beta1-adrenoceptors as the response was competitively antagonized by a beta1-selective antagonist atenolol with a pA2 value of 7.01. Iberiotoxin (IbTx, 10(-7) M), a selective MaxiK channel inhibitor, substantially diminished the relaxant response to isoprenaline. The extent of the MaxiK channel contribution to the relaxant response was 15-40% of the control response when estimated as the E50%-Emax responses to isoprenaline. The relaxation to isoprenaline was also attenuated by high-KCl (80 mM) to the same degree as the relaxant response generated in the presence of IbTx, and thus the estimated extent of the K+ channel contribution was 10-40%. These findings indicate that beta1-adrenoceptors are substantially coupled with MaxiK channels to produce relaxation of esophageal smooth muscle in the guinea-pig. Although MaxiK channels account for the contribution of K+ channels to the beta1-adrenoceptor-mediated relaxation in this smooth muscle preparation, their contribution seems to be less when compared to the beta2-adrenoceptor-mediated relaxation of tracheal smooth muscle.

cAMP-independent mechanism is significantly involved in beta2-adrenoceptor-mediated tracheal relaxation.

The role of cAMP in the beta2-adrenoceptor-mediated relaxation in response to salbutamol was examined in guinea pig tracheal smooth muscle. The concentration-dependent salbutamol-induced relaxation was antagonized in a competitive fashion by a beta2-selective adrenoceptor antagonist, butoxamine, with a pA2 value of 6.90. Salbutamol (10 microM) elevated the tracheal smooth muscle cAMP content by about fivefold, a response which was significantly inhibited by an adenylyl cyclase inhibitor, 9-(tetrahydro-2-furanyl)-9H-purin-6-amine (SQ 22,536, 100 microM). However, the salbutamol-elicited relaxation was not diminished by SQ 22,536 (100 microM). These results provide evidence for the first time that a cAMP-independent mechanism(s) is involved in beta2-adrenoceptor-mediated tracheal smooth muscle relaxation in the guinea pig.