Effects of 5-hydroxytryptamine on electrical responses of circular smooth muscle isolated from the guinea-pig gastric antrum.

The effects of 5-hydroxytryptamine (5-HT) on electrical responses of the membrane were investigated in circular smooth muscle isolated from the guinea-pig stomach antrum. Small segment of circular muscle tissue produced a periodical generation of slow potentials at frequency of 0.1-2 cycles min(-1), during random generation of unitary potentials. Application of 5-HT (10(-7)-10(-5) M) hyperpolarized the membrane and either increased or decreased the frequency of slow potentials, both with associated increase in amplitude of slow potential. These effects of 5-HT were abolished by methysergide. N(omega)-nitro-L-arginine (L-NA) increased the frequency of spontaneously generated slow potentials and also increased the frequency of slow potentials generated during stimulation with 5-HT, suggesting an involvement of the increased production of nitric oxide (NO) by 5-HT. Atropine did not alter spontaneous and 5-HT-induced electrical responses. The hyperpolarization produced by 5-HT was associated with a decrease in input resistance and time constant of the membrane. The amplitude of the 5-HT-induced hyperpolarization was increased in low [K(+)](o) solution and decreased in high [K(+)](o) solution or in the presence of glybenclamide, suggesting that the hyperpolarization was produced by activation of ATP-sensitive K-channels. The increase in amplitude of slow potentials by 5-HT may be secondary due to hyperpolarization of the membrane. The inhibition by 5-HT of the frequency of slow potentials may be partly due to the increased release of NO, however the mechanism by which dual effects of 5-HT on the frequency of slow potentials remains unsolved.     

Effects of iodoacetate on spontaneous electrical activity, slow wave, in the circular muscle of the guinea-pig gastric antrum

In the circular muscle of the guinea-pig gastric antrum, the contribution of glycolysis to spontaneous electrical activity, slow wave, was studied. The slow wave could be maintained without a marked change in glucose-free solution for more than 1 h even when treated with iodoacetic acid (IAA, 0.1-0.5 mM). However, reapplication of glucose following the IAA treatment produced clear inhibitory effects on the slow wave. Lactate release from the tissue was reduced to about 10% of the control by IAA (0.1 mM) in the absence of glucose and there was very slow recovery on glucose reapplication. This suggests that IAA did not block glycolysis completely and that the inhibition of slow wave was mainly due to the accumulation of some metabolites. Small electrical activity often remained during the inhibition by IAA and glucose. When the excitability of the smooth muscle was increased by Co(2+) application or Na(+) removal, slow wave-like activity could be generated under the condition in which the slow wave was strongly inhibited by IAA and glucose. These results may be explained by assuming that the accumulation of glycolytic metabolites decreases the excitability of smooth muscle cells and also reduces the driving potential generated in the interstitial cells of Cajal to a subthreshold level for the slow wave in the smooth muscle cells.     

Voltage dependency of the frequency of slow waves in antrum smooth muscle of the guinea-pig stomach

The effects of membrane depolarization on the frequency of spontaneous activities were investigated in circular smooth muscle of the guinea-pig antrum attached with (intact tissue) or without longitudinal muscles (circular tissue). Both types of tissue were spontaneously active; the intact tissues generated slow wave and circular tissues generated regenerative potential. The latter but not the former was abolished by caffeine. Increasing K(+) concentrations depolarized the membrane and reduced the amplitude and interval between spontaneous activities in both tissues; the amplitude was reduced linearly with depolarization and disappeared at about -35 mV; the interval was reduced successively with depolarization and reached a stable value (about 8 s) at about -45 mV. The depolarization and reduction in amplitude and interval of spontaneous activities induced by high K(+) solution were not altered by atropine, nitroarginine, or apamin in either tissue, suggesting that these changes did not involve the effects of neurotransmitters. The depolarization of the membrane by electrical stimulation also reduced the amplitude and interval of spontaneous activities in both tissues, in a potential-dependent way. The absolute refractory period for generation of the evoked regenerative potential was about 8 s, and the relative refractory period was 8--12 s. The results indicate that the frequency of slow waves increases with a depolarization of the membrane up to -45 mV, irrespective of the presence of caffeine-insensitive components. A depolarization of the membrane above -45 mV does not further increase the frequency of slow waves, possibly because of the refractory period for the generation of slow waves.     

Dual effects of cyclopiazonic acid on excitation of circular smooth muscle isolated from the guinea-pig gastric antrum.

The effects of cyclopiazonic acid (CPA), a known Ca2+-pump inhibitor at internal stores, were investigated on electrical responses of the membrane of smooth muscle cells in small segments (0.3-0.5 mm long) of circular smooth muscle isolated from the guinea-pig gastric antrum. In most preparations, the membrane was spontaneously active with the generation of unitary potentials and regenerative slow potentials. Low concentrations (< 1 microM) of CPA did not alter either the membrane potential or the amplitude and frequency of slow potentials. CPA at a concentration of 1 microM initially increased the frequency of slow potentials, but this was followed by a decrease in the frequency as a result of sustained exposure to CPA, with no alteration of either the membrane potential or the amplitude of slow potentials. Higher concentrations of CPA (2-5 microM) depolarized the membrane and decreased the amplitude and frequency of slow potentials. CPA at higher than 10 microM abolished slow potentials with depolarization of the membrane. Intracellular electrical responses recorded simultaneously from paired cells were synchronized, indicating electrical coupling of the cells. Depolarization of the membrane with current stimuli through one electrode evoked regenerative slow potentials superimposed on the electrotonic potentials. The evoked slow potential had a refractory period of about 7 s. CPA (up to 10 microM) did not prevent the synchronization of paired cells. The refractory period for slow potentials was reduced by low concentrations of CPA (< 1 microM) and increased by higher concentrations of CPA (2-10 microM). These results suggest that lower concentrations of CPA produce excitatory actions on gastric smooth muscles due to a secondary effect of increased intracellular [Ca2+], while higher concentrations of CPA produce inhibitory actions as a result of reduced release of Ca2+ from depleted internal stores.     

Effects of RHC-80267, an inhibitor of diacylglycerol lipase, on excitation of circular smooth muscle of the guinea-pig gastric antrum.

In small segments of circular smooth muscle isolated from the guinea-pig gastric antrum, the effects of RHC-80267, an inhibitor of diacylglycerol lipase, were investigated both on regenerative slow potentials (either occurring spontaneously or as the result of a depolarizing intracellular current injection) and on the actions of acetylcholine (ACh). As diacylglycerol is a known activator of protein kinase C (PKC), it would therefore be expected that RHC-80267 would activate PKC indirectly. In circular smooth muscle bundles, spontaneously generating slow potentials recorded simultaneously from two given cells were synchronized, indicating that these two cells were electrically coupled. RHC-80267 (0.3-1 microM) increased the frequency of slow potential generation, with no alteration to the amplitude of either the slow potentials or the resting membrane potential. Synchronous electrical activity in a given pair of cells was also unchanged by RHC-80267, indicating that intercellular electrical coupling was not altered. The input resistance of smooth muscle cells calculated from the amplitude of electrotonic potentials produced by injection of current was not significantly altered by RHC-80267. The refractory period for the generation of slow potentials evoked by depolarizing stimuli was about 8 s, and it was decreased to about 5 s by RHC-80267, with no significant alteration to the amplitude of spontaneous or evoked slow potentials. ACh (0.5 microM) depolarized the membrane by about 5 mV and increased the amplitude and frequency of slow potentials. The actions of ACh on the frequency of slow potentials were enhanced by RHC-80267, with no alteration to the amplitudes of both the ACh-induced depolarization and slow potentials. These results support the idea that PKC is involved in determining the frequency of slow potentials, by shortening the refractory period for excitation of gastric smooth muscle cells.     

Voltage-dependent calcium entry underlies propagation of slow waves in canine gastric antrum

Electrical slow waves in gastrointestinal (GI) muscles are generated by interstitial cells of Cajal (ICC), and these events actively propagate through networks of ICC within the walls of GI organs. The mechanism by which spontaneously active pacemaker sites throughout ICC networks are entrained to produce orderly propagation of slow waves is unresolved. A three-chambered partition bath was used to test the effects of agents that affect metabolism, membrane potential and voltage-dependent Ca²⁺ entry on slow wave propagation in canine antral smooth muscle strips. Slow waves evoked by electrical field stimulation actively propagated from end to end of antral muscle strips with a constant latency between two points of recording. When the central chamber of the bath was perfused with low-temperature solutions, mitochondrial inhibitors, reduced extracellular Ca²⁺ or blockers of voltage-dependent Ca²⁺ channels, active propagation failed. Depolarization or hyperpolarization of the tissue within the central chamber also blocked propagation. Blockade of propagation by reduced extracellular Ca²⁺ and inhibitors of dihydropyridine-resistant Ca²⁺ channels suggests that voltage-dependent Ca²⁺ entry may be the 'entrainment factor' that facilitates active propagation of slow waves in the gastric antrum.     

Effects of endogenous and exogenous nitric oxide on electrical responses of circular smooth muscle isolated from the guinea-pig stomach antrum.

The effects of endogenous and exogenous nitric oxide (NO) on electrical activity were investigated in circular smooth muscle preparations isolated from the guinea-pig stomach antrum. The actions of endogenous NO were evaluated from the effects of inhibition of NO synthesis by N(omega)-nitro-L-arginine (nitroarginine), while those of exogenous NO were assessed from the effects of SIN-1, an NO donor. Antral circular smooth muscle generated slow potentials periodically at a frequency of about 1 cycle per min (cpm), and unitary potentials were also generated in a random fashion in the interval between slow potentials. Application of nitroarginine (10(-5) M) increased the frequency of slow potentials, with no significant alteration of the resting membrane potential and amplitude of slow potentials. Frequency analysis of unitary potentials revealed that nitroarginine also increased the spectral density at 0.01-1 Hz frequency. The refractory period for the generation of slow potentials evoked by depolarizing pulses was about 10 s, but was decreased to 6 s by nitroarginine. In the presence of nitroarginine, SIN-1 (10(-9)-10(-7) M) reduced the amplitude and frequency of slow potentials: low concentrations (<10(-8) M) reduced only the frequency of slow potentials, while higher concentrations (10(-8)-10(-7) M) reduced both the amplitude and frequency of slow potentials, in a concentration-dependent manner, before abolishing the slow potentials. The power spectrum of the unitary potentials indicated that SIN-1 (>10(-8) M) reduced the spectral density at 0.01-1 Hz frequency. The refractory period for the generation of slow potentials was increased again to about 10 s by SIN-1. Thus, the excitatory effects of nitroarginine could be antagonized by SIN-1, suggesting that the inhibitory effects of endogenous NO are comparable to those of exogenous NO produced by SIN-1. The results also suggested that the effects of NO on smooth muscle are insignificant and NO selectively inhibits the activity of intramuscular interstitial cells of Cajal (ICC-IM).     

Effects of inhibitors of nonselective cation channels on the acetylcholine-induced depolarization of circular smooth muscle from the guinea-pig stomach antrum.

In circular smooth muscle bundles isolated from the guinea-pig stomach antrum, the effects of quinidine, Ni2+, flufenamic acid, niflumic acid, La3+, SKF-96365 and 4'-diisothiocyanatostilbene-2,2'-disulphonic acid (DIDS) on acetylcholine (ACh)-induced depolarization were investigated. Recording membrane potentials from smooth muscle cells with intracellular microelectrodes revealed that ACh (1 microM) depolarized the membrane by 5-8 mV and increased the amplitude and frequency of slow potentials. These effects were inhibited by atropine. Quinidine (10 microM) increased the amplitude of ACh-induced depolarization, with no alteration to the properties of slow potentials. Ni2+ (50 microM) transiently (5-10 min) depolarized the membrane by about 5 mV, with an associated increase in frequency and amplitude of slow potentials. In the stabilized condition with Ni2+, the amplitude of ACh-induced depolarization remained unchanged. Flufenamic acid (10 microM) inhibited the generation of slow potentials, with no change in either the amplitude of ACh-induced depolarization or of the amplitude and frequency of slow potentials generated during ACh stimulation. A high concentration of flufenamic acid (100 microM) depolarized the membrane and increased the amplitude of ACh-induced depolarization. Niflumic acid (10 microM) hyperpolarized the membrane and increased the amplitude and frequency of slow potentials and also the amplitude of ACh-induced depolarization. DIDS (100 microM) hyperpolarized the membrane and inhibited the amplitude and frequency of slow potentials, with no alteration to the amplitude of ACh-induced depolarization. SKF-96365 (3-50 microM) depolarized the membrane in a concentration-dependent manner, but did not change the level of ACh-induced depolarization. La3+ (50 microM) did not alter the properties of the slow potentials or the ACh-induced responses. These results provide evidence that ACh-induced depolarization is not inhibited by chemicals known to inhibit non-selective cation channels. We suggest that muscarinic receptor-mediated signal transduction may be different in smooth muscle and interstitial cells.     

On the nature of the oscillations of the membrane potential (slow waves) produced by acetylcholine or carbachol in intestinal smooth muscle

1. Intracellular recording was made with glass micro-electrodes from cells of the longitudinal muscle of the guinea-pig ileum in isotonic and in hypertonic solution.2. In isotonic solution spontaneous bursts of electrical activity occurred; these consisted of a slow potential component which carried a burst of spike action potentials. Acetylcholine increased the size (and the frequency) of the slow potential component. This had the effect of first reducing and then abolishing the spike potentials; continuous slow wave activity was thus produced. Slow waves were about 1 sec in duration and up to 50 mV in size in isotonic solution.3. In hypertonic solution the membrane potential was stable. There were no spontaneous spikes and no slow potentials. However, spikes, but not slow potentials, were elicited by depolarizing current. Carbachol (or acetylcholine) reduced the membrane potential and initiated spikes and oscillations of the membrane potential (slow waves). Slow waves were 2-5 sec in duration and 10-40 mV in size in hypertonic solution.4. The response to carbachol in hypertonic solution was unaffected by surgical denervation of the tissue, by tetrodotoxin, or by ganglion blocking agents, indicating that muscarinic stimulants produced their effects by acting directly on the smooth muscle cell.5. In hypertonic solution slow waves occurred only in the presence of a muscarinic stimulant and could not be elicited with depolarizing current (unless carbachol was present) nor by increasing the external potassium concentration.6. In hypertonic solution slow waves were abolished by hyperpolarizing the membrane and their rate of rise was proportional to the level of the membrane potential from which they arose. The membrane resistance was reduced at the peak of the slow wave. Slow waves were rapidly abolished by sodium-deficient solutions but spikes were not.7. It is suggested that slow waves represent an inward current through a slow, sodium-sensitive and voltage-dependent ion channel, and that acetylcholine or carbachol increase, while hypertonic solution decreases, the current carried by this channel.     

Effects of removal of Na(+) and Cl(-) on spontaneous electrical activity, slow wave, in the circular muscle of the guinea-pig gastric antrum

In the circular muscle of the guinea-pig gastric antrum, a decrease in the external Na(+) to less than 20 mM produced depolarization of the membrane with transient prolongation of the slow wave. This was followed by a high rhythmic activity. The activity was inhibited by reapplication of Na(+) before recovery. The depolarization in Na(+)-deficient solution was prevented and rhythmic activity continued at about 5/min for at least 6 min by simultaneous removal of K(+), Ca(2+), or Cl(-). After exposure to a Na(+)- and Cl(-)-deficient solution for a few minutes, reapplication of the Na(+) in Cl(-)-deficient solution inhibited generation of the slow wave until Cl(-) reapplication. Similar results were obtained when Na(+) and Cl(-) were reapplied in the absence of K(+) after exposure to a Na(+)-, K(+)-free, and Cl(-)-deficient solution, although the inhibition was weaker than Na(+) reapplication in a Cl(-)-deficient solution. In the presence of furosemide or bumetanide, a strong inhibition of activity was produced by the reapplication of Na(+) and Cl(-) after exposure to an Na(+)- and Cl(-)-deficient solution. A hypothesis is presented that intracellular Ca(2+) concentration ([Ca(2+)](i)) is the most important factor determining the generation and frequency of the slow wave and that [Ca(2+)](i) is regulated by the Na(+) concentration gradient across the plasma membrane. The recovery of the Na(+) concentration gradient by Na(+) reapplication after removal of Na(+) and Cl(-) is mainly controlled by a Na(+)-K(+)-Cl(-) co-transport.     

Big endothelin-1 but not endothelin-1 is present in the smooth muscle stroma of the prostate gland of the rat

Immunohistochemical techniques were employed to localize the presence of endothelins in the mature rat prostate gland. Immunoreactivity for big endothelin‐1 but not endothelin‐1 was observed in the fibromuscular stroma of the rat prostate gland. No immunoreactivity was seen in the glandular epithelium. Double staining procedures showed big endothelin‐1 immunoreactivity to be co‐localized with α‐actin immunoreactivity. The stroma of the prostate gland also contained nerve fibres coursing through it which are immunopositive for tyrosine hydroxylase. These results suggest that big endothelin‐1 but not endothelin‐1 is co‐localized with α‐actin in the smooth muscle cells of the rat prostate gland. This implies that endothelin‐1 is synthesized on demand from big endothelin‐1 in the fibromuscular stroma of the rat prostate.     

糖尿病大鼠胃平滑肌细胞凋亡与线粒体膜电位改变

目的 揭示糖尿病胃轻瘫(DGP)发病机制 方法 SD大鼠随机分为对照组和模型组,造模10周后,模型检测;流式细胞术测细胞凋亡与 m;免疫组化测CYT C。结果 与对照组相比：(1)模型组造模后均出现多尿、多饮、多食症状,体重减轻;血糖浓度显著增高 (P＜0.01);胃内色素残留率显著降低（P＜0.01）。(2)模型组胃平滑肌细胞凋亡率显著增高（P＜0.01）, m显著降低（P＜0.01）, 胞质CYT C显著增加。结论 线粒体介导了糖尿病大鼠胃平滑肌细胞凋亡,后者在糖尿病胃轻瘫发病机制中扮演了一定角色。     

内皮素-1对大鼠血管平滑肌表型转化和增殖的影响

目的:通过内皮素-1作用于大鼠血管平滑肌细胞(VSMC)及对内皮素-1受体信号的阻断,探讨内皮素-1对VSMC表型转化和增殖的影响及机制.方法:取大鼠主动脉贴块培养VSMC,用内皮素-1及其受体阻断剂BQ123分别作用于一般培养的VSMC和血清饥饿培养的VSMC.用BrdU标记细胞增殖;RT-PCR检测高血压相关基因-1(HRG-1)和SM22α表达变化.结果:内皮素-1作用后VSMC增殖显著增多,HRG-1和SM22α mRNA在一般培养和饥饿培养的VSMC中表达均明显减少;而加入阻断剂BQ123后增殖细胞大大减少,HRG-1和SM22α mRNA表达明显上调.结论:内皮素-1有促进VSMC增殖作用并可使VSMC从收缩型向合成型转化,并且内皮素-1对VSMC的作用是不可逆的;受体信号途径是内皮素-1对VSMC表型转化和增殖作用的机制之一.     

Effects of removal and reapplication of K(+) and Cl(-) on spontaneous electrical activity, slow wave, in the circular muscle of the guinea-pig gastric antrum

In the circular muscle of guinea-pig gastric antrum, the effects of removal and reapplication of K(+) and Cl(-) were studied on the slow wave, which consists of the lower, first and upper, second components. The first component appeared to be triggered by the driving potential generated in the interstitial cells. K(+) removal slightly depolarized the membrane, increased frequency, and shortened the first component and driving potential, and K(+) reapplication hyperpolarized and prolonged these potentials transiently. Ouabain abolished the K(+)-induced hyper-polarization but had no inhibitory effect on the K(+)-induced potentiation. The K(+)-induced prolongation was much reduced in Ca(2+)-deficient and increased in Ca(2+)-excess solution. BAPTA-AM, thapsigargin, and cyclopiazonic acid shortened the slow wave and inhibited the K(+)-induced prolongation but did not block the slow wave. Effects of Cl(-) removal were stronger than K(+) removal in shortening and increasing the frequency. In Cl(-)-deficient solution, no prolongation was observed on K(+) reapplication. Although no conclusive evidence was obtained as to the ionic mechanism involved in the effects of K(+) or Cl(-) removal and reapplication, a possibility is considered that the sarcoplasmic reticulum is involved in determining the duration of the driving potential and the first component of the slow wave.     

Spontaneous activity and its cholinergic modulation in circular smooth muscle isolated from guinea-pig stomach antrum

Circular smooth muscle isolated from the guinea-pig gastric antrum generated periodic slow potentials in the presence of nifedipine and nitroarginine to prevent the activity of voltage-gated L-type Ca-channels and endogenous production of NO respectively. Chelerythrine, an inhibitor of protein kinase C (PKC), in the concentration range 10^–7–3×10^–7 M reduced the frequency but not the amplitude of spontaneous slow potentials without altering the resting membrane potential. 2-Aminoethoxydiphenyl borate (2-APB, 3×10^–6 M), an inhibitor at inositol-1,4,5-trisphosphate (IP₃) receptors, depolarized the membrane, increased the frequency and reduced the amplitude of the slow potentials; the latter actions were independent of depolarization. Two different phorbol esters, phorbol 12,13-dibutyrate and phorbol-12-myristate-13-acetate, increased the frequency of slow potentials, without altering the amplitude or changing the resting membrane potential; the effects of phorbol esters were antagonized by chelerythrine. Stimulation of muscarinic receptors with acetylcholine (ACh), in concentrations below those causing membrane depolarization (3×10^–8–10^–7 M), increased the amplitude and frequency of slow potentials. Chelerythrine inhibited the ACh-induced increase in the frequency of slow potentials but did not prevent the increase in their amplitude. 2-APB inhibited the ACh-induced increase in the amplitude of slow potentials but did not prevent the increase in their frequency. These results suggest that the frequency of spontaneous slow potentials is regulated by PKC and their amplitude by IP₃ production. ACh increases both the amplitude and frequency of slow potentials; the former is related to the activation of PKC, while the latter is related to activation of IP₃-receptors.