Christinck F, Jury J, Cayabyab F, Daniel E E
McMaster University, Department of Biomedical Sciences, Hamilton, Ont., Canada.
Can J Physiol Pharmacol. 1991 Oct;69(10):1448-58. doi: 10.1139/y91-217.
This study tested the hypothesis that the final mediator of nonadrenergic, noncholinergic (NANC) inhibitory junction potentials (ijps) and associated relaxation responses was nitric oxide (NO) or a related substance and not vasoactive intestinal polypeptide (VIP). We used opossum esophagus body circular muscle and canine intestine circular muscle. In both these tissues, ijps had reversal potentials near the potassium equilibrium potential, (EK); in esophagus the ijps were apamin insensitive, but in the intestine they were partially apamin sensitive. N omega-Nitro-L-arginine methyl ester (NAME) (10(-5) to 5 x 10(-4) M) abolished ijps in both tissues, an effect overcome by 10(-3) M L-arginine but not D-arginine. NAME increased input resistance of esophagus tissues in the double sucrose gap but caused no significant depolarization in the sucrose gap or in studies with microelectrodes. Contractions and basal tension were increased in both tissues by NAME. The apamin sensitive and insensitive ijp components in canine muscle were both abolished by NAME, but the time course of this abolition was different for the two components. Methylene blue (10-50 microM) with variable rapidity and extent inhibited ijps in both tissues, but L-arginine could not overcome this effect. Methylene blue, like NAME, did not depolarize detectably but enhanced the contractile activity. VIP (10(-6) M) had very small effects in both tissues, little or no hyperpolarization and increased input resistance in esophagus, these effects were not changed by NAME, and VIP did not affect ijps. We conclude that NO may be the final mediator of NANC-initiated inhibitory junction potentials in gastrointestinal circular smooth muscle.
非肾上腺素能、非胆碱能(NANC)抑制性接头电位(ijps)及相关舒张反应的最终介质是一氧化氮(NO)或一种相关物质,而非血管活性肠肽(VIP)。我们使用了负鼠食管体环行肌和犬肠环行肌。在这两种组织中,ijps的反转电位接近钾平衡电位(EK);在食管中,ijps对蜂毒明肽不敏感,但在肠中它们对蜂毒明肽部分敏感。Nω-硝基-L-精氨酸甲酯(NAME)(10^(-5)至5×10^(-4)M)消除了两种组织中的ijps,10^(-3)M的L-精氨酸可克服此效应,但D-精氨酸不能。在双蔗糖间隙实验中,NAME增加了食管组织的输入电阻,但在蔗糖间隙实验或微电极研究中未引起明显的去极化。NAME使两种组织的收缩和基础张力增加。犬肌肉中对蜂毒明肽敏感和不敏感的ijp成分均被NAME消除,但两种成分消除的时间进程不同。亚甲蓝(10 - 50μM)以不同的速度和程度抑制了两种组织中的ijps,但L-精氨酸不能克服这种效应。亚甲蓝与NAME一样,未检测到可察觉的去极化,但增强了收缩活性。VIP(10^(-6)M)对两种组织的作用非常小,几乎没有或没有超极化,且增加了食管的输入电阻,这些效应不受NAME影响,VIP也不影响ijps。我们得出结论,NO可能是胃肠道环行平滑肌中NANC引发的抑制性接头电位的最终介质。
