Zhang X, Scicli G A, Xu X, Nasjletti A, Hintze T H
Department of Physiology, New York Medical College, Valhalla 10595, USA.
Hypertension. 1997 Nov;30(5):1105-11. doi: 10.1161/01.hyp.30.5.1105.
The purpose of the present study was to determine whether interventions that promote kinin production or decrease kinin inactivation affect nitric oxide production in isolated canine coronary microvessels. Accordingly, bradykinin (10[-8] to 10[-5] mol/L), ramiprilat (10[-10] to 10[-8] mol/L), A23187 (10[-8] to 10[-6] mol/L), kallikrein (1 to 20 U/mL), and kininogen (0.5 to 10 microg/mL) were used to stimulate endothelium-dependent nitric oxide production. Receptor antagonists, serine protease inhibitors, and a kinin antibody were used to inactivate local kallikrein-kinin activity. Nitrite, the metabolite of nitric oxide in aqueous solution, was measured using the Griess reaction. All the agonists significantly increased nitrite release. For instance, the highest dose of bradykinin, ramiprilat, A23187, kallikrein, and kininogen markedly increased nitrite production, from 60+/-10 to 156+/-12, 153+/-11, 161+/-15, 176+/-15, and 168+/-16 pmol/mg (all P<.05), respectively. The increased nitrite production caused by these agents was not only blocked by N omega-nitro-L-arginine methyl ester (L-NAME) and HOE 140 (which blocks B2 kinin receptor) but by the kinin antibody also. For instance, nitrite production elicited by bradykinin, ramiprilat, A23187, and kininogen was reduced to 95+/-8, 87+/-8, 94+/-11, and 85+/-11 pmol/mg (all P<.05), respectively, by the kinin antibody. Carbachol-induced nitrite production (from 66+/-8 to 144+/-13) was blocked by L-NAME but not by HOE 140 or the kinin antibody. These results suggest that either increasing kininogen to promote endogenous kinin formation or inhibiting angiotensin-converting enzyme to decrease kinin breakdown, increases nitric oxide production in isolated coronary microvessels. These data indicate that a microvessel kallikrein-kinin system has an important role in the control of nitric oxide production in coronary microvessels.
本研究的目的是确定促进激肽生成或减少激肽失活的干预措施是否会影响离体犬冠状动脉微血管中一氧化氮的生成。因此,使用缓激肽(10[-8]至10[-5]mol/L)、雷米普利拉(10[-10]至10[-8]mol/L)、A23187(10[-8]至10[-6]mol/L)、激肽释放酶(1至20U/mL)和激肽原(0.5至10μg/mL)来刺激内皮依赖性一氧化氮的生成。使用受体拮抗剂、丝氨酸蛋白酶抑制剂和激肽抗体来灭活局部激肽释放酶-激肽活性。使用格里斯反应测量水溶液中一氧化氮的代谢产物亚硝酸盐。所有激动剂均显著增加亚硝酸盐释放。例如,缓激肽、雷米普利拉、A23187、激肽释放酶和激肽原的最高剂量均显著增加亚硝酸盐生成,分别从60±10增加至156±12、153±11、161±15、176±15和168±16pmol/mg(均P<0.05)。这些药物引起的亚硝酸盐生成增加不仅被Nω-硝基-L-精氨酸甲酯(L-NAME)和HOE 140(阻断B2激肽受体)阻断,也被激肽抗体阻断。例如,激肽抗体使缓激肽、雷米普利拉、A23187和激肽原引起的亚硝酸盐生成分别降至95±8、87±8、94±11和85±11pmol/mg(均P<0.05)。卡巴胆碱诱导的亚硝酸盐生成(从66±8至144±13)被L-NAME阻断,但未被HOE 140或激肽抗体阻断。这些结果表明,增加激肽原以促进内源性激肽形成或抑制血管紧张素转换酶以减少激肽分解,均可增加离体冠状动脉微血管中一氧化氮的生成。这些数据表明,微血管激肽释放酶-激肽系统在冠状动脉微血管中一氧化氮生成的调控中起重要作用。
