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S-亚硝基谷胱甘肽抗血小板作用中不依赖环鸟苷酸机制的证据。

Evidence for a cyclic GMP-independent mechanism in the anti-platelet action of S-nitrosoglutathione.

作者信息

Gordge M P, Hothersall J S, Noronha-Dutra A A

机构信息

Centre for Nephrology, Department of Medicine, University College London.

出版信息

Br J Pharmacol. 1998 May;124(1):141-8. doi: 10.1038/sj.bjp.0701821.

DOI:10.1038/sj.bjp.0701821
PMID:9630353
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1565373/
Abstract
  1. We have measured the ability of a range of NO donor compounds to stimulate cyclic GMP accumulation and inhibit collagen-induced aggregation of human washed platelets. In addition, the rate of spontaneous release of NO from each donor has been measured spectrophotometrically by the oxidation of oxyhaemoglobin to methaemoglobin. The NO donors used were five s-nitrosothiol compounds: S-nitrosoglutathione (GSNO), S-nitrosocysteine (cysNO), S-nitroso-N-acetyl-DL-penicillamine (SNAP), S-nitroso-N-acetyl-cysteine (SNAC), S-nitrosohomocysteine (homocysNO), and two non-nitrosothiol compounds: diethylamine NONOate (DEANO) and sodium nitroprusside (SNP). 2. Using 10 microM of each donor compound, mean+/-s.e.mean rate of NO release ranged from 0.04+/-0.001 nmol min(-1) (for SNP) to 3.15+/-0.29 nmol min(-1) (for cysNO); cyclic GMP accumulation ranged from 0.43+/-0.05 pmol per 10(8) platelets (for SNP) to 2.67+/-0.31 pmol per 10(8) platelets (for cysNO), and inhibition of platelet aggregation ranged from 40+/-6.4% (for SNP) to 90+/-3.8% (for SNAC). 3. There was a significant positive correlation between the rate of NO release and the ability of the different NO donors to stimulate intra-platelet cyclic GMP accumulation (r = 0.83; P = 0.02). However, no significant correlation was observed between the rate of NO release and the inhibition of platelet aggregation by the different NO donors (r= -0.17), nor was there a significant correlation between cyclic GMP accumulation and inhibition of aggregation by the different NO donor compounds (r = 0.34). 4. Comparison of the dose-response curves obtained with GSNO, DEANO and 8-bromo cyclic GMP showed DEANO to be the most potent stimulator of intraplatelet cyclic GMP accumulation (P < 0.001 vs both GSNO and 8-bromo cyclic GMP), but GSNO to be the most potent inhibitor of platelet aggregation (P < 0.01 vs DEANO, and P < 0.001 vs 8-bromo cyclic GMP). 5. The rate of NO release from GSNO, and its ability both to stimulate intra-platelet cyclic GMP accumulation and to inhibit platelet aggregation, were all significantly diminished by the copper (I) (Cu+) chelating agent bathocuproine disulphonic acid (BCS). In contrast, BCS had no effect on either the rate of NO release, or the anti-platelet action of the non-nitrosothiol compound DEANO. 6. Cyclic GMP accumulation in response to GSNO (10(-9) 10(-5) M) was undetectable following treatment of platelets with ODQ (100 microM), a selective inhibitor of soluble guanylate cyclase. Despite this abolition of guanylate cyclase stimulation, GSNO retained some ability to inhibit aggregation, indicating the presence of a cyclic GMP-independent component in its anti-platelet action. However, this component was abolished following treatment of platelets with a combination of both ODQ and BCS, suggesting that Cu+ ions were required for the cyclic GMP-independent pathway to operate. 7. The cyclic GMP-independent action of GSNO, observed in ODQ-treated platelets, could not be explained by an increase in intra-platelet cyclic AMP. 8. The impermeable thiol modifying agent p-chloromercuriphenylsulphonic acid (CMPS) produced a concentration-dependent inhibition of aggregation of ODQ-treated platelets, accompanied by a progressive loss of detectable platelet surface thiol groups. Additional treatment with GSNO failed to increase the degree of aggregation inhibition, suggesting that a common pathway of thiol modification might be utilized by both GSNO and CMPS to elicit cyclic GMP-independent inhibition of platelet aggregation. 9. We conclude that NO donor compounds mediate inhibition of platelet aggregation by both cyclic GMP-dependent and -independent pathways. Cyclic GMP generation is related to the rate of spontaneous release of NO from the donor compound, but transfer of the NO signal to the cyclic GMP-independent pathway may depend upon a cellular system which involves both copper (I) (Cu+) ions and surface membrane thiol groups. The potent anti-platelet action of GSNO
摘要
  1. 我们测定了一系列一氧化氮供体化合物刺激环磷酸鸟苷(cGMP)积累以及抑制胶原诱导的人洗涤血小板聚集的能力。此外,通过将氧合血红蛋白氧化为高铁血红蛋白,用分光光度法测定了每种供体自发释放一氧化氮的速率。所使用的一氧化氮供体为五种S-亚硝基硫醇化合物:S-亚硝基谷胱甘肽(GSNO)、S-亚硝基半胱氨酸(cysNO)、S-亚硝基-N-乙酰-DL-青霉胺(SNAP)、S-亚硝基-N-乙酰半胱氨酸(SNAC)、S-亚硝基高半胱氨酸(homocysNO),以及两种非亚硝基硫醇化合物:二乙胺亚硝酰酯(DEANO)和硝普钠(SNP)。2. 使用每种供体化合物10微摩尔,一氧化氮释放的平均±标准误速率范围为0.04±0.001纳摩尔·分钟⁻¹(对于SNP)至3.15±0.29纳摩尔·分钟⁻¹(对于cysNO);cGMP积累范围为每10⁸个血小板0.43±0.05皮摩尔(对于SNP)至每10⁸个血小板2.67±0.31皮摩尔(对于cysNO),血小板聚集抑制范围为40±6.4%(对于SNP)至90±3.8%(对于SNAC)。3. 一氧化氮释放速率与不同一氧化氮供体刺激血小板内cGMP积累的能力之间存在显著正相关(r = 0.83;P = 0.02)。然而,未观察到一氧化氮释放速率与不同一氧化氮供体对血小板聚集的抑制之间存在显著相关性(r = -0.17),不同一氧化氮供体化合物的cGMP积累与聚集抑制之间也未存在显著相关性(r = 0.34)。4. 用GSNO、DEANO和8-溴环磷酸鸟苷获得的剂量反应曲线比较表明,DEANO是血小板内cGMP积累的最有效刺激剂(与GSNO和8-溴环磷酸鸟苷相比,P < 0.001),但GSNO是血小板聚集的最有效抑制剂(与DEANO相比,P < 0. 01;与8-溴环磷酸鸟苷相比,P < 0.001)。5. 铜(I)(Cu⁺)螯合剂bathocuproine二磺酸(BCS)显著降低了GSNO释放一氧化氮的速率及其刺激血小板内cGMP积累和抑制血小板聚集的能力。相比之下,BCS对非亚硝基硫醇化合物DEANO的一氧化氮释放速率或抗血小板作用均无影响。6. 用可溶性鸟苷酸环化酶的选择性抑制剂ODQ(100微摩尔)处理血小板后,未检测到对GSNO(10⁻⁹ - 10⁻⁵摩尔)的cGMP积累反应。尽管鸟苷酸环化酶刺激被消除,但GSNO仍保留了一些抑制聚集的能力,表明其抗血小板作用中存在不依赖cGMP的成分。然而,用ODQ和BCS联合处理血小板后,该成分被消除,表明Cu⁺离子是不依赖cGMP途径发挥作用所必需的。7. 在ODQ处理的血小板中观察到的GSNO不依赖cGMP的作用不能用血小板内环磷酸腺苷(cAMP)增加来解释。8. 不可渗透的巯基修饰剂对氯汞苯磺酸(CMPS)对ODQ处理的血小板聚集产生浓度依赖性抑制,同时可检测到的血小板表面巯基基团逐渐丧失。用GSNO进一步处理未能增加聚集抑制程度,表明GSNO和CMPS可能利用共同的巯基修饰途径引发不依赖cGMP的血小板聚集抑制。9. 我们得出结论,一氧化氮供体化合物通过依赖cGMP和不依赖cGMP的途径介导血小板聚集的抑制。cGMP的产生与供体化合物自发释放一氧化氮的速率相关,但一氧化氮信号向不依赖cGMP途径的传递可能取决于一个涉及铜(I)(Cu⁺)离子和表面膜巯基基团的细胞系统。GSNO的强效抗血小板作用

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