Role of nitric oxide in the synthesis of guanidinosuccinic acid, an activator of the N-methyl-D-aspartate receptor.

Kidney international. Supplement Pub Date : 2001-01-01 DOI:10.1046/j.1523-1755.2001.07842.x

K. Aoyagi, S. Shahrzad, S. Iida, C. Tomida, A. Hirayama, S. Nagase, K. Takemura, A. Koyama, S. Ohba, M. Narita, B. Cohen

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引用次数: 11

Abstract

BACKGROUND We propose that reactive oxygen and argininosuccinic acid (ASA) form guanidinosuccinic acid (GSA). An alternative to this hypothesis is the so-called guanidine cycle, which consists of a series of hydroxyurea derivatives that serve as intermediates in a pathway leading from urea to GSA. We compare the role of the guanidine cycle to that of nitric oxide (NO) in the synthesis of GSA. METHODS The members of the guanidine cycle (hydroxyurea, hydroxylamine plus homoserine, L-canaline, and L-canavanine) were incubated with isolated rat hepatocytes. The known NO donors, NOR-2, NOC-7, and SIN-1, were incubated with ASA in vitro. Ornithine, arginine, or citrulline, which increase arginine, a precursor of NO, were incubated with isolated rat hepatocytes. GSA was determined by high-performance liquid chromatography. RESULTS None of guanidine cycle members except for urea formed GSA. SIN-1, which generates superoxide and NO formed GSA, but other simple NO donors, did not. Both carboxy-PTIO, a scavenger of NO, and dimethyl sulfoxide, a hydroxyl radical scavenger, completely inhibited GSA synthesis by SIN-1. GSA formation by SIN-1 reached a maximum at 0.5 mmol/L and decreased at higher concentrations. GSA synthesis, stimulated by urea in isolated hepatocytes, was inhibited by ornithine, arginine, or citrulline with ammonia, but not by ornithine without ammonia, where arginine production is limited. CONCLUSION GSA is formed from ASA and the hydroxyl radical. When arginine increased in hepatocytes, GSA synthesis decreased. These data suggest that increased NO, which results from high concentrations of arginine, or SIN-1 scavenges the hydroxyl radical. This may explain the decreased GSA synthesis in inborn errors of the urea cycle where ASA is decreased, and also the diminished GSA excretion in arginemia.

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一氧化氮在n -甲基- d -天冬氨酸受体活化剂胍丁二酸合成中的作用。

我们提出活性氧和精氨酸琥珀酸(ASA)形成胍丁二酸(GSA)。这一假设的另一种选择是所谓的胍循环，它由一系列羟基脲衍生物组成，作为从尿素到GSA的途径的中间体。我们比较了胍循环和一氧化氮(NO)在GSA合成中的作用。方法用离体大鼠肝细胞孵育胍环的成员(羟基脲、羟胺加同型丝氨酸、l -犬碱和l -犬碱)。已知NO供体NO -2、NOC-7和SIN-1用ASA体外孵育。鸟氨酸、精氨酸或瓜氨酸能增加精氨酸(一氧化氮的前体)，与分离的大鼠肝细胞孵育。采用高效液相色谱法测定GSA。结果除尿素外，所有胍环成员均不形成GSA。生成超氧化物和一氧化氮的SIN-1形成了GSA，但其他简单的一氧化氮供体却没有。羧基ptio (NO的清除剂)和二甲基亚砜(羟基自由基的清除剂)都能完全抑制SIN-1合成GSA。在0.5 mmol/L时，SIN-1的GSA生成量最大，浓度越高，GSA生成量越低。在分离的肝细胞中，尿素刺激GSA的合成，被鸟氨酸、精氨酸或瓜氨酸加氨抑制，但不加氨的鸟氨酸不抑制GSA的合成，因为精氨酸的产生有限。结论sa是由ASA和羟基自由基形成的。当精氨酸在肝细胞中增加时，GSA的合成减少。这些数据表明，高浓度精氨酸或SIN-1引起的一氧化氮增加可以清除羟基自由基。这可能解释了先天性尿素循环错误中GSA合成减少的原因，也解释了精氨酸血症中GSA排泄减少的原因。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Kidney international. Supplement

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